Understanding how speciation occurs is central to biology. Gene flow between diverging taxa is correlated with geography and other aspects of speciation; therefore, the examination of gene flow during divergence is a potent approach to understanding the nature of speciation. Here, we inferred the speciation process of the sympatric rockfishes Sebastes steindachneri and Sebastes wakiyai in the north-western Pacific and its marginal seas based on genome-wide single nucleotide polymorphism and mitochondrial DNA data. Model-based demographic inference showed that gene flow between the two species was absent in the initial and late stages of divergence and present only in the middle stage. Population expansion occurred before or during the period of gene flow. The estimated timings of the initial divergence and population expansion fell within the Pleistocene, during which the seas currently inhabited by the two species were repeatedly isolated and reconnected. Contemporary isolation was supported by the absence of hybrids and the shared mitochondrial DNA haplotypes. Our results suggest that the two species initially diverged in allopatry, followed by secondary contact and introgression and by the completion of reproductive isolation. Given that complete isolation following secondary contact has rarely been tested or documented in marine organisms, we highlight the importance of careful consideration of alternative divergence scenarios to be tested, which should take into account the geological and environmental settings.
Speciation is a continuous process, and postmating isolation is thought to be an important driver of the late stages of speciation. However, relatively little is empirically known about the process compared to other isolating mechanisms that drive the early stages of speciation, especially in non-model organisms. In this study, we characterized the genetic architecture of postmating isolation between two rockfishes, Sebastes schlegelii and S. trivittatus, whose reproductive isolation is complete. We examined transmission ratio distortion (TRD) patterns of genetic markers in two reciprocal backcross populations. Markers showing either of the two types of TRD was widespread across the genome, with some of the distorted markers forming extensive clusters around the recombination coldspots. These suggest that the postmating isolation effectively prevents gene flow across the genome and the recombination landscape contributes to the genetic architecture. Comparisons between two backcross families and two developmental stages showed little similarity in the distorted markers, suggesting asymmetry and stage-specificity of the isolation. This may be due to hybrid incompatibility involving maternal factors or extrinsic selection. The lack of sex-ratio distortion in the mapping families suggested that Haldane’s rule in terms of hybrid inviability does not hold. Additionally, QTL mapping detected significant QTLs for sex and the morphological traits relevant to divergence and convergence of rockfishes, including the body colour patterns and the overall intensities of pigmentations. These findings, coupled with the first linkage map for rockfishes presented herein, constitute an essential step towards a comprehensive understanding of speciation and morphological diversification of rockfishes.
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