Abstract
Genetic structure within marine species may be driven by local adaptation to their environment, or alternatively by historical processes, such as geographic isolation. The gulfs and seas bordering the Arabian Peninsula offer an ideal setting to examine connectivity patterns in coral reef fishes with respect to environmental gradients and vicariance. The Red Sea is characterized by a unique marine fauna, historical periods of desiccation and isolation, as well as environmental gradients in salinity, temperature, and primary productivity that vary both by latitude and by season. The adjacent Arabian Sea is characterized by a sharper environmental gradient, ranging from extensive coral cover and warm temperatures in the southwest, to sparse coral cover, cooler temperatures, and seasonal upwelling in the northeast. Reef fish, however, are not confined to these seas, with some Red Sea fishes extending varying distances into the northern Arabian Sea, while their pelagic larvae are presumably capable of much greater dispersal. These species must therefore cope with a diversity of conditions that invoke the possibility of steep clines in natural selection. Here, we test for genetic structure in two widespread reef fish species (a butterflyfish and surgeonfish) and eight range‐restricted butterflyfishes across the Red Sea and Arabian Sea using genome‐wide single nucleotide polymorphisms. We performed multiple matrix regression with randomization analyses on genetic distances for all species, as well as reconstructed scenarios for population subdivision in the species with signatures of isolation. We found that (a) widespread species displayed more genetic subdivision than regional endemics and (b) this genetic structure was not correlated with contemporary environmental parameters but instead may reflect historical events. We propose that the endemic species may be adapted to a diversity of local conditions, but the widespread species are instead subject to ecological filtering where different combinations of genotypes persist under divergent ecological regimes.
Highlights
In the marine environment, coral reef fishes are a model group for understanding processes of speciation because they are well-characterized and represent the most diverse vertebrate communities on the planet (Nelson, 2006)
For C. trifascialis, a widespread butterflyfish species with apparent genetic structure, comparisons of the 67 models that tested different combinations of the effects of isolation by barrier (IBB), isolation by distance (IBD), and isolation by environment (IBE) indicated that the four models that best explained genetic differentiation based on pairwise FST were those that included the Strait of Bab Al Mandab (b2) as a barrier to gene flow, as well as both geographic and environmental distances (Table S2)
These results indicate that the evolutionary processes that influence divergence between endemic species (C. austriacus and C. melapterus) might be similar to those processes influencing divergence within widespread species (i.e., Ct. striatus and C. trifascialis)
Summary
Coral reef fishes are a model group for understanding processes of speciation because they are well-characterized and represent the most diverse vertebrate communities on the planet (Nelson, 2006). Reef fishes have broad geographic ranges (typically much greater than terrestrial species; Jones, Caley, & Munday, 2002), a nearly ubiquitous pelagic larval stage with relatively few barriers to dispersal, and occupy a variety of habitats. Understanding how such traits influence the evolution and distributions of reef fishes has long motivated researchers (Bowen et al, 2013; Cowman & Bellwood, 2013). Testing the generality of these patterns as precursors to speciation requires evaluating co-distributed taxa that inhabit contrasting environmental or ecological regimes
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