Abstract
Adaptation to derived habitats often occurs from standing genetic variation. The maintenance within ancestral populations of genetic variants favourable in derived habitats is commonly ascribed to long‐term antagonism between purifying selection and gene flow resulting from hybridization across habitats. A largely unexplored alternative idea based on quantitative genetic models of polygenic adaptation is that variants favoured in derived habitats are neutral in ancestral populations when their frequency is relatively low. To explore the latter, we first identify genetic variants important to the adaptation of threespine stickleback fish (Gasterosteus aculeatus) to a rare derived habitat—nutrient‐depleted acidic lakes—based on whole‐genome sequence data. Sequencing marine stickleback from six locations across the Atlantic Ocean then allows us to infer that the frequency of these derived variants in the ancestral habitat is unrelated to the likely opportunity for gene flow of these variants from acidic‐adapted populations. This result is consistent with the selective neutrality of derived variants within the ancestor. Our study thus supports an underappreciated explanation for the maintenance of standing genetic variation, and calls for a better understanding of the fitness consequences of adaptive variation across habitats and genomic backgrounds.
Highlights
In eukaryotes, adaptation of populations to novel ecological conditions often occurs from standing genetic variation (SGV), that is, selectively relevant variation pre-existing in the ancestor (Barrett & Schluter, 2008; Hermisson & Pennings, 2005; Matuszewski et al, 2015; Messer & Petrov, 2013; Orr & Betancourt, 2001)
A puzzle, is how SGV is maintained in the ancestor (Yeaman, 2015): if genetic variants are favoured by selection in a novel, derived habitat, should they not be unfavourable and eliminated by purifying selection in the ancestral habitat? One solution to this paradox is that genetic variants favoured in the derived habitat are maintained as SGV in the ancestor by continued hybridization between derived and ancestral populations, counteracting the selective removal of these variants in the latter (Barrett & Schluter, 2008; Bolnick & Nosil, 2007; Colosimo et al, 2005; Galloway et al, 2020; Schluter & Conte, 2009; Yeaman & Whitlock, 2011)
To explore the extent to which adaptive genetic variation discovered in freshwater fish is present as SGV in marine stickleback, we focused on samples from six locations across the Atlantic Ocean: North Uist (NU), Ireland (IR), The Netherlands (NL), Germany (DE), Iceland (IS) and Eastern Canada (CA) (Figure 1b; Table S1; note that North Uist subsumes two nearby marine sample sites, ARDH and HAENEL et al (a)
Summary
Adaptation of populations to novel ecological conditions often occurs from standing genetic variation (SGV), that is, selectively relevant variation pre-existing in the ancestor (Barrett & Schluter, 2008; Hermisson & Pennings, 2005; Matuszewski et al, 2015; Messer & Petrov, 2013; Orr & Betancourt, 2001). Due to its particular surface geology (Waterston et al, 1979), the eastern part of this island harbours numerous acidic lakes (pH around 5–6) inhabited by archetypal acidic-adapted stickleback that have probably evolved multiple times independently (Giles, 1983; Haenel et al, 2019a; Klepaker et al, 2016; Magalhaes et al, 2016; Spence et al, 2013) This parallel evolution has occurred though the deterministic sorting of SGV available in the marine ancestor, because alleles recruited repeatedly for acidic adaptation are consistently found in extant marine stickleback breeding in coastal habitats of North Uist, albeit generally at modest to low frequency (Haenel et al, 2019a). Our data support this latter scenario, highlighting selective neutrality as an underappreciated explanation for the maintenance of SGV
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