Methionine, Not S -adenosylmethionine, Acts as a Primary Metabolic Stress Signal for Chromatin Remodeling

Abstract Epigenetic regulation is tightly linked to cellular metabolism through chromatin-modifying enzymes that depend on central metabolites as co-substrates. Methionine is an essential amino acid that is directly converted by methionine adenosyltransferase 2A (MAT2A) into S -adenosylmethionine (SAM), the universal methyl donor required for histone and DNA methylation. Although methionine restriction/depletion can alter the chromatin methylation landscape and improve physiological outcomes in diverse biological systems, it remains unclear whether these effects arise from loss of methionine itself or from secondary depletion of SAM. Here, we show that methionine depletion induces nuclear accumulation of MAT2A together with redistribution of H3K9 methylation, derepression of transposable elements, activation of stress-response pathways, and broad transcriptional reprogramming. Surprisingly, pharmacologic inhibition reduced intracellular SAM to levels comparable to methionine depletion but failed to reproduce these major epigenetic or transcriptional responses. Furthermore, depletion of the SAM-sensor SAMTOR and inhibition of KDM4 histone demethylases did not prevent methionine-dependent chromatin remodeling, indicating that canonical SAM-sensing pathways are not required for this adaptation. Instead, methionine depletion uniquely induced innate immune and integrated stress-response programs consistent with a viral mimicry-like state. These findings demonstrate that methionine availability, rather than SAM abundance, functions as a primary metabolic signal regulating epigenetic adaptation to nutrient stress. Our data support a model in which methionine is sensed independently of SAM abundance and acts upstream of stress signaling pathways that secondarily remodel chromatin.