doi: 10.1016/j.cell.2009.10.033.
Little effect of the tan locus on pigmentation in female hybrids between Drosophila santomea and D. melanogaster
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- PMID: 20005810
- PMCID: PMC2798109
- DOI: 10.1016/j.cell.2009.10.033
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Little effect of the tan locus on pigmentation in female hybrids between Drosophila santomea and D. melanogaster
Cell.
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Abstract
Previous work on Drosophila santomea suggested that its absence of abdominal pigmentation, compared to the other darkly pigmented species, is based on mutations in the cis-regulatory region of tan, inactivating the expression of that gene in the abdomen of D. santomea males and females. Our discovery that D. santomea males can produce viable hybrids when mated to D. melanogaster females enables us to use the armamentarium of genetic tools in the latter species to study the genetic basis of this interspecific difference in pigmentation. Hybridization tests using D. melanogaster deficiencies that include tan show no evidence that this locus is involved in the lighter pigmentation of D. santomea females; rather, the pigmentation difference appears to involve at least four other loci in the region. Earlier results implicating tan may have been based on a type of transgenic analysis that can give misleading results about the genes involved in an evolutionary change.
Figures
Abdominal pigmentation of D. melanogaster, D. santomea and D. yakuba. A. ♀ D. melanogaster, B. ♀ D. santomea, C. ♀ D. yakuba, D. ♂ D. melanogaster, E. ♂ D. santomea and F. ♂ D. yakuba.
D. melanogaster females heterozygous for tan mutants and the Basc balancer chromosome (mel tan/Basc) backcrossed to tan males. In all cases Basc/tan heterozygotes (A–F) homozygotes (G–L) can be clearly distinguished from tan/tan homozygotes in D. melanogaster.
Phenotypic distribution of the progeny produced by the (Df(1)t20A/Basc) x Df(1)t20A (A) and (Df(1)t20A/Basc) × san (B) crosses.
Interspecific complementation tests. D. melanogaster females heterozygous for tan mutants and the Basc balancer chromosome (mel tan/Basc) were crossed to males of four different species: D. mauritiana, D. simulans, D. melanogaster and D. santomea. Only the crosses involving Df(1)t20A/Basc females are shown but the results are the same with all the mutants studied. Top panels: F1 hybrid females carrying Basc. A.mau/Basc, B.sim/Basc, C.mel/Basc, D.san/Basc. Lower panels: F1 hybrid females carrying tan: E. mau/ Df(1)t20A, F. sim/ Df(1)t20A, G. mel/ Df(1)t20A, H. san/ Df(1)t20A.
Deficiency analysis of QTL affecting pigmentation between D. melanogaster and D. santomea. Only two of the sixteen tested deficiencies are shown. D. melanogaster (Df(1)BK10) when crossed to a D. santomea male produced two kinds of progeny (Basc/san (A) and Df(1)BK10/san (C)) that showed a significant difference in pigmentation. The progeny of the cross mel (Df(1)r-D17) × san (Basc/san (B) and Df(1)r-D17/san (D)) showed no significant differences in their pigmentation levels. Top panels: F1 hybrid females carrying Basc. A. Basc/san, B. Basc/san Lower panels: F1 hybrid females carrying a deficiency C. Df(1)BK10/san, D. Df(1)r-D17/san
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