Functional and Adaptive Significance of Promoter Mutations That Affect Divergent Myocardial Expressions of TRIM72 in Primates

Overview

Journal Mol Biol Evol

Publisher Oxford University Press

Specialty Biology

Date 2021 Mar 21

PMID 33744959

Citations 1

Authors

Yuanqing Feng

Hongzhan Xu

Jinghao Liu

Ning Xie

Lei Gao

Yanyun He

Yuan Yao

Fengxiang Lv

Yan Zhang

Jian Lu

Wei Zhang

Chuan-Yun Li

Xinli Hu

Ziheng Yang

Rui-Ping Xiao

Affiliations

Soon will be listed here.

Abstract

Cis-regulatory elements play important roles in tissue-specific gene expression and in the evolution of various phenotypes, and mutations in promoters and enhancers may be responsible for adaptations of species to environments. TRIM72 is a highly conserved protein that is involved in energy metabolism. Its expression in the heart varies considerably in primates, with high levels of expression in Old World monkeys and near absence in hominids. Here, we combine phylogenetic hypothesis testing and experimentation to demonstrate that mutations in promoter are responsible for the differences among primate species in the heart-specific expression of TRIM72. Maximum likelihood estimates of lineage-specific substitution rates under local-clock models show that relative to the evolutionary rate of introns, the rate of promoter was accelerated by 78% in the common ancestor of Old World monkeys, suggesting a role for positive selection in the evolution of the TRIM72 promoter, possibly driven by selective pressure due to changes in cardiac physiology after species divergence. We demonstrate that mutations in the TRIM72 promoter account for the differential myocardial TRIM72 expression of the human and the rhesus macaque. Furthermore, changes in TRIM72 expression alter the expression of genes involved in oxidative phosphorylation, which in turn affects mitochondrial respiration and cardiac energy capacity. On a broader timescale, phylogenetic regression analyses of data from 29 mammalian species show that mammals with high cardiac expression of TRIM72 have high heart rate, suggesting that the expression changes of TRIM72 may be related to differences in the heart physiology of those species.

Citing Articles

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PMID: 37112854 PMC: 10145180. DOI: 10.3390/v15040875.

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