Positive selection plays a major role in shaping signatures of differentiation across the genomic landscape of two independent Ficedula flycatcher species pairs
A current debate within population genomics surrounds the relevance of patterns of genomic differentiation between closely related species for our understanding of adaptation and speciation. Mounting evidence across many taxa suggests that the same genomic regions repeatedly develop elevated differe...
| Main Authors: | , , |
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| Format: | Dataset |
| Language: | unknown |
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2021
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| Online Access: | https://zenodo.org/record/4763897 https://doi.org/10.5061/dryad.n2z34tmw6 |
| Summary: | A current debate within population genomics surrounds the relevance of patterns of genomic differentiation between closely related species for our understanding of adaptation and speciation. Mounting evidence across many taxa suggests that the same genomic regions repeatedly develop elevated differentiation in independent species pairs. These regions often coincide with high gene density and/or low recombination, leading to the hypothesis that the genomic differentiation landscape mostly reflects a history of background selection, and reveals little about adaptation or speciation. A comparative genomics approach with multiple independent species pairs at a timescale where gene flow and ILS are negligible permits investigating whether different evolutionary processes are responsible for generating lineage-specific versus shared patterns of species differentiation. We use whole-genome re-sequencing data of 195 individuals from four Ficedula flycatcher species comprising two independent species pairs: collared and pied flycatchers, and red-breasted and taiga flycatchers. We found that both shared and lineage-specific FST peaks could partially be explained by selective sweeps, with recurrent selection likely to underlie shared signatures of selection, while indirect evidence supports a role of recombination landscape evolution in driving lineage specific-signatures of selection. This work therefore provides evidence for an interplay of positive selection and recombination to genomic landscape evolution. Additional files contain positions of SNPs with more than 10 percent missing data for each of the species or species pairs. For species pairs, sites with greater than 10% missing data in either species were removed. A bed file contains the coordinates of regions identified as putatively collapsed duplicates in the assembly. SNPs falling within these regions were removed from all analyses. Funding provided by: Knut och Alice Wallenbergs StiftelseCrossref Funder Registry ID: ... |
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