Genetic Variation in PTPN1 Contributes to Metabolic Adaptation to High-altitude Hypoxia in Tibetan Migratory Locusts

Overview

Journal Nat Commun

Specialty Biology

Date 2018 Nov 28

PMID 30478313

Citations 25

Authors

Ding Ding

Guangjian Liu

Li Hou

Wanying Gui

Bing Chen

Le Kang

Affiliations

Soon will be listed here.

Abstract

Animal and human highlanders have evolved distinct traits to enhance tissue oxygen delivery and utilization. Unlike vertebrates, insects use their tracheal system for efficient oxygen delivery. However, the genetic basis of insect adaptation to high-altitude hypoxia remains unexplored. Here, we report a potential mechanism of metabolic adaptation of migratory locusts in the Tibetan Plateau, through whole-genome resequencing and functional investigation. A genome-wide scan revealed that the positively selected genes in Tibetan locusts are predominantly involved in carbon and energy metabolism. We observed a notable signal of natural selection in the gene PTPN1, which encodes PTP1B, an inhibitor of insulin signaling pathway. We show that a PTPN1 coding mutation regulates the metabolism of Tibetan locusts by mediating insulin signaling activity in response to hypoxia. Overall, our findings provide evidence for the high-altitude hypoxia adaptation of insects at the genomic level and explore a potential regulatory mechanism underlying the evolved metabolic homeostasis.

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