Coordinated histone methylation loss and MYC activation promote translational capacity under amino acid restriction.

Background: Cells adapt to nutrient fluctuations through both signaling and epigenetic mechanisms. While amino acid (AA) deprivation is known to suppress protein synthesis via mTORC1 inactivation, the epigenetic pathways that support cellular adaptation and recovery remain poorly understood. We investigated how chromatin and transcriptional changes contribute to maintaining translational capacity during AA restriction and priming cells for growth upon AA repletion.

Methods: Human cells were cultured under amino acid-replete or -depleted conditions, and global histone methylation levels were assessed by Western blotting and ChIP-seq. RNA-seq and chromatin-associated RNA-seq (chromRNA-seq) were used to evaluate gene expression and transcriptional output. Ribosome profiling and [³⁵S]-methionine/cysteine or O-propargyl-puromycin (OPP) incorporation assays measured protein synthesis. Functional contributions of SETD8 and MYC were tested through knockdown and overexpression experiments.

Results: AA deprivation induced a selective, genome-wide loss of H4K20me1, particularly from gene bodies, and led to increased MYC expression and binding at promoter regions. These changes were most pronounced at genes encoding ribosomal proteins and translation initiation factors. Although overall protein synthesis declined during AA restriction, these cells showed increased translational capacity evidenced by accumulation of monomeric ribosomes and enhanced translation upon AA repletion. Loss of H4K20me1 was independent of mTORC1 signaling and partly driven by SETD8 protein downregulation. While MYC overexpression alone was insufficient to upregulate translation-related genes, its combination with SETD8 knockdown in nutrient-rich conditions was both necessary and sufficient to induce expression of these genes and enhance protein synthesis.

Conclusions: Our findings reveal a chromatin-based mechanism by which cells integrate metabolic status with transcriptional regulation to adapt to amino acid limitation. Loss of H4K20me1 and increased MYC activity act in parallel to prime the translational machinery during AA deprivation, enabling rapid recovery of protein synthesis upon nutrient restoration. This mechanism may help explain how cells maintain competitive growth potential under fluctuating nutrient conditions and has implications for understanding MYC-driven cancer progression.