Quantifying the relative contributions of the X chromosome, autosomes, and mitochondrial genome to local adaptation*

Lasne, Clementine; Heerwaarden, Belinda Van; Sgrò, Carla M.; Connallon, Tim

doi:10.1111/evo.13647

Cited by 19 publications

(22 citation statements)

References 86 publications

(193 reference statements)

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“…; Lasne et al. ), studies conducted since The Millenial Drought (1996–2010) have reported elevated desiccation resistance in temperate populations from southeastern Australia, where desiccation stresses have been particularly intense (Lasne et al., , ; the current study). In light of these observations, our four focal traits are among the best candidates for adaptive divergence by latitude across eastern Australia.…”

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confidence: 48%

“…Australian Drosophila populations have played a key role in studies of climatic adaptation, repeatedly exhibiting genetically based clinal divergence in body size and thermal stress traits, despite strong gene flow across the cline (Kennington et al 2003;Hoffmann and Weeks 2007;Sgrò et al 2010;Hangartner et al 2015;Lasne et al 2018). Although desiccation resistance has shown less consistent clinal divergence than our other focal traits (Hoffmann et al 2001;Lasne et al 2018), studies conducted since The Millenial Drought (1996)(1997)(1998)(1999)(2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009)(2010) have reported elevated desiccation resistance in temperate populations from southeastern Australia, where desiccation stresses have been particularly intense (Lasne et al, 2018(Lasne et al, , 2019; the current study). In light of these observations, our four focal traits are among the best candidates for adaptive divergence by latitude across eastern Australia.…”

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confidence: 87%

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Genetic covariances promote climatic adaptation in AustralianDrosophila*

et al. 2019

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Evolutionary potential for adaptation hinges upon the orientation of genetic variation for traits under selection, captured by the additive genetic variance‐covariance matrix (G), as well as the evolutionary stability of G. Yet studies that assess both the stability of G and its alignment with selection are extraordinarily rare. We evaluated the stability of G in three Drosophila melanogaster populations that have adapted to local climatic conditions along a latitudinal cline. We estimated population‐ and sex‐specific G matrices for wing size and three climatic stress‐resistance traits that diverge adaptively along the cline. To determine how G affects evolutionary potential within these populations, we used simulations to quantify how well G aligns with the direction of trait divergence along the cline (as a proxy for the direction of local selection) and how genetic covariances between traits and sexes influence this alignment. We found that G was stable across the cline, showing no significant divergence overall, or in sex‐specific subcomponents, among populations. G also aligned well with the direction of clinal divergence, with genetic covariances strongly elevating evolutionary potential for adaptation to climatic extremes. These results suggest that genetic covariances between both traits and sexes should significantly boost evolutionary responses to environmental change.

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confidence: 48%

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confidence: 87%

Genetic covariances promote climatic adaptation in AustralianDrosophila*

et al. 2019

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“…Recently, sometimes unexpected complexity of sex chromosome markers has been highlighted ( cf . Lasne, van Heerwaarden, Sgrò, & Connallon, 2018; Battey, 2020; Hayes, Barton, & Zeng, 2020). This system offers much to the study of the genomics of differentiation and speciation.…”

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confidence: 99%

Robbery in progress: Historical museum collections bring to light a mitochondrial capture within a bird species widespread across southern Australia, the Copperback Quail‐thrush Cinclosoma clarum

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et al. 2020

Ecology and Evolution

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We surveyed mitochondrial, autosomal, and Z chromosome diversity within and between the Copperback Quail‐thrush Cinclosoma clarum and Chestnut Quail‐thrush C. castanotum, which together span the arid and semi‐arid zones of southern Australia, and primarily from specimens held in museum collections. We affirm the recent taxonomic separation of the two species and then focus on diversity within the more widespread of the two species, C. clarum. To guide further study of the system and what it offers to understanding the genomics of the differentiation and speciation processes, we develop and present a hypothesis to explain mitonuclear discordance that emerged in ourdata. Following a period of historical allopatry, secondary contact has resulted in an eastern mitochondrial genome replacing the western mitochondrial genome in western populations. This is predicted under a population‐level invasion in the opposite direction, that of the western population invading the range of the eastern one. Mitochondrial captures can be driven by neutral, demographic processes, or adaptive mechanisms, and we favor the hypothesized capture being driven by neutral means. We cannot fully reject the adaptive process but suggest how these alternatives may be further tested. We acknowledge an alternative hypothesis, which finds some support in phenotypic data published elsewhere, namely that outcomes of secondary contact have been more complex than our current genomic data suggest. Discriminating and reconciling these two alternative hypotheses, which may not be mutually exclusive, could be tested with closer sampling at levels of population, individual, and nucleotide than has so far been possible. This would be further aided by knowledge of the genetic basis to phenotypic variation described elsewhere.

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“…Lasne et al. () explore this problem by investigating trait variation in two divergent populations of Drosophila melanogaster from each end of the eastern Australian latitudinal cline. First, they construct a series of theoretical models to create predictions about the contribution of mitochondrial, autosomal, and sex chromosomes to adaptive trait divergence given different patterns of dispersal and variation in population size and selection strength.…”

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confidence: 99%

“…Although recent work has made predictions about the importance of different genomes for adaptation, namely, the mitochondrial genome (e.g., Camus et al 2017), there is little experimental evidence available for the relative contributions of autosomal chromosomes, sex chromosomes, and mitochondrial genomes to adaptive trait divergence and local adaptation. Lasne et al (2019) explore this problem by investigating trait variation in two divergent populations of Drosophila melanogaster from each end of the eastern Australian latitudinal cline. First, they construct a series of theoretical models to create predictions about the contribution of mitochondrial, autosomal, and sex chromosomes to adaptive trait divergence given * This article corresponds to Lasne, C., B.…”

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confidence: 99%