TY - JOUR
T1 - Parallel genomic responses to historical climate change and high elevation in East Asian songbirds
AU - Cheng, Yalin
AU - Miller, Matthew J.
AU - Zhang, Dezhi
AU - Xiong, Ying
AU - Hao, Yan
AU - Jia, Chenxi
AU - Cai, Tianlong
AU - Li, Shou Hsien
AU - Johansson, Ulf S.
AU - Liu, Yang
AU - Chang, Yongbin
AU - Song, Gang
AU - Qu, Yanhua
AU - Lei, Fumin
N1 - Publisher Copyright:
© 2021 National Academy of Sciences. All rights reserved.
PY - 2021/12/14
Y1 - 2021/12/14
N2 - Parallel evolution can be expected among closely related taxa exposed to similar selective pressures. However, parallelism is typically stronger at the phenotypic level, while genetic solutions to achieve these phenotypic similarities may differ. For polygenic traits, the availability of standing genetic variation (i.e., heterozygosity) may influence such genetic nonparallelism. Here, we examine the extent to which high-elevation adaptation is parallel—and whether the level of parallelism is affected by heterozygosity—by analyzing genomes of 19 Paridae species distributed across East Asia with a dramatic east–west elevation gradient. We find that western highlands endemic parids have consistently lower levels of heterozygosity—likely the result of late-Pleistocene demographic contraction—than do parids found exclusively in eastern lowlands, which remained unglaciated during the late Pleistocene. Three widespread species (east to west) have high levels of heterozygosity similar to that observed in eastern species, although their western populations are less variable than eastern ones. Comparing genomic responses to extreme environments of the Qinghai–Tibet Plateau, we find that the most differentiated genomic regions between each high-elevation taxon and its low-elevation relative are significantly enriched for genes potentially related to the oxygen transport cascade and/or thermogenesis. Despite no parallelism at particular genes, high similarity in gene function is found among comparisons. Furthermore, parallelism is not higher in more heterozygous widespread parids than in highland endemics. Thus, in East Asian parids, parallel functional response to extreme elevation appears to rely on different genes, with differences in heterozygosity having no effect on the degree of genetic parallelism.
AB - Parallel evolution can be expected among closely related taxa exposed to similar selective pressures. However, parallelism is typically stronger at the phenotypic level, while genetic solutions to achieve these phenotypic similarities may differ. For polygenic traits, the availability of standing genetic variation (i.e., heterozygosity) may influence such genetic nonparallelism. Here, we examine the extent to which high-elevation adaptation is parallel—and whether the level of parallelism is affected by heterozygosity—by analyzing genomes of 19 Paridae species distributed across East Asia with a dramatic east–west elevation gradient. We find that western highlands endemic parids have consistently lower levels of heterozygosity—likely the result of late-Pleistocene demographic contraction—than do parids found exclusively in eastern lowlands, which remained unglaciated during the late Pleistocene. Three widespread species (east to west) have high levels of heterozygosity similar to that observed in eastern species, although their western populations are less variable than eastern ones. Comparing genomic responses to extreme environments of the Qinghai–Tibet Plateau, we find that the most differentiated genomic regions between each high-elevation taxon and its low-elevation relative are significantly enriched for genes potentially related to the oxygen transport cascade and/or thermogenesis. Despite no parallelism at particular genes, high similarity in gene function is found among comparisons. Furthermore, parallelism is not higher in more heterozygous widespread parids than in highland endemics. Thus, in East Asian parids, parallel functional response to extreme elevation appears to rely on different genes, with differences in heterozygosity having no effect on the degree of genetic parallelism.
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U2 - 10.1073/pnas.2023918118
DO - 10.1073/pnas.2023918118
M3 - Article
C2 - 34873033
AN - SCOPUS:85121423015
SN - 0027-8424
VL - 118
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 50
M1 - e2023918118
ER -