Abstract
The rough periwinkle, Littorina saxatilis, is a model system for studying parallel ecological speciation in microparapatry. Phenotypically parallel wave‐adapted and crab‐adapted ecotypes that hybridize within the middle shore are replicated along the northwestern coast of Spain and have likely arisen from two separate glacial refugia. We tested whether greater geographic separation corresponding to reduced opportunity for contemporary or historical gene flow between parallel ecotypes resulted in less parallel genomic divergence. We sequenced double‐digested restriction‐associated DNA (ddRAD) libraries from individual snails from upper, mid, and low intertidal levels of three separate sites colonized from two separate refugia. Outlier analysis of 4256 SNP markers identified 34.4% sharing of divergent loci between two geographically close sites; however, these sites each shared only 9.9%–15.1% of their divergent loci with a third more‐distant site. STRUCTURE analysis revealed that genotypes from only three of 166 phenotypically intermediate mid‐shore individuals appeared to result from recent hybridization, suggesting that hybrids cannot be reliably identified using shell traits. Hierarchical AMOVA indicated that the primary source of genomic differentiation was geographic separation, but also revealed greater similarity of the same ecotype across the two geographically close sites than previously estimated with dominant markers. These results from a model system for ecological speciation suggest that genomic parallelism is affected by the opportunity for historical or contemporary gene flow between populations.
Highlights
Strong evidence for a primary role for natural selection in driving ecological speciation is found in cases in which similar local selective forces generate comparably adapted phenotypes and similar sources of reproductive isolation (Arendt & Reznick, 2008; Rundle& Nosil, 2005; Schluter & Nagel, 1995)
Our results show marked difference from other studies of parallel genomic divergence that emphasize a role for standing variation in driving local adaptation (Barrett & Schluter, 2008; Nelson & Cresko, 2018; Schluter & Conte, 2009)
We identified substantial sharing of total divergent outlier loci between upper and lower shore ecotypes across two geographically close sites that was not observed at a third distant site colonized from a separate glacial refuge
Summary
Strong evidence for a primary role for natural selection in driving ecological speciation is found in cases in which similar local selective forces generate comparably adapted phenotypes and similar sources of reproductive isolation | 8313 predation across rocky intertidal zones in the northeast Atlantic and are differentiated by life history, behavior, and shell morphology and ornamentation (Rolán-Alvarez, Austin, & Boulding, 2015; Galindo & Grahame, 2014; Johannesson et al, 2010; Rolán-Alvarez, 2007; Rolán-Alvarez, Johannesson, & Erlandsson, 1997) These ecotypes are considered a model system for the study of parallel incipient ecological speciation with gene flow (Nosil, 2012; Schluter, 2009), as local adaptation and subsequent extrinsic reproductive isolation are believed to have evolved independently in response to similar ecological pressures across multiple populations, despite molecular evidence for gene flow between ecotypes (Butlin et al, 2014; Johannesson et al 1995; Johannesson et al, 2010; Quesada, Posada, Caballero, Morán, & Rolán-Alvarez, 2007; Rolán-Alvarez et al, 2004). This study contributes to our understanding of factors dictating genomic parallelism and provides new evidence of more extensive genomic isolation and progress toward potential microparapatric speciation in the model “crab” and “wave” ecotypes of L. saxatilis
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