Chromosomal fusion and life history‐associated genomic variation contribute to within‐river local adaptation of Atlantic salmon

Chromosomal inversions have been implicated in facilitating adaptation in the face of high levels of gene flow, but whether chromosomal fusions also have similar potential remains poorly understood. Atlantic salmon are usually characterized by population structure at multiple spatial scales; however...

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Bibliographic Details
Published in:Molecular ecology 2019-03, Vol.28 (6), p.1439-1459
Main Authors: Wellband, Kyle, Mérot, Claire, Linnansaari, Tommi, Elliott, J. A. K., Curry, R. Allen, Bernatchez, Louis
Format: Article
Language:English
Subjects:
Adaptation
Atlantic salmon
chromosomal fusion
Chromosome 9
Chromosomes
Divergence
Fish
Gene flow
Heterozygosity
Inversions
Life history
local adaptation
Polygenic inheritance
Population genetics
Population structure
Populations
Rivers
Salmo salar
Salmon
Single-nucleotide polymorphism
SIX gene family
six6
Structural hierarchy
structural variation
Tributaries
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Summary:Chromosomal inversions have been implicated in facilitating adaptation in the face of high levels of gene flow, but whether chromosomal fusions also have similar potential remains poorly understood. Atlantic salmon are usually characterized by population structure at multiple spatial scales; however, this is not the case for tributaries of the Miramichi River in North America. To resolve genetic relationships between populations in this system and the potential for known chromosomal fusions to contribute to adaptation, we genotyped 728 juvenile salmon using a 50 K SNP array. Consistent with previous work, we report extremely weak overall population structuring (Global FST = 0.004) and failed to support hierarchical structure between the river's two main branches. We provide the first genomic characterization of a previously described polymorphic fusion between chromosomes 8 and 29. Fusion genomic characteristics included high LD, reduced heterozygosity in the fused homokaryotes, and strong divergence between the fused and the unfused rearrangement. Population structure based on fusion karyotype was five times stronger than neutral variation (FST = 0.019), and the frequency of the fusion was associated with summer precipitation supporting a hypothesis that this rearrangement may contribute local adaptation despite weak neutral differentiation. Additionally, both outlier variation among populations and a polygenic framework for characterizing adaptive variation in relation to climate identified a 250‐Kb region of chromosome 9, including the gene six6 that has previously been linked to age‐at‐maturity and run‐timing for this species. Overall, our results indicate that adaptive processes, independent of major river branching, are more important than neutral processes for structuring these populations.
ISSN:0962-1083
1365-294X
DOI:10.1111/mec.14965