Metabolic insight into mechanisms of high-altitude adaptation in Tibetans

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• 作者：Ri-Li Ge^a ; ¹ ; Tatum S. Simonson^b ; ¹ ; ² ; Robert C. Cooksey^b ; Uran Tanna^a ; Ga Qin^a ; Chad D. Huff^b ; David J. Witherspoon^b ; Jinchuan Xing^b ; ³ ; Bai Zhengzhong^a ; Josef T. Prchal^b ; Lynn B. Jorde^b ; Donald A. McClain^b ; ^{donald.mcclain@hsc.utah.edu}
• 关键词：Adaptation ; High altitude ; Metabolism
• 刊名：Molecular Genetics and Metabolism
• 出版年：2012
• 出版时间：June, 2012
• 年：2012
• 卷：106
• 期：2
• 页码：244-247
• 全文大小：257 K

文摘

Recent studies have identified genes involved in high-altitude adaptation in Tibetans. Genetic variants/haplotypes within regions containing three of these genes (EPAS1, EGLN1, and PPARA) are associated with relatively decreased hemoglobin levels observed in Tibetans at high altitude, providing corroborative evidence for genetic adaptation to this extreme environment. The mechanisms that afford adaptation to high-altitude hypoxia, however, remain unclear. Considering the strong metabolic demands imposed by hypoxia, we hypothesized that a shift in fuel preference to glucose oxidation and glycolysis at the expense of fatty acid oxidation would improve adaptation to decreased oxygen availability. Correlations between serum free fatty acid and lactate concentrations in Tibetan groups living at high altitude and putatively selected haplotypes provide insight into this hypothesis. An EPAS1 haplotype that exhibits a signal of positive selection is significantly associated with increased lactate concentration, the product of anaerobic glycolysis. Furthermore, the putatively advantageous PPARA haplotype is correlated with serum free fatty acid concentrations, suggesting a possible decrease in the activity of fatty acid oxidation. Although further studies are required to assess the molecular mechanisms underlying these patterns, these associations suggest that genetic adaptation to high altitude involves alteration in energy utilization pathways.