N6-methyladenosine (m⁶A) RNA modification has emerged as a pivotal epigenetic regulator that intricately controls gene expression and profoundly influences cancer biology. Recent work by a team of researchers led by Professors Zili Zhang and Mei Guo at Nanjing University of Chinese Medicine presents a comprehensive synthesis of the dualistic and complex roles m⁶A methylation plays in tumor progression and suppression. This groundbreaking review navigates the multifaceted regulatory dynamics of m⁶A, highlighting its indispensable function in RNA metabolism and its far-reaching implications in oncogenesis, therapy resistance, and emerging targeted therapeutics.
At the molecular level, m⁶A is a widespread internal modification on messenger RNA (mRNA) critical for fine-tuning gene expression post-transcriptionally. Through an elaborate interplay of enzymatic complexes known as “writers,” “erasers,” and “readers,” m⁶A orchestrates fundamental RNA processes such as splicing, stability, transport, translation efficiency, and degradation. The “writers,” mainly methyltransferase-like proteins METTL3 and METTL14, catalyze the methylation of adenosine residues, while “erasers” like FTO and ALKBH5 demethylate these modifications dynamically. “Readers,” including the YTH domain-containing proteins and IGF2BP family, recognize m⁶A marks and guide the fate of modified transcripts, thus establishing a sophisticated regulatory network that can either promote or inhibit oncogenic pathways.
The review dissects how aberrant expression and mutation of these m⁶A regulators disrupt normal RNA metabolism, often tipping the scale towards tumorigenesis. For instance, overexpression of METTL3 is frequently observed to drive malignant transformation by stabilizing oncogene transcripts and enhancing pro-tumorigenic pathways. Conversely, underexpression of erasers like FTO can lead to increased methylation and repression of tumor suppressor genes. This paradoxical impact underscores the nuanced and context-dependent nature of m⁶A modifications across diverse cancer types, contributing to hallmark traits such as unchecked cellular proliferation, evasion of apoptosis, enhanced metastatic potential, and neoangiogenesis.
A particularly striking aspect emphasized in this research is m⁶A’s definitive role in modulating cancer stem cell properties and immune evasion mechanisms. By regulating stability and translation of transcripts encoding stemness factors and immunomodulatory molecules, m⁶A shapes the tumor microenvironment and influences interactions with immune cells. This insight opens new avenues to understand why certain tumors develop resistance to conventional therapies and immune checkpoint blockade, positioning m⁶A as a nexus of immune escape and therapeutic failure.
Moreover, the authors present compelling evidence of m⁶A’s involvement in metabolic reprogramming within tumors. Altered m⁶A patterns affect key enzymes and regulatory RNAs governing metabolic pathways, thereby fine-tuning the adaptation of cancer cells to nutrient-deprived and hypoxic microenvironments. Such metabolic plasticity, driven by epitranscriptomic modifications, equips tumors with enhanced survival capabilities, further complicating treatment outcomes.
From a clinical perspective, the review amplifies the diagnostic and prognostic significance of m⁶A machinery. Aberrant expression profiles of writers, erasers, and readers are increasingly associated with disease progression and patient survival in malignancies such as colorectal carcinoma, hepatocellular carcinoma, and acute myeloid leukemia. Profiling m⁶A regulators thus holds promise as a biomarker framework for early cancer detection and prognosis stratification, potentially revolutionizing personalized oncology.
On the therapeutic front, this research spotlights innovative approaches that target the m⁶A modification landscape. Small-molecule inhibitors, such as STM2457 targeting METTL3 and FB23-2 aimed at FTO, have demonstrated potent antitumor activity by disrupting aberrant methylation signaling. Additionally, RNA-based technologies like CRISPR-dCas13-mediated m⁶A editing introduce a transformative method for locus-specific epitranscriptomic modulation, offering highly precise and reversible intervention strategies.
Combination therapies integrating m⁶A modulation with chemotherapy, radiotherapy, and immunotherapy represent a burgeoning frontier to overcome resistance mechanisms. These synergistic regimens leverage the epigenetic plasticity conferred by m⁶A alterations to sensitize tumors, enhance immune surveillance, and potentiate cytotoxic effects. Clinical trials investigating these combinations could redefine the therapeutic landscape for refractory cancers.
Personalized medicine also stands to benefit immensely from m⁶A research. The dynamic and individualized m⁶A methylation patterns in tumors suggest that patient-specific epitranscriptomic profiling could tailor treatment decisions optimally. Emerging liquid biopsy techniques to monitor circulating m⁶A marks and regulators might enable real-time assessment of therapeutic efficacy and disease progression, thus fine-tuning patient management in a non-invasive manner.
Despite the revolutionary potential, challenges remain regarding the complexity of m⁶A regulatory networks and the risk of systemic side effects given the modification’s ubiquity in normal biology. The pharmacodynamics and delivery systems of m⁶A-targeted therapies require refinement to ensure selectivity and minimize off-target impacts. Continued interdisciplinary research integrating molecular biology, medicinal chemistry, and clinical oncology is critical to translate these insights into safe and effective treatments.
Ultimately, the review by Zhang, Guo, and colleagues decisively establishes m⁶A methylation not merely as a molecular hallmark of cancer but as a central epigenetic orchestrator with vast diagnostic, prognostic, and therapeutic implications. This epitranscriptomic modification emerges as a compelling frontier, heralding a new era of RNA-targeted precision oncology that could reshape how we understand and combat cancer in the coming decades.
Subject of Research:
Article Title: The m⁶A modification in cancer: roles, implications, and its potential in therapy
News Publication Date: 23-Sep-2025
Web References: http://dx.doi.org/10.1186/s43556-025-00314-2
Image Credits: Mei Guo
Keywords: m⁶A, epitranscriptomics, RNA modification, cancer biology, METTL3, FTO, RNA methylation, cancer stem cells, immune evasion, targeted therapy, CRISPR-dCas13, personalized medicine
