In the recent past, insights in post transcriptional regulation of gene expression have profoundly reshaped our understanding of the molecular mechanisms underlying health and disease. This paradigm shift largely stems from the emerging field of epitranscriptomics, which highlights the pivotal role of chemical RNA modifications. While more than 170 distinct chemical modifications on the RNA are known, the m6A modification is the most abundant internal mRNA modification in higher eukaryotic cells, present not only on protein coding transcripts but also on non-coding RNAs, regulated by “writers”, “erasers”, and “readers” that together modulate alternative splicing, nuclear export, translation efficiency, and mRNA stability. This review addresses an important gap by presenting a multilayered regulatory framework that catalogs the full repertoire of m6A machinery and uniquely reveals how non-coding RNAs, transcription factors, histone modifications, and chromatin remodelers governs the spatiotemporal specificity of m6A modification. We explore how dysregulation of m6A modification and its regulatory proteins contribute to the development and progression of various diseases such as cardiovascular disease, neurological disorders, cancer, and type 2 diabetes through context-dependent modulation of gene networks. Furthermore, we present an integrative overview of the therapeutic pipeline, tracing the development of small-molecule inhibitors targeting m6A regulators, thus bridging a crucial link between fundamental mechanisms and new therapies. Overall, this review integrates current findings and emerging insights to provide a comprehensive understanding of m6A biology. By linking upstream regulatory mechanisms with downstream pathological consequences and therapeutic interventions, we highlight the potential of targeting the epitranscriptome for clinical applications.
Kansal et al. (Mon,) studied this question.