Genomic architecture underlying morphological and physiological adaptation to high elevation in a songbird

Organisms often acquire physiological and morphological modifications to conquer ecological challenges when colonizing new environments which lead to their adaptive evolution. However, deciphering the genomic mechanism of ecological adaptation is difficult because ecological environments are often t...

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Bibliographic Details
Published in:Molecular ecology 2023-05, Vol.32 (9), p.2234-2251
Main Authors: Lu, Chia‐Wei, Huang, Shih‐Ting, Cheng, Shun‐Jen, Lin, Chen‐Tau, Hsu, Yu‐Cheng, Yao, Cheng‐Te, Dong, Feng, Hung, Chih‐Ming, Kuo, Hao‐Chih
Format: Article
Language:English
Subjects:
Adaptation
Adaptation, Physiological - genetics
Allen's rule
altitudinal adaptation
Animals
beak morphology
Beaks
Cerebrum
chromosomal inversion
Collagen (type IX)
Divergence
Ecological adaptation
Ecology
Elevation
Evolution & development
Gene flow
Genes
Genome - genetics
genome sequencing
Genomics
Hypoxia
Inversions
Low temperature
Morphology
Mutation
Passeriformes - genetics
Physiological adaptation
Physiology
Plumage
Populations
Songbirds
Songbirds - genetics
Ultraviolet radiation
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Summary:Organisms often acquire physiological and morphological modifications to conquer ecological challenges when colonizing new environments which lead to their adaptive evolution. However, deciphering the genomic mechanism of ecological adaptation is difficult because ecological environments are often too complex for straightforward interpretation. Thus, we examined the adaptation of a widespread songbird—the rufous‐capped babbler (Cyanoderma ruficeps)—to a relatively simple system: distinct environments across elevational gradients on the mountainous island of Taiwan. We focused on the genomic sequences of 43 birds from five populations to show that the Taiwan group split from its sister group in mainland China around 1–2 million years ago (Ma) and colonized the montane habitats of Taiwan at least twice around 0.03–0.22 Ma. The montane and lowland Taiwan populations diverged with gene flow between them, suggesting strong selection associated with different elevations. We found that the montane babblers had smaller beaks than the lowland ones, consistent with Allen's rule, and identified candidate genes—COL9A1 and SOX11—underlying the beak size changes. We also found that altitudinally divergent mutations were mostly located in noncoding regions and tended to accumulate in chromosomal inversions and autosomes. The altitudinally divergent mutations might regulate genes related to haematopoietic, metabolic, immune, auditory and vision functions, as well as cerebrum morphology and plumage development. The results reveal the genomic bases of morphological and physiological adaptation in this species to the low temperature, hypoxia and high UV light environment at high elevation. These findings improve our understanding of how ecological adaptation drives population divergence from the perspective of genomic architecture.
ISSN:0962-1083
1365-294X
DOI:10.1111/mec.16875