The Developmental Genetics of Hybrid Inviability: A Mitotic Defect in Drosophila Hybrids

We report studies of the developmental basis of hybrid inviability in the Drosophila melanogaster complex. The pathology of these hybrids closely resembles that of mitotic mutants in D. melanogaster. We use mosaic and cytological analyses to show that hybrid male inviability is associated with, and probably caused by, a defect in mitotic cell division. In the mosaic study, we find that male clones produced in otherwise female hybrids are not cell lethal but are very small, probably reflecting defects in mitotic proliferation. Cytological inspection of larval neuroblasts reveals a profound mitotic defect in hybrids: chromosomes show a near-complete failure to condense even after 2 hr of incubation in colchicine. Both the defect in clonal proliferation and in chromatin condensation are rescued by mutations known to rescue normally inviable hybrid males. We present a simple model in which hybrid inviability is partly or entirely caused by a mitotic defect; this defect is, in turn, caused by an interaction between the Hybrid male rescue (Hmr) locus of D. melanogaster and autosomal gene(s) from D. melanogaster's sister species.     

Hybrid Lethal Systems in the Drosophila Melanogaster Species Complex. II. the Zygotic Hybrid Rescue (Zhr) Gene of D. Melanogaster

Hybrid females from Drosophila simulans females X Drosophila melanogaster males die as embryos while hybrid males from the reciprocal cross die as larvae. We have recovered a mutation in melanogaster that rescues the former hybrid females. It was located on the X chromosome at a position close to the centromere, and it was a zygotically acting gene, in contrast with mhr (maternal hybrid rescue) in simulans that rescues the same hybrids maternally. We named it Zhr (Zygotic hybrid rescue). The gene also rescues hybrid females from embryonic lethals in crosses of Drosophila mauritiana females X D. melanogaster males and of Drosophila sechellia females X D. melanogaster males. Independence of the hybrid embryonic lethality and the hybrid larval lethality suggested in a companion study was confirmed by employing two rescue genes, Zhr and Hmr (Hybrid male rescue), in doubly lethal hybrids. A model is proposed to explain the genetic mechanisms of hybrid lethalities as well as the evolutionary pathways.     

A Genetic Basis for the Inviability of Hybrids between Sibling Species of Drosophila

A mutation of Drosophila melanogaster whose only known effect is the rescue of otherwise lethal interspecific hybrids has been characterized. This mutation, Hmr, maps to 1-31.84 (9D1-9E4). Hmr may be the consequence of a P element insertion. It rescues hybrid males from the cross of D. melanogaster females to males of its three sibling species, D. simulans, D. mauritiana and D. sechellia. This rescue is recessive, since hybrid males that carry both Hmr and a duplication expected to be Hmr+ are not rescued. Hmr also rescues the otherwise inviable female hybrids from the cross of compound-X D. melanogaster females to males of its sibling species. This rescue is also recessive, since a compound-X heterozygous for Hmr does not rescue. Another mutation, discovered on the In(1)AB chromosome of D. melanogaster, is also found to rescue normally inviable species hybrids: unlike Hmr, however, In(1)AB rescues hybrid females from the cross of In(1)AB/Y males to sibling females, as well as hybrid males from the cross of In(1)AB females to sibling males. These data are interpreted on the basis of a model for the genetic basis of hybrid inviability of complementary genes.     

Genetic analysis of the hybrid male rescue locus of Drosophila

Several hybrid rescue mutations-alleles that restore the viability of normally lethal hybrids-have been discovered in Drosophila melanogaster and its relatives. Here we analyze one of these genes, Hybrid male rescue (Hmr), asking two questions about its role in hybrid inviability. (1) Does the wild-type allele from D. melanogaster (Hmr(mel)) cause hybrid embryonic inviability? (2) Does Hmr(mel) cause hybrid larval inviability? Our results show that the wild-type product of Hmr is neither necessary nor sufficient for hybrid embryonic inviability. Hmr(mel) does, however, appear to lower the viability of hybrid larvae. The data further suggest (though do not prove) that Hmr(mel) acts as a gain-of-function poison in hybrids. These findings support previous claims that hybrid embryonic and larval lethalities are genetically distinct and suggest that Hmr(mel) is at least one of the proximate causes of hybrid larval inviability.     

The Drosophila melanogaster hybrid male rescue gene causes inviability in male and female species hybrids

The Drosophila melanogaster mutation Hmr rescues inviable hybrid sons from the cross of D. melanogaster females to males of its sibling species D. mauritiana, D. simulans, and D. sechellia. We have extended previous observations that hybrid daughters from this cross are poorly viable at high temperatures and have shown that this female lethality is suppressed by Hmr and the rescue mutations In(1)AB and D. simulans Lhr. Deficiencies defined here as Hmr(-) also suppressed lethality, demonstrating that reducing Hmr(+) activity can rescue otherwise inviable hybrids. An Hmr(+) duplication had the opposite effect of reducing the viability of female and sibling X-male hybrid progeny. Similar dose-dependent viability effects of Hmr were observed in the reciprocal cross of D. simulans females to D. melanogaster males. Finally, Lhr and Hmr(+) were shown to have mutually antagonistic effects on hybrid viability. These data suggest a model where the interaction of sibling species Lhr(+) and D. melanogaster Hmr(+) causes lethality in both sexes of species hybrids and in both directions of crossing. Our results further suggest that a twofold difference in Hmr(+) dosage accounts in part for the differential viability of male and female hybrid progeny, but also that additional, unidentified genes must be invoked to account for the invariant lethality of hybrid sons of D. melanogaster mothers. Implications of our findings for understanding Haldane's rule-the observation that hybrid breakdown is often specific to the heterogametic sex-are also discussed.     

A novel system of fertility rescue in Drosophila hybrids reveals a link between hybrid lethality and female sterility

Hybrid daughters of crosses between Drosophila melanogaster females and males from the D. simulans species clade are fully viable at low temperature but have agametic ovaries and are thus sterile. We report here that mutations in the D. melanogaster gene Hybrid male rescue (Hmr), along with unidentified polymorphic factors, rescue this agametic phenotype in both D. melanogaster/D. simulans and D. melanogaster/D. mauritiana F(1) female hybrids. These hybrids produced small numbers of progeny in backcrosses, their low fecundity being caused by incomplete rescue of oogenesis as well as by zygotic lethality. F(1) hybrid males from these crosses remained fully sterile. Hmr(+) is the first Drosophila gene shown to cause hybrid female sterility. These results also suggest that, while there is some common genetic basis to hybrid lethality and female sterility in D. melanogaster, hybrid females are more sensitive to fertility defects than to lethality.     

rough deal: a gene required for proper mitotic segregation in Drosophila

We describe a genetic locus rough deal (rod) in Drosophila melanogaster, identified by mutations that interfere with the faithful transmission of chromosomes to daughter cells during mitosis. Five mutant alleles were isolated, each associated with a similar set of mitotic abnormalities in the dividing neuroblasts of homozygous mutant larvae: high frequencies of aneuploid cells and abnormal anaphase figures, in which chromatids may lag, form bridges, or completely fail to separate. Surviving homozygous adults are sterile, and show cuticular defects associated with cell death, i.e., roughened eyes, sparse abdominal bristles, and notched wing margins. The morphological process of spermatogenesis is largely unaffected and motile sperm are produced, but meiocyte aneuploidy is common. The nature of the observed abnormalities in mitotic cells suggests that the reduced fidelity of chromosome transmission to the daughter cells is due to a failure in a mechanism involved in assuring the proper release of sister chromatids.     

'Exceptional sons' from Drosophila melanogaster mothers carrying a balancer X chromosome

This study reports on exceptional males which are obtained by using Drosophila melanogaster mothers carrying the balancers In(1)FM6 or In(1)FM7 as one of their X chromosomes. The phenomenon was first observed in interspecific crosses between D. melanogaster females and males of its closest relatives which normally produce unisexual female hybrid progeny. Whereas hybrid sons from these crosses die as third instar larvae, the presence of the particular X balancers in the mother allows a low percentage of sons to survive. Similar sterile males are also observed among non-hybrid flies. Data are presented which suggest that the males thus generated could be hyperploid for part of their X chromosome as a result of a meiotic event in their mothers or else they could start life as female zygotes and change sex through a mitotic event at an early stage.     

A New Hybrid Rescue Allele in Drosophila melanogaster

Crosses of Drosophila melanogaster females to males of its sibling species Drosophila simulans, Drosophila mauritiana and Drosophila sechellia produce no sons and daughters that are viable only at low temperatures. We describe here a novel rescue allele Df(1)EP307-1-2 isolated on the basis of its suppression of high temperature hybrid female lethality. Df(1)EP307-1-2 also rescues hybrid males to the pharate adult stage, the same stage at which it is lethal to D. melanogaster pure species males. Molecular analysis indicates that Df(1)EP307-1-2 is associated with a deletion of about 61 kb in the 9D region of the X chromosome. The structure of Df(1)EP307-1-2 suggests that it was formed by a process similar to P-element induced male recombination.     

Misregulation of sex-lethal and disruption of male-specific lethal complex localization in Drosophila species hybrids

A major model system for the study of evolutionary divergence between closely related species has been the unisexual lethality resulting from reciprocal crosses of Drosophila melanogaster and D. simulans. Sex-lethal (Sxl), a critical gene for sex determination, is misregulated in these hybrids. In hybrid males from D. melanogaster mothers, there is an abnormal expression of Sxl and a failure of localization of the male-specific lethal (MSL) complex to the X chromosome, which causes changes in gene expression. Introduction of a Sxl mutation into this hybrid genotype will allow expression of the MSL complex but there is no sequestration to the X chromosome. Lethal hybrid rescue (Lhr), which allows hybrid males from this cross to survive, corrects the SXL and MSL defects. The reciprocal cross of D. simulans mothers by D. melanogaster males exhibits underexpression of Sxl in embryos.     

Nup96-dependent hybrid lethality occurs in a subset of species from the simulans clade of Drosophila

The cross of Drosophila melanogaster females to D. simulans males typically produces lethal F(1) hybrid males. F(1) male lethality is suppressed when the D. simulans Lhr(1) hybrid rescue strain is used. Viability of these F(1) males carrying Lhr(1) is in turn substantially reduced when the hybrids are heterozygous for some mutant alleles of the D. melanogaster Nup96 gene. I show here that similar patterns of Nup96-dependent lethality occur when other hybrid rescue mutations are used to create F(1) males, demonstrating that Nup96 does not reduce hybrid viability by suppressing the Lhr(1) rescue effect. The penetrance of this Nup96-dependent lethality does not correlate with the penetrance of the F(1) hybrid rescue, arguing that these two phenomena reflect genetically independent processes. D. simulans, together with two additional sister species, forms a clade that speciated after the divergence of their common ancestor from D. melanogaster. I report here that Nup96(-) reduces F(1) viability in D. melanogaster hybrids with one of these sister species, D. sechellia, but not with the other, D. mauritiana. These results suggest that Nup96-dependent lethality evolved after the speciation of D. melanogaster from the common ancestor of the simulans clade and is caused by an interaction among Nup96, unknown gene(s) on the D. melanogaster X chromosome, and unknown autosomal gene(s), at least some of which have diverged in D. simulans and D. sechellia but not in D. mauritiana. The genetic properties of Nup96 are also discussed relative to other hybrid lethal genes.     

Mutations in Genes Encoding Essential Mitotic Functions in DROSOPHILA MELANOGASTER

Temperature-sensitive mutations at 15 loci that affect the fidelity of mitotic chromosome behavior have been isolated in Drosophila melanogaster. These mitotic mutants were detected in a collection of 168 EMS-induced X-linked temperature-sensitive (ts) lethal and semilethal mutants. Our screen for mutations with mitotic effects was based upon the reasoning that under semirestrictive conditions such mutations could cause an elevated frequency of mitotic chromosome misbehavior and that such events would be detectable with somatic cell genetic techniques. Males hemizygous for each ts lethal and heterozygous for the recessive autosomal cell marker mwh were reared under semirestrictive conditions, and the wings of those individuals surviving to adulthood were examined for an increased frequency of mwh clones. Those mutations producing elevated levels of chromosome instability during growth of the wing imaginal disc were also examined for their effects on chromosome behavior in the cell lineages producing the abdominal cuticle. Fifteen mutations affect chromosome behavior in both wing and abdominal cells and thus identify loci generally required for the fidelity of mitotic chromosome transmission. Mapping and complementation tests show that these mutations represent 15 loci. One mutant is an allele of a locus (mus-101) previously identified by mutagen-sensitive mutants and a second mutant is an allele of the lethal locus zw 10.--The 15 mutants were also examined cytologically for their effects on chromosomes in larval neuroblasts. Taken together, the results of our cytological and genetical studies show that these mutants identify loci with wild-type functions necessary for either maintenance of chromosome integrity or regular disjunction of chromosomes or chromosome condensation. Thus, these mutations define a broad spectrum of genes required for the normal execution of the mitotic chromosome cycle.     

An Attempt to Hybridize Drosophila Species Using Pole Cell Transplantation

We have made hybrid embryos in Drosophila by pole cell transplants, by transfering pole cells from two species, D. rajasekari and D. eugracilis, into sterile D. melanogaster hosts. These females were then mated to melanogaster males and the older these females were, the further their hybrid offspring developed. In the case of the rajasekari/melanogaster hybrids, the embryos form cuticle but had defective heads, while the eugracilis/melanogaster hatched as larvae that grew but did not moult to the second instar. Hybrid pole cells could be transferred to melanogaster hosts but they failed to make eggs.     

Chromosome Damage and Early Developmental Arrest Caused by the Rex Element of Drosophila Melanogaster

Rex (Ribosomal exchange) is a genetically identified repeated element within the ribosomal DNA (rDNA) of Drosophila melanogaster. Rex has a semidominant maternal effect that promotes exchange between and within rDNA arrays in the first few embryonic mitoses. Several of Rex's genetic properties suggest that its primary effect is rDNA-specific chromosome breakage that is resolved by recombination. We report here that rDNA crossovers are only a small, surviving minority of Rex-induced events. Cytology of embryos produced by Rex-homozygous females reveals obvious chromosome damage in at least a quarter of the embryos within the first three mitotic divisions. More than half of the embryos produced by Rex females die, and the developmental arrest is among the earliest reported for any maternal-effect lethal. The striking lethal phenotype suggests that embryos with early chromosome damage could be particularly fruitful subjects for analysis of the cell biology of early embryos.     

Incompatibility between X chromosome factor and pericentric heterochromatic region causes lethality in hybrids between Drosophila melanogaster and its sibling species

The Dobzhansky-Muller model posits that postzygotic reproductive isolation results from the evolution of incompatible epistatic interactions between species: alleles that function in the genetic background of one species can cause sterility or lethality in the genetic background of another species. Progress in identifying and characterizing factors involved in postzygotic isolation in Drosophila has remained slow, mainly because Drosophila melanogaster, with all of its genetic tools, forms dead or sterile hybrids when crossed to its sister species, D. simulans, D. sechellia, and D. mauritiana. To circumvent this problem, we used chromosome deletions and duplications from D. melanogaster to map two hybrid incompatibility loci in F(1) hybrids with its sister species. We mapped a recessive factor to the pericentromeric heterochromatin of the X chromosome in D. simulans and D. mauritiana, which we call heterochromatin hybrid lethal (hhl), which causes lethality in F(1) hybrid females with D. melanogaster. As F(1) hybrid males hemizygous for a D. mauritiana (or D. simulans) X chromosome are viable, the lethality of deficiency hybrid females implies that a dominant incompatible partner locus exists on the D. melanogaster X. Using small segments of the D. melanogaster X chromosome duplicated onto the Y chromosome, we mapped a dominant factor that causes hybrid lethality to a small 24-gene region of the D. melanogaster X. We provide evidence suggesting that it interacts with hhl(mau). The location of hhl is consistent with the emerging theme that hybrid incompatibilities in Drosophila involve heterochromatic regions and factors that interact with the heterochromatin.     

Mutations in Drosophila myb lead to centrosome amplification and genomic instability.

We have previously established that the single myb gene in Drosophila melanogaster, Dm myb, which is related to the proto-oncogene Myb, is required for the G2/M transition of the cell cycle and for suppression of endoreduplication in pupal wing cells. We now report that studies of the abdominal phenotype in loss-of-function Dm myb mutants reveal additional roles for Dm myb in the cell cycle, specifically in mitosis. Abdominal epidermal cells that are mutant for Dm myb proliferate more slowly than wild-type controls throughout pupation, with particularly sluggish progression through the early stages of mitosis. Abnormal mitoses associated with multiple functional centrosomes, unequal chromosome segregation, formation of micronuclei, and/or failure to complete cell division are common in the later cell cycles of mutant cells. Resulting nuclei are often aneuploid and/or polyploid. Similar defects have also been observed in loss-of-function mutations of the tumor suppressor genes p53, Brca1 and Brca2. These data demonstrate that in abdominal epidermal cells, Dm myb is required to sustain the appropriate rate of proliferation, to suppress formation of supernumerary centrosomes, and to maintain genomic integrity.