Markhor-derived Introgression of a Genomic Region Encompassing PAPSS2 Confers High-altitude Adaptability in Tibetan Goats

Overview

Journal Mol Biol Evol

Publisher Oxford University Press

Specialty Biology

Date 2022 Nov 16

PMID 36382357

Authors

Chao Li

Yujiang Wu

Bingchun Chen

Yudong Cai

Jiazhong Guo

Alexander S Leonard

Peter Kalds

Shiwei Zhou

Jingchen Zhang

Ping Zhou

Shangqu Gan

Ting Jia

Tianchun Pu

Langda Suo

Yan Li

Ke Zhang

Lan Li

Myagmarsuren Purevdorj

Xihong Wang

Ming Li

Yu Wang

Yao Liu

Shuhong Huang

Tad Sonstegard

Ming-Shan Wang

Stephen Kemp

Hubert Pausch

Yulin Chen

Jian-Lin Han

Yu Jiang

Xiaolong Wang

Affiliations

Soon will be listed here.

Abstract

Understanding the genetic mechanism of how animals adapt to extreme conditions is fundamental to determine the relationship between molecular evolution and changing environments. Goat is one of the first domesticated species and has evolved rapidly to adapt to diverse environments, including harsh high-altitude conditions with low temperature and poor oxygen supply but strong ultraviolet radiation. Here, we analyzed 331 genomes of domestic goats and wild caprid species living at varying altitudes (high > 3000 m above sea level and low < 1200 m), along with a reference-guided chromosome-scale assembly (contig-N50: 90.4 Mb) of a female Tibetan goat genome based on PacBio HiFi long reads, to dissect the genetic determinants underlying their adaptation to harsh conditions on the Qinghai-Tibetan Plateau (QTP). Population genomic analyses combined with genome-wide association studies (GWAS) revealed a genomic region harboring the 3'-phosphoadenosine 5'-phosphosulfate synthase 2 (PAPSS2) gene showing strong association with high-altitude adaptability (PGWAS = 3.62 × 10-25) in Tibetan goats. Transcriptomic data from 13 tissues revealed that PAPSS2 was implicated in hypoxia-related pathways in Tibetan goats. We further verified potential functional role of PAPSS2 in response to hypoxia in PAPSS2-deficient cells. Introgression analyses suggested that the PAPSS2 haplotype conferring the high-altitude adaptability in Tibetan goats originated from a recent hybridization between goats and a wild caprid species, the markhor (Capra falconeri). In conclusion, our results uncover a hitherto unknown contribution of PAPSS2 to high-altitude adaptability in Tibetan goats on QTP, following interspecific introgression and natural selection.

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