Consequences of domestication in eastern oyster: Insights from whole genomic analyses

Honggang Zhao; Ximing Guo; Wenlu Wang; Zhenwei Wang; Paul Rawson; Ami Wilbur; Matthew Hare

doi:10.1111/eva.13710

Evolutionary Applications (Jun 2024)

Consequences of domestication in eastern oyster: Insights from whole genomic analyses

Honggang Zhao,
Ximing Guo,
Wenlu Wang,
Zhenwei Wang,
Paul Rawson,
Ami Wilbur,
Matthew Hare

Affiliations

Honggang Zhao: Department of Natural Resources & the Environment Cornell University Ithaca New York USA
Ximing Guo: Haskin Shellfish Research Laboratory Rutgers University Port Norris New Jersey USA
Wenlu Wang: Department of Computer Sciences Texas A&M University‐Corpus Christi Corpus Christi Texas USA
Zhenwei Wang: Haskin Shellfish Research Laboratory Rutgers University Port Norris New Jersey USA
Paul Rawson: School of Marine Sciences University of Maine Orono Maine USA
Ami Wilbur: Shellfish Research Hatchery, Center for Marine Science University of North Carolina Wilmington Wilmington North Carolina USA
Matthew Hare: Department of Natural Resources & the Environment Cornell University Ithaca New York USA

DOI: https://doi.org/10.1111/eva.13710
Journal volume & issue: Vol. 17, no. 6
pp. n/a – n/a

Abstract

Read online

Abstract Selective breeding for production traits has yielded relatively rapid successes with high‐fecundity aquaculture species. Discovering the genetic changes associated with selection is an important goal for understanding adaptation and can also facilitate better predictions about the likely fitness of selected strains if they escape aquaculture farms. Here, we hypothesize domestication as a genetic change induced by inadvertent selection in culture. Our premise is that standardized culture protocols generate parallel domestication effects across independent strains. Using eastern oyster as a model and a newly developed 600K SNP array, this study tested for parallel domestication effects in multiple independent selection lines compared with their progenitor wild populations. A single contrast was made between pooled selected strains (1–17 generations in culture) and all wild progenitor samples combined. Population structure analysis indicated rank order levels of differentiation as [wild − wild] < [wild − cultured] < [cultured − cultured]. A genome scan for parallel adaptation to the captive environment applied two methodologically distinct outlier tests to the wild versus selected strain contrast and identified a total of 1174 candidate SNPs. Contrasting wild versus selected strains revealed the early evolutionary consequences of domestication in terms of genomic differentiation, standing genetic diversity, effective population size, relatedness, runs of homozygosity profiles, and genome‐wide linkage disequilibrium patterns. Random Forest was used to identify 37 outlier SNPs that had the greatest discriminatory power between bulked wild and selected oysters. The outlier SNPs were in genes enriched for cytoskeletal functions, hinting at possible traits under inadvertent selection during larval culture or pediveliger setting at high density. This study documents rapid genomic changes stemming from hatchery‐based cultivation of eastern oysters, identifies candidate loci responding to domestication in parallel among independent aquaculture strains, and provides potentially useful genomic resources for monitoring interbreeding between farm and wild oysters.

Published in Evolutionary Applications

ISSN: 1752-4571 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Biology (General): Evolution
Website: https://onlinelibrary.wiley.com/journal/17524571

About the journal

Abstract

Keywords