Abstract
The one‑carbon metabolism pathway, regulated by the methylenetetrahydrofolate reductase (MTHFR) enzyme, represents a key nexus where genetic predisposition and nutrient status converge to shape the epigenetic landscape of autoimmune diseases. The objective of the present review is to synthesize evidence of how the MTHFR‑folate axis drives epigenomic patterns in these conditions. One of the main diseases involved is rheumatoid arthritis, where drug‑naïve patients show T‑cell and synovial hypomethylation with cytokine‑driven DNMT suppression, a process aggravated by reduced folate availability and MTHFR polymorphisms that constrain S‑adenosylmethionine supply. Similarly, in systemic lupus erythematosus, CD4(+) T cells exhibit global hypomethylation with an interferon‑skewed signature (such as IFI44L), associated with impaired MTHFR activity and a folate‑dependent SAM:SAH imbalance that further diminishes DNMT function. Finally, in celiac disease, intestinal differential methylation, including LINE‑1 hypomethylation, is observed, driven by gluten‑induced villous atrophy and folate malabsorption. Overall, impaired one‑carbon metabolism and MTHFR‑dependent methylation capacity may be key determinants of epigenomic dysfunction underlying autoimmune disease and its clinical severity.17.