Implications of barrier ephemerality in geogenomic research

Aim Previous population genetic and phylogeographical studies have shown how generation time and dispersal affect population divergence in the presence of a vicariant barrier. More recently, speciation genomic studies have revealed that selection and recombination can be equally impactful. Here, we...

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Bibliographic Details
Published in:Journal of biogeography 2022-11, Vol.49 (11), p.2050-2063
Main Authors: Araya‐Donoso, Raúl, Baty, Sarah M., Alonso‐Alonso, Pedro, Sanín, María José, Wilder, Benjamin T., Munguia‐Vega, Adrian, Dolby, Greer A.
Format: Article
Language:English
Subjects:
Barriers
community evolution
comparative phylogeography
Differentiation
Diploids
Dispersal
Dispersion
Divergence
earth‐life science
Eukaryotes
Gene flow
Genomics
Mutation
Mutation rates
Population
Population differentiation
Population genetics
Population studies
Recombination
Speciation
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Summary:Aim Previous population genetic and phylogeographical studies have shown how generation time and dispersal affect population divergence in the presence of a vicariant barrier. More recently, speciation genomic studies have revealed that selection and recombination can be equally impactful. Here, we test how the interaction of these factors shapes the divergence expected in response to an ephemeral barrier and compare these results to empirical literature using the Baja California peninsula as a test case. Location Global. Taxon Diploid eukaryotes. Methods We forward simulated population genomic data with CDMetaPOP and SLiM by varying dispersal rate, mutation rate, generation time, selection pressure and recombination in the presence and then removal of a physical barrier. We tested which factors affect the divergence signal (measured as FST). We compared simulation results to empirical literature that included 147 records of generation times and 78 divergence estimates from population genomic studies. Results Population differentiation not only occurred due to the presence of a barrier under lower dispersal abilities but also emerged as a result of low dispersal among structured populations without a barrier. Divergent selection strengthened differentiation, which is supported by empirical data. Barrier removal quickly eroded the divergence signal (~500 generations) for high‐dispersing species, but low dispersal species retained divergence after gene flow resumed. In the empirical data, generation times varied by four orders of magnitude and dispersal by three orders of magnitude. Main Conclusions Divergence can arise without vicariant barriers, it may not produce a tight co‐divergence peak in absolute time, and co‐divergence may not imply a common cause of divergence. Deeper integration of geologic, climatic and genomic data (i.e. geogenomics) may help clarify origins of divergence in physically complex settings.
ISSN:0305-0270
1365-2699
DOI:10.1111/jbi.14487