Mitochondrial genome diversity and population mitogenomics of polar cod (Boreogadus saida) and Arctic dwelling gadoids

High-latitude fish typically exhibit a narrow thermal tolerance window, which may pose challenges when coping with temperatures that shift outside of a species’ range of tolerance. Due to its role in aerobic metabolism and energy balance, the mitochondrial genome is likely critical for the acclimati...

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Bibliographic Details
Published in:Polar biology 2020-08, Vol.43 (8), p.979-994
Main Authors: Wilson, Robert E., Sonsthagen, Sarah A., Smé, Noel, Gharrett, A. J., Majewski, Andrew R., Wedemeyer, Kate, Nelson, R. John, Talbot, Sandra L.
Format: Article
Language:English
Subjects:
Acclimation
Acclimatization
Adaptation
Amino acids
Biological diversity
Biomedical and Life Sciences
Boreogadus saida
Changing environments
Differential thermal analysis
Dispersal
Ecology
Electron transport chain
Eleginus
Energy balance
Energy metabolism
Environmental changes
Environmental conditions
Evolution
Fish
Fishes
Genes
Genetic diversity
Genetic research
Genetic variation
Genomes
Genomics
Life Sciences
Metabolism
Microbiology
Mitochondria
Ocean currents
Oceanography
Oceans
Original Paper
Plant Sciences
Population
Population number
Population studies
Positive selection
Species
Temperature tolerance
Thermal stress
Water temperature
Zoology
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Summary:High-latitude fish typically exhibit a narrow thermal tolerance window, which may pose challenges when coping with temperatures that shift outside of a species’ range of tolerance. Due to its role in aerobic metabolism and energy balance, the mitochondrial genome is likely critical for the acclimation and adaptation to differing temperature regimes in marine ectotherms. As oceans continue to warm, there is growing need to understand the ability of organisms to respond to changing environmental conditions given evidence that some species, in particular cold-water species, may already be experiencing difficulties. To assess how Arctic gadids in Alaska have responded to differential thermal preferences in the past and how regions are interconnected, we sequenced complete mitochondrial genomes for four Arctic gadids to determine the distribution of mitochondrial diversity and population-level structure as well as to detect signatures of selection acting on the mitochondrial genome. We found little population-level structure within all four species with the clear exception of Gulf of Alaska saffron cod ( Eleginus gracilis ). Northern localities exhibited higher levels of genetic diversity and primarily northern lineages were observed within polar cod ( Boreogadus saida ) and saffron cod, likely reflecting asymmetrical dispersal and potentially admixture of distinct lineages via ocean currents. The main evolutionary force shaping the evolution of the mitogenome appears to be purifying selection, but we also identified potential positive selection of candidate amino acid replacements primarily in complex I (ND genes) in polar cod. The high levels of mitochondrial diversity observed in our study and large population size may provide this species with the ability to respond evolutionarily (i.e. long-term) to a changing environment.
ISSN:0722-4060
1432-2056
DOI:10.1007/s00300-020-02703-5