Speciation genomics in Ficedula flycatchers

Understanding what evolutionary processes have shaped patterns of genomic differentiation between species is a major aim of speciation genomics. However, disentangling the role of different processes that generate similar patterns remains a substantial challenge. Within this thesis, I aimed to infer...

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Bibliographic Details
Main Author: Chase, Madeline
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Uppsala universitet, Evolutionsbiologi 2023
Subjects:
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-495937
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Summary:Understanding what evolutionary processes have shaped patterns of genomic differentiation between species is a major aim of speciation genomics. However, disentangling the role of different processes that generate similar patterns remains a substantial challenge. Within this thesis, I aimed to infer the action of different evolutionary processes through population-level genome re-sequencing of closely related species. I explored how processes such as recombination, natural selection, and genetic drift interact to shape the genomic differentiation landscape among multiple species of Ficedula flycatcher. Collared flycatcher and pied flycatcher are a pair of closely related species, which hybridize in regions of secondary contact. Reproductive isolation is strong and hybrids appear to be sterile. I compared the differentiation landscape between collared and pied flycatchers with a more distantly related species pair, the red-breasted and taiga flycatchers. This comparison revealed elevated regions of genomic differentiation shared between the two pairs, i.e. shared differentiation peaks, and those unique to a single pair, i.e. lineage-specific differentiation peaks. Since the two species pairs share a negligible portion of genetic variation, shared patterns in the differentiation landscape should be driven and maintained by conserved processes, while lineage-specific patterns should be driven by lineage-specific changes in relevant evolutionary processes. Selective sweep scans suggested that both shared and lineage-specific peaks can result from adaptive evolution and that lineage-specific adaptation is not a sufficient determinant of lineage-specific peaks. Instead, lineage-specific differentiation peaks appeared to be driven by evolutionary changes in the recombination landscape, the dynamics of which had strong impacts on the detection of signatures of linked selection. I also found that adaptation did not play a prominent role on Z-chromosome differentiation. Both the fast-Z and large-Z effects were apparent ...