N-6-Methyladenosine in Vasoactive microRNAs during Hypoxia; A Novel Role for METTL4

N-6-methyladenosine (m6A) is the most prevalent post-transcriptional RNA modification in eukaryotic cells. The modification is reversible and can be dynamically regulated by writer and eraser enzymes. Alteration in the levels of these enzymes can lead to changes in mRNA stability, alternative splicing or microRNA processing, depending on the m6A-binding proteins. Dynamic regulation of mRNA m6A methylation after ischemia and hypoxia influences mRNA stability, alternative splicing and translation, contributing to heart failure. In this study, we studied vasoactive microRNA m6A methylation in fibroblasts and examined the effect of hypoxia on microRNAs methylation using m6A immunoprecipitation. Of the 19 microRNAs investigated, at least 16 contained m6A in both primary human fibroblasts and a human fibroblast cell line, suggesting vasoactive microRNAs are commonly m6A methylated in fibroblasts. More importantly, we found that mature microRNA m6A levels increased upon subjecting cells to hypoxia. By silencing different m6A writer and eraser enzymes followed by m6A immunoprecipitation, we identified METTL4, an snRNA m6A methyltransferase, to be predominantly responsible for the increase in m6A modification. Moreover, by using m6A-methylated microRNA mimics, we found that microRNA m6A directly affects downstream target mRNA repression efficacy. Our findings highlight the regulatory potential of the emerging field of microRNA modifications.

Automated summary

N-6-methyladenosine (m6A) is a common post-transcriptional RNA modification that can be dynamically regulated by enzymes. This study investigates the role of m6A methylation in fibroblasts, specifically focusing on vasoactive microRNAs. The research found that hypoxia increases m6A levels in mature microRNAs, and METTL4 is the enzyme responsible for this increase. Additionally, the study reveals that microRNA m6A modification directly affects downstream target mRNA repression. These findings highlight the regulatory potential of microRNA modifications.