Mitochondrial reactive oxygen species regulate acetyl-CoA flux between cytokine production and fatty acid synthesis in effector T cells.

Genetic and environmental factors shape an individual's susceptibility to autoimmunity. To identify genetic variations regulating effector T cell functions, we used a forward genetics screen of inbred mouse strains and uncovered genomic loci linked to cytokine expression. Among the candidate genes, we characterized a mitochondrial inner membrane protein, TMEM11, as an important determinant of Th1 responses. Loss of TMEM11 selectively impairs Th1 cell functions, reducing autoimmune symptoms in mice. Mechanistically, Tmem11(-/-) Th1 cells exhibit altered cristae architecture, impaired respiration, and increased mitochondrial reactive oxygen species (mtROS) production. Elevated mtROS hindered histone acetylation while promoting neutral lipid accumulation. Further experiments using genetic, biochemical, and pharmacological tools revealed that mtROS regulate acetyl-CoA flux between histone acetylation and fatty acid synthesis. Our findings highlight the role of mitochondrial cristae integrity in directing metabolic pathways that influence chromatin modifications and lipid biosynthesis in Th1 cells, providing new insights into immune cell metabolism.