Cell autonomous metabolic remodeling governs regeneration of the thymus

Abstract

Abstract Competent T cell development relies on efficient functioning of the thymus, which is extremely sensitive to acute and chronic insults, but has a remarkable ability to regenerate. We identified that cell-specific metabolic remodeling triggers key molecular mechanisms driving this endogenous regeneration process, namely the transcription of Foxn1 by thymic epithelial cells (TECs). Firstly, following acute damage (sub-lethal total body irradiation) murine CD4+CD8+ (DP) thymocytes, which undergo high levels of death, have a disrupted glycolytic flux triggering a switch to OXPHOS, with reduced mitophagy and increased mitochondrial ROS, an effect not observed in TECs, which are relatively damage-resistant, suggesting metabolic stability confers protection. Furthermore, DPs preferentially undergo pyroptotic cell death after damage facilitated by increased pyruvate-induced TCA cycling, evidenced by an acute surge in caspase 1 cleavage compared to caspase 3. Importantly, pyroptotic thymocytes induce Foxn1 transcription in cortical TECs (cTECs) and in vitro screening revealed the purinergic receptors P2Y2 as a critical molecular target. Moreover, we translated this therapeutic strategy in vivo and demonstrated enhanced thymic regeneration after damage in mice treated with a P2Y2 agonist. Together these data describe an innovative mechanism of immunometabolic regulation of T cell development and tissue regeneration and provides a novel therapeutic strategy to enhance immune function.