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Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella

The diverse biology and ecology of marine organisms may lead to complex patterns of intraspecific diversity for both neutral and adaptive genetic variation. Sebastes mentella displays a particular life-history as livebearers, for which existence of multiple ecotypes has been suspected to complicate...

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Autores principales: Saha, Atal, Kent, Matthew, Hauser, Lorenz, Drinan, Daniel P., Nielsen, Einar E., Westgaard, Jon-Ivar, Lien, Sigbjørn, Johansen, Torild
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8158871/
https://www.ncbi.nlm.nih.gov/pubmed/34043665
http://dx.doi.org/10.1371/journal.pone.0251976
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author Saha, Atal
Kent, Matthew
Hauser, Lorenz
Drinan, Daniel P.
Nielsen, Einar E.
Westgaard, Jon-Ivar
Lien, Sigbjørn
Johansen, Torild
author_facet Saha, Atal
Kent, Matthew
Hauser, Lorenz
Drinan, Daniel P.
Nielsen, Einar E.
Westgaard, Jon-Ivar
Lien, Sigbjørn
Johansen, Torild
author_sort Saha, Atal
collection PubMed
description The diverse biology and ecology of marine organisms may lead to complex patterns of intraspecific diversity for both neutral and adaptive genetic variation. Sebastes mentella displays a particular life-history as livebearers, for which existence of multiple ecotypes has been suspected to complicate the genetic population structure of the species. Double digest restriction-site associated DNA was used to investigate genetic population structure in S. mentella and to scan for evidence of selection. In total, 42,288 SNPs were detected in 277 fish, and 1,943 neutral and 97 tentatively adaptive loci were selected following stringent filtration. Unprecedented levels of genetic differentiation were found among the previously defined ‘shallow pelagic’, ‘deep pelagic’ and ‘demersal slope’ ecotypes, with overall mean F(ST) = 0.05 and 0.24 in neutral and outlier SNPs, respectively. Bayesian computation estimated a concurrent and historical divergence among these three ecotypes and evidence of local adaptation was found in the S. mentella genome. Overall, these findings imply that the depth-defined habitat divergence of S. mentella has led to reproductive isolation and possibly adaptive radiation among these ecotypes. Additional sub-structuring was detected within the ‘shallow’ and ‘deep’ pelagic ecotypes. Population assignment of individual fish showed more than 94% agreement between results based on SNP and previously generated microsatellite data, but the SNP data provided a lower estimate of hybridization among the ecotypes than that by microsatellite data. We identified a SNP panel with only 21 loci to discriminate populations in mixed samples based on a machine-learning algorithm. This first SNP based investigation clarifies the population structure of S. mentella, and provides novel and high-resolution genomic tools for future investigations. The insights and tools provided here can readily be incorporated into the management of S. mentella and serve as a template for other exploited marine species exhibiting similar complex life history traits.
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spelling pubmed-81588712021-06-09 Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella Saha, Atal Kent, Matthew Hauser, Lorenz Drinan, Daniel P. Nielsen, Einar E. Westgaard, Jon-Ivar Lien, Sigbjørn Johansen, Torild PLoS One Research Article The diverse biology and ecology of marine organisms may lead to complex patterns of intraspecific diversity for both neutral and adaptive genetic variation. Sebastes mentella displays a particular life-history as livebearers, for which existence of multiple ecotypes has been suspected to complicate the genetic population structure of the species. Double digest restriction-site associated DNA was used to investigate genetic population structure in S. mentella and to scan for evidence of selection. In total, 42,288 SNPs were detected in 277 fish, and 1,943 neutral and 97 tentatively adaptive loci were selected following stringent filtration. Unprecedented levels of genetic differentiation were found among the previously defined ‘shallow pelagic’, ‘deep pelagic’ and ‘demersal slope’ ecotypes, with overall mean F(ST) = 0.05 and 0.24 in neutral and outlier SNPs, respectively. Bayesian computation estimated a concurrent and historical divergence among these three ecotypes and evidence of local adaptation was found in the S. mentella genome. Overall, these findings imply that the depth-defined habitat divergence of S. mentella has led to reproductive isolation and possibly adaptive radiation among these ecotypes. Additional sub-structuring was detected within the ‘shallow’ and ‘deep’ pelagic ecotypes. Population assignment of individual fish showed more than 94% agreement between results based on SNP and previously generated microsatellite data, but the SNP data provided a lower estimate of hybridization among the ecotypes than that by microsatellite data. We identified a SNP panel with only 21 loci to discriminate populations in mixed samples based on a machine-learning algorithm. This first SNP based investigation clarifies the population structure of S. mentella, and provides novel and high-resolution genomic tools for future investigations. The insights and tools provided here can readily be incorporated into the management of S. mentella and serve as a template for other exploited marine species exhibiting similar complex life history traits. Public Library of Science 2021-05-27 /pmc/articles/PMC8158871/ /pubmed/34043665 http://dx.doi.org/10.1371/journal.pone.0251976 Text en https://creativecommons.org/publicdomain/zero/1.0/This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 (https://creativecommons.org/publicdomain/zero/1.0/) public domain dedication.
spellingShingle Research Article
Saha, Atal
Kent, Matthew
Hauser, Lorenz
Drinan, Daniel P.
Nielsen, Einar E.
Westgaard, Jon-Ivar
Lien, Sigbjørn
Johansen, Torild
Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title_full Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title_fullStr Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title_full_unstemmed Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title_short Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella
title_sort hierarchical genetic structure in an evolving species complex: insights from genome wide ddrad data in sebastes mentella
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8158871/
https://www.ncbi.nlm.nih.gov/pubmed/34043665
http://dx.doi.org/10.1371/journal.pone.0251976
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