Abstract
AbstractAimNatural range expansions and human‐mediated colonizations usually involve a small number of individuals that establish new populations in novel habitats. In both cases, founders carry only a fraction of the total genetic variation of the source populations. Here, we used native and non‐native populations of the green anole, Anolis carolinensis, to compare the current distribution of genetic variation in populations shaped by natural range expansion and human‐mediated colonization.LocationNorth America, Hawaiian Islands, Western Pacific Islands.MethodsWe analysed 401 mtDNA haplotypes to infer the colonization history of A. carolinensis on nine islands in the Pacific Ocean. We then genotyped 576 individuals at seven microsatellite loci to assess the levels of genetic diversity and population genetic differentiation for both the native and non‐native ranges.ResultsOur findings support two separate introductions to the Hawaiian Islands and several western Pacific islands, with subsequent colonizations within each region following a stepping‐stone model. Genetic diversity at neutral markers was significantly lower in the non‐native range because of founder effects, which also contributed to the increased population genetic differentiation among the non‐native regions. In contrast, a steady reduction in genetic diversity with increasing distance from the ancestral population was observed in the native range following range expansion.Main conclusionsRange expansions cause serial founder events that are the spatial analogue of genetic drift, producing a pattern of isolation‐by‐distance in the native range of the species. In human‐mediated colonizations, after an initial loss of genetic diversity, founder effects appear to persist, resulting in overall high genetic differentiation among non‐native regions but an absence of isolation‐by‐distance. Contrasting the processes influencing the amount and structuring of genetic variability during natural range expansion and human‐mediated biological invasions can shed new light on the fate of natural populations exposed to novel and changing environments.
Highlights
The current range of a species reflects a combination of its dispersal ability and climatic tolerances as well as the influence of interspecific interactions (Gaston, 1996; Sexton, McIntyre, Angert & Rice, 2009)
Genetic diversity at neutral markers was significantly lower in the non-native range because of founder effects, which contributed to the increased population genetic differentiation among the non-native regions
We first performed pre-evaluation of scenarios and prior distributions to check that at least one combination of scenarios and priors can produce simulated data sets that are close enough to the observed data set
Summary
The current range of a species reflects a combination of its dispersal ability and climatic tolerances as well as the influence of interspecific interactions (Gaston, 1996; Sexton, McIntyre, Angert & Rice, 2009). Modifications of a species’ distribution, population size and connectivity should be reflected in the amount and structuring of genetic diversity within and genetic differentiation among contemporary populations, largely because of the effects of natural selection, genetic drift and gene flow. Understanding how these mechanisms drive population differentiation as well as generate diversity is a major aim in evolutionary biology. A key question is whether recent human-mediated changes in species ranges (i.e., non-native species introductions) result in different patterns of genetic diversity and differentiation in the non-native compared to the native ranges of a species
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