Spatial control of m6A deposition on enhancer and promoter RNAs through co-acetylation of METTL3 and H3K27 on chromatin

The microbiota-m6A-metabolism axis: Implications for therapeutic strategies in gastrointestinal cancers

Gastrointestinal (GI) cancers remain a leading cause of cancer-related mortality worldwide, with metabolic reprogramming recognized as a central driver of tumor progression and therapeutic resistance. Among the key regulatory layers, N6-methyladenosine (m6A) RNA modification-mediated by methyltransferases (writers such as METTL3/14), RNA-binding proteins (readers like YTHDFs and IGF2BPs), and demethylases (erasers including FTO and ALKBH5), plays a pivotal role in controlling gene expression and metabolic flux in the tumor context. Concurrently, the gut microbiota profoundly influences GI tumorigenesis and immune evasion by modulating metabolite availability and remodeling the tumor microenvironment. Recent evidence has uncovered a bidirectional crosstalk between microbial metabolites and m6A methylation: microbiota-derived signals dynamically regulate m6A deposition on metabolic and immune transcripts, while m6A modifications, in turn, regulate the stability and translation of key mRNAs such as PD-L1 and FOXP3. This reciprocal interaction forms self-reinforcing epigenetic circuits that drive tumor plasticity, immune escape, and metabolic adaptation. In this review, we dissect the molecular underpinnings of the microbiota-m6A-metabolism axis in GI cancers and explore its potential to inform novel strategies in immunotherapy, metabolic intervention, and microbiome-guided precision oncology.

Epitranscriptome-epigenome interactions in development and disease mechanisms

Crosstalk between epitranscriptomic modifications to RNA and epigenomic modifications to DNA and histones plays fundamental roles in development and disease. Here, we summarize two major regulatory modes of the crosstalk between the epigenome and epitranscriptome. In the 'cis mode', the crosstalk occurs co-transcriptionally, with direct interactions observed between epigenetic modifications mediated by their regulators. In the 'trans mode', the modification of an epigenetic layer regulates the expression of another epigenetic layer's writers/erasers and subsequently induces downstream epigenetic alteration. Additionally, we focus on the functional roles of the crosstalk mechanism in physiological and pathological contexts, including development, differentiation, cancer, and complex genetic diseases. Lastly, we discuss the potential future directions for a systematic understanding of epigenetic crosstalk in development and disease.