Metabolic rewiring during bone development underlies tRNA m7G–associated primordial dwarfism

• Published in: The Journal of clinical investigation Vol. 134; no. 20; pp. 1 - 17
• Main Authors: Li, Qiwen, Jiang, Shuang, Lei, Kexin, Han, Hui, Chen, Yaqian, Lin, Weimin, Xiong, Qiuchan, Qi, Xingying, Gan, Xinyan, Sheng, Rui, Wang, Yuan, Zhang, Yarong, Ma, Jieyi, Li, Tao, Lin, Shuibin, Zhou, Chenchen, Chen, Demeng, Yuan, Quan
• Format: Journal Article
• Language: English
• Published: United States American Society for Clinical Investigation 10.09.2024
• Subjects: Amino acids; Apoptosis; Bone growth; Bone marrow; Bone mass; Cartilage; Cellular stress response; Clonal deletion; Cytoskeleton; Dwarfism; Endochondral bone; Energy metabolism; Gene deletion; Intracellular signalling; Ketoglutaric acid; Metabolism; Missense mutation; mRNA stability; Osteogenesis; Postpartum period; Protein structure; Protein synthesis; Protein turnover; Proteins; Quality control; Rapamycin; Stem cells; Structure-function relationships; TOR protein; Transaminase; Transfer RNA; Translation initiation; tRNA; tRNA Ala; Bone biology; Translation; Metabolism; Bone development
• ISSN: 1558-8238; 0021-9738; 1558-8238
• DOI: 10.1172/JCI177220

Translation of mRNA to protein is tightly regulated by tRNAs, which are subject to various chemical modifications that maintain the structure, stability and function. Deficiency of tRNA N7-methylguanosine (m7G) modification in patients causes a type of primordial dwarfism, but the underlying mechanism remains unknown. Here we report the loss of m7G rewires cellular metabolism, leading to the pathogenesis of primordial dwarfism. Conditional deletion of the catalytic enzyme Mettl1 or missense mutation of the scaffold protein Wdr4 severely impaired endochondral bone formation and bone mass accrual. Mechanistically, Mettl1 knockout decreased abundance of m7G-modified tRNAs and inhibited translation of mRNAs relating to cytoskeleton and Rho GTPase signaling. Meanwhile, Mettl1 knockout enhanced cellular energy metabolism despite of incompetent proliferation and osteogenic commitment. Further exploration revealed that impaired Rho GTPase signaling upregulated branched-chain amino acid transaminase 1 (BCAT1) level that rewired cell metabolism and restricted intracellular α-ketoglutarate (αKG). Supplementation of αKG ameliorated the skeletal defect of Mettl1-deficient mice. In addition to the selective translation of metabolism-related mRNAs, we further revealed that Mettl1 knockout globally regulated translation via integrated stress response (ISR) and mammalian target of rapamycin complex 1 (mTORC1) signaling. Restoring translation either by targeting ISR or mTORC1 aggravated bone defects of Mettl1-deficient mice. Overall, our study unveils a critical role of m7G tRNA modification in bone development by regulating cellular metabolism, and indicates that suspension of translation initiation as quality control mechanism in response to tRNA dysregulation.