Abstract
Early metabolic stress is a key factor influencing long term intergenerational adaptation in organisms. While excessive dietary methionine is known to disrupt one-carbon metabolism, it remains unclear whether early gestational methionine excess induces sustained epigenetic remodeling, thereby affecting redox stability in offspring. Using C. elegans as a model, we demonstrate that early gestational methionine excess in parental induces sustained metabolic stress in offspring, impairing their functional stability. This manifests as impaired motility, shortened lifespan, and elevated oxidative stress levels. Mechanistically, this intergenerational vulnerability is associated with metabolic reprogramming towards a serine-glycine-one-carbon axis. This leads to methyl donor imbalance and chromatin remodeling, characterized by SET-2/WDR-5.1 dependent H3K4 hypermethylation. Meanwhile, the stress response programs of DAF-16/FOXO and SKN-1/Nrf2 are restricted, thus affecting the redox adaptability of the offspring. Importantly, intervention with the dietary polyphenol epigallocatechin gallate (EGCG) can restore metabolic homeostasis and alleviate these chromatin and transcriptional restrictions. In summary, our findings reveal a metabolic and epigenetic framework by which early-life nutritional imbalances influence intergenerational redox resilience. We also emphasize that EGCG represents a potential nutritional strategy to alleviate metabolic stress caused by methionine excess.