Abstract
Mitochondrial DNA (mtDNA) is highly polymorphic, and host mtDNA variation has been associated with altered cancer severity. To determine the basis of this mtDNA-cancer association, we analyzed conplastic mice with the C57BL/6J (B6) nucleus but two naturally occurring mtDNA lineages, mtDNA(B6) and mtDNA(NZB), where mtDNA(NZB) mitochondria generate more oxidative phosphorylation (OXPHOS)-derived reactive oxygen species (mROS). In a cardiac transplant model, mtDNA(B6) Foxp3+ T regulatory (Treg) cells supported long-term allograft survival, whereas mtDNA(NZB) Treg cells failed to suppress host T effector (Teff) cells, leading to acute rejection. When challenged with melanoma or colon cancer cells, the mtDNA(NZB) mice exhibited strikingly impaired tumor growth while mtDNA(B6) mice showed Treg-dependent inhibition of Teff cells and allowed rapid tumor growth. Transcriptional analysis showed that activation of mtDNA(NZB) Teff cells increased mitochondrial gene expression while activation of mtDNA(NZB) Treg cells impaired mitochondrial gene expression and resulted in mtDNA(NZB) Treg cell exhaustion. Induction of the mitochondrially targeted catalytic antioxidant, mCAT, in hematopoietic cells normalized mtDNA(NZB) Treg function in both transplant and tumor models, indicating a key role for mROS in promoting Treg dysfunction. Anti-PD-L1 therapy did not modulate these effects, indicating that modulation of host mitochondrial function provides an independent approach for enhancing tumor cell destruction.