Quantitative Trait Loci for Sexual Isolation Between Drosophila simulans and D. mauritiana

324

359

Sexual isolation is a critical form of reproductive isolation in the early stages of animal speciation, yet little is known about the genetic basis of divergent mate preferences and preference cues in young species. Heliconius butterflies, well known for their diversity of wing color patterns, mate assortatively as a result of divergence in male preference for wing patterns. Here we show that the specific cue used by Heliconius cydno and Heliconius pachinus males to recognize conspecific females is the color of patches on the wings. In addition, male mate preference segregates with forewing color in hybrids, indicating a genetic association between the loci responsible for preference and preference cue. Quantitative trait locus mapping places a preference locus coincident with the locus that determines forewing color, which itself is perfectly linked to the wing patterning candidate gene, wingless. Furthermore, yellow-colored males of the polymorphic race H. cydno alithea prefer to court yellow females, indicating that wing color and color preference are controlled by loci that are located in an inversion or are pleiotropic effects of a single locus. Tight genetic associations between preference and preference cue, although rare, make divergence and speciation particularly likely because the effects of natural and sexual selection on one trait are transferred to the other, leading to the coordinated evolution of mate recognition. This effect of linkage on divergence is especially important in Heliconius because differentiation of wing color patterns in the genus has been driven and maintained by natural selection for Mü llerian mimicry.Heliconius ͉ Lepidoptera ͉ sexual isolation ͉ speciation

Section: Discussionmentioning

confidence: 99%

Linkage of butterfly mate preference and wing color preference cue at the genomic location ofwingless

Kronforst

Young

Kapan

et al. 2006

324

359

“…Two recent studies addressed the genetic basis of variation in sexual isolation between Drosophila pseudoobscura and Drosophila persimilis (61) and between Drosophila simulans and Drosophila mauritiana (62) by linkage to molecular markers in large backcross populations. In the first species pair, sexual isolation is attributable to female discrimination against males of the sibling species; males readily court females of either species.…”

Section: Drosophila Mating Behaviormentioning

confidence: 99%

Genetics and genomics of Drosophila mating behavior

Mackay

Heinsohn

Lyman

et al. 2005

132

134

The first steps of animal speciation are thought to be the development of sexual isolating mechanisms. In contrast to recent progress in understanding the genetic basis of postzygotic isolating mechanisms, little is known about the genetic architecture of sexual isolation. Here, we have subjected Drosophila melanogaster to 29 generations of replicated divergent artificial selection for mating speed. The phenotypic response to selection was highly asymmetrical in the direction of reduced mating speed, with estimates of realized heritability averaging 7%. The selection response was largely attributable to a reduction in female receptivity. We assessed the whole genome transcriptional response to selection for mating speed using Affymetrix GeneChips and a rigorous statistical analysis. Remarkably, >3,700 probe sets (21% of the array elements) exhibited a divergence in message levels between the Fast and Slow replicate lines. Genes with altered transcriptional abundance in response to selection fell into many different biological process and molecular function Gene Ontology categories, indicating substantial pleiotropy for this complex behavior. Future functional studies are necessary to test the extent to which transcript profiling of divergent selection lines accurately predicts genes that directly affect the selected trait.Species are groups of actually or potentially interbreeding natural populations, which are reproductively isolated from other such groups.Recent studies by the students of animal behavior, as well as the revised interpretation of many earlier observations, indicate that behavior differences are among animals the most important factor in restricting random mating between closely related forms.E. Mayr, 1942

“…The genetic control of the signal and its reception must be tightly coadapted, especially in interindividual sexual communication to ensure sexual isolation (1)(2)(3). However, the basic genetic architecture of prezygotic sexual isolation remains largely unexplored in most natural populations (4,5), and there is very little empirical evidence for tight genetic linkage between the emission and reception of a sensory signal (6)(7)(8)(9). Theoritical prediction and experimental studies assume that the "emission/reception coupling" depends on the inheritance of separate genes found on the same or on different chromosomes and linked with a high probability (linkage desequilibrium (10)(11)(12)(13)(14), whereas the "single-gene" hypothesis seems very unlikely (4), as the tissues involved in the emission and perception of sensory signals are usually different (15).…”

mentioning

confidence: 99%

Expression of a desaturase gene,desat1, in neural and nonneural tissues separately affects perception and emission of sex pheromones inDrosophila

Bousquet

Nojima

Houot

et al. 2011

101

Animals often use sex pheromones for mate choice and reproduction. As for other signals, the genetic control of the emission and perception of sex pheromones must be tightly coadapted, and yet we still have no worked-out example of how these two aspects interact. Most models suggest that emission and perception rely on separate genetic control. We have identified a Drosophila melanogaster gene, desat1, that is involved in both the emission and the perception of sex pheromones. To explore the mechanism whereby these two aspects of communication interact, we investigated the relationship between the molecular structure, tissue-specific expression, and pheromonal phenotypes of desat1. We characterized the five desat1 transcripts-all of which yielded the same desaturase protein-and constructed transgenes with the different desat1 putative regulatory regions. Each region was used to target reporter transgenes with either (i) the fluorescent GFP marker to reveal desat1 tissue expression, or (ii) the desat1 RNAi sequence to determine the effects of genetic down-regulation on pheromonal phenotypes. We found that desat1 is expressed in a variety of neural and nonneural tissues, most of which are involved in reproductive functions. Our results suggest that distinct desat1 putative regulatory regions independently drive the expression in nonneural and in neural cells, such that the emission and perception of sex pheromones are precisely coordinated in this species.sensory communication | pleiotropy | hydrocarbon | oenocyte