ABSR
{
RETE|ID 1 FBab0025194	CLA 1 Aberration	GSYM 1 Ab(?)B13	DT 1 20 Apr 05	RESZ 406	REF 1	
ABSY|Ab(?)B13
DT|20 Apr 05
SYN|R(B)13
ID|FBab0025194
REF
{
REFM|FBrf0088157
|Goldsborough and Kornberg
|1996
|0
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0088157
|Goldsborough and Kornberg
|1996
PHP|Moderately suppresses transvection in @Ubx<up>1:Cbx-1</up>@/+ heterozygotes.
OTH|Induced on the Brasil wild type chromosome.
SYN|R(B)13
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025195	CLA 1 Aberration	GSYM 1 Ab(?)B3	DT 1 20 Apr 05	RESZ 401	REF 1	
ABSY|Ab(?)B3
DT|20 Apr 05
SYN|R(B)3
ID|FBab0025195
REF
{
REFM|FBrf0088157
|Goldsborough and Kornberg
|1996
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0088157
|Goldsborough and Kornberg
|1996
PHP|Strongly suppresses transvection in @Ubx<up>1:Cbx-1</up>@/+ heterozygotes.
OTH|Induced on the Brasil wild type chromosome.
SYN|R(B)3
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025196	CLA 1 Aberration	GSYM 1 Ab(?)B4	DT 1 20 Apr 05	RESZ 399	REF 1	
ABSY|Ab(?)B4
DT|20 Apr 05
SYN|R(B)4
ID|FBab0025196
REF
{
REFM|FBrf0088157
|Goldsborough and Kornberg
|1996
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0088157
|Goldsborough and Kornberg
|1996
PHP|Weakly suppresses transvection in @Ubx<up>1:Cbx-1</up>@/+ heterozygotes.
OTH|Induced on the Brasil wild type chromosome.
SYN|R(B)4
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025197	CLA 1 Aberration	GSYM 1 Ab(?)B8	DT 1 20 Apr 05	RESZ 399	REF 1	
ABSY|Ab(?)B8
DT|20 Apr 05
SYN|R(B)8
ID|FBab0025197
REF
{
REFM|FBrf0088157
|Goldsborough and Kornberg
|1996
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0088157
|Goldsborough and Kornberg
|1996
PHP|Weakly suppresses transvection in @Ubx<up>1:Cbx-1</up>@/+ heterozygotes.
OTH|Induced on the Brasil wild type chromosome.
SYN|R(B)8
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029530	CLA 1 Aberration	GSYM 1 Ab(?)DTD44.2	DT 1 20 Apr 05	RESZ 726	REF 1	
ABSY|Ab(?)DTD44.2
DT|20 Apr 05
SYN|DTDD44.2
ID|FBab0029530
REF
{
REFM|FBrf0132343
|Su et al.
|2001
|-1
}

CCM|Class relative to wildtype: Aberration
MU|irradiation
COR|Selected as: an exceptional DTD (dpp transvection disruptor) that results in heldout wings in combination with @dpp<up>d-ho</up>@/@dpp<up>hr4</up>@.
|Induced on: a @dpp<up>d-ho</up>@ chromosome.
REFDSR
{
RDID|FBrf0132343
|Su et al.
|2001
MU|irradiation
COR|Selected as: an exceptional DTD (dpp transvection disruptor) that results in heldout wings in combination with @dpp<up>d-ho</up>@/@dpp<up>hr4</up>@.
|Induced on: a @dpp<up>d-ho</up>@ chromosome.
CCM|Complex cytology.
PHP|Homozygous lethal.
SYN|DTDD44.2
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029531	CLA 1 Aberration	GSYM 1 Ab(?)DTD45.2	DT 1 20 Apr 05	RESZ 829	REF 1	
ABSY|Ab(?)DTD45.2
DT|20 Apr 05
SYN|DTD45.2
ID|FBab0029531
REF
{
REFM|FBrf0132343
|Su et al.
|2001
|-1
}

CCM|Class relative to wildtype: Aberration
MU|irradiation
COR|Selected as: an exceptional DTD (dpp transvection disruptor) that results in heldout wings in combination with @dpp<up>d-ho</up>@/@dpp<up>hr4</up>@.
|Induced on: a @dpp<up>d-ho</up>@ chromosome.
REFDSR
{
RDID|FBrf0132343
|Su et al.
|2001
MU|irradiation
COR|Selected as: an exceptional DTD (dpp transvection disruptor) that results in heldout wings in combination with @dpp<up>d-ho</up>@/@dpp<up>hr4</up>@.
|Induced on: a @dpp<up>d-ho</up>@ chromosome.
CCM|Complex cytology. No females carrying @Ab(?)DTD45.2@ are observed
|possibly due to an undetected translocation between chromosomes 2 and
|Y.
SYN|DTD45.2
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028197	CLA 1 Aberration	GSYM 1 Ab(?;3)TSR-2<up>Sz</up>	DT 1 20 Apr 05	RESZ 878	CLOC 1 [];87B	REF 1	
ABSY|Ab(?;3)TSR-2<up>Sz</up>
DT|20 Apr 05
SYN|TSR-2<up>Sz</up>
ID|FBab0028197
REF
{
REFM|FBrf0103039
|Sipos et al.
|1998
|-1
}

BPT|[];87B
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0103039)
MU|X ray
COR|Induced on: an @Abd-B<up>Fab7-1</up>@ chromosome.
|Selected as: a mutation on an @Abd-B<up>Fab7-1</up>@ chromosome that eliminates or reduces the suppression of the @Abd-B<up>Fab7-1</up>@ gain of function phenotype by @Abd-B<up>iab8-D16</up>@.
REFDSR
{
RDID|FBrf0103039
|Sipos et al.
|1998
BPT|het;87B
MU|X ray
COR|Induced on: an @Abd-B<up>Fab7-1</up>@ chromosome.
|Selected as: a mutation on an @Abd-B<up>Fab7-1</up>@ chromosome that eliminates or reduces the suppression of the @Abd-B<up>Fab7-1</up>@ gain of function phenotype by @Abd-B<up>iab8-D16</up>@.
SYN|TSR-2<up>Sz</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029777	CLA 1 Aberration	GSYM 1 Ab(?;f)A887	DT 1 20 Apr 05	RESZ 392	REF 1	
ABSY|Ab(?;f)A887
DT|20 Apr 05
SYN|A887
ID|FBab0029777
REF
{
REFM|FBrf0149015
|Yan et al.
|2002
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0149015
|Yan et al.
|2002
TRNA|FBti0023924 == P{SUPor-P}A887
OTH|@P{SUPor-P}A887@ is inserted in the centric region of @Ab(?;f)A887@,
|which appears to be a minichromosome.
SYN|A887
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029751	CLA 1 Aberration	GSYM 1 Ab(1)r20	DT 1 20 Apr 05	RESZ 269	REF 1	
ABSY|Ab(1)r20
DT|20 Apr 05
SYN|r20
ID|FBab0029751
REF
{
REFM|FBrf0144905
|Popkova et al.
|2001
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0144905
|Popkova et al.
|2001
SYN|r20
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028195	CLA 1 Aberration	GSYM 1 Ab(1)w<up>8x1</up>N<up>+</up>	DT 1 27 Nov 05	RESZ 827	REF 1	
ABSY|Ab(1)w<up>8x1</up>N<up>+</up>
DT|27 Nov 05
SYN|unnamed
ID|FBab0028195
REF
{
REFM|FBrf0042381
|Grimwade et al.
|1985
|-1
}

ASAL|FBal0091689 == N<up>66h26rv1</up>
|FBal0018079 == w<up>8x1</up>
CCM|Class relative to wildtype: Aberration
BIP|3C2;3C7 (from In(1)N<up>66h26</up>)
MU|spontaneous
PRG|N<up>66h26</up>
|w<up>8x</up>
|In(1)N<up>66h26</up>
AMD|w
REFDSR
{
RDID|FBrf0042381
|Grimwade et al.
|1985
MU|spontaneous
PRG|N<up>66h26</up>
|w<up>8x</up>
|In(1)N<up>66h26</up>
CCM|Cytologically normal in the 3C7 region, although some undefined abnormalities
|are seen in the 3C1-3C2 region. Reinversion of @In(1)N<up>66h26</up>@.
AMD|w
OTH|Unstable in crosses involving a @w<up>a</up>@ @N<up>fa-g</up>@ @rb<up>1</up>@ stock.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028196	CLA 1 Aberration	GSYM 1 Ab(1)w<up>8x2</up>N<up>+</up>	DT 1 27 Nov 05	RESZ 739	REF 1	
ABSY|Ab(1)w<up>8x2</up>N<up>+</up>
DT|27 Nov 05
SYN|unnamed
ID|FBab0028196
REF
{
REFM|FBrf0042381
|Grimwade et al.
|1985
|-1
}

ASAL|FBal0091688 == N<up>66h26rv2</up>
|FBal0018080 == w<up>8x2</up>
CCM|Class relative to wildtype: Aberration
BIP|3C2;3C7 (from In(1)N<up>66h26</up>)
MU|spontaneous
PRG|N<up>66h26</up>
|w<up>8x</up>
|In(1)N<up>66h26</up>
AMD|w
REFDSR
{
RDID|FBrf0042381
|Grimwade et al.
|1985
MU|spontaneous
PRG|N<up>66h26</up>
|w<up>8x</up>
|In(1)N<up>66h26</up>
CCM|Cytologically normal in the 3C7 region, although some undefined abnormalities
|are seen in the 3C1-3C2 region. Reinversion of @In(1)N<up>66h26</up>@.
AMD|w
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027942	CLA 1 Aberration	GSYM 1 Ab(1)ZWD16	DT 1 27 Nov 05	RESZ 479	REF 1	
ABSY|Ab(1)ZWD16
DT|27 Nov 05
ID|FBab0027942
REF
{
REFM|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
REFDSR
{
RDID|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
MU|&ggr; ray
CCM|Class I rearrangement: breakpoints are between @w@ and the constriction.
|Breakpoints were not analyzed by in situ hybridization.
PHP|Hemizygous males are wild type, homozygous males are sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027943	CLA 1 Aberration	GSYM 1 Ab(1)ZWD17	DT 1 27 Nov 05	RESZ 479	REF 1	
ABSY|Ab(1)ZWD17
DT|27 Nov 05
ID|FBab0027943
REF
{
REFM|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
REFDSR
{
RDID|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
MU|&ggr; ray
CCM|Class I rearrangement: breakpoints are between @w@ and the constriction.
|Breakpoints were not analyzed by in situ hybridization.
PHP|Hemizygous males are wild type, homozygous males are sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023382	CLA 1 Aberration	GSYM 1 Ab(1;?)if<up>B2.1</up>	DT 1 20 Apr 05	RESZ 353	REF 1	
ABSY|Ab(1;?)if<up>B2.1</up>
DT|20 Apr 05
ID|FBab0023382
REF
{
REFM|FBrf0072704
|Brown
|1994
|-1
}

ASAL|FBal0039416 == if<up>B2.1</up>
CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
AMD|if
REFDSR
{
RDID|FBrf0072704
|Brown
|1994
MU|&ggr; ray
AMD|if
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023371	CLA 1 Aberration	GSYM 1 Ab(1;?)w<up>m4000</up>	DT 1 20 Apr 05	RESZ 462	REF 1	
ABSY|Ab(1;?)w<up>m4000</up>
DT|20 Apr 05
SYN|w<up>m4000</up>
ID2|FBal0018282
ID|FBab0023371
REF
{
REFM|FBrf0006058
|Buzzati-Traverso
|1943
|-1
}

DIS|Buzzati-Traverso, 7th Dec. 1941.
MU|X ray
CCM|Class relative to wildtype: Aberration
|rearrangement with break in w
PED|position-effect variegation for: w
PHP|eyes cream colored, darker in males
|male viable
|male fertile
|female viable
|female fertile
}
# EOR
ABSR
{
RETE|ID 1 FBab0028377	CLA 1 Aberration	GSYM 1 Ab(1;2)vs<up>P4</up>	DT 1 20 Apr 05	RESZ 446	REF 1	
ABSY|Ab(1;2)vs<up>P4</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0028377
REF
{
REFM|FBrf0063296
|Bateman
|1951
|-1
}

ASAL|FBal0092451 == vs<up>P4</up>
CCM|Class relative to wildtype: Aberration
MU|<up>32</up>P
AMD|vs
REFDSR
{
RDID|FBrf0063296
|Bateman
|1951
MU|<up>32</up>P
CCM|Segmental interchange involving the left end of the X chromosome and
|most of 2L.
AMD|vs
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024294	CLA 1 Aberration	GSYM 1 Ab(1;f)&ggr;845	DT 1 20 Apr 05	RESZ 564	REF 1	
ABSY|Ab(1;f)&ggr;845
DT|20 Apr 05
SYN|&ggr;845
ID|FBab0024294
REF
{
REFM|FBrf0084112
|Le et al.
|1995
|-1
}

ASAL|FBal0046835 == y<up>&ggr;845</up>
CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
PRG|Dp1187-8-23
AMD|y
REFDSR
{
RDID|FBrf0084112
|Le et al.
|1995
MU|&ggr; ray
PRG|Dp1187-8-23
CCM|Complex rearrangement on the @Dp(1;f)1187@ derivative @Dp1187-8-23@.
|Maybe a translocation + inversion, translocation + insertion or insertion
|+ inversion.
AMD|y
SYN|&ggr;845
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027545	CLA 1 Aberration	GSYM 1 Ab(2)12-4	DT 1 20 Apr 05	RESZ 497	CLOC 1 49C	REF 1	
ABSY|Ab(2)12-4
DT|20 Apr 05
SYN|unnamed
ID|FBab0027545
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
}

BPT|49C
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0099191)
MU|X ray
PRG|FBti0016764 == P{lacW}50C.x3
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
BPT|49C;het
MU|X ray
PRG|FBti0016764 == P{lacW}50C.x3
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x3@.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027546	CLA 1 Aberration	GSYM 1 Ab(2)12-7	DT 1 20 Apr 05	RESZ 497	CLOC 1 46B	REF 1	
ABSY|Ab(2)12-7
DT|20 Apr 05
SYN|unnamed
ID|FBab0027546
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
}

BPT|46B
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0099191)
MU|X ray
PRG|FBti0016764 == P{lacW}50C.x3
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
BPT|46B;het
MU|X ray
PRG|FBti0016764 == P{lacW}50C.x3
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x3@.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0038742	CLA 1 Aberration	GSYM 1 Ab(2)2.3-65S12	DT 1 20 Apr 05	RESZ 677	REF 1	
ABSY|Ab(2)2.3-65S12
DT|20 Apr 05
SYN|2.3<up>65S12</up>
ID|FBab0038742
REF
{
REFM|FBrf0180291
|Brumby et al.
|2004
|-1
}

MU|X ray \?
|ethyl methanesulfonate \?
AMD|l(2)36Fd
|l(2)37Ac
|ham
AM|@Ab(2)2.3-65S12@ gives about 5% escapers in combination with @l(2)37Ac@
|mutants.
REFDSR
{
RDID|FBrf0180291
|Brumby et al.
|2004
MU|X ray \?
|ethyl methanesulfonate \?
AMD|l(2)36Fd
|l(2)37Ac
|ham
AM|@Ab(2)2.3-65S12@ gives about 5% escapers in combination with @l(2)37Ac@
|mutants.
SYN|2.3<up>65S12</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027946	CLA 1 Aberration	GSYM 1 Ab(2)bw-R68	DT 1 20 Apr 05	RESZ 368	REF 1	
ABSY|Ab(2)bw-R68
DT|20 Apr 05
SYN|R<up>68</up>(+)
ID|FBab0027946
REF
{
REFM|FBrf0010226
|Slatis
|1955
|-1
}

CCM|Class relative to wildtype: Aberration
MU|X ray
REFDSR
{
RDID|FBrf0010226
|Slatis
|1955
MU|X ray
CCM|Complex rearrangement
PHP|Chromosome exhibits position effect variegation for @bw@: white eyes.
SYN|R<up>68</up>(+)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027944	CLA 1 Aberration	GSYM 1 Ab(2)DTD117	DT 1 20 Apr 05	RESZ 439	REF 1	
ABSY|Ab(2)DTD117
DT|20 Apr 05
SYN|Decapentaplegic Transvection Disrupter rearrangement 117
ID|FBab0027944
REF
{
REFM|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
REFDSR
{
RDID|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
MU|&ggr; ray
CCM|Normal.
PHP|@z@ disrupted phenotype.
SYN|Decapentaplegic Transvection Disrupter rearrangement 117
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027945	CLA 1 Aberration	GSYM 1 Ab(2)DTD119	DT 1 20 Apr 05	RESZ 439	REF 1	
ABSY|Ab(2)DTD119
DT|20 Apr 05
SYN|Decapentaplegic Transvection Disrupter rearrangement 119
ID|FBab0027945
REF
{
REFM|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
REFDSR
{
RDID|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
MU|&ggr; ray
CCM|Normal.
PHP|@z@ disrupted phenotype.
SYN|Decapentaplegic Transvection Disrupter rearrangement 119
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029776	CLA 1 Aberration	GSYM 1 Ab(2)l(2)44Fp<up>9</up>	DT 1 20 Apr 05	RESZ 689	REF 1	
ABSY|Ab(2)l(2)44Fp<up>9</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0029776
REF
{
REFM|FBrf0147061
|Mohr and Boswell
|2002
|-1
}

ASAL|FBal0137186 == l(2)44Fp<up>9</up>
CCM|Class relative to wildtype: Aberration
MU|ethyl methanesulfonate
AMD|l(2)44Fp
|l(2)44Fa
|l(2)44Fg
|l(2)44Fh
|l(2)44Fj
REFDSR
{
RDID|FBrf0147061
|Mohr and Boswell
|2002
MU|ethyl methanesulfonate
AMD|l(2)44Fp
|l(2)44Fa
|l(2)44Fg
|l(2)44Fh
|l(2)44Fj
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037631	CLA 1 Aberration	GSYM 1 Ab(2)Pvr<up>KO8</up>	DT 1 20 Apr 05	RESZ 699	REF 1	
ABSY|Ab(2)Pvr<up>KO8</up>
DT|20 Apr 05
SYN|Pvr<up>KO8</up>
ID|FBab0037631
REF
{
REFM|FBrf0160936
|Sears et al.
|2003
|-1
}

CCM|Class relative to wildtype: Aberration
MU|recombination
|SCEI endonuclease
|FLPase
PRG|Pvr<up>4.5.Scer\SceI.RS</up>
REFDSR
{
RDID|FBrf0160936
|Sears et al.
|2003
MU|recombination
|SCEI endonuclease
|FLPase
PRG|Pvr<up>4.5.Scer\SceI.RS</up>
OTH|Targeted homologous recombination event at the @Pvr@ locus, using @P{FRT(w<up>+</up>.Pvr<up>4.5.Scer\SceI.RS</up>)}@
|as the donor template. The chromosome appears to have undergone a
|complex combination of DNA insertion and duplication.
SYN|Pvr<up>KO8</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028056	CLA 1 Deficiency (cytologically invisible)	GSYM 1 Ab(2)Sco<up>rv15</up>	DT 1 20 Apr 05	RESZ 795	CLOC 1 [35B2];[35D1]	REF 1	
ABSY|Ab(2)Sco<up>rv15</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0028056
REF
{
REFM|FBrf0063478
|Grau et al.
|1984
|-1
}

ASAL|FBal0013053 == noc<up>Sco-rv15</up>
|FBal0088619 == sna<up>Sco-rv15</up>
BPT|[35B2];[35D1]
CCM|Class relative to wildtype: Deficiency
|Limits of break 1 from complementation mapping against noc (FBrf0063478)
|Limits of break 2 from complementation mapping against sna (FBrf0063478)
FGD|bk1 hits noc << bk2 hits sna
BIP|35B1;35B3;35C1;35D1--2 (from Tp(2;2)Sco)
ACLA|Deficiency (cytologically invisible)
MU|ethyl methanesulfonate
PRG|Tp(2;2)Sco
AMD|sna
REFDSR
{
RDID|FBrf0063478
|Grau et al.
|1984
ACLA|Deficiency (cytologically invisible)
MU|ethyl methanesulfonate
PRG|Tp(2;2)Sco
AMD|sna
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024094	CLA 1 Aberration	GSYM 1 Ab(2)SM6#16	DT 1 27 Nov 05	RESZ 603	ALESR 1	SK 2	REF 1	
ABSY|Ab(2)SM6#16
DT|27 Nov 05
SYN|In(2LR)SM6#16
ID|FBab0024094
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

DIS|L. Craymer.
MU|X ray
PRG|In(2LR)SM6
CCM|Class relative to wildtype: Aberration
|Presumptive additional aberration(s) on @SM6a@ associated with @SM6#16@.
BGV
{
BGVSY|SM6#16
ID|FBba0000102
MK|al<up>2</up> Cy<up>1</up> dp<up>lvI</up> cn<up>2P</up> sp<up>2</up>
IBAL
PRG|SM6a
BSN|SM6#16
PHP|X-ray derivative of @SM6a@, presumably has additional aberrations.
REF|FBrf0141259
SK|FBst0001287
|en[Apa]/SM6#16
|FBst0001219
|wg[Sp-1] Bl[1] L[rm] Bc[1] Pu[2]/SM6#16
}

SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0038743	CLA 1 Aberration	GSYM 1 Ab(2;?)2.5-58S12	DT 1 20 Apr 05	RESZ 465	REF 1	
ABSY|Ab(2;?)2.5-58S12
DT|20 Apr 05
SYN|2.5<up>58S12</up>
ID|FBab0038743
REF
{
REFM|FBrf0180291
|Brumby et al.
|2004
|-1
}

MU|X ray \?
|ethyl methanesulfonate \?
AMD|Eb1
OAB|Lethal in combination with @Df(2R)nap1@.
REFDSR
{
RDID|FBrf0180291
|Brumby et al.
|2004
MU|X ray \?
|ethyl methanesulfonate \?
AMD|Eb1
OAB|Lethal in combination with @Df(2R)nap1@.
SYN|2.5<up>58S12</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024296	CLA 1 Aberration	GSYM 1 Ab(2;?)al<up>ice</up>	DT 1 27 Nov 05	RESZ 606	REF 3	
ABSY|Ab(2;?)al<up>ice</up>
DT|27 Nov 05
ID|FBab0024296
REF
{
REFM|FBrf0183860
|Kojima et al.
|2005
|-1
REFM|FBrf0064389
|Campbell et al.
|1993
|-1
REFM|FBrf0183856
|Campbell
|2005
|-1
}

ASAL|FBal0030482 == al<up>ice</up>
CCM|Class relative to wildtype: Aberration
MU|ethyl methanesulfonate
REFDSR
{
RDID|FBrf0064389
|Campbell et al.
|1993
MU|ethyl methanesulfonate
CCM|uncharacterized
}

REFDSR
{
RDID|FBrf0183856
|Campbell
|2005
}

REFDSR
{
RDID|FBrf0183860
|Kojima et al.
|2005
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024297	CLA 1 Aberration	GSYM 1 Ab(2;?)al<up>vin</up>	DT 1 20 Apr 05	RESZ 372	REF 1	
ABSY|Ab(2;?)al<up>vin</up>
DT|20 Apr 05
ID|FBab0024297
REF
{
REFM|FBrf0064389
|Campbell et al.
|1993
|-1
}

ASAL|FBal0030483 == al<up>vin</up>
CCM|Class relative to wildtype: Aberration
MU|ethyl methanesulfonate
REFDSR
{
RDID|FBrf0064389
|Campbell et al.
|1993
MU|ethyl methanesulfonate
CCM|uncharacterized; probably an inversion.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028891	CLA 1 Aberration	GSYM 1 Ab(2;?)dare<up>34</up>	DT 1 20 Apr 05	RESZ 543	REF 1	
ABSY|Ab(2;?)dare<up>34</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0028891
REF
{
REFM|FBrf0111361
|Freeman et al.
|1999
|-1
}

ASAL|FBal0101458 == dare<up>34</up>
CCM|Class relative to wildtype: Aberration
MU|&Dgr;2-3
PRG|dare<up>1</up>
|FBti0009263 == FBti0003650 == P{lacW}dare<up>1</up>
AMD|dare
REFDSR
{
RDID|FBrf0111361
|Freeman et al.
|1999
MU|&Dgr;2-3
PRG|dare<up>1</up>
|FBti0009263 == FBti0003650 == P{lacW}dare<up>1</up>
AMD|dare
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029529	CLA 1 Aberration	GSYM 1 Ab(2;?)wun<up>CE</up>	DT 1 20 Apr 05	RESZ 461	REF 1	
ABSY|Ab(2;?)wun<up>CE</up>
DT|20 Apr 05
SYN|wunen<up>CE</up>
ID|FBab0029529
REF
{
REFM|FBrf0134584
|Starz-Gaiano et al.
|2001
|-1
}

ASAL|FBal0050885 == wun<up>CE</up>
CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0134584
|Starz-Gaiano et al.
|2001
CCM|The @Ab(2;?)wun<up>CE</up>@ lesion has not been characterized.
OTH|@Ab(2;?)wun<up>CE</up>@ affects both @wun@ and @wun2@.
SYN|wunen<up>CE</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023960	CLA 1 Aberration	GSYM 1 Ab(2;3)boss<up>8</up>	DT 1 20 Apr 05	RESZ 403	REF 1	
ABSY|Ab(2;3)boss<up>8</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0023960
REF
{
REFM|FBrf0051837
|Hart et al.
|1990
|-1
}

ASAL|FBal0019775 == boss<up>8</up>
CCM|Class relative to wildtype: Aberration
MU|X ray
AMD|boss
REFDSR
{
RDID|FBrf0051837
|Hart et al.
|1990
MU|X ray
CCM|Complex rearrangement.
AMD|boss
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023383	CLA 1 Aberration	NAM 1 eya transvection disruptor	GSYM 1 Ab(2;3)ETD4.4	DT 1 20 Apr 05	RESZ 578	CLOC 1 26D;40;58;81	REF 1	
ABSY|Ab(2;3)ETD4.4
DT|20 Apr 05
NAM|eya transvection disruptor
ID|FBab0023383
REF
{
REFM|FBrf0078888
|Leiserson et al.
|1994
|-1
}

BPT|26D;40;58;81
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0078888)
MU|X ray
PRG|eya<up>4</up>
REFDSR
{
RDID|FBrf0078888
|Leiserson et al.
|1994
BPT|26D;40;58;81
MU|X ray
PRG|eya<up>4</up>
PHP|Disrupts pairing in the eya region, causing suppression of @eya<up>2</up>@/@eya<up>4</up>@
|transvection and a reduction in size of adult eye to less than 3/4.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027547	CLA 1 Aberration	GSYM 1 Ab(2;3)T-1	DT 1 27 Nov 05	RESZ 1429	REF 2	
ABSY|Ab(2;3)T-1
DT|27 Nov 05
SYN|unnamed
|T-1
ID|FBab0027547
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
REFM|FBrf0141552
|Ronsseray et al.
|2001
|-1
}

CCM|Class relative to wildtype: Aberration
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x7@.
|Enhancement is specific for the transgene array at 50C, it does not
|result from mutations in modifiers of PEV (chromosomes with and without
|the transgene array fail to enhance variegation of @w@ in either @In(1)w<up>m4</up>@
|or @P{lacW}92E.x3@).
SYN|unnamed
}

REFDSR
{
RDID|FBrf0141552
|Ronsseray et al.
|2001
OTH|@Ab(2;3)T-1@ significantly represses the occurrence of P-induced dysgenic
|sterility compared to controls in crosses of @Ab(2;3)T-1@ females to
|P males. A stronger repression of P-induced dysgenic sterility is
|seen if the @Ab(2;3)T-1@ females are also carrying @P{lArB}A171.1F1@.
|The array of @P{lacW}@ element on @Ab(2;3)T-1@ can repress germline
|expression of other @P{lacZ}@ insertions, either located on the same
|chromosome at a different site, or on a different chromosome. Repression
|is detected only when the @Ab(2;3)T-1@ chromosome is maternally inherited.
SYN|T-1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029627	CLA 1 Aberration	GSYM 1 Ab(2;3)Tell	DT 1 27 Nov 05	RESZ 1987	ALESR 2	REF 1	
ABSY|Ab(2;3)Tell
DT|27 Nov 05
SYN|Tell
ID|FBab0029627
REF
{
REFM|FBrf0137374
|Seum et al.
|2000
|-1
}

CCM|Class relative to wildtype: Aberration
MU|X ray
COR|Induced on: @P{Winkelried}D@.
REFDSR
{
RDID|FBrf0137374
|Seum et al.
|2000
MU|X ray
COR|Induced on: @P{Winkelried}D@.
PHP|lethal | recessive
OTH|The @Ab(2;3)Tell@ rearrangement was induced on a chromosome carrying
|@P{Winkelried}D@ and juxtaposes the @P{Winkelried}D@ insertion and
|pericentromeric heterochromatin.
|FlyBase curator comment: the @Ab(2;3)Tell-P{Winkelried}D@ genotype
|variant represents the genotype that carries both the @Ab(2;3)Tell@
|rearrangement and the @P{Winkelried}D@ insertion. The
|@Ab(2;3)Tell-P{Winkelried}D@ variant shows position effect
|variegation for the @w@ gene present in the @P{Winkelried}D@
|insertion.
SYN|Tell
}

BGV
{
BGVSY|Ab(2;3)Tell-P{Winkelried(-FRT)}
ID|FBba0000503
REF|FBrf0137374
REFDSR
{
RDID|FBrf0137374
|Seum et al.
|2000
TRNA|FBti0018245 == P{Winkelried(-FRT)}D
PRG|Ab(2;3)Tell-P{Winkelried}D
DIS|C. Seum
}

}

BGV
{
BGVSY|Ab(2;3)Tell-P{Winkelried}D
ID|FBba0000504
REF|FBrf0137374
REFDSR
{
RDID|FBrf0137374
|Seum et al.
|2000
MK|Ecol\lacZ<up>Hsp70Bb.-190</up> scs'<up>unspecified</up> scs<up>unspecified</up> w<up>E2F.Scer\UAS</up>
TRNA|FBti0017779 == P{Winkelried}D
OTH|The @Ab(2;3)Tell@ rearrangement was induced on a chromosome carrying
|@P{Winkelried}D@ and juxtaposes the @P{Winkelried}D@ insertion and
|pericentromeric heterochromatin.
|FlyBase curator comment: the @Ab(2;3)Tell-P{Winkelried}D@ genotype
|variant represents the genotype that carries both the @Ab(2;3)Tell@
|rearrangement and the @P{Winkelried}D@ insertion. The
|@Ab(2;3)Tell-P{Winkelried}D@ variant shows position effect
|variegation for the @w@ gene present in the @P{Winkelried}D@
|insertion.
DIS|C. Seum
}

}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024295	CLA 1 Aberration	GSYM 1 Ab(2;3;?)ul10#1	DT 1 20 Apr 05	RESZ 1066	CLOC 1 80;89D;81;22A;40	REF 1	
ABSY|Ab(2;3;?)ul10#1
DT|20 Apr 05
SYN|R(Df(3R)ul10)#1
ID|FBab0024295
REF
{
REFM|FBrf0080101
|Hopmann et al.
|1995
|-1
}

BPT|80;89D;81;22A;40
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0080101)
BIP|89E3;90A2--3 (from Df(3R)ul10)
NCO|Junctions: 1L:2L
|Junctions: 2R:4R
MU|X ray
PRG|Df(3R)ul10
REFDSR
{
RDID|FBrf0080101
|Hopmann et al.
|1995
BPT|80;89D;81;22A;40;het
NCO|Junctions: 1L:2L
|Junctions: 2R:4R
MU|X ray
PRG|Df(3R)ul10
CCM|Cytology described as 61-80/89D-81 + 100-89D/22A-40 + 21-22A/undetermined
|heterochromatin.
PHP|Does not completely block transvection, shows some reduction of alula
|when heterozygous with Cbx alleles of @Ubx@. Causes moderate reduction
|of pigmentation in posterior segments when heterozygous with @Df(3R)Ubx-RS4-8@.
|Causes strong disruption of pairing at BX-C in salivary chromosomes
|when heterozygous with wild type.
OTH|Selected on basis of ability to suppress transvection in @Ubx@<up>Cbx</up>
|heterozygotes.
SYN|R(Df(3R)ul10)#1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023384	CLA 1 Aberration	GSYM 1 Ab(2L;?)34Cy<up>rv</up>	DT 1 20 Apr 05	RESZ 460	CLOC 1 23B1--2	REF 1	
ABSY|Ab(2L;?)34Cy<up>rv</up>
DT|20 Apr 05
SYN|unnamed
ID|FBab0023384
REF
{
REFM|FBrf0076536
|Littleton and Bellen
|1994
|-1
}

BPT|23B1--2
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0076536)
MU|&ggr; ray
REFDSR
{
RDID|FBrf0076536
|Littleton and Bellen
|1994
BPT|23B1--2
MU|&ggr; ray
CCM|Complex rearrangement.
PHP|Reversion of the dominant curly wing phenotype.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023372	CLA 1 Aberration	GSYM 1 Ab(2L;?)eya<up>X11</up>	DT 1 20 Apr 05	RESZ 378	REF 1	
ABSY|Ab(2L;?)eya<up>X11</up>
DT|20 Apr 05
SYN|Ab(2L;?)cli<up>eya-X11</up>
ID|FBab0023372
REF
{
REFM|FBrf0057885
|Bonini et al.
|1993
|-1
}

ASAL|FBal0030783 == eya<up>X11</up>
CCM|Class relative to wildtype: Aberration
MU|X ray
REFDSR
{
RDID|FBrf0057885
|Bonini et al.
|1993
MU|X ray
OTH|Has complex cytology: not all breakpoints determined.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023373	CLA 1 Aberration	GSYM 1 Ab(2L;?)eya<up>X9</up>	DT 1 20 Apr 05	RESZ 375	REF 1	
ABSY|Ab(2L;?)eya<up>X9</up>
DT|20 Apr 05
SYN|Ab(2L;?)cli<up>eya-X9</up>
ID|FBab0023373
REF
{
REFM|FBrf0057885
|Bonini et al.
|1993
|-1
}

ASAL|FBal0030789 == eya<up>X9</up>
CCM|Class relative to wildtype: Aberration
MU|X ray
REFDSR
{
RDID|FBrf0057885
|Bonini et al.
|1993
MU|X ray
OTH|Has complex cytology: not all breakpoints determined.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023385	CLA 1 Aberration	GSYM 1 Ab(2L;?)her<up>3</up>	DT 1 20 Apr 05	RESZ 359	CLOC 1 36A	REF 1	
ABSY|Ab(2L;?)her<up>3</up>
DT|20 Apr 05
ID|FBab0023385
REF
{
REFM|FBrf0068639
|Pultz et al.
|1994
|-1
}

ASAL|FBal0039401 == her<up>3</up>
BPT|36A
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0068639)
MU|X ray
REFDSR
{
RDID|FBrf0068639
|Pultz et al.
|1994
BPT|36A
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027548	CLA 1 Aberration	GSYM 1 Ab(2LR)C-2	DT 1 27 Nov 05	RESZ 1866	CLOC 1 h35--h46;42A;51F	ALESR 1	REF 3	
ABSY|Ab(2LR)C-2
DT|27 Nov 05
SYN|unnamed
|C-2
ID|FBab0027548
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
REFM|FBrf0141552
|Ronsseray et al.
|2001
|-1
REFM|FBrf0105816
|Fanti et al.
|1998
|-1
}

BPT|h35--h46;42A;51F
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0099191)
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
BPT|h35--h46;42A;51F
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
PHP|Homozygous viable.
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x7@.
|Enhancement is specific for the transgene array at 50C, it does not
|result from mutations in modifiers of PEV (chromosomes with and without
|the transgene array fail to enhance variegation of @w@ in either @In(1)w<up>m4</up>@
|or @P{lacW}92E.x3@).
SYN|unnamed
}

REFDSR
{
RDID|FBrf0141552
|Ronsseray et al.
|2001
OTH|Does not show significant repression of P-induced dysgenic sterility
|when @Ab(2LR)C-2@ females are crossed to P males. Does show significant
|repression of P-induced dysgenic sterility when females carrying both
|@P{lArB}A171.1F1@ and @Ab(2LR)C-2@ are crossed to P males.
SYN|C-2
}

BGV
{
BGVSY|Ab(2LR)C-2-w
SYN|unnamed
ID|FBba0000230
REF|FBrf0099191
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
SYN|unnamed
PHP|@P{lacW}50C.x7@ array is lost by recombination or transposase activity.
|Enhancement of @P{lacW}50C.x7@ variegation also occurs when in trans
|to the rearrangement, this suggests transvection is not the cause of
|the enhancement. Increased proximity of the array to heterochromatin
|in either cis or trans can increase the strength of transgene silencing.
}

}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037786	CLA 1 Aberration	GSYM 1 Ab(2R)55-20	DT 1 22 Aug 04	RESZ 2599	REF 1	
ABSY|Ab(2R)55-20
DT|22 Aug 04
SYN|55-20
ID|FBab0037786
REF
{
REFM|FBrf0145131
|Goldstein et al.
|2001
|-1
}

MU|diepoxybutane
AMD|TER94
|l(2)46Ci
|l(2)46CFn
AMDD|Mef2
|l(2)46CDa
|eve
|Adam
|l(2)46Dj
|l(2)46Dh
|l(2)46Di
|l(2)46Ck
|l(2)46Cn
|Jra
|14-3-3&zgr;
|l(2)46Eb
|l(2)46Ed
|l(2)46Fb
|l(2)46Cm
|l(2)46Ei
|l(2)46Cl
|l(2)46Ej
|l(2)46Cj
|l(2)46Ea
|l(2)46Fa
|l(2)46Eg
|l(2)46Eh
|l(2)46Ec
|Hr46
|Syb
REFDSR
{
RDID|FBrf0145131
|Goldstein et al.
|2001
MU|diepoxybutane
AMD|TER94
|l(2)46Ci
|l(2)46CFn
AMDD|Mef2
|l(2)46CDa
|eve
|Adam
|l(2)46Dj
|l(2)46Dh
|l(2)46Di
|l(2)46Ck
|l(2)46Cn
|Jra
|14-3-3&zgr;
|l(2)46Eb
|l(2)46Ed
|l(2)46Fb
|l(2)46Cm
|l(2)46Ei
|l(2)46Cl
|l(2)46Ej
|l(2)46Cj
|l(2)46Ea
|l(2)46Fa
|l(2)46Eg
|l(2)46Eh
|l(2)46Ec
|Hr46
|Syb
OTH|The "55-20" line has a very complex pattern of failing to complement
|other mutations, and can be postulated to carry multiple small deletions.
SYN|55-20
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037787	CLA 1 Aberration	GSYM 1 Ab(2R)89-22	DT 1 22 Aug 04	RESZ 2563	REF 1	
ABSY|Ab(2R)89-22
DT|22 Aug 04
SYN|89-22
ID|FBab0037787
REF
{
REFM|FBrf0145131
|Goldstein et al.
|2001
|-1
}

MU|&ggr; ray
AMD|Mef2
|l(2)46CDa
|eve
|Adam
|TER94
AMDD|l(2)46Ci
|l(2)46CFn
|l(2)46Dj
|l(2)46Dh
|l(2)46Di
|l(2)46Ck
|l(2)46Cn
|Jra
|14-3-3&zgr;
|l(2)46Eb
|l(2)46Ed
|l(2)46Fb
|l(2)46Cm
|l(2)46Ei
|l(2)46Cl
|l(2)46Ej
|l(2)46Cj
|l(2)46Ea
|l(2)46Fa
|l(2)46Eg
|l(2)46Eh
|l(2)46Ec
|Hr46
|Syb
REFDSR
{
RDID|FBrf0145131
|Goldstein et al.
|2001
MU|&ggr; ray
AMD|Mef2
|l(2)46CDa
|eve
|Adam
|TER94
AMDD|l(2)46Ci
|l(2)46CFn
|l(2)46Dj
|l(2)46Dh
|l(2)46Di
|l(2)46Ck
|l(2)46Cn
|Jra
|14-3-3&zgr;
|l(2)46Eb
|l(2)46Ed
|l(2)46Fb
|l(2)46Cm
|l(2)46Ei
|l(2)46Cl
|l(2)46Ej
|l(2)46Cj
|l(2)46Ea
|l(2)46Fa
|l(2)46Eg
|l(2)46Eh
|l(2)46Ec
|Hr46
|Syb
OTH|The "89-22" line has a very complex pattern of failing to complement
|other mutations, and can be postulated to carry multiple small deletions.
SYN|89-22
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028057	CLA 1 Aberration	GSYM 1 Ab(2R)ClassII	DT 1 20 Apr 05	RESZ 783	REF 1	
ABSY|Ab(2R)ClassII
DT|20 Apr 05
ID|FBab0028057
REF
{
REFM|FBrf0102481
|Salinas et al.
|1998
|-1
}

ASAL|FBal0089833 == Asx<up>II</up>
|FBal0089370 == cpsf<up>II</up>
CCM|Class relative to wildtype: Aberration
MU|&Dgr;2-3
PRG|Asx<up>P1</up>
AMD|Asx
|cpsf
REFDSR
{
RDID|FBrf0102481
|Salinas et al.
|1998
MU|&Dgr;2-3
PRG|Asx<up>P1</up>
CCM|Complex rearrangement.
AMD|Asx
|cpsf
PHP|Most embryos show head defects and may exhibit weak posterior transformations
|of the sixth and seventh abdominal segment towards the eighth. Most
|embryos also show reduction of the H-piece and deposits of yellow,
|chitinous material in the cuticle.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028058	CLA 1 Aberration	GSYM 1 Ab(2R)ClassV	DT 1 20 Apr 05	RESZ 471	REF 1	
ABSY|Ab(2R)ClassV
DT|20 Apr 05
ID|FBab0028058
REF
{
REFM|FBrf0102481
|Salinas et al.
|1998
|-1
}

ASAL|FBal0089367 == cpsf<up>V</up>
CCM|Class relative to wildtype: Aberration
MU|&Dgr;2-3
PRG|Asx<up>P1</up>
AMD|cpsf
REFDSR
{
RDID|FBrf0102481
|Salinas et al.
|1998
MU|&Dgr;2-3
PRG|Asx<up>P1</up>
CCM|Breakpoints and nature of the rearrangement are not mapped.
AMD|cpsf
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024809	CLA 1 Aberration	GSYM 1 Ab(2R)dpn<up>8</up>	DT 1 20 Apr 05	RESZ 474	CLOC 1 44C	REF 1	
ABSY|Ab(2R)dpn<up>8</up>
DT|20 Apr 05
ID|FBab0024809
REF
{
REFM|FBrf0084726
|Barbash and Cline
|1995
|-1
}

ASAL|FBal0049434 == dpn<up>8</up>
BPT|44C
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0084726)
MU|spontaneous
AMD|dpn
REFDSR
{
RDID|FBrf0084726
|Barbash and Cline
|1995
BPT|44C
MU|spontaneous
CCM|Small alteration in proximal 44C.
AMD|dpn
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027354	CLA 1 Deficiency (cytologically invisible)	GSYM 1 Ab(2R)IR36	DT 1 20 Apr 05	RESZ 874	CLOC 1 [<h35];[>h35]	REF 1	
ABSY|Ab(2R)IR36
DT|20 Apr 05
SYN|l(2Rh)IR36
ID|FBab0027354
REF
{
REFM|FBrf0094580
|Dimitri et al.
|1997
|-1
}

BPT|[<h35];[>h35]
CCM|Class relative to wildtype: Deficiency
|Right limit of break 1 from complementation mapping against l(2)40Ff (FBrf0094580)
|Left limit of break 2 from complementation mapping against l(2)40Fe (FBrf0094580)
ACLA|Deficiency (cytologically invisible)
MU|IR-hybrid dysgenesis
AMD|l(2)40Fe
|l(2)40Ff
|l(2)40Fg
|lt
REFDSR
{
RDID|FBrf0094580
|Dimitri et al.
|1997
BPT|[];[]
ACLA|Deficiency (cytologically invisible)
MU|IR-hybrid dysgenesis
AMD|l(2)40Fe
|l(2)40Ff
|l(2)40Fg
|lt
SYN|l(2Rh)IR36
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027355	CLA 1 Deficiency (cytologically invisible)	GSYM 1 Ab(2R)IR45	DT 1 20 Apr 05	RESZ 529	CLOC 1 [];[]	REF 1	
ABSY|Ab(2R)IR45
DT|20 Apr 05
SYN|l(2Rh)IR45
ID|FBab0027355
REF
{
REFM|FBrf0094580
|Dimitri et al.
|1997
|-1
}

CCM|Class relative to wildtype: Deficiency
BPT|[];[]
ACLA|Deficiency (cytologically invisible)
MU|IR-hybrid dysgenesis
AMDD|l(2)40Fc
REFDSR
{
RDID|FBrf0094580
|Dimitri et al.
|1997
BPT|[];[]
ACLA|Deficiency (cytologically invisible)
MU|IR-hybrid dysgenesis
AMDD|l(2)40Fc
SYN|l(2Rh)IR45
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0038744	CLA 1 Aberration	GSYM 1 Ab(3)20S1	DT 1 20 Apr 05	RESZ 440	CLOC 1 63E	REF 1	
ABSY|Ab(3)20S1
DT|20 Apr 05
SYN|20S1
ID|FBab0038744
REF
{
REFM|FBrf0180291
|Brumby et al.
|2004
|-1
}

ASAL|FBal0175986 == S(CycE<up>JP</up>)20S1<up>20S1</up>
BPT|63E
MU|X ray \?
|ethyl methanesulfonate \?
|X ray \?
|ethyl methanesulfonate \?
REFDSR
{
RDID|FBrf0180291
|Brumby et al.
|2004
BPT|63E
MU|X ray \?
|ethyl methanesulfonate \?
|X ray \?
|ethyl methanesulfonate \?
SYN|20S1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0038745	CLA 1 Aberration	GSYM 1 Ab(3)42S12	DT 1 20 Apr 05	RESZ 451	CLOC 1 62E--F	REF 1	
ABSY|Ab(3)42S12
DT|20 Apr 05
SYN|42S12
ID|FBab0038745
REF
{
REFM|FBrf0180291
|Brumby et al.
|2004
|-1
}

ASAL|FBal0175974 == S(CycE<up>JP</up>)42S12<up>42S12</up>
BPT|62E--F
MU|X ray \?
|ethyl methanesulfonate \?
|X ray \?
|ethyl methanesulfonate \?
REFDSR
{
RDID|FBrf0180291
|Brumby et al.
|2004
BPT|62E--F
MU|X ray \?
|ethyl methanesulfonate \?
|X ray \?
|ethyl methanesulfonate \?
SYN|42S12
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0038746	CLA 1 Aberration	GSYM 1 Ab(3)59S9	DT 1 20 Apr 05	RESZ 342	CLOC 1 62B	REF 1	
ABSY|Ab(3)59S9
DT|20 Apr 05
ID|FBab0038746
REF
{
REFM|FBrf0180291
|Brumby et al.
|2004
|-1
}

ASAL|FBal0175969 == S(CycE<up>JP</up>)59S9<up>59S9</up>
BPT|62B
MU|X ray \?
|ethyl methanesulfonate \?
REFDSR
{
RDID|FBrf0180291
|Brumby et al.
|2004
BPT|62B
MU|X ray \?
|ethyl methanesulfonate \?
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027947	CLA 1 Aberration	GSYM 1 Ab(3)BTD4	DT 1 20 Apr 05	RESZ 419	REF 1	
ABSY|Ab(3)BTD4
DT|20 Apr 05
SYN|Bithorax Transvection Disrupter rearrangement 4
ID|FBab0027947
REF
{
REFM|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
REFDSR
{
RDID|FBrf0046365
|Smolik-Utlaut and Gelbart
|1987
MU|&ggr; ray
CCM|Normal.
PHP|@z@ disrupted phenotype.
SYN|Bithorax Transvection Disrupter rearrangement 4
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027356	CLA 1 Aberration	GSYM 1 Ab(3)JY16	DT 1 20 Apr 05	RESZ 593	REF 2	
ABSY|Ab(3)JY16
DT|20 Apr 05
ID|FBab0027356
REF
{
REFM|FBrf0054607
|Breen and Harte
|1991
|-1
REFM|FBrf0108148
|Breen
|1999
|-1
}

ASAL|FBal0096650 == trx<up>JY16</up>
CCM|Class relative to wildtype: Aberration
AMD|trx
REFDSR
{
RDID|FBrf0054607
|Breen and Harte
|1991
CCM|Chromosomal rearrangement is unknown.
|Chromosome fails to complement @trx@ and mutations of flanking loci.
AMD|trx
}

REFDSR
{
RDID|FBrf0108148
|Breen
|1999
CCM|Rearrangement may be a small inversion.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025193	CLA 1 Aberration	GSYM 1 Ab(3;?)comm<up>4</up>	DT 1 20 Apr 05	RESZ 532	CLOC 1 70C1--2;71E3--5	REF 1	
ABSY|Ab(3;?)comm<up>4</up>
DT|20 Apr 05
ID|FBab0025193
REF
{
REFM|FBrf0089842
|Tear et al.
|1996
|-1
}

ASAL|FBal0051697 == comm<up>4</up>
BPT|70C1--2;71E3--5
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0089842)
MU|X ray
AMD|comm
REFDSR
{
RDID|FBrf0089842
|Tear et al.
|1996
BPT|70C1--2;71E3--5;het
MU|X ray
CCM|Rearrangement breakpoint at 71E3--71E5 lies 40kb distal to the @comm@
|transcription unit.
AMD|comm
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024298	CLA 1 Aberration	GSYM 1 Ab(3;?)Csr-rv7	DT 1 20 Apr 05	RESZ 549	CLOC 1 93F2--4;h47--h58	REF 1	
ABSY|Ab(3;?)Csr-rv7
DT|20 Apr 05
ID|FBab0024298
REF
{
REFM|FBrf0084260
|Pereira et al.
|1995
|-1
}

BPT|93F2--4;h47--h58
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0084260)
MU|&ggr; ray
PRG|Csr<up>3</up>
REFDSR
{
RDID|FBrf0084260
|Pereira et al.
|1995
BPT|93F2--4;h47--h58
MU|&ggr; ray
PRG|Csr<up>3</up>
CCM|Either a paracentric inversion of a T(3;4).
PHP|Chromosome is temperature-sensitive recessive lethal.
OTH|Induced on chromosome carrying @Csr<up>rv7</up>@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024299	CLA 1 Aberration	GSYM 1 Ab(3;?)D24,D18#6	DT 1 20 Apr 05	RESZ 975	CLOC 1 80--81;62F	REF 1	
ABSY|Ab(3;?)D24,D18#6
DT|20 Apr 05
SYN|R(abd-A<up>D24</up>Abd-B<up>D18</up>)#6
ID|FBab0024299
REF
{
REFM|FBrf0080101
|Hopmann et al.
|1995
|-1
}

BPT|80--81;62F
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0080101)
MU|X ray
PRG|abd-A<up>D24</up>
|Abd-B<up>D18</up>
REFDSR
{
RDID|FBrf0080101
|Hopmann et al.
|1995
BPT|80--81;62F
MU|X ray
PRG|abd-A<up>D24</up>
|Abd-B<up>D18</up>
CCM|New order stated as: 100-81/62F-61A/unknown short segment/62F/80.
PHP|Causes moderate pairing disruption of BX-C in salivary gland nuclei.
|A5 and A6 identities are indistinguishable from those seen in unrearranged
|@Dp(3;2)D109@; @abd-A<up>D24</up>@,@Abd-B<up>D18</up>@/@Df(3R)Ubx-RS4-8@ adults,
|and this phenotype is not affected by @T(2;3)bw<up>VDe3</up>@.
OTH|Selected on basis of ability to suppress transvection in @Ubx@<up>Cbx</up>
|heterozygotes.
SYN|R(abd-A<up>D24</up>Abd-B<up>D18</up>)#6
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024300	CLA 1 Aberration	GSYM 1 Ab(3;?)D24,D18#8	DT 1 20 Apr 05	RESZ 945	CLOC 1 86F	REF 1	
ABSY|Ab(3;?)D24,D18#8
DT|20 Apr 05
SYN|R(abd-A<up>D24</up>Abd-B<up>D18</up>)#8
ID|FBab0024300
REF
{
REFM|FBrf0080101
|Hopmann et al.
|1995
|-1
}

BPT|86F
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0080101)
MU|X ray
PRG|abd-A<up>D24</up>
|Abd-B<up>D18</up>
REFDSR
{
RDID|FBrf0080101
|Hopmann et al.
|1995
BPT|86F;het
MU|X ray
PRG|abd-A<up>D24</up>
|Abd-B<up>D18</up>
CCM|Second break in undetermined heterochromatin.
PHP|Causes moderate pairing disruption of BX-C in salivary gland nuclei.
|A5 and A6 identities are indistinguishable from those seen in unrearranged
|@Dp(3;2)D109@; @abd-A<up>D24</up>@,@Abd-B<up>D18</up>@/@Df(3R)Ubx-RS4-8@ adults,
|and this phenotype is not affected by @T(2;3)bw<up>VDe3</up>@.
OTH|Selected on basis of ability to suppress transvection in @Ubx@<up>Cbx</up>
|heterozygotes.
SYN|R(abd-A<up>D24</up>Abd-B<up>D18</up>)#8
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0014439	CLA 1 Aberration	GSYM 1 Ab(3;?)ss<up>D114.7</up>	DT 1 20 Apr 05	RESZ 430	CLOC 1 89C	REF 1	
ABSY|Ab(3;?)ss<up>D114.7</up>
DT|20 Apr 05
ID|FBab0014439
REF
{
REFM|FBrf0102306
|Duncan et al.
|1998
|-1
}

ASAL|FBal0090120 == ss<up>D114.7</up>
BPT|89C
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0102306)
MU|X ray
AMD|ss
REFDSR
{
RDID|FBrf0102306
|Duncan et al.
|1998
BPT|89C;het
MU|X ray
AMD|ss
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023377	CLA 1 Aberration	GSYM 1 Ab(3L;?)Rdl<up>20</up>	DT 1 20 Apr 05	RESZ 655	CLOC 1 66F	REF 2	
ABSY|Ab(3L;?)Rdl<up>20</up>
DT|20 Apr 05
SYN|InvRdl-20
ID|FBab0023377
REF
{
REFM|FBrf0055003
|ffrench-Constant et al.
|1991
|-1
REFM|FBrf0058168
|ffrench-Constant
|1993
|-1
}

ASAL|FBal0030107 == Rdl<up>20</up>
BPT|66F
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0055003)
MU|&ggr; ray
REFDSR
{
RDID|FBrf0055003
|ffrench-Constant et al.
|1991
BPT|66F
MU|&ggr; ray
CCM|Complex rearrangement with one break in the 66F region and three others.
}

REFDSR
{
RDID|FBrf0058168
|ffrench-Constant
|1993
SYN|InvRdl-20
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024810	CLA 1 Aberration	GSYM 1 Ab(3L;h)GI1a	DT 1 20 Apr 05	RESZ 738	REF 2	
ABSY|Ab(3L;h)GI1a
DT|20 Apr 05
SYN|fz<up>GI1a</up>
|GI1a
|Ab(3L;h?)GI1a
ID|FBab0024810
REF
{
REFM|FBrf0064754
|Wong and Adler
|1993
|-1
REFM|FBrf0051945
|Adler et al.
|1990
|-1
}

CCM|Class relative to wildtype: Aberration
MU|&ggr; ray
PED|position-effect variegation for: fz
REFDSR
{
RDID|FBrf0051945
|Adler et al.
|1990
MU|&ggr; ray
CCM|Chromosomal rearrangement with the @fz@ locus juxtaposed to centromeric
|heterochromatin.
PED|position-effect variegation for: fz
PHP|This rearrangement has a weak @fz@ phenotype, probably due to position
|effect variegation.
SYN|fz<up>GI1a</up>
}

REFDSR
{
RDID|FBrf0064754
|Wong and Adler
|1993
SYN|GI1a
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023374	CLA 1 Aberration	GSYM 1 Ab(3L;h)ME178	DT 1 27 Nov 05	RESZ 2065	CLOC 1 78A7--B1	SK 1	REF 4	
ABSY|Ab(3L;h)ME178
DT|27 Nov 05
SYN|Df(3L)ME178
|Ab(3L;h?)ME178
ID|FBab0023374
REF
{
REFM|FBrf0089804
|Russell et al.
|1996
|-1
REFM|FBrf0106081
|Carpenter
|1998.11.24
|-1
REFM|FBrf0179365
|Onel et al.
|2004
|-1
REFM|FBrf0075380
|Carpenter
|1994
|-1
}

ASAL|FBal0094488 == l(3)78Ad<up>1</up>
BPT|78A7--B1
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0075380)
DIS|A.T.C. Carpenter.
MU|X ray
OAB|Fails to complement 78C deficiencies (no visible cytological defect)
|and fails to complement 78A deficiencies.
REFDSR
{
RDID|FBrf0075380
|Carpenter
|1994
BPT|78A7--B1;het
DIS|A.T.C. Carpenter.
MU|X ray
CCM|May be a translocation or an inversion.
AMDD|l(3)78Aa
|l(3)78Ab
|l(3)78Ac
OTH|Lethal in 78A and 78C, although there is no visible cytological defect
|there even in asynapsed chromosomes. Mapping of the lethal is complicated
|by the facts that when @Ab(3L;h)ME178@ is transmitted by the mother
|it is viable over most other 78C lethals and deficiencies, and even
|when it is transmitted by the father it leaks. It is nearly lethal
|over most @Pc@ deficiencies, including @In(3)Pc-T7@ and @Pc<up>3</up>@ and
|@Ubx@ duplication, but is less lethal over @Df(3L)Pc-30A@ is viable
|over @Pc<up>73</up>@ and @Df(3L)ME1325@. Lethal over @In(3)80c@ even when
|transmitted from female. Completely lethal over @Df(3L)ME107@ from
|78A lesion so 78C lesion cannot be tested. Not phenotypically @Pc@.
}

REFDSR
{
RDID|FBrf0089804
|Russell et al.
|1996
BPT|78A7--B1;het
MU|X ray
CCM|Maybe an inversion or translocation.
OAB|Fails to complement 78C deficiencies (no visible cytological defect)
|and fails to complement 78A deficiencies.
}

REFDSR
{
RDID|FBrf0106081
|Carpenter
|1998.11.24
AMD|l(3)78Ad
}

REFDSR
{
RDID|FBrf0179365
|Onel et al.
|2004
SYN|Df(3L)ME178
}

SK|FBst0004904
|Ab(3L;h)ME178, mwh[1] l(3)78Ad[1] red[1] e[4]/TM2
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0023375	CLA 1 Aberration	GSYM 1 Ab(3L;h)ME200	DT 1 27 Nov 05	RESZ 1159	CLOC 1 78D1--3	REF 2	
ABSY|Ab(3L;h)ME200
DT|27 Nov 05
SYN|Ab(3L;h?)ME200
ID|FBab0023375
REF
{
REFM|FBrf0089804
|Russell et al.
|1996
|-1
REFM|FBrf0075380
|Carpenter
|1994
|-1
}

BPT|78D1--3
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0075380)
DIS|A.T.C. Carpenter.
MU|X ray
REFDSR
{
RDID|FBrf0075380
|Carpenter
|1994
BPT|78D1--3;het
DIS|A.T.C. Carpenter.
MU|X ray
CCM|May be a translocation or an inversion.
OTH|Position-effect lethal; viability over
|deficiencies increases in the presence of an extra Y. Mapping of the
|lethal is
|complicated by the facts that when @Ab(3L;h)ME200@ is transmitted by
|the mother it is viable over everything, and even when it is transmitted
|by the father it leaks. Without an extra Y it is nearly lethal over
|most @Pc@ deficiencies but less lethal over @Df(3L)Pc-30A@, @Pc<up>3</up>@
|and @Ubx@ duplication, @Pc<up>73</up>@, @Df(3L)Pc-MK@, @Df(3L)ME107@ and @In(3)Pc-T7@
|viable over @In(3)80c@. Not phenotypically @Pc@.
}

REFDSR
{
RDID|FBrf0089804
|Russell et al.
|1996
BPT|78D1--3;het
MU|X ray
CCM|Maybe an inversion or translocation.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023376	CLA 1 Aberration	GSYM 1 Ab(3L;h)Pc-109	DT 1 27 Nov 05	RESZ 1388	CLOC 1 78C3--9	REF 2	
ABSY|Ab(3L;h)Pc-109
DT|27 Nov 05
SYN|Ab(3L;h?)Pc-109
ID|FBab0023376
REF
{
REFM|FBrf0089804
|Russell et al.
|1996
|-1
REFM|FBrf0075380
|Carpenter
|1994
|-1
}

BPT|78C3--9
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0075380)
DIS|A.T.C. Carpenter.
MU|X ray
OAB|Even with an extra Y, remains lethal over @Df(3L)Pc-101@.
PED|position-effect variegation for: Pc
|position-effect variegation for: ppl
REFDSR
{
RDID|FBrf0075380
|Carpenter
|1994
BPT|78C3--9;het
DIS|A.T.C. Carpenter.
MU|X ray
CCM|May be a translocation or an inversion.
AMDD|l(3)78Da
PED|position-effect variegation for: Pc
|position-effect variegation for: ppl
OTH|Position-effect
|variegating lethal for @Pc@, @ppl@ and the lethality of @In(3)80c@
|since rescuable by addition of a Y chromosome; however, even with
|an extra Y, remains lethal over @Df(3L)Pc-101@.
}

REFDSR
{
RDID|FBrf0089804
|Russell et al.
|1996
BPT|78C3--9;het
MU|X ray
CCM|Maybe an inversion or a translocation.
AMD|ppl
|Pc
AMDD|Ilk
|l(3)78Da
OAB|Even with an extra Y, remains lethal over @Df(3L)Pc-101@.
PHP|Position-effect variegating lethal for @Pc@, @ppl@ and the lethality
|of @In(3)80c@ since rescuable by addition of a Y chromosome.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023378	CLA 1 Aberration	GSYM 1 Ab(3R;?)A4-4L4	DT 1 20 Apr 05	RESZ 710	REF 2	
ABSY|Ab(3R;?)A4-4L4
DT|20 Apr 05
SYN|R(3R)A4-4L4
|l(3)A4-4L4
ID|FBab0023378
REF
{
REFM|FBrf0056442
|Pereira et al.
|1992
|-1
REFM|FBrf0055967
|Garzino et al.
|1992
|-1
}

ASAL|FBal0032163 == mod<up>L4</up>
CCM|Class relative to wildtype: Aberration
MU|&Dgr;2-3
PRG|FBti0001478 == FBti0001300 == P{wA}4-4
AMD|mod
OAB|Lethal in combination with @Df(3R)AP4@.
REFDSR
{
RDID|FBrf0055967
|Garzino et al.
|1992
AMD|mod
SYN|R(3R)A4-4L4
}

REFDSR
{
RDID|FBrf0056442
|Pereira et al.
|1992
MU|&Dgr;2-3
PRG|FBti0001478 == FBti0001300 == P{wA}4-4
OAB|Lethal in combination with @Df(3R)AP4@.
SYN|l(3)A4-4L4
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023379	CLA 1 Aberration	GSYM 1 Ab(3R;?)faf<up>BX13</up>	DT 1 20 Apr 05	RESZ 381	REF 1	
ABSY|Ab(3R;?)faf<up>BX13</up>
DT|20 Apr 05
ID|FBab0023379
REF
{
REFM|FBrf0055917
|Fischer-Vize et al.
|1992
|-1
}

ASAL|FBal0031247 == faf<up>BX13</up>
CCM|Class relative to wildtype: Aberration
MU|X ray
REFDSR
{
RDID|FBrf0055917
|Fischer-Vize et al.
|1992
MU|X ray
OTH|Complicated rearrangement involving the tip of chromosome 3R.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023380	CLA 1 Aberration	GSYM 1 Ab(3R;?)faf<up>BX9</up>	DT 1 20 Apr 05	RESZ 379	REF 1	
ABSY|Ab(3R;?)faf<up>BX9</up>
DT|20 Apr 05
ID|FBab0023380
REF
{
REFM|FBrf0055917
|Fischer-Vize et al.
|1992
|-1
}

ASAL|FBal0031256 == faf<up>BX9</up>
CCM|Class relative to wildtype: Aberration
MU|X ray
REFDSR
{
RDID|FBrf0055917
|Fischer-Vize et al.
|1992
MU|X ray
OTH|Complicated rearrangement involving the tip of chromosome 3R.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023381	CLA 1 Aberration	GSYM 1 Ab(3R;h)82Fj<up>1</up>	DT 1 20 Apr 05	RESZ 700	CLOC 1 [];83A1--2	SK 1	REF 2	
ABSY|Ab(3R;h)82Fj<up>1</up>
DT|20 Apr 05
SYN|Ab(het;3R)82Fj<up>1</up>
|Ab(3R;?)82Fj<up>1</up>
|Ab(3R;h?)82Fj<up>1</up>
|Ab(3R;het)82Fj<up>1</up>
ID|FBab0023381
REF
{
REFM|FBrf0075380
|Carpenter
|1994
|-1
REFM|FBrf0111824
|Carpenter
|1999
|-1
}

ASAL|FBal0031906 == l(3)82Fj<up>1</up>
BPT|[];83A1--2
CCM|Class relative to wildtype: Aberration
|All limits from polytene analysis (FBrf0075380)
DIS|A.T.C. Carpenter.
MU|X ray
REFDSR
{
RDID|FBrf0075380
|Carpenter
|1994
BPT|het;83A1+
DIS|A.T.C. Carpenter.
MU|X ray
CCM|May be a translocation or an inversion.
}

REFDSR
{
RDID|FBrf0111824
|Carpenter
|1999
BPT|het;83A1+
MU|X ray
SYN|Ab(het;3R)82Fj<up>1</up>
}

SK|FBst0004905
|Ab(3R;h)82Fj[1], mwh[1] l(3)82Fj[1] red[1] e[4]/TM3, Sb[1] Ser[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010379	CLA 1 Translocation	GSYM 1 Ab(3R;h)Cha<up>l3</up>	DT 1 31 Aug 01	RESZ 502	CLOC 1 [];91C7	REF 1	
ABSY|Ab(3R;h)Cha<up>l3</up>
DT|31 Aug 01
SYN|Ab(3R;h?)Cha<up>l3</up>
ID|FBab0010379
REF
{
REFM|745375211
|Myers and W.M. Gelbart
|Cited in Lindsley and Zimm
|-1
|1992
}

ASAL|FBal0001605 == Cha<up>l3</up>
BPT|[];91C7
ACLA|Translocation
DIS|Myers and Gelbart.
MU|X ray
CCM|Left limit of break 2 from complementation mapping against Cha (citation unavailable)
|Right limit of break 2 from polytene analysis (citation unavailable)
FGD|bk2 hits Cha
REFDSR
{
RDID|745375211
|Myers and W.M. Gelbart
|Cited in Lindsley and Zimm
BPT|het;91C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027948	CLA 1 Aberration	GSYM 1 Ab(4)ci<up>+</up>1	DT 1 20 Apr 05	RESZ 269	REF 1	
ABSY|Ab(4)ci<up>+</up>1
DT|20 Apr 05
SYN|R<up>1</up>(+)
ID|FBab0027948
REF
{
REFM|FBrf0006600
|Stern et al.
|1946
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0006600
|Stern et al.
|1946
SYN|R<up>1</up>(+)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027949	CLA 1 Aberration	GSYM 1 Ab(4)ci<up>+</up>7	DT 1 20 Apr 05	RESZ 255	REF 1	
ABSY|Ab(4)ci<up>+</up>7
DT|20 Apr 05
SYN|R(7)(+)
ID|FBab0027949
REF
{
REFM|FBrf0006600
|Stern et al.
|1946
|-1
}

CCM|Class relative to wildtype: Aberration
REFDSR
{
RDID|FBrf0006600
|Stern et al.
|1946
SYN|R(7)(+)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029421	CLA 1 Aberration	GSYM 1 Ab(Y)Y146	DT 1 20 Apr 05	RESZ 4294	CLOC 1 h21;h4	REF 1	
ABSY|Ab(Y)Y146
DT|20 Apr 05
SYN|Y146
ID|FBab0029421
REF
{
REFM|FBrf0127362
|Timakov and Zhang
|2000
|-1
}

CCM|Class relative to wildtype: Aberration
BPT|h21;h4
MU|&ggr; ray
PRG|Dp(1;Y)B<up>S</up>Yy<up>+</up>
MK|B<up>S</up>
OAB|X/@Ab(Y)Y146@/@Dp(1;Y)y<up>+</up>@ males are sterile. Testes show a departure
|from normal development at early postmeiotic stages of spermatid differentiation.
|Before nuclear elongation, round spermatid nuclei begin to fall apart
|in a large number of spermatid bundles, resulting in singular nuclei
|heads that are dispersed throughout the tails. In approximately 10%
|of males, the testes contain exclusively round spermatids scattered
|throughout the length of the tails. Many of the spermatid bundles
|with scattered nuclei are much smaller in diameter than normal, suggesting
|that some of the spermatid tails fail to develop. However, some spermatid
|bundles show aligned nuclear heads associated with individualization
|complexes, as in wild type.
|@C(1;YS)1@/@Ab(Y)Y146@ males are fertile.
|@Ab(Y)Y146@ is not complemented by @Ts(1Rt;YSt)V8@.
|@Ab(Y)Y146@ is complemented by @Ts(1Rt;YSt)W19@.
|@Ts(1Lt;YSt)P7@/@Ab(Y)Y146@ males produce large numbers of progeny,
|comparable to wild-type X/Y males.
|@Ts(1Lt;YSt)W27@/@Ab(Y)Y146@ males produce large numbers of progeny,
|comparable to wild-type X/Y males.
|@Ts(1Lt;YSt)V24@/@Ab(Y)Y146@ males show a significant reduction in
|male fertility compared to wild type; 19% of males fail to produce
|any progeny, 46% produce very small numbers of progeny (less than 40/male)
|and only 10% produce more than 80 progeny/male. Postmeiotic defects
|are seen in the testes; spermatid bundles with scattered singular nuclear
|heads are seen frequently, but account only for a small proportion
|of spermatid bundles. Some individualization complexes are located
|away from the nuclear bundles, apparently resulting from caudal movement
|along the tails (as occurs in wild type). Individualised spermatids
|are seen in the basal region of the testes and mature sperm are seen
|in the seminal vesicles.
REFDSR
{
RDID|FBrf0127362
|Timakov and Zhang
|2000
BPT|h21;h4
MU|&ggr; ray
PRG|Dp(1;Y)B<up>S</up>Yy<up>+</up>
CCM|New order: h1-h21 | h4-h1 (a duplication of h1-h4 and a deletion of
|h22-h25).
MK|B<up>S</up>
OAB|X/@Ab(Y)Y146@/@Dp(1;Y)y<up>+</up>@ males are sterile. Testes show a departure
|from normal development at early postmeiotic stages of spermatid differentiation.
|Before nuclear elongation, round spermatid nuclei begin to fall apart
|in a large number of spermatid bundles, resulting in singular nuclei
|heads that are dispersed throughout the tails. In approximately 10%
|of males, the testes contain exclusively round spermatids scattered
|throughout the length of the tails. Many of the spermatid bundles
|with scattered nuclei are much smaller in diameter than normal, suggesting
|that some of the spermatid tails fail to develop. However, some spermatid
|bundles show aligned nuclear heads associated with individualization
|complexes, as in wild type.
|@C(1;YS)1@/@Ab(Y)Y146@ males are fertile.
|@Ab(Y)Y146@ is not complemented by @Ts(1Rt;YSt)V8@.
|@Ab(Y)Y146@ is complemented by @Ts(1Rt;YSt)W19@.
|@Ts(1Lt;YSt)P7@/@Ab(Y)Y146@ males produce large numbers of progeny,
|comparable to wild-type X/Y males.
|@Ts(1Lt;YSt)W27@/@Ab(Y)Y146@ males produce large numbers of progeny,
|comparable to wild-type X/Y males.
|@Ts(1Lt;YSt)V24@/@Ab(Y)Y146@ males show a significant reduction in
|male fertility compared to wild type; 19% of males fail to produce
|any progeny, 46% produce very small numbers of progeny (less than 40/male)
|and only 10% produce more than 80 progeny/male. Postmeiotic defects
|are seen in the testes; spermatid bundles with scattered singular nuclear
|heads are seen frequently, but account only for a small proportion
|of spermatid bundles. Some individualization complexes are located
|away from the nuclear bundles, apparently resulting from caudal movement
|along the tails (as occurs in wild type). Individualised spermatids
|are seen in the basal region of the testes and mature sperm are seen
|in the seminal vesicles.
SYN|Y146
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029422	CLA 1 Aberration	GSYM 1 Ab(Y)Y2	DT 1 20 Apr 05	RESZ 2478	CLOC 1 h24;h3	REF 1	
ABSY|Ab(Y)Y2
DT|20 Apr 05
SYN|Y2
ID|FBab0029422
REF
{
REFM|FBrf0127362
|Timakov and Zhang
|2000
|-1
}

CCM|Class relative to wildtype: Aberration
BPT|h24;h3
MU|&ggr; ray
PRG|Dp(1;Y)B<up>S</up>Yy<up>+</up>
MK|B<up>S</up>
OAB|X/@Ab(Y)Y2@/@Dp(1;Y)y<up>+</up>@ males are sterile. Testes show a departure
|from normal development at early postmeiotic stages of spermatid differentiation.
|Before nuclear elongation, round spermatid nuclei begin to fall apart
|in a large number of spermatid bundles, resulting in singular nuclei
|heads that are dispersed throughout the tails. In approximately 10%
|of males, the testes contain exclusively round spermatids scattered
|throughout the length of the tails. Many of the spermatid bundles
|with scattered nuclei are much smaller in diameter than normal, suggesting
|that some of the spermatid tails fail to develop. However, some spermatid
|bundles show aligned nuclear heads associated with individualization
|complexes, as in wild type.
|@C(1;YS)1@/@Ab(Y)Y2@ males are fertile.
|@Ab(Y)Y2@ is complemented by @Ts(1Rt;YSt)V8@.
|@Ts(1Lt;YSt)P7@/@Ab(Y)Y2@, @Ts(1Lt;YSt)W27@/@Ab(Y)Y2@ and @Ts(1Lt;YSt)V24@/@Ab(Y)Y2@
|males produce large numbers of progeny.
REFDSR
{
RDID|FBrf0127362
|Timakov and Zhang
|2000
BPT|h24;h3
MU|&ggr; ray
PRG|Dp(1;Y)B<up>S</up>Yy<up>+</up>
CCM|New order: h1-h24 | h3-h1 (a duplication of h1-h3 and a deletion of
|h25).
MK|B<up>S</up>
OAB|X/@Ab(Y)Y2@/@Dp(1;Y)y<up>+</up>@ males are sterile. Testes show a departure
|from normal development at early postmeiotic stages of spermatid differentiation.
|Before nuclear elongation, round spermatid nuclei begin to fall apart
|in a large number of spermatid bundles, resulting in singular nuclei
|heads that are dispersed throughout the tails. In approximately 10%
|of males, the testes contain exclusively round spermatids scattered
|throughout the length of the tails. Many of the spermatid bundles
|with scattered nuclei are much smaller in diameter than normal, suggesting
|that some of the spermatid tails fail to develop. However, some spermatid
|bundles show aligned nuclear heads associated with individualization
|complexes, as in wild type.
|@C(1;YS)1@/@Ab(Y)Y2@ males are fertile.
|@Ab(Y)Y2@ is complemented by @Ts(1Rt;YSt)V8@.
|@Ts(1Lt;YSt)P7@/@Ab(Y)Y2@, @Ts(1Lt;YSt)W27@/@Ab(Y)Y2@ and @Ts(1Lt;YSt)V24@/@Ab(Y)Y2@
|males produce large numbers of progeny.
SYN|Y2
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027549	CLA 1 Aberration	GSYM 1 Ab(Y;2;3)O-1	DT 1 20 Apr 05	RESZ 431	REF 1	
ABSY|Ab(Y;2;3)O-1
DT|20 Apr 05
SYN|unnamed
ID|FBab0027549
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
}

CCM|Class relative to wildtype: Aberration
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x7@.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027550	CLA 1 Aberration	GSYM 1 Ab(Y;2;3)X2-1	DT 1 20 Apr 05	RESZ 432	REF 1	
ABSY|Ab(Y;2;3)X2-1
DT|20 Apr 05
SYN|unnamed
ID|FBab0027550
REF
{
REFM|FBrf0099191
|Dorer and Henikoff
|1997
|-1
}

CCM|Class relative to wildtype: Aberration
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
REFDSR
{
RDID|FBrf0099191
|Dorer and Henikoff
|1997
MU|X ray
PRG|FBti0016766 == P{lacW}50C.x7
OTH|Enhancement of @w@ variegation from the transgene array @P{lacW}50C.x7@.
SYN|unnamed
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000078	CLA 1 Aberration	GSYM 1 C(1)94-2A	DT 1 20 Apr 05	RESZ 959	REF 2	
ABSY|C(1)94-2A
DT|20 Apr 05
ID|FBab0000078
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009544
|Novitski and Braver
|1954
|-1
}

NCO|| 1A - 5E | 1F - 1A . 20 - 5E | 1F - 20 |
DIS|Rosenfeld, 1964.
MU|spontaneous \?
PRG|C(1)TR94-2
COR|Possibly X ray induced premeiotically. Apparently arose through an
|asymmetrical or reversed exchange between the 1F region near
|the centromere and the 5E region near the interstitial
|heterochromatin
CCM|Class relative to wildtype: Homo-compound chromosome
|Ring shaped in mitotic metaphase.
MK|y<up>1</up>
OTH|Originally heterozygous for @cv<up>1</up>@, @sn<up>1</up>@,
|@v<up>1</up>@, @g<up>1</up>@, and @sd<up>1</up>@.
PHP|Crossing over in region 1F - 6A produces a single ring
|carrying In(1)94-2A = In(1)1F-2A;5E-6A. Reversibly
|convertible to other double-ring configurations by other
|types of exchange (e.g., Novitski and Braver, 1954, Genetics
|39: 197-209).
}
# EOR
ABSR
{
RETE|ID 1 FBab0000079	CLA 1 Aberration	NAM 1 Compound (1) of Armentrout	GSYM 1 C(1)A	DT 1 20 Apr 05	RESZ 2157	SK 30	REF 6	
ABSY|C(1)A
DT|20 Apr 05
NAM|Compound (1) of Armentrout
ID|FBab0000079
REF
{
REFM|FBrf0048950
|Traverse and Pardue
|1988
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0137894
|Letizia et al.
|2001
|-1
REFM|FBrf0128883
|Agudo et al.
|2000
|-1
REFM|FBrf0130123
|Tyler-Smith and Floridia
|2000
|-1
REFM|FBrf0132093
|Abad et al.
|2000
|-1
}

NCO|| 1A - 6F2 | 6F2 - 1A | 20 - 7A1 | 7A1 - 20 . |
DIS|Armentrout, 1964.
MU|spontaneous
PRG|C(1)TR94, y cv v sd . y sn g
COR|Apparently arose by a process
|describable as reversed crossing over in region 6F2 - 7A1.
|Current versions of this chromosome have apparently opened,
|since they are no longer ring-shaped in metaphase. Shown to
|have separated at 13E by Traverse and Pardue (1988, Proc.
|Nat. Acad. Sci. USA 85: 8116-20) such that the new order is
|13E - 7A1 | 7A1 - 20.1 - 6F2 | 6F2 - 1 | 20 - 13E | 13E -
|20.1 - 6F2 | 6F2 - 1 | 20 - 7A1 | 7A1 - 13E which are
|interconvertable by exchange between regions 20 and 13. The
|newly terminal ends at 13E have acquired moderately repeated
|sequences (He-T DNA) ordinarily encountered at telomeres and
|in the chromocenter (Traverse and Pardue). Transmission of
|C(1)A is reduced owing to the fact that half of meiotic
|exchanges lead to the production of dicentric chromosomes.
CCM|Class relative to wildtype: Homo-compound chromosome
|Ring shaped in mitotic metaphase.
MK|y<up>1</up>
OTH|Should be the best of all compound-X chromosomes for stock purposes.
|Probably originally heterozygous for @cv<up>1</up>@, @sn<up>1</up>@,
|@v<up>1</up>@, @g<up>1</up>@, and @sd<up>1</up>@.
PHP|An apparently completely stable, compound-ring-X chromosome;
|cannot produce single-X chromosome derivative by
|heterochromatic exchange.
REFDSR
{
RDID|FBrf0048950
|Traverse and Pardue
|1988
OTH|The C(1)A chromosome has spontaneously opened in polytene region 13E
|to produce two new telomeres. Each of the new telomeres has acquired
|HeT-A DNA sequences.
}

SK|FBst0001954
|C(1)A, y[1]/Y & FM0
|FBst0004049
|C(1)A, y[1]; T(1;Y;3)W27, y[1] y[+] w[1] f[1] B[S]
|FBst0003219
|C(1;Y)1, Df(1)g, y[1] f[1] B[1]/C(1)A, y[1]/Dp(1;f)LJ9, y[+] g[+] na[+] Ste[+]
|FBst0001879
|Df(1)GE202/Y; Dp(1;2)sn[+]72d/Dp(?;2)bw[D], bw[D] & C(1)A, y[1]/Y; Dp(1;2)sn[+]72d/Dp(?;2)bw[D], bw[D]
|FBst0003224
|T(1;Y)E15, y[1] w[1]: y[+] B[S]/C(1)A, y[1]
|FBst0003158
|T(1;Y)F12, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001848
|T(1;Y)G20, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1] w[1] f[1]
|FBst0002474
|T(1;Y)G25, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0003239
|T(1;Y)G8, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0002928
|T(1;Y)N12, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0002575
|T(1;Y)N29, y[1] w[a] Ste[+] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001850
|T(1;Y)N5, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001855
|T(1;Y)P11, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001857
|T(1;Y)R2, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001880
|T(1;Y)R34, y[1] w[1] f[1]: y[+]/C(1)A, y[1]
|FBst0001881
|T(1;Y)R38, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001864
|T(1;Y)R4, y[1] w[1] f[1]: y[+]/C(1)A, y[1]
|FBst0001839
|T(1;Y)R44, y[1] w[1] f[1]: B[S]/C(1)A, y[1]
|FBst0001895
|T(1;Y)S19, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001904
|T(1;Y)S29, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001913
|T(1;Y)T16, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001912
|T(1;Y)T9, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0003060
|T(1;Y)V24, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001915
|T(1;Y)V43, y[1] w[1] Ste[+] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001922
|T(1;Y)V63, y[1] w[1] Ste[+] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0000478
|T(1;Y)V8, y[1] w[1]: y[+] B[S]/Dp(1;Y)V8, y[+] & C(1)A, y[1]/Dp(1;Y)V8, y[+]
|FBst0002950
|T(1;Y)W19, y[1] w[1] f[1]: y[+] B[S]/C(1)A, y[1]
|FBst0001449
|Ts(1Lt;Y)E5, y[1] w[1] f[1]: y[+] & C(1)A, y[1]/0
|FBst1001487
|Y[S]X.Y[L], In(1)EN, y v f B.Y[L]y[+]/C(1)A, y v/0
|FBst0004621
|y[1] w[1] ec[1] s[1] f[1]/C(1)A, y[1]
|total=
|30
SKC|30
}
# EOR
ABSR
{
RETE|ID 1 FBab0000080	CLA 1 Aberration	NAM 1 Compound (1) Double X	GSYM 1 C(1)DX	DT 1 27 Nov 05	RESZ 3809	ALESR 1	SK 350	REF 19	
ABSY|C(1)DX
DT|27 Nov 05
SYN|Compound-1 DX
|:=
NAM|Compound (1) Double X
ID|FBab0000080
REF
{
REFM|FBrf0174706
|Niemi et al.
|2004
|-1
REFM|FBrf0111904
|Helms et al.
|1999
|-1
REFM|FBrf0141717
|Carvalho et al.
|2001
|-1
REFM|FBrf0174705
|Simmons et al.
|2004
|-1
REFM|FBrf0179437
|Schumacher et al.
|2004
|-1
REFM|FBrf0127410
|Zakharenko et al.
|2000
|-1
REFM|FBrf0052612
|Prudhommeau and Proust
|1990
|-1
REFM|FBrf0127332
|Skaer and Simpson
|2000
|-1
REFM|FBrf0098381
|The Moscow Regional Drosophila melanogaster Stock Center
|Dubna
|-1
REFM|FBrf0095657
|Mason et al.
|1997
|-1
REFM|FBrf0007401
|Valencia et al.
|1949
|-1
REFM|FBrf0045718
|Zhimulev et al.
|1987
|-1
REFM|FBrf0005925
|Muller
|1943
|-1
REFM|FBrf0132437
|Green and Piergentili
|2000
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
REFM|FBrf0082182
|Jang et al.
|1995
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0145107
|Hunter et al.
|2002
|-1
REFM|FBrf0056147
|Birchler
|1992
|-1
}

DIS|Muller.
MU|X ray
PRG|In(1)dl-49, y<up>1</up> w<up>1</up> f<up>1</up>/In(1)sc<up>8</up>, sc<up>8</up> B<up>1</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)DX, In(1)dl-49 - In(1)sc<up>8</up>., y f - y<up>-</up> sc<up>8</up> f..
AMD|bb
BIP|4D7--E1;11F2--4 (from In(1)dl-49)
MK|y<up>1</up> f<up>1</up>
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|female [stated by Muller to have been
|In(1)dl-49/In(1)sc<up>8L</up>y<up>3PR</up>, but the derivative does not
|carry y<up>3P</up>]. Was originally y<up>1</up> w<up>1</up> f<up>1</up> - y<up>-</up> sc<up>8</up> B<up>1</up> ., but by
|double exchange f<up>1</up> became homozygous and B<up>1</up> was lost.
|@y<up>1</up>@, @w<up>1</up>@, @f<up>1</up>@ versions exist.
PHP|A reversed acrocentric heterozygous for In(1)dl-49; it is
|useful in balancing because it is very stable, which is
|probably due to little interstitial heterochromatin. y w f
|detachments very rarely produced. Also produces a low
|incidence of homozygosis for w.
|C(1)DX/0 lethal
REFDSR
{
RDID|FBrf0056147
|Birchler
|1992
OTH|Attached X chromosomes homozygous for various @w@ alleles were used
|to study dosage compensation of @w@.
}

REFDSR
{
RDID|FBrf0082182
|Jang et al.
|1995
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A study of metaphase arrest found that crossovers between homologs
|attached to the same centromere do not induce metaphase arrest. Hence
|exchanges induce metaphase arrest only when they physically conjoin
|two separate kinetochores. The signal that mediates metaphase arrest
|is not the exchange event per se, but the resulting tension on homologous
|kinetochores.
}

REFDSR
{
RDID|FBrf0098381
|The Moscow Regional Drosophila melanogaster Stock Center
|Dubna
MK|y<up>1</up> f<up>1</up>
OTH|Some versions also marked with @w<up>1</up>@.
}

REFDSR
{
RDID|FBrf0127332
|Skaer and Simpson
|2000
SYN|Compound-1 DX
}

BGV
{
BGVSY|C(1)DX-P
ID|FBba0000076
OTH|Carries @P-element@s derived from &pgr;2.
REF|FBrf0141259
}

SK|FBst0004354
|Binscy, w[1]/C(1)DX, y[1] f[1]
|FBst0003233
|Binscy/C(1)DX, y[1] f[1]/Dp(1;Y)y[+]
|FBst0000017
|Bx[3]/C(1)DX, y[1] w[1] f[1]
|FBst1000002
|C(1)DX, w cv/ w
|FBst1000215
|C(1)DX, y f/ Df(1)64c4/ w[+] Y
|FBst1000214
|C(1)DX, y f/ Df(1)X12, y sc/ w[+] Y
|FBst1000205
|C(1)DX, y f/ Df(1)sc[J4], sc[J4]; Dp(1;f)z[9], z
|FBst1000201
|C(1)DX, y f/ Df(1)svr, svr spl ras[2] fw/ y[2] Y
|FBst1000781
|C(1)DX, y f/ amx lz[g] v
|FBst1000212
|C(1)DX, y w f/ Df(1)64c18, g sd/ w[+] Y
|FBst1000222
|C(1)DX, y w f/ Df(1)A113; Dp(1;2)w[+64b]/ +
|FBst1000230
|C(1)DX, y w f/ Df(1)ct[J4]; Dp(1;3)sn[13a1]/ Ki
|FBst1000199
|C(1)DX, y w f/ Df(1)sc[8] In(1)sc[8], w[a]/ y[+] Y
|FBst1000235
|C(1)DX, y w f/ Df(1)v[L15], y; Dp(1;2)v[+75d]/ +
|FBst1000236
|C(1)DX, y w f/ Df(1)v[L3]; Dp(1;2)v[+63i]
|FBst1000217
|C(1)DX, y w f/ Df(1)w[258-45-64], y[2] sn[3]; Dp(1;3)w[+67k27]/ +
|FBst1000219
|C(1)DX, y w f/ Df(1)w[67k30]; Dp(1;3)w[m49a]/ +
|FBst1000218
|C(1)DX, y w f/ w[a] N[55e11]; Dp(1;2)51b/ +
|FBst1000224
|C(1)DX, y w f; T(1;2)rb[+71g], ct[6] v
|FBst0004242
|C(1)DX, y[1] f[1]/Dp(1;Y)y[+]; ca[1] awd[K]
|FBst0003721
|C(1)DX, y[1] f[1]/FM6; ry[506]
|FBst0004040
|C(1)DX, y[1] f[1]/In(1)dl-49, w[1] lz[s]
|FBst0004338
|C(1)DX, y[1] f[1]/In(1)sc[S1L]sc[8R], In(1)dl-49, In(1)At, sc[8] sc[S1] w[a] v[Of] At[1]
|FBst0004045
|C(1)DX, y[1] f[1]/R(1)2, B[1]/Dp(1;Y)y[+]; Dp(?;2)bw[D], bw[D]
|FBst0003838
|C(1)DX, y[1] f[1]/R(1)2, In(1)sc[8], Df(1)ac, ac[1] sc[8] w[a] B[1]/Dp(1;Y)y[+]
|FBst0004050
|C(1)DX, y[1] f[1]/R(1)2, y[1] f[1]/Dp(1;Y)y[+]; st[1] mus302[*]
|FBst0004054
|C(1)DX, y[1] f[1]/R(1)5, In(1)w[m4]; T(1;4)w[m258-18], y[1]
|FBst0003896
|C(1)DX, y[1] f[1]/Sxl[f1] oc[1] ptg[1] v[1]
|FBst0004069
|C(1)DX, y[1] f[1]/lz[BS+46] ras[4] v[1]
|FBst0002527
|C(1)DX, y[1] f[1]/pch[2] y[1]/Dp(1;Y)y[+]; sv[spa-pol]
|total=
|350
SKC|350
}
# EOR
ABSR
{
RETE|ID 1 FBab0023961	CLA 1 Aberration	GSYM 1 C(1)FMA4	DT 1 27 Nov 05	RESZ 597	REF 1	
ABSY|C(1)FMA4
DT|27 Nov 05
ID|FBab0023961
REF
{
REFM|FBrf0040979
|Ganetzky
|1984
|-1
}

CCM|Class relative to wildtype: Homo-compound chromosome
BIP|3C2;h28 (from In(1)w<up>m4</up>)
PRG|In(1)w<up>m4</up>
|In(1)FM7
COR|The @In(1)w<up>m4</up>@ progenitor has accumulated an undefined additional
|aberration.
REFDSR
{
RDID|FBrf0040979
|Ganetzky
|1984
PRG|In(1)w<up>m4</up>
|In(1)FM7
COR|The @In(1)w<up>m4</up>@ progenitor has accumulated an undefined additional
|aberration.
OTH|The @In(1)FM7@ chromosome is marked with @y<up>2</up>@ and @bb@<up>-</up>.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000081	CLA 1 Aberration	NAM 1 Compound (1) Multiple	GSYM 1 C(1)M2	DT 1 27 Nov 05	RESZ 575	REF 2	
ABSY|C(1)M2
DT|27 Nov 05
SYN|FMA2
|First Multiple Attached
NAM|Compound (1) Multiple
ID|FBab0000081
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0063641
|Lewis
|1958
|-1
}

DIS|Lewis, Aug. 1954.
MU|X ray
PRG|In(1)sc<up>7</up> + In(1)AM
|In(1)FM4
COR|exchange of the proximal heterochromatin of In(1)sc<up>7</up> + AM and the distal heterochromatin of In(1)FM4
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)M2, In(1)sc<up>7</up>+ AM - In(1)FM4., sc<up>7</up> - y<up>-</up> sc<up>8</up> dm B..
BIP|3C;4E--F (from In(1)FM4)
}
# EOR
ABSR
{
RETE|ID 1 FBab0000082	CLA 1 Aberration	GSYM 1 C(1)M3	DT 1 20 Apr 05	RESZ 579	SK 17	REF 3	
ABSY|C(1)M3
DT|20 Apr 05
SYN|FMA3
ID|FBab0000082
REF
{
REFM|FBrf0086407
|Francis-Lang et al.
|1996
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0063641
|Lewis
|1958
|-1
}

DIS|Lewis, Feb. 1955.
MU|recombination
PRG|In(1)sc<up>7</up>
|C(1)M2, y<up>2</up>
COR|exchange within In(1)AM element of C(1)M2 in triploid
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)M3, In(1)AM - In(1)FM4., y<up>2</up> - y<up>-</up> sc<up>8</up> dm B..
BIP|1B4;6D8 (from In(1)sc<up>7</up>)
PHP|Detachment rare; useful in balancing.
SK|FBst0001018
|C(1)M3, y[1]/Dp(1;Y)y[+]; P{ry[+t7.2]=A92}tsh[i71]; ca[1] awd[K]
|FBst0001296
|C(1)M3, y[1]/Dp(1;Y)y[+]; P{w[+tAR] ry[+t7.2AR]=wA[R]}tsh[4-3]; awd[K]
|FBst0001993
|C(1)M3, y[2] bb[1]/Dp(1;Y)y[+]; Df(3R)A/TM6 & C(1;Y)*, y[1]/Dp(1;Y)y[+]; Df(3R)A/TM6
|FBst0001139
|C(1)M3, y[2]/0; CyO/T(2;3)ap[Xa] & C(1;Y)1, y[1]: y[+]/0; CyO/T(2;3)ap[Xa], ap[Xa]
|FBst0001641
|C(1)M3, y[2]; Dp(2;1)G146, sn[3]: pal[1] Bl[1]/CyO
|FBst0001780
|C(1)M3, y[2]; ru[1] h[1] st[1] p[p] ss[1] e[s]
|FBst0003509
|C(1)M3; Ubx[bx-3] abd-A[Hab-1] Abd-B[Mc]/TM1
|FBst0000937
|Df(1)N-71h/C(1)M3, y[2]; Dp(1;2)51b/+
|FBst0006348
|Df(1)sc[8], w[a]/C(1)M3, y[2]; Dp(1;3)sc[J4], y[+], jv[1]
|FBst0006349
|Df(1)sc[8], w[a]/C(1)M3, y[2]; Dp(1;3)sc[J4], y[+], mwh[1] jv[1]/TM1
|FBst0001992
|Df(3R)A/Dp(3;3)Tpl; C(1)M3, y[2] bb[*]/C(1;Y)2, y[1]
|FBst0002934
|Df(3R)Tpl9/Dp(3;3)Tpl; C(1)M3, y[2] bb[*]/C(1;Y)*
|FBst0001304
|In(1)w[m4], In(1)AB, y[2]/C(1)M3
|FBst0001809
|T(Y;3)Antp[Ns-rv3], Antp[Ns-rv3] H[1]/C(1)M3, y[2]/TM6
|FBst0000666
|e(S)X[1]/C(1)M3, y[2]; al[1] S[1] ast[1] dpp[d-ho]/SM1
|FBst0004153
|y[1] cho[*] (w[*] B[1]) Zw[n1]/C(1)M3, y[2] bb[-]; Cy[1]/?
|FBst0000681
|y[2] z[ae(bx)2] w[bf]/C(1)M3, y[2]; Sb[sbd-2] ss[1] Ubx[bx-34e]/TM1
SKC|17
}
# EOR
ABSR
{
RETE|ID 1 FBab0000083	CLA 1 Aberration	GSYM 1 C(1)M4	DT 1 20 Apr 05	RESZ 1275	SK 42	REF 5	
ABSY|C(1)M4
DT|20 Apr 05
ID|FBab0000083
REF
{
REFM|FBrf0159638
|Presgraves et al.
|2003
|-1
REFM|FBrf0026093
|Craymer
|1974
|-1
REFM|FBrf0144851
|Schotta et al.
|2002
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0127307
|Sawamura et al.
|2000
|-1
}

DIS|Craymer, May 1972.
MU|X ray
PRG|In(1)w<up>m4</up> + In(1)AB
|In(1)FM7
COR|exchange of the proximal heterochromatin of In(1)w<up>m4</up> + AB and the distal heterochromatin of FM7
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)M4, In(1)w<up>m4</up> + AB - FM7., y w<up>m4</up> - y<up>-</up> w<up>a</up> v<up>Of</up> sc<up>8</up>..
PED|position-effect variegation for: w
OTH|Useful in maintenance of XY-bearing stocks without a free Y.
|Some derivatives are marked with @y<up>2</up>@ @bb@<up>-</up>.
PHP|Because of the w<up>m4</up>/w<up>a</up> constitution, C(1)M4 females
|without a Y chromosome display strong variegation, those
|with YS moderate variegation and those with YL or a complete
|Y almost no variegation.
|Detachment rate
|approximately 1/15,000. A powerful enhancer of autosomal
|recombination, but has low viability in combination with
|autosomal rearrangements.
SK|FBst0001999
|C(1)M4, y[2]/C(1;Y)6, w[1118]
|FBst0002000
|C(1)M4, y[2]/Y & C(1;Y)6, w[1118]/Y
|FBst0002550
|C(1)M4, y[2]/ct[n] oc[1] Hmr[1] v[1]
|FBst0001173
|C(1)M4, y[2]/shi[1]; (st[1]) in[1] kni[ri-1] p[p]
|FBst0001179
|C(1)M4, y[2]/shi[1]; In(3LR)224, ru[1]
|FBst0001170
|C(1)M4, y[2]/shi[1]; In(3LR)225/TM3, Sb[1]
|FBst0001172
|C(1)M4, y[2]/shi[1]; In(3LR)230/th[1] st[1] cp[1] in[1] kni[ri-1] Kg[V] Ki[1] p[p]
|FBst0001177
|C(1)M4, y[2]/shi[1]; In(3LR)234
|FBst0001175
|C(1)M4, y[2]/shi[1]; In(3LR)C190/Sb[1]
|FBst0001330
|C(1)M4, y[2]/shi[1]; or[1] Kr[If-1]; Sb[1]/In(3R)Ubx[80], Ubx[80]
|FBst0001249
|C(1)M4, y[2]; In(3L)C90[L]P[R], In(3R)Ubx[P18], Ubx[1] Ubx[P18] e[4]/In(3L)P[L]C90[R], Hn[r] h[1] app[1]
|FBst0001204
|C(1)M4, y[2]; In(3L)P, rs[2] th[1]
|FBst0001451
|C(1)M4, y[2]; In(3LR)206/In(3R)Hu, Antp[Hu] Sb[Spi]
|FBst0001320
|C(1)M4, y[2]; In(3LR)230/th[1] st[1] cp[1] in[1] kni[ri-1] Kg[V] Ki[1] p[p]
|FBst0003073
|C(1)M4, y[2]; In(3LR)A114/Sb[1] Ubx[1]
|FBst0001435
|C(1)M4, y[2]; In(3LR)B158/In(3LR)Ubx[16R], th[1] st[1] cp[1] Ubx[R16]
|FBst0001297
|C(1)M4, y[2]; In(3LR)C190[L]A114[R]/In(3LR)A114[L]Ubx[101R], th[1] st[1], kni[ri-1]
|FBst0001186
|C(1)M4, y[2]; In(3LR)HR33, In(3LR)LD6, ru[1] h[1] Sb[sbd-2]
|FBst0001390
|C(1)M4, y[2]; In(3LR)P42, st[1] cp[1] in[1] kni[ri-1]
|FBst0001193
|C(1)M4, y[2]; In(3LR)bxd[194L]79i[R], p[p]/In(3LR)79i[L]bxd[194R], p[p]
|FBst0001456
|C(1)M4, y[2]; In(3LR)bxd[194L]C190[R], p[p]/In(3LR)C190[L]bxd[194R], p[p]
|FBst0001216
|C(1)M4, y[2]; LS(2)SM1, In(2R)bw[V57e]//DS(2)SM1, In(2L)Cy, Cy[1]
|FBst0001198
|C(1)M4, y[2]; LS(3)HR33, In(3LR)LD6, In(3L)HR27, In(3LR)P42, In(3LR)224, st[1] Sb[sbd-2]//DS(3)HR33 + In(3LR)LD6, In(3L)HR15, In(3L)HR27, In(3LR)P42, In(3LR)224, st[1] Sb[sbd-2]
|FBst0001440
|C(1)M4, y[2]; LS(3)Ubx[42T], D[3]//DS(3)Ubx[42T]
|FBst0001289
|C(1)M4, y[2]; TM6B, Tb[1] Dr[Mio]/In(3R)Dl[B], Dl[B]
|FBst0001633
|C(1)M4, y[2]; p[p]
|FBst0001408
|C(1)M4, y[2]; th[1] st[1] cp[1] in[1] kni[ri-1] Kg[V] Ki[1] p[p]/TM3, Sb[1] Ser[1]
|FBst0001394
|C(1;Y)1, In(1)dl-49, y[1] pn[62] v[Of] f[1]/0/C(1)M4
|FBst0000995
|C(1;Y)3, In(1)FM7, w[1] m[2]/0/C(1)M4, y[2]
|FBst0001398
|C(1;Y)6, Dp(3;1)P115, y[2] sc[1] su(s)[2] pn[1] sn[3], y[+]/0 & C(1)M4, y[1]
|total=
|42
SKC|42
}
# EOR
ABSR
{
RETE|ID 1 FBab0028738	CLA 1 Aberration	GSYM 1 C(1)M5	DT 1 20 Apr 05	RESZ 188	SK 2	REF 1	
ABSY|C(1)M5
DT|20 Apr 05
ID|FBab0028738
REF
{
REFM|FBrf0109188
|Florence
|1999.7.22
|-1
}

CCM|Class relative to wildtype: Homo-compound chromosome
SK|FBst0005279
|Df(1)JC70/Dp(1;Y)dx[+]5, y[+]/C(1)M5
|FBst0005281
|Df(1)dx81, w[*]/Dp(1;Y)dx[+]1/C(1)M5
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0000084	CLA 1 Aberration	NAM 1 Compound (1) of Novitski and Braver	GSYM 1 C(1)NB	DT 1 20 Apr 05	RESZ 918	REF 2	
ABSY|C(1)NB
DT|20 Apr 05
NAM|Compound (1) of Novitski and Braver
ID|FBab0000084
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009544
|Novitski and Braver
|1954
|-1
}

DIS|Novitski and Braver.
MU|recombination
PRG|In(1)EN
|In(1)dl-49
COR|exchange between the heterochromatic short arm of In(1)EN and the proximal heterochromatin of In(1)dl-49
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)NB, In(1)dl-49.In(1)sc<up>4L</up>EN<up>R</up>; originally y v f
|car . y m; In(1)dl-49 and In(1)EN attached proximally to a
|single centromere.
|Essentially a tandem metacentric heterozygous for @In(1)dl-49@.
|Can exist in a number of different configurations interconvertible by
|crossing over.
BIP|1A;20F;20F (from In(1)EN)
|4D7--E1;11F2--4 (from In(1)dl-49)
PHP|Generates single rings at different frequencies, depending on
|configuration of the compound.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000085	CLA 1 Aberration	NAM 1 Compound (1) Reversed Acrocentric	GSYM 1 C(1)RA	DT 1 20 Apr 05	RESZ 1940	SK 7	REF 5	
ABSY|C(1)RA
DT|20 Apr 05
SYN|RA
NAM|Compound (1) Reversed Acrocentric
ID|FBab0000085
REF
{
REFM|FBrf0011855
|Sandler
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009543
|Novitski
|1954
|-1
REFM|FBrf0009563
|Sandler
|1954
|-1
REFM|FBrf0033196
|Sandler and O'Tousa
|1979
|-1
}

DIS|Novitski.
MU|spontaneous
|recombination
PRG|C(1;YL)1
|In(1)sc<up>8</up>
COR|between the proximal heterochromatin of X.YL and the distal
|heterochromatin of In(1)sc<up>8</up> or possibly by sister-strand
|union in one of the heterochromatic segments followed by a
|normal euchromatic exchange. A frequently recurring event
|that seems to require the presence of YL. More recent
|attempts to repeat such constructions have been
|unsuccessful, except in response to X-irradiation.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RA, + - In(1)sc<up>8</up>..
BIP|1B2;h32 (from In(1)sc<up>8</up>)
PHP|Yields frequent detachments resulting from exchange between
|the Y chromosome and the interstitial heterochromatin of the
|reversed acrocentric and preferential recovery of the
|proximal X. Tetrad distribution usually quite abnormal;
|one-exchange tetrads infrequent and no- and two-exchange
|tetrads frequent. Exchange frequency increased by addition
|of Y or y<up>+</up>YL, but tetrad distribution remains abnormal
|(Sandler, 1954). YL appended as a second arm to C(1)RA
|normalizes tetrad distribution (Sandler, 1958). Tetrad
|distribution is normal in more recently recovered C(1)RA
|chromosomes (Sandler and O'Tousa, 1979), reason for differences
|between 1954 and 1979 data is unclear. The presence of a Y
|chromosome or a free-X duplication as a homologue markedly
|increases both exchange between the elements of the compound
|and fecundity of compound-bearing females.
SK|FBst0003923
|C(1)RA, In(1)AB, y[1], In(1)sc[8], sc[8]/Dp(1;YL)sc[S1]/C(1;Y)1, y[1] B[1]
|FBst0003220
|C(1)RA, In(1)sc[J1], In(1)sc[8], l(1)1Ac[1], sc[J1] sc[8]/C(1;Y)6, Df(1)259, w[1]/Dp(1;Y)y[53i], y[53i] sc[8]
|FBst0004554
|C(1)RA, cin[1] y[1]/Dp(1;Y)y[+]/Sxl[K1274-1] v[24]
|FBst0001305
|C(1)RA, cin[1] y[1]/Dp(1;Y)y[+]/cin[1] y[1] w[1]
|FBst0003924
|C(1)RA, v[1] f[1]/C(1;YL)C2, y[1] cv[1] v[1] f[1] car[1] bb[-]/C(YS)1
|FBst0004486
|C(1)RA, y[1]: In(1)sc[8], sc[8]/Dp(1;YL)y[+]YL/C(1;Y)1, y[1] B[1]
|FBst0003925
|Dp(1;f)1173; C(1)RA, Df(1)259, y[1]/C(1;Y)6, Df(1)259, y[1] w[1]
SKC|7
}
# EOR
ABSR
{
RETE|ID 1 FBab0000086	CLA 1 Aberration	GSYM 1 C(1)RA60g	DT 1 20 Apr 05	RESZ 1017	SK 3	REF 4	
ABSY|C(1)RA60g
DT|20 Apr 05
SYN|XX,Df(1)60g
ID|FBab0000086
REF
{
REFM|FBrf0063713
|Mohler
|1960
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0018685
|Gethmann
|1967
|-1
REFM|FBrf0063456
|Gethmann
|1967
|-1
}

DIS|Mohler, July 1960.
MU|spontaneous
COR|A spontaneous euchromatic event (perhaps sister chromatid union)
|a triploid female heterozygous for In(1)sc<up>8</up>+dl-49
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RA60g, + - In(1)sc<up>8</up>.
|Deleted for interstitial heterochromatin of X.
|Deleted for proximal euchromatin of X.
AMD|su(f)
OAB|Requires a duplication carrying @su(f)@ and @bb@ in order to survive.
OTH|The reciprocal exchange product, Dp(1;f)60g, recovered from
|same fly.
PHP|Exhibits standard distribution of tetrads in meiosis
|(Gethmann).
REFDSR
{
RDID|FBrf0063456
|Gethmann
|1967
SYN|XX,Df(1)60g
}

REFDSR
{
RDID|FBrf0063713
|Mohler
|1960
MU|spontaneous
SYN|XX,Df(1)60g
}

SK|FBst0002170
|C(1)RA60g, y[1] B[1] w[a]/FM7c/Dp(1;Y)su(f)[+]
|FBst0002153
|Dp(1;f)60g, y[31d]/C(1)RA60g/y[1] ac[Hw-1] g[2] f[1]
|FBst0002164
|Dp(1;f)65X[C2], y[+]/C(1)RA60g/C(1;Y)*, y[1] v[1] f[1] car[1]
SKC|3
}
# EOR
ABSR
{
RETE|ID 1 FBab0000087	CLA 1 Aberration	GSYM 1 C(1)RA85	DT 1 20 Apr 05	RESZ 691	REF 2	
ABSY|C(1)RA85
DT|20 Apr 05
ID|FBab0000087
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0048200
|Mount et al.
|1988
|-1
}

MU|spontaneous
|recombination
PRG|In(1)sc<up>S1L</up>sc<up>8R</up> + In(1)S, w<up>a</up> B y w<up>1118</up> f<up>5</up>
COR|between the proximal heterochromatin of y w<up>1118</up> f<up>5</up> and the distally inverted heterochromatin of Basc, with subsequent loss of B and homozygosis of f<up>5</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RA85, y w<up>1118</up> f<up>5</up> - In(1)sc<up>S1L</up> sc<up>8R</up> +S, y<up>-</up>
|sc<up>8</up> w<up>r</up> f<up>5</up>.
PHP|A stable compound X chromosome.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000088	CLA 1 Aberration	NAM 1 Compound (1) Reversed Metacentric	GSYM 1 C(1)RM	DT 1 27 Nov 05	RESZ 3309	ALESR 1	SK 353	REF 18	
ABSY|C(1)RM
DT|27 Nov 05
SYN|Attached-X
|A-X
|attached-X
|.=
NAM|Compound (1) Reversed Metacentric
ID|FBab0000088
REF
{
REFM|FBrf0073960
|Moore et al.
|1994
|-1
REFM|FBrf0152012
|Dauwalder et al.
|2002
|-1
REFM|FBrf0108616
|Bloomington Drosophila Stock Center
|1999.7.1
|-1
REFM|FBrf0003106
|Beadle and Emerson
|1935
|-1
REFM|FBrf0001148
|Morgan
|1922
|-1
REFM|FBrf0098381
|The Moscow Regional Drosophila melanogaster Stock Center
|Dubna
|-1
REFM|FBrf0089627
|Dernburg et al.
|1996
|-1
REFM|FBrf0095657
|Mason et al.
|1997
|-1
REFM|FBrf0180638
|Takano-Shimizu et al.
|2004
|-1
REFM|FBrf0001401
|Anderson
|1925
|-1
REFM|FBrf0132437
|Green and Piergentili
|2000
|-1
REFM|FBrf0056104
|Rose and Wieschaus
|1992
|-1
REFM|FBrf0023530
|Leigh
|1972
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0010234
|Welshons
|1955
|-1
REFM|FBrf0056147
|Birchler
|1992
|-1
REFM|FBrf0004291
|Morgan
|1938
|-1
REFM|FBrf0004154
|Morgan
|1938
|-1
}

DIS|L. V. Morgan, 12th Feb. 1921.
MU|recombination
COR|Recurs regularly by exchange between the heterochromatin of the short
|arm of one X, XYS, or XYL that of the base of the long arm of a sister
|or homolog. Can
|be induced in mature X.YL -bearing sperm (Leigh, 1972, DIS
|48: 107). Presumably the pericentric heterochromatic
|constitutions of independently arising C(1)RM chromosomes varies.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RM, +.+; two X chromosomes in normal sequence attached
|proximally to the same centromere
MK|f<up>1</up> mal<up>2</up>
OTH|Exists with many combinations of markers.
PHP|Recombination with the Y chromosome leads to detachments
|with a frequency of about 10<up>-3</up> in C(1)RM/Y females. Has
|been extensively used in studies of crossing over (e.g.,
|Anderson, 1925, Genetics 10: 403-17; Beadle and Emerson,
|1935, Genetics 20: 192-206; Welshons, 1955, Genetics 40:
|918-36).
REFDSR
{
RDID|FBrf0004291
|Morgan
|1938
SYN|Attached-X
}

REFDSR
{
RDID|FBrf0056147
|Birchler
|1992
OTH|Attached X chromosomes homozygous for various @w@ alleles were used
|to study dosage compensation of @w@.
}

REFDSR
{
RDID|FBrf0098381
|The Moscow Regional Drosophila melanogaster Stock Center
|Dubna
MK|f<up>1</up> mal<up>2</up>
}

REFDSR
{
RDID|FBrf0132437
|Green and Piergentili
|2000
SYN|A-X
|attached-X
}

BGV
{
BGVSY|C(1)RM-w<up>+</up>8
ID|FBba0000291
REF|FBrf0108616
REFDSR
{
RDID|FBrf0108616
|Bloomington Drosophila Stock Center
|1999.7.1
MK|y<up>1</up> w<up>*</up>
|Ecol\lacZ<up>3-76</up> Ecol\lacZ<up>5-45fD</up> Ecol\lacZ<up>P\T.W</up>
TRNA|FBti0001034 == P{lacW}5-45fD
|FBti0001033 == P{lacW}4-5fP
|FBti0001031 == P{lacW}3-52d
|FBti0001032 == P{lacW}3-76a
}

}

SK|FBst0004093
|C(1)RM, In(1)dl-49, y[1] ct[l] sn[X2]: y[1] ct[n] oc[1] ptg[1] car[1]/R(YL)/C(1;YS)1, oc[1] ptg[1]
|FBst0004488
|C(1)RM, sc[1] v[1] f[1]/C(1;YS)1, f[1]/Df(YS)st
|FBst0003959
|C(1)RM, sc[1] v[1] f[1]/R(YL)/C(1;YS)6, In(1)EN2, w[1] oc[1] ptg[1] f[1]
|FBst1000289
|C(1)RM, y/ Y[S] X.Y[L] In(1)EN, y; In(2L)Cy In(2R)Cy, Cy cn[2]; T(Y;2)G44, y[+]
|FBst0003697
|C(1)RM, y[1] P{w[+mC]=lacW}5-45fD w[*] P{lacW}4-5fP P{lacW}3-52d P{lacW}3-76a/+
|FBst0000016
|C(1)RM, y[1] P{w[+mC]=lacW}5-45fD w[*] P{lacW}4-5fP P{lacW}3-52d P{lacW}3-76a/0/C(1;Y)13, v[1] f[1]
|FBst0003711
|C(1)RM, y[1] P{w[+mC]=lacW}5-45fD w[*] P{lacW}4-5fP P{lacW}3-52d P{lacW}3-76a/w[1118]/Y
|FBst0001217
|C(1)RM, y[1] pn[1] v[1]/0 & C(1;Y)*, y[1] B[1]/0
|FBst0004248
|C(1)RM, y[1] pn[1] v[1]/C(1;Y)1, y[1] B[1]/0; sv[spa-pol]
|FBst0004485
|C(1)RM, y[1] sc[1] t[2] v[1] f[1] car[1]/C(1;Y)1, y[1] y[+] w[1] sn[5] oc[1] ptg[1] v[1]/0
|FBst0003758
|C(1)RM, y[1] v[1] bb[-]/0/C(1;Y)110-8, y[2] y[+] su(w[a])[1] w[a]
|FBst0003752
|C(1)RM, y[1] v[1] bb[-]/0/C(1;Y)129-16, y[2] y[+] su(w[a])[1] w[a]
|FBst0004494
|C(1)RM, y[1] v[1] bb[-]/C(1;Y)112-17, y[2] su(w[a])[1] w[a]/0
|FBst0001612
|C(1)RM, y[1] v[1] bb[1]/0; C(4)RM, ci[1] ey[R]/0 & C(1;Y)1, v[1] f[1] B[1]/0; C(4)RM, ci[1] ey[R]/0
|FBst0004490
|C(1)RM, y[1] v[1] f[1]/Dp(1;1)L-B[S] Df(1)bb3a, y[1] cv[1] v[1] f[1] B[S] bb[-]
|FBst0003969
|C(1)RM, y[1] v[1] f[1]/R(YL)/C(1;YS)1
|FBst0004489
|C(1)RM, y[1]/C(1;YL)1, y[1] cv[1] v[1] f[1] car[1]/C(YS)1
|FBst0001141
|C(1)RM, y[2] sc[1] z[1]/T(1;3)m9, dsx[D] Sb[1] e[1] l(3)e[1]
|FBst0003807
|C(1)RM, y[2] su(w[a])[1] w[a] bb[-]/0/C(1;Y)1, y[1] y[+]; dp[olv] wg[Sp-1] cn[1]/In(2L)Cy, S[2] Cy[1] cn[1] bw[1] sp[1]
|FBst0003934
|C(1)RM, y[2] su(w[a])[1] w[a] bb[-]/R(YL)/C(1;YS)6, In(1)EN2, oc[1] ptg[1] f[1]
|FBst1000064
|C(1)RM, y[2]/ y; TM3, y[+]/ Sb
|FBst0002548
|C(1;Y)1, y[1] cv[1] B[1]/0 & C(1)RM, y[1] v[1] bb[-]/0
|FBst0002549
|C(1;Y)1, y[1] cv[1] v[1] B[1]/0 & C(1)RM, y[1] v[1] bb[-]/0
|FBst0005128
|C(1;Y)1, y[1] sn[3] l(1)dd4[1]/C(1)RM, y[1] v[1]; Dp(1;f)LJ9, y[+]
|FBst0002556
|C(1;Y)1, y[1] v[1] f[1] B[1]: y[+]/0 & C(1)RM, y[1] v[1]/0
|FBst0000700
|C(1;Y)1, y[1] v[1] f[1] B[1]: y[+]/C(1)RM, y[2] su(w[a])[1] w[a]
|FBst0002494
|C(1;Y)1, y[1] w[A738]: y[+]/0 & C(1)RM, y[1] v[1]/0
|FBst0005952
|C(1;Y)108-9, y[2] su(w[a])[1] w[a]/C(1)RM, y[1] v[1] bb[1]/0
|FBst0005953
|C(1;Y)115-9, y[2] su(w[a])[1] w[a]/C(1)RM, y[1] v[1] bb[1]/0
|FBst0002454
|C(1;Y)2, B[S], y[1] ct[6] f[1]/0 & C(1)RM, y[1] v[1] bb[-]/0
|total=
|353
SKC|353
}
# EOR
ABSR
{
RETE|ID 1 FBab0000089	CLA 1 Aberration	NAM 1 Compound (1) Reversed Ring	GSYM 1 C(1)RR1	DT 1 20 Apr 05	RESZ 503	REF 2	
ABSY|C(1)RR1
DT|20 Apr 05
SYN|RR
NAM|Compound (1) Reversed Ring
ID|FBab0000089
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009543
|Novitski
|1954
|-1
}

DIS|Zimmering.
MU|spontaneous
PRG|C(1)TR1
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RR1, + - In(1)EN, y<up>-</up> sc<up>-</up> - y; two X chromosomes
|attached by their normally distal ends to a common
|centromere and by their normally proximal ends to each
|other.
MK|y<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000090	CLA 1 Aberration	GSYM 1 C(1)RR2	DT 1 20 Apr 05	RESZ 958	REF 3	
ABSY|C(1)RR2
DT|20 Apr 05
ID|FBab0000090
REF
{
REFM|FBrf0011855
|Sandler
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0011393
|Sandler
|1957
|-1
}

DIS|Sandler.
MU|X ray
PRG|C(1)RM, In(1)sc<up>8</up>, In(1)sc<up>S1L</up>EN<up>R</up>
COR|Recovered as simultaneous loss of y<up>+</up> from the
|tip of both arms.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RR2, In(1)sc<up>8</up>.In(1)sc<up>S1L</up>EN<up>R</up>; originally y<up>-</up> cv v
|f . y m car. In(1)sc<up>8</up> and In(1)sc<up>S1L</up>EN<up>R</up> attached
|proximally to a single centromere and distally at their
|distal heterochromatic segments.
PHP|Tetrad distribution abnormal; one-exchange tetrads are
|infrequent and no- and two-exchange tetrads are frequent.
|Exchange frequency increased by addition of Y or y<up>+</up>YL, but
|tetrad distribution remains abnormal.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000091	CLA 1 Aberration	GSYM 1 C(1)RR94-2F	DT 1 20 Apr 05	RESZ 495	REF 2	
ABSY|C(1)RR94-2F
DT|20 Apr 05
ID|FBab0000091
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0017221
|Sandler
|1965
|-1
}

DIS|Rosenfeld, 1964.
MU|X ray
PRG|C(1)TR94
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)RR94-2F, +.+; two X chromosomes of normal sequence
|attached proximally to a single centromere and joined
|distally by a segment of heterochromatin.
PHP|Tetrad distribution more nearly normal than in C(1)RR2.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000092	CLA 1 Aberration	NAM 1 Compound (1) of Sturtevant	GSYM 1 C(1)SB	DT 1 27 Nov 05	RESZ 844	SK 1	REF 3	
ABSY|C(1)SB
DT|27 Nov 05
NAM|Compound (1) of Sturtevant
ID|FBab0000092
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0018681
|Sandler and Lindsley
|1967
|-1
REFM|FBrf0010801
|Novitski and Sandler
|1956
|-1
}

DIS|Sturtevant and Beadle.
MU|recombination
PRG|In(1)y<up>4</up>
|C(1)RM
COR|exchange between the uninverted portion of In(1)y<up>4</up> and C(1)RM in a triploid
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)SB, +.In(1)y<up>4</up>; In(1)y<up>4</up> and a normal sequence
|attached proximally to a single centromere.
|A reversed metacentric heterozygous for @In(1)y<up>4</up>@.
BIP|1B1;18A3--4 (from In(1)y<up>4</up>)
PHP|Meiotic behavior similar to that of a tandem metacentric. Crossing
|over within inversion generates single ring, R(1)y<up>4</up>.
SK|FBst0003935
|Dp(1;1)Co/C(1)SB, In(1)y[4], y[4] cv[1] v[1] f[1] bb[-]: y[2] su(w[a])[1] w[a] bb[-]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000096	CLA 1 Aberration	GSYM 1 C(1)TA.sc<up>V1</up>	DT 1 20 Apr 05	RESZ 706	REF 2	
ABSY|C(1)TA.sc<up>V1</up>
DT|20 Apr 05
ID|FBab0000096
REF
{
REFM|FBrf0019613
|Merriam
|1968
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

MU|recombination
PRG|C(1)TA.YL
|T(1;4)B<up>S</up>, B<up>S</up>
|In(1LR)sc<up>V1</up>, car . sc<up>V1</up> y<up>+</up>
COR|Derived as a recombinant in the B - car region between
|C(1)TA.YL and the X<up>P</up>4<up>D</up> element of T(1;4)B<up>SL</up>In(1LR)sc<up>V1R</up>, B<up>S</up> car . sc<up>V1</up> y<up>+</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TA.sc<up>V1</up>, + - +., y - y.sc<up>V1</up> y<up>+</up>.
BIP|1B2--12;h33--h34 (from In(1LR)sc<up>V1</up>)
|16A1;16A7--B1;102F (from T(1;4)B<up>S</up>)
}
# EOR
ABSR
{
RETE|ID 1 FBab0000095	CLA 1 Aberration	GSYM 1 C(1)TA.YL	DT 1 20 Apr 05	RESZ 651	REF 2	
ABSY|C(1)TA.YL
DT|20 Apr 05
ID|FBab0000095
REF
{
REFM|FBrf0019613
|Merriam
|1968
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

MU|spontaneous
|recombination
PRG|X.YS, In(1)sc<up>8L</up>EN<up>R</up>, y<up>+</up> y
|X.YL, y cv v f car
COR|thought to result from an euchromatic exchange
|between the X.YL chromosome and the acentric ring formed by
|dyscentric exchange between the distal and proximal
|heterochromatin of the long arm of X.YS, In(1)sc<up>8L</up>EN<up>R</up>.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TA.YL + - +., y - y.KL; original line segregating
|for cv, v, f, and car.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000093	CLA 1 Aberration	NAM 1 Compound (1) Tandem Acrocentric	GSYM 1 C(1)TA1	DT 1 20 Apr 05	RESZ 682	REF 2	
ABSY|C(1)TA1
DT|20 Apr 05
SYN|TA
NAM|Compound (1) Tandem Acrocentric
ID|FBab0000093
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009543
|Novitski
|1954
|-1
}

DIS|Novitski.
MU|X ray
PRG|In(1)sc<up>4</up>
|C(1;YL)1
COR|exchange of the proximal heterochromatin of In(1)sc<up>4</up> and YS of YSX.YL
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TA1, In(1)sc<up>4</up> - In(1)EN.YL, y sc<up>4</up> - y..
BIP|1B3;h26--h28 (from In(1)sc<up>4</up>)
PHP|Produces a single, centric, rod-X chromosome and either an
|acentric, ring-X or a tandem triple-X chromosome by
|recombination between the proximal and distal X chromosomes.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000094	CLA 1 Aberration	GSYM 1 C(1)TA2	DT 1 20 Apr 05	RESZ 552	REF 2	
ABSY|C(1)TA2
DT|20 Apr 05
ID|FBab0000094
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0015576
|Sandler and Lindsley
|1963
|-1
}

DIS|Sandler and Lindsley.
MU|X ray
|recombination
PRG|YSX, y<up>+</up> YS . y cv v f
|XYL, y car . YL
COR|origin requires triple exchange.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TA2, + - +.; originally y cv f - y f..
AMD|bb \?
PHP|Generates single X chromosomes like C(1)TA1. Tetrad
|distribution about normal.
|C(1)TA2/0 lethal
}
# EOR
ABSR
{
RETE|ID 1 FBab0000097	CLA 1 Aberration	NAM 1 Compound (1) Tandem Metacentric of Hinton	GSYM 1 C(1)TM-H	DT 1 27 Nov 05	RESZ 890	REF 2	
ABSY|C(1)TM-H
DT|27 Nov 05
NAM|Compound (1) Tandem Metacentric of Hinton
ID|FBab0000097
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0011387
|Hinton
|1957
|-1
}

MU|recombination
PRG|Dp(1;1)B<up>S</up>-H
|In(1)dl-49
COR|Generated by exchange between the B<up>S</up> duplication and In(1)dl-49
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TM-H, In(1)sc<up>4L</up>R(1)2<up>R</up> [.In(1)w<up>vC</up>]+dl-49;
|position of centromere indeterminate.
|Linear derivative of the unstable @R(1)2@, @In(1)w<up>vC</up>@.
BIP|4D7--E1;11F2--4 (from In(1)dl-49)
PHP|Exhibits variable stability as indicated by
|(a) their reduced recovery among the progeny of C(1)TM-H
|mothers, (b) the production of X0 patroclinous sons
|and (c) the instability of single rings produced by single
|exchange between the arms of the tandem metacentric.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000098	CLA 1 Aberration	NAM 1 Compound (1) Tandem Metacentric	GSYM 1 C(1)TM1	DT 1 20 Apr 05	RESZ 1078	REF 4	
ABSY|C(1)TM1
DT|20 Apr 05
NAM|Compound (1) Tandem Metacentric
ID|FBab0000098
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0008188
|Novitski
|1951
|-1
REFM|FBrf0007714
|Novitski and Lindsley
|1950
|-1
REFM|FBrf0010801
|Novitski and Sandler
|1956
|-1
}

DIS|Novitski, 1950.
MU|spontaneous
|recombination
PRG|R(1)2
|In(1)EN
COR|Product of one crossover between + and R(1)2 and one between In(1)EN and R(1)2 in a +/R(1)2/In(1)EN triploid
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TM1, +.In(1)sc<up>8L</up>EN<up>R</up>, y Hw f . y<up>+</up> y f; a normal
|sequence and In(1)EN attached proximally to a single
|centromere derived from R(1)2.
BIP|1A;20F;20F (from In(1)EN)
|1A3--4;19F1--20A1 (from R(1)2)
PHP|Single crossover between the arms produces single-ring-X
|chromosome with the same structure as R(1)2 and an
|acentric-rod X chromosome. Tetrad distribution about normal
|(Novitski, 1951, Genetics 36: 267-80; Novitski and Sandler,
|1956, Genetics 41: 194-206.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000099	CLA 1 Aberration	GSYM 1 C(1)TM2	DT 1 20 Apr 05	RESZ 882	REF 2	
ABSY|C(1)TM2
DT|20 Apr 05
SYN|TMX y
ID|FBab0000099
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0017013
|Lindsley and Sandler
|1965
|-1
}

DIS|Lindsley and Sandler, 1963.
MU|X ray
PRG|X.YL, In(1)sc<up>4L</up>EN<up>R</up>
COR|exchange of the proximal heterochromatin of a normal X and YL of X.YL, In(1)sc<up>4L</up>EN<up>R</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TM2, +.In(1)sc<up>4L</up>EN<up>R</up>; originally y cv v sd . y sn g.
|The sequence in mitotic prophase is: the normal X
|euchromatin, two large heterochromatic segments, a small
|segment, the centromere, a small segment, the inverted X
|euchromatin.
PHP|Recombination between the arms produces a single-ring-X
|chromosome and an acentric, rod-X chromosome. Meiotic
|behavior similar to that of C(1)TM1; tetrad distribution
|about normal.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000100	CLA 1 Aberration	GSYM 1 C(1)TM5	DT 1 20 Apr 05	RESZ 873	REF 4	
ABSY|C(1)TM5
DT|20 Apr 05
ID|FBab0000100
REF
{
REFM|FBrf0016827
|Lucchesi et al.
|1965
|-1
REFM|FBrf0022726
|Pasztor
|1971
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0018407
|Pasztor
|1967
|-1
}

DIS|Lucchesi, Mills and Rosenbleeth.
MU|X ray
PRG|YSX.YL, In(1)EN, y w v f B
|XYL.YS, y . y<up>+</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TM5, YSIn(1)EN.+; originally y w v B KS . y
PHP|Single exchange generates highly unstable single ring
|chromosomes as seen by very low recovery of ring-bearing
|daughters and by 16-46% gynandromorphs among
|single-ring-bearing progeny. Single rings apparently
|deficient for proximal euchromatic material, as they are
|Male lethal in combination with a normal Y but survive in
|combination with B<up>S</up>Y or su(f)<up>+</up>Y.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000101	CLA 1 Aberration	NAM 1 Compound (1) Tandem	GSYM 1 C(1)TMB<up>S</up>9-1	DT 1 20 Apr 05	RESZ 1213	REF 2	
ABSY|C(1)TMB<up>S</up>9-1
DT|20 Apr 05
SYN|Dp(1;1)B<up>S</up>TRG
|TMXB<up>S</up>9-1
NAM|Compound (1) Tandem
ID|FBab0000101
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0017013
|Lindsley and Sandler
|1965
|-1
}

DIS|Lindsley and Sandler, 1963.
MU|X ray
PRG|Dp(1;1)B<up>S</up>TAG
|X.YL, In(1)sc<up>8L</up>EN<up>R</up>
COR|exchange of the proximal heterochromatin of Dp(1;1)B<up>S</up>TAG and YL of X.YL, In(1)sc<up>8L</up>EN<up>R</up>
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TMB<up>S</up>9-1, Dp(1;1)B<up>S</up>TAG.In(1)sc<up>8L</up> EN<up>R</up>; originally
|B<up>S</up> y cv v sd . y sn g. The sequence in mitotic prophase is:
|the normal X euchromatin, two large heterochromatic
|segments, a small segment, the centromere, a small segment,
|the inverted X euchromatin.
BIP|15F9--16A1;20 (from Dp(1;1)B<up>S</up>TAG)
PHP|Recombination between the arms produces a single-ring-X
|chromosome, R(1)9-1 and an acentric, rod-X chromosome.
|Recombination between the B<up>S</up> duplication and the
|homologous region of the inverted arm generates a
|nontransmissible tandem-ring chromosome. Meiotic behavior
|similar to that of C(1)TM2.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000102	CLA 1 Aberration	GSYM 1 C(1)TMB<up>S</up>9-4	DT 1 20 Apr 05	RESZ 1148	REF 3	
ABSY|C(1)TMB<up>S</up>9-4
DT|20 Apr 05
SYN|Dp(1;1)B<up>S</up>TRG
|TMXB<up>S</up>9-4
ID|FBab0000102
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0128883
|Agudo et al.
|2000
|-1
REFM|FBrf0017013
|Lindsley and Sandler
|1965
|-1
}

DIS|Lindsley and Sandler, 1963.
MU|X ray
PRG|Dp(1;1)B<up>S</up>TAG
|X.YL, In(1)sc<up>8L</up>EN<up>R</up>
COR|exchange of the proximal heterochromatin (YL of X.YL)
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TMB<up>S</up>9-4, Dp(1;1)B<up>S</up>TAG.In(1)sc<up>8L</up> EN<up>R</up>; originally
|B<up>S</up> y cv v sd . y sn g. The sequence in mitotic prophase is:
|the normal X euchromatin, a large heterochromatic segment, a
|small segment, the centromere, a small segment, the inverted
|X euchromatin.
BIP|15F9--16A1;20 (from Dp(1;1)B<up>S</up>TAG)
PHP|Recombination between arms produces single-ring-X
|chromosome, R(1)9-4 and an acentric, rod-X chromosome.
|Recombination between the B<up>S</up> duplication and the
|homologous region of the inverted arm produces a tandem-ring
|chromosome that may be transmissible.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000103	CLA 1 Aberration	NAM 1 Compound (1) Tandem Ring	GSYM 1 C(1)TR1	DT 1 20 Apr 05	RESZ 893	REF 2	
ABSY|C(1)TR1
DT|20 Apr 05
NAM|Compound (1) Tandem Ring
ID|FBab0000103
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0009543
|Novitski
|1954
|-1
}

DIS|Novitski.
MU|spontaneous
|recombination
PRG|C(1)TA1
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TR1, In(1)sc<up>4</up> - In(1)EN., y<up>-</up> sc<up>-</up> - y..
OTH|the YL second arm had been replaced by the X<up>P</up>4<up>D</up> element of T(1;4)B<up>S</up> =
|T(1;4)15F9-16A1;16A7-B1;102F. A product of recombination
|between the duplicated B<up>S</up> second arm and the homologous
|region of the distal element of the tandem acrocentric.
PHP|Seems to be poorly transmissible (Novitski, 1954). Produces
|a centric, single-ring-X and either an acentric,
|single-ring-X or a tandem, triple-ring-X chromosome by
|recombination between the two elements of the compound.
}
# EOR
ABSR
{
RETE|ID 1 FBab0000104	CLA 1 Aberration	GSYM 1 C(1)TR94	DT 1 20 Apr 05	RESZ 1134	REF 4	
ABSY|C(1)TR94
DT|20 Apr 05
ID|FBab0000104
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0128883
|Agudo et al.
|2000
|-1
REFM|FBrf0018681
|Sandler and Lindsley
|1967
|-1
REFM|FBrf0033172
|Gatti et al.
|1979
|-1
}

DIS|Sandler and Lindsley.
MU|recombination
PRG|C(1)TMB<up>S</up>9-4
COR|Regular but infrequent product formed by
|exchange between the duplicated B<up>S</up> section and the
|homologous region of the inverted arm.
CCM|Class relative to wildtype: Homo-compound chromosome
|C(1)TR94, +.In(1)sc<up>4L</up>EN<up>R</up>.
OTH|Originally @y<up>1</up>@ @cv<up>1</up>@ @v<up>1</up>@
|@sd<up>1</up>@.@y<up>1</up>@ @sn<up>1</up>@ @g<up>1</up>@.
PHP|Produces a centric, single-ring-X and either an acentric,
|single-ring-X or a tandem, triple-ring-X chromosome by
|crossing over between the two arms of the compound.
|Transmission higher than that of C(1)TR1. Tetrad
|distribution about normal. Exhibits < 0.20% dicentric
|quadruple rings in mitotic metaphases (Gatti, Santini,
|Pimpinelli and Olivieri, 1979, Genetics 91: 255-74).
}
# EOR
ABSR
{
RETE|ID 1 FBab0000105	CLA 1 Aberration	NAM 1 Compound (1) of Valencia and Muller	GSYM 1 C(1)VM	DT 1 20 Apr 05	RESZ 1149	REF 2	
ABSY|C(1)VM
DT|20 Apr 05
NAM|Compound (1) of Valencia and Muller
ID|FBab0000105
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0007401
|Valencia et al.
|1949
|-1
}

DIS|Valencia, Muller and Valencia.
MU|X ray
PRG|In(1)sc<up>S1</up> + In(1)dl-49
COR|regularly X ray induced
|either by exchange between the proximal heterochromatin of the
|normal sequence and the distal heterochromatin of
|In(1)sc<up>S1</up> or by sister-strand union in one of the
|heterochromatic elements accompanied by normal euchromatic
|exchange.
CCM|Class relative to wildtype: Homo-compound chromosome
|Essentially a reversed acrocentric in which the proximal
|element contains @In(1)dl-49@.
|C(1)VM, + - In(1)sc<up>S1</up> In(1)dl-49.
OTH|Originally @y<up>1</up>@ @ac<up>1</up>@ @sc<up>1</up>@
|@pn<up>1</up>@ @w<up>1</up>@ @rb<up>1</up>@ @cm<up>1</up>@
|@ct<up>6</up>@ @sn<up>3</up>@ @oc<up>1</up>@ @ras<up>2</up>@ @v<up>1</up>@ @dy<up>1</up>@
|@g<up>1</up>@ @f<up>1</up>@ @car<up>1</up>@ -
|@y<up>1</up>@ @sc<up>S1</up>@ @lz<up>s</up>@ @B@.
PHP|Detachment by crossing over
|with a Y chromosome relatively frequent.
}
# EOR
ABSR
{
RETE|ID 1 FBab0010395	CLA 1 Aberration	GSYM 1 C(1;1;Y)4	DT 1 20 Apr 05	RESZ 802	REF 3	
ABSY|C(1;1;Y)4
DT|20 Apr 05
SYN|Y<up>S</up>X.Y<up>L</up>
|YSXX.YL
ID|FBab0010395
REF
{
REFM|FBrf0095657
|Mason et al.
|1997
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|recombination
COR|Exchange in triploid females carrying C(1)RA, first replacing the
|centromere region of the proximal X with that of YSX.YL, In(1)EN and then
|the terminus of the distal X with that of YSX.
CCM|Class relative to wildtype: Compound chromosome
|An X-Y combination carrying a C(1)RA; the distal X is YSX in
|normal sequence and the proximal X is an inverted sequence
|with YL attached as a second arm.
REFDSR
{
RDID|FBrf0095657
|Mason et al.
|1997
SYN|Y<up>S</up>X.Y<up>L</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027873	CLA 1 Aberration	GSYM 1 C(1;1;YL)RA<up>.</up>YL	DT 1 27 Nov 05	RESZ 577	SK 1	REF 1	
ABSY|C(1;1;YL)RA<up>.</up>YL
DT|27 Nov 05
ID|FBab0027873
REF
{
REFM|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
|-1
}

CCM|Class relative to wildtype: Compound chromosome
PRG|In(1)sc<up>8L</up>EN<up>R</up>
MK|y<up>1</up> y<up>+</up>
REFDSR
{
RDID|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
PRG|In(1)sc<up>8L</up>EN<up>R</up>
CCM|Centromere presumably from @C(1;Y)1@.
MK|y<up>1</up> y<up>+</up>
OTH|@In(1)sc<up>8L</up>EN<up>R</up>@ carries @y<up>1</up>@, and YL carries @y@<up>+</up>.
}

SK|FBst0004487
|C(1;1;YL)RA[.]YL: In(1)sc[8L]EN[R], y[1]: y[+]/Dp(1;YL)sc[S1]/C(1;Y)1, y[1] B[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0027874	CLA 1 Aberration	GSYM 1 C(1;1;YS)RM<up>.</up>YS	DT 1 20 Apr 05	RESZ 389	SK 1	REF 1	
ABSY|C(1;1;YS)RM<up>.</up>YS
DT|20 Apr 05
ID|FBab0027874
REF
{
REFM|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
|-1
}

CCM|Class relative to wildtype: Compound chromosome
PRG|C(1;Y)1
REFDSR
{
RDID|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
PRG|C(1;Y)1
CCM|Probably YSIn(1)EN<up>.</up>In(1)ENYS.
}

SK|FBst0004462
|C(1;1;YS)RM[.]YS, In(1)EN, y[1]/C(1;Y)1, In(1)dl-49, y[1] v[Of] f[1] car[1]/0
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010396	CLA 1 Aberration	GSYM 1 C(1;Y)1	DT 1 27 Nov 05	RESZ 2600	SK 331	REF 11	
ABSY|C(1;Y)1
DT|27 Nov 05
SYN|Y<up>S</up>X.Y<up>L</up>,In(1)En
|YSX.YL,In(1)EN,y<up>+</up>
|YSX.YL, In(1)EN
|C(1;Y)
|YSX.YL, In(1)24<up>L</up>A2<up>R</up>
|YSX.YL, In(1)26
ID|FBab0010396
REF
{
REFM|FBrf0007701
|Lindsley and Novitski
|1950
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0054128
|Rasooly and Robbins
|1991
|-1
REFM|FBrf0128883
|Agudo et al.
|2000
|-1
REFM|FBrf0152012
|Dauwalder et al.
|2002
|-1
REFM|FBrf0026093
|Craymer
|1974
|-1
REFM|FBrf0109049
|Sass and Henikoff
|1999
|-1
REFM|FBrf0008126
|Novitski
|1951
|-1
REFM|FBrf0158808
|Manheim and McKim
|2003
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
REFM|FBrf0059084
|Sawamura and Yamamoto
|1993
|-1
}

DIS|Lindsley, 1949.
MU|recombination
PRG|YSX, In(1)sc<up>8L</up>EN<up>R</up>
|y<up>+</up>Y
COR|exchange between the proximal heterochromatin of YSX, In(1)sc<up>8L</up>EN<up>R</up> and y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|YSX.YL, @In(1)EN@, YS @y@ . YL @y@<up>+</up>.
AMDP|Zhr
OTH|A derivative with B<up>S</up> at the end
|of YL described by Craymer (1974, D. I. S. 51: 21); also exists
|with various combinations of sex-linked markers. Two
|X-ray-induced paracentric-inversion derivatives described by
|Novitski: In(1)24, a nearly complete inversion with one
|break in the normally proximal euchromatin and the other in
|the centric heterochromatin and In(1)26 with one break in
|10A and one break in heterochromatin, distal or proximal not
|specified (Novitski, 1951, D. I. S. 25: 122; Lindsley and
|Novitski, 1959, Genetics 44: 187-96).
|Exists without the @y@<up>+</up> marker at the end of the YL arm.
PHP|male viable
|male fertile
REFDSR
{
RDID|FBrf0054128
|Rasooly and Robbins
|1991
CCM|X chromosome inserted between the two arms of the Y.
SYN|Y<up>S</up>X.Y<up>L</up>,In(1)En
}

REFDSR
{
RDID|FBrf0059084
|Sawamura and Yamamoto
|1993
AMDP|Zhr
OTH|Fails to rescue hybrid females from a cross between D.melanogaster
|males and D.sechellia females.
SYN|YSX.YL,In(1)EN,y<up>+</up>
}

REFDSR
{
RDID|FBrf0109049
|Sass and Henikoff
|1999
SYN|YSX.YL, In(1)EN
}

REFDSR
{
RDID|FBrf0128883
|Agudo et al.
|2000
SYN|Y<up>S</up>X.Y<up>L</up>,In(1)En
}

REFDSR
{
RDID|FBrf0158808
|Manheim and McKim
|2003
SYN|C(1;Y)
}

SK|FBst0001139
|C(1)M3, y[2]/0; CyO/T(2;3)ap[Xa] & C(1;Y)1, y[1]: y[+]/0; CyO/T(2;3)ap[Xa], ap[Xa]
|FBst0003923
|C(1)RA, In(1)AB, y[1], In(1)sc[8], sc[8]/Dp(1;YL)sc[S1]/C(1;Y)1, y[1] B[1]
|FBst0004486
|C(1)RA, y[1]: In(1)sc[8], sc[8]/Dp(1;YL)y[+]YL/C(1;Y)1, y[1] B[1]
|FBst0004248
|C(1)RM, y[1] pn[1] v[1]/C(1;Y)1, y[1] B[1]/0; sv[spa-pol]
|FBst0004485
|C(1)RM, y[1] sc[1] t[2] v[1] f[1] car[1]/C(1;Y)1, y[1] y[+] w[1] sn[5] oc[1] ptg[1] v[1]/0
|FBst0001612
|C(1)RM, y[1] v[1] bb[1]/0; C(4)RM, ci[1] ey[R]/0 & C(1;Y)1, v[1] f[1] B[1]/0; C(4)RM, ci[1] ey[R]/0
|FBst0003807
|C(1)RM, y[2] su(w[a])[1] w[a] bb[-]/0/C(1;Y)1, y[1] y[+]; dp[olv] wg[Sp-1] cn[1]/In(2L)Cy, S[2] Cy[1] cn[1] bw[1] sp[1]
|FBst0004487
|C(1;1;YL)RA[.]YL: In(1)sc[8L]EN[R], y[1]: y[+]/Dp(1;YL)sc[S1]/C(1;Y)1, y[1] B[1]
|FBst0004462
|C(1;1;YS)RM[.]YS, In(1)EN, y[1]/C(1;Y)1, In(1)dl-49, y[1] v[Of] f[1] car[1]/0
|FBst0003219
|C(1;Y)1, Df(1)g, y[1] f[1] B[1]/C(1)A, y[1]/Dp(1;f)LJ9, y[+] g[+] na[+] Ste[+]
|FBst0001394
|C(1;Y)1, In(1)dl-49, y[1] pn[62] v[Of] f[1]/0/C(1)M4
|FBst0000705
|C(1;Y)1, In(1)dl-49, y[1]; bw[1]; e[4]; ci[1] ey[R]
|FBst0001920
|C(1;Y)1, y[+]; Df(3R)sbd104/TM2, ry[*]
|FBst0013435
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}CG11642[KG01407]; ry[506]
|FBst0013422
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}CG18823[KG01298]
|FBst0013407
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}CG9281[KG01147]; ry[506]
|FBst0013643
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG00095
|FBst0013383
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG00162/C(1)DX, y[1] f[1]; ry[506]
|FBst0013387
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG00217
|FBst0014884
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01171
|FBst0013408
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01177
|FBst0013409
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01186; ry[506]
|FBst0013420
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01288
|FBst0013421
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01292
|FBst0014892
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01295
|FBst0013429
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01373; ry[506]
|FBst0013430
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01378; ry[506]
|FBst0013459
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01624
|FBst0014377
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01654; ry[506]
|FBst0013472
|C(1;Y)1, y[1] P{y[+mDint2] w[BR.E.BR]=SUPor-P}KG01701
|total=
|331
SKC|331
}
# EOR
ABSR
{
RETE|ID 1 FBab0022015	CLA 1 Aberration	GSYM 1 C(1;Y)10	DT 1 20 Apr 05	RESZ 992	REF 3	
ABSY|C(1;Y)10
DT|20 Apr 05
SYN|Y<up>S</up>.X InEN B y.Y<up>L</up>
|YSX.YL,y,B
|YSX.YL,In(1)EN,Df(1)Zhr,y,B
|YSX.YL,In(1)EN,y,B
ID|FBab0022015
REF
{
REFM|FBrf0055832
|Hawley et al.
|1992
|-1
REFM|FBrf0031636
|Durica and Krider
|1978
|-1
REFM|FBrf0059084
|Sawamura and Yamamoto
|1993
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
PRG|C(1;Y)1
AMND|Zhr
REFDSR
{
RDID|FBrf0031636
|Durica and Krider
|1978
SYN|Y<up>S</up>.X InEN B y.Y<up>L</up>
}

REFDSR
{
RDID|FBrf0055832
|Hawley et al.
|1992
SYN|YSX.YL,y,B
}

REFDSR
{
RDID|FBrf0059084
|Sawamura and Yamamoto
|1993
PRG|C(1;Y)1
AMND|Zhr
PHP|Rescues hybrid females from a cross between D.melanogaster males and
|D.sechellia females.
OTH|Marker @y@<up>+</up> has been lost by an unknown rearrangement.
SYN|YSX.YL,In(1)EN,Df(1)Zhr,y,B
|YSX.YL,In(1)EN,y,B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010397	CLA 1 Aberration	GSYM 1 C(1;Y)108-9	DT 1 20 Apr 05	RESZ 633	SK 1	REF 3	
ABSY|C(1;Y)108-9
DT|20 Apr 05
SYN|XYL.YS108-9
ID|FBab0010397
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb
|y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) YL . YS.
PHP|male viable
|male fertile
SK|FBst0005952
|C(1;Y)108-9, y[2] su(w[a])[1] w[a]/C(1)RM, y[1] v[1] bb[1]/0
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0022016	CLA 1 Aberration	GSYM 1 C(1;Y)11	DT 1 27 Nov 05	RESZ 517	REF 1	
ABSY|C(1;Y)11
DT|27 Nov 05
SYN|XYL.YS,y<up>2</up>,sc,cv,v,f
ID|FBab0022016
REF
{
REFM|FBrf0059084
|Sawamura and Yamamoto
|1993
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
PRG|C(1)RM
AMDP|Zhr
REFDSR
{
RDID|FBrf0059084
|Sawamura and Yamamoto
|1993
PRG|C(1)RM
AMDP|Zhr
OTH|Fails to rescue hybrid females from a cross between D.melanogaster
|males and D.sechellia females.
SYN|XYL.YS,y<up>2</up>,sc,cv,v,f
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010398	CLA 1 Aberration	GSYM 1 C(1;Y)110-8	DT 1 27 Nov 05	RESZ 989	CLOC 1 h18--h25B	SK 1	REF 4	
ABSY|C(1;Y)110-8
DT|27 Nov 05
SYN|XYS.YL110-8
ID|FBab0010398
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0099369
|Lindsley
|1997.12.1
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

BPT|h18--h25B
DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb/Dp(1;Y)y<up>+</up>
COR|Y breakpoint is distal to ks-2
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0099369)
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) YS . YL @y@<up>+</up>.
|YL may carry any marker available on the long arm
|of marked Y chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male viable
|male fertile
REFDSR
{
RDID|FBrf0099369
|Lindsley
|1997.12.1
BPT|h18--h25B
CCM|XYS.YL with the X in normal sequence. Possibly like @C(1;Y)8@.
}

SK|FBst0003758
|C(1)RM, y[1] v[1] bb[-]/0/C(1;Y)110-8, y[2] y[+] su(w[a])[1] w[a]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010399	CLA 1 Aberration	GSYM 1 C(1;Y)112-17	DT 1 20 Apr 05	RESZ 808	CLOC 1 h1--h17;[]	SK 1	REF 4	
ABSY|C(1;Y)112-17
DT|20 Apr 05
SYN|XYL.YS112-17
ID|FBab0010399
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0099369
|Lindsley
|1997.12.1
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

BPT|h1--h17;[]
DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb
|y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0099369)
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) YL . YS.
PHP|male viable
|male fertile
REFDSR
{
RDID|FBrf0099369
|Lindsley
|1997.12.1
BPT|h1--h17
CCM|XYL.YS with the X in normal sequence. Like @C(1;Y)6@.
}

SK|FBst0004494
|C(1)RM, y[1] v[1] bb[-]/C(1;Y)112-17, y[2] su(w[a])[1] w[a]/0
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010400	CLA 1 Aberration	GSYM 1 C(1;Y)115-9	DT 1 27 Nov 05	RESZ 987	CLOC 1 h18--h25B	SK 1	REF 4	
ABSY|C(1;Y)115-9
DT|27 Nov 05
SYN|XYS.YL115-9
ID|FBab0010400
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0099369
|Lindsley
|1997.12.1
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

BPT|h18--h25B
DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb/Dp(1;Y)y<up>+</up>
COR|Y breakpoint is distal to ks-2
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0099369)
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm
|of marked Y chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male viable
|male fertile
REFDSR
{
RDID|FBrf0099369
|Lindsley
|1997.12.1
BPT|h18--h25B
CCM|XYS.YL with the X in normal sequence. Possibly like @C(1;Y)8@.
}

SK|FBst0005953
|C(1;Y)115-9, y[2] su(w[a])[1] w[a]/C(1)RM, y[1] v[1] bb[1]/0
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0022017	CLA 1 Aberration	GSYM 1 C(1;Y)12	DT 1 20 Apr 05	RESZ 333	REF 1	
ABSY|C(1;Y)12
DT|20 Apr 05
SYN|YSX.YL,y,su(w<up>a</up>),w<up>a</up>
ID|FBab0022017
REF
{
REFM|FBrf0055832
|Hawley et al.
|1992
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
REFDSR
{
RDID|FBrf0055832
|Hawley et al.
|1992
SYN|YSX.YL,y,su(w<up>a</up>),w<up>a</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010401	CLA 1 Aberration	GSYM 1 C(1;Y)129-11	DT 1 20 Apr 05	RESZ 803	CLOC 1 h1--h17	SK 1	REF 4	
ABSY|C(1;Y)129-11
DT|20 Apr 05
SYN|XYL.YS129-11
ID|FBab0010401
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0099369
|Lindsley
|1997.12.1
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

BPT|h1--h17
DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb
|y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0099369)
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male viable
|male fertile
REFDSR
{
RDID|FBrf0099369
|Lindsley
|1997.12.1
BPT|h1--h17
CCM|XYL.YS with the X in normal sequence. Like @C(1;Y)6@.
}

SK|FBst0004453
|C(1;Y)129-11, y[2] su(w[a])[1] w[a]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010402	CLA 1 Aberration	GSYM 1 C(1;Y)129-16	DT 1 27 Nov 05	RESZ 1290	SK 1	REF 5	
ABSY|C(1;Y)129-16
DT|27 Nov 05
SYN|C(1;Y)XYL<up>*</up>YS129-16
|XYL-YS 129-16
|XYL.YS129-16
ID|FBab0010402
REF
{
REFM|FBrf0019328
|Parker
|1968
|-1
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0111950
|Lilly and Botas
|1999
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0098436
|Wickline and Lindsley
|1997
|-1
}

DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb/Dp(1;Y)y<up>+</up>
CCM|Class relative to wildtype: Hetero-compound chromosome
|The break in the y<up>+</up>Y occurs between l(1)1Ac<up>+</up> and y<up>+</up> (Parker, 1968).
|Essentially an intact Y chromosome with all of the X
|euchromatin attached to YL distal to @y@<up>+</up>.
|Interstitial position of @y@<up>+</up> shown by recovery of @y@<up>+</up>
|reattachment.
|XYL.YS.
PED|position-effect variegation for: y
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) @y@<up>+</up> KL.KS.
PHP|interstitial y<up>+</up> allele shows strong variegation.
|male viable
|male fertile
REFDSR
{
RDID|FBrf0098436
|Wickline and Lindsley
|1997
SYN|C(1;Y)XYL<up>*</up>YS129-16
}

REFDSR
{
RDID|FBrf0111950
|Lilly and Botas
|1999
SYN|XYL-YS 129-16
}

SK|FBst0003752
|C(1)RM, y[1] v[1] bb[-]/0/C(1;Y)129-16, y[2] y[+] su(w[a])[1] w[a]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0023386	CLA 1 Aberration	GSYM 1 C(1;Y)13	DT 1 20 Apr 05	RESZ 257	SK 1	REF 1	
ABSY|C(1;Y)13
DT|20 Apr 05
ID|FBab0023386
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

DIS|M.M. Green.
CCM|Class relative to wildtype: Hetero-compound chromosome
MK|v<up>1</up> f<up>1</up>
OTH|structure not known
SK|FBst0000016
|C(1)RM, y[1] P{w[+mC]=lacW}5-45fD w[*] P{lacW}4-5fP P{lacW}3-52d P{lacW}3-76a/0/C(1;Y)13, v[1] f[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010403	CLA 1 Aberration	GSYM 1 C(1;Y)2	DT 1 20 Apr 05	RESZ 475	SK 11	REF 2	
ABSY|C(1;Y)2
DT|20 Apr 05
SYN|YSX.YL
ID|FBab0010403
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Lindsley and Novitski.
MU|recombination
PRG|YSX
|C(1;YL)1
CCM|Class relative to wildtype: Hetero-compound chromosome
|An attached XY with the X in normal sequence.
|YSX.YL, KS y.YL.
OTH|Commonly kept in stock as YSX.YL/0 males crossed to C(1)/0 females.
PHP|male viable
|male fertile
SK|FBst0002454
|C(1;Y)2, B[S], y[1] ct[6] f[1]/0 & C(1)RM, y[1] v[1] bb[-]/0
|FBst0002501
|C(1;Y)2, B[S], y[1] v[1] bb[-]/0 & C(1)RM, y[1] v[1] bb[-]
|FBst0002486
|C(1;Y)2, y[+]/0 & C(1)RM, y[1] v[1]/0
|FBst0002510
|C(1;Y)2, y[1] B[1]/0 & C(1)RM, ras[l1]/0
|FBst0002487
|C(1;Y)2, y[1] B[1]/0 & C(1)RM, y[1] v[1]/0
|FBst0003710
|C(1;Y)2, y[1] P{w[+mC]=lacW}5-45fD w[*] P{w[+mC]=lacW}4-5fP P{w[+mC]=lacW}3-52d P{w[+mC]=lacW}3-76a: y[+]/0/C(1)RM, y[1] pn[1]
|FBst0001608
|C(1;Y)2, y[1] ct[6] f[1] & C(1)DX, y[1] f[1]
|FBst0002545
|C(1;Y)2, y[1] f[1] B[S]/0 & C(1)RM, y[1] v[1] bb[-]/0
|FBst0002503
|C(1;Y)2, y[1] f[1] car[1]/0 & C(1)RM, y[1] v[1] bb[1]/0
|FBst0002498
|C(1;Y)2, y[1]/0 & C(1)RM, y[1] v[1] bb[-]/0
|FBst0001992
|Df(3R)A/Dp(3;3)Tpl; C(1)M3, y[2] bb[*]/C(1;Y)2, y[1]
SKC|11
}
# EOR
ABSR
{
RETE|ID 1 FBab0010404	CLA 1 Aberration	GSYM 1 C(1;Y)2-10T13	DT 1 20 Apr 05	RESZ 635	REF 3	
ABSY|C(1;Y)2-10T13
DT|20 Apr 05
SYN|XYL.YS2-10T13
ID|FBab0010404
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb
|y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male viable
|male fertile
}
# EOR
ABSR
{
RETE|ID 1 FBab0010405	CLA 1 Aberration	GSYM 1 C(1;Y)2-10T15	DT 1 20 Apr 05	RESZ 635	REF 3	
ABSY|C(1;Y)2-10T15
DT|20 Apr 05
SYN|XYL.YS2-10T15
ID|FBab0010405
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
MU|X ray
|detachment
PRG|C(1)RM, y<up>2</up> su(w<up>a</up>) bb
|y<up>+</up>Y
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male viable
|male fertile
}
# EOR
ABSR
{
RETE|ID 1 FBab0010406	CLA 1 Aberration	GSYM 1 C(1;Y)3	DT 1 20 Apr 05	RESZ 901	SK 1	REF 3	
ABSY|C(1;Y)3
DT|20 Apr 05
SYN|FM7Y
|YSX.YL, In(1)FM7
ID|FBab0010406
REF
{
REFM|FBrf0030180
|Mitchell
|1977
|-1
REFM|FBrf0026093
|Craymer
|1974
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

DIS|Craymer, April 1974.
MU|recombination
PRG|YSX, In(1)FM7, y<up>+</up> KS y<up>-</up> w<up>a</up> v<up>Of</up>
|YSX.YL, In(1)EN, KS y.KL B<up>S</up>
CCM|Class relative to wildtype: Hetero-compound chromosome
|YSX.YL, In(1)FM7<up>L</up>EN<up>R</up>, y<up>+</up> KS y v<up>Of</up>.KL B<up>S</up>.
MK|y<up>+</up> y<up>1</up> v<up>Of</up> B<up>S</up>
OTH|such that the w<up>a</up> y<up>-</up>
|base of FM7 is replaced by the w<up>+</up> y.KL of YSX.YL,
|In(1)EN.
PHP|male viable
|male fertile
|The FM7
|inversions prevents euchromatic crossovers and the y<up>+</up> and
|B<up>S</up> markers serve to detect recombinational events in the
|heterochromatin.
SK|FBst0000995
|C(1;Y)3, In(1)FM7, w[1] m[2]/0/C(1)M4, y[2]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010407	CLA 1 Aberration	GSYM 1 C(1;Y)5	DT 1 20 Apr 05	RESZ 722	REF 4	
ABSY|C(1;Y)5
DT|20 Apr 05
SYN|YSXYL.
ID|FBab0010407
REF
{
REFM|FBrf0025061
|Donady et al.
|1973
|-1
REFM|FBrf0016239
|Novitski and Brosseau
|1964
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Lindsley.
MU|recombination
PRG|XYL.
|YSX
CCM|Class relative to wildtype: Hetero-compound chromosome
|YSXYL., KS y<up>1</up> KL..
PHP|Shows extremely reduced recovery from above heterozygous
|females (Lindsley and Novitski, 1959), all zygotes carrying
|YSXYL. being lethal in some autosomal backgrounds;
|reciprocal recombinant recovered frequently (Novitski and
|Brosseau, 1964; Donady et al., 1973).
}
# EOR
ABSR
{
RETE|ID 1 FBab0022018	CLA 1 Aberration	GSYM 1 C(1;Y)6	DT 1 20 Apr 05	RESZ 544	SK 15	REF 3	
ABSY|C(1;Y)6
DT|20 Apr 05
SYN|XY<up>L</up>.Y<up>S</up>
|XYL.YS
ID|FBab0022018
REF
{
REFM|FBrf0174695
|Hirai et al.
|2004
|-1
REFM|FBrf0011879
|Brosseau and Lindsley
|1958
|-1
REFM|FBrf0086963
|Chubykin
|1996
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
|XYL.YS
REFDSR
{
RDID|FBrf0011879
|Brosseau and Lindsley
|1958
SYN|XY<up>L</up>.Y<up>S</up>
}

REFDSR
{
RDID|FBrf0086963
|Chubykin
|1996
SYN|XY<up>L</up>.Y<up>S</up>
}

SK|FBst0001999
|C(1)M4, y[2]/C(1;Y)6, w[1118]
|FBst0002000
|C(1)M4, y[2]/Y & C(1;Y)6, w[1118]/Y
|FBst0003220
|C(1)RA, In(1)sc[J1], In(1)sc[8], l(1)1Ac[1], sc[J1] sc[8]/C(1;Y)6, Df(1)259, w[1]/Dp(1;Y)y[53i], y[53i] sc[8]
|FBst0001398
|C(1;Y)6, Dp(3;1)P115, y[2] sc[1] su(s)[2] pn[1] sn[3], y[+]/0 & C(1)M4, y[1]
|FBst0004555
|C(1;Y)6, y[1] fs(1)Yb[M104-2] cv[1] v[1]/FM7c
|FBst0005459
|C(1;Y)6, y[1] w[*] P{w[+*]=white-un4}BE1305 mew[023]/C(1)RM, y[1] pn[1] v[1]; Dp(1;f)y[+]
|FBst0001310
|C(1;Y)6, y[2] su(w[a])[1] w[a]/0/C(1)M4, y[1]
|FBst0001057
|Df(1)259, C(1;Y)6, w[1]/C(1)RM, y[1] v[1] f[1]; Dp(1;4)174/+
|FBst0003925
|Dp(1;f)1173; C(1)RA, Df(1)259, y[1]/C(1;Y)6, Df(1)259, y[1] w[1]
|FBst0003929
|Dp(1;f)122; C(1)RM, y[1] v[1] f[1]/C(1;Y)6, Df(1)259, w[1]
|FBst0003930
|Dp(1;f)164; C(1)RM, y[1] v[1]/C(1;Y)6, Df(1)259, w[1]
|FBst0003928
|Dp(1;f)18; C(1)RM, y[1] pn[1] v[1]/C(1;Y)6, Df(1)259, w[1]
|FBst0003926
|Dp(1;f)3; C(1)RM, y[1]/C(1;Y)6, Df(1)259, w[1]
|FBst0003806
|Dp(1;f)52; C(1)DX, y[1] f[1]/C(1;Y)6, Df(1)259, w[1]
|FBst0004060
|In(1)sc[8L]R(1)2[R], Dp(1;1)B[S]TMG, f[1] B[S]; T(1;4)B[S], C(1;Y)6, B[S]
SKC|15
}
# EOR
ABSR
{
RETE|ID 1 FBab0010408	CLA 1 Aberration	GSYM 1 C(1;Y)7	DT 1 27 Nov 05	RESZ 987	SK 1	REF 2	
ABSY|C(1;Y)7
DT|27 Nov 05
SYN|X-Y<up>bb-</up>
|XYL.YS, bb<up>-</up>
ID|FBab0010408
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0044481
|Komma and Endow
|1986
|-1
}

DIS|Komma.
MU|detachment
PRG|C(1)DX
|Dp(1;Ybb<up>-</up>)B<up>S</up>
COR|derived by detachment of the
|distal [In(1)dl-49] X of C(1)DX and its attachment to YL of
|B<up>S</up>Ybb<up>-</up> with loss of B<up>S</up>; In(1)dl-49 replaced by
|recombination.
CCM|Class relative to wildtype: Hetero-compound chromosome
|A Ybb<up>-</up> chromosome with the X euchromatin attached (in
|normal sequence) distal to YL.
|XYL.YS, y<up>1</up> v<up>1</up> bb<up>-</up> KL.bb<up>-</up> KS.
AMD|bb
MK|y<up>1</up> v<up>1</up>
OTH|bb/C(1;Y)6, bb<up>-</up> females show an increase in the number of
|18S + 28S ribosomal genes (magnification) in their
|offspring.
|rDNA-deficient chromosome carrying most of B<up>S</up> Ybb<up>-</up>
PHP|male viable
|male fertile
SK|FBst0000082
|C(1;Y)7, y[1] v[1] bb[-]: bb[-]/Dp(1;f)1185/C(1)DX, y[1] w[a]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0022019	CLA 1 Aberration	GSYM 1 C(1;Y)8	DT 1 20 Apr 05	RESZ 211	SK 4	REF 1	
ABSY|C(1;Y)8
DT|20 Apr 05
SYN|XYS.YL
ID|FBab0022019
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
|XYS.YL
SK|FBst0001396
|C(1;Y)8, Dp(3;1)P115, y[1] pn[1] sn[3], B[S]/0/C(1)M4
|FBst0001397
|FBst0001397
|FBst0001395
|C(1;Y)8, Dp(3;1)P115, y[2] sc[1] su(s)[2] pn[1] sn[3]/0/C(1)M4, y[1]
|FBst0002496
|C(1;Y)8, y[1] su(w[a])[1] w[a]: y[+]; kni[ri-1] p[p] & C(1)RM, y[1] v[1] bb[1]; kni[ri-1] p[p]
SKC|4
}
# EOR
ABSR
{
RETE|ID 1 FBab0010409	CLA 1 Aberration	GSYM 1 C(1;Y)9	DT 1 20 Apr 05	RESZ 593	REF 3	
ABSY|C(1;Y)9
DT|20 Apr 05
SYN|X.YSYL
ID|FBab0010409
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0019332
|Johnsen
|1968
|-1
REFM|FBrf0023023
|Johnsen and Zarrow
|1971
|-1
}

MU|X ray
PRG|X.YS, y w
|y<up>+</up>YL
CCM|Class relative to wildtype: Hetero-compound chromosome
|X.Y, YL, y<up>1</up> w<up>1</up>.KS KL y<up>+</up>; metacentric chromosome.
PHP|Attached XY with X in normal sequence on one side of the
|centromere and a complete Y on the other.
|X.YSYL/0 males fertile
|transmission of the XY somewhat reduced.
}
# EOR
ABSR
{
RETE|ID 1 FBab0029161	CLA 1 Aberration	GSYM 1 C(1;Y)B<up>S</up>	DT 1 20 Apr 05	RESZ 364	REF 1	
ABSY|C(1;Y)B<up>S</up>
DT|20 Apr 05
ID|FBab0029161
REF
{
REFM|FBrf0011879
|Brosseau and Lindsley
|1958
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|recombination
PRG|Ts(1Lt;4Lt)B<up>S</up>
|C(1;Y)6
REFDSR
{
RDID|FBrf0011879
|Brosseau and Lindsley
|1958
MU|recombination
PRG|Ts(1Lt;4Lt)B<up>S</up>
|C(1;Y)6
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010410	CLA 1 Aberration	GSYM 1 C(1;Y)E12	DT 1 20 Apr 05	RESZ 848	REF 4	
ABSY|C(1;Y)E12
DT|20 Apr 05
SYN|XYL.YSE12
ID|FBab0010410
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|Y-chromosome breakpoint distal to @kl-5@.
|XYL.Y.
AMDD|kl-5
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010411	CLA 1 Aberration	GSYM 1 C(1;Y)E17	DT 1 20 Apr 05	RESZ 811	REF 4	
ABSY|C(1;Y)E17
DT|20 Apr 05
SYN|XYL.YSE17
ID|FBab0010411
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
AM|Y-chromosome breakpoint distal to kl-5.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010412	CLA 1 Aberration	GSYM 1 C(1;Y)F6	DT 1 20 Apr 05	RESZ 811	REF 4	
ABSY|C(1;Y)F6
DT|20 Apr 05
SYN|XYL.YSF6
ID|FBab0010412
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010413	CLA 1 Aberration	GSYM 1 C(1;Y)G7	DT 1 20 Apr 05	RESZ 883	REF 4	
ABSY|C(1;Y)G7
DT|20 Apr 05
SYN|XYS.YLG7
ID|FBab0010413
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010414	CLA 1 Aberration	GSYM 1 C(1;Y)K1	DT 1 20 Apr 05	RESZ 811	REF 4	
ABSY|C(1;Y)K1
DT|20 Apr 05
SYN|XYL.YSK1
ID|FBab0010414
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010415	CLA 1 Aberration	GSYM 1 C(1;Y)N10	DT 1 20 Apr 05	RESZ 885	REF 4	
ABSY|C(1;Y)N10
DT|20 Apr 05
SYN|XYS.YLN10
ID|FBab0010415
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010416	CLA 1 Aberration	GSYM 1 C(1;Y)N16	DT 1 20 Apr 05	RESZ 813	REF 4	
ABSY|C(1;Y)N16
DT|20 Apr 05
SYN|XYL.YSN16
ID|FBab0010416
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010417	CLA 1 Aberration	GSYM 1 C(1;Y)N30	DT 1 20 Apr 05	RESZ 885	REF 4	
ABSY|C(1;Y)N30
DT|20 Apr 05
SYN|XYS.YLN30
ID|FBab0010417
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010418	CLA 1 Aberration	GSYM 1 C(1;Y)P1	DT 1 20 Apr 05	RESZ 826	REF 4	
ABSY|C(1;Y)P1
DT|20 Apr 05
SYN|XYS.YLP1
ID|FBab0010418
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
PHP|of marked Y chromosomes, e.g., y<up>+</up>, B<up>S</up>, etc.
|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010419	CLA 1 Aberration	GSYM 1 C(1;Y)P9	DT 1 20 Apr 05	RESZ 811	REF 4	
ABSY|C(1;Y)P9
DT|20 Apr 05
SYN|XYL.YSP9
ID|FBab0010419
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0029162	CLA 1 Aberration	GSYM 1 C(1;Y)sc<up>260-14</up>	DT 1 20 Apr 05	RESZ 514	REF 1	
ABSY|C(1;Y)sc<up>260-14</up>
DT|20 Apr 05
SYN|C(1;Y)6, In(1)sc<up>260-14</up>
ID|FBab0029162
REF
{
REFM|FBrf0125111
|Gornek et al.
|2000.2.4
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|1B2--3;11D3--8 (from In(1)sc<up>260-14</up>)
MU|recombination
PRG|C(1;Y)6
|In(1)sc<up>260-14</up>
REFDSR
{
RDID|FBrf0125111
|Gornek et al.
|2000.2.4
MU|recombination
PRG|C(1;Y)6
|In(1)sc<up>260-14</up>
SYN|C(1;Y)6, In(1)sc<up>260-14</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028794	CLA 1 Translocation	GSYM 1 C(1;Y)sc<up>7</up>	DT 1 20 Apr 05	RESZ 437	CLOC 1 [];h1--h17	REF 1	
ABSY|C(1;Y)sc<up>7</up>
DT|20 Apr 05
SYN|T(1;Y)sc<up>7</up>
ID|FBab0028794
REF
{
REFM|FBrf0109188
|Florence
|1999.7.22
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|1B4;6D8 (from In(1)sc<up>7</up>)
BPT|[];h1--h17
ACLA|Translocation
PRG|In(1)sc<up>7</up>
REFDSR
{
RDID|FBrf0109188
|Florence
|1999.7.22
BPT|[];h1--h17
ACLA|Translocation
PRG|In(1)sc<up>7</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010420	CLA 1 Aberration	GSYM 1 C(1;Y)V13	DT 1 20 Apr 05	RESZ 813	REF 4	
ABSY|C(1;Y)V13
DT|20 Apr 05
SYN|XYL.YSV13
ID|FBab0010420
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010421	CLA 1 Aberration	GSYM 1 C(1;Y)V23	DT 1 20 Apr 05	RESZ 883	REF 4	
ABSY|C(1;Y)V23
DT|20 Apr 05
SYN|XYS.YLV23
ID|FBab0010421
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., y<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010422	CLA 1 Aberration	GSYM 1 C(1;Y)V25	DT 1 20 Apr 05	RESZ 885	REF 4	
ABSY|C(1;Y)V25
DT|20 Apr 05
SYN|XYS.YLV25
ID|FBab0010422
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010423	CLA 1 Aberration	GSYM 1 C(1;Y)V36	DT 1 20 Apr 05	RESZ 885	REF 4	
ABSY|C(1;Y)V36
DT|20 Apr 05
SYN|XYS.YLV36
ID|FBab0010423
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010424	CLA 1 Aberration	GSYM 1 C(1;Y)V4	DT 1 20 Apr 05	RESZ 883	REF 4	
ABSY|C(1;Y)V4
DT|20 Apr 05
SYN|XYS.YLV4
ID|FBab0010424
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0010425	CLA 1 Aberration	GSYM 1 C(1;Y)W8	DT 1 20 Apr 05	RESZ 811	REF 4	
ABSY|C(1;Y)W8
DT|20 Apr 05
SYN|XYL.YSW8
ID|FBab0010425
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

DIS|Parker.
COR|This compound structure is a frequent
|product of X-Y translocation induced in X/Y sperm, at least
|when the Y is B<up>S</up>Yy<up>+</up> (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Y-chromosome breakpoint distal to @kl-5@.
|Essentially an intact Y chromosome with all of the X
|euchromatin appended distally to KL.
|XYL.Y.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KL.KS.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0028059	CLA 1 Aberration	GSYM 1 C(1;Y)X.FrYLd33a	DT 1 20 Apr 05	RESZ 432	REF 1	
ABSY|C(1;Y)X.FrYLd33a
DT|20 Apr 05
SYN|X.FrYLd33a
ID|FBab0028059
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|FLPase
PRG|C(1;Y;4)d7
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MU|FLPase
PRG|C(1;Y;4)d7
CCM|The most distal bright block on YL is missing in mitotic @C(1;Y)X.FrYLd33a@
|chromosomes.
SYN|X.FrYLd33a
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028060	CLA 1 Aberration	GSYM 1 C(1;Y)X.FrYLd5d	DT 1 20 Apr 05	RESZ 428	REF 1	
ABSY|C(1;Y)X.FrYLd5d
DT|20 Apr 05
SYN|X.FrYLd5d
ID|FBab0028060
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|FLPase
PRG|C(1;Y;4)d7
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MU|FLPase
PRG|C(1;Y;4)d7
CCM|The most distal bright block on YL is missing in mitotic @C(1;Y)X.FrYLd5d@
|chromosomes.
SYN|X.FrYLd5d
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022020	CLA 1 Aberration	GSYM 1 C(1;Y)XYSYL-B<up>S</up>	DT 1 20 Apr 05	RESZ 306	REF 1	
ABSY|C(1;Y)XYSYL-B<up>S</up>
DT|20 Apr 05
SYN|XYS.YLB<up>S</up>
ID|FBab0022020
REF
{
REFM|FBrf0034415
|Poodry
|1980
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
DIS|D. Lindsley.
REFDSR
{
RDID|FBrf0034415
|Poodry
|1980
DIS|D. Lindsley.
SYN|XYS.YLB<up>S</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010426	CLA 1 Aberration	GSYM 1 C(1;Y)Z14	DT 1 20 Apr 05	RESZ 885	REF 4	
ABSY|C(1;Y)Z14
DT|20 Apr 05
SYN|XYS.YLZ14
ID|FBab0010426
REF
{
REFM|FBrf0012016
|Parker and McCrone
|1958
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|segregation
COR|from translocation with one break in X heterochromatin
|and one distal to ks-2 in B<up>S</up>Yy+ (Kennison, 1981).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Essentially an intact @Dp(1;Y)y<up>+</up>@ chromosome with all of the X
|euchromatin appended distally to YS.
|XYS.YL.
OTH|Originally @y<up>2</up>@ @su(w<up>a</up>)<up>1</up>@ @w<up>a</up>@ (@bb@?) KS.KL @y@<up>+</up>.
|YL may carry any marker available on the long arm of marked Y
|chromosomes, e.g., @y@<up>+</up>, @B<up>S</up>@, etc.
PHP|male fertile
|male viable
}
# EOR
ABSR
{
RETE|ID 1 FBab0028064	CLA 1 Aberration	GSYM 1 C(1;Y;4)d7	DT 1 20 Apr 05	RESZ 671	REF 1	
ABSY|C(1;Y;4)d7
DT|20 Apr 05
SYN|C(1;YL)d7
|X.DcYL
ID|FBab0028064
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|X ray
PRG|DcY
AMDP|gvl
|ey
|sv
MK|sv<up>spa-Cat</up>
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MU|X ray
PRG|DcY
CCM|X-Y exchange placing YL and the chromosome 4 duplication of @DcY@ as
|a right arm of the X chromosome.
AMDP|gvl
|ey
|sv
MK|sv<up>spa-Cat</up>
TRNA|FBti0012180 == P{RS5}ZY2A
|FBti0012283 == P{RS5}ZY2B
SYN|C(1;YL)d7
|X.DcYL
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028061	CLA 1 Aberration	GSYM 1 C(1;Y;4)X.FrYL28m	DT 1 20 Apr 05	RESZ 509	CLOC 1 102D	REF 1	
ABSY|C(1;Y;4)X.FrYL28m
DT|20 Apr 05
SYN|X.FrYL28m
ID|FBab0028061
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

BPT|102D
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0101865)
MU|FLPase
PRG|C(1;Y;4)d7
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
BPT|102D
MU|FLPase
PRG|C(1;Y;4)d7
CCM|Shows a strong signal with a @HeT-A@ probe, and has therefore acquired
|@HeT-A@ telomeric sequences.
SYN|X.FrYL28m
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028062	CLA 1 Aberration	GSYM 1 C(1;Y;4)X.FrYLd26e	DT 1 20 Apr 05	RESZ 512	REF 1	
ABSY|C(1;Y;4)X.FrYLd26e
DT|20 Apr 05
SYN|X.FrYLd26e
ID|FBab0028062
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|FLPase
PRG|C(1;Y;4)d7
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MU|FLPase
PRG|C(1;Y;4)d7
PHP|There is a reduction in the rate of transmission of the @C(1;Y;4)X.FrYLd26e@
|chromosome, seen as a reduction in male progeny from an X/@C(1;Y;4)X.FrYLd26e@
|father.
SYN|X.FrYLd26e
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028063	CLA 1 Aberration	GSYM 1 C(1;Y;4)X.FrYLd34r	DT 1 20 Apr 05	RESZ 512	REF 1	
ABSY|C(1;Y;4)X.FrYLd34r
DT|20 Apr 05
SYN|X.FrYLd34r
ID|FBab0028063
REF
{
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
MU|FLPase
PRG|C(1;Y;4)d7
REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MU|FLPase
PRG|C(1;Y;4)d7
PHP|There is a reduction in the rate of transmission of the @C(1;Y;4)X.FrYLd34r@
|chromosome, seen as a reduction in male progeny from an X/@C(1;Y;4)X.FrYLd34r@
|father.
SYN|X.FrYLd34r
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010427	CLA 1 Aberration	GSYM 1 C(1;YL)1	DT 1 27 Nov 05	RESZ 1740	SK 12	REF 9	
ABSY|C(1;YL)1
DT|27 Nov 05
SYN|X.YL
|XY'
ID|FBab0010427
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0002602
|Kaufmann
|1933
|-1
REFM|FBrf0019413
|Frankel
|1968
|-1
REFM|FBrf0063415
|Erickson
|1968
|-1
REFM|FBrf0025041
|Frankel
|1973
|-1
REFM|FBrf0001472
|Stern
|1926
|-1
REFM|FBrf0001913
|Stern
|1929
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0141717
|Carvalho et al.
|2001
|-1
}

MU|recombination
COR|A recurrent product of exchange between
|the proximal heterochromatin of C(1)RM and either arm of the Y
|Also may result from exchange between YS and the proximal
|heterochromatin of a normal X or the interstitial
|heterochromatin of C(1)RA. Have also been recovered as one
|element of T(1;Y)'s induced in X/Y sperm with one break in
|YS and the other in X heterochromatin (Kennison, 1981,
|Genetics 98: 529-48). May be recovered with YL marked with
|various euchromatic markers, e.g., bw<up>+</up> (Erickson, 1968,
|D. I. S. 43: 63), y<up>+</up>, or B<up>S</up>.
CCM|Class relative to wildtype: Hetero-compound chromosome
|Chromosome V-shaped in metaphase.
|An X chromosome in normal sequence with YL appended as a
|second arm. May carry varying amounts of the proximal part
|of YS between the X and the centromere.
OTH|A series of X-ray-induced exchanges between X.YL and y<up>+</up>Y
|replacing YL with y<up>+</up>YL investigated by Frankel (1968, DIS
|43: 99; 1973, Genetics 74: 115-32).
PHP|Males carrying X.YL require KS in some form
|for fertility.
SK|FBst0004489
|C(1)RM, y[1]/C(1;YL)1, y[1] cv[1] v[1] f[1] car[1]/C(YS)1
|FBst0004481
|C(1;YL)1, In(1)dl-49, v[Of] f[1] B[1]/F(YS)1/C(1)DX, y[1] f[1]
|FBst0004482
|C(1;YL)1, In(1)sc[8L]sc[4R], y[31d] sc[-]/Dp(1;YL)sc[S1]/C(1)DX, y[1] f[1]
|FBst0002562
|C(1;YL)1, bb[+] ac[+] y[+]/C(1;YS)1, y[1] w[1] & C(1)DX, y[1] f[1]/0
|FBst0000701
|C(1;YL)1, g[2] B[1]/C(YS)* & C(1)RM, y[1]/C(YS)*
|FBst0005275
|C(1;YL)1, y[1] N[TA17V] l(1)7Ad[TA17V]/FM7c/Dp(1;Y)y[+]
|FBst0005276
|C(1;YL)1, y[1] WC1[WC1] Oce[WC1]/FM7c/Dp(1;Y)y[+]
|FBst0005277
|C(1;YL)1, y[1] cv[1] v[1] g[2] exd[S136]/FM7c
|FBst0005278
|C(1;YL)1, y[1] fs(1)h[TA54]/FM7c
|FBst0002559
|C(YS)2/C(1;YL)1, y[1] v[1] f[1] bb[-] & C(1)DX, y[1] f[1]/0
|FBst0004480
|Dp(1;YS)sc[V1]/C(1;YL)1, In(1)dl-49, y[1] v[Of] B[1]/C(1)DX, y[1] f[1]
|FBst0004473
|Dp(1;YS)sc[V1]/C(1;YL)1, y[1] w[1] v[1] f[1]; e[11]
SKC|12
}
# EOR
ABSR
{
RETE|ID 1 FBab0010428	CLA 1 Aberration	GSYM 1 C(1;YL)2	DT 1 20 Apr 05	RESZ 382	REF 1	
ABSY|C(1;YL)2
DT|20 Apr 05
SYN|X.YL, In(1)EN
ID|FBab0010428
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

MU|recombination
PRG|C(1;Y)1
|In(1)EN
COR|Single euchromatic recombination event
CCM|Class relative to wildtype: Hetero-compound chromosome
|X.YL, In(1)EN, y.KL
|An entirely inverted X chromosome with YL appended as a second arm.
BIP|1A;20F;20F (from In(1)EN)
}
# EOR
ABSR
{
RETE|ID 1 FBab0010429	CLA 1 Aberration	GSYM 1 C(1;YL)3	DT 1 20 Apr 05	RESZ 579	REF 2	
ABSY|C(1;YL)3
DT|20 Apr 05
SYN|Dp(1;Y;2)bw<up>+</up>
|X.bw<up>+</up>YL
ID|FBab0010429
REF
{
REFM|FBrf0063415
|Erickson
|1968
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

DIS|Erickson.
MU|spontaneous
PRG|Dp(2;Y)bw<up>+</up>
COR|in y v/Dp(2;Y)bw<up>+</up>; bw stock
CCM|Class relative to wildtype: Hetero-compound chromosome
|@bw@<up>+</up> - @bs@<up>+</up> inserted proximal to KL.
|X.(w<up>+</up>-ba<up>+</up>) KL. X chromosome with prominent YL as
|second arm.
OTH|X chromosome originally carried @y@ and @v@; Y arm carries YL
|fertility factors.
}
# EOR
ABSR
{
RETE|ID 1 FBab0010430	CLA 1 Aberration	GSYM 1 C(1;YL)4	DT 1 20 Apr 05	RESZ 361	REF 2	
ABSY|C(1;YL)4
DT|20 Apr 05
SYN|XYL
ID|FBab0010430
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
}

MU|detachment
COR|from XYL.X or XYL.YLX by interchange with small, free-X
|heterochromatic duplications, i.e., Dp(1;f).
CCM|Class relative to wildtype: Hetero-compound chromosome
}
# EOR
ABSR
{
RETE|ID 1 FBab0010431	CLA 1 Aberration	GSYM 1 C(1;YL)C2	DT 1 20 Apr 05	RESZ 685	SK 1	REF 3	
ABSY|C(1;YL)C2
DT|20 Apr 05
SYN|X.YLC2
ID|FBab0010431
REF
{
REFM|FBrf0040458
|Stone
|1984
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0008554
|Novitski
|1952
|-1
}

DIS|Lindsley.
MU|recombination
PRG|C(1)RM
|Y
COR|YS proximal to bb<up>+</up> and C(1)RM distal to bb<up>+</up>
CCM|Class relative to wildtype: Hetero-compound chromosome
|X.YL, bb<up>-</up> KL
AMD|bb
OAB|C(1;YL)C2/Dp(1;Y)y<up>+</up>mal<up>+</up> male sterile (Stone, 1984, Can. J. Genet. Cytol. 26: 67-77).
PHP|X.YLC2/0 lethal.
|Shows unique behavior in double, first anaphase bridges (Novitski,
|1952, Genetics 37: 270-87).
SK|FBst0003924
|C(1)RA, v[1] f[1]/C(1;YL)C2, y[1] cv[1] v[1] f[1] car[1] bb[-]/C(YS)1
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0029163	CLA 1 Inversion	GSYM 1 C(1;YL)w<up>mMc</up>	DT 1 27 Nov 05	RESZ 4366	CLOC 1 h1--h17	SK 1	REF 9	
ABSY|C(1;YL)w<up>mMc</up>
DT|27 Nov 05
SYN|w<up>mMc</up>
|In(1)w<up>mMc</up>
|white<up>mottled McLean</up>
|McT
ID|FBab0029163
REF
{
REFM|FBrf0093154
|Lloyd et al.
|1997
|-1
REFM|FBrf0107340
|Talbert and Henikoff
|1999
|-1
REFM|FBrf0125106
|Talbert and Henikoff
|2000.1.29
|-1
REFM|FBrf0049515
|Tartof et al.
|1989
|-1
REFM|FBrf0101109
|Talbert and Henikoff
|1998
|-1
REFM|FBrf0048198
|Locke et al.
|1988
|-1
REFM|FBrf0123212
|Talbert and Henikoff
|2000
|-1
REFM|FBrf0098841
|Martin-Morris et al.
|1997
|-1
REFM|FBrf0040503
|Tartof et al.
|1984
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|[3C1--3C2];[20F] (from In(1)w<up>mMc</up>)
BPT|h1--h17
ACLA|Inversion
PRG|In(1)w<up>mMc</up>
PED|position-effect variegation for: w
REFDSR
{
RDID|FBrf0040503
|Tartof et al.
|1984
ACLA|Inversion
PED|position-effect variegation for: w
PHP|Eyes have a "peppered" phenotype - flecks of dark brown pigmented ommatidia
|are scattered throughout the wild type surface of the eye.
OTH|The chromosome referred to as "w<up>mMc</up>" in this paper is actually
|@C(1;YL)w<up>mMc</up>@ (this chromosome is a descendent of @In(1)w<up>mMc</up>@ which
|carries an X.YL translocation - see FBrf0123212 and Talbert and
|Henikoff, 2000.1.29, personal communication).
SYN|w<up>mMc</up>
}

REFDSR
{
RDID|FBrf0048198
|Locke et al.
|1988
PED|position-effect variegation for: w
OTH|The chromosome referred to as "In(1)w<up>mMc</up>" in this paper is
|actually @C(1;YL)w<up>mMc</up>@ (this chromosome is a descendent of
|@In(1)w<up>mMc</up>@ which carries an X.YL translocation - see FBrf0123212
|and Talbert and Henikoff, 2000.1.29, personal communication).
SYN|In(1)w<up>mMc</up>
}

REFDSR
{
RDID|FBrf0049515
|Tartof et al.
|1989
OTH|The chromosome referred to as "In(1)w<up>mMc</up>" in this paper is
|actually @C(1;YL)w<up>mMc</up>@ (this chromosome is a descendent of
|@In(1)w<up>mMc</up>@ which carries an X.YL translocation - see FBrf0123212
|and Talbert and Henikoff, 2000.1.29, personal communication).
SYN|In(1)w<up>mMc</up>
}

REFDSR
{
RDID|FBrf0093154
|Lloyd et al.
|1997
OAB|The position effect variegation of @Sb@ caused by @T(2;3)Sb<up>V</up>@ is
|strongly suppressed by @C(1;YL)w<up>mMc</up>@ in both males and females. This
|interaction is both dominant and dosage sensitive; one copy of the
|@C(1;YL)w<up>mMc</up>@ chromosome is sufficient to suppress variegation of @Sb@
|caused by @T(2;3)Sb<up>V</up>@, however, two copies of @C(1;YL)w<up>mMc</up>@ produce
|slightly greater suppression than one copy. The @T(2;3)Sb<up>V</up>@ chromosome
|may have a slight suppressing effect on the variegation of @w@ caused
|by @C(1;YL)w<up>mMc</up>@ in males.
|@In(2R)bw<up>VDe2</up>@ and @C(1;YL)w<up>mMc</up>@ in combination show dominant suppression
|of variegation of one or both of @w@ and @bw@, as measured by eye pigment
|levels.
PED|position-effect variegation for: w
OTH|The chromosome referred to as "In(1)w<up>mMc</up>" in this paper is
|actually @C(1;YL)w<up>mMc</up>@ (this chromosome is a descendent of
|@In(1)w<up>mMc</up>@ which carries an X.YL translocation - see FBrf0123212
|and Talbert and Henikoff, 2000.1.29, personal communication).
SYN|In(1)w<up>mMc</up>
}

REFDSR
{
RDID|FBrf0098841
|Martin-Morris et al.
|1997
OTH|The chromosome referred to as "white<up>mottled McLean</up>" in this paper
|is actually @C(1;YL)w<up>mMc</up>@ (this chromosome is a descendent of
|@In(1)w<up>mMc</up>@ which carries an X.YL translocation - see FBrf0123212
|and Talbert and Henikoff, 2000.1.29, personal communication).
SYN|white<up>mottled McLean</up>
}

REFDSR
{
RDID|FBrf0123212
|Talbert and Henikoff
|2000
BPT|h1--h17
PRG|In(1)w<up>mMc</up>
CCM|X.YL translocation with the point of exchange in the rDNA.
OAB|@C(1;YL)w<up>mMc</up>@/0 ; @T(Y;3)A78@/+ males are fertile.
|Suppresses the @In(2R)bw<up>VDe2</up>@ pigmentation phenotype.
PED|position-effect variegation for: w
PHP|@C(1;YL)w<up>mMc</up>@/0 males are sterile.
SYN|McT
}

REFDSR
{
RDID|FBrf0125106
|Talbert and Henikoff
|2000.1.29
PRG|In(1)w<up>mMc</up>
}

SK|FBst0004478
|C(1;YL)w[mMc]/Y/C(1)DX, y[1] f[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010432	CLA 1 Aberration	GSYM 1 C(1;YS)1	DT 1 27 Nov 05	RESZ 1317	SK 13	REF 6	
ABSY|C(1;YS)1
DT|27 Nov 05
SYN|X.YS
ID|FBab0010432
REF
{
REFM|FBrf0141717
|Carvalho et al.
|2001
|-1
REFM|FBrf0127362
|Timakov and Zhang
|2000
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036525
|Kennison
|1981
|-1
REFM|FBrf0002602
|Kaufmann
|1933
|-1
REFM|FBrf0021831
|Janning
|1970
|-1
}

DIS|Kaufmann.
MU|spontaneous
|recombination
PRG|C(1)RM
|Y
COR|Recurrent product of recombination
|the proximal heterochromatin of C(1)RM and the Y
|Also recovered as one
|element of T(1;Y)'s induced in X/Y sperm with one break in
|YL and the other in X heterochromatin (Kennison, 1981,
|Genetics 98: 529-48).
CCM|Class relative to wildtype: Hetero-compound chromosome
|Chromosome J-shaped in metaphase [e.g., Janning, 1970, Mol. Gen. Genet. 107: 150-57 (fig.)].
|An X chromosome in normal sequence with YS appended as a
|second arm. May carry varying amounts of the proximal part
|of YL between X and the centromere.
PHP|Males carrying X.YS require KL in
|some form for fertility.
REFDSR
{
RDID|FBrf0127362
|Timakov and Zhang
|2000
PHP|@C(1;YS)1@/Y males produce a similar number of progeny as X/Y males.
SYN|X.YS
}

SK|FBst0004093
|C(1)RM, In(1)dl-49, y[1] ct[l] sn[X2]: y[1] ct[n] oc[1] ptg[1] car[1]/R(YL)/C(1;YS)1, oc[1] ptg[1]
|FBst0004488
|C(1)RM, sc[1] v[1] f[1]/C(1;YS)1, f[1]/Df(YS)st
|FBst0003969
|C(1)RM, y[1] v[1] f[1]/R(YL)/C(1;YS)1
|FBst0002562
|C(1;YL)1, bb[+] ac[+] y[+]/C(1;YS)1, y[1] w[1] & C(1)DX, y[1] f[1]/0
|FBst0000703
|C(1;YS)1, Df(1)y-ac, w[a] ct[6] f[1]/Dp(1;YL)sc[S1]/C(1)DX, y[1] f[1]
|FBst0004452
|C(1;YS)1, In(1)dl-49, y[1] v[Of] f[1]/Dp(1;YL)sc[S1]
|FBst0004476
|Dp(1;YL)sc[S1]; C(1;YS)1, T(1;4)B[S], B[S]/C(1)DX, y[1] w[1] f[1]
|FBst0003962
|In(1)B[M1], y[2] oc[1] ptg[1] B[M1]/Insc, fu[1]/R(YL)/C(1;YS)1, y[2] oc[1] ptg[1] fu[1]
|FBst0003966
|In(1)dl-49, In(1)B[M1], oc[1] ptg[1] B[M1]/In(1)sc[S1L]sc[8R], y[c4] sc[8] sc[S1] w[1] sn[X2] sl[1]/R(YL)/C(1;YS)1, y[1] sn[1] oc[1] ptg[1] v[1]
|FBst0003963
|In(1)dl-49, Sxl[f1] v[Of] g[4]/R(YL)/C(1;YS)1, oc[1] ptg[1]
|FBst0003756
|In(1)sc[S1], In(1)S, sc[S1] B[1]/C(1;YS)1, In(1)dl-49, y[1] l(1)ml[1] w[1] f[1]
|FBst0003970
|R(YL)/C(1;YS)1, w[1]
|FBst0000710
|R(YL)/C(1;YS)1, y[1] w[1]
SKC|13
}
# EOR
ABSR
{
RETE|ID 1 FBab0010433	CLA 1 Aberration	GSYM 1 C(1;YS)2	DT 1 20 Apr 05	RESZ 692	REF 2	
ABSY|C(1;YS)2
DT|20 Apr 05
SYN|X.YS, Basc
ID|FBab0010433
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0022256
|Ehrlich
|1971
|-1
}

DIS|Ehrlich.
MU|X ray
|detachment
PRG|C(1)RM, In(1)sc<up>S1L</up>sc<up>8R</up>+S, w<up>a</up>
|Dp(1;Y)1E
COR|recovered from female
CCM|Class relative to wildtype: Hetero-compound chromosome
|X.YS, In(1)sc<up>S1L</up>sc<up>8R</up>+S, y<up>31d</up> sc<up>S1</up> sc<up>8</up> w<up>a</up> B . y
|sc<up>+</up>.
OAB|C(1;YS)2/Y male viable
|C(1;YS)2/Y male fertile
|C(1;YS)2/Dp(1;Y)1E male lethal
BIP|[<2B6];[>1E4] (from Dp(1;Y)1E)
PHP|homozygous females viable
|homozygous females fertile
|Suppresses crossing over in X.
}
# EOR
ABSR
{
RETE|ID 1 FBab0010434	CLA 1 Aberration	GSYM 1 C(1;YS)3	DT 1 27 Nov 05	RESZ 674	SK 5	REF 4	
ABSY|C(1;YS)3
DT|27 Nov 05
SYN|FR1
|Fragment 1
|YSX
ID|FBab0010434
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0012642
|Lindsley and Novitski
|1959
|-1
REFM|FBrf0021831
|Janning
|1970
|-1
REFM|FBrf0008554
|Novitski
|1952
|-1
}

DIS|Novitski.
MU|spontaneous
PRG|YSX.YL, In(1)EN, KS y.KL/sc cv v f
CCM|Class relative to wildtype: Hetero-compound chromosome
|An X in normal sequence marked with @y@ and with YS appended
|distal to @pch@<up>+</up>.
|YSX.
OTH|Originally KS @y<up>1</up>@ @cv<up>1</up>@ @v<up>1</up>@
|@f<up>1</up>@ (Braver).
PHP|Reduces crossing over near y.
SK|FBst0002546
|C(1;YS)3, B[S], y[1] cv[1] v[1] f[1]/R(YL) & C(1)RM, y[1] v[1] f[1]/R(YL)
|FBst0001311
|C(1;YS)3, T(1;Y)W16, cv[1] v[1] f[1]: y[+] B[S]/FM7a
|FBst0001427
|C(1;YS)3, y[1] cv[1] v[1] f[1]/C(1)DX, y[1] f[1]
|FBst0002560
|C(1;YS)3, y[1] m[1] f[1] car[1]/R(YL)bb[+]
|FBst0004331
|Dp(1;Y)B[S]y[31d]/C(1)DX, y[1] w[1] f[1]/C(1;YS)3, y[1] cv[1] v[1] f[1]
SKC|5
}
# EOR
ABSR
{
RETE|ID 1 FBab0010435	CLA 1 Aberration	GSYM 1 C(1;YS)4	DT 1 20 Apr 05	RESZ 547	REF 2	
ABSY|C(1;YS)4
DT|20 Apr 05
SYN|YSX, In(1)FM7
ID|FBab0010435
REF
{
REFM|FBrf0026093
|Craymer
|1974
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

MU|X ray
|recombination
|detachment
PRG|C(1)M4
|Dp(1;Y)B<up>S</up>Yy<up>+</up>
COR|exchange between interstitial heterochromatin of C(1)M4 with the short arm of B<up>S</up>Yy<up>+</up>
CCM|Class relative to wildtype: Hetero-compound chromosome
|YSX, In(1)FM7, @y@<up>+</up> KS @y@<up>-</up> @w<up>a</up>@ @v<up>Of</up>@.
MK|y<up>+</up> y<up>1</up> w<up>a</up> v<up>Of</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0010394	CLA 1 Aberration	GSYM 1 C(1;YS)5	DT 1 27 Nov 05	RESZ 1427	REF 5	
ABSY|C(1;YS)5
DT|27 Nov 05
SYN|YSX, In(1)sc<up>8</up>
|sc<up>8</up> c.o. X
ID|FBab0010394
REF
{
REFM|FBrf0004909
|Sidorov
|1940
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0005329
|Sidorov
|1941
|-1
REFM|FBrf0025662
|Ritossa
|1973
|-1
REFM|FBrf0010215
|Lindsley
|1955
|-1
}

DIS|Sidorov.
MU|recombination \spermatogonial
PRG|In(1)sc<up>8</up>
|Y
COR|Infrequent product of spermatogonial exchange between
|YS and the distal inverted heterochromatic segment of In(1)sc<up>8</up>.
|The incidence of recovery increased twenty-fold in genotypes undergoing
|ribosomal DNA magnification [e.g., In(1)sc<up>8</up>, bb<up>l</up>
|sc<up>8</up>/Ybb], but decreasing with successive generations of
|magnification (Ritossa, 1973).
|Deficiency recovered in single crossover between @In(1)sc<up>8</up>@ and
|@In(1)EN@, i.e., 'In(1)sc<up>8L</up>EN<up>R</up>'.
CCM|Class relative to wildtype: Hetero-compound chromosome
|Resembles In(1)sc<up>8</up> in mitotic prophase.
|@In(1)sc<up>8</up>@ with the distal uninverted euchromatic region
|carrying the normal alleles of @pch@ through @ac@ replaced by KS.
|YSX, In(1)sc<up>8</up>, KS [pch-ac]<up>-</up> sc<up>8</up>.
AMD|pch
|ac
MK|sc<up>8</up>
BIP|1B2;h32 (from In(1)sc<up>8</up>)
}
# EOR
ABSR
{
RETE|ID 1 FBab0027950	CLA 1 Aberration	GSYM 1 C(1;YS)6	DT 1 20 Apr 05	RESZ 405	SK 3	REF 1	
ABSY|C(1;YS)6
DT|20 Apr 05
ID|FBab0027950
REF
{
REFM|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|1A3--4;19F--20A;20F (from In(1)EN2)
PRG|In(1)EN2
REFDSR
{
RDID|FBrf0100324
|Bloomington Drosophila Stock Center
|1998.1.9
PRG|In(1)EN2
CCM|In(1)EN2<up>.</up>YS.
}

SK|FBst0003959
|C(1)RM, sc[1] v[1] f[1]/R(YL)/C(1;YS)6, In(1)EN2, w[1] oc[1] ptg[1] f[1]
|FBst0003934
|C(1)RM, y[2] su(w[a])[1] w[a] bb[-]/R(YL)/C(1;YS)6, In(1)EN2, oc[1] ptg[1] f[1]
|FBst0001392
|C(1;YS)6, In(1)EN2, oc[1] ptg[1] f[1]/R(YL)/C(1)RM, y[2] su(w[a])[1] w[a]
SKC|3
}
# EOR
ABSR
{
RETE|ID 1 FBab0029236	CLA 1 Aberration	GSYM 1 C(1;YS)bb<up>l-3a</up>	DT 1 20 Apr 05	RESZ 330	REF 1	
ABSY|C(1;YS)bb<up>l-3a</up>
DT|20 Apr 05
ID|FBab0029236
REF
{
REFM|FBrf0128883
|Agudo et al.
|2000
|-1
}

CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|[16A1--h32];[>h26] (from Df(1)bb3a)
PRG|Df(1)bb3a
REFDSR
{
RDID|FBrf0128883
|Agudo et al.
|2000
PRG|Df(1)bb3a
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027551	CLA 1 Aberration	GSYM 1 C(1;YS)P0	DT 1 27 Nov 05	RESZ 667	CLOC 1 h18--h25B	REF 1	
ABSY|C(1;YS)P0
DT|27 Nov 05
SYN|YSX<up>.</up>P0
ID|FBab0027551
REF
{
REFM|FBrf0099368
|Lindsley
|1997.10.13
|-1
}

BPT|h18--h25B
CCM|Class relative to wildtype: Hetero-compound chromosome
|All limits from polytene analysis (FBrf0099368)
PRG|In(1)sc<up>8L</up>EN<up>R</up>
COR|Resulted from an exchange between YS and the distal heterochromatin of @In(1)sc<up>8L</up>EN<up>R</up>@.
REFDSR
{
RDID|FBrf0099368
|Lindsley
|1997.10.13
BPT|h18--h25B
PRG|In(1)sc<up>8L</up>EN<up>R</up>
COR|Resulted from an exchange between YS and the distal heterochromatin of @In(1)sc<up>8L</up>EN<up>R</up>@.
SYN|YSX<up>.</up>P0
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000106	CLA 1 Aberration	NAM 1 Compound (2) ENtire	GSYM 1 C(2)EN	DT 1 27 Nov 05	RESZ 7517	ALESR 7	SK 10	REF 21	
ABSY|C(2)EN
DT|27 Nov 05
NAM|Compound (2) ENtire
ID|FBab0000106
REF
{
REFM|FBrf0064721
|Sullivan et al.
|1993
|-1
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
REFM|FBrf0028334
|Novitski
|1976
|-1
REFM|FBrf0089628
|Dernburg et al.
|1996
|-1
REFM|FBrf0135801
|Tomkiel
|2000
|-1
REFM|FBrf0089627
|Dernburg et al.
|1996
|-1
REFM|FBrf0094717
|Fedorova et al.
|1997
|-1
REFM|FBrf0182700
|D'Amours and Amon
|2004
|-1
REFM|FBrf0098399
|Fedorova and Omelyanchuk
|1997
|-1
REFM|FBrf0030167
|Robbins
|1977
|-1
REFM|FBrf0131432
|Yu et al.
|2000
|-1
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0138260
|Stapleton et al.
|2001
|-1
REFM|FBrf0039404
|Falk
|1983
|-1
REFM|FBrf0049924
|Brittnacher and Ganetzky
|1989
|-1
REFM|FBrf0082182
|Jang et al.
|1995
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0109513
|Coelho and Sunkel
|1999
|-1
REFM|FBrf0038444
|Strommen
|1982
|-1
REFM|FBrf0053960
|Gonzalez et al.
|1991
|-1
REFM|FBrf0040572
|Goldstein et al.
|1984
|-1
}

COR|Synthesized by first selecting a T(Y;2) with a break in YL
|of B<up>S</up>Yy<up>+</up> and an absolutely terminal break in 2L and next
|transferring the terminal YL to C(2L)RM by recombination in
|a Dp(Y;2)/C(2L)RM/C(2R)RM triploid; the terminal YL was
|homozygosed to produce C(2LYL)RM, B<up>S</up>. Irradiated
|C(2LYL)RM, B<up>S</up>/C(2R) females were crossed to C(2L);
|F(2R)/F(2R) males; this cross selects for progeny that
|receive C(2LYL)RM, B<up>S</up> plus a single copy of 2R from their
|mothers; those with wider Bar eyes are putative results of a
|translocation between the base of 2R from C(2R)RM and a
|terminal YL of C(2LYL)RM and the surviving offspring are
|YL2L.2L2R/F(2R); crosses of females of this constitution to
|C(2L)RM; C(2R)RM have yielded C(2)EN-bearing progeny as a
|consequence of fertilization of an ovum that has received a
|derivative homozygous (non B<up>S</up>) for the 2L2R arm of the
|compound and no F(2R) by a nullo-2 sperm. In situ
|hybridization with a telomeric probe reveals the presence of
|telomeric sequences at the junction between 2L and 2R
|(Goldstein, Berry and Novitski, 1984, D. I. S. 60: 117).
CCM|Class relative to wildtype: Homo-compound chromosome
|C(2)EN, 2R2L - 2L2R.
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
PHP|Provides all of chromosome 2 necessary for normal
|development. C(2)EN-bearing flies produce two types of
|meiotic products with respect to chromosome 2; half disomic
|and half nullosomic. Accordingly crosses to normal diploids
|produce mainly inviable mono- and triplo-2 zygotes; however
|crosses of C(2)EN flies to each other produce progeny.
|Transmission of C(2)EN by males versus that from females
|varies from about 30% to very low values (see also Robbins,
|1977, Genetics 87: 67-81). This is attributed to zygote
|mortality by Novitski et al.; however, it may be reflected
|in defects in spermatogenesis as seen in cross sections of
|bundles of elongated sperm tails. Male transmission ratio is
|sensitive to the particular Y chromosome present (Strommen,
|1982, Mol. Gen. Genet. 187: 126-31). Sex-chromosome
|disjunction in both sexes influenced by C(2)EN (Falk, 1982,
|Genet. Res. 41: 17-28); in XY/0 males the XY segregates
|preferentially from the compound; in X/Y males and X/X
|females, sex chromosome nondisjunction is elevated with the
|sex chromosomes segregating preferentially away from C(2)EN.
|In general, C(2)EN-bearing flies perform poorly in stocks
|and crosses.
REFDSR
{
RDID|FBrf0038444
|Strommen
|1982
OTH|Genetic analysis demonstrates that the sex chromosome of the male directly
|correlates with the proportion of successful sperm carrying the C(2)EN
|chromosome: the information on the Y chromosome influences the rate
|of C(2)EN transmission in the male.
}

REFDSR
{
RDID|FBrf0064721
|Sullivan et al.
|1993
OTH|Chromosome does not increase the error frequency of the late larva
|neuroblast divisions. In the syncytial embryonic nuclear divisions,
|the chromosome produces a 10-fold increase in division errors relative
|to embryos with a normal karotype.
}

REFDSR
{
RDID|FBrf0082182
|Jang et al.
|1995
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A study of metaphase arrest found that crossovers between homologs
|attached to the same centromere do not induce metaphase arrest. Hence
|exchanges induce metaphase arrest only when they physically conjoin
|two separate kinetochores. The signal that mediates metaphase arrest
|is not the exchange event per se, but the resulting tension on homologous
|kinetochores.
}

REFDSR
{
RDID|FBrf0089628
|Dernburg et al.
|1996
PHP|Distortion in paternal transmission of @C(2)EN@ is established before
|fertilization. @C(2)EN@-bearing sperm are selectively lost after sperm
|transfer to the female and before storage of sperm in the seminal receptacles
|and spermathecae. This is consistent with a model of meiotic drive
|in which aberrations occurring early in meiosis lead ultimately to
|sperm dysfunction.
}

BGV
{
BGVSY|C(2)EN-vNa
SYN|C(2)EN, b bw
ID|FBba0000077
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MK|b<up>1</up> bw<up>1</up>
}

}

BGV
{
BGVSY|C(2)EN-vNb
SYN|C(2)EN, bw sp
|C(2)EN<up>bw sp</up>
ID|FBba0000078
REF|FBrf0089628
|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MK|bw<up>1</up> sp<up>1</up>
}

REFDSR
{
RDID|FBrf0089628
|Dernburg et al.
|1996
SYN|C(2)EN<up>bw sp</up>
MK|bw<up>1</up> sp<up>1</up>
}

}

BGV
{
BGVSY|C(2)EN-vNc
SYN|C(2)EN, c bw
ID|FBba0000079
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MK|c<up>1</up> bw<up>1</up>
}

}

BGV
{
BGVSY|C(2)EN-vNd
SYN|C(2)EN, sp
ID|FBba0000080
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MK|sp<up>1</up>
}

}

BGV
{
BGVSY|C(2)EN-S28<up>+</up>
SYN|C(2)EN S28, +
|C(2)EN-S28, +
ID|FBba0000081
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
SYN|C(2)EN S28, +
}

}

BGV
{
BGVSY|C(2)EN<up>+</up>
SYN|C(2)EN, +
ID|FBba0000155
REF|FBrf0089628
REFDSR
{
RDID|FBrf0089628
|Dernburg et al.
|1996
SYN|C(2)EN<up>+</up>
}

}

BGV
{
BGVSY|C(2)EN-vDa
SYN|C(2)EN, b pr
|C(2)EN<up>b pr</up>
ID|FBba0000156
REF|FBrf0089628
REFDSR
{
RDID|FBrf0089628
|Dernburg et al.
|1996
MK|b<up>*</up> pr<up>*</up>
SYN|C(2)EN<up>b pr</up>
}

}

SK|FBst0002974
|C(2)EN
|FBst0001113
|C(2)EN, b[1] bw[1]; st[1]
|FBst0001112
|C(2)EN, b[1] pr[1]
|FBst0001020
|C(2)EN, bw[1] sp[1]
|FBst0001109
|FBst0001109
|FBst0001116
|C(2)EN, bw[1]; ru[1]
|FBst0001370
|C(2)EN, c[1] bw[1]
|FBst0001118
|C(2)EN, c[1] bw[1]; C(3L)RM-*, h[2]; C(3R)RM-*
|FBst0001021
|Dp(1;Y)B[S]Yy[+]/+; C(2)EN
|FBst0001111
|Dp(1;Y)B[S]Yy[+]/+; C(2)EN, bw[1] sp[1]
SKC|10
}
# EOR
ABSR
{
RETE|ID 1 FBab0022021	CLA 1 Aberration	GSYM 1 C(2)v	DT 1 27 Nov 05	RESZ 316	REF 3	
ABSY|C(2)v
DT|27 Nov 05
ID|FBab0022021
REF
{
REFM|FBrf0086407
|Francis-Lang et al.
|1996
|-1
REFM|FBrf0146973
|Lecuit et al.
|2002
|-1
REFM|FBrf0056104
|Rose and Wieschaus
|1992
|-1
}

CCM|Class relative to wildtype: Homo-compound chromosome
}
# EOR
ABSR
{
RETE|ID 1 FBab0000107	CLA 1 Aberration	NAM 1 Compound (2;3) ENtire	GSYM 1 C(2;3)EN	DT 1 20 Apr 05	RESZ 979	SK 1	REF 2	
ABSY|C(2;3)EN
DT|20 Apr 05
NAM|Compound (2;3) ENtire
ID|FBab0000107
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|irradiation
PRG|C(2)EN
|C(3L3R.)
COR|recovered from female
|Recovered as a translocation involving the centric
|heterochromatin of both elements resulting in the
|replacement of one arm of C(2)EN with 3R3L.
CCM|Class relative to wildtype: Hetero-compound chromosome
|EN, 2R2L.3L3R
|Carries a complete haploid set of the large autosomes
|attached to a single centromere.
PHP|Transmission by
|heterozygous females is reduced by nonrandom disjunction of
|heteromorphic dyads resulting from exchange between the
|compound and a normal homologue, but it is high if
|recombination is suppressed by homologous inversions.
|Transmission by heterozygous males is low.
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MU|irradiation
PRG|C(2)EN
|C(3L3R.)
}

SK|FBst0004065
|C(2;3)EN
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000108	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2L)CN10	DT 1 20 Apr 05	RESZ 338	REF 2	
ABSY|C(2L)CN10
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000108
REF
{
REFM|FBrf0039521
|Nishimura and Gethmann
|1983
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
OTH|complex contains Y fertility genes and bw<up>+</up> and sp<up>+</up> from 2R
}
# EOR
ABSR
{
RETE|ID 1 FBab0023387	CLA 1 Aberration	GSYM 1 C(2L)RM-B<up>S</up>	DT 1 20 Apr 05	RESZ 382	REF 1	
ABSY|C(2L)RM-B<up>S</up>
DT|20 Apr 05
SYN|C(2LYL)RM, B<up>S</up>
ID|FBab0023387
REF
{
REFM|FBrf0028334
|Novitski
|1976
|-1
}

MU|recombination \in triploid
PRG|C(2L)RM
|Dp(1;2)B<up>S</up>
CCM|Class relative to wildtype: Compound chromosome arm
BIP|[<16A1];[>16A1] (from Dp(1;2)B<up>S</up>)
OTH|An intermediate in the synthesis of @C(2)EN@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0022022	CLA 1 Aberration	GSYM 1 C(2L)RM-C3	DT 1 20 Apr 05	RESZ 748	CLOC 1 40D--E;41A	REF 3	
ABSY|C(2L)RM-C3
DT|20 Apr 05
SYN|C(2L)C3
ID|FBab0022022
REF
{
REFM|FBrf0178882
|Roote
|2004.6.24
|-1
REFM|FBrf0082537
|Roote
|1995.9.6
|-1
REFM|FBrf0053501
|Gubb et al.
|1991
|-1
}

BPT|40D--E;41A
CCM|Class relative to wildtype: Compound chromosome arm
|All limits from polytene analysis (FBrf0053501)
DIS|D. Gubb.
MU|&ggr; ray
COR|b pr pk<up>sple-1</up>
MK|b<up>1</up> pr<up>1</up>
REFDSR
{
RDID|FBrf0053501
|Gubb et al.
|1991
BPT|40D--E;41A
NCO|2Lt - 40D | 41A - 2Lt
DIS|D. Gubb.
MU|&ggr; ray
COR|b pr pk<up>sple-1</up>
MK|b<up>1</up> pr<up>1</up>
SYN|C(2L)C3
}

REFDSR
{
RDID|FBrf0178882
|Roote
|2004.6.24
BPT|40D--40E;41A
NCO|2Lt - 41A | 40D - 2Lt
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000109	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2L)RM-LS1	DT 1 20 Apr 05	RESZ 301	REF 2	
ABSY|C(2L)RM-LS1
DT|20 Apr 05
SYN|C(2L)RM, b pr
NAM|Compound (Autosomal arm)
ID|FBab0000109
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|b<up>1</up> pr<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000111	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Pasadena	GSYM 1 C(2L)RM-P1	DT 1 20 Apr 05	RESZ 1116	SK 3	REF 5	
ABSY|C(2L)RM-P1
DT|20 Apr 05
SYN|C(2L)P, b
|C(2L)RM,b
|C(2L)RM-P, b
NAM|Compound (Autosomal arm) Pasadena
ID|FBab0000111
REF
{
REFM|FBrf0053577
|Ponimaskin and Omel'ianchuk
|1991
|-1
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
REFM|FBrf0053579
|Ponimaskin and Omel'ianchuk
|1991
|-1
}

DIS|E.B. Lewis.
CCM|Class relative to wildtype: Compound chromosome arm
MK|b<up>1</up>
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2L)P, b
}

REFDSR
{
RDID|FBrf0053577
|Ponimaskin and Omel'ianchuk
|1991
SYN|C(2L)RM,b
}

REFDSR
{
RDID|FBrf0053579
|Ponimaskin and Omel'ianchuk
|1991
SYN|C(2L)RM,b
}

SK|FBst0003982
|C(2L)RM-P1, b[1]/C(2R)RM-S1, cn[1]
|FBst0000713
|C(2L)RM-P1, b[1]; C(2R)RM-P4, px[1]
|FBst0001621
|C(2L)RM-P1, b[1]; C(2R)RM-SKIA, cn[1] bw[1]
SKC|3
}
# EOR
ABSR
{
RETE|ID 1 FBab0000112	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Pasadena	GSYM 1 C(2L)RM-P2	DT 1 20 Apr 05	RESZ 636	SK 2	REF 4	
ABSY|C(2L)RM-P2
DT|20 Apr 05
SYN|C(2L)RM,dp
|C(2L)RM, dp
|C(2L)#4 \?
|C(2L)RM-P, dp
NAM|Compound (Autosomal arm) Pasadena
ID|FBab0000112
REF
{
REFM|FBrf0053577
|Ponimaskin and Omel'ianchuk
|1991
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0086978
|Coyne
|1996
|-1
REFM|FBrf0027487
|Hardy
|1975
|-1
}

DIS|E.B. Lewis.
CCM|Class relative to wildtype: Compound chromosome arm
MK|dp<up>ov1</up>
REFDSR
{
RDID|FBrf0053577
|Ponimaskin and Omel'ianchuk
|1991
SYN|C(2L)RM,dp
}

REFDSR
{
RDID|FBrf0086978
|Coyne
|1996
SYN|C(2L)RM, dp
}

SK|FBst0000716
|C(2L)RM-P2, dp[ov1]; C(2R)RM-P4, px[1]
|FBst0002707
|y[1]; C(2L)RM-P2, dp[ov1]; F(2R)1, bw[1]
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0000110	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2L)RM-P3	DT 1 20 Apr 05	RESZ 386	SK 1	REF 3	
ABSY|C(2L)RM-P3
DT|20 Apr 05
SYN|C(2L)RM, j
NAM|Compound (Autosomal arm)
ID|FBab0000110
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|j<up>63</up>
SK|FBst0000715
|C(2L)RM-P3, j[63]; C(2R)RM-P4, px[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0023388	CLA 1 Aberration	GSYM 1 C(2L)RM-P4	DT 1 20 Apr 05	RESZ 235	SK 1	REF 1	
ABSY|C(2L)RM-P4
DT|20 Apr 05
SYN|C(2L)P3
ID|FBab0023388
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|+
SK|FBst0004044
|Dp(1;Y)B[S]; C(2L)RM-P4/C(2R)RM-P4
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000113	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2L)RM-SD72	DT 1 20 Apr 05	RESZ 410	REF 3	
ABSY|C(2L)RM-SD72
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000113
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
}

NCO|2Lt - 42A10 | 39D3 - 2Lt
COR|induced in In(2LR)SD72;
CCM|Class relative to wildtype: Compound chromosome arm
PHP|80% segregation from C(2R)RM-SD72 in males
}
# EOR
ABSR
{
RETE|ID 1 FBab0000114	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Storrs	GSYM 1 C(2L)RM-SH1	DT 1 20 Apr 05	RESZ 1646	REF 8	
ABSY|C(2L)RM-SH1
DT|20 Apr 05
SYN|C(2L)SH1
|C(2L)SH1,Dup(2R)rl<up>+</up>
|C(2L)SHI
NAM|Compound (Autosomal arm) Storrs
ID|FBab0000114
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0056363
|Ghosh and Mukherjee
|1992
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
REFM|FBrf0055754
|Bhadra et al.
|1992
|-1
REFM|FBrf0051455
|Ghosh and Mukherjee
|1990
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
AMDP|rl
OAB|Euploid in combination with @C(2R)RM-SH3@.
PHP|segregates randomly in males
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
CCM|Carries a section of proximal 2R including @rl@<up>+</up>.
OAB|Euploid in combination with @C(2R)RM-SH3@.
SYN|C(2L)SH1
|C(2L)SH1,Dup(2R)rl<up>+</up>
}

REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2L)SH1
}

REFDSR
{
RDID|FBrf0051455
|Ghosh and Mukherjee
|1990
SYN|C(2L)SHI
}

REFDSR
{
RDID|FBrf0055754
|Bhadra et al.
|1992
SYN|C(2L)SHI
}

REFDSR
{
RDID|FBrf0056363
|Ghosh and Mukherjee
|1992
SYN|C(2L)SHI
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000115	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Storrs	GSYM 1 C(2L)RM-SH3	DT 1 20 Apr 05	RESZ 1288	REF 6	
ABSY|C(2L)RM-SH3
DT|20 Apr 05
SYN|C(2L)SH3
|C(2L)RM-SH3, +
NAM|Compound (Autosomal arm) Storrs
ID|FBab0000115
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0048206
|Gubb et al.
|1988
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
OAB|Euploid in combination with @C(2R)RM-SH3@ or @C(2R)RM-VK2@.
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
OAB|Euploid in combination with @C(2R)RM-SH3@ or @C(2R)RM-VK2@.
OTH|@C(2L)RM-SH3@ is an isochromosome for 2L free of a duplication for
|2R genetic loci.
SYN|C(2L)SH3
}

REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2L)SH3
}

REFDSR
{
RDID|FBrf0048206
|Gubb et al.
|1988
SYN|C(2L)SH3
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022023	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Vancouver	GSYM 1 C(2L)RM-V12	DT 1 20 Apr 05	RESZ 620	REF 1	
ABSY|C(2L)RM-V12
DT|20 Apr 05
SYN|C(2L)V12
NAM|Compound (Autosomal arm) Vancouver
ID|FBab0022023
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022024	CLA 1 Aberration	GSYM 1 C(2L)RM-V43	DT 1 20 Apr 05	RESZ 582	REF 1	
ABSY|C(2L)RM-V43
DT|20 Apr 05
SYN|C(2L)V43
ID|FBab0022024
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000116	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Vancouver	GSYM 1 C(2L)RM-VH1	DT 1 20 Apr 05	RESZ 808	REF 3	
ABSY|C(2L)RM-VH1
DT|20 Apr 05
SYN|C(2L)VH1
|C(2L)RM-VH1, lt
NAM|Compound (Autosomal arm) Vancouver
ID|FBab0000116
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|rl<up>+</up> lt<up>1</up>
PHP|segregates randomly in males
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2L)VH1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000117	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Vancouver	GSYM 1 C(2L)RM-VH2	DT 1 20 Apr 05	RESZ 234	REF 1	
ABSY|C(2L)RM-VH2
DT|20 Apr 05
SYN|C(2L)RM-VH2, lt
NAM|Compound (Autosomal arm) Vancouver
ID|FBab0000117
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|lt<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000118	CLA 1 Aberration	NAM 1 Compound (Autosomal arm) Vancouver	GSYM 1 C(2L)RM-VT1	DT 1 20 Apr 05	RESZ 238	REF 1	
ABSY|C(2L)RM-VT1
DT|20 Apr 05
SYN|C(2L)RM-VT1, ho
NAM|Compound (Autosomal arm) Vancouver
ID|FBab0000118
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|dpp<up>d-ho</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0023962	CLA 1 Aberration	GSYM 1 C(2L)TY1	DT 1 20 Apr 05	RESZ 386	REF 1	
ABSY|C(2L)TY1
DT|20 Apr 05
ID|FBab0023962
REF
{
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|b<up>1</up> pr<up>1</up>
OAB|Euploid in combination with @C(2R)Pl@.
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
MK|b<up>1</up> pr<up>1</up>
OAB|Euploid in combination with @C(2R)Pl@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023389	CLA 1 Aberration	GSYM 1 C(2L.2L2R)B<up>S</up>	DT 1 20 Apr 05	RESZ 373	REF 2	
ABSY|C(2L.2L2R)B<up>S</up>
DT|20 Apr 05
SYN|YL2L.2L2R
ID|FBab0023389
REF
{
REFM|FBrf0028334
|Novitski
|1976
|-1
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|X ray
PRG|C(2L)RM, B<up>S</up>
|C(2R)RM
CCM|Class relative to wildtype: Compound chromosome arm
OTH|An intermediate in the synthesis of @C(2)EN@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0010436	CLA 1 Aberration	GSYM 1 C(2L.2R2L)	DT 1 20 Apr 05	RESZ 370	REF 1	
ABSY|C(2L.2R2L)
DT|20 Apr 05
ID|FBab0010436
REF
{
REFM|FBrf0035649
|Holm et al.
|1980
|-1
}

MU|recombination
PRG|T(2;4)lt<up>m3</up>
COR|synthesized by exchange between a standard sequence chromosome 2 and In(2LR)lt<up>m3</up>.
CCM|Class relative to wildtype: Compound chromosome arm
BIP|h37;60D;102F (from T(2;4)lt<up>m3</up>)
}
# EOR
ABSR
{
RETE|ID 1 FBab0023963	CLA 1 Aberration	GSYM 1 C(2R)Pl	DT 1 20 Apr 05	RESZ 363	REF 1	
ABSY|C(2R)Pl
DT|20 Apr 05
ID|FBab0023963
REF
{
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|px<up>1</up>
OAB|Euploid in combination with @C(2L)TY1@.
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
MK|px<up>1</up>
OAB|Euploid in combination with @C(2L)TY1@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000119	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-1	DT 1 20 Apr 05	RESZ 206	REF 1	
ABSY|C(2R)RM-1
DT|20 Apr 05
SYN|C(2R)RM, +
NAM|Compound (Autosomal arm)
ID|FBab0000119
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0022025	CLA 1 Aberration	GSYM 1 C(2R)RM-C1	DT 1 20 Apr 05	RESZ 533	CLOC 1 40D--E;41A	REF 2	
ABSY|C(2R)RM-C1
DT|20 Apr 05
SYN|C(2R)C1
ID|FBab0022025
REF
{
REFM|FBrf0082537
|Roote
|1995.9.6
|-1
REFM|FBrf0053501
|Gubb et al.
|1991
|-1
}

BPT|40D--E;41A
MU|&ggr; ray
CCM|Class relative to wildtype: Compound chromosome arm
|All limits from polytene analysis (FBrf0053501)
MK|pk<up>sple-1</up>
NCO|2Rt - 40E | 41A - 2Rt
DIS|D. Gubb.
COR|b pr pk<up>sple-1</up>
REFDSR
{
RDID|FBrf0053501
|Gubb et al.
|1991
BPT|40D--E;41A
NCO|2Rt - 40E | 41A - 2Rt
DIS|D. Gubb.
COR|b pr pk<up>sple-1</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023390	CLA 1 Aberration	GSYM 1 C(2R)RM-C2	DT 1 20 Apr 05	RESZ 270	REF 1	
ABSY|C(2R)RM-C2
DT|20 Apr 05
SYN|C(2R)C2
ID|FBab0023390
REF
{
REFM|FBrf0082537
|Roote
|1995.9.6
|-1
}

DIS|D. Gubb.
MU|&ggr; ray
COR|b pr pk<up>sple-1</up>
CCM|Class relative to wildtype: Compound chromosome arm
MK|pk<up>sple-1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0023391	CLA 1 Aberration	GSYM 1 C(2R)RM-C5	DT 1 20 Apr 05	RESZ 273	REF 1	
ABSY|C(2R)RM-C5
DT|20 Apr 05
SYN|C(2R)C5
ID|FBab0023391
REF
{
REFM|FBrf0082537
|Roote
|1995.9.6
|-1
}

DIS|D. Gubb.
MU|&ggr; ray
COR|In(2L)Cy, In(2R)Cy/Df(2R)MS-10
CCM|Class relative to wildtype: Compound chromosome arm
MK|Cy<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000120	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-G1	DT 1 20 Apr 05	RESZ 275	REF 2	
ABSY|C(2R)RM-G1
DT|20 Apr 05
SYN|C(2R)RM, bw
NAM|Compound (Autosomal arm)
ID|FBab0000120
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0028784
|Gethmann
|1976
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|bw<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000122	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-LS1	DT 1 20 Apr 05	RESZ 305	REF 2	
ABSY|C(2R)RM-LS1
DT|20 Apr 05
SYN|C(2R)RM, stw bw
NAM|Compound (Autosomal arm)
ID|FBab0000122
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|stw<up>1</up> bw<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000123	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-LS2	DT 1 20 Apr 05	RESZ 287	REF 2	
ABSY|C(2R)RM-LS2
DT|20 Apr 05
SYN|C(2R)RM, vg
NAM|Compound (Autosomal arm)
ID|FBab0000123
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|vg<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0023392	CLA 1 Aberration	GSYM 1 C(2R)RM-P3	DT 1 20 Apr 05	RESZ 246	REF 1	
ABSY|C(2R)RM-P3
DT|20 Apr 05
SYN|C(2R)P3
ID2|FBab0022026
ID|FBab0023392
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock Center
CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0000124	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-P4	DT 1 20 Apr 05	RESZ 1098	SK 4	REF 6	
ABSY|C(2R)RM-P4
DT|20 Apr 05
SYN|C(2R)P, px
|C(2R)RM4,bw
|C(2L)RM-4 \?
|C(2R)P4
|C(2R)RM-P, px
NAM|Compound (Autosomal arm)
ID|FBab0000124
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
REFM|FBrf0028784
|Gethmann
|1976
|-1
REFM|FBrf0053579
|Ponimaskin and Omel'ianchuk
|1991
|-1
REFM|FBrf0027487
|Hardy
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
AMND|lt
MK|px<up>1</up>
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2R)P, px
}

REFDSR
{
RDID|FBrf0053579
|Ponimaskin and Omel'ianchuk
|1991
SYN|C(2R)RM4,bw
}

SK|FBst0000713
|C(2L)RM-P1, b[1]; C(2R)RM-P4, px[1]
|FBst0000716
|C(2L)RM-P2, dp[ov1]; C(2R)RM-P4, px[1]
|FBst0000715
|C(2L)RM-P3, j[63]; C(2R)RM-P4, px[1]
|FBst0004044
|Dp(1;Y)B[S]; C(2L)RM-P4/C(2R)RM-P4
SKC|4
}
# EOR
ABSR
{
RETE|ID 1 FBab0000121	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-S1	DT 1 20 Apr 05	RESZ 678	SK 2	REF 5	
ABSY|C(2R)RM-S1
DT|20 Apr 05
SYN|C(2R)RM, cn
NAM|Compound (Autosomal arm)
ID|FBab0000121
REF
{
REFM|FBrf0019626
|Sandler et al.
|1968
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0086978
|Coyne
|1996
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
REFM|FBrf0028784
|Gethmann
|1976
|-1
}

NCO|2Rt - 39 | 41A - 2Rt
CCM|Class relative to wildtype: Compound chromosome arm
MK|cn<up>1</up>
PHP|segregates regularly from C(2L) in males
REFDSR
{
RDID|FBrf0019626
|Sandler et al.
|1968
SYN|C(2R)RM, cn
}

REFDSR
{
RDID|FBrf0086978
|Coyne
|1996
SYN|C(2R)RM, cn
}

SK|FBst0002722
|C(1)*, y[*]/y[1]; C(2R)RM-S1, cn[1]; F(2L)1, dp[ov1]
|FBst0003982
|C(2L)RM-P1, b[1]/C(2R)RM-S1, cn[1]
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0000125	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-SD72	DT 1 20 Apr 05	RESZ 429	REF 3	
ABSY|C(2R)RM-SD72
DT|20 Apr 05
SYN|C(2R)RM-V43
NAM|Compound (Autosomal arm)
ID|FBab0000125
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
}

NCO|2Rt - 42A14 | 39D4 - 2Rt
COR|induced in In(2LR)SD72;
CCM|Class relative to wildtype: Compound chromosome arm
OTH|--> 80% segregation from C(2L)RM-SD72 in males
}
# EOR
ABSR
{
RETE|ID 1 FBab0000126	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-SH1	DT 1 20 Apr 05	RESZ 791	REF 4	
ABSY|C(2R)RM-SH1
DT|20 Apr 05
SYN|C(2R)SH1
|C(2R)RM-SH1, +
NAM|Compound (Autosomal arm)
ID|FBab0000126
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2R)SH1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000127	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-SH3	DT 1 20 Apr 05	RESZ 1047	REF 5	
ABSY|C(2R)RM-SH3
DT|20 Apr 05
SYN|C(2R)SH3
|C(2R)RM-SH3, +
NAM|Compound (Autosomal arm)
ID|FBab0000127
REF
{
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0039156
|Holm
|1983
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
OAB|Euploid in combination with @C(2L)RM-SH3@ or @C(2L)RM-SH1@.
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
OAB|Euploid in combination with @C(2L)RM-SH3@ or @C(2L)RM-SH1@.
SYN|C(2R)SH3
}

REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023393	CLA 1 Aberration	GSYM 1 C(2R)RM-SKIA	DT 1 20 Apr 05	RESZ 263	SK 1	REF 1	
ABSY|C(2R)RM-SKIA
DT|20 Apr 05
SYN|C(2R)SKIA
ID|FBab0023393
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|cn<up>1</up> bw<up>1</up>
SK|FBst0001621
|C(2L)RM-P1, b[1]; C(2R)RM-SKIA, cn[1] bw[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000128	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-VHK1	DT 1 20 Apr 05	RESZ 299	REF 2	
ABSY|C(2R)RM-VHK1
DT|20 Apr 05
SYN|C(2R)RM-VHK1, rl cn
NAM|Compound (Autosomal arm)
ID|FBab0000128
REF
{
REFM|FBrf0029874
|Hilliker et al.
|1977
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|rl<up>1</up> cn<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000129	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-VK1	DT 1 20 Apr 05	RESZ 1355	CLOC 1 [<h35];[>h35]	REF 4	
ABSY|C(2R)RM-VK1
DT|20 Apr 05
SYN|C(2R)VK1,Dup(2L)lt<up>+</up>bw
|C(2R)VK1
|C(2R)RM-VK1, bw
|C(2R)VK1,Dp(2L)lt<up>+</up>bw
|Dp(2;2)lt<up>+</up>
ID2|FBab0003524
NAM|Compound (Autosomal arm)
ID|FBab0000129
REF
{
REFM|FBrf0039521
|Nishimura and Gethmann
|1983
|-1
REFM|FBrf0037994
|Hilliker et al.
|1982
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

BPT|[<h35];[>h35]
CCM|Class relative to wildtype: Compound chromosome arm
|All limits from complementation mapping against lt (citation unavailable)
FGD|bk1 << lt << bk2
MK|bw<up>1</up>
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
CCM|Does not carry the prominent secondary constriction frequently observed
|at the euchromatic/heterochromatic junction of 2L.
OTH|Carries @lt@<up>+</up>, and therefore loci proximal to @lt@, from 2L.
SYN|C(2R)VK1,Dup(2L)lt<up>+</up>bw
}

REFDSR
{
RDID|FBrf0037994
|Hilliker et al.
|1982
OTH|The second chromosome heterochromatin does not appear to influence
|the random meiotic segregation of compound second autosomes during
|spermatogenesis. The proximal euchromatin is implicated in male meiotic
|pairing: male autosomal meiotic pairing sites are specific euchromatic
|chromosomal regions.
SYN|C(2R)VK1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000130	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(2R)RM-VK2	DT 1 20 Apr 05	RESZ 724	REF 4	
ABSY|C(2R)RM-VK2
DT|20 Apr 05
SYN|C(2R)VK2
|C(2R)RM-VK2, bw
NAM|Compound (Autosomal arm)
ID|FBab0000130
REF
{
REFM|FBrf0048206
|Gubb et al.
|1988
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036153
|Hilliker
|1981
|-1
REFM|FBrf0027524
|Hilliker and Holm
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
AMDP|lt
MK|bw<up>1</up>
OAB|Euploid in combination with @C(2L)RM-SH3@.
PHP|segregates randomly in males
REFDSR
{
RDID|FBrf0027524
|Hilliker and Holm
|1975
MK|b<up>1</up>
OAB|Euploid in combination with @C(2L)RM-SH3@.
SYN|C(2R)VK2
}

REFDSR
{
RDID|FBrf0048206
|Gubb et al.
|1988
SYN|C(2R)VK2
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000012	CLA 1 Aberration	GSYM 1 C(2R2L.)	DT 1 27 Nov 05	RESZ 659	REF 1	
ABSY|C(2R2L.)
DT|27 Nov 05
SYN|2R2L.
|In(2L)tp
|Inversion(2L)terminal pericentric
ID|FBab0000012
REF
{
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|X ray
PRG|Y
|C(2)EN
CCM|Class relative to wildtype: Aberration
OTH|Induced breakdown of C(2)EN with a Y chromosome.
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
PRG|C(2)EN
CCM|This chromosome has the order 2R2L., with or without an additional
|smaller arm from the Y chromosome beyond the centromere.
OTH|Induced breakdown of @C(2)EN@ with a Y chromosome. The term terminal
|pericentric inversion (In(2L)tp) is suggested for this type of chromosome.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023394	CLA 1 Aberration	GSYM 1 C(2R2L.3R)	DT 1 20 Apr 05	RESZ 377	REF 1	
ABSY|C(2R2L.3R)
DT|20 Apr 05
ID|FBab0023394
REF
{
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|recombination
PRG|C(2R2L.)
|T(2;3)N2-46
CCM|Class relative to wildtype: Hetero-compound chromosome
BIP|40--41;80--81 (from T(2;3)N2-46)
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MU|recombination
PRG|C(2R2L.)
|T(2;3)N2-46
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000131	CLA 1 Aberration	NAM 1 Compound (3) ENtire	GSYM 1 C(3)EN	DT 1 20 Apr 05	RESZ 3536	ALESR 4	SK 3	REF 2	
ABSY|C(3)EN
DT|20 Apr 05
NAM|Compound (3) ENtire
ID|FBab0000131
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|irradiation
COR|Synthesized by first selecting a T(Y;3) with a break in YL
|of B<up>S</up>Yy<up>+</up> and an absolutely terminal break in 3L. Females
|heterozygous for B<up>S</up>YL3L.3R and a normal third chromosome
|were irradiated and crossed to F(3L)/F(3L)/C(3R)RM males;
|one of the few surviving products of this cross is non-Bar
|and comes from fertilization of an ovum containing a half
|translocation between the base of 3R of the normal third and
|the distal YL material of the Dp(Y;3) fertilized by a sperm
|containing F(3L) but no C(3R); the F(3L) in this case was
|the Y<up>P</up>3L<up>D</up> of a T(Y;3) involving breaks in YL of
|B<up>S</up>Yy<up>+</up> and the proximal heterochromatin of 3L, so that
|the desired survivor is 3R.3L3R/y<up>+</up>YS.3L in constitution.
|One product of recombination between 3L's in females of the
|above constitution is y<up>+</up>YS.3L3R. Females homozygous for
|the latter derivative were irradiated and crossed to
|C(3L)RM; C(3R)RM males; surviving y offspring carried
|3R3L.3L3R = C(3)EN from the mother and no third chromosomal
|elements from the father. In situ hybridization with
|telomeric sequences provides no evidence for the presence of
|such sequences at the 3L - 3R junction (Goldstein, Barry and Novitski, 1981).
CCM|Class relative to wildtype: Homo-compound chromosome
|C(3)EN, 3R3L.3L3R
PRG|C(3L3R.)
PHP|Provides all of chromosome 3 necessary for normal
|development. C(3)EN-bearing flies produce two types of
|meiotic products with respect to chromosome 3: half disomic
|and half nullosomic; accordingly crosses to normal diploids
|produce only inviable mono- and triplo-3 zygotes; however
|crosses of C(3)EN flies to each other produce progeny.
|Transmission of C(3)EN by males versus that from females
|varies widely depending on the particular isolations tested,
|from 40% relative maternal transmission in some crosses
|through equal recovery in others, to 30% relative paternal
|transmission in yet others. In general these chromosomes
|perform poorly in stocks and crosses.
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MU|irradiation
PRG|C(3L3R.)
PHP|Male fertile.
}

BGV
{
BGVSY|C(3)EN-W96-vNe
SYN|C(3)EN W96, cu ca
|C(3)EN-W96, cu ca
ID2|FBba0000082
ID|FBba0000137
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
SYN|C(3)EN W96, cu ca
MK|cu<up>1</up> ca<up>1</up>
}

}

BGV
{
BGVSY|C(3)EN-W96-vNf
SYN|C(3)EN W96, st cu ca
|C(3)EN-W96, st cu ca
ID|FBba0000138
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
SYN|C(3)EN W96, st cu ca
MK|st<up>1</up> cu<up>1</up> ca<up>1</up>
}

}

BGV
{
BGVSY|C(3)EN-W96-vNg
SYN|C(3)EN W96, th st ca
|C(3)EN-W96, th st ca
ID|FBba0000139
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
SYN|C(3)EN W96, th st ca
MK|th<up>1</up> st<up>1</up> ca<up>1</up>
}

}

BGV
{
BGVSY|C(3)EN-Z170-vNh
SYN|C(3)EN Z170, st cu ca
|C(3)EN-Z170, st cu ca
ID2|FBba0000083
ID|FBba0000140
REF|FBrf0036510
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
SYN|C(3)EN Z170, st cu ca
MK|st<up>1</up> cu<up>1</up> ca<up>1</up>
}

}

SK|FBst0001115
|Basc; C(3)EN
|FBst0001117
|C(3)EN, st[1] cu[1] e[s]
|FBst0001114
|C(3)EN, th[1] st[1]
SKC|3
}
# EOR
ABSR
{
RETE|ID 1 FBab0022027	CLA 1 Aberration	GSYM 1 C(3)se	DT 1 27 Nov 05	RESZ 251	REF 2	
ABSY|C(3)se
DT|27 Nov 05
ID|FBab0022027
REF
{
REFM|FBrf0162057
|Grosshans et al.
|2003
|-1
REFM|FBrf0056104
|Rose and Wieschaus
|1992
|-1
}

CCM|Class relative to wildtype: Homo-compound chromosome
}
# EOR
ABSR
{
RETE|ID 1 FBab0022028	CLA 1 Laevosynaptic	GSYM 1 C(3L)RM*	DT 1 20 Apr 05	RESZ 1306	REF 2	
ABSY|C(3L)RM*
DT|20 Apr 05
SYN|C(3)L
|C(3L)
ID|FBab0022028
REF
{
REFM|FBrf0082182
|Jang et al.
|1995
|-1
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A C(3L) of unknown origin
|Carries no known marker mutations.
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
}

REFDSR
{
RDID|FBrf0082182
|Jang et al.
|1995
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A study of metaphase arrest found that crossovers between homologs
|attached to the same centromere do not induce metaphase arrest. Hence
|exchanges induce metaphase arrest only when they physically conjoin
|two separate kinetochores. The signal that mediates metaphase arrest
|is not the exchange event per se, but the resulting tension on homologous
|kinetochores.
SYN|C(3)L
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000134	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-H1	DT 1 20 Apr 05	RESZ 312	REF 2	
ABSY|C(3L)RM-H1
DT|20 Apr 05
SYN|C(3L)RM, se h rs<up>2</up>
NAM|Compound (Autosomal arm)
ID|FBab0000134
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027487
|Hardy
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|se<up>1</up> h<up>1</up> rs<up>2</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000133	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-LS1	DT 1 20 Apr 05	RESZ 486	SK 1	REF 4	
ABSY|C(3L)RM-LS1
DT|20 Apr 05
SYN|C(3L)RM, h<up>2</up>
NAM|Compound (Autosomal arm)
ID|FBab0000133
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0086978
|Coyne
|1996
|-1
REFM|FBrf0021857
|Leigh and Sobels
|1970
|-1
REFM|FBrf0027487
|Hardy
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|h<up>2</up>
REFDSR
{
RDID|FBrf0086978
|Coyne
|1996
SYN|C(3L)RM, h<up>2</up>
}

SK|FBst0004013
|C(3L)RM-LS1, h[2]/F(3R)1, e[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0022029	CLA 1 Laevosynaptic	GSYM 1 C(3L)RM-P1	DT 1 20 Apr 05	RESZ 584	SK 1	REF 2	
ABSY|C(3L)RM-P1
DT|20 Apr 05
ID|FBab0022029
REF
{
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock Center
CCM|Class relative to wildtype: Compound chromosome arm
MK|se<up>1</up> h<up>1</up> app<up>1</up> h<up>2</up> rs<up>2</up>
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
}

SK|FBst0000717
|C(3L)RM-P1, se[1] h[1] app[1]/h[2] rs[2]; C(3R)RM-P2/+
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000135	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-P2	DT 1 20 Apr 05	RESZ 280	SK 2	REF 2	
ABSY|C(3L)RM-P2
DT|20 Apr 05
SYN|C(3L)RM-P2, ri
NAM|Compound (Autosomal arm)
ID|FBab0000135
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0020335
|Holm et al.
|1969
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|kni<up>ri-1</up>
SK|FBst0001623
|C(3L)RM-P2, kni[ri-1]; C(3R)RM-VT2, cu[1]
|FBst0004052
|y[1]; C(3L)RM-P2, kni[ri-1]; C(3R)RM-SH3, ry[2]
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0022030	CLA 1 Laevosynaptic	GSYM 1 C(3L)RM-P3	DT 1 20 Apr 05	RESZ 537	SK 1	REF 2	
ABSY|C(3L)RM-P3
DT|20 Apr 05
ID|FBab0022030
REF
{
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock Center
CCM|Class relative to wildtype: Compound chromosome arm
MK|kni<up>ri-1</up>
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
}

SK|FBst0000718
|C(3L)RM-P3, kni[ri-1]; C(3R)RM-P3
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000136	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-P5	DT 1 20 Apr 05	RESZ 302	REF 2	
ABSY|C(3L)RM-P5
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000136
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

PRG|In(3L)P/ve<up>1</up> h<up>1</up> th<up>1</up>
CCM|Class relative to wildtype: Compound chromosome arm
}
# EOR
ABSR
{
RETE|ID 1 FBab0022031	CLA 1 Laevosynaptic	GSYM 1 C(3L)RM-P6	DT 1 20 Apr 05	RESZ 517	SK 1	REF 2	
ABSY|C(3L)RM-P6
DT|20 Apr 05
ID|FBab0022031
REF
{
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech Stock Center
CCM|Class relative to wildtype: Compound chromosome arm
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
ACLA|Laevosynaptic
AMDD|dodeca
AMND|dodeca
}

SK|FBst0000719
|C(3L)RM-P6; C(3R)RM-P6
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000137	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-SH2	DT 1 20 Apr 05	RESZ 277	REF 2	
ABSY|C(3L)RM-SH2
DT|20 Apr 05
SYN|C(3L)RM-SH2, +
NAM|Compound (Autosomal arm)
ID|FBab0000137
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0000138	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-SH3	DT 1 20 Apr 05	RESZ 277	REF 2	
ABSY|C(3L)RM-SH3
DT|20 Apr 05
SYN|C(3L)RM-SH3, +
NAM|Compound (Autosomal arm)
ID|FBab0000138
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0000139	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-VG1	DT 1 20 Apr 05	RESZ 763	REF 5	
ABSY|C(3L)RM-VG1
DT|20 Apr 05
SYN|C(3L)VGI
|C(3L)RM-VG1, ru st
NAM|Compound (Autosomal arm)
ID|FBab0000139
REF
{
REFM|FBrf0056363
|Ghosh and Mukherjee
|1992
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0044097
|Ghosh and Mukherjee
|1986
|-1
REFM|FBrf0055754
|Bhadra et al.
|1992
|-1
REFM|FBrf0051455
|Ghosh and Mukherjee
|1990
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|ru<up>1</up> st<up>1</up>
REFDSR
{
RDID|FBrf0051455
|Ghosh and Mukherjee
|1990
SYN|C(3L)VGI
}

REFDSR
{
RDID|FBrf0055754
|Bhadra et al.
|1992
SYN|C(3L)VGI
}

REFDSR
{
RDID|FBrf0056363
|Ghosh and Mukherjee
|1992
SYN|C(3L)VGI
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000140	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3L)RM-VH3	DT 1 20 Apr 05	RESZ 224	REF 1	
ABSY|C(3L)RM-VH3
DT|20 Apr 05
SYN|C(3L)RM-VH3, st
NAM|Compound (Autosomal arm)
ID|FBab0000140
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|st<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0024811	CLA 1 Aberration	GSYM 1 C(3L)st	DT 1 20 Apr 05	RESZ 287	REF 1	
ABSY|C(3L)st
DT|20 Apr 05
ID|FBab0024811
REF
{
REFM|FBrf0086407
|Francis-Lang et al.
|1996
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
DIS|E. Wieschaus.
REFDSR
{
RDID|FBrf0086407
|Francis-Lang et al.
|1996
DIS|E. Wieschaus.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0010162	CLA 1 Aberration	GSYM 1 C(3L3R.)	DT 1 27 Nov 05	RESZ 555	REF 1	
ABSY|C(3L3R.)
DT|27 Nov 05
SYN|y+.3L3R
|In(3L)tp
|Inversion(3L)terminal pericentric
ID|FBab0010162
REF
{
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|recombination
PRG|C(3R3L.3R)
|T(Y;3)A95
CCM|Class relative to wildtype: Aberration
|C(3L3R.)
MK|y<up>+</up>
BIP|h1--h25B;80--81 (from T(Y;3)A95)
OTH|An intermediate in the synthesis of @C(3)EN@.
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MU|recombination
PRG|T(Y;3)A95
|C(3R3L.3R)
OTH|An intermediate in the synthesis of @C(3)EN@.
SYN|y+.3L3R
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024812	CLA 1 Aberration	GSYM 1 C(3R)e	DT 1 20 Apr 05	RESZ 286	REF 1	
ABSY|C(3R)e
DT|20 Apr 05
ID|FBab0024812
REF
{
REFM|FBrf0086407
|Francis-Lang et al.
|1996
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
DIS|E. Wieschaus.
REFDSR
{
RDID|FBrf0086407
|Francis-Lang et al.
|1996
DIS|E. Wieschaus.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022032	CLA 1 Aberration	GSYM 1 C(3R)RM*	DT 1 20 Apr 05	RESZ 1419	REF 3	
ABSY|C(3R)RM*
DT|20 Apr 05
SYN|C(3)R
|C(3R)RM, sr
|C(3R)
ID|FBab0022032
REF
{
REFM|FBrf0082182
|Jang et al.
|1995
|-1
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0086978
|Coyne
|1996
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
AMDD|dodeca
AMND|dodeca
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A C(3R)RM of unknown origin.
|Carries no known marker mutations.
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
AMDD|dodeca
AMND|dodeca
}

REFDSR
{
RDID|FBrf0082182
|Jang et al.
|1995
OAB|Oocytes from All-Compound females produce anaphase I and meiosis II figures 64% of the time, i.e. they have bypassed metaphase I arrest.
OTH|A study of metaphase arrest found that crossovers between homologs
|attached to the same centromere do not induce metaphase arrest. Hence
|exchanges induce metaphase arrest only when they physically conjoin
|two separate kinetochores. The signal that mediates metaphase arrest
|is not the exchange event per se, but the resulting tension on homologous
|kinetochores.
SYN|C(3)R
}

REFDSR
{
RDID|FBrf0086978
|Coyne
|1996
SYN|C(3R)RM, sr
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000141	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-1	DT 1 20 Apr 05	RESZ 259	REF 2	
ABSY|C(3R)RM-1
DT|20 Apr 05
SYN|C(3R)RM, +
NAM|Compound (Autosomal arm)
ID|FBab0000141
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027487
|Hardy
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0022033	CLA 1 Aberration	GSYM 1 C(3R)RM-P2	DT 1 20 Apr 05	RESZ 235	SK 1	REF 1	
ABSY|C(3R)RM-P2
DT|20 Apr 05
SYN|C(3R)P2
ID|FBab0022033
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|+
SK|FBst0000717
|C(3L)RM-P1, se[1] h[1] app[1]/h[2] rs[2]; C(3R)RM-P2/+
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0022034	CLA 1 Aberration	GSYM 1 C(3R)RM-P3	DT 1 20 Apr 05	RESZ 514	SK 2	REF 2	
ABSY|C(3R)RM-P3
DT|20 Apr 05
SYN|C(3R)P3
ID|FBab0022034
REF
{
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|sr<up>1</up>
AMDD|dodeca
AMND|dodeca
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
AMDD|dodeca
AMND|dodeca
}

SK|FBst0000718
|C(3L)RM-P3, kni[ri-1]; C(3R)RM-P3
|FBst0002682
|y[1]; F(3L)2, h[2]; C(3R)RM-P3, sr[1]
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0000144	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-P5	DT 1 20 Apr 05	RESZ 383	REF 2	
ABSY|C(3R)RM-P5
DT|20 Apr 05
SYN|C(3R)RM, sbd<up>2</up> gl e<up>2</up>
|C(3R)RM-P5, sbd<up>2</up> gl e<up>s</up>
NAM|Compound (Autosomal arm)
ID|FBab0000144
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|Sb<up>sbd-2</up> gl<up>1</up> e<up>s</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0022035	CLA 1 Aberration	GSYM 1 C(3R)RM-P6	DT 1 20 Apr 05	RESZ 503	SK 1	REF 2	
ABSY|C(3R)RM-P6
DT|20 Apr 05
SYN|C(3R)P6
ID|FBab0022035
REF
{
REFM|FBrf0058823
|Carmena et al.
|1993
|-1
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech stock collection
CCM|Class relative to wildtype: Compound chromosome arm
MK|+
AMDD|dodeca
AMND|dodeca
REFDSR
{
RDID|FBrf0058823
|Carmena et al.
|1993
AMDD|dodeca
AMND|dodeca
}

SK|FBst0000719
|C(3L)RM-P6; C(3R)RM-P6
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000145	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SB1	DT 1 20 Apr 05	RESZ 312	REF 2	
ABSY|C(3R)RM-SB1
DT|20 Apr 05
SYN|C(3R)RM-SB1, p<up>p</up> gl<up>3</up>
NAM|Compound (Autosomal arm)
ID|FBab0000145
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0020335
|Holm et al.
|1969
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|p<up>p</up> gl<up>3</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000146	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SC1	DT 1 20 Apr 05	RESZ 242	REF 1	
ABSY|C(3R)RM-SC1
DT|20 Apr 05
SYN|C(3R)RM-SC1, kar ry
NAM|Compound (Autosomal arm)
ID|FBab0000146
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|kar<up>1</up> ry<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000147	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH19	DT 1 20 Apr 05	RESZ 214	REF 1	
ABSY|C(3R)RM-SH19
DT|20 Apr 05
SYN|C(3R)RM-SH19, +
NAM|Compound (Autosomal arm)
ID|FBab0000147
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0000148	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH20	DT 1 20 Apr 05	RESZ 279	REF 2	
ABSY|C(3R)RM-SH20
DT|20 Apr 05
SYN|C(3R)RM-SH20, +
NAM|Compound (Autosomal arm)
ID|FBab0000148
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|+
}
# EOR
ABSR
{
RETE|ID 1 FBab0000149	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH21	DT 1 20 Apr 05	RESZ 255	REF 2	
ABSY|C(3R)RM-SH21
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000149
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
}
# EOR
ABSR
{
RETE|ID 1 FBab0000151	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH3	DT 1 20 Apr 05	RESZ 295	SK 1	REF 2	
ABSY|C(3R)RM-SH3
DT|20 Apr 05
SYN|C(3R)RM-SH3, ry<up>2</up>
NAM|Compound (Autosomal arm)
ID|FBab0000151
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0040984
|Clark et al.
|1984
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|ry<up>2</up>
SK|FBst0004052
|y[1]; C(3L)RM-P2, kni[ri-1]; C(3R)RM-SH3, ry[2]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000152	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH4a	DT 1 20 Apr 05	RESZ 370	REF 2	
ABSY|C(3R)RM-SH4a
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000152
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

PRG|In(3R)C, Sb<up>1</up> e<up>1</up> l(3)e<up>1</up> ca<up>1</up> awd<up>K</up>
CCM|Class relative to wildtype: Compound chromosome arm
BIP|92D1--9;100F2--3 (from In(3R)C)
}
# EOR
ABSR
{
RETE|ID 1 FBab0000153	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SH4b	DT 1 20 Apr 05	RESZ 310	REF 2	
ABSY|C(3R)RM-SH4b
DT|20 Apr 05
SYN|C(3R)RM-SH4b, ca K-pn
NAM|Compound (Autosomal arm)
ID|FBab0000153
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|ca<up>1</up> awd<up>K</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000154	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SHK16	DT 1 20 Apr 05	RESZ 381	REF 2	
ABSY|C(3R)RM-SHK16
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000154
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0040984
|Clark et al.
|1984
|-1
}

PRG|kar<up>2</up> ry<up>406</up> pic<up>23</up>/ry<up>+10</up> Ace<up>1</up>
CCM|Class relative to wildtype: Compound chromosome arm
OTH|used in half-tetrad analysis or ry fine structure
}
# EOR
ABSR
{
RETE|ID 1 FBab0000155	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-SK2	DT 1 20 Apr 05	RESZ 290	REF 2	
ABSY|C(3R)RM-SK2
DT|20 Apr 05
NAM|Compound (Autosomal arm)
ID|FBab0000155
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0027491
|Holm and Chovnick
|1975
|-1
}

PRG|p<up>p</up> ss e<up>s</up>/cu gl
CCM|Class relative to wildtype: Compound chromosome arm
}
# EOR
ABSR
{
RETE|ID 1 FBab0000156	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-VC1	DT 1 20 Apr 05	RESZ 297	REF 2	
ABSY|C(3R)RM-VC1
DT|20 Apr 05
SYN|C(3R)RM-VC1, e<up>s</up>
NAM|Compound (Autosomal arm)
ID|FBab0000156
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0044097
|Ghosh and Mukherjee
|1986
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|e<up>s</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000157	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-VK1	DT 1 20 Apr 05	RESZ 232	REF 1	
ABSY|C(3R)RM-VK1
DT|20 Apr 05
SYN|C(3R)RM-VK1, e<up>s</up>
NAM|Compound (Autosomal arm)
ID|FBab0000157
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|e<up>s</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0000158	CLA 1 Aberration	NAM 1 Compound (Autosomal arm)	GSYM 1 C(3R)RM-VT2	DT 1 20 Apr 05	RESZ 290	SK 1	REF 2	
ABSY|C(3R)RM-VT2
DT|20 Apr 05
SYN|C(3R)RM-VT2, cu
NAM|Compound (Autosomal arm)
ID|FBab0000158
REF
{
REFM|FBrf0034858
|Harger and Holm
|1980
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

CCM|Class relative to wildtype: Compound chromosome arm
MK|cu<up>1</up>
SK|FBst0001623
|C(3L)RM-P2, kni[ri-1]; C(3R)RM-VT2, cu[1]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000013	CLA 1 Aberration	GSYM 1 C(3R3L.3R)	DT 1 20 Apr 05	RESZ 491	REF 1	
ABSY|C(3R3L.3R)
DT|20 Apr 05
SYN|3R3L.3R
ID|FBab0000013
REF
{
REFM|FBrf0036510
|Novitski et al.
|1981
|-1
}

MU|&ggr; ray
PRG|Dp(1;3)B<up>S</up>
CCM|Class relative to wildtype: Compound chromosome arm
BIP|[<16A1];[>16A1] (from Dp(1;3)B<up>S</up>)
OTH|An intermediate in the synthesis of @C(3)EN@.
REFDSR
{
RDID|FBrf0036510
|Novitski et al.
|1981
MU|&ggr; ray
PRG|Dp(1;3)B<up>S</up>
OTH|An intermediate in the synthesis of @C(3)EN@. Highly unstable.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0029628	CLA 1 Aberration	GSYM 1 C(4)DRA-1	DT 1 20 Apr 05	RESZ 514	REF 1	
ABSY|C(4)DRA-1
DT|20 Apr 05
ID|FBab0029628
REF
{
REFM|FBrf0135565
|Sousa-Neves
|2000
|-1
}

CCM|Class relative to wildtype: Homo-compound chromosome
BIP|1B4;101F1--102D1;[] (from T(1;4)sc<up>H</up>)
MU|recombination
PRG|C(4)RM
|T(1;4)sc<up>H</up>
MK|y<up>+</up>
REFDSR
{
RDID|FBrf0135565
|Sousa-Neves
|2000
MU|recombination
PRG|C(4)RM
|T(1;4)sc<up>H</up>
MK|y<up>+</up>
PHP|Hemizygous viable in males and females, homozygous viable in females
|but lethal in homozygous males.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000159	CLA 1 Aberration	GSYM 1 C(4)RM	DT 1 20 Apr 05	RESZ 1864	SK 6	REF 13	
ABSY|C(4)RM
DT|20 Apr 05
SYN|C(4)EN
ID|FBab0000159
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0104517
|Starr et al.
|1998
|-1
REFM|FBrf0028767
|Hall and Kankel
|1976
|-1
REFM|FBrf0132334
|Tomkiel et al.
|2001
|-1
REFM|FBrf0073755
|Locke and Tartof
|1994
|-1
REFM|FBrf0015566
|Grell
|1963
|-1
REFM|FBrf0023684
|Grell
|1972
|-1
REFM|FBrf0103272
|Halder et al.
|1998
|-1
REFM|FBrf0073960
|Moore et al.
|1994
|-1
REFM|FBrf0101865
|Ahmad and Golic
|1998
|-1
REFM|FBrf0109303
|Basu et al.
|1999
|-1
REFM|FBrf0129777
|Cox et al.
|2000
|-1
REFM|FBrf0099905
|Ruden et al.
|1997
|-1
}

DIS|E. B. Lewis.
MU|X ray
CCM|Class relative to wildtype: Homo-compound chromosome
|Two right arms
|of chromosome 4 attached proximally to a single centromere.
MK|ci<up>1</up> ey<up>R</up> sv<up>spa-pol</up>
OTH|Exists with different markers; presumably these are different syntheses.
|Exists with various marker combinations.
PHP|Produces haplo-4 and triplo-4 progeny in crosses to normal
|diplo-4 flies. Tetra-4 flies carrying two copies of C(4)RM
|exhibit but slightly reduced viability (Grell, 1972, D. I. S. 48:
|69). Segregates quasi-regularly from C(1)RM in C(1)RM/0;
|C(4)RM/0 females (Grell, 1963, Genetics 48: 1217-29).
REFDSR
{
RDID|FBrf0073960
|Moore et al.
|1994
SYN|C(4)EN
}

REFDSR
{
RDID|FBrf0099905
|Ruden et al.
|1997
MK|ci<up>1</up> ey<up>R</up>
}

REFDSR
{
RDID|FBrf0101865
|Ahmad and Golic
|1998
MK|sv<up>spa-pol</up>
}

REFDSR
{
RDID|FBrf0132334
|Tomkiel et al.
|2001
SYN|C(4)EN
}

SK|FBst0001612
|C(1)RM, y[1] v[1] bb[1]/0; C(4)RM, ci[1] ey[R]/0 & C(1;Y)1, v[1] f[1] B[1]/0; C(4)RM, ci[1] ey[R]/0
|FBst0001785
|C(4)RM, ci[1] ey[R]/0
|FBst1001604
|Opt[G]; C(4)RM, ey
|FBst0001611
|y[1] pn[1]; C(4)RM, ci[1] ey[R]/0
|FBst0003698
|y[1] v[1]; C(4)RM, sv[spa-pol]
|FBst0004406
|y[1]; ry[506]; C(4)RM, ci[1] ey[R]/0
SKC|6
}
# EOR
ABSR
{
RETE|ID 1 FBab0022036	CLA 1 Aberration	GSYM 1 C(4)RM-P2	DT 1 20 Apr 05	RESZ 285	SK 1	REF 1	
ABSY|C(4)RM-P2
DT|20 Apr 05
SYN|C(4)P2
ID|FBab0022036
REF
{
REFM|FBrf0141259
|Bloomington Drosophila Stock Center
|19??-
|-1
}

COR|Caltech stock collection
CCM|Class relative to wildtype: Homo-compound chromosome
MK|ci<up>1</up> ey<up>R</up>/gvl<up>1</up> sv<up>n</up>
SK|FBst0000720
|C(4)RM-P2, ci[1] ey[R]: gvl[1] sv[n]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010437	CLA 1 Aberration	GSYM 1 C(YS)1	DT 1 20 Apr 05	RESZ 411	SK 2	REF 2	
ABSY|C(YS)1
DT|20 Apr 05
SYN|Y''
|YS.YS1
ID|FBab0010437
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0001913
|Stern
|1929
|-1
}

DIS|Stern.
MU|spontaneous
CCM|Class relative to wildtype: Compound chromosome arm
|V-shaped chromosome in mitotic metaphase, with both arms the
|length of YS.
|KS bb<up>+</up>.bb<up>+</up> KS.
MK|bb<up>+</up>
SK|FBst0003924
|C(1)RA, v[1] f[1]/C(1;YL)C2, y[1] cv[1] v[1] f[1] car[1] bb[-]/C(YS)1
|FBst0004489
|C(1)RM, y[1]/C(1;YL)1, y[1] cv[1] v[1] f[1] car[1]/C(YS)1
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0010438	CLA 1 Aberration	GSYM 1 C(YS)2	DT 1 27 Nov 05	RESZ 496	SK 1	REF 3	
ABSY|C(YS)2
DT|27 Nov 05
SYN|Y''
|YS.YS2
ID|FBab0010438
REF
{
REFM|FBrf0007064
|Muller
|1948
|-1
REFM|FBrf0141717
|Carvalho et al.
|2001
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

DIS|Muller.
MU|spontaneous
PRG|XYS
|y<up>+</up>Y
CCM|Class relative to wildtype: Compound chromosome arm
|V-shaped chromosome in mitotic metaphase, with both arms the
|length of YS.
|KS bb<up>+</up>.bb<up>+</up> KS.
MK|bb<up>+</up>
SK|FBst0002559
|C(YS)2/C(1;YL)1, y[1] v[1] f[1] bb[-] & C(1)DX, y[1] f[1]/0
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0010439	CLA 1 Aberration	GSYM 1 C(YS)3	DT 1 20 Apr 05	RESZ 416	REF 2	
ABSY|C(YS)3
DT|20 Apr 05
SYN|Y''
|YS.YS3
ID|FBab0010439
REF
{
REFM|FBrf0007064
|Muller
|1948
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

DIS|Muller.
MU|spontaneous
PRG|XYS
|y<up>+</up>Y
COR|males
CCM|Class relative to wildtype: Compound chromosome arm
|V-shaped chromosome in mitotic metaphase, with both arms the
|length of YS.
|KS bb<up>+</up>.bb<up>+</up> KS.
MK|bb<up>+</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0025198	CLA 1 Inversion	GSYM 1 Dacu\In(2L)B	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dacu\In(2L)B
DT|08 Nov 97
ID|FBab0025198
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025199	CLA 1 Inversion	GSYM 1 Dacu\In(2L)C	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dacu\In(2L)C
DT|08 Nov 97
ID|FBab0025199
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025200	CLA 1 Inversion	GSYM 1 Dacu\In(2L)D	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dacu\In(2L)D
DT|08 Nov 97
ID|FBab0025200
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025201	CLA 1 Inversion	GSYM 1 Dacu\In(X)B<up>S</up>	DT 1 08 Nov 97	RESZ 285	REF 1	
ABSY|Dacu\In(X)B<up>S</up>
DT|08 Nov 97
ID|FBab0025201
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025202	CLA 1 Inversion	GSYM 1 Dacu\In(X)C	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dacu\In(X)C
DT|08 Nov 97
ID|FBab0025202
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025203	CLA 1 Inversion	GSYM 1 Dacu\In(X)D	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dacu\In(X)D
DT|08 Nov 97
ID|FBab0025203
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025204	CLA 1 Inversion	GSYM 1 Dacu\In(X)E	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dacu\In(X)E
DT|08 Nov 97
ID|FBab0025204
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025206	CLA 1 Inversion	GSYM 1 Daff\In(4)v	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Daff\In(4)v
DT|11 Feb 97
ID|FBab0025206
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025205	CLA 1 Inversion	GSYM 1 Dafs\In(1)SR	DT 1 29 Oct 99	RESZ 287	REF 1	
ABSY|Dafs\In(1)SR
DT|29 Oct 99
ID|FBab0025205
REF
{
REFM|FBrf0005036
|Sturtevant
|1940
|-1
}

ASAL|FBal0055163 == Dafs\SR<up>1</up>
ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0005036
|Sturtevant
|1940
ACLA|Inversion
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025207	CLA 1 Inversion	GSYM 1 Dagl\In(4)m<up>3</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Dagl\In(4)m<up>3</up>
DT|11 Feb 97
ID|FBab0025207
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025208	CLA 1 Inversion	GSYM 1 Dalb\In(1)A	DT 1 08 Nov 97	RESZ 271	REF 1	
ABSY|Dalb\In(1)A
DT|08 Nov 97
ID|FBab0025208
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025209	CLA 1 Inversion	GSYM 1 Dalb\In(1)R5	DT 1 27 Nov 05	RESZ 1602	CLOC 1 12.0;18.0	REF 11	
ABSY|Dalb\In(1)R5
DT|27 Nov 05
ID|FBab0025209
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|12.0;18.0
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|12.0;18.0
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025210	CLA 1 Inversion	GSYM 1 Dalb\In(2)I2	DT 1 08 Nov 97	RESZ 260	REF 1	
ABSY|Dalb\In(2)I2
DT|08 Nov 97
ID|FBab0025210
REF
{
REFM|FBrf0039177
|Mather and Pope
|1983
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0039177
|Mather and Pope
|1983
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025211	CLA 1 Inversion	GSYM 1 Dalb\In(2L)A	DT 1 08 Nov 97	RESZ 272	REF 1	
ABSY|Dalb\In(2L)A
DT|08 Nov 97
ID|FBab0025211
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025212	CLA 1 Inversion	GSYM 1 Dalb\In(2L)A5	DT 1 08 Nov 97	RESZ 273	REF 1	
ABSY|Dalb\In(2L)A5
DT|08 Nov 97
ID|FBab0025212
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025213	CLA 1 Inversion	GSYM 1 Dalb\In(2L)A7	DT 1 08 Nov 97	RESZ 633	CLOC 1 12.4;18.0	REF 4	
ABSY|Dalb\In(2L)A7
DT|08 Nov 97
SYN|In(2L)R6
ID|FBab0025213
REF
{
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0044121
|Mather and Pope
|1986
|-1
REFM|FBrf0090304
|Mather and Pope
|1984
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|12.4;18.0
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044121
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
BPT|12.4;18.0
MU|natural population
COR|Thailand
SYN|In(2L)R6
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024301	CLA 1 Aberration	GSYM 1 Dalb\In(2L)B<down>1</down>D<down>5</down>	DT 1 08 Nov 97	RESZ 470	REF 2	
ABSY|Dalb\In(2L)B<down>1</down>D<down>5</down>
DT|08 Nov 97
ID|FBab0024301
REF
{
REFM|FBrf0051332
|Chang and Lin
|1990
|-1
REFM|FBrf0079935
|Chang and Lin
|1995
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051332
|Chang and Lin
|1990
MU|natural population
}

REFDSR
{
RDID|FBrf0079935
|Chang and Lin
|1995
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025214	CLA 1 Inversion	GSYM 1 Dalb\In(2L)C	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dalb\In(2L)C
DT|08 Nov 97
ID|FBab0025214
REF
{
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025215	CLA 1 Inversion	GSYM 1 Dalb\In(2L)C6	DT 1 27 Nov 05	RESZ 549	CLOC 1 1.1;10.0	REF 3	
ABSY|Dalb\In(2L)C6
DT|27 Nov 05
ID|FBab0025215
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
}

ACLA|Inversion
BPT|1.1;10.0
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
BPT|1.1;10.0
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025216	CLA 1 Inversion	GSYM 1 Dalb\In(2L)D5	DT 1 08 Nov 97	RESZ 273	REF 1	
ABSY|Dalb\In(2L)D5
DT|08 Nov 97
ID|FBab0025216
REF
{
REFM|FBrf0090305
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0090305
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025217	CLA 1 Inversion	GSYM 1 Dalb\In(2L)E'	DT 1 27 Nov 05	RESZ 1433	CLOC 1 6.5;20.3	REF 10	
ABSY|Dalb\In(2L)E'
DT|27 Nov 05
ID|FBab0025217
REF
{
REFM|FBrf0090305
|Mather and Pope
|1984
|-1
REFM|FBrf0042217
|Mather and Tam
|1985
|-1
REFM|FBrf0034309
|Mather and Thongmeearkom
|1980
|-1
REFM|FBrf0042216
|Mather and Tam
|1985
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0044119
|Mather and Casu
|1986
|-1
REFM|FBrf0044121
|Mather and Pope
|1986
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|6.5;20.3
MU|natural population
REFDSR
{
RDID|FBrf0034309
|Mather and Thongmeearkom
|1980
BPT|6.5;20.3
MU|natural population
COR|Tawain
}

REFDSR
{
RDID|FBrf0042216
|Mather and Tam
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042217
|Mather and Tam
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044119
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044121
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090305
|Mather and Pope
|1984
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025218	CLA 1 Inversion	GSYM 1 Dalb\In(2L)E1	DT 1 08 Nov 97	RESZ 913	REF 6	
ABSY|Dalb\In(2L)E1
DT|08 Nov 97
ID|FBab0025218
REF
{
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0090302
|Mather and Balwin
|1982
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0090302
|Mather and Balwin
|1982
MU|natural population
COR|Tawain
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025219	CLA 1 Inversion	GSYM 1 Dalb\In(2L)H	DT 1 08 Nov 97	RESZ 272	REF 1	
ABSY|Dalb\In(2L)H
DT|08 Nov 97
ID|FBab0025219
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025220	CLA 1 Inversion	GSYM 1 Dalb\In(2L)I	DT 1 08 Nov 97	RESZ 272	REF 1	
ABSY|Dalb\In(2L)I
DT|08 Nov 97
ID|FBab0025220
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025221	CLA 1 Inversion	GSYM 1 Dalb\In(2L)J	DT 1 08 Nov 97	RESZ 272	REF 1	
ABSY|Dalb\In(2L)J
DT|08 Nov 97
ID|FBab0025221
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025222	CLA 1 Inversion	GSYM 1 Dalb\In(2L)J2	DT 1 15 Dec 97	RESZ 285	REF 1	
ABSY|Dalb\In(2L)J2
DT|15 Dec 97
ID|FBab0025222
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
OTH|Complex.
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025223	CLA 1 Inversion	GSYM 1 Dalb\In(2L)J6	DT 1 27 Nov 05	RESZ 537	CLOC 1 6.6;21.3	REF 3	
ABSY|Dalb\In(2L)J6
DT|27 Nov 05
ID|FBab0025223
REF
{
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
}

ACLA|Inversion
BPT|6.6;21.3
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
BPT|6.6;21.3
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025224	CLA 1 Inversion	GSYM 1 Dalb\In(2L)J8	DT 1 08 Nov 97	RESZ 283	REF 1	
ABSY|Dalb\In(2L)J8
DT|08 Nov 97
ID|FBab0025224
REF
{
REFM|FBrf0042216
|Mather and Tam
|1985
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
AM|complex
REFDSR
{
RDID|FBrf0042216
|Mather and Tam
|1985
MU|natural population
COR|Thailand
AM|complex
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025225	CLA 1 Inversion	GSYM 1 Dalb\In(2L)S5	DT 1 27 Nov 05	RESZ 1333	CLOC 1 6.0;10.4	REF 9	
ABSY|Dalb\In(2L)S5
DT|27 Nov 05
ID|FBab0025225
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0039177
|Mather and Pope
|1983
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0044121
|Mather and Pope
|1986
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|6.0;10.4
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|6.0;10.4
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0039177
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0044121
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025226	CLA 1 Inversion	GSYM 1 Dalb\In(2L)T5	DT 1 08 Nov 97	RESZ 437	CLOC 1 8.2;21.3	REF 2	
ABSY|Dalb\In(2L)T5
DT|08 Nov 97
ID|FBab0025226
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
}

ACLA|Inversion
BPT|8.2;21.3
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|8.2;21.3
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025227	CLA 1 Inversion	GSYM 1 Dalb\In(2L)U5	DT 1 08 Nov 97	RESZ 601	CLOC 1 1.1;13.2	REF 3	
ABSY|Dalb\In(2L)U5
DT|08 Nov 97
ID|FBab0025227
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
}

ACLA|Inversion
BPT|1.1;13.2
MU|natural population
COR|Thailand
AM|complex
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|1.1;13.2
MU|natural population
COR|Thailand
AM|complex
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025228	CLA 1 Inversion	GSYM 1 Dalb\In(2R)C	DT 1 08 Nov 97	RESZ 272	REF 1	
ABSY|Dalb\In(2R)C
DT|08 Nov 97
ID|FBab0025228
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025229	CLA 1 Inversion	GSYM 1 Dalb\In(2R)C5	DT 1 08 Nov 97	RESZ 273	REF 1	
ABSY|Dalb\In(2R)C5
DT|08 Nov 97
ID|FBab0025229
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025230	CLA 1 Inversion	GSYM 1 Dalb\In(3)A	DT 1 08 Nov 97	RESZ 271	REF 1	
ABSY|Dalb\In(3)A
DT|08 Nov 97
ID|FBab0025230
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025231	CLA 1 Inversion	GSYM 1 Dalb\In(3)A6	DT 1 08 Nov 97	RESZ 298	CLOC 1 32.4;38.8	REF 1	
ABSY|Dalb\In(3)A6
DT|08 Nov 97
ID|FBab0025231
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
}

ACLA|Inversion
BPT|32.4;38.8
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
BPT|32.4;38.8
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025232	CLA 1 Inversion	GSYM 1 Dalb\In(3)B	DT 1 08 Nov 97	RESZ 271	REF 1	
ABSY|Dalb\In(3)B
DT|08 Nov 97
ID|FBab0025232
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025233	CLA 1 Inversion	GSYM 1 Dalb\In(3)B'	DT 1 27 Nov 05	RESZ 422	CLOC 1 36.0;43.6	REF 2	
ABSY|Dalb\In(3)B'
DT|27 Nov 05
ID|FBab0025233
REF
{
REFM|FBrf0034309
|Mather and Thongmeearkom
|1980
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
}

ACLA|Inversion
BPT|36.0;43.6
MU|natural population
COR|Tawain
REFDSR
{
RDID|FBrf0034309
|Mather and Thongmeearkom
|1980
BPT|36.0;43.6
MU|natural population
COR|Tawain
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025234	CLA 1 Inversion	GSYM 1 Dalb\In(3)B1	DT 1 08 Nov 97	RESZ 518	REF 3	
ABSY|Dalb\In(3)B1
DT|08 Nov 97
ID|FBab0025234
REF
{
REFM|FBrf0090302
|Mather and Balwin
|1982
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0090302
|Mather and Balwin
|1982
MU|natural population
COR|Tawain
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025235	CLA 1 Inversion	GSYM 1 Dalb\In(3)B5	DT 1 08 Nov 97	RESZ 260	REF 1	
ABSY|Dalb\In(3)B5
DT|08 Nov 97
ID|FBab0025235
REF
{
REFM|FBrf0039179
|Mather and Pope
|1983
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0039179
|Mather and Pope
|1983
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025236	CLA 1 Inversion	GSYM 1 Dalb\In(3)B6	DT 1 27 Nov 05	RESZ 1356	CLOC 1 34.2;40.1	REF 9	
ABSY|Dalb\In(3)B6
DT|27 Nov 05
ID|FBab0025236
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0044119
|Mather and Casu
|1986
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
}

ACLA|Inversion
BPT|34.2;40.1
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
BPT|34.2;40.1
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044119
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025237	CLA 1 Inversion	GSYM 1 Dalb\In(3)C1	DT 1 27 Nov 05	RESZ 2510	REF 18	
ABSY|Dalb\In(3)C1
DT|27 Nov 05
ID|FBab0025237
REF
{
REFM|FBrf0034309
|Mather and Thongmeearkom
|1980
|-1
REFM|FBrf0039179
|Mather and Pope
|1983
|-1
REFM|FBrf0039178
|Mather and Pope
|1983
|-1
REFM|FBrf0039177
|Mather and Pope
|1983
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0029790
|Thongmeearkom
|1977
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0044119
|Mather and Casu
|1986
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0029790
|Thongmeearkom
|1977
MU|natural population
COR|Malaysia
}

REFDSR
{
RDID|FBrf0034309
|Mather and Thongmeearkom
|1980
BPT|6.1;11.3
}

REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|6.1;11.0
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0039177
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0039178
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0039179
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044119
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025238	CLA 1 Inversion	GSYM 1 Dalb\In(3)D6	DT 1 08 Nov 97	RESZ 436	CLOC 1 1.1;7.4	REF 2	
ABSY|Dalb\In(3)D6
DT|08 Nov 97
ID|FBab0025238
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
}

ACLA|Inversion
BPT|1.1;7.4
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
BPT|1.1;7.4
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025239	CLA 1 Inversion	GSYM 1 Dalb\In(3)E3	DT 1 27 Nov 05	RESZ 390	REF 2	
ABSY|Dalb\In(3)E3
DT|27 Nov 05
ID|FBab0025239
REF
{
REFM|FBrf0029790
|Thongmeearkom
|1977
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
}

ACLA|Inversion
MU|natural population
COR|Malaysia
AM|complex
REFDSR
{
RDID|FBrf0029790
|Thongmeearkom
|1977
MU|natural population
COR|Malaysia
AM|complex
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025240	CLA 1 Inversion	GSYM 1 Dalb\In(3)E6	DT 1 27 Nov 05	RESZ 1826	REF 13	
ABSY|Dalb\In(3)E6
DT|27 Nov 05
ID|FBab0025240
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0039179
|Mather and Pope
|1983
|-1
REFM|FBrf0039178
|Mather and Pope
|1983
|-1
REFM|FBrf0039177
|Mather and Pope
|1983
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0039177
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0039178
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0039179
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025241	CLA 1 Inversion	GSYM 1 Dalb\In(3)E7	DT 1 27 Nov 05	RESZ 396	CLOC 1 19.7;24.2	REF 2	
ABSY|Dalb\In(3)E7
DT|27 Nov 05
ID|FBab0025241
REF
{
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
}

ACLA|Inversion
BPT|19.7;24.2
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
BPT|19.7;24.2
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025242	CLA 1 Inversion	GSYM 1 Dalb\In(3)F	DT 1 08 Nov 97	RESZ 271	REF 1	
ABSY|Dalb\In(3)F
DT|08 Nov 97
ID|FBab0025242
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025243	CLA 1 Inversion	GSYM 1 Dalb\In(3)I6	DT 1 08 Nov 97	RESZ 428	CLOC 1 36.2;42.4	REF 2	
ABSY|Dalb\In(3)I6
DT|08 Nov 97
ID|FBab0025243
REF
{
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
}

ACLA|Inversion
BPT|36.2;42.4
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
BPT|36.2;42.4
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025244	CLA 1 Inversion	GSYM 1 Dalb\In(3)K	DT 1 08 Nov 97	RESZ 271	REF 1	
ABSY|Dalb\In(3)K
DT|08 Nov 97
ID|FBab0025244
REF
{
REFM|FBrf0020992
|Wilson et al.
|1969
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0020992
|Wilson et al.
|1969
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027875	CLA 1 Aberration	GSYM 1 Dalb\In(3)L	DT 1 12 Mar 98	RESZ 218	REF 1	
ABSY|Dalb\In(3)L
DT|12 Mar 98
ID|FBab0027875
REF
{
REFM|FBrf0051887
|Casu
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051887
|Casu
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025245	CLA 1 Inversion	GSYM 1 Dalb\In(3)L3	DT 1 27 Nov 05	RESZ 2016	CLOC 1 21.6;36.5	REF 14	
ABSY|Dalb\In(3)L3
DT|27 Nov 05
ID|FBab0025245
REF
{
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0039177
|Mather and Pope
|1983
|-1
REFM|FBrf0034309
|Mather and Thongmeearkom
|1980
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0042215
|Mather and Pope
|1985
|-1
REFM|FBrf0044122
|Mather and Pope
|1986
|-1
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0042213
|Mather and Pope
|1985
|-1
REFM|FBrf0044119
|Mather and Casu
|1986
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0042212
|Mather and Casu
|1985
|-1
REFM|FBrf0090306
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|21.6;36.5
MU|natural population
REFDSR
{
RDID|FBrf0034309
|Mather and Thongmeearkom
|1980
BPT|21.6;36.5
MU|natural population
COR|Phuket, Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0039177
|Mather and Pope
|1983
COR|Thailand
}

REFDSR
{
RDID|FBrf0042212
|Mather and Casu
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042213
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0042215
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0044119
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0044122
|Mather and Pope
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0090306
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025246	CLA 1 Inversion	GSYM 1 Dalb\In(3)N5	DT 1 08 Nov 97	RESZ 420	REF 2	
ABSY|Dalb\In(3)N5
DT|08 Nov 97
ID|FBab0025246
REF
{
REFM|FBrf0039179
|Mather and Pope
|1983
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0039179
|Mather and Pope
|1983
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025247	CLA 1 Inversion	GSYM 1 Dalb\In(3)T4	DT 1 27 Nov 05	RESZ 582	CLOC 1 11.1;16.4	REF 3	
ABSY|Dalb\In(3)T4
DT|27 Nov 05
ID|FBab0025247
REF
{
REFM|FBrf0034309
|Mather and Thongmeearkom
|1980
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|11.1;16.4
MU|natural population
REFDSR
{
RDID|FBrf0034309
|Mather and Thongmeearkom
|1980
BPT|11.1;16.4
MU|natural population
COR|Phuket, Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
MU|natural population
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025248	CLA 1 Inversion	GSYM 1 Dalb\In(3)V5	DT 1 08 Nov 97	RESZ 436	CLOC 1 2.5;10.8	REF 2	
ABSY|Dalb\In(3)V5
DT|08 Nov 97
ID|FBab0025248
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
}

ACLA|Inversion
BPT|2.5;10.8
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|2.5;10.8
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025249	CLA 1 Inversion	GSYM 1 Dalb\In(3)W5	DT 1 27 Nov 05	RESZ 954	CLOC 1 27.0;30.2	REF 6	
ABSY|Dalb\In(3)W5
DT|27 Nov 05
ID|FBab0025249
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0044120
|Mather and Casu
|1986
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
REFM|FBrf0051887
|Casu
|1990
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|27.0;30.2
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|27.0;30.2
MU|natural population
COR|Thailand
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0044120
|Mather and Casu
|1986
COR|Thailand
}

REFDSR
{
RDID|FBrf0051887
|Casu
|1990
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025250	CLA 1 Inversion	GSYM 1 Dalb\In(3)X5	DT 1 08 Nov 97	RESZ 728	CLOC 1 21.6;40.4	REF 4	
ABSY|Dalb\In(3)X5
DT|08 Nov 97
ID|FBab0025250
REF
{
REFM|FBrf0036173
|Mather and Balwin
|1981
|-1
REFM|FBrf0037693
|Mather and Balwin
|1982
|-1
REFM|FBrf0034496
|Mather and Balwin
|1980
|-1
REFM|FBrf0039178
|Mather and Pope
|1983
|-1
}

ACLA|Inversion
BPT|21.6;40.4
MU|natural population
COR|Thailand
AM|complex
REFDSR
{
RDID|FBrf0034496
|Mather and Balwin
|1980
BPT|21.6;40.4
MU|natural population
COR|Thailand
AM|complex
}

REFDSR
{
RDID|FBrf0036173
|Mather and Balwin
|1981
COR|Thailand
}

REFDSR
{
RDID|FBrf0037693
|Mather and Balwin
|1982
COR|Thailand
}

REFDSR
{
RDID|FBrf0039178
|Mather and Pope
|1983
COR|Thailand
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025251	CLA 1 Inversion	GSYM 1 Dalb\In(3)Z6	DT 1 08 Nov 97	RESZ 514	CLOC 1 42.0;47.2	REF 3	
ABSY|Dalb\In(3)Z6
DT|08 Nov 97
SYN|In(3)Q6
ID|FBab0025251
REF
{
REFM|FBrf0042214
|Mather and Pope
|1985
|-1
REFM|FBrf0090304
|Mather and Pope
|1984
|-1
REFM|FBrf0090303
|Mather and Pope
|1984
|-1
}

ACLA|Inversion
BPT|42.0;47.2
MU|natural population
COR|Thailand
REFDSR
{
RDID|FBrf0042214
|Mather and Pope
|1985
COR|Thailand
}

REFDSR
{
RDID|FBrf0090303
|Mather and Pope
|1984
BPT|42.0;47.2
MU|natural population
COR|Thailand
SYN|In(3)Q6
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025252	CLA 1 Inversion	GSYM 1 Dame\In(2)a	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(2)a
DT|08 Nov 97
ID|FBab0025252
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025253	CLA 1 Inversion	GSYM 1 Dame\In(2)b	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(2)b
DT|08 Nov 97
ID|FBab0025253
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025254	CLA 1 Inversion	GSYM 1 Dame\In(2)c	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(2)c
DT|08 Nov 97
ID|FBab0025254
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025255	CLA 1 Inversion	GSYM 1 Dame\In(3)a	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(3)a
DT|08 Nov 97
ID|FBab0025255
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025256	CLA 1 Inversion	GSYM 1 Dame\In(4)a	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(4)a
DT|08 Nov 97
ID|FBab0025256
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025257	CLA 1 Inversion	GSYM 1 Dame\In(4)b	DT 1 22 Aug 04	RESZ 484	CLOC 1 [];[]	REF 2	
ABSY|Dame\In(4)b
DT|22 Aug 04
SYN|Dame\In(4)ab
ID|FBab0025257
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
REFM|FBrf0167635
|McAllister
|2003
|-1
}

ACLA|Inversion
BPT|[];[]
MU|natural population
PRG|Dame\In(4)a
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
PRG|Dame\In(4)a
}

REFDSR
{
RDID|FBrf0167635
|McAllister
|2003
BPT|[];[]
ACLA|Inversion
MU|natural population
SYN|Dame\In(4)ab
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025258	CLA 1 Inversion	GSYM 1 Dame\In(5)a	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(5)a
DT|08 Nov 97
ID|FBab0025258
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025259	CLA 1 Inversion	GSYM 1 Dame\In(5)b	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(5)b
DT|08 Nov 97
ID|FBab0025259
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025260	CLA 1 Inversion	GSYM 1 Dame\In(X)a	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(X)a
DT|08 Nov 97
ID|FBab0025260
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025261	CLA 1 Inversion	GSYM 1 Dame\In(X)b	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(X)b
DT|08 Nov 97
ID|FBab0025261
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025262	CLA 1 Inversion	GSYM 1 Dame\In(X)c	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dame\In(X)c
DT|08 Nov 97
ID|FBab0025262
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027552	CLA 1 Aberration	GSYM 1 Dana\Ab(2)Dana\Om(2D)<up>63R28</up>	DT 1 29 Oct 99	RESZ 646	REF 1	
ABSY|Dana\Ab(2)Dana\Om(2D)<up>63R28</up>
DT|29 Oct 99
ID|FBab0027552
REF
{
REFM|FBrf0054576
|Matsubayashi et al.
|1991
|-1
}

ASAL|FBal0038374 == Dana\Om(2D)<up>63R28</up>
MU|diepoxybutane
PRG|Dana\Om(2D)<up>63</up>
CCM|Associated with an undetermined rearrangement, probably a small insertion
|or a small duplication.
AMD|Dana\Om(2D)
REFDSR
{
RDID|FBrf0054576
|Matsubayashi et al.
|1991
MU|diepoxybutane
PRG|Dana\Om(2D)<up>63</up>
CCM|Associated with an undetermined rearrangement, probably a small insertion
|or a small duplication.
AMD|Dana\Om(2D)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027403	CLA 1 Deficiency	GSYM 1 Dana\Df(2R)Om(2D)<up>63R23</up>	DT 1 29 Oct 99	RESZ 688	CLOC 1 48B;48B	REF 2	
ABSY|Dana\Df(2R)Om(2D)<up>63R23</up>
DT|29 Oct 99
ID|FBab0027403
REF
{
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0054576
|Matsubayashi et al.
|1991
|-1
}

ASAL|FBal0066195 == Dana\Om(2D)<up>63R23</up>
BPT|48B;48B
ACLA|Deficiency
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
REFDSR
{
RDID|FBrf0054576
|Matsubayashi et al.
|1991
BPT|48B;48B
ACLA|Deficiency
MU|diepoxybutane
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
BPT|48B;48B
ACLA|Deficiency
MU|spontaneous
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027404	CLA 1 Deficiency	GSYM 1 Dana\Df(2R)Om(2D)<up>63R6</up>	DT 1 29 Oct 99	RESZ 682	CLOC 1 48B;48B	REF 2	
ABSY|Dana\Df(2R)Om(2D)<up>63R6</up>
DT|29 Oct 99
ID|FBab0027404
REF
{
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0054576
|Matsubayashi et al.
|1991
|-1
}

ASAL|FBal0066194 == Dana\Om(2D)<up>63R6</up>
BPT|48B;48B
ACLA|Deficiency
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
REFDSR
{
RDID|FBrf0054576
|Matsubayashi et al.
|1991
BPT|48B;48B
ACLA|Deficiency
MU|&ggr; ray
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
BPT|48B;48B
ACLA|Deficiency
MU|spontaneous
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022037	CLA 1 Inversion	GSYM 1 Dana\In(1)B-H1-73R1	DT 1 12 Nov 00	RESZ 552	REF 2	
ABSY|Dana\In(1)B-H1-73R1
DT|12 Nov 00
SYN|Dana\In(1)Om(1D)-73R1
ID|FBab0022037
REF
{
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0053894
|Tanda and Corces
|1991
|-1
}

ASAL|FBal0029180 == Dana\B-H1<up>73R1</up>
ACLA|Inversion
AMD|Dana\B-H1
REFDSR
{
RDID|FBrf0053894
|Tanda and Corces
|1991
BPT|1Lt--1cen;13A
ACLA|Inversion
OTH|Second breakpoint not reported.
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
BPT|12A;13A
ACLA|Inversion
AMD|Dana\B-H1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022038	CLA 1 Inversion	GSYM 1 Dana\In(1)B-H1-9R64	DT 1 12 Nov 00	RESZ 552	REF 2	
ABSY|Dana\In(1)B-H1-9R64
DT|12 Nov 00
SYN|Dana\In(1)Om(1D)-9R64
ID|FBab0022038
REF
{
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0053894
|Tanda and Corces
|1991
|-1
}

ASAL|FBal0029183 == Dana\B-H1<up>9R64</up>
ACLA|Inversion
AMD|Dana\B-H1
REFDSR
{
RDID|FBrf0053894
|Tanda and Corces
|1991
BPT|13A;1Lt--1cen
ACLA|Inversion
OTH|Second breakpoint not reported.
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
BPT|11B;13A
ACLA|Inversion
AMD|Dana\B-H1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023409	CLA 1 Aberration	GSYM 1 Dana\In(1L)A	DT 1 15 Dec 97	RESZ 901	REF 7	
ABSY|Dana\In(1L)A
DT|15 Dec 97
SYN|Dana\In(XL)A
ID|FBab0023409
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0036072
|Tripathy et al.
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Futch 66; Hinton and Downs 75; Tripathy, Dasmohapatra and Das 81; Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea, India, Guam.
CCM|FBrf0063916: 4A;10D, Seecof:5.7;16.0, Hinton and Downs: 4A;8C.
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\In(XL)A
}

REFDSR
{
RDID|FBrf0063921
|Tomimura et al.
|1993
SYN|Dana\In(XL)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023410	CLA 1 Aberration	GSYM 1 Dana\In(1L)B	DT 1 15 Dec 97	RESZ 756	REF 6	
ABSY|Dana\In(1L)B
DT|15 Dec 97
SYN|Dana\In(XL)B
ID|FBab0023410
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Futch 66; Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 11B;13C, Seecof: 16.7;20.3, Hinton and Downs: 9A;11B.
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\In(XL)B
}

REFDSR
{
RDID|FBrf0063921
|Tomimura et al.
|1993
SYN|Dana\In(XL)B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023411	CLA 1 Aberration	GSYM 1 Dana\In(1L)b	DT 1 15 Dec 97	RESZ 456	REF 3	
ABSY|Dana\In(1L)b
DT|15 Dec 97
SYN|Dana\In(XL)b
ID|FBab0023411
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0023591
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|natural population
COR|South India.
CCM|Rajeshwari: 4D;6B.
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\In(XL)b
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023412	CLA 1 Aberration	GSYM 1 Dana\In(1R)A	DT 1 15 Dec 97	RESZ 617	REF 5	
ABSY|Dana\In(1R)A
DT|15 Dec 97
SYN|Dana\In(XR)A
ID|FBab0023412
REF
{
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Futch 66; Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 16C;19D, Seecof:2.3;8.5, Hinton and Downs:14B;17A.
REFDSR
{
RDID|FBrf0063921
|Tomimura et al.
|1993
SYN|Dana\In(XR)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023413	CLA 1 Aberration	GSYM 1 Dana\In(2L)A	DT 1 01 Feb 00	RESZ 1143	REF 12	
ABSY|Dana\In(2L)A
DT|01 Feb 00
SYN|Dana\C II L, alpha.
ID|FBab0023413
REF
{
REFM|FBrf0048186
|Hinton
|1988
|-1
REFM|FBrf0006047
|Dobzhansky and Dreyfus
|1943
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0008473
|Shirai and Moriwaki
|1952
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0080448
|Tobari and Moriwaki
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
REFM|FBrf0003683
|Kaufmann
|1936
|-1
}

DIS|Kaufmann 36; Kikkawa 38; Dobzhansky and Dreyfus 43; Shirai and Moriwaki 52; Futch 66; Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 22C;37C, Seecof: 3.1;30.5, Hinton and Downs: 19B;36C.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2LA
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023414	CLA 1 Aberration	NAM 1 alpha	GSYM 1 Dana\In(2L)AL	DT 1 27 Nov 05	RESZ 2883	REF 16	
ABSY|Dana\In(2L)AL
DT|27 Nov 05
SYN|AL
|In(2L)alpha
NAM|alpha
ID|FBab0023414
REF
{
REFM|FBrf0088970
|Singh
|1996
|-1
REFM|FBrf0073447
|Jamiruddin et al.
|1994
|-1
REFM|FBrf0086369
|Das et al.
|1993
|-1
REFM|FBrf0174366
|Som and Singh
|2004
|-1
REFM|FBrf0130085
|Singh
|2000
|-1
REFM|FBrf0054281
|Singh and Mohanty
|1991
|-1
REFM|FBrf0084377
|Singh et al.
|1995
|-1
REFM|FBrf0076624
|Das et al.
|1994
|-1
REFM|FBrf0052051
|Singh and Mohanty
|1990
|-1
REFM|FBrf0052100
|Singh and Mohanty
|1991
|-1
REFM|FBrf0081811
|Das et al.
|1994
|-1
REFM|FBrf0148938
|Singh and Som
|2001
|-1
REFM|FBrf0082327
|Mathew and Singh
|1995
|-1
REFM|FBrf0053595
|Singh
|1991
|-1
REFM|FBrf0105328
|Singh
|1998
|-1
REFM|FBrf0053593
|Singh and Singh
|1991
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0052051
|Singh and Mohanty
|1990
SYN|AL
}

REFDSR
{
RDID|FBrf0052100
|Singh and Mohanty
|1991
PHP|Crossing-over in the X chromosome is enhanced in flies heterozygous
|for @Dana\In(2L)AL@.
SYN|AL
}

REFDSR
{
RDID|FBrf0053593
|Singh and Singh
|1991
SYN|AL
}

REFDSR
{
RDID|FBrf0053595
|Singh
|1991
MU|natural population
OTH|Cosmopolitan inversion.
SYN|AL
}

REFDSR
{
RDID|FBrf0054281
|Singh and Mohanty
|1991
SYN|AL
}

REFDSR
{
RDID|FBrf0073447
|Jamiruddin et al.
|1994
OTH|@Dana\In(2L)AL@, @Dana\In(3L)DE@ and @Dana\In(3R)ET@ are cosmopolitan
|in distribution, genetic differentiation does exist among populations
|of different geographical areas and there is no evidence for intra-
|or interchromosomal interactions in natural populations.
}

REFDSR
{
RDID|FBrf0076624
|Das et al.
|1994
SYN|AL
}

REFDSR
{
RDID|FBrf0082327
|Mathew and Singh
|1995
MU|natural population
}

REFDSR
{
RDID|FBrf0084377
|Singh et al.
|1995
SYN|AL
|In(2L)alpha
}

REFDSR
{
RDID|FBrf0088970
|Singh
|1996
SYN|AL
}

REFDSR
{
RDID|FBrf0130085
|Singh
|2000
SYN|AL
}

REFDSR
{
RDID|FBrf0148938
|Singh and Som
|2001
PHP|There is a significant one-sided rare male mating advantage in favor
|of @Dana\In(2L)AL@ males.
SYN|AL
}

REFDSR
{
RDID|FBrf0174366
|Som and Singh
|2004
PHP|There is a one-sided rare male mating advantage for @Dana\In(2L)AL@/@Dana\In(2L)AL@
|males in female-choice experiments. Preferential mating is present
|within the strain having the @Dana\In(2L)AL@/@Dana\In(2L)AL@ karyotype.
SYN|AL
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023415	CLA 1 Aberration	GSYM 1 Dana\In(2L)B	DT 1 01 Feb 00	RESZ 714	REF 7	
ABSY|Dana\In(2L)B
DT|01 Feb 00
SYN|Dana\C II L O.
ID|FBab0023415
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
}

DIS|Kikkawa 38; Seecof 55; Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 37D;41B, Seecof: 30.3;34.4.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2LB
|2LC
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023416	CLA 1 Aberration	GSYM 1 Dana\In(2L)C	DT 1 15 Dec 97	RESZ 499	REF 5	
ABSY|Dana\In(2L)C
DT|15 Dec 97
SYN|Dana\In(2L)h.
ID|FBab0023416
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Seecof 56; Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 22A;28A, Seecof: 2.6;12.8.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023417	CLA 1 Aberration	GSYM 1 Dana\In(2L)D	DT 1 15 Dec 97	RESZ 566	REF 5	
ABSY|Dana\In(2L)D
DT|15 Dec 97
ID|FBab0023417
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch (66); Tomimura and Tobari.
CCM|FBrf0063916: 26C;30D, Seecof: 10.4;17.0.
PRG|Dana\In(2L)C
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023430	CLA 1 Aberration	GSYM 1 Dana\In(2L)d	DT 1 15 Dec 97	RESZ 361	REF 3	
ABSY|Dana\In(2L)d
DT|15 Dec 97
ID|FBab0023430
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0023523
|Nirmala Sajjan and Krishnamurthy
|1972
|-1
}

DIS|Sajjan and Krishnamurthy 72.
MU|natural population
COR|India.
CCM|Rajeshwari: 17A;24F.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023418	CLA 1 Aberration	GSYM 1 Dana\In(2L)E	DT 1 15 Dec 97	RESZ 564	REF 5	
ABSY|Dana\In(2L)E
DT|15 Dec 97
ID|FBab0023418
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 29A;39C, Seecof: 14.8;31.6.
PRG|Dana\In(2L)B
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023431	CLA 1 Aberration	GSYM 1 Dana\In(2L)e	DT 1 09 Mar 99	RESZ 384	REF 3	
ABSY|Dana\In(2L)e
DT|09 Mar 99
ID|FBab0023431
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0023591
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|natural population
COR|South India.
CCM|Rajeshwari: 20D;31E on @Dana\In(2L)A@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023419	CLA 1 Aberration	GSYM 1 Dana\In(2L)F	DT 1 15 Dec 97	RESZ 564	REF 5	
ABSY|Dana\In(2L)F
DT|15 Dec 97
ID|FBab0023419
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 30C;41C, Seecof: 16.8;34.8.
PRG|Dana\In(2L)E
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)E
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023432	CLA 1 Aberration	GSYM 1 Dana\In(2L)f	DT 1 09 Mar 99	RESZ 388	REF 3	
ABSY|Dana\In(2L)f
DT|09 Mar 99
ID|FBab0023432
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0023591
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|natural population
COR|South India.
CCM|Rajeshwari: 23C;26D within @Dana\In(2L)A@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023420	CLA 1 Aberration	GSYM 1 Dana\In(2L)G	DT 1 15 Dec 97	RESZ 562	REF 5	
ABSY|Dana\In(2L)G
DT|15 Dec 97
ID|FBab0023420
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 21D;25B, Seecof: 2.3;9.2.
PRG|Dana\In(2L)C
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023421	CLA 1 Aberration	GSYM 1 Dana\In(2L)H	DT 1 15 Dec 97	RESZ 355	REF 3	
ABSY|Dana\In(2L)H
DT|15 Dec 97
ID|FBab0023421
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 35C;36C, Hinton and Downs: 34C;36A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023422	CLA 1 Aberration	GSYM 1 Dana\In(2L)I	DT 1 15 Dec 97	RESZ 441	REF 3	
ABSY|Dana\In(2L)I
DT|15 Dec 97
ID|FBab0023422
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 32A;40C.
PRG|Dana\In(2L)B
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023423	CLA 1 Aberration	GSYM 1 Dana\In(2L)J	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2L)J
DT|15 Dec 97
ID|FBab0023423
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 21A;26B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023424	CLA 1 Aberration	GSYM 1 Dana\In(2L)K	DT 1 15 Dec 97	RESZ 341	REF 3	
ABSY|Dana\In(2L)K
DT|15 Dec 97
ID|FBab0023424
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Thailand.
CCM|FBrf0063916: 21C;26C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023425	CLA 1 Aberration	GSYM 1 Dana\In(2L)L	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2L)L
DT|15 Dec 97
ID|FBab0023425
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 23D;32C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023426	CLA 1 Aberration	GSYM 1 Dana\In(2L)M	DT 1 15 Dec 97	RESZ 510	REF 4	
ABSY|Dana\In(2L)M
DT|15 Dec 97
SYN|Dana\AL<up>in</up>
ID|FBab0023426
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0039376
|Singh
|1983
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Malaysia.
CCM|FBrf0063916: 30C;37D.
PRG|Dana\In(2L)A
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023427	CLA 1 Aberration	GSYM 1 Dana\In(2L)N	DT 1 15 Dec 97	RESZ 341	REF 3	
ABSY|Dana\In(2L)N
DT|15 Dec 97
ID|FBab0023427
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Thailand.
CCM|FBrf0063916: 26A;36C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023428	CLA 1 Aberration	GSYM 1 Dana\In(2L)O	DT 1 15 Dec 97	RESZ 441	REF 3	
ABSY|Dana\In(2L)O
DT|15 Dec 97
ID|FBab0023428
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 29D;39D.
PRG|Dana\In(2L)A
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023429	CLA 1 Aberration	GSYM 1 Dana\In(2L)P	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2L)P
DT|15 Dec 97
ID|FBab0023429
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 32D;43D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023433	CLA 1 Aberration	GSYM 1 Dana\In(2LR)	DT 1 15 Dec 97	RESZ 357	REF 3	
ABSY|Dana\In(2LR)
DT|15 Dec 97
ID|FBab0023433
REF
{
REFM|FBrf0022148
|Singh et al.
|1971
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Singh, Mishra and Jha 71.
MU|natural population
COR|India.
CCM|Ray-Chaudhuri and Jha: 14A;2B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023434	CLA 1 Aberration	GSYM 1 Dana\In(2LR)9	DT 1 09 Mar 99	RESZ 391	REF 3	
ABSY|Dana\In(2LR)9
DT|09 Mar 99
ID|FBab0023434
REF
{
REFM|FBrf0023592
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|natural population
COR|South India.
CCM|Rajeshwari: 26F;45A with @Dana\In(2L)A@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023435	CLA 1 Aberration	GSYM 1 Dana\In(2LR)A	DT 1 15 Dec 97	RESZ 543	REF 5	
ABSY|Dana\In(2LR)A
DT|15 Dec 97
ID|FBab0023435
REF
{
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Futch 66; Hinton and Downs 75.
MU|natural population
COR|Niue Island.
CCM|FBrf0063916: 41D;46D, Seecof: 35.2;28.9, Hinton and Downs: 38C;44B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023440	CLA 1 Aberration	GSYM 1 Dana\In(2LR)a	DT 1 15 Dec 97	RESZ 369	REF 4	
ABSY|Dana\In(2LR)a
DT|15 Dec 97
ID|FBab0023440
REF
{
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0010075
|Freire-Maia
|1955
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Freire-Maia 53.
MU|natural population
COR|Brazil.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023436	CLA 1 Aberration	GSYM 1 Dana\In(2LR)B	DT 1 15 Dec 97	RESZ 278	REF 2	
ABSY|Dana\In(2LR)B
DT|15 Dec 97
ID|FBab0023436
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Guam.
CCM|FBrf0063916: 42B;45D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023437	CLA 1 Aberration	GSYM 1 Dana\In(2LR)B,Ubx	DT 1 09 Mar 99	RESZ 254	REF 1	
ABSY|Dana\In(2LR)B,Ubx
DT|09 Mar 99
ID|FBab0023437
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 79.
COR|Arose as a single Ubx male from @Dana\px@ females x @Dana\ca@ males.
CCM|Hinton and Downs: 27B;52B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023438	CLA 1 Aberration	GSYM 1 Dana\In(2LR)C	DT 1 15 Dec 97	RESZ 280	REF 2	
ABSY|Dana\In(2LR)C
DT|15 Dec 97
ID|FBab0023438
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Noumea.
CCM|FBrf0063916: 43D;48A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0025263	CLA 1 Inversion	GSYM 1 Dana\In(2LR)d	DT 1 08 Nov 97	RESZ 413	REF 2	
ABSY|Dana\In(2LR)d
DT|08 Nov 97
SYN|In(2LR)D
ID|FBab0025263
REF
{
REFM|FBrf0009412
|Freire-Maia
|1954
|-1
REFM|FBrf0008966
|Freire-Maia
|1953
|-1
}

ACLA|Inversion
MU|natural population
COR|Brazil.
REFDSR
{
RDID|FBrf0008966
|Freire-Maia
|1953
MU|natural population
COR|Brazil.
SYN|In(2LR)D
}

REFDSR
{
RDID|FBrf0009412
|Freire-Maia
|1954
SYN|In(2LR)D
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023439	CLA 1 Aberration	GSYM 1 Dana\In(2LR)Lo	DT 1 28 Sep 98	RESZ 195	REF 1	
ABSY|Dana\In(2LR)Lo
DT|28 Sep 98
ID|FBab0023439
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

ASAL|FBal0038263 == Dana\Lo<up>1</up>
CCM|FBrf0063916: 41B;48A
}
# EOR
ABSR
{
RETE|ID 1 FBab0023441	CLA 1 Aberration	GSYM 1 Dana\In(2R)A	DT 1 01 Feb 00	RESZ 864	REF 9	
ABSY|Dana\In(2R)A
DT|01 Feb 00
SYN|Dana\In(2R)d.
ID|FBab0023441
REF
{
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0008473
|Shirai and Moriwaki
|1952
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
REFM|FBrf0003683
|Kaufmann
|1936
|-1
}

DIS|Kaufmann 36; Kikkawa 38; Shirai and Moriwaki 52; Seecof 55; Futch 66; Tomimura and Tobari.
CCM|FBrf0063916: 55B;62C, Seecof: 3.4;14.0.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2RA
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023456	CLA 1 Aberration	GSYM 1 Dana\In(2R)a	DT 1 15 Dec 97	RESZ 269	REF 2	
ABSY|Dana\In(2R)a
DT|15 Dec 97
ID|FBab0023456
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0023523
|Nirmala Sajjan and Krishnamurthy
|1972
|-1
}

MU|natural population
COR|India.
CCM|Rajeshwari: 43D;47A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023442	CLA 1 Aberration	GSYM 1 Dana\In(2R)B	DT 1 15 Dec 97	RESZ 449	REF 3	
ABSY|Dana\In(2R)B
DT|15 Dec 97
ID|FBab0023442
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Noumea, Papua New Guinea.
CCM|FBrf0063916: 50B;58D.
PRG|Dana\In(2L)A
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023457	CLA 1 Aberration	GSYM 1 Dana\In(2R)b	DT 1 15 Dec 97	RESZ 269	REF 2	
ABSY|Dana\In(2R)b
DT|15 Dec 97
ID|FBab0023457
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0023523
|Nirmala Sajjan and Krishnamurthy
|1972
|-1
}

MU|natural population
COR|India.
CCM|Rajeshwari: 45C;49C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023443	CLA 1 Aberration	GSYM 1 Dana\In(2R)C	DT 1 15 Dec 97	RESZ 605	REF 5	
ABSY|Dana\In(2R)C
DT|15 Dec 97
ID|FBab0023443
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 60D;63D, Seecof: 1.7;7.4.
PRG|Dana\In(2L)A
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023444	CLA 1 Aberration	GSYM 1 Dana\In(2R)D	DT 1 15 Dec 97	RESZ 515	REF 5	
ABSY|Dana\In(2R)D
DT|15 Dec 97
ID|FBab0023444
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 48C;52B, Seecof: 19.3;25.6.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023445	CLA 1 Aberration	GSYM 1 Dana\In(2R)E	DT 1 15 Dec 97	RESZ 341	REF 3	
ABSY|Dana\In(2R)E
DT|15 Dec 97
ID|FBab0023445
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Thailand.
CCM|FBrf0063916: 53D;60A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023446	CLA 1 Aberration	GSYM 1 Dana\In(2R)F	DT 1 15 Dec 97	RESZ 338	REF 3	
ABSY|Dana\In(2R)F
DT|15 Dec 97
ID|FBab0023446
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Kenya.
CCM|FBrf0063916: 51B;55B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023458	CLA 1 Aberration	GSYM 1 Dana\In(2R)f	DT 1 15 Dec 97	RESZ 275	REF 2	
ABSY|Dana\In(2R)f
DT|15 Dec 97
ID|FBab0023458
REF
{
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Bikini.
CCM|Seecof: 4.9;7.2.
}
# EOR
ABSR
{
RETE|ID 1 FBab0027405	CLA 1 Aberration	GSYM 1 Dana\In(2R)G	DT 1 15 Dec 97	RESZ 129	REF 1	
ABSY|Dana\In(2R)G
DT|15 Dec 97
ID|FBab0027405
REF
{
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023447	CLA 1 Aberration	GSYM 1 Dana\In(2R)H	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2R)H
DT|15 Dec 97
ID|FBab0023447
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 49D;61A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023448	CLA 1 Aberration	GSYM 1 Dana\In(2R)I	DT 1 15 Dec 97	RESZ 337	REF 3	
ABSY|Dana\In(2R)I
DT|15 Dec 97
ID|FBab0023448
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Fiji.
CCM|FBrf0063916: 55D;60C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023449	CLA 1 Aberration	GSYM 1 Dana\In(2R)J	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2R)J
DT|15 Dec 97
ID|FBab0023449
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 49A;63C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023450	CLA 1 Aberration	GSYM 1 Dana\In(2R)K	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(2R)K
DT|15 Dec 97
ID|FBab0023450
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 50C;55C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023451	CLA 1 Aberration	GSYM 1 Dana\In(2R)L	DT 1 15 Dec 97	RESZ 441	REF 3	
ABSY|Dana\In(2R)L
DT|15 Dec 97
ID|FBab0023451
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 51D;58C.
PRG|Dana\In(2L)K
REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
PRG|Dana\In(2L)K
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023452	CLA 1 Aberration	GSYM 1 Dana\In(2R)M	DT 1 15 Dec 97	RESZ 339	REF 3	
ABSY|Dana\In(2R)M
DT|15 Dec 97
ID|FBab0023452
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Brazil.
CCM|FBrf0063916: 51C;55B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023453	CLA 1 Aberration	GSYM 1 Dana\In(2R)N	DT 1 15 Dec 97	RESZ 339	REF 3	
ABSY|Dana\In(2R)N
DT|15 Dec 97
ID|FBab0023453
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Brazil.
CCM|FBrf0063916: 47C;56B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023454	CLA 1 Aberration	GSYM 1 Dana\In(2R)O	DT 1 15 Dec 97	RESZ 339	REF 3	
ABSY|Dana\In(2R)O
DT|15 Dec 97
ID|FBab0023454
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Brazil.
CCM|FBrf0063916: 48B;58D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023455	CLA 1 Inversion	NAM 1 zeta	GSYM 1 Dana\In(2R)ZE	DT 1 27 Nov 05	RESZ 1124	CLOC 1 2A;9B	REF 7	
ABSY|Dana\In(2R)ZE
DT|27 Nov 05
SYN|ZE
|Dana\In(2R)&Zgr;E
|In(2R)zeta
NAM|zeta
ID|FBab0023455
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0084377
|Singh et al.
|1995
|-1
REFM|FBrf0052051
|Singh and Mohanty
|1990
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0052071
|Singh and Singh
|1990
|-1
REFM|FBrf0053593
|Singh and Singh
|1991
|-1
REFM|FBrf0082327
|Mathew and Singh
|1995
|-1
}

DIS|Singh and Singh 91.
COR|Isofemale line from India.
CCM|Ray-Chaudhuri and Jha: 2A;9B.
BPT|2A;9B
ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0052051
|Singh and Mohanty
|1990
SYN|ZE
}

REFDSR
{
RDID|FBrf0053593
|Singh and Singh
|1991
BPT|2A;9B
ACLA|Inversion
SYN|ZE
}

REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\In(2R)&Zgr;E
}

REFDSR
{
RDID|FBrf0082327
|Mathew and Singh
|1995
MU|natural population
}

REFDSR
{
RDID|FBrf0084377
|Singh et al.
|1995
SYN|In(2R)zeta
|ZE
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023459	CLA 1 Aberration	GSYM 1 Dana\In(3L)A	DT 1 01 Feb 00	RESZ 989	REF 10	
ABSY|Dana\In(3L)A
DT|01 Feb 00
SYN|Dana\CIIIL
|Dana\delta.
ID|FBab0023459
REF
{
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0008473
|Shirai and Moriwaki
|1952
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
REFM|FBrf0003683
|Kaufmann
|1936
|-1
}

DIS|Kaufmann 36; Kikkawa 38; Shirai and Moriwaki 52; Seecof 55; Futch 66; Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 64A;75B, Seecof: 1.0;19.5, Hinton and Downs: 62A;75A.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|3LA
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023470	CLA 1 Aberration	GSYM 1 Dana\In(3L)a	DT 1 15 Dec 97	RESZ 337	REF 3	
ABSY|Dana\In(3L)a
DT|15 Dec 97
ID|FBab0023470
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Bikini.
CCM|Seecof: 22.4;26.5.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023460	CLA 1 Aberration	GSYM 1 Dana\In(3L)B	DT 1 15 Dec 97	RESZ 505	REF 5	
ABSY|Dana\In(3L)B
DT|15 Dec 97
ID|FBab0023460
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66.
MU|natural population
COR|Light form in American Samoa.
CCM|FBrf0063916: 66B;71B, Seecof: 5.9;12.4.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023461	CLA 1 Aberration	GSYM 1 Dana\In(3L)C	DT 1 15 Dec 97	RESZ 514	REF 5	
ABSY|Dana\In(3L)C
DT|15 Dec 97
ID|FBab0023461
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 65A;73D, Seecof: 2.3;15.4.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023471	CLA 1 Aberration	GSYM 1 Dana\In(3L)c	DT 1 15 Dec 97	RESZ 336	REF 3	
ABSY|Dana\In(3L)c
DT|15 Dec 97
ID|FBab0023471
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Majuro.
CCM|Seecof: 3.1;12.5.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023462	CLA 1 Aberration	GSYM 1 Dana\In(3L)Cu	DT 1 16 Jun 98	RESZ 150	
ABSY|Dana\In(3L)Cu
DT|16 Jun 98
ID|FBab0023462
ASAL|FBal0038250 == Dana\Cu<up>1</up>
DIS|Bogahawatta 82k5.
MU|spontaneous
CCM|80B;81BC
}
# EOR
ABSR
{
RETE|ID 1 FBab0023463	CLA 1 Aberration	GSYM 1 Dana\In(3L)D	DT 1 09 Mar 99	RESZ 389	REF 3	
ABSY|Dana\In(3L)D
DT|09 Mar 99
ID|FBab0023463
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton and Downs 75.
COR|Laboratory stock (@Dana\bri@ @Dana\Rf@ @Dana\mot@).
CCM|FBrf0063916: 76C;81D, Hinton and Downs: 76B;81C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023464	CLA 1 Aberration	NAM 1 delta	GSYM 1 Dana\In(3L)DE	DT 1 27 Nov 05	RESZ 2266	REF 14	
ABSY|Dana\In(3L)DE
DT|27 Nov 05
SYN|DE
|In(3L)delta
NAM|delta
ID|FBab0023464
REF
{
REFM|FBrf0088970
|Singh
|1996
|-1
REFM|FBrf0073447
|Jamiruddin et al.
|1994
|-1
REFM|FBrf0086369
|Das et al.
|1993
|-1
REFM|FBrf0130085
|Singh
|2000
|-1
REFM|FBrf0054281
|Singh and Mohanty
|1991
|-1
REFM|FBrf0084377
|Singh et al.
|1995
|-1
REFM|FBrf0076624
|Das et al.
|1994
|-1
REFM|FBrf0052051
|Singh and Mohanty
|1990
|-1
REFM|FBrf0052100
|Singh and Mohanty
|1991
|-1
REFM|FBrf0081811
|Das et al.
|1994
|-1
REFM|FBrf0082327
|Mathew and Singh
|1995
|-1
REFM|FBrf0053595
|Singh
|1991
|-1
REFM|FBrf0052071
|Singh and Singh
|1990
|-1
REFM|FBrf0105328
|Singh
|1998
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0052051
|Singh and Mohanty
|1990
SYN|DE
}

REFDSR
{
RDID|FBrf0052071
|Singh and Singh
|1990
}

REFDSR
{
RDID|FBrf0052100
|Singh and Mohanty
|1991
PHP|Crossing-over in the X chromosome is enhanced in flies heterozygous
|for @Dana\In(3L)DE@.
SYN|DE
}

REFDSR
{
RDID|FBrf0053595
|Singh
|1991
MU|natural population
OTH|Cosmopolitan inversion.
SYN|DE
}

REFDSR
{
RDID|FBrf0054281
|Singh and Mohanty
|1991
SYN|DE
}

REFDSR
{
RDID|FBrf0073447
|Jamiruddin et al.
|1994
OTH|@Dana\In(2L)AL@, @Dana\In(3L)DE@ and @Dana\In(3R)ET@ are cosmopolitan
|in distribution, genetic differentiation does exist among populations
|of different geographical areas and there is no evidence for intra-
|or interchromosomal interactions in natural populations.
}

REFDSR
{
RDID|FBrf0076624
|Das et al.
|1994
SYN|DE
}

REFDSR
{
RDID|FBrf0082327
|Mathew and Singh
|1995
MU|natural population
}

REFDSR
{
RDID|FBrf0084377
|Singh et al.
|1995
SYN|DE
|In(3L)delta
}

REFDSR
{
RDID|FBrf0088970
|Singh
|1996
SYN|DE
}

REFDSR
{
RDID|FBrf0130085
|Singh
|2000
SYN|DE
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023465	CLA 1 Aberration	GSYM 1 Dana\In(3L)E	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3L)E
DT|15 Dec 97
ID|FBab0023465
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 65B;78A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023466	CLA 1 Aberration	GSYM 1 Dana\In(3L)F	DT 1 15 Dec 97	RESZ 348	REF 3	
ABSY|Dana\In(3L)F
DT|15 Dec 97
ID|FBab0023466
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|The Philippines.
CCM|FBrf0063916: 64A;78D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023467	CLA 1 Aberration	GSYM 1 Dana\In(3L)G	DT 1 15 Dec 97	RESZ 338	REF 3	
ABSY|Dana\In(3L)G
DT|15 Dec 97
ID|FBab0023467
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Tonga.
CCM|FBrf0063916: 76C;80A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023472	CLA 1 Aberration	GSYM 1 Dana\In(3L)g	DT 1 15 Dec 97	RESZ 335	REF 3	
ABSY|Dana\In(3L)g
DT|15 Dec 97
ID|FBab0023472
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Bikini.
CCM|Seecof: 6.2;8.2.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023468	CLA 1 Aberration	GSYM 1 Dana\In(3L)H	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3L)H
DT|15 Dec 97
ID|FBab0023468
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 65B;75B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023469	CLA 1 Aberration	GSYM 1 Dana\In(3L)I	DT 1 15 Dec 97	RESZ 338	REF 3	
ABSY|Dana\In(3L)I
DT|15 Dec 97
ID|FBab0023469
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Nauru.
CCM|FBrf0063916: 72D;78D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023473	CLA 1 Aberration	GSYM 1 Dana\In(3LR)A	DT 1 15 Dec 97	RESZ 431	REF 4	
ABSY|Dana\In(3LR)A
DT|15 Dec 97
ID|FBab0023473
REF
{
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66.
MU|natural population
COR|American Samoa.
CCM|FBrf0063916: 74C;96D, Seecof:18.3;8.0.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023482	CLA 1 Aberration	GSYM 1 Dana\In(3LR)a	DT 1 15 Dec 97	RESZ 767	REF 7	
ABSY|Dana\In(3LR)a
DT|15 Dec 97
SYN|In(3LR)A
ID|FBab0023482
REF
{
REFM|FBrf0008430
|Freire-Maia
|1952
|-1
REFM|FBrf0009412
|Freire-Maia
|1954
|-1
REFM|FBrf0008966
|Freire-Maia
|1953
|-1
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0010075
|Freire-Maia
|1955
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Freire-Maia 52.
MU|natural population
COR|Brazil.
REFDSR
{
RDID|FBrf0008430
|Freire-Maia
|1952
SYN|In(3LR)A
}

REFDSR
{
RDID|FBrf0008966
|Freire-Maia
|1953
SYN|In(3LR)A
}

REFDSR
{
RDID|FBrf0009412
|Freire-Maia
|1954
SYN|In(3LR)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023474	CLA 1 Aberration	GSYM 1 Dana\In(3LR)B	DT 1 15 Dec 97	RESZ 428	REF 4	
ABSY|Dana\In(3LR)B
DT|15 Dec 97
ID|FBab0023474
REF
{
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66.
MU|natural population
COR|Niue Island.
CCM|FBrf0063916: 66C;98A, Seecof: 5.0;5.5.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023483	CLA 1 Aberration	GSYM 1 Dana\In(3LR)b	DT 1 15 Dec 97	RESZ 767	REF 7	
ABSY|Dana\In(3LR)b
DT|15 Dec 97
SYN|In(3LR)B
ID|FBab0023483
REF
{
REFM|FBrf0008430
|Freire-Maia
|1952
|-1
REFM|FBrf0009412
|Freire-Maia
|1954
|-1
REFM|FBrf0008966
|Freire-Maia
|1953
|-1
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0010075
|Freire-Maia
|1955
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Freire-Maia 52.
MU|natural population
COR|Brazil.
REFDSR
{
RDID|FBrf0008430
|Freire-Maia
|1952
SYN|In(3LR)B
}

REFDSR
{
RDID|FBrf0008966
|Freire-Maia
|1953
SYN|In(3LR)B
}

REFDSR
{
RDID|FBrf0009412
|Freire-Maia
|1954
SYN|In(3LR)B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023475	CLA 1 Aberration	GSYM 1 Dana\In(3LR)C	DT 1 15 Dec 97	RESZ 282	REF 2	
ABSY|Dana\In(3LR)C
DT|15 Dec 97
ID|FBab0023475
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Thailand.
CCM|FBrf0063916: 73A;93B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023484	CLA 1 Aberration	GSYM 1 Dana\In(3LR)c	DT 1 15 Dec 97	RESZ 767	REF 7	
ABSY|Dana\In(3LR)c
DT|15 Dec 97
SYN|In(3LR)C
ID|FBab0023484
REF
{
REFM|FBrf0008430
|Freire-Maia
|1952
|-1
REFM|FBrf0009412
|Freire-Maia
|1954
|-1
REFM|FBrf0008966
|Freire-Maia
|1953
|-1
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0010075
|Freire-Maia
|1955
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Freire-Maia 52.
MU|natural population
COR|Brazil.
REFDSR
{
RDID|FBrf0008430
|Freire-Maia
|1952
SYN|In(3LR)C
}

REFDSR
{
RDID|FBrf0008966
|Freire-Maia
|1953
SYN|In(3LR)C
}

REFDSR
{
RDID|FBrf0009412
|Freire-Maia
|1954
SYN|In(3LR)C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023476	CLA 1 Aberration	GSYM 1 Dana\In(3LR)D	DT 1 09 Mar 99	RESZ 291	REF 1	
ABSY|Dana\In(3LR)D
DT|09 Mar 99
SYN|Dana\In(3LR)D, Bl[2]
ID|FBab0023476
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 80.
COR|As a single @Dana\Bl<up>2</up>@ female from @Dana\px@ females x @Dana\ca@ males.
CCM|Hinton and Downs: 71AB;88B-89A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023485	CLA 1 Aberration	GSYM 1 Dana\In(3LR)d	DT 1 15 Dec 97	RESZ 369	REF 4	
ABSY|Dana\In(3LR)d
DT|15 Dec 97
ID|FBab0023485
REF
{
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0010075
|Freire-Maia
|1955
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Freire-Maia 53.
MU|natural population
COR|Brazil.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023477	CLA 1 Aberration	GSYM 1 Dana\In(3LR)E	DT 1 29 Oct 99	RESZ 221	REF 1	
ABSY|Dana\In(3LR)E
DT|29 Oct 99
SYN|Dana\In(3LR)E, stw
ID|FBab0023477
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton.
COR|From @Dana\T(2;3)J@, Dana\Xa @Dana\ca@ @Dana\stw@.
}
# EOR
ABSR
{
RETE|ID 1 FBab0025264	CLA 1 Inversion	GSYM 1 Dana\In(3LR)e	DT 1 08 Nov 97	RESZ 413	REF 2	
ABSY|Dana\In(3LR)e
DT|08 Nov 97
SYN|In(3LR)E
ID|FBab0025264
REF
{
REFM|FBrf0009412
|Freire-Maia
|1954
|-1
REFM|FBrf0008966
|Freire-Maia
|1953
|-1
}

ACLA|Inversion
MU|natural population
COR|Brazil.
REFDSR
{
RDID|FBrf0008966
|Freire-Maia
|1953
MU|natural population
COR|Brazil.
SYN|In(3LR)E
}

REFDSR
{
RDID|FBrf0009412
|Freire-Maia
|1954
SYN|In(3LR)E
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023478	CLA 1 Aberration	GSYM 1 Dana\In(3LR)F	DT 1 15 Dec 97	RESZ 290	REF 2	
ABSY|Dana\In(3LR)F
DT|15 Dec 97
ID|FBab0023478
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 66D;92D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023479	CLA 1 Aberration	GSYM 1 Dana\In(3LR)G	DT 1 15 Dec 97	RESZ 279	REF 2	
ABSY|Dana\In(3LR)G
DT|15 Dec 97
ID|FBab0023479
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|India.
CCM|FBrf0063916: 73B;91C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023480	CLA 1 Aberration	GSYM 1 Dana\In(3LR)H	DT 1 15 Dec 97	RESZ 279	REF 2	
ABSY|Dana\In(3LR)H
DT|15 Dec 97
ID|FBab0023480
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|India.
CCM|FBrf0063916: 81A;91C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023481	CLA 1 Aberration	GSYM 1 Dana\In(3LR)I	DT 1 15 Dec 97	RESZ 279	REF 2	
ABSY|Dana\In(3LR)I
DT|15 Dec 97
ID|FBab0023481
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|India.
CCM|FBrf0063916: 75B;85C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023486	CLA 1 Aberration	GSYM 1 Dana\In(3R)A	DT 1 01 Feb 00	RESZ 976	REF 10	
ABSY|Dana\In(3R)A
DT|01 Feb 00
SYN|Dana\CIIIR
|Dana\eta
ID|FBab0023486
REF
{
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0008473
|Shirai and Moriwaki
|1952
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
REFM|FBrf0003683
|Kaufmann
|1936
|-1
}

DIS|Kaufmann 36; Kikkawa 38; Shirai and Moriwaki 52; Futch 66; Hinton and Downs 75; Tomimura and Tobari.
CCM|FBrf0063916: 83C;87B, Seecof: 22.0;27.8, Hinton and Downs: 83B;87B.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|3RA
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023487	CLA 1 Aberration	GSYM 1 Dana\In(3R)B	DT 1 15 Dec 97	RESZ 651	REF 6	
ABSY|Dana\In(3R)B
DT|15 Dec 97
ID|FBab0023487
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Futch 66; Hinton and Downs 75; Tomimura and Tobari.
MU|natural population
COR|American Samoa, Papua New Guinea, Nauru.
CCM|FBrf0063916: 87A;94D, Seecof: 3.0;22.9, Hinton and Downs: 87A;100A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023501	CLA 1 Aberration	GSYM 1 Dana\In(3R)b	DT 1 15 Dec 97	RESZ 336	REF 3	
ABSY|Dana\In(3R)b
DT|15 Dec 97
ID|FBab0023501
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Majuro.
CCM|Seecof: 5.1;10.9.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023488	CLA 1 Aberration	GSYM 1 Dana\In(3R)C	DT 1 15 Dec 97	RESZ 513	REF 5	
ABSY|Dana\In(3R)C
DT|15 Dec 97
ID|FBab0023488
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 96B;99B, Seecof: 1.9;7.5.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023489	CLA 1 Aberration	GSYM 1 Dana\In(3R)D	DT 1 01 Feb 00	RESZ 588	REF 5	
ABSY|Dana\In(3R)D
DT|01 Feb 00
ID|FBab0023489
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Futch 66; Tomimura and Tobari.
MU|natural population
COR|American Samoa.
CCM|FBrf0063916: 82D;91A, Seecof: 16.4;29.0.
REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|3RD
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023490	CLA 1 Aberration	GSYM 1 Dana\In(3R)E	DT 1 15 Dec 97	RESZ 365	REF 3	
ABSY|Dana\In(3R)E
DT|15 Dec 97
ID|FBab0023490
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton and Downs 75.
COR|Laboratory stock (Dana\pc).
CCM|FBrf0063916: 93D;98B, Hinton and Downs: 94C;99B.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023502	CLA 1 Aberration	GSYM 1 Dana\In(3R)e	DT 1 15 Dec 97	RESZ 336	REF 3	
ABSY|Dana\In(3R)e
DT|15 Dec 97
ID|FBab0023502
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Seecof 55, 56.
MU|natural population
COR|Bikini.
CCM|Seecof: 6.2;11.5.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023491	CLA 1 Aberration	GSYM 1 Dana\In(3R)ET	DT 1 27 Nov 05	RESZ 1932	REF 12	
ABSY|Dana\In(3R)ET
DT|27 Nov 05
SYN|ET
|eta
ID|FBab0023491
REF
{
REFM|FBrf0088970
|Singh
|1996
|-1
REFM|FBrf0073447
|Jamiruddin et al.
|1994
|-1
REFM|FBrf0086369
|Das et al.
|1993
|-1
REFM|FBrf0130085
|Singh
|2000
|-1
REFM|FBrf0054281
|Singh and Mohanty
|1991
|-1
REFM|FBrf0076624
|Das et al.
|1994
|-1
REFM|FBrf0052051
|Singh and Mohanty
|1990
|-1
REFM|FBrf0052100
|Singh and Mohanty
|1991
|-1
REFM|FBrf0081811
|Das et al.
|1994
|-1
REFM|FBrf0053595
|Singh
|1991
|-1
REFM|FBrf0052071
|Singh and Singh
|1990
|-1
REFM|FBrf0105328
|Singh
|1998
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0052051
|Singh and Mohanty
|1990
SYN|ET
}

REFDSR
{
RDID|FBrf0052071
|Singh and Singh
|1990
}

REFDSR
{
RDID|FBrf0052100
|Singh and Mohanty
|1991
PHP|Crossing-over in the X chromosome is enhanced in flies heterozygous
|for @Dana\In(3R)ET@.
SYN|ET
}

REFDSR
{
RDID|FBrf0053595
|Singh
|1991
MU|natural population
OTH|Cosmopolitan inversion.
SYN|ET
}

REFDSR
{
RDID|FBrf0054281
|Singh and Mohanty
|1991
SYN|ET
}

REFDSR
{
RDID|FBrf0073447
|Jamiruddin et al.
|1994
OTH|@Dana\In(2L)AL@, @Dana\In(3L)DE@ and @Dana\In(3R)ET@ are cosmopolitan
|in distribution, genetic differentiation does exist among populations
|of different geographical areas and there is no evidence for intra-
|or interchromosomal interactions in natural populations.
}

REFDSR
{
RDID|FBrf0076624
|Das et al.
|1994
SYN|ET
}

REFDSR
{
RDID|FBrf0088970
|Singh
|1996
SYN|ET
}

REFDSR
{
RDID|FBrf0130085
|Singh
|2000
SYN|ET
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023492	CLA 1 Aberration	GSYM 1 Dana\In(3R)F	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)F
DT|15 Dec 97
ID|FBab0023492
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 82D;93D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023493	CLA 1 Aberration	GSYM 1 Dana\In(3R)G	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)G
DT|15 Dec 97
ID|FBab0023493
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 86B;94C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023494	CLA 1 Aberration	GSYM 1 Dana\In(3R)H	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)H
DT|15 Dec 97
ID|FBab0023494
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 90A;99C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023495	CLA 1 Aberration	GSYM 1 Dana\In(3R)I	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)I
DT|15 Dec 97
ID|FBab0023495
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 84C;99A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023496	CLA 1 Aberration	GSYM 1 Dana\In(3R)J	DT 1 15 Dec 97	RESZ 378	REF 3	
ABSY|Dana\In(3R)J
DT|15 Dec 97
ID|FBab0023496
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea, Fiji, Tonga, American Samoa.
CCM|FBrf0063916: 94A;97C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023497	CLA 1 Aberration	GSYM 1 Dana\In(3R)K	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)K
DT|15 Dec 97
ID|FBab0023497
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 90B;93A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023498	CLA 1 Aberration	GSYM 1 Dana\In(3R)L	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)L
DT|15 Dec 97
ID|FBab0023498
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 89A;99D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023499	CLA 1 Aberration	GSYM 1 Dana\In(3R)M	DT 1 15 Dec 97	RESZ 349	REF 3	
ABSY|Dana\In(3R)M
DT|15 Dec 97
ID|FBab0023499
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|FBrf0063916: 84C;89D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023500	CLA 1 Aberration	GSYM 1 Dana\In(3R)N	DT 1 15 Dec 97	RESZ 336	REF 3	
ABSY|Dana\In(3R)N
DT|15 Dec 97
ID|FBab0023500
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|natural population
COR|Papua New Guinea.
CCM|86A;89D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023503	CLA 1 Aberration	GSYM 1 Dana\T(1;2)	DT 1 15 Dec 97	RESZ 468	REF 4	
ABSY|Dana\T(1;2)
DT|15 Dec 97
SYN|(XR-2R)
ID|FBab0023503
REF
{
REFM|FBrf0021319
|Nirmala Sajjan and Krishnamurthy
|1970
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Sajjan and Krishnamurthy 70.
MU|spontaneous
|natural population
COR|India.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(XR-2R)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023504	CLA 1 Aberration	GSYM 1 Dana\T(1;2)8	DT 1 15 Dec 97	RESZ 499	REF 4	
ABSY|Dana\T(1;2)8
DT|15 Dec 97
SYN|(XR-2L)8
ID|FBab0023504
REF
{
REFM|FBrf0023592
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|spontaneous
|natural population
COR|India.
CCM|Rajeshwari: 14D;22E.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(XR-2L)8
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023505	CLA 1 Aberration	GSYM 1 Dana\T(1;2)A	DT 1 15 Dec 97	RESZ 541	REF 5	
ABSY|Dana\T(1;2)A
DT|15 Dec 97
SYN|(XL-2R)A
ID|FBab0023505
REF
{
REFM|FBrf0018187
|Futch
|1966
|-1
REFM|FBrf0011708
|Stone et al.
|1957
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Futch 66.
MU|spontaneous
|natural population
COR|Niue Island.
CCM|Seecof:11.2;26.0.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(XL-2R)A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023506	CLA 1 Aberration	GSYM 1 Dana\T(1;2)A-H	DT 1 29 Oct 99	RESZ 473	REF 2	
ABSY|Dana\T(1;2)A-H
DT|29 Oct 99
SYN|T(1;2)A, M Ubx ca
ID|FBab0023506
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|As Dana\M @Dana\bx@ female from @Dana\bri@ female x @Dana\ca@; @Dana\stw@ male.
MK|Dana\bx<up>1</up> Dana\ca<up>1</up>
PHP|Minute phenotype.
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(1;2)A, M Ubx ca
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023507	CLA 1 Aberration	GSYM 1 Dana\T(1;2)B	DT 1 15 Dec 97	RESZ 257	REF 2	
ABSY|Dana\T(1;2)B
DT|15 Dec 97
ID|FBab0023507
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tomimura and Tobari.
MU|spontaneous
COR|Nauru.
CCM|2D;24D.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023508	CLA 1 Aberration	GSYM 1 Dana\T(1;2)B-H	DT 1 29 Oct 99	RESZ 480	REF 2	
ABSY|Dana\T(1;2)B-H
DT|29 Oct 99
SYN|Dana\T(1;2)B, ca Th
ID|FBab0023508
REF
{
REFM|FBrf0036540
|Hinton
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 79.
MU|spontaneous
COR|As a single @Dana\ca@ Dana\Th female from a recurrent backcross, X4 +/@Dana\ca@ female x @Dana\ca@ male.
MK|Dana\ca<up>1</up> Dana\Th<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|Dana\T(1;2)B, ca Th
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0026730	CLA 1 Translocation	GSYM 1 Dana\T(1;2)Om(1E)53<up>R1</up>	DT 1 12 Nov 00	RESZ 451	CLOC 1 16D1--7;26C1--4	REF 1	
ABSY|Dana\T(1;2)Om(1E)53<up>R1</up>
DT|12 Nov 00
ID|FBab0026730
REF
{
REFM|FBrf0088243
|Juni et al.
|1996
|-1
}

ASAL|FBal0055012 == Dana\anon-16Da<up>53-R1</up>
BPT|16D1--7;26C1--4
CCM|All limits from polytene analysis (FBrf0088243)
ACLA|Translocation
AMD|Dana\anon-16Da
REFDSR
{
RDID|FBrf0088243
|Juni et al.
|1996
BPT|16D;26C
ACLA|Translocation
AMD|Dana\anon-16Da
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023509	CLA 1 Aberration	GSYM 1 Dana\T(1;3)A	DT 1 01 Feb 00	RESZ 346	REF 1	
ABSY|Dana\T(1;3)A
DT|01 Feb 00
ID|FBab0023509
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 85.
MU|spontaneous
COR|As a single female from @Dana\ca@; @Dana\px@ female x X1 @Dana\ca@/NG2 male.
MK|Dana\Mo<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(1;3)A, Mo
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023510	CLA 1 Translocation	GSYM 1 Dana\T(1;3)ct<up>15ER27</up>	DT 1 29 Oct 99	RESZ 396	CLOC 1 1A;87B	REF 1	
ABSY|Dana\T(1;3)ct<up>15ER27</up>
DT|29 Oct 99
SYN|T(1;3)Om(1A)15E<up>R27</up>
ID|FBab0023510
REF
{
REFM|FBrf0072534
|Awasaki et al.
|1994
|-1
}

ASAL|FBal0038452 == Dana\ct<up>15ER27</up>
BPT|1A;87B
ACLA|Translocation
MU|&ggr; ray
REFDSR
{
RDID|FBrf0072534
|Awasaki et al.
|1994
BPT|1A;87B
ACLA|Translocation
MU|&ggr; ray
SYN|T(1;3)Om(1A)15E<up>R27</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023511	CLA 1 Aberration	GSYM 1 Dana\T(2;3)10	DT 1 15 Dec 97	RESZ 503	REF 4	
ABSY|Dana\T(2;3)10
DT|15 Dec 97
SYN|(2L-3L)10
ID|FBab0023511
REF
{
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0023523
|Nirmala Sajjan and Krishnamurthy
|1972
|-1
}

DIS|Sajjan and Krishnamurthy 72.
MU|spontaneous
|natural population
COR|India.
CCM|Rajeshwari: 20B;55D.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(2L-3L)10
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023512	CLA 1 Aberration	GSYM 1 Dana\T(2;3)15	DT 1 15 Dec 97	RESZ 528	REF 3	
ABSY|Dana\T(2;3)15
DT|15 Dec 97
SYN|Dana\T(2L-3L)15
ID|FBab0023512
REF
{
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Singh, B.N. 89.
MU|natural population
COR|India.
CCM|Ray-Chaudhuri and Jha: 1C;4C.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
MU|natural population
COR|India.
CCM|Breakpoints are near 1C in chromosome arm 2L and 4C in chromosome arm
|3L.
SYN|Dana\T(2L-3L)15
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023513	CLA 1 Aberration	GSYM 1 Dana\T(2;3)66	DT 1 15 Dec 97	RESZ 297	REF 2	
ABSY|Dana\T(2;3)66
DT|15 Dec 97
ID|FBab0023513
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Tanaka 66.
MU|spontaneous
COR|Cage population established with 28 isofemale lines from Honolulu.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023514	CLA 1 Aberration	GSYM 1 Dana\T(2;3)8	DT 1 15 Dec 97	RESZ 300	REF 2	
ABSY|Dana\T(2;3)8
DT|15 Dec 97
ID|FBab0023514
REF
{
REFM|FBrf0026069
|Sreerama Reddy and Krishnamurthy
|1974
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Reddy and Krishnamurthy 74.
MU|spontaneous
|natural population
COR|India.
CCM|2L;3L
}
# EOR
ABSR
{
RETE|ID 1 FBab0023515	CLA 1 Aberration	GSYM 1 Dana\T(2;3)9	DT 1 15 Dec 97	RESZ 505	REF 4	
ABSY|Dana\T(2;3)9
DT|15 Dec 97
SYN|(2L-3L)9
ID|FBab0023515
REF
{
REFM|FBrf0023591
|Sreerama Reddy and Krishnamurthy
|1972
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

DIS|Reddy and Krishnamurthy 72.
MU|spontaneous
|natural population
COR|South India.
CCM|Rajeshwari: 19A;55D.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(2L-3L)9
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023516	CLA 1 Aberration	GSYM 1 Dana\T(2;3)A	DT 1 09 Mar 99	RESZ 577	REF 3	
ABSY|Dana\T(2;3)A
DT|09 Mar 99
SYN|T(2;3)A, ca stw
|Dana\T(2;3)269.
ID|FBab0023516
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male backcrossed to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 60A;84B.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)A, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023517	CLA 1 Aberration	GSYM 1 Dana\T(2;3)AA	DT 1 06 May 99	RESZ 490	REF 1	
ABSY|Dana\T(2;3)AA
DT|06 May 99
SYN|Dana\T(2;3)AA, Ly
ID|FBab0023517
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 87.
MU|&ggr; ray
COR|Arose as a single female from @Dana\m<up>2</up>@ @Dana\v<up>2</up>@
|@Dana\B-H1<up>9</up>@ @Dana\g<up>3</up>@ females mated to @Dana\f<up>68</up>@ males
|irradiated with gamma-rays.
CCM|2R;3R
MK|Dana\Ly<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|Dana\T(2;3)AA, Ly
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023518	CLA 1 Aberration	GSYM 1 Dana\T(2;3)B	DT 1 09 Mar 99	RESZ 707	REF 4	
ABSY|Dana\T(2;3)B
DT|09 Mar 99
SYN|T(2-3)B
|T(2;3)B, M ca stw
|Dana\T(2;3)655b.
ID|FBab0023518
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose as Minute female from @Dana\px@ female mated to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: 44A;94B.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
PHP|Minute phenotype.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|T(2-3)B
}

REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)B, M ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027406	CLA 1 Translocation	GSYM 1 Dana\T(2;3)B43	DT 1 27 Nov 05	RESZ 495	CLOC 1 2Lt--2cen;3Lt--3cen	REF 2	
ABSY|Dana\T(2;3)B43
DT|27 Nov 05
ID|FBab0027406
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

BPT|2Lt--2cen;3Lt--3cen
ACLA|Translocation
DIS|Dobzhansky and Dreyfuss, 1943.
MU|spontaneous
COR|Isolated from Brazil.
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
BPT|2Lt--2cen;3Lt--3cen
ACLA|Translocation
DIS|Dobzhansky and Dreyfuss, 1943.
MU|spontaneous
COR|Isolated from Brazil.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027407	CLA 1 Translocation	GSYM 1 Dana\T(2;3)B61	DT 1 27 Nov 05	RESZ 471	CLOC 1 2cen--2Rt;3cen--3Rt	REF 2	
ABSY|Dana\T(2;3)B61
DT|27 Nov 05
ID|FBab0027407
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

BPT|2cen--2Rt;3cen--3Rt
ACLA|Translocation
DIS|Freire-Maia, 1961.
MU|spontaneous
COR|Isolated from Brazil.
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
BPT|2cen--2Rt;3cen--3Rt
ACLA|Translocation
DIS|Freire-Maia, 1961.
MU|spontaneous
COR|Isolated from Brazil.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023519	CLA 1 Aberration	GSYM 1 Dana\T(2;3)C	DT 1 09 Mar 99	RESZ 572	REF 3	
ABSY|Dana\T(2;3)C
DT|09 Mar 99
SYN|T(2;3)C, M ca stw
|Dana\T(2;3)331.
ID|FBab0023519
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from @Dana\bri@ female mated to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: 27C;93C.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
PHP|Minute phenotype.
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)C, M ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023520	CLA 1 Aberration	GSYM 1 Dana\T(2;3)D	DT 1 09 Mar 99	RESZ 576	REF 3	
ABSY|Dana\T(2;3)D
DT|09 Mar 99
SYN|T(2;3)D, ca stw
|Dana\T(2;3)9.
ID|FBab0023520
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\bri@/@Dana\stw@ female to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: 45A;95B.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)D, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023521	CLA 1 Aberration	GSYM 1 Dana\T(2;3)DD	DT 1 15 Dec 97	RESZ 330	REF 2	
ABSY|Dana\T(2;3)DD
DT|15 Dec 97
SYN|IIL-IIIL
ID|FBab0023521
REF
{
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0006047
|Dobzhansky and Dreyfus
|1943
|-1
}

DIS|Dobzhansky and Dreyfus 43.
MU|spontaneous
COR|Brazil.
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|IIL-IIIL
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023522	CLA 1 Aberration	GSYM 1 Dana\T(2;3)E	DT 1 09 Mar 99	RESZ 631	REF 4	
ABSY|Dana\T(2;3)E
DT|09 Mar 99
SYN|T(2;3)E, ca stw
|Dana\T(2;3)34.
ID|FBab0023522
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\bri@/@Dana\stw@ female to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: 20C;85A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)E, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023523	CLA 1 Aberration	GSYM 1 Dana\T(2;3)F	DT 1 09 Mar 99	RESZ 492	REF 2	
ABSY|Dana\T(2;3)F
DT|09 Mar 99
SYN|T(2;3)F, ca stw
|Dana\T(2;3)208.
ID|FBab0023523
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from mating of +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|33C;78A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)F, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023524	CLA 1 Aberration	GSYM 1 Dana\T(2;3)FM	DT 1 15 Dec 97	RESZ 322	REF 2	
ABSY|Dana\T(2;3)FM
DT|15 Dec 97
SYN|IIR-IIIR
ID|FBab0023524
REF
{
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0013856
|Freire-Maia
|1961
|-1
}

DIS|Freire-Maia 61.
MU|spontaneous
|natural population
COR|Brazil.
CCM|2R;3R
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|IIR-IIIR
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023525	CLA 1 Aberration	GSYM 1 Dana\T(2;3)G	DT 1 09 Mar 99	RESZ 575	REF 3	
ABSY|Dana\T(2;3)G
DT|09 Mar 99
SYN|T(2;3)G, ca stw
|Dana\T(2;3)238.
ID|FBab0023525
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from mating of +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 38B;64C.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)G, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023526	CLA 1 Aberration	GSYM 1 Dana\T(2;3)H	DT 1 09 Mar 99	RESZ 629	REF 4	
ABSY|Dana\T(2;3)H
DT|09 Mar 99
SYN|T(2;3)H, ca stw
|Dana\T(2;3)580.
ID|FBab0023526
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from mating of +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 21B;93C.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)H, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027408	CLA 1 Translocation	GSYM 1 Dana\T(2;3)I70	DT 1 27 Nov 05	RESZ 495	CLOC 1 2cen--2Rt;3cen--3Rt	REF 2	
ABSY|Dana\T(2;3)I70
DT|27 Nov 05
ID|FBab0027408
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
}

BPT|2cen--2Rt;3cen--3Rt
ACLA|Translocation
DIS|Sajjan and Krishnamurthy, 1961.
MU|spontaneous
COR|Isolated from India.
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
BPT|2cen--2Rt;3cen--3Rt
ACLA|Translocation
DIS|Sajjan and Krishnamurthy, 1961.
MU|spontaneous
COR|Isolated from India.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023527	CLA 1 Aberration	GSYM 1 Dana\T(2;3)J	DT 1 09 Mar 99	RESZ 692	REF 4	
ABSY|Dana\T(2;3)J
DT|09 Mar 99
SYN|T(2;3)J, Xa ca stw
|Dana\T(2;3)108.
ID|FBab0023527
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from mating of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 55A;94B and also In(3LR) with breaks at 73C;88B.
MK|Dana\Xa<up>1</up> Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)J, Xa ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023528	CLA 1 Aberration	GSYM 1 Dana\T(2;3)K	DT 1 09 Mar 99	RESZ 628	REF 4	
ABSY|Dana\T(2;3)K
DT|09 Mar 99
SYN|T(2;3)K, ca stw
|Dana\T(2;3)222.
ID|FBab0023528
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from mating of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 27A;77A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)K, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023529	CLA 1 Aberration	GSYM 1 Dana\T(2;3)L	DT 1 09 Mar 99	RESZ 631	REF 4	
ABSY|Dana\T(2;3)L
DT|09 Mar 99
SYN|T(2;3)L, ca stw
|Dana\T(2;3)243.
ID|FBab0023529
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 57A;62A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)L, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023530	CLA 1 Aberration	GSYM 1 Dana\T(2;3)M	DT 1 09 Mar 99	RESZ 631	REF 4	
ABSY|Dana\T(2;3)M
DT|09 Mar 99
SYN|T(2;3)M, ca stw
|Dana\T(2;3)246.
ID|FBab0023530
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 36C;70C.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)M, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023531	CLA 1 Aberration	GSYM 1 Dana\T(2;3)N	DT 1 09 Mar 99	RESZ 577	REF 3	
ABSY|Dana\T(2;3)N
DT|09 Mar 99
SYN|T(2;3)N, ca stw
|Dana\T(2;3)246.
ID|FBab0023531
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 19B;96A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)N, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023532	CLA 1 Aberration	GSYM 1 Dana\T(2;3)NSK	DT 1 15 Dec 97	RESZ 348	REF 2	
ABSY|Dana\T(2;3)NSK
DT|15 Dec 97
SYN|(2R-3R)
ID|FBab0023532
REF
{
REFM|FBrf0021319
|Nirmala Sajjan and Krishnamurthy
|1970
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
}

DIS|Sajjan and Krishnamurthy 70.
MU|spontaneous
|natural population
COR|India.
CCM|2R;3R
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|(2R-3R)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023533	CLA 1 Aberration	GSYM 1 Dana\T(2;3)O	DT 1 06 May 99	RESZ 630	REF 4	
ABSY|Dana\T(2;3)O
DT|06 May 99
SYN|T(2;3)O, ca stw
|Dana\T(2;3)340
ID|FBab0023533
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 53A;78A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)O, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023534	CLA 1 Translocation	GSYM 1 Dana\T(2;3)Om(2D)<up>63R5</up>	DT 1 29 Oct 99	RESZ 843	CLOC 1 48B;96A	REF 3	
ABSY|Dana\T(2;3)Om(2D)<up>63R5</up>
DT|29 Oct 99
ID|FBab0023534
REF
{
REFM|FBrf0076964
|Yoshida et al.
|1994
|-1
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0054576
|Matsubayashi et al.
|1991
|-1
}

ASAL|FBal0038376 == Dana\Om(2D)<up>63R5</up>
BPT|48B;96A
ACLA|Translocation
MU|&ggr; ray
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
REFDSR
{
RDID|FBrf0054576
|Matsubayashi et al.
|1991
BPT|48B;96A
ACLA|Translocation
MU|&ggr; ray
PRG|Dana\Om(2D)<up>63</up>
AMD|Dana\Om(2D)
}

REFDSR
{
RDID|FBrf0076964
|Yoshida et al.
|1994
BPT|48B;96A
ACLA|Translocation
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
BPT|48B;96A
ACLA|Translocation
AMD|Dana\Om(2D)
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023535	CLA 1 Aberration	GSYM 1 Dana\T(2;3)P	DT 1 09 Mar 99	RESZ 631	REF 4	
ABSY|Dana\T(2;3)P
DT|09 Mar 99
SYN|T(2;3)P, ca stw
|Dana\T(2;3)354.
ID|FBab0023535
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 18A;93B.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)P, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023536	CLA 1 Aberration	GSYM 1 Dana\T(2;3)Q	DT 1 09 Mar 99	RESZ 631	REF 4	
ABSY|Dana\T(2;3)Q
DT|09 Mar 99
SYN|T(2;3)Q, ca stw
|Dana\T(2;3)536.
ID|FBab0023536
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of +/@Dana\ca@; @Dana\px@/@Dana\stw@ male to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: 55B;95A.
MK|Dana\ca<up>1</up> Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)Q, ca stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023537	CLA 1 Aberration	GSYM 1 Dana\T(2;3)R	DT 1 06 May 99	RESZ 333	REF 2	
ABSY|Dana\T(2;3)R
DT|06 May 99
SYN|Dana\T(2;3)31.
ID|FBab0023537
REF
{
REFM|FBrf0036540
|Hinton
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|J. Lance 79.
MU|spontaneous
COR|Arose from testcross of an F1 +/@Dana\ca@; @Dana\px@/+ male to @Dana\ca@; @Dana\px@ females.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023538	CLA 1 Aberration	GSYM 1 Dana\T(2;3)S	DT 1 06 May 99	RESZ 428	REF 3	
ABSY|Dana\T(2;3)S
DT|06 May 99
SYN|Dana\T(2;3)76.
ID|FBab0023538
REF
{
REFM|FBrf0036540
|Hinton
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|J. Lance 79.
MU|spontaneous
COR|Arose from testcross of an F1 +/@Dana\ca@; @Dana\px@/+ male to @Dana\ca@; @Dana\px@ females.
CCM|Hinton and Downs: 58A;94C.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023539	CLA 1 Aberration	GSYM 1 Dana\T(2;3)T	DT 1 06 May 99	RESZ 429	REF 3	
ABSY|Dana\T(2;3)T
DT|06 May 99
SYN|Dana\T(2;3)148.
ID|FBab0023539
REF
{
REFM|FBrf0036540
|Hinton
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|J. Lance 79.
MU|spontaneous
COR|Arose from testcross of an F1 +/@Dana\ca@; @Dana\px@/+ male to @Dana\ca@; @Dana\px@ females.
CCM|Hinton and Downs: 34C;90A.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023540	CLA 1 Aberration	GSYM 1 Dana\T(2;3)U	DT 1 09 Mar 99	RESZ 554	REF 3	
ABSY|Dana\T(2;3)U
DT|09 Mar 99
SYN|T(2;3)U, ca Cy
|Dana\T(2;3)Cy.
ID|FBab0023540
REF
{
REFM|FBrf0036540
|Hinton
|1981
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 79.
MU|spontaneous
COR|Arose from backcross of X8 @Dana\px@ females to @Dana\ca@ males.
CCM|Hinton and Downs: 26C;90A and 64A;96A.
MK|Dana\ca<up>1</up> Dana\Cy<up>89</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)U, ca Cy
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023541	CLA 1 Aberration	GSYM 1 Dana\T(2;3)V	DT 1 06 May 99	RESZ 489	REF 2	
ABSY|Dana\T(2;3)V
DT|06 May 99
SYN|Dana\T(2;3)14.
ID|FBab0023541
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton.
MU|spontaneous
COR|Arose from cross of X1 @Dana\Dl<up>2</up>@/+; @Dana\Bb@/@Dana\px@ male to @Dana\ca@; @Dana\px@ females.
CCM|Hinton and Downs: 24B;88A plus @Dana\In(2L)A@, derived from @Dana\px@
|stock, with superimposed break at 24B on 2L plus break in 88A).
}
# EOR
ABSR
{
RETE|ID 1 FBab0023542	CLA 1 Aberration	GSYM 1 Dana\T(2;3)W	DT 1 09 Mar 99	RESZ 520	REF 2	
ABSY|Dana\T(2;3)W
DT|09 Mar 99
SYN|T(2;3)W, Cy<up>EX</up>
|Dana\T(2;3)Exc 620.
ID|FBab0023542
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 80.
MU|spontaneous
COR|Arose from recurrent backcross of X6 +/@Dana\ca@ female to @Dana\ca@ male.
CCM|Hinton and Downs: 30C;81C plus @Dana\In(3L)E@.
MK|Dana\Cy<up>89</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)W, Cy<up>EX</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023543	CLA 1 Aberration	GSYM 1 Dana\T(2;3)Z	DT 1 06 May 99	RESZ 446	REF 1	
ABSY|Dana\T(2;3)Z
DT|06 May 99
SYN|T(2;3)Z, Mot
ID|FBab0023543
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 86.
MU|diepoxybutane
COR|Arose from mating of @Dana\m<up>2</up>@ @Dana\v<up>2</up>@ @Dana\B-H1<up>9</up>@ @Dana\g<up>3</up>@ female to @Dana\Om(1K)Su<up>86</up>@/Y treated with DEB.
MK|Dana\Mot<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(2;3)Z, Mot
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023544	CLA 1 Aberration	GSYM 1 Dana\T(3;4)	DT 1 15 Dec 97	RESZ 283	REF 2	
ABSY|Dana\T(3;4)
DT|15 Dec 97
ID|FBab0023544
REF
{
REFM|FBrf0071819
|Ray-Chaudhuri and Jha
|1966
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Ray-Chaudhuri and Jha 66.
MU|spontaneous
|natural population
COR|India.
CCM|3L;4
}
# EOR
ABSR
{
RETE|ID 1 FBab0023545	CLA 1 Aberration	GSYM 1 Dana\T(3;4)Pm	DT 1 15 Dec 97	RESZ 502	REF 5	
ABSY|Dana\T(3;4)Pm
DT|15 Dec 97
SYN|IIIL-IV
ID|FBab0023545
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0063921
|Tomimura et al.
|1993
|-1
REFM|FBrf0004281
|Kikkawa
|1938
|-1
}

DIS|Kikkawa 38.
MU|spontaneous
|natural population
COR|Ryukyu.
CCM|3L;4
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|IIIL-IV
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023546	CLA 1 Aberration	GSYM 1 Dana\T(Y;2)A	DT 1 09 Mar 99	RESZ 641	REF 3	
ABSY|Dana\T(Y;2)A
DT|09 Mar 99
SYN|T(Y-2)A
|T(Y;2)A, ca
ID|FBab0023546
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male mated to @Dana\ca@; @Dana\stw@ female.
CCM|YS;27B: mitotic analysis shows distal half of chromosome 2 on Y and about 1/3 of Y on 2L.
MK|Dana\ca<up>1</up>
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|T(Y-2)A
}

REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(Y;2)A, ca
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023547	CLA 1 Aberration	GSYM 1 Dana\T(Y;2)B	DT 1 09 Mar 99	RESZ 777	REF 4	
ABSY|Dana\T(Y;2)B
DT|09 Mar 99
SYN|T(Y-2)B
|T(Y;2)B, ca
|Dana\T(Y;2)303,ca.
ID|FBab0023547
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0053596
|Singh
|1991
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 75.
MU|spontaneous
COR|Arose from +/@Dana\ca@; @Dana\bri@/@Dana\stw@ male mated to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: YS;19B; mitotic analysis indicates exchange of small
|segments such that Y2 is distally splayed, 2Y is distally fused.
MK|Dana\ca<up>1</up>
REFDSR
{
RDID|FBrf0053596
|Singh
|1991
SYN|T(Y-2)B
}

REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(Y;2)B, ca
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023548	CLA 1 Aberration	GSYM 1 Dana\T(Y;2)C	DT 1 09 Mar 99	RESZ 730	REF 5	
ABSY|Dana\T(Y;2)C
DT|09 Mar 99
SYN|T(Y;2)C, ca
|Dana\T(Y;2L)C
ID|FBab0023548
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from +/@Dana\ca@; @Dana\px@/@Dana\stw@ female mated to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: Y;34B.
MK|Dana\ca<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(Y;2)C, ca
}

REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\T(Y;2L)C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023549	CLA 1 Aberration	GSYM 1 Dana\T(Y;2;3)A	DT 1 20 Apr 05	RESZ 471	REF 2	
ABSY|Dana\T(Y;2;3)A
DT|20 Apr 05
SYN|Dana\T(Y;2;3)234, M ca stw
|Dana\T(Y;2;3)A, M ca stw
ID|FBab0023549
REF
{
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from @Dana\bri@/@Dana\px@ female mated to @Dana\ca@; @Dana\stw@ male.
CCM|Polytene analysis shows at least 8 euchromatic breaks, 4 in 2L, 3 in 3L, 1 in 3R, but new order not established.
}
# EOR
ABSR
{
RETE|ID 1 FBab0023550	CLA 1 Aberration	GSYM 1 Dana\T(Y;3)A	DT 1 06 May 99	RESZ 488	REF 2	
ABSY|Dana\T(Y;3)A
DT|06 May 99
SYN|T(Y;3)A, stw
|Dana\T(Y;3)340, stw.
ID|FBab0023550
REF
{
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose as a single male during analysis of @Dana\T(2;3)O@.
CCM|Polytene analysis suggests chromosome breaks in chromosome 3.
MK|Dana\stw<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(Y;3)A, stw
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023551	CLA 1 Aberration	GSYM 1 Dana\T(Y;3)B	DT 1 09 Mar 99	RESZ 368	REF 2	
ABSY|Dana\T(Y;3)B
DT|09 Mar 99
SYN|Dana\T(Y;3)108.
ID|FBab0023551
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|J. Lance 79.
MU|spontaneous
COR|Arose from +/@Dana\ca@; @Dana\px@/+ male mated to @Dana\ca@; @Dana\stw@ female.
CCM|Hinton and Downs: Y;99A (3R tip).
}
# EOR
ABSR
{
RETE|ID 1 FBab0023552	CLA 1 Aberration	GSYM 1 Dana\T(Y;3)C	DT 1 09 Mar 99	RESZ 612	REF 2	
ABSY|Dana\T(Y;3)C
DT|09 Mar 99
SYN|T(Y;3)C, e se;ru
|Dana\T(Y;3L)C
ID|FBab0023552
REF
{
REFM|FBrf0063916
|Tobari et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Matsuda 88.
MU|spontaneous
COR|Arose from @Dana\e@/+(L8); @Dana\bri@ @Dana\ru@/+(L8) male mated to @Dana\e@ @Dana\se@; @Dana\bri@ @Dana\ru@ females.
CCM|Y;79A.
MK|Dana\e<up>1</up> Dana\se<up>1</up> Dana\ru<up>1</up>
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|T(Y;3)C, e se;ru
}

REFDSR
{
RDID|FBrf0063916
|Tobari et al.
|1993
SYN|Dana\T(Y;3L)C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023553	CLA 1 Aberration	GSYM 1 Dana\T(Y;3)D	DT 1 06 May 99	RESZ 313	
ABSY|Dana\T(Y;3)D
DT|06 May 99
ID|FBab0023553
DIS|Matsubayashi 90.
MU|diepoxybutane
COR|Arose as a single male from DEB treated @Dana\e@ @Dana\pi@ @Dana\Om(2D)<up>63</up>@ males mated to @Dana\e@ @Dana\pi@ @Dana\Om(2D)<up>63</up>@/NG2 females.
CCM|Y;67D-68A.
MK|Dana\pe<up>1</up> Dana\v<up>1</up>
}
# EOR
ABSR
{
RETE|ID 1 FBab0027409	CLA 1 Aberration	GSYM 1 Dana\T(Y;3)pe<up>v</up>	DT 1 16 Jun 98	RESZ 380	REF 1	
ABSY|Dana\T(Y;3)pe<up>v</up>
DT|16 Jun 98
ID|FBab0027409
REF
{
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
}

DIS|Matsubayashi, 1990.
MU|diepoxybutane
PED|position-effect variegation for: Dana\pe
REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
DIS|Matsubayashi, 1990.
MU|diepoxybutane
PED|position-effect variegation for: Dana\pe
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024302	CLA 1 Unoriented insertional transposition	GSYM 1 Dana\Tp(2;2)Sb	DT 1 02 Jul 03	RESZ 1040	CLOC 1 34C;39B;57A	ALESR 1	REF 3	
ABSY|Dana\Tp(2;2)Sb
DT|02 Jul 03
SYN|Tp(2L;2R)Sb
ID|FBab0024302
REF
{
REFM|FBrf0098952
|Tanda et al.
|1993
|-1
REFM|FBrf0063720
|Moriwaki and Tobari
|1993
|-1
REFM|FBrf0048186
|Hinton
|1988
|-1
}

ASAL|FBal0044735 == Dana\Sb<up>2</up>
BPT|34C;39B;57A
ACLA|Unoriented insertional transposition
REFDSR
{
RDID|FBrf0048186
|Hinton
|1988
BPT|34C;39B;57A
ACLA|Unoriented insertional transposition
SYN|Tp(2L;2R)Sb
}

REFDSR
{
RDID|FBrf0063720
|Moriwaki and Tobari
|1993
SYN|Tp(2L;2R)Sb
}

REFDSR
{
RDID|FBrf0098952
|Tanda et al.
|1993
SYN|Tp(2L;2R)Sb
}

SEP
{
SPSY|Dana\Dp(2;2)Sb
DT|02 Jul 03
ID|FBab0024303
REF|FBrf0048186
ACLA|Unoriented insertional duplication
AMDP|Dana\Om(2B)
|Dana\Om(2G)
|Dana\Om(2H)
REFDSR
{
RDID|FBrf0048186
|Hinton
|1988
AMDP|Dana\Om(2B)
|Dana\Om(2G)
|Dana\Om(2H)
}

}

}
# EOR
ABSR
{
RETE|ID 1 FBab0023554	CLA 1 Aberration	NAM 1 Transposition (2L;2R) with Stubble	GSYM 1 Dana\Tp(2L;2R)Sb	DT 1 09 Mar 99	RESZ 467	REF 3	
ABSY|Dana\Tp(2L;2R)Sb
DT|09 Mar 99
NAM|Transposition (2L;2R) with Stubble
ID|FBab0023554
REF
{
REFM|FBrf0033156
|Hinton
|1979
|-1
REFM|FBrf0034423
|Hinton
|1980
|-1
REFM|FBrf0027749
|Hinton and Downs
|1975
|-1
}

DIS|Hinton 76.
MU|spontaneous
COR|Arose from backcross of @Dana\px@/@Dana\bri@ female to @Dana\ca@; @Dana\stw@ male.
CCM|Hinton and Downs: 34C7-39B1 transferred from 2L into 2R at 57A1.2.
}
# EOR
ABSR
{
RETE|ID 1 FBab0025265	CLA 1 Inversion	GSYM 1 Dari\In(2)i	DT 1 08 Nov 97	RESZ 255	REF 1	
ABSY|Dari\In(2)i
DT|08 Nov 97
ID|FBab0025265
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025266	CLA 1 Inversion	GSYM 1 Darw\In(2L)E	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Darw\In(2L)E
DT|08 Nov 97
ID|FBab0025266
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025267	CLA 1 Inversion	GSYM 1 Darw\In(2L)M'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Darw\In(2L)M'
DT|08 Nov 97
ID|FBab0025267
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025268	CLA 1 Inversion	GSYM 1 Dass\In(4)n<up>3</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Dass\In(4)n<up>3</up>
DT|11 Feb 97
ID|FBab0025268
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025269	CLA 1 Inversion	GSYM 1 Dast\In(2L)a	DT 1 08 Nov 97	RESZ 318	REF 2	
ABSY|Dast\In(2L)a
DT|08 Nov 97
ID|FBab0025269
REF
{
REFM|FBrf0025036
|Bicudo
|1973
|-1
REFM|FBrf0026037
|Bicudo et al.
|1974
|-1
}

ACLA|Inversion
MU|natural population
COR|Brasil
REFDSR
{
RDID|FBrf0026037
|Bicudo et al.
|1974
MU|natural population
COR|Brasil
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025270	CLA 1 Inversion	GSYM 1 Dast\In(3)a	DT 1 08 Nov 97	RESZ 317	REF 2	
ABSY|Dast\In(3)a
DT|08 Nov 97
ID|FBab0025270
REF
{
REFM|FBrf0025036
|Bicudo
|1973
|-1
REFM|FBrf0026037
|Bicudo et al.
|1974
|-1
}

ACLA|Inversion
MU|natural population
COR|Brasil
REFDSR
{
RDID|FBrf0026037
|Bicudo et al.
|1974
MU|natural population
COR|Brasil
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025271	CLA 1 Inversion	GSYM 1 Dast\In(3)b	DT 1 08 Nov 97	RESZ 263	REF 1	
ABSY|Dast\In(3)b
DT|08 Nov 97
ID|FBab0025271
REF
{
REFM|FBrf0026037
|Bicudo et al.
|1974
|-1
}

ACLA|Inversion
MU|natural population
COR|Brasil
REFDSR
{
RDID|FBrf0026037
|Bicudo et al.
|1974
MU|natural population
COR|Brasil
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025272	CLA 1 Inversion	GSYM 1 Dast\In(XR)A	DT 1 08 Nov 97	RESZ 264	REF 1	
ABSY|Dast\In(XR)A
DT|08 Nov 97
ID|FBab0025272
REF
{
REFM|FBrf0026037
|Bicudo et al.
|1974
|-1
}

ACLA|Inversion
MU|natural population
COR|Brasil
REFDSR
{
RDID|FBrf0026037
|Bicudo et al.
|1974
MU|natural population
COR|Brasil
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025274	CLA 1 Inversion	GSYM 1 Dath\In(1L)II	DT 1 08 Nov 97	RESZ 333	REF 1	
ABSY|Dath\In(1L)II
DT|08 Nov 97
ID|FBab0025274
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 15 | 16d | 10 - 16p | 20 - 40.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 15 | 16d | 10 - 16p | 20 - 40.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025273	CLA 1 Inversion	GSYM 1 Dath\In(1L)MI	DT 1 15 Dec 97	RESZ 465	REF 3	
ABSY|Dath\In(1L)MI
DT|15 Dec 97
ID|FBab0025273
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
REFM|FBrf0021302
|Miller
|1970
|-1
}

ACLA|Inversion
NCO|1 - 3 | 15 - 4 | 16.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 3 | 15 - 4 | 16.
}

REFDSR
{
RDID|FBrf0021302
|Miller
|1970
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025275	CLA 1 Inversion	GSYM 1 Dath\In(1L)MII	DT 1 08 Nov 97	RESZ 520	REF 3	
ABSY|Dath\In(1L)MII
DT|08 Nov 97
ID|FBab0025275
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
REFM|FBrf0021302
|Miller
|1970
|-1
}

ACLA|Inversion
NCO|1 - 3 | 11 - 15 | 10 - 4 | 16.
MU|natural population
PRG|Dath\In(1L)MI
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 3 | 11 - 15 | 10 - 4 | 16.
PRG|Dath\In(1L)MI
}

REFDSR
{
RDID|FBrf0021302
|Miller
|1970
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025276	CLA 1 Inversion	GSYM 1 Dath\In(1L)MIII	DT 1 08 Nov 97	RESZ 381	REF 2	
ABSY|Dath\In(1L)MIII
DT|08 Nov 97
ID|FBab0025276
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
}

ACLA|Inversion
MU|natural population
NCO|1 - 2 | 8 - 10 | 15 - 11 | 3 | 7 - 4 | 16.
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 2 | 8 - 10 | 15 - 11 | 3 | 7 - 4 | 16.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025277	CLA 1 Inversion	GSYM 1 Dath\In(1L)MIV	DT 1 08 Nov 97	RESZ 390	REF 2	
ABSY|Dath\In(1L)MIV
DT|08 Nov 97
ID|FBab0025277
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
}

ACLA|Inversion
MU|natural population
NCO|1 - 3 | 11 - 13 | 16d | 4 - 10 | 15 - 14 | 16p.
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 3 | 11 - 13 | 16d | 4 - 10 | 15 - 14 | 16p.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025278	CLA 1 Inversion	GSYM 1 Dath\In(1L)MIX	DT 1 08 Nov 97	RESZ 484	REF 2	
ABSY|Dath\In(1L)MIX
DT|08 Nov 97
ID|FBab0025278
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
}

ACLA|Inversion
MU|natural population
NCO|17 | 39 - 35 | 27p - 29d | 23 - 19p | 24 - 27d | 30 - 34 | 29p | 19p - 18 | 40.
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
OTH|Including @Dath\In(1L)MX@.
NCO|17 | 39 - 35 | 27p - 29d | 23 - 19p | 24 - 27d | 30 - 34 | 29p | 19p - 18 | 40.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025279	CLA 1 Inversion	GSYM 1 Dath\In(1L)MVI	DT 1 08 Nov 97	RESZ 484	REF 3	
ABSY|Dath\In(1L)MVI
DT|08 Nov 97
ID|FBab0025279
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
REFM|FBrf0021302
|Miller
|1970
|-1
}

ACLA|Inversion
NCO|- 18 | 19d | 23 - 19p | 24 -.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|- 18 | 19d | 23 - 19p | 24 -.
}

REFDSR
{
RDID|FBrf0021302
|Miller
|1970
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025280	CLA 1 Inversion	GSYM 1 Dath\In(1L)MVII	DT 1 08 Nov 97	RESZ 471	REF 3	
ABSY|Dath\In(1L)MVII
DT|08 Nov 97
ID|FBab0025280
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
REFM|FBrf0021302
|Miller
|1970
|-1
}

ACLA|Inversion
NCO|- 27d | 30 - 27p | 35.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|- 27d | 30 - 27p | 35.
}

REFDSR
{
RDID|FBrf0021302
|Miller
|1970
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025281	CLA 1 Inversion	GSYM 1 Dath\In(1L)MVIII	DT 1 08 Nov 97	RESZ 530	REF 3	
ABSY|Dath\In(1L)MVIII
DT|08 Nov 97
ID|FBab0025281
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
REFM|FBrf0021302
|Miller
|1970
|-1
}

ACLA|Inversion
NCO|- 27d | 30 - 34 | 29 - 27p | 35.
MU|natural population
PRG|Dath\In(1L)MVII
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|- 27d | 30 - 34 | 29 - 27p | 35.
PRG|Dath\In(1L)MVII
}

REFDSR
{
RDID|FBrf0021302
|Miller
|1970
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025282	CLA 1 Inversion	GSYM 1 Dath\In(1L)MX	DT 1 08 Nov 97	RESZ 484	REF 2	
ABSY|Dath\In(1L)MX
DT|08 Nov 97
ID|FBab0025282
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
REFM|FBrf0022449
|Miller
|1971
|-1
}

ACLA|Inversion
MU|natural population
NCO|17 | 39 - 35 | 27p - 29d | 23 - 19p | 24 - 27d | 30 - 34 | 29p | 19p - 18 | 40.
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
OTH|Including @Dath\In(1L)MIX@.
NCO|17 | 39 - 35 | 27p - 29d | 23 - 19p | 24 - 27d | 30 - 34 | 29p | 19p - 18 | 40.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025283	CLA 1 Inversion	GSYM 1 Dath\In(1L)MXI	DT 1 08 Nov 97	RESZ 336	REF 1	
ABSY|Dath\In(1L)MXI
DT|08 Nov 97
ID|FBab0025283
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 3 | 16 | 4 - 10 | 15 - 11 | 17.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|1 - 3 | 16 | 4 - 10 | 15 - 11 | 17.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025284	CLA 1 Inversion	GSYM 1 Dath\In(1L)MXII	DT 1 08 Nov 97	RESZ 339	REF 1	
ABSY|Dath\In(1L)MXII
DT|08 Nov 97
ID|FBab0025284
REF
{
REFM|FBrf0020733
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|- 5p | 23 | 19d - 16 | 4 - 5d | 22-.
MU|natural population
REFDSR
{
RDID|FBrf0020733
|Miller and Voelker
|1969
NCO|- 5p | 23 | 19d - 16 | 4 - 5d | 22-.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025285	CLA 1 Inversion	GSYM 1 Dath\In(1L)MXIII	DT 1 08 Nov 97	RESZ 230	REF 1	
ABSY|Dath\In(1L)MXIII
DT|08 Nov 97
ID|FBab0025285
REF
{
REFM|FBrf0022449
|Miller
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0022449
|Miller
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025286	CLA 1 Inversion	GSYM 1 Dath\In(1L)MXIV	DT 1 08 Nov 97	RESZ 389	REF 1	
ABSY|Dath\In(1L)MXIV
DT|08 Nov 97
ID|FBab0025286
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 3 | 11 - 13 | 6 - 10 | 15 - 14 | 4 - 4 | 16.
MU|natural population
PRG|Dath\In(1L)MI Dath\In(1L)MII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 3 | 11 - 13 | 6 - 10 | 15 - 14 | 4 - 4 | 16.
MU|natural population
PRG|Dath\In(1L)MI Dath\In(1L)MII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025287	CLA 1 Inversion	GSYM 1 Dath\In(1L)MXV	DT 1 08 Nov 97	RESZ 354	REF 1	
ABSY|Dath\In(1L)MXV
DT|08 Nov 97
ID|FBab0025287
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 3 | 11 - 15 | 10 - 4 | 16.
MU|natural population
PRG|Dath\In(1L)MI Dath\In(1L)MIII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 3 | 11 - 15 | 10 - 4 | 16.
MU|natural population
PRG|Dath\In(1L)MI Dath\In(1L)MIII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025288	CLA 1 Inversion	GSYM 1 Dath\In(1S)II	DT 1 08 Nov 97	RESZ 303	REF 1	
ABSY|Dath\In(1S)II
DT|08 Nov 97
ID|FBab0025288
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 3 | 9 -4 | 10-.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 3 | 9 -4 | 10-.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025289	CLA 1 Inversion	GSYM 1 Dath\In(1S)III	DT 1 08 Nov 97	RESZ 296	REF 1	
ABSY|Dath\In(1S)III
DT|08 Nov 97
ID|FBab0025289
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 | 4 - 2 | 5-.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 | 4 - 2 | 5-.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025290	CLA 1 Inversion	GSYM 1 Dath\In(1S)IV	DT 1 08 Nov 97	RESZ 281	REF 1	
ABSY|Dath\In(1S)IV
DT|08 Nov 97
ID|FBab0025290
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 6d | 9d - 6p | 9p - 10.
MU|natural population
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 6d | 9d - 6p | 9p - 10.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025291	CLA 1 Inversion	GSYM 1 Dath\In(1S)MI	DT 1 08 Nov 97	RESZ 309	REF 1	
ABSY|Dath\In(1S)MI
DT|08 Nov 97
ID|FBab0025291
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 2p | 26.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 2p | 26.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025292	CLA 1 Inversion	GSYM 1 Dath\In(1S)MII	DT 1 08 Nov 97	RESZ 380	REF 1	
ABSY|Dath\In(1S)MII
DT|08 Nov 97
ID|FBab0025292
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025293	CLA 1 Inversion	GSYM 1 Dath\In(1S)MIII	DT 1 08 Nov 97	RESZ 367	REF 1	
ABSY|Dath\In(1S)MIII
DT|08 Nov 97
ID|FBab0025293
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 23d | 26p.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 23d | 26p.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025294	CLA 1 Inversion	GSYM 1 Dath\In(1S)MIV	DT 1 08 Nov 97	RESZ 442	REF 1	
ABSY|Dath\In(1S)MIV
DT|08 Nov 97
ID|FBab0025294
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 6 | 19 - 12 | 20 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 6 | 19 - 12 | 20 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025295	CLA 1 Inversion	GSYM 1 Dath\In(1S)MIX	DT 1 08 Nov 97	RESZ 412	REF 1	
ABSY|Dath\In(1S)MIX
DT|08 Nov 97
ID|FBab0025295
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 7 | 20 - 12 | 6 | 21 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 2d | 25 - 23p | 26d | 2p - 5 | 11 - 7 | 20 - 12 | 6 | 21 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025296	CLA 1 Inversion	GSYM 1 Dath\In(1S)MV	DT 1 08 Nov 97	RESZ 389	REF 1	
ABSY|Dath\In(1S)MV
DT|08 Nov 97
ID|FBab0025296
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 24p | 18 - 24d | 17 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 24p | 18 - 24d | 17 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025297	CLA 1 Inversion	GSYM 1 Dath\In(1S)MVI	DT 1 08 Nov 97	RESZ 366	REF 1	
ABSY|Dath\In(1S)MVI
DT|08 Nov 97
ID|FBab0025297
REF
{
REFM|FBrf0020734
|Miller and Voelker
|1969
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 23 | 12 - 22 | 6 - 11 | 5 - 2p | 26.
MU|natural population
REFDSR
{
RDID|FBrf0020734
|Miller and Voelker
|1969
NCO|1 - 2d | 25 - 23 | 12 - 22 | 6 - 11 | 5 - 2p | 26.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025298	CLA 1 Inversion	GSYM 1 Dath\In(1S)MVII	DT 1 08 Nov 97	RESZ 417	REF 1	
ABSY|Dath\In(1S)MVII
DT|08 Nov 97
ID|FBab0025298
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 24p | 18 - 24d | 17 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI Dath\In(1S)MII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 2d | 25 - 24p | 18 - 24d | 17 - 12 | 6 - 11 | 5 - 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI Dath\In(1S)MII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025299	CLA 1 Inversion	GSYM 1 Dath\In(1S)MVIII	DT 1 08 Nov 97	RESZ 478	REF 1	
ABSY|Dath\In(1S)MVIII
DT|08 Nov 97
ID|FBab0025299
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 2d | 25 - 24p | 10 - 11 | 5 - 2p | 26d | 23p - 24d | 9 - 6 | 19 - 22 | 20 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII Dath\In(1S)MIV
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 2d | 25 - 24p | 10 - 11 | 5 - 2p | 26d | 23p - 24d | 9 - 6 | 19 - 22 | 20 - 23d | 26p.
MU|natural population
PRG|Dath\In(1S)MIII Dath\In(1S)MIV
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025300	CLA 1 Inversion	GSYM 1 Dath\In(1S)MX	DT 1 08 Nov 97	RESZ 395	REF 1	
ABSY|Dath\In(1S)MX
DT|08 Nov 97
ID|FBab0025300
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 2d | 19p - 25 | 19d - 12 | 6 | 11 | 5 | 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI Dath\In(1S)MII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 2d | 19p - 25 | 19d - 12 | 6 | 11 | 5 | 2p | 26.
MU|natural population
PRG|Dath\In(1S)MI Dath\In(1S)MII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025301	CLA 1 Inversion	GSYM 1 Dath\In(BL)MII	DT 1 08 Nov 97	RESZ 334	REF 1	
ABSY|Dath\In(BL)MII
DT|08 Nov 97
SYN|In(BL)II
ID|FBab0025301
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 4 | 18 - 5 | 19 - 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 4 | 18 - 5 | 19 - 24.
MU|natural population
SYN|In(BL)II
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025302	CLA 1 Inversion	GSYM 1 Dath\In(BL)MIII	DT 1 08 Nov 97	RESZ 343	REF 1	
ABSY|Dath\In(BL)MIII
DT|08 Nov 97
ID|FBab0025302
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 3 | 10p - 18 | 4 | 10d - 5 | 19 - 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 3 | 10p - 18 | 4 | 10d - 5 | 19 - 24.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025303	CLA 1 Inversion	GSYM 1 Dath\In(BL)MIV	DT 1 08 Nov 97	RESZ 346	REF 1	
ABSY|Dath\In(BL)MIV
DT|08 Nov 97
ID|FBab0025303
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 2 | 15 - 18 | 4 - 3 | 14 - 5 | 19 - 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 2 | 15 - 18 | 4 - 3 | 14 - 5 | 19 - 24.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025304	CLA 1 Inversion	GSYM 1 Dath\In(BL)MV	DT 1 08 Nov 97	RESZ 359	REF 1	
ABSY|Dath\In(BL)MV
DT|08 Nov 97
ID|FBab0025304
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 2 | 15 - 18 | 8 - 14 | 3- 4 | 7 - 5 | 19 - 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 2 | 15 - 18 | 8 - 14 | 3- 4 | 7 - 5 | 19 - 24.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025305	CLA 1 Inversion	GSYM 1 Dath\In(BS)MII	DT 1 08 Nov 97	RESZ 310	REF 1	
ABSY|Dath\In(BS)MII
DT|08 Nov 97
ID|FBab0025305
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 6 | 10 - 7 | 11 - 15.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 6 | 10 - 7 | 11 - 15.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025306	CLA 1 Inversion	GSYM 1 Dath\In(C)II	DT 1 08 Nov 97	RESZ 241	CLOC 1 6;14	REF 1	
ABSY|Dath\In(C)II
DT|08 Nov 97
ID|FBab0025306
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|6;14
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
OTH|Hypothetical.
BPT|6;14
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025307	CLA 1 Inversion	GSYM 1 Dath\In(C)III	DT 1 08 Nov 97	RESZ 269	CLOC 1 5;8p	REF 1	
ABSY|Dath\In(C)III
DT|08 Nov 97
ID|FBab0025307
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|5;8p
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|5;8p
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025308	CLA 1 Inversion	GSYM 1 Dath\In(C)IV	DT 1 08 Nov 97	RESZ 268	CLOC 1 6;13	REF 1	
ABSY|Dath\In(C)IV
DT|08 Nov 97
ID|FBab0025308
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|6;13
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|6;13
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025309	CLA 1 Inversion	GSYM 1 Dath\In(C)IX	DT 1 08 Nov 97	RESZ 268	CLOC 1 9;14	REF 1	
ABSY|Dath\In(C)IX
DT|08 Nov 97
ID|FBab0025309
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|9;14
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|9;14
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025310	CLA 1 Inversion	GSYM 1 Dath\In(C)MI	DT 1 08 Nov 97	RESZ 288	REF 1	
ABSY|Dath\In(C)MI
DT|08 Nov 97
ID|FBab0025310
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|1 | 4 - 2 | 5.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|1 | 4 - 2 | 5.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025311	CLA 1 Inversion	GSYM 1 Dath\In(C)MII	DT 1 08 Nov 97	RESZ 293	REF 1	
ABSY|Dath\In(C)MII
DT|08 Nov 97
ID|FBab0025311
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|5 | 14 - 6 | 15.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|5 | 14 - 6 | 15.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025312	CLA 1 Inversion	GSYM 1 Dath\In(C)MIII	DT 1 08 Nov 97	RESZ 316	REF 1	
ABSY|Dath\In(C)MIII
DT|08 Nov 97
ID|FBab0025312
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|32 - 33d | 35d - 33p | 35p.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|32 - 33d | 35d - 33p | 35p.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025313	CLA 1 Inversion	GSYM 1 Dath\In(C)MIV	DT 1 08 Nov 97	RESZ 325	REF 1	
ABSY|Dath\In(C)MIV
DT|08 Nov 97
ID|FBab0025313
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|3 | 9 - 14 | 5 - 4 | 8 - 6 | 15.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|3 | 9 - 14 | 5 - 4 | 8 - 6 | 15.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025314	CLA 1 Inversion	GSYM 1 Dath\In(C)MIX	DT 1 08 Nov 97	RESZ 311	REF 1	
ABSY|Dath\In(C)MIX
DT|08 Nov 97
ID|FBab0025314
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|27 | 33d - 30p | 28 | 34.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|27 | 33d - 30p | 28 | 34.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025315	CLA 1 Inversion	GSYM 1 Dath\In(C)MV	DT 1 08 Nov 97	RESZ 310	REF 1	
ABSY|Dath\In(C)MV
DT|08 Nov 97
ID|FBab0025315
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|5 | 14 | 7 - 13 | 6 | 15.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|5 | 14 | 7 - 13 | 6 | 15.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025316	CLA 1 Inversion	GSYM 1 Dath\In(C)MVI	DT 1 08 Nov 97	RESZ 271	CLOC 1 25;29	REF 1	
ABSY|Dath\In(C)MVI
DT|08 Nov 97
ID|FBab0025316
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|25;29
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|25;29
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025317	CLA 1 Inversion	GSYM 1 Dath\In(C)MVII	DT 1 08 Nov 97	RESZ 332	REF 1	
ABSY|Dath\In(C)MVII
DT|08 Nov 97
ID|FBab0025317
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|24 | 29 | 30d | 25 - 28 | 30p - 31.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|24 | 29 | 30d | 25 - 28 | 30p - 31.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025318	CLA 1 Inversion	GSYM 1 Dath\In(C)MVIII	DT 1 08 Nov 97	RESZ 355	REF 1	
ABSY|Dath\In(C)MVIII
DT|08 Nov 97
ID|FBab0025318
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|20 - 21d | 25 | 30d | 29 | 24 - 22 | 21p | 26.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|20 - 21d | 25 | 30d | 29 | 24 - 22 | 21p | 26.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025319	CLA 1 Inversion	GSYM 1 Dath\In(C)MX	DT 1 08 Nov 97	RESZ 314	REF 1	
ABSY|Dath\In(C)MX
DT|08 Nov 97
ID|FBab0025319
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|30 - 31d | 34d - 31p | 34p.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|30 - 31d | 34d - 31p | 34p.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025320	CLA 1 Inversion	GSYM 1 Dath\In(C)MXI	DT 1 08 Nov 97	RESZ 355	REF 1	
ABSY|Dath\In(C)MXI
DT|08 Nov 97
ID|FBab0025320
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|24 | 29p | 32 - 30p | 28 - 25 | 30d | 29d | 33.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|24 | 29p | 32 - 30p | 28 - 25 | 30d | 29d | 33.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025321	CLA 1 Inversion	GSYM 1 Dath\In(C)MXII	DT 1 08 Nov 97	RESZ 338	REF 1	
ABSY|Dath\In(C)MXII
DT|08 Nov 97
ID|FBab0025321
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|21 | 28 - 29 | 24 - 22 | 27 - 35 | 30.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|21 | 28 - 29 | 24 - 22 | 27 - 35 | 30.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025322	CLA 1 Inversion	GSYM 1 Dath\In(C)MXIII	DT 1 08 Nov 97	RESZ 321	REF 1	
ABSY|Dath\In(C)MXIII
DT|08 Nov 97
ID|FBab0025322
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|25 | 32 - 33d | 27 - 26 | 31.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|25 | 32 - 33d | 27 - 26 | 31.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025323	CLA 1 Inversion	GSYM 1 Dath\In(C)MXIV	DT 1 08 Nov 97	RESZ 386	REF 1	
ABSY|Dath\In(C)MXIV
DT|08 Nov 97
ID|FBab0025323
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|29 | 30dd | 31p - 33d | 27 - 25 | 30dp | 31d - 30p | 28 | 33p.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|29 | 30dd | 31p - 33d | 27 - 25 | 30dp | 31d - 30p | 28 | 33p.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025324	CLA 1 Inversion	GSYM 1 Dath\In(C)MXV	DT 1 08 Nov 97	RESZ 311	REF 1	
ABSY|Dath\In(C)MXV
DT|08 Nov 97
ID|FBab0025324
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|27 | 25p - 26 | 25d | 30.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|27 | 25p - 26 | 25d | 30.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025325	CLA 1 Inversion	GSYM 1 Dath\In(C)MXVI	DT 1 08 Nov 97	RESZ 344	REF 1	
ABSY|Dath\In(C)MXVI
DT|08 Nov 97
ID|FBab0025325
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|14 | 13p | 29p | 24 - 15 | 6 - 13d | 29d.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|14 | 13p | 29p | 24 - 15 | 6 - 13d | 29d.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025326	CLA 1 Inversion	GSYM 1 Dath\In(C)MXVII	DT 1 08 Nov 97	RESZ 323	REF 1	
ABSY|Dath\In(C)MXVII
DT|08 Nov 97
ID|FBab0025326
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|14 | 19 - 24 | 29p | 13p | 18.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|14 | 19 - 24 | 29p | 13p | 18.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025327	CLA 1 Inversion	GSYM 1 Dath\In(C)MXVIII	DT 1 08 Nov 97	RESZ 348	REF 1	
ABSY|Dath\In(C)MXVIII
DT|08 Nov 97
ID|FBab0025327
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|1 | 23 - 24 | 29p | 13p - 14 | 5 - 2 | 22.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|1 | 23 - 24 | 29p | 13p - 14 | 5 - 2 | 22.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025328	CLA 1 Inversion	GSYM 1 Dath\In(C)MXVIX	DT 1 08 Nov 97	RESZ 331	REF 1	
ABSY|Dath\In(C)MXVIX
DT|08 Nov 97
ID|FBab0025328
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|5 | 21 - 24 | 29p | 13p - 14 | 20.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|5 | 21 - 24 | 29p | 13p - 14 | 20.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025329	CLA 1 Inversion	GSYM 1 Dath\In(C)MXX	DT 1 08 Nov 97	RESZ 379	REF 1	
ABSY|Dath\In(C)MXX
DT|08 Nov 97
ID|FBab0025329
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|14 - 13p | 27 - 25 | 30d | 29 | 24 - 15 | 6 -12 | 13d | 28.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|14 - 13p | 27 - 25 | 30d | 29 | 24 - 15 | 6 -12 | 13d | 28.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025330	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXI	DT 1 08 Nov 97	RESZ 320	REF 1	
ABSY|Dath\In(C)MXXI
DT|08 Nov 97
ID|FBab0025330
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|23 | 25 | 30d | 29 | 24 | 26.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|23 | 25 | 30d | 29 | 24 | 26.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025331	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXII	DT 1 08 Nov 97	RESZ 341	REF 1	
ABSY|Dath\In(C)MXXII
DT|08 Nov 97
ID|FBab0025331
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|5 | 25 - 27 | 13p - 14 | 30d | 29 | 24.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|5 | 25 - 27 | 13p - 14 | 30d | 29 | 24.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025332	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXIII	DT 1 08 Nov 97	RESZ 430	REF 1	
ABSY|Dath\In(C)MXXIII
DT|08 Nov 97
ID|FBab0025332
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|14 - 13p | 27 - 26p | 32 - 30p | 28 | 13d - 6 | 15 - 24 | 29 | 30d | 25 - 26d | 33.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|14 - 13p | 27 - 26p | 32 - 30p | 28 | 13d - 6 | 15 - 24 | 29 | 30d | 25 - 26d | 33.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025333	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXIV	DT 1 08 Nov 97	RESZ 317	REF 1	
ABSY|Dath\In(C)MXXIV
DT|08 Nov 97
ID|FBab0025333
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|32 - 33d | 35d - 33p | 35p.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|32 - 33d | 35d - 33p | 35p.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025334	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXXI	DT 1 08 Nov 97	RESZ 345	REF 1	
ABSY|Dath\In(C)MXXXI
DT|08 Nov 97
ID|FBab0025334
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 3 | 8 - 7 | 14 - 4 | 9 - 13 | 6 | 15.
MU|natural population
PRG|Dath\In(C)MII
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 3 | 8 - 7 | 14 - 4 | 9 - 13 | 6 | 15.
MU|natural population
PRG|Dath\In(C)MII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025335	CLA 1 Inversion	GSYM 1 Dath\In(C)MXXXII	DT 1 08 Nov 97	RESZ 350	REF 1	
ABSY|Dath\In(C)MXXXII
DT|08 Nov 97
ID|FBab0025335
REF
{
REFM|FBrf0029928
|Miller
|1977
|-1
}

ACLA|Inversion
NCO|1 - 5 | 14 - 13p | 30d | 25 - 27 | 29 | 24.
MU|natural population
PRG|Dath\In(C)MXX
REFDSR
{
RDID|FBrf0029928
|Miller
|1977
NCO|1 - 5 | 14 - 13p | 30d | 25 - 27 | 29 | 24.
MU|natural population
PRG|Dath\In(C)MXX
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025336	CLA 1 Inversion	GSYM 1 Dath\In(C)V	DT 1 08 Nov 97	RESZ 269	CLOC 1 25;29	REF 1	
ABSY|Dath\In(C)V
DT|08 Nov 97
ID|FBab0025336
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|25;29
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|25;29
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025337	CLA 1 Inversion	GSYM 1 Dath\In(C)VI	DT 1 08 Nov 97	RESZ 374	REF 1	
ABSY|Dath\In(C)VI
DT|08 Nov 97
ID|FBab0025337
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|1 - 18 | 26 - 29 | 24 - 19 | 25 | 30 - 35.
MU|natural population
PRG|Dath\In(C)V
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|1 - 18 | 26 - 29 | 24 - 19 | 25 | 30 - 35.
MU|natural population
PRG|Dath\In(C)V
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025338	CLA 1 Inversion	GSYM 1 Dath\In(C)VII	DT 1 08 Nov 97	RESZ 271	CLOC 1 4p;18	REF 1	
ABSY|Dath\In(C)VII
DT|08 Nov 97
ID|FBab0025338
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|4p;18
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|4p;18
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025339	CLA 1 Inversion	GSYM 1 Dath\In(C)VIII	DT 1 08 Nov 97	RESZ 272	CLOC 1 19;24	REF 1	
ABSY|Dath\In(C)VIII
DT|08 Nov 97
ID|FBab0025339
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|19;24
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|19;24
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025340	CLA 1 Inversion	GSYM 1 Dath\In(C)X	DT 1 08 Nov 97	RESZ 269	CLOC 1 16;18	REF 1	
ABSY|Dath\In(C)X
DT|08 Nov 97
ID|FBab0025340
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|16;18
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|16;18
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025341	CLA 1 Inversion	GSYM 1 Dath\In(C)XI	DT 1 08 Nov 97	RESZ 358	REF 1	
ABSY|Dath\In(C)XI
DT|08 Nov 97
ID|FBab0025341
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|1 - 24 | 29 - 26p | 31 - 30 | 25 - 26d | 32 - 35.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|1 - 24 | 29 - 26p | 31 - 30 | 25 - 26d | 32 - 35.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025342	CLA 1 Inversion	GSYM 1 Dath\In(C)XII	DT 1 08 Nov 97	RESZ 271	CLOC 1 25;26	REF 1	
ABSY|Dath\In(C)XII
DT|08 Nov 97
ID|FBab0025342
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|25;26
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|25;26
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025343	CLA 1 Inversion	GSYM 1 Dath\In(C)XIII	DT 1 08 Nov 97	RESZ 344	REF 1	
ABSY|Dath\In(C)XIII
DT|08 Nov 97
ID|FBab0025343
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
NCO|1 - 18 | 29 | 24 - 19 | 28 -25 | 30 - 35.
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
NCO|1 - 18 | 29 | 24 - 19 | 28 -25 | 30 - 35.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025344	CLA 1 Inversion	GSYM 1 Dath\In(C)XIV	DT 1 08 Nov 97	RESZ 271	CLOC 1 1p;18	REF 1	
ABSY|Dath\In(C)XIV
DT|08 Nov 97
ID|FBab0025344
REF
{
REFM|FBrf0019854
|Miller and Voelker
|1968
|-1
}

ACLA|Inversion
BPT|1p;18
MU|natural population
REFDSR
{
RDID|FBrf0019854
|Miller and Voelker
|1968
BPT|1p;18
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025345	CLA 1 Inversion	GSYM 1 Dath\In(EL)II	DT 1 08 Nov 97	RESZ 329	REF 1	
ABSY|Dath\In(EL)II
DT|08 Nov 97
SYN|In(EL)MII
ID|FBab0025345
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 16 | 23 - 17 | 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 16 | 23 - 17 | 24.
MU|natural population
SYN|In(EL)MII
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025346	CLA 1 Inversion	GSYM 1 Dath\In(EL)III	DT 1 08 Nov 97	RESZ 310	REF 1	
ABSY|Dath\In(EL)III
DT|08 Nov 97
ID|FBab0025346
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 3 | 13 - 4 | 14 - 24.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 3 | 13 - 4 | 14 - 24.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025347	CLA 1 Inversion	GSYM 1 Dath\In(ES)II	DT 1 08 Nov 97	RESZ 313	REF 1	
ABSY|Dath\In(ES)II
DT|08 Nov 97
ID|FBab0025347
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 6d | 12 - 6p | 13 - 19.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 6d | 12 - 6p | 13 - 19.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025348	CLA 1 Inversion	GSYM 1 Dath\In(ES)MIII	DT 1 08 Nov 97	RESZ 311	REF 1	
ABSY|Dath\In(ES)MIII
DT|08 Nov 97
ID|FBab0025348
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 4 | 11 - 5 | 12 - 19.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 4 | 11 - 5 | 12 - 19.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025349	CLA 1 Inversion	GSYM 1 Dath\In(ES)MIV	DT 1 08 Nov 97	RESZ 314	REF 1	
ABSY|Dath\In(ES)MIV
DT|08 Nov 97
ID|FBab0025349
REF
{
REFM|FBrf0024126
|Miller and Voelker
|1972
|-1
}

ACLA|Inversion
NCO|1 - 7 | 14d - 8 | 14p - 19.
MU|natural population
REFDSR
{
RDID|FBrf0024126
|Miller and Voelker
|1972
NCO|1 - 7 | 14d - 8 | 14p - 19.
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025350	CLA 1 Inversion	GSYM 1 Datt\In(4)b<up>3</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Datt\In(4)b<up>3</up>
DT|11 Feb 97
ID|FBab0025350
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025351	CLA 1 Inversion	GSYM 1 Datt\In(4)c<up>3</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Datt\In(4)c<up>3</up>
DT|11 Feb 97
ID|FBab0025351
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025352	CLA 1 Inversion	GSYM 1 Dazt\In(1)beta1	DT 1 11 Feb 97	RESZ 180	CLOC 1 3;12	REF 1	
ABSY|Dazt\In(1)beta1
DT|11 Feb 97
ID|FBab0025352
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|3;12
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025353	CLA 1 Inversion	GSYM 1 Dazt\In(1)beta2	DT 1 12 Nov 00	RESZ 189	CLOC 1 17--18;21--22	REF 1	
ABSY|Dazt\In(1)beta2
DT|12 Nov 00
ID|FBab0025353
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|17--18;21--22
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025354	CLA 1 Inversion	GSYM 1 Dazt\In(1)gamma1	DT 1 27 Aug 98	RESZ 216	CLOC 1 2;3	REF 1	
ABSY|Dazt\In(1)gamma1
DT|27 Aug 98
ID|FBab0025354
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ASAL|FBal0054977 == Dazt\SR<up>1</up>
BPT|2;3
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025355	CLA 1 Inversion	GSYM 1 Dazt\In(1)gamma2	DT 1 27 Aug 98	RESZ 218	CLOC 1 11;17	REF 1	
ABSY|Dazt\In(1)gamma2
DT|27 Aug 98
ID|FBab0025355
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ASAL|FBal0089749 == Dazt\SR<up>2</up>
BPT|11;17
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025356	CLA 1 Inversion	GSYM 1 Dazt\In(1)gamma3	DT 1 28 Sep 98	RESZ 254	CLOC 1 19;21	REF 1	
ABSY|Dazt\In(1)gamma3
DT|28 Sep 98
ID|FBab0025356
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ASAL|FBal0054977 == Dazt\SR<up>1</up>
|FBal0089748 == Dazt\SR<up>3</up>
BPT|19;21
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025357	CLA 1 Inversion	GSYM 1 Dazt\In(A)beta	DT 1 11 Feb 97	RESZ 180	CLOC 1 45;53	REF 1	
ABSY|Dazt\In(A)beta
DT|11 Feb 97
ID|FBab0025357
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|45;53
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025358	CLA 1 Inversion	GSYM 1 Dazt\In(A)delta	DT 1 11 Feb 97	RESZ 214	REF 1	
ABSY|Dazt\In(A)delta
DT|11 Feb 97
ID|FBab0025358
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|39 - 44 | 46 - 45 | 57 - 47 | 58 - 60.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025359	CLA 1 Inversion	GSYM 1 Dazt\In(A)epsilon	DT 1 11 Feb 97	RESZ 218	REF 1	
ABSY|Dazt\In(A)epsilon
DT|11 Feb 97
ID|FBab0025359
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|39 - 46 | 56d - 57 | 56p - 47 | 58 - 60.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025360	CLA 1 Inversion	GSYM 1 Dazt\In(A)eta	DT 1 11 Feb 97	RESZ 214	REF 1	
ABSY|Dazt\In(A)eta
DT|11 Feb 97
ID|FBab0025360
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|39 - 46 | 48 - 56p | 57 - 56d | 58 - 60.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025361	CLA 1 Inversion	GSYM 1 Dazt\In(A)gamma	DT 1 11 Feb 97	RESZ 181	CLOC 1 47;57	REF 1	
ABSY|Dazt\In(A)gamma
DT|11 Feb 97
ID|FBab0025361
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|47;57
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025362	CLA 1 Inversion	GSYM 1 Dazt\In(A)zeta	DT 1 11 Feb 97	RESZ 220	REF 1	
ABSY|Dazt\In(A)zeta
DT|11 Feb 97
ID|FBab0025362
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|39 - 46 | 48 - 56p | 57 | 56d | 47 | 58 - 60.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025363	CLA 1 Inversion	GSYM 1 Dazt\In(B1)beta-d	DT 1 11 Feb 97	RESZ 183	CLOC 1 61;64	REF 1	
ABSY|Dazt\In(B1)beta-d
DT|11 Feb 97
ID|FBab0025363
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|61;64
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025364	CLA 1 Inversion	GSYM 1 Dazt\In(B1)beta-p	DT 1 11 Feb 97	RESZ 183	CLOC 1 66;73	REF 1	
ABSY|Dazt\In(B1)beta-p
DT|11 Feb 97
ID|FBab0025364
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

BPT|66;73
ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025365	CLA 1 Inversion	GSYM 1 Dazt\In(B1)delta	DT 1 11 Feb 97	RESZ 231	REF 1	
ABSY|Dazt\In(B1)delta
DT|11 Feb 97
ID|FBab0025365
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|61 - 66p | 73 - 72d | 69d - 72p | 69p - 66d | 74 - 78.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025366	CLA 1 Inversion	GSYM 1 Dazt\In(B1)gamma	DT 1 11 Feb 97	RESZ 224	REF 1	
ABSY|Dazt\In(B1)gamma
DT|11 Feb 97
ID|FBab0025366
REF
{
REFM|FBrf0004730
|Dobzhansky and Sokoloff
|1939
|-1
}

ACLA|Inversion
NCO|61 - 66p | 73 - 72d | 77 - 74 | 66d - 72p | 78.
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0022039	CLA 1 Inversion	GSYM 1 Dbip\In(2L)D	DT 1 27 Nov 05	RESZ 1057	REF 5	
ABSY|Dbip\In(2L)D
DT|27 Nov 05
SYN|In(D)2L
ID|FBab0022039
REF
{
REFM|FBrf0100634
|Singh and Banerjee
|1997
|-1
REFM|FBrf0093063
|Banerjee and Singh
|1996
|-1
REFM|FBrf0085944
|Singh and Banerjee
|1995
|-1
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
REFM|FBrf0053260
|Singh and Das
|1991
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
}

REFDSR
{
RDID|FBrf0053260
|Singh and Das
|1991
MU|natural population
OTH|The linked inversions @Dbip\In(2L)D@ and @Dbip\In(2R)C@ are associated
|nonrandomly in three stocks (Varanasi, Mysore and Nepai). This provides
|evidence for linkage disequilibrium between inversions maintained by
|epistatic gene interactions.
}

REFDSR
{
RDID|FBrf0085944
|Singh and Banerjee
|1995
ACLA|Inversion
SYN|In(D)2L
}

REFDSR
{
RDID|FBrf0093063
|Banerjee and Singh
|1996
SYN|In(D)2L
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027876	CLA 1 Aberration	GSYM 1 Dbip\In(2L)E	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(2L)E
DT|27 Nov 05
ID|FBab0027876
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027877	CLA 1 Aberration	GSYM 1 Dbip\In(2L)F	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(2L)F
DT|27 Nov 05
ID|FBab0027877
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027878	CLA 1 Aberration	GSYM 1 Dbip\In(2R)A	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(2R)A
DT|27 Nov 05
ID|FBab0027878
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027879	CLA 1 Aberration	GSYM 1 Dbip\In(2R)B	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(2R)B
DT|27 Nov 05
ID|FBab0027879
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0022040	CLA 1 Inversion	GSYM 1 Dbip\In(2R)C	DT 1 27 Nov 05	RESZ 1121	REF 5	
ABSY|Dbip\In(2R)C
DT|27 Nov 05
SYN|InCin2R
|In(C)2R
ID|FBab0022040
REF
{
REFM|FBrf0081364
|Banerjee and Singh
|1995
|-1
REFM|FBrf0093063
|Banerjee and Singh
|1996
|-1
REFM|FBrf0085944
|Singh and Banerjee
|1995
|-1
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
REFM|FBrf0053260
|Singh and Das
|1991
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
}

REFDSR
{
RDID|FBrf0053260
|Singh and Das
|1991
MU|natural population
OTH|The linked inversions @Dbip\In(2L)D@ and @Dbip\In(2R)C@ are associated
|nonrandomly in three stocks (Varanasi, Mysore and Nepai). This provides
|evidence for linkage disequilibrium between inversions maintained by
|epistatic gene interactions.
}

REFDSR
{
RDID|FBrf0081364
|Banerjee and Singh
|1995
SYN|InCin2R
}

REFDSR
{
RDID|FBrf0085944
|Singh and Banerjee
|1995
ACLA|Inversion
SYN|In(C)2R
}

REFDSR
{
RDID|FBrf0093063
|Banerjee and Singh
|1996
SYN|In(C)2R
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027880	CLA 1 Aberration	GSYM 1 Dbip\In(3L)G	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(3L)G
DT|27 Nov 05
ID|FBab0027880
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024813	CLA 1 Inversion	GSYM 1 Dbip\In(3L)H	DT 1 27 Nov 05	RESZ 670	REF 4	
ABSY|Dbip\In(3L)H
DT|27 Nov 05
SYN|In(H)3L
ID|FBab0024813
REF
{
REFM|FBrf0100634
|Singh and Banerjee
|1997
|-1
REFM|FBrf0093063
|Banerjee and Singh
|1996
|-1
REFM|FBrf0085944
|Singh and Banerjee
|1995
|-1
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
}

REFDSR
{
RDID|FBrf0085944
|Singh and Banerjee
|1995
ACLA|Inversion
MU|natural population
SYN|In(H)3L
}

REFDSR
{
RDID|FBrf0093063
|Banerjee and Singh
|1996
SYN|In(H)3L
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027881	CLA 1 Aberration	GSYM 1 Dbip\In(3L)I	DT 1 27 Nov 05	RESZ 245	REF 1	
ABSY|Dbip\In(3L)I
DT|27 Nov 05
ID|FBab0027881
REF
{
REFM|FBrf0051901
|Gupta and Panigrahy
|1990
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0051901
|Gupta and Panigrahy
|1990
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027126	CLA 1 Aberration	GSYM 1 Dbor\In(2)f<up>8</up>	DT 1 08 Nov 97	RESZ 244	REF 1	
ABSY|Dbor\In(2)f<up>8</up>
DT|08 Nov 97
SYN|2f<up>8</up>
ID|FBab0027126
REF
{
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2f<up>8</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027127	CLA 1 Aberration	GSYM 1 Dbor\In(2)g<up>8</up>	DT 1 08 Nov 97	RESZ 244	REF 1	
ABSY|Dbor\In(2)g<up>8</up>
DT|08 Nov 97
SYN|2g<up>8</up>
ID|FBab0027127
REF
{
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2g<up>8</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027128	CLA 1 Aberration	GSYM 1 Dbor\In(2)h<up>8</up>	DT 1 08 Nov 97	RESZ 244	REF 1	
ABSY|Dbor\In(2)h<up>8</up>
DT|08 Nov 97
SYN|2h<up>8</up>
ID|FBab0027128
REF
{
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2h<up>8</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025367	CLA 1 Inversion	GSYM 1 Dbor\In(2)m	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dbor\In(2)m
DT|08 Nov 97
ID|FBab0025367
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025368	CLA 1 Inversion	GSYM 1 Dbor\In(3)g	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dbor\In(3)g
DT|08 Nov 97
ID|FBab0025368
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025369	CLA 1 Inversion	GSYM 1 Dbor\In(3)t	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dbor\In(3)t
DT|08 Nov 97
ID|FBab0025369
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025370	CLA 1 Inversion	GSYM 1 Dbor\In(5)g	DT 1 08 Nov 97	RESZ 241	REF 1	
ABSY|Dbor\In(5)g
DT|08 Nov 97
ID|FBab0025370
REF
{
REFM|FBrf0008801
|Hsu
|1952
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0008801
|Hsu
|1952
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025371	CLA 1 Inversion	GSYM 1 Dbos\In(4)v	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Dbos\In(4)v
DT|11 Feb 97
ID|FBab0025371
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0027952	CLA 1 Aberration	GSYM 1 Dbrb\In(2)e<up>8</up>	DT 1 16 Jun 98	RESZ 288	REF 1	
ABSY|Dbrb\In(2)e<up>8</up>
DT|16 Jun 98
SYN|2e<up>8</up>
ID|FBab0027952
REF
{
REFM|FBrf0100627
|Ruiz et al.
|1997
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0100627
|Ruiz et al.
|1997
MU|natural population
SYN|2e<up>8</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025372	CLA 1 Inversion	GSYM 1 Dbrb\In(2)f<up>8</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dbrb\In(2)f<up>8</up>
DT|08 Nov 97
ID|FBab0025372
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025373	CLA 1 Inversion	GSYM 1 Dbrb\In(2)g<up>8</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dbrb\In(2)g<up>8</up>
DT|08 Nov 97
ID|FBab0025373
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025374	CLA 1 Inversion	GSYM 1 Dbrb\In(2)h<up>8</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dbrb\In(2)h<up>8</up>
DT|08 Nov 97
ID|FBab0025374
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025375	CLA 1 Aberration	GSYM 1 Dbus\In(1)Aa	DT 1 29 Oct 99	RESZ 315	CLOC 1 X:3;X:10B;X:11C;X:20D	REF 1	
ABSY|Dbus\In(1)Aa
DT|29 Oct 99
ID|FBab0025375
REF
{
REFM|FBrf0010353
|Krivshenko
|1955
|-1
}

ASAL|FBal0054932 == Dbus\Aa<up>1</up>
BPT|X:3;X:10B;X:11C;X:20D
REFDSR
{
RDID|FBrf0010353
|Krivshenko
|1955
BPT|X:3;X:10B;X:11C;X:20D
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025376	CLA 1 Inversion	GSYM 1 Dbus\In(1)Bly	DT 1 29 Oct 99	RESZ 269	REF 1	
ABSY|Dbus\In(1)Bly
DT|29 Oct 99
ID|FBab0025376
REF
{
REFM|FBrf0012630
|Krivshenko
|1959
|-1
}

ASAL|FBal0054927 == Dbus\Bly<up>1</up>
ACLA|Inversion
REFDSR
{
RDID|FBrf0012630
|Krivshenko
|1959
ACLA|Inversion
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025377	CLA 1 Inversion	GSYM 1 Dbus\In(1)Ce	DT 1 29 Oct 99	RESZ 467	CLOC 1 X:19;X20	REF 2	
ABSY|Dbus\In(1)Ce
DT|29 Oct 99
SYN|IN(1) CE
ID|FBab0025377
REF
{
REFM|FBrf0090158
|Drosophila Species Resource Center
|1996
|-1
REFM|FBrf0012899
|Krivshenko
|1959
|-1
}

ASAL|FBal0054926 == Dbus\Ce<up>1</up>
BPT|X:19;X20
ACLA|Inversion
MU|X ray
REFDSR
{
RDID|FBrf0012899
|Krivshenko
|1959
BPT|X:19;X20
ACLA|Inversion
MU|X ray
}

REFDSR
{
RDID|FBrf0090158
|Drosophila Species Resource Center
|1996
SYN|IN(1) CE
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025378	CLA 1 Inversion	GSYM 1 Dbus\In(1)P	DT 1 08 Nov 97	RESZ 288	CLOC 1 X:5D;X:13D	REF 1	
ABSY|Dbus\In(1)P
DT|08 Nov 97
ID|FBab0025378
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

BPT|X:5D;X:13D
ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
BPT|X:5D;X:13D
ACLA|Inversion
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025380	CLA 1 Inversion	GSYM 1 Dbus\In(2L)Dpl1	DT 1 29 Oct 99	RESZ 261	REF 1	
ABSY|Dbus\In(2L)Dpl1
DT|29 Oct 99
ID|FBab0025380
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054917 == Dbus\Dpl<up>1</up>
ACLA|Inversion
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Inversion
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025381	CLA 1 Inversion	GSYM 1 Dbus\In(2L)Hr1	DT 1 29 Oct 99	RESZ 299	REF 1	
ABSY|Dbus\In(2L)Hr1
DT|29 Oct 99
ID|FBab0025381
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054912 == Dbus\Hr<up>1</up>
ACLA|Inversion
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Inversion
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025382	CLA 1 Inversion	GSYM 1 Dbus\In(2L)SP1	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2L)SP1
DT|10 Feb 98
ID|FBab0025382
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025383	CLA 1 Inversion	GSYM 1 Dbus\In(2L)SP2	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2L)SP2
DT|10 Feb 98
ID|FBab0025383
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025384	CLA 1 Inversion	GSYM 1 Dbus\In(2L)SP3	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2L)SP3
DT|10 Feb 98
ID|FBab0025384
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025385	CLA 1 Inversion	GSYM 1 Dbus\In(2L)SP4	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2L)SP4
DT|10 Feb 98
ID|FBab0025385
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025387	CLA 1 Inversion	GSYM 1 Dbus\In(2L)Um1	DT 1 27 Aug 98	RESZ 299	REF 1	
ABSY|Dbus\In(2L)Um1
DT|27 Aug 98
ID|FBab0025387
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054896 == Dbus\Um<up>1</up>
ACLA|Inversion
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Inversion
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025388	CLA 1 Inversion	GSYM 1 Dbus\In(2R)P5	DT 1 10 Feb 98	RESZ 352	REF 1	
ABSY|Dbus\In(2R)P5
DT|10 Feb 98
ID|FBab0025388
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025389	CLA 1 Inversion	GSYM 1 Dbus\In(2R)Ro1	DT 1 20 Apr 00	RESZ 421	REF 1	
ABSY|Dbus\In(2R)Ro1
DT|20 Apr 00
ID|FBab0025389
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
COR|Associated with: @Dbus\In(2R)Ro2@.
CCM|Added to Princeton inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
COR|Associated with: @Dbus\In(2R)Ro2@.
CCM|Added to Princeton inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025379	CLA 1 Inversion	GSYM 1 Dbus\In(2R)Ro2	DT 1 20 Apr 00	RESZ 421	REF 1	
ABSY|Dbus\In(2R)Ro2
DT|20 Apr 00
ID|FBab0025379
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
COR|Associated with: @Dbus\In(2R)Ro1@.
CCM|Added to Princeton inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
COR|Associated with: @Dbus\In(2R)Ro1@.
CCM|Added to Princeton inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025390	CLA 1 Inversion	GSYM 1 Dbus\In(2R)SP1	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2R)SP1
DT|10 Feb 98
ID|FBab0025390
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025391	CLA 1 Inversion	GSYM 1 Dbus\In(2R)SP2	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2R)SP2
DT|10 Feb 98
ID|FBab0025391
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025392	CLA 1 Inversion	GSYM 1 Dbus\In(2R)SP3	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2R)SP3
DT|10 Feb 98
ID|FBab0025392
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025393	CLA 1 Inversion	GSYM 1 Dbus\In(2R)SP4	DT 1 10 Feb 98	RESZ 353	REF 1	
ABSY|Dbus\In(2R)SP4
DT|10 Feb 98
ID|FBab0025393
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Sao Paulo inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025394	CLA 1 Inversion	GSYM 1 Dbus\In(3L)Br1	DT 1 10 Feb 98	RESZ 347	REF 1	
ABSY|Dbus\In(3L)Br1
DT|10 Feb 98
ID|FBab0025394
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025395	CLA 1 Inversion	GSYM 1 Dbus\In(3L)Br2	DT 1 10 Feb 98	RESZ 347	REF 1	
ABSY|Dbus\In(3L)Br2
DT|10 Feb 98
ID|FBab0025395
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025396	CLA 1 Inversion	GSYM 1 Dbus\In(3L)Br3	DT 1 10 Feb 98	RESZ 347	REF 1	
ABSY|Dbus\In(3L)Br3
DT|10 Feb 98
ID|FBab0025396
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025397	CLA 1 Inversion	GSYM 1 Dbus\In(3L)Br4	DT 1 10 Feb 98	RESZ 347	REF 1	
ABSY|Dbus\In(3L)Br4
DT|10 Feb 98
ID|FBab0025397
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025398	CLA 1 Inversion	GSYM 1 Dbus\In(3L)Br5	DT 1 10 Feb 98	RESZ 347	REF 1	
ABSY|Dbus\In(3L)Br5
DT|10 Feb 98
ID|FBab0025398
REF
{
REFM|FBrf0015568
|Krivshenko
|1963
|-1
}

ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
REFDSR
{
RDID|FBrf0015568
|Krivshenko
|1963
ACLA|Inversion
MU|natural population
CCM|Component of Brazil inversion complex.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025399	CLA 1 Translocation	GSYM 1 Dbus\T(1;2L)Z1	DT 1 29 Oct 99	RESZ 306	REF 1	
ABSY|Dbus\T(1;2L)Z1
DT|29 Oct 99
ID|FBab0025399
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054894 == Dbus\Z<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025400	CLA 1 Translocation	GSYM 1 Dbus\T(1;2L;2R)m1	DT 1 29 Oct 99	RESZ 309	REF 1	
ABSY|Dbus\T(1;2L;2R)m1
DT|29 Oct 99
ID|FBab0025400
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054883 == Dbus\m<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025401	CLA 1 Translocation	GSYM 1 Dbus\T(1;2L;3R)ec1	DT 1 29 Oct 99	RESZ 311	REF 1	
ABSY|Dbus\T(1;2L;3R)ec1
DT|29 Oct 99
ID|FBab0025401
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054888 == Dbus\ec<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025402	CLA 1 Aberration	GSYM 1 Dbus\T(1;2R)Sms<up>2</up>	DT 1 29 Oct 99	RESZ 472	REF 2	
ABSY|Dbus\T(1;2R)Sms<up>2</up>
DT|29 Oct 99
SYN|545
|T(1;2R) SMS
ID|FBab0025402
REF
{
REFM|FBrf0090158
|Drosophila Species Resource Center
|1996
|-1
REFM|FBrf0012899
|Krivshenko
|1959
|-1
}

ASAL|FBal0054902 == Dbus\Sms<up>2</up>
MU|X ray
REFDSR
{
RDID|FBrf0012899
|Krivshenko
|1959
MU|X ray
SYN|545
}

REFDSR
{
RDID|FBrf0090158
|Drosophila Species Resource Center
|1996
OTH|Identity assumed.
SYN|T(1;2R) SMS
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025403	CLA 1 Aberration	GSYM 1 Dbus\T(1;2R;3L;3R)Ci	DT 1 12 Nov 00	RESZ 343	CLOC 1 X:20A;2R:22--23;3L:13;3R:2;3R:6	REF 1	
ABSY|Dbus\T(1;2R;3L;3R)Ci
DT|12 Nov 00
ID|FBab0025403
REF
{
REFM|FBrf0010353
|Krivshenko
|1955
|-1
}

ASAL|FBal0054924 == Dbus\Ci<up>1</up>
BPT|X:20A;2R:22--23;3L:13;3R:2;3R:6
REFDSR
{
RDID|FBrf0010353
|Krivshenko
|1955
BPT|X:20A;2R:22--23;3L:13;3R:2;3R:6
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025404	CLA 1 Translocation	GSYM 1 Dbus\T(1;3L)Ge1	DT 1 29 Oct 99	RESZ 308	REF 1	
ABSY|Dbus\T(1;3L)Ge1
DT|29 Oct 99
ID|FBab0025404
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054913 == Dbus\Ge<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025405	CLA 1 Translocation	GSYM 1 Dbus\T(1;3L)pin	DT 1 29 Oct 99	RESZ 287	REF 1	
ABSY|Dbus\T(1;3L)pin
DT|29 Oct 99
SYN|753
ID|FBab0025405
REF
{
REFM|FBrf0012899
|Krivshenko
|1959
|-1
}

ASAL|FBal0054881 == Dbus\pin<up>1</up>
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0012899
|Krivshenko
|1959
ACLA|Translocation
MU|X ray
SYN|753
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025406	CLA 1 Translocation	GSYM 1 Dbus\T(1;3L)y1	DT 1 29 Oct 99	RESZ 306	REF 1	
ABSY|Dbus\T(1;3L)y1
DT|29 Oct 99
ID|FBab0025406
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054870 == Dbus\y<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025407	CLA 1 Translocation	GSYM 1 Dbus\T(1;3L;3R)fo1	DT 1 29 Oct 99	RESZ 311	REF 1	
ABSY|Dbus\T(1;3L;3R)fo1
DT|29 Oct 99
ID|FBab0025407
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054886 == Dbus\fo<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025408	CLA 1 Translocation	GSYM 1 Dbus\T(1;3R)mo	DT 1 29 Oct 99	RESZ 425	REF 2	
ABSY|Dbus\T(1;3R)mo
DT|29 Oct 99
SYN|188
ID|FBab0025408
REF
{
REFM|FBrf0012899
|Krivshenko
|1959
|-1
REFM|FBrf0012630
|Krivshenko
|1959
|-1
}

ASAL|FBal0054882 == Dbus\mo<up>1</up>
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0012630
|Krivshenko
|1959
ACLA|Translocation
}

REFDSR
{
RDID|FBrf0012899
|Krivshenko
|1959
MU|X ray
SYN|188
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025409	CLA 1 Translocation	GSYM 1 Dbus\T(2L;2R;3R)Dl1	DT 1 29 Oct 99	RESZ 272	REF 1	
ABSY|Dbus\T(2L;2R;3R)Dl1
DT|29 Oct 99
ID|FBab0025409
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054919 == Dbus\Dl<up>1</up>
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025410	CLA 1 Translocation	GSYM 1 Dbus\T(2L;2R;3R)Dt1	DT 1 29 Oct 99	RESZ 312	REF 1	
ABSY|Dbus\T(2L;2R;3R)Dt1
DT|29 Oct 99
ID|FBab0025410
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054916 == Dbus\Dt<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025411	CLA 1 Translocation	GSYM 1 Dbus\T(2L;3L)Dpl1	DT 1 29 Oct 99	RESZ 311	REF 1	
ABSY|Dbus\T(2L;3L)Dpl1
DT|29 Oct 99
ID|FBab0025411
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054917 == Dbus\Dpl<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025412	CLA 1 Translocation	GSYM 1 Dbus\T(2L;3R)Hr1	DT 1 29 Oct 99	RESZ 269	REF 1	
ABSY|Dbus\T(2L;3R)Hr1
DT|29 Oct 99
ID|FBab0025412
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054912 == Dbus\Hr<up>1</up>
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025413	CLA 1 Translocation	GSYM 1 Dbus\T(2R;3L)Chy1	DT 1 29 Oct 99	RESZ 311	REF 1	
ABSY|Dbus\T(2R;3L)Chy1
DT|29 Oct 99
ID|FBab0025413
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054925 == Dbus\Chy<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025414	CLA 1 Translocation	GSYM 1 Dbus\T(2R;3L)Cv1	DT 1 29 Oct 99	RESZ 309	REF 1	
ABSY|Dbus\T(2R;3L)Cv1
DT|29 Oct 99
ID|FBab0025414
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054920 == Dbus\Cv<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025415	CLA 1 Translocation	GSYM 1 Dbus\T(2R;3R)Ab1	DT 1 29 Oct 99	RESZ 309	REF 1	
ABSY|Dbus\T(2R;3R)Ab1
DT|29 Oct 99
ID|FBab0025415
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054931 == Dbus\Ab<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025416	CLA 1 Translocation	GSYM 1 Dbus\T(2R;3R)Um1	DT 1 29 Oct 99	RESZ 269	REF 1	
ABSY|Dbus\T(2R;3R)Um1
DT|29 Oct 99
ID|FBab0025416
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054896 == Dbus\Um<up>1</up>
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025418	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2L;2R)Dl<up>2</up>	DT 1 29 Oct 99	RESZ 370	REF 1	
ABSY|Dbus\T(Y;2L;2R)Dl<up>2</up>
DT|29 Oct 99
SYN|356
ID|FBab0025418
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054918 == Dbus\Dl<up>2</up>
ACLA|Translocation
DIS|J.D. Krivshenko, 15 August 1949.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
ACLA|Translocation
DIS|J.D. Krivshenko, 15 August 1949.
MU|X ray
SYN|356
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025419	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2L;3L)Crd1	DT 1 29 Oct 99	RESZ 313	REF 1	
ABSY|Dbus\T(Y;2L;3L)Crd1
DT|29 Oct 99
ID|FBab0025419
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054923 == Dbus\Crd<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025420	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2R)Cu<up>1</up>	DT 1 29 Oct 99	RESZ 369	REF 1	
ABSY|Dbus\T(Y;2R)Cu<up>1</up>
DT|29 Oct 99
SYN|404
ID|FBab0025420
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054922 == Dbus\Cu<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko, 28 October 1949.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
ACLA|Translocation
DIS|J.D. Krivshenko, 28 October 1949.
MU|X ray
SYN|404
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025421	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2R)Curled-Y(404)	DT 1 12 Nov 00	RESZ 314	CLOC 1 h1--h25;2R:7	REF 1	
ABSY|Dbus\T(Y;2R)Curled-Y(404)
DT|12 Nov 00
ID|FBab0025421
REF
{
REFM|FBrf0007940
|Krivshenko
|1950
|-1
}

BPT|h1--h25;2R:7
ACLA|Translocation
MU|X ray
REFDSR
{
RDID|FBrf0007940
|Krivshenko
|1950
BPT|h1--h25;2R:7
ACLA|Translocation
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025422	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2R)Inc1	DT 1 29 Oct 99	RESZ 310	REF 1	
ABSY|Dbus\T(Y;2R)Inc1
DT|29 Oct 99
ID|FBab0025422
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054911 == Dbus\Inc<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025423	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2R)Ri	DT 1 29 Oct 99	RESZ 277	REF 1	
ABSY|Dbus\T(Y;2R)Ri
DT|29 Oct 99
ID|FBab0025423
REF
{
REFM|FBrf0012630
|Krivshenko
|1959
|-1
}

ASAL|FBal0054904 == Dbus\Ri<up>1</up>
ACLA|Translocation
REFDSR
{
RDID|FBrf0012630
|Krivshenko
|1959
ACLA|Translocation
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025424	CLA 1 Translocation	GSYM 1 Dbus\T(Y;2R)Sp<up>1</up>	DT 1 29 Oct 99	RESZ 363	REF 1	
ABSY|Dbus\T(Y;2R)Sp<up>1</up>
DT|29 Oct 99
SYN|186
ID|FBab0025424
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054900 == Dbus\Sp<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko, 30 June 1949.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
ACLA|Translocation
DIS|J.D. Krivshenko, 30 June 1949.
MU|X ray
SYN|186
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025425	CLA 1 Translocation	GSYM 1 Dbus\T(Y;3L)Ga1	DT 1 29 Oct 99	RESZ 308	REF 1	
ABSY|Dbus\T(Y;3L)Ga1
DT|29 Oct 99
ID|FBab0025425
REF
{
REFM|FBrf0090292
|Krivshenko
|1939
|-1
}

ASAL|FBal0054914 == Dbus\Ga<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
REFDSR
{
RDID|FBrf0090292
|Krivshenko
|1939
ACLA|Translocation
DIS|J.D. Krivshenko.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025426	CLA 1 Translocation	GSYM 1 Dbus\T(Y;3L)M-Y<up>1</up>	DT 1 29 Oct 99	RESZ 380	REF 1	
ABSY|Dbus\T(Y;3L)M-Y<up>1</up>
DT|29 Oct 99
SYN|236
ID2|FBab0025417
ID|FBab0025426
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054910 == Dbus\M-Y<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko, October 1937.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
ACLA|Translocation
DIS|J.D. Krivshenko, October 1937.
MU|X ray
SYN|236
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028065	CLA 1 Aberration	GSYM 1 Dbus\T(Y;3L)M<up>1</up>	DT 1 29 Oct 99	RESZ 313	REF 1	
ABSY|Dbus\T(Y;3L)M<up>1</up>
DT|29 Oct 99
ID|FBab0028065
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054909 == Dbus\M<up>1</up>
DIS|J.D. Krivshenko, October 1937.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
DIS|J.D. Krivshenko, October 1937.
MU|X ray
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025427	CLA 1 Translocation	GSYM 1 Dbus\T(Y;3R)Ec<up>1</up>	DT 1 29 Oct 99	RESZ 371	REF 1	
ABSY|Dbus\T(Y;3R)Ec<up>1</up>
DT|29 Oct 99
SYN|507/1
ID|FBab0025427
REF
{
REFM|FBrf0008559
|Krivshenko
|1952
|-1
}

ASAL|FBal0054915 == Dbus\Ec<up>1</up>
ACLA|Translocation
DIS|J.D. Krivshenko, 9 January 1950.
MU|X ray
REFDSR
{
RDID|FBrf0008559
|Krivshenko
|1952
ACLA|Translocation
DIS|J.D. Krivshenko, 9 January 1950.
MU|X ray
SYN|507/1
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025428	CLA 1 Aberration	GSYM 1 Dbus\Tp(1;3L)Sms<up>1</up>	DT 1 29 Oct 99	RESZ 438	REF 2	
ABSY|Dbus\Tp(1;3L)Sms<up>1</up>
DT|29 Oct 99
SYN|916
ID|FBab0025428
REF
{
REFM|FBrf0012899
|Krivshenko
|1959
|-1
REFM|FBrf0012630
|Krivshenko
|1959
|-1
}

ASAL|FBal0054903 == Dbus\Sms<up>1</up>
MU|X ray
CCM|Transposition
REFDSR
{
RDID|FBrf0012630
|Krivshenko
|1959
CCM|Transposition
}

REFDSR
{
RDID|FBrf0012899
|Krivshenko
|1959
MU|X ray
SYN|916
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025429	CLA 1 Inversion	GSYM 1 Dbuz\In(2)c<up>9</up>	DT 1 29 Feb 04	RESZ 754	REF 4	
ABSY|Dbuz\In(2)c<up>9</up>
DT|29 Feb 04
SYN|2jc<up>9</up>
|2c<up>9</up>
ID|FBab0025429
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0136875
|Dahlgaard et al.
|2001
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2jc<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2c<up>9</up>
}

REFDSR
{
RDID|FBrf0136875
|Dahlgaard et al.
|2001
SYN|2jc<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025430	CLA 1 Inversion	GSYM 1 Dbuz\In(2)d<up>9</up>	DT 1 01 Feb 00	RESZ 568	REF 3	
ABSY|Dbuz\In(2)d<up>9</up>
DT|01 Feb 00
ID|FBab0025430
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2jd<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2d<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025431	CLA 1 Inversion	GSYM 1 Dbuz\In(2)e<up>9</up>	DT 1 01 Feb 00	RESZ 567	REF 3	
ABSY|Dbuz\In(2)e<up>9</up>
DT|01 Feb 00
ID|FBab0025431
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2e<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2e<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025432	CLA 1 Inversion	GSYM 1 Dbuz\In(2)f<up>9</up>	DT 1 08 Nov 97	RESZ 435	REF 2	
ABSY|Dbuz\In(2)f<up>9</up>
DT|08 Nov 97
SYN|2f<up>9</up>
ID|FBab0025432
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2f<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025433	CLA 1 Inversion	GSYM 1 Dbuz\In(2)g<up>9</up>	DT 1 01 Feb 00	RESZ 567	REF 3	
ABSY|Dbuz\In(2)g<up>9</up>
DT|01 Feb 00
ID|FBab0025433
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2g<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2g<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025434	CLA 1 Inversion	GSYM 1 Dbuz\In(2)h<up>9</up>	DT 1 01 Feb 00	RESZ 568	REF 3	
ABSY|Dbuz\In(2)h<up>9</up>
DT|01 Feb 00
ID|FBab0025434
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2jh<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2h<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025435	CLA 1 Inversion	GSYM 1 Dbuz\In(2)i<up>9</up>	DT 1 01 Feb 00	RESZ 568	REF 3	
ABSY|Dbuz\In(2)i<up>9</up>
DT|01 Feb 00
ID|FBab0025435
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2ji<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2i<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025436	CLA 1 Inversion	GSYM 1 Dbuz\In(2)j	DT 1 27 Nov 05	RESZ 36013	DBA 61	ALESR 30	REF 32	
ABSY|Dbuz\In(2)j
DT|27 Nov 05
SYN|2j
|j
|jz<up>3</up>
|2jq<up>7</up>
|2jz<up>3</up>
|2J
|J
|JZ<up>3</up>
|2JZ<up>3</up>
|2JQ7
|2JZ3
ID|FBab0025436
REF
{
REFM|FBrf0146320
|Puig et al.
|2002
|-1
REFM|FBrf0099859
|Norry et al.
|1997
|-1
REFM|FBrf0056348
|Hasson et al.
|1992
|-1
REFM|FBrf0147121
|Fernandez Iriarte et al.
|2002
|-1
REFM|FBrf0102137
|Betran et al.
|1998
|-1
REFM|FBrf0109445
|Caceres et al.
|1999
|-1
REFM|FBrf0036047
|Ruiz and Fontdevila
|1981
|-1
REFM|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
|-1
REFM|FBrf0079895
|Betran et al.
|1995
|-1
REFM|FBrf0098863
|Norry et al.
|1997
|-1
REFM|FBrf0108453
|Rodriguez et al.
|1999
|-1
REFM|FBrf0106290
|Caceres et al.
|1999
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0138543
|Kidwell and Holyoake
|2001
|-1
REFM|FBrf0067195
|Barker
|1994
|-1
REFM|FBrf0098780
|Fanara et al.
|1997
|-1
REFM|FBrf0179396
|Puig et al.
|2004
|-1
REFM|FBrf0187633
|Casals et al.
|2005
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
|-1
REFM|FBrf0108260
|Ranz et al.
|1999
|-1
REFM|FBrf0016682
|Carson and Wasserman
|1965
|-1
REFM|FBrf0076525
|Vilardi et al.
|1994
|-1
REFM|FBrf0125477
|Fernandez Iriarte et al.
|1999
|-1
REFM|FBrf0136875
|Dahlgaard et al.
|2001
|-1
REFM|FBrf0132383
|Rodriguez et al.
|2000
|-1
REFM|FBrf0131339
|Laayouni et al.
|2000
|-1
REFM|FBrf0084230
|Norry et al.
|1995
|-1
REFM|FBrf0137257
|Caceres et al.
|2001
|-1
REFM|FBrf0081984
|Fanara et al.
|1995
|-1
REFM|FBrf0078017
|Barbadilla et al.
|1994
|-1
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
COR|@Dbuz\Galileo@ insertions lie at both @Dbuz\In(2)j@ inversion
|breakpoints not present in the "2 standard" (2st) progenitor
|chromosome.  7bp sequences, like target site duplications, flank the
|insertions, but the duplicated sequences are separated and inverted,
|suggesting that @Dbuz\In(2)j@ arose by intrachromosomal pairing and
|recombination between the two homologous sequences inserted in distant
|sites in opposite orientations. All versions of @Dbuz\In(2)j@ tested
|(21 lines) show the same pattern of @Dbuz\Galileo@ insertion,
|suggesting that the @Dbuz\In(2)j@ arrangements are monophyletic.
DBA|NA:AF162796
|NA:AF162797
|NA:AF162798
|NA:AF162799
|NA:AF368842
|NA:AF368843
|NA:AF368844
|NA:AF368845
|NA:AF368846
|NA:AF368847
|NA:AF368848
|NA:AF368849
|NA:AF368851
|NA:AF368852
|NA:AF368853
|NA:AF368854
|NA:AF368855
|NA:AF368856
|NA:AF368857
|NA:AF368858
|NA:AF368861
|NA:AF368862
|NA:AF368863
|NA:AF368864
|NA:AF368865
|NA:AF368866
|NA:AF368867
|NA:AF368868
|NA:AF368869
|NA:AF368870
|NA:AF368871
|NA:AF368872
|NA:AF368873
|NA:AF368874
|NA:AF368875
|NA:AF368876
|NA:AF368877
|NA:AF368878
|NA:AF368879
|NA:AF368880
|NA:AF368881
|NA:AF368882
|NA:AF368883
|NA:AF368884
|NA:AF368885
|NA:AF368886
|NA:AF368887
|NA:AF368888
|NA:AF368889
|NA:AF368890
|NA:AF368891
|NA:AF368892
|NA:AF368893
|NA:AF368894
|NA:AF368895
|NA:AF368896
|NA:AF368897
|NA:AF368898
|NA:AF368899
|NA:AF368900
|NA:AY551073
REFDSR
{
RDID|FBrf0036047
|Ruiz and Fontdevila
|1981
MU|natural population
}

REFDSR
{
RDID|FBrf0056348
|Hasson et al.
|1992
PHP|Rearrangements are correlated with a large thorax size.
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2j
}

REFDSR
{
RDID|FBrf0067195
|Barker
|1994
SYN|j
}

REFDSR
{
RDID|FBrf0076525
|Vilardi et al.
|1994
SYN|2j
}

REFDSR
{
RDID|FBrf0078017
|Barbadilla et al.
|1994
SYN|2j
}

REFDSR
{
RDID|FBrf0079895
|Betran et al.
|1995
SYN|2j
}

REFDSR
{
RDID|FBrf0081984
|Fanara et al.
|1995
SYN|j
|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0084230
|Norry et al.
|1995
SYN|2j
}

REFDSR
{
RDID|FBrf0098780
|Fanara et al.
|1997
PHP|The biometrical effect of inversions on body size is due to genetic
|differences between rearrangements and not to the historical relationship
|between the populations studied.
SYN|j
}

REFDSR
{
RDID|FBrf0098863
|Norry et al.
|1997
PHP|Genetic variation in correlations among size-related traits of head,
|thorax and wings are examined in D.buzzatii by comparing the pattern
|of the Phenotypic Correlation Matrix between inversion karyotypes of
|the second chromosomes. Results indicate chromosome inversions are
|factors affecting genetic correlations among traits known to be phenotypically
|correlated with adult fitness components.
SYN|j
}

REFDSR
{
RDID|FBrf0099859
|Norry et al.
|1997
SYN|j
|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0102137
|Betran et al.
|1998
SYN|2j
|2jq<up>7</up>
|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0106290
|Caceres et al.
|1999
SYN|2j
}

REFDSR
{
RDID|FBrf0108260
|Ranz et al.
|1999
SYN|2j
}

REFDSR
{
RDID|FBrf0108453
|Rodriguez et al.
|1999
SYN|2J
}

REFDSR
{
RDID|FBrf0109445
|Caceres et al.
|1999
COR|@Dbuz\Galileo@ insertions lie at both @Dbuz\In(2)j@ inversion
|breakpoints not present in the "2 standard" (2st) progenitor
|chromosome.  7bp sequences, like target site duplications, flank the
|insertions, but the duplicated sequences are separated and inverted,
|suggesting that @Dbuz\In(2)j@ arose by intrachromosomal pairing and
|recombination between the two homologous sequences inserted in distant
|sites in opposite orientations. All versions of @Dbuz\In(2)j@ tested
|(21 lines) show the same pattern of @Dbuz\Galileo@ insertion,
|suggesting that the @Dbuz\In(2)j@ arrangements are monophyletic.
SYN|2j
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2j
}

REFDSR
{
RDID|FBrf0125477
|Fernandez Iriarte et al.
|1999
SYN|J
|JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
SYN|2j
|2jq<up>7</up>
|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0131339
|Laayouni et al.
|2000
SYN|j
}

REFDSR
{
RDID|FBrf0132383
|Rodriguez et al.
|2000
SYN|2J
|2JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0136875
|Dahlgaard et al.
|2001
SYN|2j
|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
SYN|2J
|2JQ7
|2JZ3
}

REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|2j
|2jq<up>7</up>
|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0138543
|Kidwell and Holyoake
|2001
SYN|2j
}

REFDSR
{
RDID|FBrf0146320
|Puig et al.
|2002
SYN|2j
}

REFDSR
{
RDID|FBrf0147121
|Fernandez Iriarte et al.
|2002
SYN|2J
|2JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|2j
}

BGV
{
BGVSY|Dbuz\In(2)j-1
SYN|j-1
ID|FBba0000470
REF|FBrf0137257
|FBrf0187633
|FBrf0179396
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-1
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|j-1
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|j-1
}

}

BGV
{
BGVSY|Dbuz\In(2)j-10
SYN|j-10
ID|FBba0000471
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-10
TRNA|FBti0023948 == Dbuz\BuT1{}j-10
|FBti0023949 == Dbuz\Kepler{}j-10-1
|FBti0023970 == Dbuz\INE-1{}j-10
|FBti0023971 == Dbuz\Kepler{}j-10-2
|FBti0023972 == Dbuz\Galileo{}j-10
PHP|Isolated from: Palo Labrado, Argentina.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-11
SYN|j-11
ID|FBba0000472
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-11
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Los Negros, Bolivia.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-12
SYN|j-12
ID|FBba0000473
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-12
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Guaritas, Brazil.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-13
SYN|j-13
ID|FBba0000474
REF|FBrf0137257
|FBrf0179396
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-13
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Guaritas, Brazil.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|j-13
}

}

BGV
{
BGVSY|Dbuz\In(2)j-14
SYN|j-14
ID|FBba0000475
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-14
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-15
SYN|j-15
ID|FBba0000476
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-15
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Catamarca, Argentina.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-16
SYN|j-16
ID|FBba0000477
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-16
TRNA|FBti0023938 == Dbuz\BuT1{}jz<up>3</up>-4
|FBti0023939 == Dbuz\Galileo{}jz<up>3</up>-4
|FBti0023940 == Dbuz\BuT3{}jz<up>3</up>-4
|FBti0023941 == Dbuz\Kepler{}jz<up>3</up>-4
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Salta, Argentina.
|Variants @Dbuz\In(2)j-16@ and @Dbuz\In(2)jz<up>3</up>-4@ have the same structure
|at the proximal breakpoint except that @Dbuz\In(2)jz<up>3</up>-4@ has a deletion
|which is not present in @Dbuz\In(2)j-16@.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-17
SYN|j-17
ID|FBba0000478
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-17
TRNA|FBti0023942 == Dbuz\BuT1{}j-17
|FBti0023943 == Dbuz\BuT3{}j-17
|FBti0023944 == Dbuz\Kepler{}j-17
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Tilcara, Argentina.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-18
SYN|j-18
ID|FBba0000479
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-18
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Termas Rio Hondo, Argentina.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-19
SYN|j-19
ID|FBba0000480
REF|FBrf0137257
|FBrf0187633
|FBrf0179396
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-19
TRNA|FBti0023953 == Dbuz\BuT1{}j-19
|FBti0023954 == Dbuz\BuT3{}j-19
|FBti0023955 == Dbuz\Newton{}j-19
|FBti0023956 == Dbuz\Kepler{}j-19-1
|FBti0023973 == Dbuz\INE-1{}j-19
|FBti0023974 == Dbuz\Kepler{}j-19-2
|FBti0023975 == Dbuz\Galileo{}j-19
PHP|Isolated from: Ticucho, Argentina.
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|j-19
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|j-19
}

}

BGV
{
BGVSY|Dbuz\In(2)j-2
SYN|j-2
ID|FBba0000481
REF|FBrf0137257
|FBrf0187633
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-2
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|j-2
}

}

BGV
{
BGVSY|Dbuz\In(2)j-20
SYN|j-20
ID|FBba0000482
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-20
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Hemmant, Australia.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-21
SYN|j-21
ID|FBba0000483
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-21
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Hemmant, Australia.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-22
SYN|j-22
ID|FBba0000484
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-22
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Trinkey, Australia.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-3
SYN|j-3
ID|FBba0000485
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-3
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-4
SYN|j-4
ID|FBba0000486
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-4
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-5
SYN|j-5
ID|FBba0000487
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-5
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-6
SYN|j-6
ID|FBba0000488
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-6
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-7
SYN|j-7
ID|FBba0000489
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-7
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Caldetas, Spain.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)j-8
SYN|j-8
ID|FBba0000490
REF|FBrf0137257
|FBrf0187633
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-8
TRNA|FBti0023945 == Dbuz\BuT1{}j-8
|FBti0023946 == Dbuz\BuT2{}j-8
|FBti0023947 == Dbuz\Kepler{}j-8
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: San Luis, Argentina.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|j-8
}

}

BGV
{
BGVSY|Dbuz\In(2)j-9
SYN|j-9
ID|FBba0000491
REF|FBrf0137257
|FBrf0187633
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|j-9
TRNA|FBti0023950 == Dbuz\BuT1{}j-12
|FBti0023951 == Dbuz\BuT3{}j-12
|FBti0023952 == Dbuz\Kepler{}j-12
|FBti0023967 == Dbuz\INE-1{}j-9
|FBti0023969 == Dbuz\ISBu2{}j-9
PHP|Isolated from: Quilmes, Argentina.
|Variants @Dbuz\In(2)j-9@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-18@ and @Dbuz\In(2)j-22@ have the same structure at the
|proximal breakpoint (although @Dbuz\In(2)j-12@ has a deletion in this
|region detected during sequencing and it is not known whether this
|deletion is present in the other variants).
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|j-9
}

}

BGV
{
BGVSY|Dbuz\In(2)jq<up>7</up>-1
SYN|jq<up>7</up>-1
ID|FBba0000492
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jq<up>7</up>-1
TRNA|FBti0023933 == Dbuz\BuT1{}jq<up>7</up>-2
|FBti0023934 == Dbuz\BuT3{}jq<up>7</up>-2-1
|FBti0023935 == Dbuz\Kepler{}jq<up>7</up>-2-1
|FBti0023936 == Dbuz\Kepler{}jq<up>7</up>-2-2
|FBti0023937 == Dbuz\INE-1{}jq<up>7</up>-2-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)jq<up>7</up>-1@, @Dbuz\In(2)jq<up>7</up>-2@ and @Dbuz\In(2)jq<up>7</up>-3@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jq<up>7</up>-2
SYN|jq<up>7</up>-2
ID|FBba0000493
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jq<up>7</up>-2
PHP|Isolated from: Mogan, Canary Islands, Spain.
|Variants @Dbuz\In(2)jq<up>7</up>-1@, @Dbuz\In(2)jq<up>7</up>-2@ and @Dbuz\In(2)jq<up>7</up>-3@
|have the same structure at the proximal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jq<up>7</up>-3
SYN|jq<up>7</up>-3
ID|FBba0000494
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jq<up>7</up>-3
TRNA|FBti0023933 == Dbuz\BuT1{}jq<up>7</up>-2
|FBti0023934 == Dbuz\BuT3{}jq<up>7</up>-2-1
|FBti0023935 == Dbuz\Kepler{}jq<up>7</up>-2-1
|FBti0023936 == Dbuz\Kepler{}jq<up>7</up>-2-2
|FBti0023937 == Dbuz\INE-1{}jq<up>7</up>-2-2
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Caldetas, Spain.
|Variants @Dbuz\In(2)jq<up>7</up>-1@, @Dbuz\In(2)jq<up>7</up>-2@ and @Dbuz\In(2)jq<up>7</up>-3@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jq<up>7</up>-4
SYN|jq<up>7</up>-4
ID|FBba0000495
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jq<up>7</up>-4
TRNA|FBti0023929 == Dbuz\BuT1{}j-1
|FBti0023930 == Dbuz\BuT3{}j-1
|FBti0023931 == Dbuz\Kepler{}j-1-1
|FBti0023932 == Dbuz\Kepler{}j-1-2
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Otamendi, Argentina.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@ and @Dbuz\In(2)jq<up>7</up>-4@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jz<up>3</up>-1
SYN|jz<up>3</up>-1
ID|FBba0000496
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jz<up>3</up>-1
TRNA|FBti0023957 == Dbuz\BuT1{}jz<up>3</up>-1
|FBti0023958 == Dbuz\BuT3{}jz<up>3</up>-1
|FBti0023959 == Dbuz\BuT5{}jz<up>3</up>-1
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-2@ and @Dbuz\In(2)jz<up>3</up>-3@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jz<up>3</up>-2
SYN|jz<up>3</up>-2
ID|FBba0000497
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jz<up>3</up>-2
TRNA|FBti0023957 == Dbuz\BuT1{}jz<up>3</up>-1
|FBti0023958 == Dbuz\BuT3{}jz<up>3</up>-1
|FBti0023959 == Dbuz\BuT5{}jz<up>3</up>-1
|FBti0023960 == Dbuz\INE-1{}j-1
PHP|Isolated from: Carboneras, Spain.
|Variants @Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-2@ and @Dbuz\In(2)jz<up>3</up>-3@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-1@, @Dbuz\In(2)j-2@, @Dbuz\In(2)j-3@, @Dbuz\In(2)j-4@,
|@Dbuz\In(2)j-5@, @Dbuz\In(2)j-6@, @Dbuz\In(2)j-7@, @Dbuz\In(2)j-13@,
|@Dbuz\In(2)j-15@, @Dbuz\In(2)j-20@, @Dbuz\In(2)j-21@, @Dbuz\In(2)jz<up>3</up>-2@,
|@Dbuz\In(2)jq<up>7</up>-1@ and @Dbuz\In(2)jq<up>7</up>-3@ have the same structure
|at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jz<up>3</up>-3
SYN|jz<up>3</up>-3
ID|FBba0000498
REF|FBrf0137257
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jz<up>3</up>-3
TRNA|FBti0023957 == Dbuz\BuT1{}jz<up>3</up>-1
|FBti0023958 == Dbuz\BuT3{}jz<up>3</up>-1
|FBti0023959 == Dbuz\BuT5{}jz<up>3</up>-1
|FBti0023964 == Dbuz\INE-1{}j-12
PHP|Isolated from: Kariouan, Tunisia.
|Variants @Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-2@ and @Dbuz\In(2)jz<up>3</up>-3@
|have the same structure at the proximal breakpoint.
|Variants @Dbuz\In(2)j-8@, @Dbuz\In(2)j-11@, @Dbuz\In(2)j-12@, @Dbuz\In(2)j-14@,
|@Dbuz\In(2)j-16@, @Dbuz\In(2)j-17@, @Dbuz\In(2)j-18@, @Dbuz\In(2)j-22@,
|@Dbuz\In(2)jz<up>3</up>-1@, @Dbuz\In(2)jz<up>3</up>-3@ and @Dbuz\In(2)jq<up>7</up>-4@ have
|the same structure at the distal breakpoint.
}

}

BGV
{
BGVSY|Dbuz\In(2)jz<up>3</up>-4
SYN|jz<up>3</up>-4
ID|FBba0000499
REF|FBrf0137257
|FBrf0179396
REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|jz<up>3</up>-4
PHP|Isolated from: Tilcara, Argentina.
|Variants @Dbuz\In(2)j-16@ and @Dbuz\In(2)jz<up>3</up>-4@ have the same structure
|at the proximal breakpoint except that @Dbuz\In(2)jz<up>3</up>-4@ has a deletion
|which is not present in @Dbuz\In(2)j-16@.
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|jz<up>3</up>-4
}

}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028892	CLA 1 Aberration	GSYM 1 Dbuz\In(2)j<up>9</up>	DT 1 01 Feb 00	RESZ 222	REF 1	
ABSY|Dbuz\In(2)j<up>9</up>
DT|01 Feb 00
ID|FBab0028892
REF
{
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2j<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025437	CLA 1 Inversion	GSYM 1 Dbuz\In(2)q<up>7</up>	DT 1 27 Nov 05	RESZ 3750	DBA 40	CLOC 1 D3b;G2f	REF 18	
ABSY|Dbuz\In(2)q<up>7</up>
DT|27 Nov 05
SYN|2jq<up>7</up>
|2q<up>7</up>
|jq<up>7</up>
|2JQ<up>7</up>
|q<up>7</up>
|2JQ7
ID|FBab0025437
REF
{
REFM|FBrf0099859
|Norry et al.
|1997
|-1
REFM|FBrf0102137
|Betran et al.
|1998
|-1
REFM|FBrf0036047
|Ruiz and Fontdevila
|1981
|-1
REFM|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
|-1
REFM|FBrf0079895
|Betran et al.
|1995
|-1
REFM|FBrf0098863
|Norry et al.
|1997
|-1
REFM|FBrf0108453
|Rodriguez et al.
|1999
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0187633
|Casals et al.
|2005
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
|-1
REFM|FBrf0076525
|Vilardi et al.
|1994
|-1
REFM|FBrf0167873
|Negre et al.
|2003
|-1
REFM|FBrf0131339
|Laayouni et al.
|2000
|-1
REFM|FBrf0084230
|Norry et al.
|1995
|-1
REFM|FBrf0137257
|Caceres et al.
|2001
|-1
REFM|FBrf0078017
|Barbadilla et al.
|1994
|-1
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
BPT|D3b;G2f
MU|natural population
DBA|NA:AY187766
|NA:AY187767
|NA:AY187768
|NA:AY187769
|NA:AY187770
|NA:AY187771
|NA:AY187772
|NA:AY187773
|NA:AY187774
|NA:AY187775
|NA:AY187776
|NA:AY187777
|NA:AY187778
|NA:AY187779
|NA:AY187780
|NA:AY187781
|NA:AY187782
|NA:AY187783
|NA:AY187784
|NA:AY187785
|NA:AY187786
|NA:AY187787
|NA:AY187788
|NA:AY187789
|NA:AY187790
|NA:AY187791
|NA:AY187792
|NA:AY187793
|NA:AY187794
|NA:AY187795
|NA:AY187796
|NA:AY187797
|NA:AY187798
|NA:AY187799
|NA:AY187800
|NA:AY187801
|NA:AY187802
|NA:AY187803
|NA:AY187804
|NA:AY187805
REFDSR
{
RDID|FBrf0036047
|Ruiz and Fontdevila
|1981
BPT|D3b;G2f
MU|natural population
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0076525
|Vilardi et al.
|1994
SYN|2q<up>7</up>
}

REFDSR
{
RDID|FBrf0078017
|Barbadilla et al.
|1994
SYN|2q<up>7</up>
}

REFDSR
{
RDID|FBrf0079895
|Betran et al.
|1995
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0084230
|Norry et al.
|1995
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0098863
|Norry et al.
|1997
PHP|Genetic variation in correlations among size-related traits of head,
|thorax and wings are examined in D.buzzatii by comparing the pattern
|of the Phenotypic Correlation Matrix between inversion karyotypes of
|the second chromosomes. Results indicate chromosome inversions are
|factors affecting genetic correlations among traits known to be phenotypically
|correlated with adult fitness components.
SYN|jq<up>7</up>
}

REFDSR
{
RDID|FBrf0099859
|Norry et al.
|1997
SYN|jq<up>7</up>
}

REFDSR
{
RDID|FBrf0102137
|Betran et al.
|1998
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0108453
|Rodriguez et al.
|1999
SYN|2JQ<up>7</up>
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2q<up>7</up>
}

REFDSR
{
RDID|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0131339
|Laayouni et al.
|2000
SYN|q<up>7</up>
}

REFDSR
{
RDID|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
SYN|2JQ7
}

REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|2jq<up>7</up>
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|2q<up>7</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025438	CLA 1 Inversion	GSYM 1 Dbuz\In(2)r<up>9</up>	DT 1 01 Feb 00	RESZ 567	REF 3	
ABSY|Dbuz\In(2)r<up>9</up>
DT|01 Feb 00
ID|FBab0025438
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2r<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2r<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025439	CLA 1 Inversion	GSYM 1 Dbuz\In(2)s<up>9</up>	DT 1 01 Feb 00	RESZ 568	REF 3	
ABSY|Dbuz\In(2)s<up>9</up>
DT|01 Feb 00
ID|FBab0025439
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2js<up>9</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2s<up>9</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025440	CLA 1 Inversion	GSYM 1 Dbuz\In(2)y<up>3</up>	DT 1 27 Nov 05	RESZ 868	REF 6	
ABSY|Dbuz\In(2)y<up>3</up>
DT|27 Nov 05
SYN|2y<up>3</up>
ID|FBab0025440
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0016682
|Carson and Wasserman
|1965
|-1
REFM|FBrf0036047
|Ruiz and Fontdevila
|1981
|-1
REFM|FBrf0187633
|Casals et al.
|2005
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0036047
|Ruiz and Fontdevila
|1981
MU|natural population
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2y<up>3</up>
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2y<up>3</up>
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|2y<up>3</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025441	CLA 1 Inversion	GSYM 1 Dbuz\In(2)z<up>3</up>	DT 1 27 Nov 05	RESZ 4934	REF 27	
ABSY|Dbuz\In(2)z<up>3</up>
DT|27 Nov 05
SYN|2jz<up>3</up>
|z<up>3</up>
|2z<up>3</up>
|jz<up>3</up>
|2JZ<up>3</up>
|JZ<up>3</up>
|2JZ3
ID|FBab0025441
REF
{
REFM|FBrf0099859
|Norry et al.
|1997
|-1
REFM|FBrf0056348
|Hasson et al.
|1992
|-1
REFM|FBrf0147121
|Fernandez Iriarte et al.
|2002
|-1
REFM|FBrf0102137
|Betran et al.
|1998
|-1
REFM|FBrf0036047
|Ruiz and Fontdevila
|1981
|-1
REFM|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
|-1
REFM|FBrf0079895
|Betran et al.
|1995
|-1
REFM|FBrf0098863
|Norry et al.
|1997
|-1
REFM|FBrf0108453
|Rodriguez et al.
|1999
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0067195
|Barker
|1994
|-1
REFM|FBrf0098780
|Fanara et al.
|1997
|-1
REFM|FBrf0179396
|Puig et al.
|2004
|-1
REFM|FBrf0187633
|Casals et al.
|2005
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
|-1
REFM|FBrf0016682
|Carson and Wasserman
|1965
|-1
REFM|FBrf0076525
|Vilardi et al.
|1994
|-1
REFM|FBrf0125477
|Fernandez Iriarte et al.
|1999
|-1
REFM|FBrf0136875
|Dahlgaard et al.
|2001
|-1
REFM|FBrf0132383
|Rodriguez et al.
|2000
|-1
REFM|FBrf0131339
|Laayouni et al.
|2000
|-1
REFM|FBrf0084230
|Norry et al.
|1995
|-1
REFM|FBrf0137257
|Caceres et al.
|2001
|-1
REFM|FBrf0081984
|Fanara et al.
|1995
|-1
REFM|FBrf0078017
|Barbadilla et al.
|1994
|-1
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0036047
|Ruiz and Fontdevila
|1981
MU|natural population
}

REFDSR
{
RDID|FBrf0056348
|Hasson et al.
|1992
PHP|Rearrangements are correlated with a large thorax size.
}

REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0067195
|Barker
|1994
SYN|z<up>3</up>
}

REFDSR
{
RDID|FBrf0076525
|Vilardi et al.
|1994
SYN|2z<up>3</up>
}

REFDSR
{
RDID|FBrf0078017
|Barbadilla et al.
|1994
SYN|2z<up>3</up>
}

REFDSR
{
RDID|FBrf0079895
|Betran et al.
|1995
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0081984
|Fanara et al.
|1995
SYN|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0084230
|Norry et al.
|1995
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0098780
|Fanara et al.
|1997
PHP|The biometrical effect of inversions on body size is due to genetic
|differences between rearrangements and not to the historical relationship
|between the populations studied.
SYN|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0098863
|Norry et al.
|1997
PHP|Genetic variation in correlations among size-related traits of head,
|thorax and wings are examined in D.buzzatii by comparing the pattern
|of the Phenotypic Correlation Matrix between inversion karyotypes of
|the second chromosomes. Results indicate chromosome inversions are
|factors affecting genetic correlations among traits known to be phenotypically
|correlated with adult fitness components.
SYN|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0099859
|Norry et al.
|1997
SYN|jz<up>3</up>
}

REFDSR
{
RDID|FBrf0102137
|Betran et al.
|1998
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0108453
|Rodriguez et al.
|1999
PHP|@Dbuz\In(2)z<up>3</up>@ appears to increase female longevity.
SYN|2JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|2z<up>3</up>
}

REFDSR
{
RDID|FBrf0125477
|Fernandez Iriarte et al.
|1999
SYN|JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0129808
|Fernandez Iriarte and Hasson
|2000
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0131339
|Laayouni et al.
|2000
SYN|z<up>3</up>
}

REFDSR
{
RDID|FBrf0132383
|Rodriguez et al.
|2000
SYN|2JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0136875
|Dahlgaard et al.
|2001
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
SYN|2JZ3
}

REFDSR
{
RDID|FBrf0137257
|Caceres et al.
|2001
SYN|2jz<up>3</up>
}

REFDSR
{
RDID|FBrf0147121
|Fernandez Iriarte et al.
|2002
SYN|2JZ<up>3</up>
}

REFDSR
{
RDID|FBrf0179396
|Puig et al.
|2004
SYN|2z<up>3</up>
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|2z<up>3</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025442	CLA 1 Inversion	GSYM 1 Dbuz\In(3)j<up>2</up>	DT 1 01 Feb 00	RESZ 567	REF 3	
ABSY|Dbuz\In(3)j<up>2</up>
DT|01 Feb 00
ID|FBab0025442
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|3<up>j2</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|3j<up>2</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025443	CLA 1 Inversion	GSYM 1 Dbuz\In(4)S	DT 1 08 Nov 97	RESZ 277	CLOC 1 D1d;F1c	REF 1	
ABSY|Dbuz\In(4)S
DT|08 Nov 97
ID|FBab0025443
REF
{
REFM|FBrf0036047
|Ruiz and Fontdevila
|1981
|-1
}

ACLA|Inversion
BPT|D1d;F1c
MU|natural population
REFDSR
{
RDID|FBrf0036047
|Ruiz and Fontdevila
|1981
BPT|D1d;F1c
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025444	CLA 1 Inversion	GSYM 1 Dbuz\In(4)s	DT 1 27 Nov 05	RESZ 1147	REF 7	
ABSY|Dbuz\In(4)s
DT|27 Nov 05
SYN|4s
|s
|4S
ID|FBab0025444
REF
{
REFM|FBrf0079895
|Betran et al.
|1995
|-1
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0131339
|Laayouni et al.
|2000
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
REFM|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
|-1
REFM|FBrf0187633
|Casals et al.
|2005
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|4s
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0079895
|Betran et al.
|1995
SYN|4s
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|4s
}

REFDSR
{
RDID|FBrf0131339
|Laayouni et al.
|2000
SYN|s
}

REFDSR
{
RDID|FBrf0137244
|Garcia Guerreiro and Fontdevila
|2001
SYN|4S
}

REFDSR
{
RDID|FBrf0187633
|Casals et al.
|2005
SYN|4s
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025445	CLA 1 Inversion	GSYM 1 Dbuz\In(5)c<up>2</up>	DT 1 01 Feb 00	RESZ 567	REF 3	
ABSY|Dbuz\In(5)c<up>2</up>
DT|01 Feb 00
ID|FBab0025445
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
REFM|FBrf0058654
|Ruiz and Wasserman
|1993
|-1
REFM|FBrf0111338
|Caceres et al.
|1999
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0058654
|Ruiz and Wasserman
|1993
SYN|5c<up>2</up>
}

REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

REFDSR
{
RDID|FBrf0111338
|Caceres et al.
|1999
SYN|5c<up>2</up>
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027953	CLA 1 Aberration	GSYM 1 Dbuz\In(5)g	DT 1 16 Jun 98	RESZ 258	REF 1	
ABSY|Dbuz\In(5)g
DT|16 Jun 98
SYN|5g
ID|FBab0027953
REF
{
REFM|FBrf0100627
|Ruiz et al.
|1997
|-1
}

MU|natural population
REFDSR
{
RDID|FBrf0100627
|Ruiz et al.
|1997
MU|natural population
SYN|5g
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027129	CLA 1 Aberration	GSYM 1 Dbuz\T(2;3)Dl<up>2</up>	DT 1 29 Oct 99	RESZ 324	REF 1	
ABSY|Dbuz\T(2;3)Dl<up>2</up>
DT|29 Oct 99
ID|FBab0027129
REF
{
REFM|FBrf0058877
|Schafer et al.
|1993
|-1
}

ASAL|FBal0063515 == Dbuz\Dl<up>2</up>
MU|X ray
AMD|Dbuz\Dl
REFDSR
{
RDID|FBrf0058877
|Schafer et al.
|1993
MU|X ray
AMD|Dbuz\Dl
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027130	CLA 1 Aberration	GSYM 1 Dbuz\T(3;5;2)Dl<up>1</up>	DT 1 29 Oct 99	RESZ 326	REF 1	
ABSY|Dbuz\T(3;5;2)Dl<up>1</up>
DT|29 Oct 99
ID|FBab0027130
REF
{
REFM|FBrf0058877
|Schafer et al.
|1993
|-1
}

ASAL|FBal0038624 == Dbuz\Dl<up>1</up>
MU|X ray
AMD|Dbuz\Dl
REFDSR
{
RDID|FBrf0058877
|Schafer et al.
|1993
MU|X ray
AMD|Dbuz\Dl
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025446	CLA 1 Inversion	GSYM 1 Dcad\In(2L)C'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcad\In(2L)C'
DT|08 Nov 97
ID|FBab0025446
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025447	CLA 1 Inversion	GSYM 1 Dcad\In(2L)D'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcad\In(2L)D'
DT|08 Nov 97
ID|FBab0025447
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025448	CLA 1 Inversion	GSYM 1 Dcad\In(2L)E'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcad\In(2L)E'
DT|08 Nov 97
ID|FBab0025448
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025449	CLA 1 Inversion	GSYM 1 Dcad\In(2L)F'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcad\In(2L)F'
DT|08 Nov 97
ID|FBab0025449
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025450	CLA 1 Inversion	GSYM 1 Dcad\In(2L)G'	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcad\In(2L)G'
DT|08 Nov 97
ID|FBab0025450
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025451	CLA 1 Inversion	GSYM 1 Dcad\In(2L)U	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(2L)U
DT|08 Nov 97
ID|FBab0025451
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025452	CLA 1 Inversion	GSYM 1 Dcad\In(2L)Z	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(2L)Z
DT|08 Nov 97
ID|FBab0025452
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025453	CLA 1 Inversion	GSYM 1 Dcad\In(2R)H	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(2R)H
DT|08 Nov 97
ID|FBab0025453
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025454	CLA 1 Inversion	GSYM 1 Dcad\In(3L)A	DT 1 08 Nov 97	RESZ 326	CLOC 1 68;76	REF 1	
ABSY|Dcad\In(3L)A
DT|08 Nov 97
SYN|IIIL-A
ID|FBab0025454
REF
{
REFM|FBrf0087678
|Rohde and Valente
|1996
|-1
}

BPT|68;76
ACLA|Inversion
MU|natural population
COR|Porto Alegre, Brazil
|Eldorado do Sul, Brazil
REFDSR
{
RDID|FBrf0087678
|Rohde and Valente
|1996
SYN|IIIL-A
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025455	CLA 1 Inversion	GSYM 1 Dcad\In(3L)B	DT 1 08 Nov 97	RESZ 299	CLOC 1 74;76	REF 1	
ABSY|Dcad\In(3L)B
DT|08 Nov 97
SYN|IIIL-B
ID|FBab0025455
REF
{
REFM|FBrf0087678
|Rohde and Valente
|1996
|-1
}

BPT|74;76
ACLA|Inversion
MU|natural population
COR|Porto Alegre, Brazil
REFDSR
{
RDID|FBrf0087678
|Rohde and Valente
|1996
SYN|IIIL-B
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025456	CLA 1 Inversion	GSYM 1 Dcad\In(3L)C	DT 1 08 Nov 97	RESZ 299	CLOC 1 72;73	REF 1	
ABSY|Dcad\In(3L)C
DT|08 Nov 97
SYN|IIIL-C
ID|FBab0025456
REF
{
REFM|FBrf0087678
|Rohde and Valente
|1996
|-1
}

BPT|72;73
ACLA|Inversion
MU|natural population
COR|Porto Alegre, Brazil
REFDSR
{
RDID|FBrf0087678
|Rohde and Valente
|1996
SYN|IIIL-C
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025457	CLA 1 Inversion	GSYM 1 Dcad\In(3L)D	DT 1 08 Nov 97	RESZ 299	CLOC 1 64;70	REF 1	
ABSY|Dcad\In(3L)D
DT|08 Nov 97
SYN|IIIL-D
ID|FBab0025457
REF
{
REFM|FBrf0087678
|Rohde and Valente
|1996
|-1
}

BPT|64;70
ACLA|Inversion
MU|natural population
COR|Porto Alegre, Brazil
REFDSR
{
RDID|FBrf0087678
|Rohde and Valente
|1996
SYN|IIIL-D
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025458	CLA 1 Inversion	GSYM 1 Dcad\In(3L)E	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(3L)E
DT|08 Nov 97
ID|FBab0025458
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025459	CLA 1 Inversion	GSYM 1 Dcad\In(3L)I	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(3L)I
DT|08 Nov 97
ID|FBab0025459
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025460	CLA 1 Inversion	GSYM 1 Dcad\In(3R)H	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(3R)H
DT|08 Nov 97
ID|FBab0025460
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025461	CLA 1 Inversion	GSYM 1 Dcad\In(3R)I	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(3R)I
DT|08 Nov 97
ID|FBab0025461
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025462	CLA 1 Inversion	GSYM 1 Dcad\In(3R)J	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcad\In(3R)J
DT|08 Nov 97
ID|FBab0025462
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025463	CLA 1 Inversion	GSYM 1 Dcai\In(2R)B	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcai\In(2R)B
DT|08 Nov 97
ID|FBab0025463
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025464	CLA 1 Inversion	GSYM 1 Dcai\In(3L)B	DT 1 08 Nov 97	RESZ 284	REF 1	
ABSY|Dcai\In(3L)B
DT|08 Nov 97
ID|FBab0025464
REF
{
REFM|FBrf0012969
|Heed and Krishnamurthy
|1959
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0012969
|Heed and Krishnamurthy
|1959
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025465	CLA 1 Inversion	GSYM 1 Dcan\In(2)r<up>4</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dcan\In(2)r<up>4</up>
DT|08 Nov 97
ID|FBab0025465
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025466	CLA 1 Inversion	GSYM 1 Dcar\In(2)L'	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcar\In(2)L'
DT|08 Nov 97
ID|FBab0025466
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025467	CLA 1 Inversion	GSYM 1 Dcar\In(2)N'	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcar\In(2)N'
DT|08 Nov 97
ID|FBab0025467
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025468	CLA 1 Inversion	GSYM 1 Dcar\In(2)O'	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcar\In(2)O'
DT|08 Nov 97
ID|FBab0025468
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025469	CLA 1 Inversion	GSYM 1 Dcar\In(2)P'	DT 1 08 Nov 97	RESZ 276	REF 1	
ABSY|Dcar\In(2)P'
DT|08 Nov 97
ID|FBab0025469
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025470	CLA 1 Inversion	GSYM 1 Dcar\In(5)P	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dcar\In(5)P
DT|08 Nov 97
ID|FBab0025470
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025471	CLA 1 Inversion	GSYM 1 Dcar\In(5)Q	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dcar\In(5)Q
DT|08 Nov 97
ID|FBab0025471
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025472	CLA 1 Inversion	GSYM 1 Dcar\In(5)R	DT 1 08 Nov 97	RESZ 275	REF 1	
ABSY|Dcar\In(5)R
DT|08 Nov 97
ID|FBab0025472
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025473	CLA 1 Inversion	GSYM 1 Dcar\In(X)B''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)B''
DT|08 Nov 97
ID|FBab0025473
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025474	CLA 1 Inversion	GSYM 1 Dcar\In(X)C''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)C''
DT|08 Nov 97
ID|FBab0025474
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025475	CLA 1 Inversion	GSYM 1 Dcar\In(X)D''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)D''
DT|08 Nov 97
ID|FBab0025475
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025476	CLA 1 Inversion	GSYM 1 Dcar\In(X)I''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)I''
DT|08 Nov 97
ID|FBab0025476
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025477	CLA 1 Inversion	GSYM 1 Dcar\In(X)J''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)J''
DT|08 Nov 97
ID|FBab0025477
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025478	CLA 1 Inversion	GSYM 1 Dcar\In(X)N''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)N''
DT|08 Nov 97
ID|FBab0025478
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025479	CLA 1 Inversion	GSYM 1 Dcar\In(X)O''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)O''
DT|08 Nov 97
ID|FBab0025479
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025480	CLA 1 Inversion	GSYM 1 Dcar\In(X)P''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)P''
DT|08 Nov 97
ID|FBab0025480
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025481	CLA 1 Inversion	GSYM 1 Dcar\In(X)S''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)S''
DT|08 Nov 97
ID|FBab0025481
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025482	CLA 1 Inversion	GSYM 1 Dcar\In(X)T''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)T''
DT|08 Nov 97
ID|FBab0025482
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025483	CLA 1 Inversion	GSYM 1 Dcar\In(X)U''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)U''
DT|08 Nov 97
ID|FBab0025483
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025484	CLA 1 Inversion	GSYM 1 Dcar\In(X)V''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)V''
DT|08 Nov 97
ID|FBab0025484
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025485	CLA 1 Inversion	GSYM 1 Dcar\In(X)W''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)W''
DT|08 Nov 97
ID|FBab0025485
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025486	CLA 1 Inversion	GSYM 1 Dcar\In(X)X''	DT 1 08 Nov 97	RESZ 277	REF 1	
ABSY|Dcar\In(X)X''
DT|08 Nov 97
ID|FBab0025486
REF
{
REFM|FBrf0023258
|Heed and Russell
|1971
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0023258
|Heed and Russell
|1971
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025487	CLA 1 Inversion	GSYM 1 Dcit\In(4)j<up>2</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Dcit\In(4)j<up>2</up>
DT|11 Feb 97
ID|FBab0025487
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025488	CLA 1 Inversion	GSYM 1 Dcnp\In(5)n	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Dcnp\In(5)n
DT|11 Feb 97
ID|FBab0025488
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025489	CLA 1 Inversion	GSYM 1 Dcru\In(3)a	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Dcru\In(3)a
DT|11 Feb 97
ID|FBab0025489
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025490	CLA 1 Inversion	GSYM 1 Dcru\In(X)b	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Dcru\In(X)b
DT|11 Feb 97
ID|FBab0025490
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025491	CLA 1 Inversion	GSYM 1 Ddes\In(2)g<up>4</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Ddes\In(2)g<up>4</up>
DT|08 Nov 97
ID|FBab0025491
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025492	CLA 1 Inversion	GSYM 1 Ddes\In(3)r	DT 1 08 Nov 97	RESZ 255	REF 1	
ABSY|Ddes\In(3)r
DT|08 Nov 97
ID|FBab0025492
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025493	CLA 1 Inversion	GSYM 1 Ddic\In(5)p	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Ddic\In(5)p
DT|11 Feb 97
ID|FBab0025493
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025494	CLA 1 Inversion	GSYM 1 Ddis\In(2)s	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Ddis\In(2)s
DT|11 Feb 97
ID|FBab0025494
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025495	CLA 1 Inversion	GSYM 1 Ddis\In(4)g<up>2</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Ddis\In(4)g<up>2</up>
DT|11 Feb 97
ID|FBab0025495
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025496	CLA 1 Inversion	GSYM 1 Ddis\In(4)h<up>2</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Ddis\In(4)h<up>2</up>
DT|11 Feb 97
ID|FBab0025496
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025497	CLA 1 Inversion	GSYM 1 Ddis\In(4)i<up>2</up>	DT 1 11 Feb 97	RESZ 173	REF 1	
ABSY|Ddis\In(4)i<up>2</up>
DT|11 Feb 97
ID|FBab0025497
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025498	CLA 1 Inversion	GSYM 1 Ddis\In(4)k	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Ddis\In(4)k
DT|11 Feb 97
ID|FBab0025498
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025499	CLA 1 Inversion	GSYM 1 Ddis\In(4)v	DT 1 11 Feb 97	RESZ 163	REF 1	
ABSY|Ddis\In(4)v
DT|11 Feb 97
ID|FBab0025499
REF
{
REFM|FBrf0063360
|Carson
|1992
|-1
}

ACLA|Inversion
MU|natural population
}
# EOR
ABSR
{
RETE|ID 1 FBab0025500	CLA 1 Inversion	GSYM 1 Dell\In(2)d<up>3</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dell\In(2)d<up>3</up>
DT|08 Nov 97
ID|FBab0025500
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025501	CLA 1 Inversion	GSYM 1 Dell\In(2)k<up>3</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Dell\In(2)k<up>3</up>
DT|08 Nov 97
ID|FBab0025501
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025502	CLA 1 Inversion	GSYM 1 Deoh\In(2)g<up>2</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Deoh\In(2)g<up>2</up>
DT|08 Nov 97
ID|FBab0025502
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0025503	CLA 1 Inversion	GSYM 1 Deoh\In(2)h<up>3</up>	DT 1 08 Nov 97	RESZ 265	REF 1	
ABSY|Deoh\In(2)h<up>3</up>
DT|08 Nov 97
ID|FBab0025503
REF
{
REFM|FBrf0063954
|Wasserman
|1992
|-1
}

ACLA|Inversion
MU|natural population
REFDSR
{
RDID|FBrf0063954
|Wasserman
|1992
MU|natural population
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027553	CLA 1 Aberration	GSYM 1 Dezo\In(1)A	DT 1 10 Feb 98	RESZ 364	REF 1	
ABSY|Dezo\In(1)A
DT|10 Feb 98
SYN|XA
ID|FBab0027553
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
SYN|XA
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027554	CLA 1 Aberration	GSYM 1 Dezo\In(2L)U	DT 1 10 Feb 98	RESZ 367	REF 1	
ABSY|Dezo\In(2L)U
DT|10 Feb 98
SYN|2LU
ID|FBab0027554
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
SYN|2LU
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027556	CLA 1 Aberration	GSYM 1 Dezo\In(2R)f	DT 1 10 Feb 98	RESZ 379	REF 1	
ABSY|Dezo\In(2R)f
DT|10 Feb 98
SYN|2Rf
ID|FBab0027556
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Found in a sample from Primorsky Area population
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Found in a sample from Primorsky Area population
SYN|2Rf
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027555	CLA 1 Aberration	GSYM 1 Dezo\In(2R)S	DT 1 10 Feb 98	RESZ 367	REF 1	
ABSY|Dezo\In(2R)S
DT|10 Feb 98
SYN|2RS
ID|FBab0027555
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Found in Kamchatka individuals (Maiskoye).
SYN|2RS
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027557	CLA 1 Aberration	GSYM 1 Dezo\In(5)Q	DT 1 10 Feb 98	RESZ 450	REF 1	
ABSY|Dezo\In(5)Q
DT|10 Feb 98
SYN|5Q
ID|FBab0027557
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Observed in a population of the Primorsky Area and in individuals from Japan strains.
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Observed in a population of the Primorsky Area and in individuals from Japan strains.
SYN|5Q
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027558	CLA 1 Aberration	GSYM 1 Dezo\In(5)R	DT 1 10 Feb 98	RESZ 336	REF 1	
ABSY|Dezo\In(5)R
DT|10 Feb 98
SYN|2R
ID|FBab0027558
REF
{
REFM|FBrf0054214
|Poluektova et al.
|1991
|-1
}

MU|natural population
COR|Observed in Finland strains.
REFDSR
{
RDID|FBrf0054214
|Poluektova et al.
|1991
MU|natural population
COR|Observed in Finland strains.
SYN|2R
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0027357	CLA 1 Deficiency	GSYM 1 Df(1)&Dgr;59	DT 1 27 Nov 05	RESZ 1392	CLOC 1 [<10D2];[>10D1]	REF 2	
ABSY|Df(1)&Dgr;59
DT|27 Nov 05
SYN|&Dgr;59
|Df(1)59
ID|FBab0027357
REF
{
REFM|FBrf0125454
|Sun et al.
|2000
|-1
REFM|FBrf0098189
|Bahri et al.
|1997
|-1
}

BPT|[<10D2];[>10D1]
CCM|All limits from inclusion of bif (FBrf0098189)
FGD|bk1 << bif << bk2
ACLA|Deficiency
MU|&Dgr;2-3
PRG|FBti0009128 == P{wA<up>R</up>}PhK&ggr;<up>P842</up>
AMD|bif
OAB|The rough eye phenotype of @Df(1)&Dgr;59@ hemizygotes is dominantly enhanced
|by @Df(3R)P14@ and @Df(2L)Prl@.
|Dominantly enhances the rough eye phenotype of @Df(1)&Dgr;59@ hemizygotes.
OTH|Deleted segment: 10D2--10D1
REFDSR
{
RDID|FBrf0098189
|Bahri et al.
|1997
BPT|[];[]
ACLA|Deficiency
MU|&Dgr;2-3
PRG|FBti0009128 == P{wA<up>R</up>}PhK&ggr;<up>P842</up>
AMD|bif
OAB|The rough eye phenotype of @Df(1)&Dgr;59@ hemizygotes is dominantly enhanced
|by @Df(3R)P14@ and @Df(2L)Prl@.
|Dominantly enhances the rough eye phenotype of @Df(1)&Dgr;59@ hemizygotes.
PHP|Homozygotes are viable and have a weak rough eye phenotype. Adjacent
|ommatidia are often fused, and bristles are short, missing or duplicated.
|Most rhabdomeres have abnormal morphology, becoming enlarged, elongated
|or split.
SYN|&Dgr;59
}

REFDSR
{
RDID|FBrf0125454
|Sun et al.
|2000
PHP|Homozygous viable and fertile.
SYN|Df(1)59
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024304	CLA 1 Aberration	GSYM 1 Df(1)&Dgr;85	DT 1 20 Apr 05	RESZ 349	REF 1	
ABSY|Df(1)&Dgr;85
DT|20 Apr 05
ID|FBab0024304
REF
{
REFM|FBrf0081621
|Chouinard et al.
|1995
|-1
}

CCM|Class relative to wildtype: Deficiency
AMDD|Hk
REFDSR
{
RDID|FBrf0081621
|Chouinard et al.
|1995
AMDD|Hk
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000170	CLA 1 Deficiency	NAM 1 Deficiency (1) gamma	GSYM 1 Df(1)&ggr;2	DT 1 27 Nov 05	RESZ 605	CLOC 1 7D14;8A3	REF 4	
ABSY|Df(1)&ggr;2
DT|27 Nov 05
NAM|Deficiency (1) gamma
ID|FBab0000170
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0050367
|Homyk and McIvor
|1989
|-1
REFM|FBrf0082629
|Spradling et al.
|1994
|-1
REFM|FBrf0050364
|Homyk and Pye
|1989
|-1
}

BPT|7D14;8A3
ACLA|Deficiency
CCM|All limits from polytene analysis (FBrf0050364)
FGD|sesD << bk1 << bk2
AMDD|sesD
OTH|Deleted segment: 7D14--8A3
REFDSR
{
RDID|FBrf0050364
|Homyk and Pye
|1989
AMDD|sesD
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024305	CLA 1 Deficiency	GSYM 1 Df(1)&ggr;308	DT 1 27 Nov 05	RESZ 954	CLOC 1 1Lt--p1:bk1;1Lt--1Rt	REF 1	
ABSY|Df(1)&ggr;308
DT|27 Nov 05
SYN|T(Dp;X)&ggr;308
ID|FBab0024305
REF
{
REFM|FBrf0084112
|Le et al.
|1995
|-1
}

ACLA|Deficiency
FGD|bk1 << p1:bk1
BPT|1Lt--p1:bk1;1Lt--1Rt
NCO|1Lt - 1Lt | 1Rt - 1Rt
MU|&ggr; ray
PRG|Dp1187-8-23
CCM|Translocation breakpoint on a normal X chromosome and between euchromatic
|positions -80 and -100 of the @Dp(1;f)1187@ derivative @Dp1187-8-23@,
|where position 0 is the @In(1)sc<up>8</up>@ inversion breakpoint.
PED|position-effect variegation for: y
OTH|Deleted segment: 1Lt--1Rt
REFDSR
{
RDID|FBrf0084112
|Le et al.
|1995
BPT|1Lt--p1:bk1;1Lt--1Rt
NCO|1Lt - 1Lt | 1Rt - 1Rt
MU|&ggr; ray
PRG|Dp1187-8-23
CCM|Translocation breakpoint on a normal X chromosome and between euchromatic
|positions -80 and -100 of the @Dp(1;f)1187@ derivative @Dp1187-8-23@,
|where position 0 is the @In(1)sc<up>8</up>@ inversion breakpoint.
PED|position-effect variegation for: y
SYN|T(Dp;X)&ggr;308
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0024306	CLA 1 Deficiency	GSYM 1 Df(1)&ggr;308-y<up>+</up>	DT 1 27 Nov 05	RESZ 957	CLOC 1 1Lt--1Rt;1Lt--p1:bk1	REF 1	
ABSY|Df(1)&ggr;308-y<up>+</up>
DT|27 Nov 05
SYN|T(X;Dp)&ggr;308
ID|FBab0024306
REF
{
REFM|FBrf0084112
|Le et al.
|1995
|-1
}

ACLA|Deficiency
FGD|bk2 << p1:bk1
BPT|1Lt--1Rt;1Lt--p1:bk1
NCO|1Lt - 1Lt | p1:bk1 - 1Rt
MU|&ggr; ray
PRG|Dp1187-8-23
CCM|Translocation breakpoint on a normal X chromosome and between euchromatic
|positions -80 and -100 of the @Dp(1;f)1187@ derivative @Dp1187-8-23@,
|where position 0 is the @In(1)sc<up>8</up>@ inversion breakpoint.
OTH|Deleted segment: 1Lt--p1:bk1
REFDSR
{
RDID|FBrf0084112
|Le et al.
|1995
BPT|1Lt--1Rt;1Lt--p1:bk1
NCO|1Lt - 1Lt | p1:bk1 - 1Rt
MU|&ggr; ray
PRG|Dp1187-8-23
CCM|Translocation breakpoint on a normal X chromosome and between euchromatic
|positions -80 and -100 of the @Dp(1;f)1187@ derivative @Dp1187-8-23@,
|where position 0 is the @In(1)sc<up>8</up>@ inversion breakpoint.
PHP|@y@ PEV phenotype, suppressible by extra Y chromosome.
SYN|T(X;Dp)&ggr;308
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000171	CLA 1 Deficiency	GSYM 1 Df(1)&ggr;a3	DT 1 27 Nov 05	RESZ 319	CLOC 1 7D4;8A3	REF 2	
ABSY|Df(1)&ggr;a3
DT|27 Nov 05
SYN|Df(1)&ggr;-a3
ID|FBab0000171
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0082629
|Spradling et al.
|1994
|-1
}

BPT|7D4;8A3
ACLA|Deficiency
CCM|All limits from polytene analysis (citation unavailable)
OTH|Deleted segment: 7D4--8A3
}
# EOR
ABSR
{
RETE|ID 1 FBab0000174	CLA 1 Deficiency	GSYM 1 Df(1)10-70d	DT 1 27 Nov 05	RESZ 2585	CLOC 1 8D3;8D9	SK 1	REF 11	
ABSY|Df(1)10-70d
DT|27 Nov 05
SYN|10-70d
|lz<up>10-70d</up>
|Df(1)lz<up>10-70d</up>
|Df(1)lz10-5
|Df(1)10-5
ID|FBab0000174
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0024272
|Green and Lefevre
|1972
|-1
REFM|FBrf0130005
|Page et al.
|2000
|-1
REFM|FBrf0159888
|Santamaria
|2003.7.4
|-1
REFM|FBrf0103357
|Saget et al.
|1998
|-1
REFM|FBrf0090589
|Gupta and Rodrigues
|1995
|-1
REFM|FBrf0105234
|Gupta et al.
|1998
|-1
REFM|FBrf0074350
|Sanchez et al.
|1994
|-1
REFM|FBrf0086384
|Docquier et al.
|1996
|-1
REFM|FBrf0080370
|Santamaria and Randsholt
|1995
|-1
REFM|FBrf0107923
|Page
|1999.3.11
|-1
}

BPT|8D3;8D9
ACLA|Deficiency
MU|spontaneous \mu
CCM|Limits of break 1 from polytene analysis (FBrf0024272)
|Left limit of break 2 from polytene analysis (FBrf0080370)
|Right limit of break 2 from polytene analysis (FBrf0024272)
FGD|bk1 << rtg << atx << bk2
OTH|Deleted segment: 8D3--8D9
REFDSR
{
RDID|FBrf0024272
|Green and Lefevre
|1972
BPT|8D3;8D8--9
ACLA|Deficiency
MU|spontaneous \mu1
SYN|10-70d
}

REFDSR
{
RDID|FBrf0074350
|Sanchez et al.
|1994
SYN|lz<up>10-70d</up>
}

REFDSR
{
RDID|FBrf0080370
|Santamaria and Randsholt
|1995
BPT|8D2+;8D9
ACLA|Deficiency
AMD|lz
|mxc
|amx
|atx
|Dsor1
|rtg
|elg
OTH|In a screen to isolate recessive lethal mutations uncovered by @Df(1)10-70d@,
|three dominant female sterile mutations were isolated and subsequently
|lost.
SYN|Df(1)lz<up>10-70d</up>
}

REFDSR
{
RDID|FBrf0086384
|Docquier et al.
|1996
BPT|8D3;8D8--9
ACLA|Deficiency
AMD|mxc
SYN|Df(1)lz<up>10-70d</up>
}

REFDSR
{
RDID|FBrf0090589
|Gupta and Rodrigues
|1995
SYN|Df(1)lz10-5
}

REFDSR
{
RDID|FBrf0103357
|Saget et al.
|1998
SYN|Df(1)lz<up>10-70d</up>
}

REFDSR
{
RDID|FBrf0107923
|Page
|1999.3.11
AMDD|mei-P26
}

REFDSR
{
RDID|FBrf0130005
|Page et al.
|2000
AMDD|mei-P26
SYN|Df(1)lz<up>10-70d</up>
}

REFDSR
{
RDID|FBrf0159888
|Santamaria
|2003.7.4
AMD|l(1)8Da
}

SK|FBst0007153
|Df(1)10-70d, cho[1] sn[3]/FM6
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0029164	CLA 1 Aberration	GSYM 1 Df(1)101	DT 1 20 Apr 05	RESZ 458	REF 1	
ABSY|Df(1)101
DT|20 Apr 05
ID|FBab0029164
REF
{
REFM|FBrf0125454
|Sun et al.
|2000
|-1
}

ASAL|FBal0104059 == Ptp10D<up>101</up>
CCM|Class relative to wildtype: Deficiency
MU|P-element activity
PRG|FBti0009128 == P{wA<up>R</up>}PhK&ggr;<up>P842</up>
REFDSR
{
RDID|FBrf0125454
|Sun et al.
|2000
MU|P-element activity
PRG|FBti0009128 == P{wA<up>R</up>}PhK&ggr;<up>P842</up>
PHP|Homozygous viable and fertile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000175	CLA 1 Deficiency	GSYM 1 Df(1)10RA	DT 1 27 Nov 05	RESZ 478	CLOC 1 6F1--5;7A	REF 2	
ABSY|Df(1)10RA
DT|27 Nov 05
ID|FBab0000175
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0034950
|Nicklas and Cline
|1980
|-1
}

BPT|6F1--5;7A
ACLA|Deficiency
DIS|Cline.
CCM|Left limit of break 1 from non-inclusion of cm (citation unavailable)
|Right limit of break 1 from inclusion of Sxl (citation unavailable)
|Limits of break 2 from polytene analysis (citation unavailable)
FGD|cm << bk1 << Sxl << bk2 << ct
OTH|Deleted segment: 6F1--7A
}
# EOR
ABSR
{
RETE|ID 1 FBab0000177	CLA 1 Deficiency	GSYM 1 Df(1)12-70b	DT 1 27 Nov 05	RESZ 460	CLOC 1 h26;h33	REF 2	
ABSY|Df(1)12-70b
DT|27 Nov 05
SYN|12-70b
ID|FBab0000177
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0024272
|Green and Lefevre
|1972
|-1
}

BPT|h26;h33
ACLA|Deficiency
MU|spontaneous \mu
CCM|All limits from polytene analysis (citation unavailable)
OTH|Deleted segment: h26--h33
REFDSR
{
RDID|FBrf0024272
|Green and Lefevre
|1972
BPT|[];[]
ACLA|Deficiency (cytologically invisible)
MU|spontaneous \mu1
SYN|12-70b
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028066	CLA 1 Aberration	GSYM 1 Df(1)120	DT 1 20 Apr 05	RESZ 1198	REF 1	
ABSY|Df(1)120
DT|20 Apr 05
ID|FBab0028066
REF
{
REFM|FBrf0039977
|Paradi et al.
|1983
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|methyl methanesulfonate
AMD|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
|wap
|uncl
|stnA
REFDSR
{
RDID|FBrf0039977
|Paradi et al.
|1983
MU|methyl methanesulfonate
AMD|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
|wap
|uncl
|stnA
OTH|Chromosome carries a double mutant.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000178	CLA 1 Deficiency	GSYM 1 Df(1)1237	DT 1 27 Nov 05	RESZ 348	CLOC 1 [<4E2];[>4E1]	REF 2	
ABSY|Df(1)1237
DT|27 Nov 05
ID|FBab0000178
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0038997
|Lawrence et al.
|1983
|-1
}

BPT|[<4E2];[>4E1]
ACLA|Deficiency
DIS|Gans.
CCM|All limits from inclusion of ovo (citation unavailable)
FGD|bk1 << ovo << bk2
OTH|Deleted segment: 4E2--4E1
PHP|Dominant female sterile (agametic)
}
# EOR
ABSR
{
RETE|ID 1 FBab0028067	CLA 1 Aberration	GSYM 1 Df(1)127	DT 1 20 Apr 05	RESZ 1117	REF 1	
ABSY|Df(1)127
DT|20 Apr 05
ID|FBab0028067
REF
{
REFM|FBrf0039977
|Paradi et al.
|1983
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|methyl methanesulfonate
AMD|wap
|uncl
|stnA
|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
REFDSR
{
RDID|FBrf0039977
|Paradi et al.
|1983
MU|methyl methanesulfonate
AMD|wap
|uncl
|stnA
|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000179	CLA 1 Deficiency	GSYM 1 Df(1)13-70b	DT 1 27 Nov 05	RESZ 495	CLOC 1 1A7;1B4	REF 3	
ABSY|Df(1)13-70b
DT|27 Nov 05
SYN|13-70b
ID|FBab0000179
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0024272
|Green and Lefevre
|1972
|-1
REFM|FBrf0055071
|Merriam et al.
|1991
|-1
}

BPT|1A7;1B4
ACLA|Deficiency
MU|spontaneous \mu
CCM|All limits from polytene analysis (FBrf0024272)
OTH|Deleted segment: 1A7--1B4
REFDSR
{
RDID|FBrf0024272
|Green and Lefevre
|1972
BPT|1A7;1B4
ACLA|Deficiency
MU|spontaneous \mu1
SYN|13-70b
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028068	CLA 1 Aberration	GSYM 1 Df(1)136	DT 1 20 Apr 05	RESZ 1184	REF 1	
ABSY|Df(1)136
DT|20 Apr 05
ID|FBab0028068
REF
{
REFM|FBrf0039977
|Paradi et al.
|1983
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|methyl methanesulfonate
AMD|stnA
|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
|wap
|uncl
REFDSR
{
RDID|FBrf0039977
|Paradi et al.
|1983
MU|methyl methanesulfonate
AMD|stnA
|l(1)20Ca
|sph
|su(f)
AMDD|sw
|l(1)19Ca
|run
|shakB
|fliI
|mst
|eo
|wap
|uncl
OTH|Chromosome carries a double mutant.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028463	CLA 1 Deficiency	GSYM 1 Df(1)13AC	DT 1 27 Nov 05	RESZ 268	CLOC 1 [];13C2--3	REF 1	
ABSY|Df(1)13AC
DT|27 Nov 05
ID|FBab0028463
REF
{
REFM|FBrf0107658
|Clyne et al.
|1999
|-1
}

BPT|[];13C2--3
ACLA|Deficiency
OTH|Deleted segment: ?--13C3
REFDSR
{
RDID|FBrf0107658
|Clyne et al.
|1999
BPT|[];13C2--3
ACLA|Deficiency
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000180	CLA 1 Deficiency	GSYM 1 Df(1)13C3	DT 1 27 Nov 05	RESZ 1191	CLOC 1 20A3;20E1--h26	REF 2	
ABSY|Df(1)13C3
DT|27 Nov 05
SYN|13C3
ID|FBab0000180
REF
{
REFM|FBrf0024685
|Schalet and Lefevre
|1973
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
}

BPT|20A3;20E1--h26
ACLA|Deficiency
MU|X ray
CCM|Limits of break 1 from polytene analysis (FBrf0024685)
|Left limit of break 2 from inclusion of su(f) (FBrf0024685)
|Right limit of break 2 from non-inclusion of bb (FBrf0024685)
FGD|eo << bk1 << wap << su(f) << bk2 << bb
AMD|wap
|intro
|su(f)
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
AMDD|eo
|bb
OTH|Deleted segment: 20A3--h26
REFDSR
{
RDID|FBrf0024685
|Schalet and Lefevre
|1973
BPT|20A3;20E--F
ACLA|Deficiency
MU|X ray
AMD|wap
|intro
|su(f)
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
AMDD|eo
|bb
SYN|13C3
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037688	CLA 1 Aberration	GSYM 1 Df(1)14-11	DT 1 20 Apr 05	RESZ 2281	SK 1	REF 1	
ABSY|Df(1)14-11
DT|20 Apr 05
ID|FBab0037688
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|neutrons
AMD|wap
|intro
|uncl
|l(1)B-56
|l(1)19Fb
|fliI
|mst
|l(1)19Fe
|l(1)E-81
|run
|Hlc
|eo
|unc
|uncl
AMDD|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|ot
|bb
|mell
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)B111@, @Df(1)B12@, @Df(1)16-3-35@
|and @Df(1)T2-14A@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)T2-14A@.
|Viable with @Df(1)17-25@, @Df(1)18-61@, @Df(1)mal10@, @Df(1)fog-1@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
MU|neutrons
AMD|wap
|intro
|uncl
|l(1)B-56
|l(1)19Fb
|fliI
|mst
|l(1)19Fe
|l(1)E-81
|run
|Hlc
|eo
|unc
|uncl
AMDD|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|ot
|bb
|mell
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)B111@, @Df(1)B12@, @Df(1)16-3-35@
|and @Df(1)T2-14A@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)T2-14A@.
|Viable with @Df(1)17-25@, @Df(1)18-61@, @Df(1)mal10@, @Df(1)fog-1@.
}

SK|FBst0008122
|Df(1)14-11/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000181	CLA 1 Deficiency	GSYM 1 Df(1)14zA	DT 1 27 Nov 05	RESZ 798	CLOC 1 [15A1--15F9];[15F1--17C5]	REF 2	
ABSY|Df(1)14zA
DT|27 Nov 05
SYN|Del. 14z
ID|FBab0000181
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0003143
|Mackensen
|1935
|-1
}

BPT|[15A1--15F9];[15F1--17C5]
ACLA|Deficiency
DIS|Mackensen.
MU|X ray
CCM|Left limit of break 1 from non-inclusion of r (FBrf0003143)
|Right limit of break 1 from inclusion of f (FBrf0003143)
|Left limit of break 2 from inclusion of f (FBrf0003143)
|Right limit of break 2 from non-inclusion of fu (FBrf0003143)
FGD|r << bk1 << f << bk2 << fu
AMD|f
AMDD|r
|fu
OTH|Deleted segment: 15A1--17C5
REFDSR
{
RDID|FBrf0003143
|Mackensen
|1935
AMD|f
AMDD|r
|fu
SYN|Del. 14z
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037689	CLA 1 Deficiency	GSYM 1 Df(1)15-13	DT 1 29 Feb 04	RESZ 1393	CLOC 1 [];[]	SK 1	REF 1	
ABSY|Df(1)15-13
DT|29 Feb 04
ID|FBab0037689
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|bb
|wap
AMDD|eo
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@ and
|@Df(1)17-322@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|bb
|wap
AMDD|eo
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@ and
|@Df(1)17-322@.
}

SK|FBst0007429
|Df(1)15-13/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0037690	CLA 1 Deficiency	GSYM 1 Df(1)15-17	DT 1 29 Feb 04	RESZ 371	CLOC 1 [];[]	REF 1	
ABSY|Df(1)15-17
DT|29 Feb 04
ID|FBab0037690
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-20@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-20@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0028069	CLA 1 Aberration	GSYM 1 Df(1)156	DT 1 20 Apr 05	RESZ 1198	REF 1	
ABSY|Df(1)156
DT|20 Apr 05
ID|FBab0028069
REF
{
REFM|FBrf0039977
|Paradi et al.
|1983
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|methyl methanesulfonate
AMD|fliI
|mst
|eo
AMDD|sw
|l(1)19Ca
|run
|shakB
|wap
|uncl
|stnA
|l(1)20Ca
|sph
|su(f)
REFDSR
{
RDID|FBrf0039977
|Paradi et al.
|1983
MU|methyl methanesulfonate
AMD|fliI
|mst
|eo
AMDD|sw
|l(1)19Ca
|run
|shakB
|wap
|uncl
|stnA
|l(1)20Ca
|sph
|su(f)
OTH|Chromosome carries a double mutant.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037691	CLA 1 Deficiency	GSYM 1 Df(1)16-1-79	DT 1 29 Feb 04	RESZ 1284	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-1-79
DT|29 Feb 04
ID|FBab0037691
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|wap
|uncl
|intro
|bb
OAB|Lethal with @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-466@,
|@Df(1)18-76@ (shows visible phenotype), @Df(1)fog-1@.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|wap
|uncl
|intro
|bb
OAB|Lethal with @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-466@,
|@Df(1)18-76@ (shows visible phenotype), @Df(1)fog-1@.
PHP|Male sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037692	CLA 1 Deficiency	GSYM 1 Df(1)16-1-80	DT 1 22 Aug 04	RESZ 1576	CLOC 1 [];[]	SK 1	REF 2	
ABSY|Df(1)16-1-80
DT|22 Aug 04
ID|FBab0037692
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|wap
|uncl
AMDD|bb
|eo
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|fog
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|wap
|uncl
AMDD|bb
|eo
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|fog
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)B111@ and @Df(1)17-196@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)17-196@.
|Viable with @Df(1)B12@, @Df(1)B57@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)fog-1@
|and @Df(1)n23@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)17-196@.
}

REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
MU|neutrons
OAB|Viable with @Df(1)17-19@, @Df(1)17-401@ and @Df(1)17-454@.
}

SK|FBst0007427
|Df(1)16-1-80/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0037693	CLA 1 Deficiency	GSYM 1 Df(1)16-1-85	DT 1 29 Feb 04	RESZ 413	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-1-85
DT|29 Feb 04
ID|FBab0037693
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMDD|intro
|sph
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMDD|intro
|sph
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037694	CLA 1 Deficiency	GSYM 1 Df(1)16-1-88	DT 1 29 Feb 04	RESZ 2435	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-1-88
DT|29 Feb 04
ID|FBab0037694
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|wap
|intro
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)19Ec
|l(1)E-81
|bb
AMDD|run
|ot
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)A118@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@ and @Df(1)mal10@.
|@Df(1)16-1-88@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|wap
|intro
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)19Ec
|l(1)E-81
|bb
AMDD|run
|ot
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)A118@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@ and @Df(1)mal10@.
|@Df(1)16-1-88@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000182	CLA 1 Deficiency	GSYM 1 Df(1)16-129	DT 1 27 Nov 05	RESZ 9320	CLOC 1 19F1;19F3	REF 22	
ABSY|Df(1)16-129
DT|27 Nov 05
SYN|16-129
|Df(1)16.129
ID|FBab0000182
REF
{
REFM|FBrf0046783
|Miklos et al.
|1987
|-1
REFM|FBrf0101952
|Maleszka et al.
|1998
|-1
REFM|FBrf0046817
|Yamamoto et al.
|1987
|-1
REFM|FBrf0064390
|Campbell et al.
|1993
|-1
REFM|FBrf0083951
|de Couet et al.
|1995
|-1
REFM|FBrf0046799
|de Couet et al.
|1987
|-1
REFM|FBrf0074350
|Sanchez et al.
|1994
|-1
REFM|FBrf0049891
|Perrimon et al.
|1989
|-1
REFM|FBrf0085507
|Maleszka et al.
|1996
|-1
REFM|FBrf0055616
|Russell et al.
|1992
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0040519
|Miklos et al.
|1984
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0080334
|Prud'homme et al.
|1995
|-1
REFM|FBrf0043301
|Eeken et al.
|1985
|-1
REFM|FBrf0137058
|Hsu et al.
|2001
|-1
REFM|FBrf0052388
|Miklos and de Couet
|1990
|-1
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0059248
|Hayward et al.
|1993
|-1
REFM|FBrf0055004
|Delaney et al.
|1991
|-1
REFM|FBrf0024685
|Schalet and Lefevre
|1973
|-1
}

BPT|19F1;19F3
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Left limit of break 1 from polytene analysis (citation unavailable)
|Right limit of break 1 from polytene analysis (FBrf0055616)
|Left limit of break 2 from inclusion of dod (FBrf0085507)
|Right limit of break 2 from polytene analysis (citation unavailable)
FGD|unc << bk1 << lfl << pen << bk2 << sol
MD|Breakpoint(s) molecularly mapped
OTH|Deleted segment: 19F1--19F3
REFDSR
{
RDID|FBrf0024685
|Schalet and Lefevre
|1973
MU|neutrons
AMD|lfl
|l(1)19Fb
|fliI
AMDD|unc
|l(1)19Fe
SYN|16-129
}

REFDSR
{
RDID|FBrf0040519
|Miklos et al.
|1984
AMD|lfl
AMDD|run
|lf
|vao
|unc
|eo
SYN|Df(1)16.129
}

REFDSR
{
RDID|FBrf0043301
|Eeken et al.
|1985
AMD|fliI
AMDD|sw
|l(1)19Ed
|l(1)19Fe
|Hlc
|eo
|wap
|soz
}

REFDSR
{
RDID|FBrf0046783
|Miklos et al.
|1987
AMDD|slgA
|sol
AMD|lfl
|l(1)19Fb
|fliI
AMDD|mal
|mell
|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|unc
|Hlc
|mst
|eo
|wap
|intro
|uncl
|fog
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
}

REFDSR
{
RDID|FBrf0046817
|Yamamoto et al.
|1987
AMDD|slgA
}

REFDSR
{
RDID|FBrf0049891
|Perrimon et al.
|1989
AMD|lfl
|l(1)19Fb
|fliI
AMDD|mal
|mell
|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|unc
|sol
|slgA
|Hlc
|mst
|tuh1
|eo
|wap
|intro
|uncl
|fog
|soz
|stnA
|stnB
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
}

REFDSR
{
RDID|FBrf0052388
|Miklos and de Couet
|1990
AMD|lfl
|l(1)19Fb
|fliI
AMDD|mal
|mell
|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|unc
|sol
|slgA
|Hlc
|mst
|tuh1
|eo
|wap
|intro
|uncl
|fog
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|soz
OAB|Lethal in combination with @Df(1)GA104@, @Df(1)17-257@, @Df(1)2/19B@
|or @Df(1)GE263@.
}

REFDSR
{
RDID|FBrf0055004
|Delaney et al.
|1991
AMDD|sol
}

REFDSR
{
RDID|FBrf0055616
|Russell et al.
|1992
BPT|19E8--F1;19F3--4
ACLA|Deficiency
AMD|lfl
|l(1)19Fb
|fliI
AMDD|unc
|sol
}

REFDSR
{
RDID|FBrf0059248
|Hayward et al.
|1993
AMD|fliI
AMDD|sol
|slgA
MD|Breakpoint(s) molecularly mapped
}

REFDSR
{
RDID|FBrf0064390
|Campbell et al.
|1993
AMD|fliI
}

REFDSR
{
RDID|FBrf0074350
|Sanchez et al.
|1994
SYN|16-129
}

REFDSR
{
RDID|FBrf0080334
|Prud'homme et al.
|1995
AMDD|eo
|wap
|intro
|su(f)
AM|Chromosome fails to complement @flam<up>1</up>@ despite not being deleted
|for the @flam@ region, possibly because of an additional mutation at
|the @flam@ locus.
}

REFDSR
{
RDID|FBrf0083951
|de Couet et al.
|1995
AMD|fliI
}

REFDSR
{
RDID|FBrf0085507
|Maleszka et al.
|1996
AMD|lfl
|l(1)19Fb
|tty
|fliI
|dod
|pen
AMDD|unc
|sol
|slgA
|Hlc
|mst
|tuh1
|eo
|wap
OAB|@fliI<up>FLI</up>@ @Df(1)16-129@/@fliI<up>FLI</up>@ @Df(1)2/19B@
|individuals are 100% viable and 98% of survivors can fly normally.
|@fliI<up>FLI</up>@ @Df(1)16-129@/@fliI<up>FLI</up>@ @Df(1)GA104@
|individuals are 76% viable and 93% of survivors can fly normally.
|@fliI<up>FLI</up>@ @Df(1)16-129@/@fliI<up>FLI</up>@ @Df(1)17-257@
|individuals are 79% viable and 94% of survivors can fly normally.
}

REFDSR
{
RDID|FBrf0101952
|Maleszka et al.
|1998
SYN|16-129
}

REFDSR
{
RDID|FBrf0137058
|Hsu et al.
|2001
OAB|@Df(1)16-129@/@Df(1)GA104@ animals (in which @fliI@ function is rescued
|by @fliI<up>FLI</up>@) are viable. Females of this genotype produce a ventralized
|eggshell phenotype, which has 35% penetrance at 25<up>o</up>C and ranges in
|expressivity from fused dorsal appendages to no appendages at all.
|At 30<up>o</up>C, the penetrance is 99% and at 18<up>o</up>C the penetrance is 3%.
|Embryos produced from @Df(1)16-129@/@Df(1)GA104@ females (in which
|@fliI@ function is rescued by @fliI<up>FLI</up>@) mated to wild-type males
|show cuticle patterning defects; expanded and fused ventral denticles.
}

REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
MU|neutrons
OAB|Viable with @Df(1)17-228@ and @Df(1)17-369@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000183	CLA 1 Deficiency	GSYM 1 Df(1)16-185	DT 1 27 Nov 05	RESZ 1953	CLOC 1 20E;20F1--h26	SK 2	REF 8	
ABSY|Df(1)16-185
DT|27 Nov 05
SYN|16-185
ID|FBab0000183
REF
{
REFM|FBrf0024685
|Schalet and Lefevre
|1973
|-1
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0087710
|Simonelig et al.
|1996
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0036523
|Rahman and Lindsley
|1981
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
REFM|FBrf0074350
|Sanchez et al.
|1994
|-1
}

ASAL|FBal0050586 == su(f)<up>16-185</up>
BPT|20E;20F1--h26
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Left limit of break 1 from non-inclusion of sph (FBrf0024685)
|Right limit of break 1 from inclusion of su(f) (FBrf0024685)
|Left limit of break 2 from polytene analysis (citation unavailable)
|Right limit of break 2 from non-inclusion of bb (FBrf0024685)
FGD|bk1 hits su(f) << bk2 << bb
MD|Breakpoint within @su(f)@.
OTH|Deleted segment: 20E--h26
REFDSR
{
RDID|FBrf0024685
|Schalet and Lefevre
|1973
MU|neutrons
AMD|su(f)
AMDD|sph
|bb
SYN|16-185
}

REFDSR
{
RDID|FBrf0036523
|Rahman and Lindsley
|1981
MU|X ray
AMD|su(f)
AMDD|Hlc
|eo
|wap
|intro
|uncl
|fog
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|bb
SYN|16-185
}

REFDSR
{
RDID|FBrf0074350
|Sanchez et al.
|1994
SYN|16-185
}

REFDSR
{
RDID|FBrf0087710
|Simonelig et al.
|1996
AMD|su(f)
MD|Breakpoint within @su(f)@.
}

SK|FBst0003787
|Df(1)16-185, su(f)[16-185]/Binsn/Dp(1;Y)v[+]y[+]
|FBst0005957
|Df(1)16-185/Binsn/Dp(1;Y)v[+]y[+]
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0000184	CLA 1 Deficiency	GSYM 1 Df(1)16-2-13	DT 1 27 Nov 05	RESZ 3953	CLOC 1 [20A2--20A3];[20A4]	SK 1	REF 10	
ABSY|Df(1)16-2-13
DT|27 Nov 05
SYN|16.2.13
ID|FBab0000184
REF
{
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
REFM|FBrf0046783
|Miklos et al.
|1987
|-1
REFM|FBrf0080334
|Prud'homme et al.
|1995
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0049891
|Perrimon et al.
|1989
|-1
REFM|FBrf0160480
|Desset et al.
|2003
|-1
REFM|FBrf0073546
|Kernan et al.
|1994
|-1
REFM|FBrf0136953
|Robert et al.
|2001
|-1
}

BPT|[20A2--20A3];[20A4]
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Left limit of break 1 from non-inclusion of eo (FBrf0046783)
|Right limit of break 1 from inclusion of flam (FBrf0080334)
|Left limit of break 2 from inclusion of uncl (FBrf0046783)
|Right limit of break 2 from non-inclusion of fog (FBrf0046783)
FGD|eo << bk1 << flam << uncl << bk2 << fog
OAB|Deficiency heterozygotes between @Df(1)B12@ or @Df(1)LB6@ and @Df(1)R21@, @Df(1)16-2-13@ or @Df(1)DCB1-35c@ are viable, fertile and do not display any visible phenotype.
OTH|Deleted segment: 20A2--20A4
REFDSR
{
RDID|FBrf0046783
|Miklos et al.
|1987
MU|neutrons
AMD|wap
|intro
|uncl
AMDD|mal
|mell
|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|unc
|lfl
|l(1)19Fb
|fliI
|sol
|slgA
|Hlc
|mst
|eo
|fog
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
}

REFDSR
{
RDID|FBrf0049891
|Perrimon et al.
|1989
AMD|wap
|intro
|uncl
AMDD|tuh1
|eo
|fog
|soz
|stnA
|stnB
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
}

REFDSR
{
RDID|FBrf0073546
|Kernan et al.
|1994
AMD|tilB
|uncl
AMDD|unc
}

REFDSR
{
RDID|FBrf0080334
|Prud'homme et al.
|1995
AMD|flam
|wap
|intro
AMDD|l(1)carot2
|mel
|mal
|Hlc
|mst
|tuh1
|eo
|su(f)
OAB|Deficiency heterozygotes between @Df(1)B12@ or @Df(1)LB6@ and @Df(1)R21@, @Df(1)16-2-13@ or @Df(1)DCB1-35c@ are viable, fertile and do not display any visible phenotype.
}

REFDSR
{
RDID|FBrf0136953
|Robert et al.
|2001
AMD|flam
|wap
AMDD|eo
SYN|16.2.13
}

REFDSR
{
RDID|FBrf0160480
|Desset et al.
|2003
AMDD|COM
}

REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-1-80@.
AMDD|fog
}

SK|FBst0005956
|Df(1)16-2-13/Binsn/Dp(1;Y)mal[+]
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0037695	CLA 1 Deficiency	GSYM 1 Df(1)16-2-14	DT 1 29 Feb 04	RESZ 664	CLOC 1 [];[]	REF 3	
ABSY|Df(1)16-2-14
DT|29 Feb 04
ID|FBab0037695
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0173250
|Munoz
|2004.1.5
|-1
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-20@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-20@.
AMDD|eo
}

REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
MU|neutrons
AMDD|l(1)19Ec
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037696	CLA 1 Deficiency	GSYM 1 Df(1)16-2-17	DT 1 29 Feb 04	RESZ 373	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-2-17
DT|29 Feb 04
ID|FBab0037696
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-93@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-93@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000185	CLA 1 Deficiency	GSYM 1 Df(1)16-2-19	DT 1 27 Nov 05	RESZ 686	CLOC 1 19A5;>19D3	REF 5	
ABSY|Df(1)16-2-19
DT|27 Nov 05
ID|FBab0000185
REF
{
REFM|FBrf0130105
|Takano-Shimizu
|2000
|-1
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
}

BPT|19A5;>19D3
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|All limits from polytene analysis (citation unavailable)
FGD|bk1 << mal << bk2
OTH|Deleted segment: 19A5--19D3
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
CCM|Similar breakpoints to @Df(1)17-25@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037697	CLA 1 Deficiency	GSYM 1 Df(1)16-2-3	DT 1 29 Feb 04	RESZ 1217	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-2-3
DT|29 Feb 04
ID|FBab0037697
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|wap
|uncl
|intro
OAB|Lethal with @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-466@,
|@Df(1)18-76@ (shows visible phenotype), @Df(1)fog-1@.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|wap
|uncl
|intro
OAB|Lethal with @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-466@,
|@Df(1)18-76@ (shows visible phenotype), @Df(1)fog-1@.
PHP|Male sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037698	CLA 1 Deficiency	GSYM 1 Df(1)16-2-5	DT 1 22 Aug 04	RESZ 1158	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-2-5
DT|22 Aug 04
ID|FBab0037698
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMDD|run
|l(1)16-1-27
|sw
|mel
|mal
OAB|Inferred to overlap with: @Df(1)16-2-5@.
|@Df(1)16-2-5@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
|Lethal with @Df(1)17-25@.
|Inferred to overlap with: @Df(1)17-25@.
|Viable with @Df(1)B111@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)T2-4A@ and
|@Df(1)17-322@.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMDD|run
|l(1)16-1-27
|sw
|mel
|mal
OAB|Inferred to overlap with: @Df(1)16-2-5@.
|@Df(1)16-2-5@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
|Lethal with @Df(1)17-25@.
|Inferred to overlap with: @Df(1)17-25@.
|Viable with @Df(1)B111@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)T2-4A@ and
|@Df(1)17-322@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000186	CLA 1 Deficiency	GSYM 1 Df(1)16-3-112	DT 1 27 Nov 05	RESZ 1007	CLOC 1 20E;20F1--h26	REF 4	
ABSY|Df(1)16-3-112
DT|27 Nov 05
SYN|16-3-112
ID|FBab0000186
REF
{
REFM|FBrf0024685
|Schalet and Lefevre
|1973
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
}

BPT|20E;20F1--h26
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Left limit of break 1 from non-inclusion of sph (FBrf0024685)
|Right limit of break 1 from inclusion of su(f) (FBrf0024685)
|Left limit of break 2 from polytene analysis (citation unavailable)
|Right limit of break 2 from non-inclusion of bb (FBrf0024685)
FGD|sph << bk1 << su(f) << bk2 << bb
AMD|su(f)
AMDD|sph
|bb
OTH|Deleted segment: 20E--h26
REFDSR
{
RDID|FBrf0024685
|Schalet and Lefevre
|1973
MU|neutrons
AMD|su(f)
AMDD|sph
|bb
SYN|16-3-112
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037699	CLA 1 Deficiency	GSYM 1 Df(1)16-3-129	DT 1 29 Feb 04	RESZ 2502	CLOC 1 [];[]	REF 2	
ABSY|Df(1)16-3-129
DT|29 Feb 04
ID|FBab0037699
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|wap
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)19Ec
|l(1)E-81
|run
|bb
AMDD|ot
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)A118@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@ and @Df(1)mal10@.
|@Df(1)19-18@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
}

REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
AMD|wap
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)19Ec
|l(1)E-81
|run
|bb
AMDD|ot
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)A118@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@ and @Df(1)mal10@.
|@Df(1)19-18@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037700	CLA 1 Deficiency	GSYM 1 Df(1)16-3-139	DT 1 29 Feb 04	RESZ 2468	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-3-139
DT|29 Feb 04
ID|FBab0037700
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|wap
|intro
|uncl
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)E-81
|run
AMDD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)T2-14A@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)T2-14A@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@, @Df(1)n20@ and @Df(1)mal10@.
|With @Df(1)n24@ and @Df(1)n23@ it shows visible phenotype.
|@Df(1)16-3-139@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|wap
|intro
|uncl
|l(1)B-56
|l(1)19Fb
|fliI
|l(1)19Fe
|mst
|Hlc
|eo
|unc
|l(1)E-81
|run
AMDD|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
OAB|Lethal with @Df(1)B111@, @Df(1)fog-1@, @Df(1)B57@, @Df(1)B12@, @Df(1)T2-14A@
|and @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)T2-14A@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Viable with @Df(1)17-25@, @Df(1)n20@ and @Df(1)mal10@.
|With @Df(1)n24@ and @Df(1)n23@ it shows visible phenotype.
|@Df(1)16-3-139@/@Dp(1;Y)mal<up>+</up>@ males are sterile.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037701	CLA 1 Deficiency	GSYM 1 Df(1)16-3-145	DT 1 29 Feb 04	RESZ 374	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-3-145
DT|29 Feb 04
ID|FBab0037701
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-93@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
CCM|Similar breakpoint limits to @Df(1)16-3-93@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037702	CLA 1 Deficiency	GSYM 1 Df(1)16-3-160	DT 1 29 Feb 04	RESZ 1794	CLOC 1 [];[]	REF 1	
ABSY|Df(1)16-3-160
DT|29 Feb 04
ID|FBab0037702
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
}

BPT|[];[]
ACLA|Deficiency
AMD|eo
|Hlc
|mst
|l(1)19Fe
|fliI
|l(1)19Fb
|l(1)B-56
|unc
|l(1)19Ec
|l(1)E-81
AMDD|run
|bb
|ot
OAB|Lethal with @Df(1)B12@, @Df(1)B57@, @Df(1)A118@, @Df(1)16-3-35@ and
|@Df(1)17-137@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)17-137@.
|Viable with @Df(1)B111@, @Df(1)17-25@, @Df(1)16-2-14@ and @Df(1)mal10@.
REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
BPT|[];[]
ACLA|Deficiency
AMD|eo
|Hlc
|mst
|l(1)19Fe
|fliI
|l(1)19Fb
|l(1)B-56
|unc
|l(1)19Ec
|l(1)E-81
AMDD|run
|bb
|ot
OAB|Lethal with @Df(1)B12@, @Df(1)B57@, @Df(1)A118@, @Df(1)16-3-35@ and
|@Df(1)17-137@.
|Inferred to overlap with: @Df(1)B12@.
|Inferred to overlap with: @Df(1)B57@.
|Inferred to overlap with: @Df(1)16-3-35@.
|Inferred to overlap with: @Df(1)A118@.
|Inferred to overlap with: @Df(1)17-137@.
|Viable with @Df(1)B111@, @Df(1)17-25@, @Df(1)16-2-14@ and @Df(1)mal10@.
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0000187	CLA 1 Deficiency	GSYM 1 Df(1)16-3-162	DT 1 27 Nov 05	RESZ 1007	CLOC 1 20E;20F1--h26	REF 4	
ABSY|Df(1)16-3-162
DT|27 Nov 05
SYN|16-3-162
ID|FBab0000187
REF
{
REFM|FBrf0024685
|Schalet and Lefevre
|1973
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
}

BPT|20E;20F1--h26
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Left limit of break 1 from non-inclusion of sph (FBrf0024685)
|Right limit of break 1 from inclusion of su(f) (FBrf0024685)
|Left limit of break 2 from polytene analysis (citation unavailable)
|Right limit of break 2 from non-inclusion of bb (FBrf0024685)
FGD|sph << bk1 << su(f) << bk2 << bb
AMD|su(f)
AMDD|sph
|bb
OTH|Deleted segment: 20E--h26
REFDSR
{
RDID|FBrf0024685
|Schalet and Lefevre
|1973
MU|neutrons
AMD|su(f)
AMDD|sph
|bb
SYN|16-3-162
}

}
# EOR
ABSR
{
RETE|ID 1 FBab0037703	CLA 1 Deficiency	GSYM 1 Df(1)16-3-20	DT 1 29 Feb 04	RESZ 1395	CLOC 1 [];[]	SK 1	REF 1	
ABSY|Df(1)16-3-20
DT|29 Feb 04
ID|FBab0037703
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|bb
|wap
AMDD|eo
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@ and
|@Df(1)17-322@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
MU|neutrons
AMD|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
|bb
|wap
AMDD|eo
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@ and
|@Df(1)17-322@.
}

SK|FBst0007428
|Df(1)16-3-20/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0037704	CLA 1 Deficiency	GSYM 1 Df(1)16-3-211	DT 1 29 Feb 04	RESZ 1358	CLOC 1 [];[]	SK 1	REF 1	
ABSY|Df(1)16-3-211
DT|29 Feb 04
ID|FBab0037704
REF
{
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

BPT|[];[]
ACLA|Deficiency
AMD|wap
|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|eo
AMP|bb
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-322@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
BPT|[];[]
ACLA|Deficiency
AMD|wap
|intro
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
AMDD|eo
AMP|bb
AM|Semi-lethal with @uncl<up>Q-456</up>@.
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@, @Df(1)fog-1@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Inferred to overlap with: @Df(1)fog-1@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)17-322@.
}

SK|FBst0007432
|Df(1)16-3-211/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000188	CLA 1 Deficiency	GSYM 1 Df(1)16-3-22	DT 1 27 Nov 05	RESZ 4589	CLOC 1 19D1;20A2	SK 2	REF 19	
ABSY|Df(1)16-3-22
DT|27 Nov 05
SYN|16-3-22
ID|FBab0000188
REF
{
REFM|FBrf0080317
|Pauli et al.
|1995
|-1
REFM|FBrf0041358
|Thomas and Wyman
|1984
|-1
REFM|FBrf0046783
|Miklos et al.
|1987
|-1
REFM|FBrf0040956
|Simmons et al.
|1984
|-1
REFM|FBrf0082455
|Pauli et al.
|1995
|-1
REFM|FBrf0058907
|Baird et al.
|1993
|-1
REFM|FBrf0079475
|Swain et al.
|1991
|-1
REFM|FBrf0056153
|Torres and Sanchez
|1992
|-1
REFM|FBrf0074350
|Sanchez et al.
|1994
|-1
REFM|FBrf0054538
|Balakrishnan and Rodrigues
|1991
|-1
REFM|FBrf0028343
|Schalet and Lefevre
|1976
|-1
REFM|FBrf0051328
|Swain et al.
|1990
|-1
REFM|FBrf0051915
|Baird et al.
|1990
|-1
REFM|FBrf0045913
|Yamamoto and Miklos
|1987
|-1
REFM|FBrf0066905
|Lindsley and Zimm
|1992
|-1
REFM|FBrf0034402
|Craymer and Roy
|1980
|-1
REFM|FBrf0058586
|Pokholkova et al.
|1993
|-1
REFM|FBrf0160480
|Desset et al.
|2003
|-1
REFM|FBrf0130115
|Toba and Aigaki
|2000
|-1
}

BPT|19D1;20A2
ACLA|Deficiency
DIS|Munoz.
MU|neutrons
CCM|Limits of break 1 from polytene analysis (FBrf0034402)
|Left limit of break 2 from polytene analysis (FBrf0054538)
|Right limit of break 2 from polytene analysis (FBrf0034402)
FGD|l(1)19Cb << bk1 << mal << eo << bk2 << wap
OTH|Deleted segment: 19D1--20A2
REFDSR
{
RDID|FBrf0034402
|Craymer and Roy
|1980
BPT|19D1;20A1--2
ACLA|Deficiency
AMDD|mal
|su(f)
}

REFDSR
{
RDID|FBrf0040956
|Simmons et al.
|1984
BPT|19D1--2;20A1--2
ACLA|Deficiency
}

REFDSR
{
RDID|FBrf0041358
|Thomas and Wyman
|1984
AMD|shakB
PHP|Heterozygotes with @shakB<up>3</up>@ display the @shakB@ physiological phenotype.
}

REFDSR
{
RDID|FBrf0046783
|Miklos et al.
|1987
AMD|mal
|mell
|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|unc
|lfl
|l(1)19Fb
|fliI
|sol
|slgA
|Hlc
|mst
AMDD|eo
|wap
|intro
|uncl
|fog
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
SYN|16-3-22
}

REFDSR
{
RDID|FBrf0051328
|Swain et al.
|1990
PHP|Homozygous flies exhibit abnormal tergotrochanteral muscle motoneuron
|morphology causing a branch of the medial neurite to cross the midline.
|Not due to deletion of shakB.
}

REFDSR
{
RDID|FBrf0054538
|Balakrishnan and Rodrigues
|1991
BPT|19D1;20A2
ACLA|Deficiency
AMD|shakB
}

REFDSR
{
RDID|FBrf0056153
|Torres and Sanchez
|1992
AMD|run
|shakB
|l(1)19Ec
|l(1)19Ed
|lf
|vao
|mell
|mal
PHP|Display lethal phenotype when in combination with Df(1)N71.
}

REFDSR
{
RDID|FBrf0058586
|Pokholkova et al.
|1993
BPT|19F6;20A2
ACLA|Deficiency
}

REFDSR
{
RDID|FBrf0058907
|Baird et al.
|1993
AMD|shakB
PHP|Extensive growth of the medial branch of the tergotrochantral muscle
|motorneuron, including a contralateral projection, in adults heterozygous
|for this deficiency chromosome, but not for other deficiencies that
|remove shakB.
}

REFDSR
{
RDID|FBrf0074350
|Sanchez et al.
|1994
SYN|16-3-22
}

REFDSR
{
RDID|FBrf0080317
|Pauli et al.
|1995
BPT|19D1;20A2
ACLA|Deficiency
PHP|Heterozygosity for this deletion has no effect on the mutant ovarian
|phenotype of @ovo<up>D2</up>@.
}

REFDSR
{
RDID|FBrf0130115
|Toba and Aigaki
|2000
AMD|Mgstl
}

REFDSR
{
RDID|FBrf0160480
|Desset et al.
|2003
AMDD|COM
}

SK|FBst1000232
|Df(1)16-3-22/ FM6
|FBst0000974
|Df(1)16-3-22/FM6
SKC|2
}
# EOR
ABSR
{
RETE|ID 1 FBab0037705	CLA 1 Aberration	GSYM 1 Df(1)16-3-34	DT 1 20 Apr 05	RESZ 1214	SK 1	REF 2	
ABSY|Df(1)16-3-34
DT|20 Apr 05
ID|FBab0037705
REF
{
REFM|FBrf0173252
|Munoz
|2004.1.5
|-1
REFM|FBrf0173246
|Munoz
|2003.12.10
|-1
}

CCM|Class relative to wildtype: Deficiency
MU|neutrons
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)fog-1@
|and @Df(1)17-196@.
REFDSR
{
RDID|FBrf0173246
|Munoz
|2003.12.10
MU|neutrons
AMD|intro
|wap
AMDD|bb
|eo
|uncl
|stnA
|l(1)20Ca
|l(1)20Cb
|sph
|su(f)
OAB|Lethal with @Dp(1;Y)B<up>S</up>Yy<up>+</up>@ and @Df(1)B111@.
|Inferred to overlap with: @Df(1)B111@.
|Viable with @Df(1)B57@, @Df(1)B12@, @Df(1)16-3-35@, @Df(1)17-25@, @Df(1)fog-1@
|and @Df(1)17-196@.
}

REFDSR
{
RDID|FBrf0173252
|Munoz
|2004.1.5
MU|neutrons
AMD|intro
}

SK|FBst0008123
|Df(1)16-3-34/Binsn
SKC|1
}
# EOR
ABSR
{
RETE|ID 1 FBab0000189	CLA 1 Deficiency	GSYM 1 Df(1)16-3-35	DT 1 27 Nov 05	RESZ 9566	CLOC 1 19D3;19E3	REF 23	
ABSY|Df(1)16-3-35
DT|27 Nov 05
SYN|Df16-3-35
|16-3-35
ID|FBab0000189
REF
{
REFM|FBrf0039985
|Kramers et al.
|1983
|-1
REFM|FBrf0046783
|Miklos et al.
|1987
|-1
REFM|FBrf0054740
|Kramers et al.
|1991
|-1
REFM|FBrf0040956
|Simmons et al.
|1984
|-1
REFM|FBrf0057903
|Krishnan et al.
|1993
|-1
REFM|FBrf0058907
|Baird et al.
|1993
|-1
REFM|FBrf0056153
|Torres and Sanchez