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TRMT1催化的tRNA修饰是氧化还原稳态所必需的,以确保细胞的正常增殖和氧化应激存活。

TRMT1-Catalyzed tRNA Modifications Are Required for Redox Homeostasis To Ensure Proper Cellular Proliferation and Oxidative Stress Survival.

作者信息

Dewe Joshua M, Fuller Benjamin L, Lentini Jenna M, Kellner Stefanie M, Fu Dragony

机构信息

Department of Biology, Center for RNA Biology, University of Rochester, Rochester, New York, USA.

LMU Munich, Department of Chemistry, Munich, Germany.

出版信息

Mol Cell Biol. 2017 Oct 13;37(21). doi: 10.1128/MCB.00214-17. Print 2017 Nov 1.

DOI:10.1128/MCB.00214-17
PMID:28784718
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5640816/
Abstract

Mutations in the tRNA methyltransferase 1 () gene have been identified as the cause of certain forms of autosomal-recessive intellectual disability (ID). However, the molecular pathology underlying ID-associated TRMT1 mutations is unknown, since the biological role of the encoded TRMT1 protein remains to be determined. Here, we have elucidated the molecular targets and function of TRMT1 to uncover the cellular effects of ID-causing TRMT1 mutations. Using human cells that have been rendered deficient in TRMT1, we show that TRMT1 is responsible for catalyzing the dimethylguanosine (m2,2G) base modification in both nucleus- and mitochondrion-encoded tRNAs. TRMT1-deficient cells exhibit decreased proliferation rates, alterations in global protein synthesis, and perturbations in redox homeostasis, including increased endogenous ROS levels and hypersensitivity to oxidizing agents. Notably, ID-causing TRMT1 variants are unable to catalyze the formation of m2,2G due to defects in RNA binding and cannot rescue oxidative stress sensitivity. Our results uncover a biological role for TRMT1-catalyzed tRNA modification in redox metabolism and show that individuals with TRMT1-associated ID are likely to have major perturbations in cellular homeostasis due to the lack of m2,2G modifications.

摘要

已确定tRNA甲基转移酶1(TRMT1)基因突变是某些常染色体隐性智力残疾(ID)的病因。然而,与ID相关的TRMT1突变的分子病理学尚不清楚,因为编码的TRMT1蛋白的生物学作用仍有待确定。在此,我们阐明了TRMT1的分子靶点和功能,以揭示导致ID的TRMT1突变的细胞效应。利用已使TRMT1缺失的人类细胞,我们发现TRMT1负责催化细胞核和线粒体编码的tRNA中的二甲基鸟苷(m2,2G)碱基修饰。TRMT1缺陷细胞表现出增殖速率降低、整体蛋白质合成改变以及氧化还原稳态紊乱,包括内源性ROS水平升高和对氧化剂的超敏反应。值得注意的是,导致ID的TRMT1变体由于RNA结合缺陷而无法催化m2,2G的形成,并且无法挽救氧化应激敏感性。我们的结果揭示了TRMT1催化的tRNA修饰在氧化还原代谢中的生物学作用,并表明与TRMT1相关的ID个体可能由于缺乏m2,2G修饰而在细胞稳态方面存在重大紊乱。

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