Exome Sequencing Reveals Genetic Differentiation Due to High-altitude Adaptation in the Tibetan Cashmere Goat (Capra Hircus)

Overview

Journal BMC Genomics

Publisher Biomed Central

Specialty Genetics

Date 2016 Feb 20

PMID 26892324

Citations 44

Authors

Shen Song

Na Yao

Min Yang

Xuexue Liu

Kunzhe Dong

Qianjun Zhao

Yabin Pu

Xiaohong He

Weijun Guan

Ning Yang

Yuehui Ma

Lin Jiang

Affiliations

Soon will be listed here.

Abstract

Background: The Tibetan cashmere goat (Capra hircus), one of the most ancient breeds in China, has historically been a critical source of meat and cashmere production for local farmers. To adapt to the high-altitude area, extremely harsh climate, and hypoxic environment that the Tibetan cashmere goat lives in, this goat has developed distinct phenotypic traits compared to lowland breeds. However, the genetic components underlying this phenotypic adaptation remain largely unknown.

Results: We obtained 118,700 autosomal SNPs through exome sequencing of 330 cashmere goats located at a wide geographic range, including the Tibetan Plateau and low-altitude regions in China. The great majority of SNPs showed low genetic differentiation among populations; however, approximately 2-3% of the loci showed more genetic differentiation than expected under a selectively neutral model. Together with a combined analysis of high- and low-altitude breeds, we revealed 339 genes potentially under high-altitude selection. Genes associated with cardiovascular system development were significantly enriched in our study. Among these genes, the most evident one was endothelial PAS domain protein 1 (EPAS1), which has been previously reported to be involved in complex oxygen sensing and significantly associated with high-altitude adaptation of human, dog, and grey wolf. The missense mutation Q579L that we identified in EPAS1, which occurs next to the Hypoxia-Inducible Factor-1 (HIF-1) domain, was exclusively enriched in the high-altitude populations.

Conclusions: Our study provides insights concerning the population variation in six different cashmere goat populations in China. The variants in cardiovascular system-related genes may explain the observed phenotypic adaptation of the Tibetan cashmere goat.

Citing Articles

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