Abstract
BackgroundThe study of speciation has expanded with the increasing availability and affordability of high-resolution genomic data. How the genome evolves throughout the process of divergence and which regions of the genome are responsible for causing and maintaining that divergence have been central questions in recent work. Here, we use three pairs of species from the recently diverged bee hummingbird clade to investigate differences in the genome at different stages of speciation, using divergence times as a proxy for the speciation continuum.ResultsPopulation measures of relative differentiation between hybridizing species reveal that different chromosome types diverge at different stages of speciation. Using FST as our relative measure of differentiation we found that the sex chromosome shows signs of divergence early in speciation. Next, small autosomes (microchromosomes) accumulate highly diverged genomic regions, while the large autosomes (macrochromosomes) accumulate genomic regions of divergence at a later stage of speciation.ConclusionsOur finding that genomic windows of elevated FST accumulate on small autosomes earlier in speciation than on larger autosomes is counter to the prediction that FST increases with size of chromosome (i.e. with decreased recombination rate), and is not represented when weighted average FST per chromosome is compared with chromosome size. The results of this study suggest that multiple chromosome characteristics such as recombination rate and gene density combine to influence the genomic locations of signatures of divergence.
Highlights
The study of speciation has expanded with the increasing availability and affordability of highresolution genomic data
We investigate 1) how genomic signatures of divergence change as speciation proceeds, and 2) the differences between micro, macro, and Z chromosomes, how those differences compare across the speciation continuum, and what that tells us about the importance of different chromosome types in speciation
We found that speciation seems to progress at different rates based on chromosome type, with the sex chromosome diverging first, the microchromosomes diverging and divergence only appearing on the macrochromosomes in late stages of reproductive isolation
Summary
The study of speciation has expanded with the increasing availability and affordability of highresolution genomic data. The recently developed field of “speciation genomics” has revealed that speciation with gene flow, a phenomenon that was once thought to be highly unlikely [2], is common [3,4,5,6,7], including between extant and extinct taxa (reviewed in [8]). These revelations suggest that the individual is not the unit of isolation, and that there must be regions of isolation within the genome maintaining species boundaries. Overall, investigating the genomic landscapes of differentiation between hybridizing species using modern genomics techniques will enhance our understanding of speciation [1, 12]
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