Adaptive and maladaptive genetic diversity in small populations; insights from the Brook Charr (Salvelinus fontinalis) case study

Abstract

Investigating the relative importance of neutral versus selective processes governing the accumulation of genetic variants is a key goal in evolutionary biology. This is particularly true in the context of small populations, where genetic drift can counteract the effect of selection. In this study, we investigated the accumulation of putatively beneficial and harmful variations using 7,950 high-quality filtered SNPs among 36 lacustrine, seven riverine and seven anadromous Brook Charr (Salvelinus fontinalis) populations (n = 1,193) from Québec, Canada. Using the Provean algorithm, we observed an accumulation of deleterious mutations that tend to be more prevalent in isolated lacustrine and riverine populations than the more connected anadromous populations. In addition, the absence of correlation between the occurrence of putative beneficial nor deleterious mutations and local recombination rate supports the hypothesis that genetic drift might be the main driver of the accumulation of such variants. Despite the effect of pronounced genetic drift and limited gene flow in non-anadromous populations, several loci representing biological functions of potential adaptive significance were associated with environmental variables, and particularly with temperature. We also identified genomic regions associated with anadromy. We also observed an overrepresentation of transposable elements associated with variation in environmental variables, thus supporting the importance of transposable elements in adaptation.