Genomic vulnerability of a freshwater salmonid under climate change

• Published in: Evolutionary applications Vol. 17; no. 2; pp. e13602 - n/a
• Main Authors: Tigano, Anna, Weir, Tyler, Ward, Hillary G. M., Gale, Marika Kirstin, Wong, Carmen M., Eliason, Erika J., Miller, Kristina M., Hinch, Scott G., Russello, Michael A.
• Format: Journal Article
• Language: English
• Published: England John Wiley & Sons, Inc 01.02.2024; Wiley
• Subjects: Adaptation; Biodiversity; Climate change; climate vulnerability; Creeks & streams; Economic importance; Endangered & extinct species; Environmental changes; Fisheries management; Genetic analysis; Genetic diversity; Genomes; Genomics; Genotypes; Lakes; local adaptation; Oncorhynchus nerka; Pacific salmon; Population viability; Salmon; standing variation; structural variants; Water temperature; British Columbia Canada; Canada; structural variants; local adaptation; Pacific salmon; climate vulnerability; standing variation
• ISSN: 1752-4571; 1752-4571
• DOI: 10.1111/eva.13602

Understanding the adaptive potential of populations and species is pivotal for minimizing the loss of biodiversity in this era of rapid climate change. Adaptive potential has been estimated in various ways, including based on levels of standing genetic variation, presence of potentially beneficial alleles, and/or the severity of environmental change. Kokanee salmon, the non‐migratory ecotype of sockeye salmon (Oncorhynchus nerka), is culturally and economically important and has already been impacted by the effects of climate change. To assess its climate vulnerability moving forward, we integrated analyses of standing genetic variation, genotype‐environment associations, and climate modeling based on sequence and structural genomic variation from 224 whole genomes sampled from 22 lakes in British Columbia and Yukon (Canada). We found that variables for extreme temperatures, particularly warmer temperatures, had the most pervasive signature of selection in the genome and were the strongest predictors of levels of standing variation and of putatively adaptive genomic variation, both sequence and structural. Genomic offset estimates, a measure of climate vulnerability, were significantly correlated with higher increases in extreme warm temperatures, further highlighting the risk of summer heat waves that are predicted to increase in frequency in the future. Levels of standing genetic variation, an important metric for population viability and resilience, were not correlated with genomic offset. Nonetheless, our combined approach highlights the importance of integrating different sources of information and genomic data to formulate more comprehensive and accurate predictions on the vulnerability of populations and species to future climate change.