Research
| Title: | Analysis of Multiplicity of Hypoxia-Inducible Factors in the Evolution of Triplophysa Fish (Osteichthyes: Nemacheilinae) Reveals Hypoxic Environments Adaptation to Tibetan Plateau |
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| First author: | Chen, Juan; Shen, Yanjun; Wang, Jing; Ouyang, Gang; Kang, Jingliang; Lv, Wenqi; Yang, Liandong; He, Shunping |
| Journal: | FRONTIERS IN GENETICS |
| Years: | 2020 |
| DOI: | 10.3389/fgene.2020.00433 |
| Abstract: | HIF (Hypoxia-inducible factor) gene family members function as master regulators of cellular and systemic oxygen homeostasis during changes in oxygen availability. Qinghai-Tibet Plateau is a natural laboratory for for long-term hypoxia and cold adaptation. In this context, T. scleroptera that is restricted to >3500 m high-altitude freshwater rivers was selected as the model to compare with a representative species from the plain, P. dabryanus. We cloned different HIF-alpha and carried out a phylogenetic analysis from invertebrates to vertebrates for identifying HIF-alpha genes and analyzing their evolutionary history. Intriguingly, the HIF-alpha has undergone gene duplications might be due to whole-genome duplication (WGD) events during evolution. PAML analysis indicated that HIF-1 alpha A was subjected to positive selection acted on specific sites in Triplophysa lineages. To investigate the relationship between hypoxia adaptation and the regulation of HIF-alpha stability by pVHL in plateau and plain fish, a series of experiments were carried out. Comparison the luciferase transcriptional activity and protein levels of HIF-alpha s and the differing interactions of HIF-alpha s with pVHL, show clear differences between plateau and plain fish. T. scleroptera pVHL could enhance HIF-alpha transcriptional activity under hypoxia, and functional validation through pVHL protein mutagenesis showed that these mutations increased the stability of HIF-alpha and its hetero dimerization affinity to ARNT. Our research shows that missense mutations of pVHL induced evolutionary molecular adaptation in Triplophysa fishes living in high altitude hypoxic environments. |
