Genetic diversities of MT-ND1 and MT-ND2 genes are associated with high-altitude adaptation in yak

Abstract

Tibetan yak (Bos grunniens) inhabiting the Qinghai-Tibet Plateau (QTP) where the average altitude is 4000 m, is specially adapted to live at these altitudes. Conversely, cattle (B. taurus) has been found to suffer from high-altitude hypertension or heart failure when exposed to these high altitudes. Two mitochondrial genes, MT-ND1 and MT-ND2, encode two subunits of NADH dehydrogenase play an essential role in the electron transport chain of oxidative phosphorylation (OXPHOS). We sequenced these two mitochondrial genes in two bovine groups (70 Tibetan yaks and 70 Xuanhan cattle) and downloaded 300 sequences of B. taurus (cattle), 93 sequences of B. grunniens (domestic yak), and 2 sequences of B. mutus (wild yak) from NCBI to increase our understanding of the mechanisms of adaptability to hypoxia at high altitudes in yaks compared to cattle. MT-ND1 SNP m.3907 C > T, present in all Tibetan yaks, was positively associated with high-altitude adaptation (p < .0006). Specially, mutation m.3638 A > G present in all cattle, resulting in the termination of transcription, was negatively associated with high-altitude adaptation (p < .0006). Additionally, MT-ND2 SNPs m.4351 G > A and m.5218 C > T also showed positive associations with high-altitude adaptation (p < .0004). MT-ND1 haplotypes H2, H3, H4, H6, and H7 showed positive associations but haplotype H20 had a negative association with high-altitude adaptation (p < .0008). Similarly, MT-ND2 haplotypes Ha1 Ha8, Ha10, and Ha11 were positively associated whereas haplotype Ha2 was negatively associated with adaptability to high-altitudes (p < .0008). Thus, MT-ND1 and MT-ND2 can be considered as candidate genes associated with adaptation to high-altitude environments.

Keywords:

• High-altitude adaptation
• MT-ND1 gene
• MT-ND2 gene
• Tibetan yak

Acknowledgements

This study was financially supported by the 13th Five-Year Breeding Research projects in Sichuan (Grant No. 2016NYZ0046), China Agricultural Research System (Grant No. CARS-44-A-2), and the double-support project of Sichuan Agricultural University.

Disclosure statement

All authors declare to have no conflicts of interest.

Additional information

Funding

This study was financially supported by the 13th Five-Year Breeding Research projects in Sichuan (Grant No. 2016NYZ0046), China Agricultural Research System (Grant No. CARS-44-A-2), and the double-support project of Sichuan Agricultural University.