The genetic basis of morphological differences among species is still poorly understood. We investigated the genetic basis of sex-specific differences in wing size between two closely related species of Nasonia by positional cloning a major male-specific locus, wing-size1 (ws1). Male wing size increases by 45% through cell size and cell number changes when the ws1 allele from N. giraulti is backcrossed into a N. vitripennis genetic background. A positional cloning approach was used to fine-scale map the ws1 locus to a 13.5 kilobase region. This region falls between prospero (a transcription factor involved in neurogenesis) and the master sex-determining gene doublesex. It contains the 5′-UTR and cis-regulatory domain of doublesex, and no coding sequence. Wing size reduction correlates with an increase in doublesex expression level that is specific to developing male wings. Our results indicate that non-coding changes are responsible for recent divergence in sex-specific morphology between two closely related species. We have not yet resolved whether wing size evolution at the ws1 locus is caused by regulatory alterations of dsx or prospero, or by another mechanism. This study demonstrates the feasibility of efficient positional cloning of quantitative trait loci (QTL) involved in a broad array of phenotypic differences among Nasonia species.
Crossing over between homologous chromosomes during meiosis repairs programmed DNA double-strand breaks, ensures proper segregation at meiosis I [1], shapes the genomic distribution of nucleotide variability in populations, and enhances the efficacy of natural selection among genetically linked sites [2]. Between closely related Drosophila species, large differences exist in the rate and chromosomal distribution of crossing over. Little, however, is known about the molecular genetic changes or population genetic forces that mediate evolved differences in recombination between species [3, 4]. Here, we show that a meiosis gene with a history of rapid evolution acts as a trans-acting modifier of species differences in crossing over. In transgenic flies, the dicistronic gene, mei-217/mei-218, recapitulates a large part of the species differences in the rate and chromosomal distribution of crossing over. These phenotypic differences appear to result from changes in protein sequence not gene expression. Our population genetics analyses show that the protein-coding sequence of mei-218, but not mei-217, has a history of recurrent positive natural selection. By modulating the intensity of centromeric and telomeric suppression of crossing over, evolution at mei-217/-218 has incidentally shaped gross differences in the chromosomal distribution of nucleotide variability between species. We speculate that recurrent bouts of adaptive evolution at mei-217/-218 might reflect a history of coevolution with selfish genetic elements.
Archaeological investigations of pastoral economies often emphasize exchange relations with agricultural populations, though for Bronze Age Eurasia the notion of a ubiquitous 'pastoral realm' has masked various forms of mixed subsistence economies. In Central Asia, there are few attempts to specifically identify the domestic crops utilized by mobile pastoralists or what they may suggest about the role of agriculture in mobile pastoral production or subsistence strategies. This study reports the macrobotanical remains from two Late/Final Bronze Age (ca. 1950-1300 BC) mobile pastoralist habitation sites in the Murghab alluvial fan region of southern Turkmenistan. We compare our results with published macrobotanical data from contemporary agricultural settlements in the Murghab region, as well as with other sites in broader prehistoric Eurasia. We find that mobile pastoralists in the Murghab utilized some of the same domestic crops as their sedentary neighbors. While the data presented here do not preclude the possibility that mobile pastoralists may have practiced some low-investment cultivation (particularly of millet), we hypothesize an economic model that places mobile pastoralists in direct contact with nearby sedentary farming communities through exchange for pre-processed grains. These results highlight one of the possible strategies of mobile pastoral subsistence in Central Asia, and are a further step toward identifying the various degrees of agricultural involvement in the conceptually outdated pastoral realm of Eurasia.
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. M ORE than 70 years ago, Dobzhansky (1937) and Muller (1942) proposed a simple two-locus model in which postzygotic isolation arises as a byproduct of divergence between effectively allopatric populations. Genes that function well in one species' genetic background might not be functional in a hybrid genetic background, rendering hybrids dead or sterile. Despite early acceptance of the Dobzhansky-Muller model, progress in identifying and characterizing factors involved in hybrid incompatibilities has remained slow. One of the reasons for the slow progress is that Drosophila melanogaster, with its many genetic tools, forms largely dead or sterile hybrids when crossed to its sister species D. simulans, D. sechellia, and D. mauritiana (Sturtevant 1920(Sturtevant , 1929Lachaise et al. 1986;Provine 1991;Barbash 2010).In general, three methods have been used to circumvent this problem. First, alleles that suppress postzygotic isolation, so-called hybrid rescue mutations, have been used to characterize hybrid inviability between D. melanogaster and its three sister species in the D. simulans complex. When D. melanogaster females are crossed to sibling species males, only hybrid females are produced while males die as larvae (Sturtevant 1920;Lachaise et al. 1986). These males are rescued by the D. melanogaster mutant allele of Hybrid male rescue (Hmr) (Hutter...
The Dobzhansky-Muller model posits that intrinsic postzygotic reproductive isolation-the sterility or lethality of species hybrids-results from the evolution of incompatible epistatic interactions between species: favorable or neutral alleles that become fixed in the genetic background of one species can cause sterility or lethality in the genetic background of another species. The kind of hybrid incompatibility that evolves between two species, however, depends on the particular evolutionary history of the causative substitutions. An allele that is functionally derived in one species can be incompatible with an allele that is functionally derived in the other species (a derived-derived hybrid incompatibility). But an allele that is functionally derived in one species can also be incompatible with an allele that has retained the ancestral state in the other species (a derived-ancestral hybrid incompatibility). The relative abundance of such derived-derived vs. derived-ancestral hybrid incompatibilities is unknown. Here, we characterize the genetics and evolutionary history of a lethal hybrid incompatibility between Drosophila mauritiana and its two sibling species, D. sechellia and D. simulans. We show that a hybrid lethality factor(s) in the pericentric heterochromatin of the D. mauritiana X chromosome, hybrid lethal on the X (hlx), is incompatible with a factor(s) in the same small autosomal region from both D. sechellia and D. simulans, Suppressor of hlx [Su(hlx)]. By combining genetic and phylogenetic information, we infer that hlx-Su(hlx) hybrid lethality is likely caused by a derived-ancestral incompatibility, a hypothesis that can be tested directly when the genes are identified.
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