Genomic stability through time despite decades of exploitation in cod on both sides of the Atlantic.

The mode and extent of rapid evolution and genomic change in response to human harvesting are key conservation issues. Although experiments and models have shown a high potential for both genetic and phenotypic change in response to fishing, empirical examples of genetic responses in wild population...

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Bibliographic Details
Main Authors: Pinsky, Malin, Eikeset, Anne, Helmerson, Cecilia, Bradbury, Ian, Bentzen, Paul, Morris, Corey, Gondek-Wyrozemska, Agata, Baalsrud, Helle, Brieuc, Marine, Kjesbu, Olav, Godiksen, Jane, Barth, Julia, Matschiner, Michael, Stenseth, Nils, Jakobsen, Kjetill, Jentoft, Sissel, Star, Bastiaan
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2021
Subjects:
fisheries-induced evolution
genetic diversity
historical DNA
population genomics
selective sweeps
Animals
Atlantic Ocean
Biomass
Evolution
Molecular
Gadus morhua
Genomic Instability
Polymorphism
Genetic
Arctic
Canada
Norway
atlantic cod
Newfoundland
Online Access:https://escholarship.org/uc/item/17v1z8pk
Description
Summary:The mode and extent of rapid evolution and genomic change in response to human harvesting are key conservation issues. Although experiments and models have shown a high potential for both genetic and phenotypic change in response to fishing, empirical examples of genetic responses in wild populations are rare. Here, we compare whole-genome sequence data of Atlantic cod (Gadus morhua) that were collected before (early 20th century) and after (early 21st century) periods of intensive exploitation and rapid decline in the age of maturation from two geographically distinct populations in Newfoundland, Canada, and the northeast Arctic, Norway. Our temporal, genome-wide analyses of 346,290 loci show no substantial loss of genetic diversity and high effective population sizes. Moreover, we do not find distinct signals of strong selective sweeps anywhere in the genome, although we cannot rule out the possibility of highly polygenic evolution. Our observations suggest that phenotypic change in these populations is not constrained by irreversible loss of genomic variation and thus imply that former traits could be reestablished with demographic recovery.

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