Mitochondrial bioenergetics of immune cells in Type 1 diabetes

Abstract

Abstract Mitochondrial (mito) bioenergetics of circulating cells change as a function of disease in Alzheimer’s, fibromyalgia, cancer, and Type 2 diabetes. We are exploring the use of mito-bioenergetics as a biomarker of Type 1 diabetes (T1D) progression and immune cell activation. T1D is a polygenic autoimmune disease in which an inflammatory leukocytic infiltrate into pancreatic islets results in destruction of insulin-producing β-cells. Autoantibody synthesis is currently used as a biomarker, but is a poor predictor of T1D since the majority of β-cells are destroyed prior to autoantibody seroconversion. We hypothesize that T1D is a chronic inflammatory disease in which conditions of oxidative stress will diminish the mitochondrial reserve capacity of immune cells and provide a surrogate marker for T1D. We compared mito-bioenergetics of murine immune cells derived from the spleen, pancreatic lymph node and bone marrow between diabetic and pre-diabetic Non-Obese Diabetic (NOD) mice. We show that mitochondrial reserve capacity is reduced in circulating CD4+ T cells from diabetic mice, but not in pre-diabetic mice during T1D progression. To explore the role of mitochondrial oxidative stress on diabetogenic CD4+ T cell effector responses, we used mito-TEMPO to scavenge mitochondrial reactive oxygen species (mROS). Mito-TEMPO reduced IFNγ synthesis in a primary recall assay by 0.24-fold and the combination of mito and cytosolic TEMPO increased Treg-associated IL-2 by 2.5-fold, suggesting that mROS have a causal role in modulating T cell effector responses critical for T1D pathology. We plan to perform human translational studies on mito-bioenergetics of PBMCs from recent onset T1D patients and further dissect the role of mROS on T1D.