3′-Terminal 2′-O-methylation of lung cancer miR-21-5p enhances its stability and association with Argonaute 2

Hongwei Liang; Zichen Jiao; Weiwei Rong; Shuang Qu; Zhicong Liao; Xinlei Sun; Wei Yao; Quan Zhao; Jun Wang; Yuan Liu; Xi Chen; Tao Wang; Chen‐Yu Zhang; Ke Zen

doi:10.1093/nar/gkaa504

3′-Terminal 2′-O-methylation of lung cancer miR-21-5p enhances its stability and association with Argonaute 2

Hongwei Liang(Nanjing Drum Tower Hospital), Zichen Jiao(Nanjing Drum Tower Hospital), Weiwei Rong(Nanjing Drum Tower Hospital), Shuang Qu(Nanjing Drum Tower Hospital), Zhicong Liao(Nanjing Drum Tower Hospital), Xinlei Sun(Nanjing Drum Tower Hospital), Wei Yao(Nanjing Drum Tower Hospital), Quan Zhao(Nanjing Drum Tower Hospital), Jun Wang(Nanjing Drum Tower Hospital), Yuan Liu(Georgia State University), Xi Chen(Nanjing Drum Tower Hospital), Tao Wang(Nanjing Drum Tower Hospital), Chen‐Yu Zhang(Nanjing Drum Tower Hospital), Ke Zen(Nanjing Drum Tower Hospital)

Nucleic Acids Research

June 4, 2020

10.1093/nar/gkaa504

Cited by 76Open Access

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Abstract

Methylation of miRNAs at the 2'-hydroxyl group on the ribose at 3'-end (2'-O-methylation, 2'Ome) is critical for miRNA function in plants and Drosophila. Whether this methylation phenomenon exists for mammalian miRNA remains unknown. Through LC-MS/MS analysis, we discover that majority of miR-21-5p isolated from human non-small cell lung cancer (NSCLC) tissue possesses 3'-terminal 2'Ome. Predominant 3'-terminal 2'Ome of miR-21-5p in cancer tissue is confirmed by qRT-PCR and northern blot after oxidation/β-elimination procedure. Cancerous and the paired non-cancerous lung tissue miRNAs display different pattern of 3'-terminal 2'Ome. We further identify HENMT1 as the methyltransferase responsible for 3'-terminal 2'Ome of mammalian miRNAs. Compared to non-methylated miR-21-5p, methylated miR-21-5p is more resistant to digestion by 3'→5' exoribonuclease polyribonucleotide nucleotidyltransferase 1 (PNPT1) and has higher affinity to Argonaute-2, which may contribute to its higher stability and stronger inhibition on programmed cell death protein 4 (PDCD4) translation, respectively. Our findings reveal HENMT1-mediated 3'-terminal 2'Ome of mammalian miRNAs and highlight its role in enhancing miRNA's stability and function.

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