There is growing interest in resolving the curious disconnect between the fields of kin selection and sexual selection. Rankin's (2011, J. Evol. Biol. 24, 71-81) theoretical study of the impact of kin selection on the evolution of sexual conflict in viscous populations has been particularly valuable in stimulating empirical research in this area. An important goal of that study was to understand the impact of sex-specific rates of dispersal upon the coevolution of male-harm and female-resistance behaviours. But the fitness functions derived in Rankin's study do not flow from his model's assumptions and, in particular, are not consistent with sex-biased dispersal. Here, we develop new fitness functions that do logically flow from the model's assumptions, to determine the impact of sex-specific patterns of dispersal on the evolution of sexual conflict. Although Rankin's study suggested that increasing male dispersal always promotes the evolution of male harm and that increasing female dispersal always inhibits the evolution of male harm, we find that the opposite can also be true, depending upon parameter values. IntroductionKin selection operates when individuals impact upon the reproductive success of their genetic relatives (Hamilton, 1963(Hamilton, , 1964(Hamilton, , 1970Maynard Smith, 1964). Because mating success is a component of reproductive success, there is great potential for kin selection to operate in contexts that have traditionally been viewed through the lens of sexual selection (Pizzari & Gardner, 2012). Yet, the vast literatures on kin selection and sexual selection remain curiously disconnected.Rankin's (2011) theoretical analysis of the role of kin selection in mediating the evolution of sexual conflict in viscous populations is therefore a welcome contribution, which has helped to draw empirical research attention to this important but greatly neglected topic (e.g. Carazo et al., 2014). Sexual conflict occurs when male-male competition favours harmful traits in males that reduce female fitness and when females evolve counteradaptations to make them less vulnerable to such male traits (Parker, 1979;Chapman et al., 2003;Arnqvist & Rowe, 2005;Parker, 2006). The major conceptual aim of Rankin's analysis was to demonstrate that kin selection can operate on such sexual conflict traits. And the main mathematical aim of the analysis was to investigate how sex-specific rates of dispersal impact upon the evolution of male-harm and femaleresistance phenotypes. Specifically, Rankin's analysis suggested that male-harm traits are promoted by male dispersal and that they are inhibited by female dispersal.Although the effects of sex-biased dispersal upon the genetical structure of the population -and hence the relatedness term in Hamilton's (1963Hamilton's ( , 1964Hamilton's ( , 1970 rule of kin selection -were carefully tracked in Rankin's analysis, the effects of sex-biased dispersal upon fitness -and hence upon the cost and benefit terms in Hamilton's rule -were neglected. As Rankin's analysis is...
Phenotypic plasticity may allow species to cope with environmental variation. The study of thermal plasticity and its evolution helps understanding how populations respond to variation in temperature. In the context of climate change, it is essential to realize the impact of historical differences in the ability of populations to exhibit a plastic response to thermal variation and how it evolves during colonization of new environments. We have analyzed the real-time evolution of thermal reaction norms of adult and juvenile traits in Drosophila subobscura populations from three locations of Europe in the laboratory. These populations were kept at a constant temperature of 18ºC, and were periodically assayed at three experimental temperatures (13ºC, 18ºC, and 23ºC). We found initial differentiation between populations in thermal plasticity as well as evolutionary convergence in the shape of reaction norms for some adult traits, but not for any of the juvenile traits. Contrary to theoretical expectations, an overall better performance of high latitude populations across temperatures in early generations was observed. Our study shows that the evolution of thermal plasticity is trait specific, and that a new stable environment did not limit the ability of populations to cope with environmental challenges.
How much can history constrain adaptive evolution? A real‐time evolutionary approach of inversion polymorphisms in Drosophila subobscura
Chromosomal inversions are present in a wide range of animals and plants, having an important role in adaptation and speciation. Although empirical evidence of their adaptive value is abundant, the role of different processes underlying evolution of chromosomal polymorphisms is not fully understood. History and selection are likely to shape inversion polymorphism variation to an extent yet largely unknown. Here, we perform a real-time evolution study addressing the role of historical constraints and selection in the evolution of these polymorphisms. We founded laboratory populations of Drosophila subobscura derived from three locations along the European cline and followed the evolutionary dynamics of inversion polymorphisms throughout the first 40 generations. At the beginning, populations were highly differentiated and remained so throughout generations. We report evidence of positive selection for some inversions, variable between foundations. Signs of negative selection were more frequent, in particular for most cold-climate standard inversions across the three foundations. We found that previously observed convergence at the phenotypic level in these populations was not associated with convergence in inversion frequencies. In conclusion, our study shows that selection has shaped the evolutionary dynamics of inversion frequencies, but doing so within the constraints imposed by previous history. Both history and selection are therefore fundamental to predict the evolutionary potential of different populations to respond to global environmental changes.
Experimental evolution is a powerful tool to understand the adaptive potential of populations under environmental change. Here, we study the importance of the historical genetic background in the outcome of evolution at the genome-wide level. Using the natural clinal variation of Drosophila subobscura, we sampled populations from two contrasting latitudes (Adraga, Portugal and Groningen, Netherlands) and introduced them in a new common environment in the laboratory. We characterized the genome-wide temporal changes underlying the evolutionary dynamics of these populations, which had previously shown fast convergence at the phenotypic level, but not at chromosomal inversion frequencies. We found that initially differentiated populations did not converge either at genome-wide level or at candidate SNPs with signs of selection. In contrast, populations from Portugal showed convergence to the control population that derived from the same geographical origin and had been long-established in the laboratory. Candidate SNPs showed a variety of different allele frequency change patterns across generations, indicative of an underlying polygenic basis. We did not detect strong linkage around candidate SNPs, but rather a small but long-ranging effect. In conclusion, we found that history played a major role in genomic variation and evolution, with initially differentiated populations reaching the same adaptive outcome through different genetic routes.
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