NRF2/Itaconate Axis Regulates Metabolism and Inflammatory Properties of T Cells in Children with JIA.

BACKGROUND: CD4+ T cells critically contribute to the initiation and perturbation of inflammation. When CD4+ T cells enter inflamed tissues, they adapt to hypoxia and oxidative stress conditions, and to a reduction in nutrients. We aimed to investigate how this distinct environment regulates T cell responses within the inflamed joints of patients with childhood rheumatism (JIA) by analyzing the behavior of NRF2-the key regulator of the anti-oxidative stress response-and its signaling pathways. METHODS: Flow cytometry and quantitative RT-PCR were used to perform metabolic profiling of T cells and to measure the production of inflammatory cytokines. Loss of function analyses were carried out by means of siRNA transfection experiments. NRF2 activation was induced by treatment with 4-octyl-Itaconate (4-OI). RESULTS: Flow cytometry analyses revealed a high metabolic status in CD4+ T cells taken from synovial fluid (SF) with greater mitochondrial mass, and increased glucose and fatty acid uptake. This resulted in a heightened oxidative status of SF CD4+ T cells. Despite raised ROS levels, expression of NRF2 and its target gene NQO1 were lower in CD4+ T cells from SF than in those from blood. Indeed, NRF2 activation of CD4+ T cells downregulated oxidative stress markers, altered the metabolic phenotype and reduced secretion of IFN-γ. CONCLUSION: NRF2 could be a potential regulator in CD4+ T cells during chronic inflammation and could instigate a drift toward disease progression or regression, depending on the inflammatory environment.

miR-23a contributes to T cellular redox metabolism in juvenile idiopathic oligoarthritis.

OBJECTIVE: JIA is a chronic inflammatory disease of unknown origin. The regulation of inflammatory processes involves multiple cellular steps including mRNA transcription and translation. Different miRNAs control these processes tightly. We aimed to determine the roles of specific miRNAs within JIA pathogenesis. METHODS: We performed a global miRNA expression analysis in parallel in cells from the arthritic joint and peripheral blood of oligoarticular JIA patients and healthy controls. Quantitative RT-PCR analysis was used to verify expression of miRNA in T cells. Ex vivo experiments and flow cytometric analyses were used to analyse proliferation and redox metabolism. RESULTS: Global miRNA expression analysis demonstrated a different composition of miRNA expression at the site of inflammation compared with peripheral blood. Bioinformatic analysis of predicted miRNA target genes suggest a huge overrepresentation of genes involved in metabolic and oxidative stress pathways in the inflamed joint. Despite enhanced reactive oxygen species (ROS) levels within the local inflammatory milieu, JIA T cells are hyperproliferative and reveal an overexpression of miR-23a, which is an inhibitor of Peptidyl-prolyl isomerase F (PPIF), the regulator of mitochondrial ROS escape. Mitochondrial ROS escape is diminished in JIA T cells, resulting in their prolonged survival. CONCLUSION: Our data suggest that miRNA-dependent mitochondrial ROS shuttling might be a mechanism that contributes to T cell regulation in JIA at the site of inflammation.

Nrf2 expression driven by Foxp3 specific deletion of Keap1 results in loss of immune tolerance in mice.

The transcription factor Nrf2 regulates oxidative stress responses. However, the specific function of Nrf2 in Tregs, the central regulators of immune homeostasis, is unclear. Here, we report an unexpected but important role of Nrf2 in Tregs. Nrf2 expression driven by Foxp3 specific deletion of Keap1 resulted in an autoinflammatory phenotype with enhanced effector T cell activation and immune cell infiltrates in the lung. While early postnatal death of mice with Foxp3 specific deletion of Keap1 was most probably due to ectopic Foxp3cre expression and subsequent Keap1 deletion in epithelial cells, bone marrow chimeras suggest that Nrf2 activation intrinsically in Tregs contributes to a loss of Treg cells and diminished peripheral tolerance. Moreover, Nrf2 activation was associated with a loss of Foxp3 expression, but an enhanced glucose uptake and mTOR activity in Tregs, thus mimicking a metabolic phenotype that is associated with impaired lineage stability and cell functioning.