Background
Mitochondrial metabolism is known to be important for T cell activation. However, its involvement in effector T cell differentiation has just begun to gain attention. Importantly, how metabolic pathways are integrated with T cell activation and effector cell differentiation and function remains largely unknown.
Objective
We sought to test our hypothesis that RhoA GTPase orchestrates glycolysis for Th2 cell differentiation and Th2-mediated allergic airway inflammation.
Methods
Conditional RhoA-deficient mice were generated by crossing RhoAflox/flox mice with CD2-Cre transgenic mice. Effects of RhoA on Th2 differentiation were evaluated by in vitro Th2-polarized culture conditions, and in vivo in ovalbumin (OVA)-induced allergic airway inflammation. Cytokines were measured by intracellular staining and ELISA. T cell metabolism was measured by Seahorse XF24 Analyzer and flow cytometry.
Results
Disruption of RhoA inhibited T cell activation and Th2 differentiation in vitro and prevented the development of allergic airway inflammation in vivo, with no effect on Th1 cells. RhoA deficiency in activated T cells led to multiple defects in metabolic pathways such as glycolysis and oxidative phosphorylation. Importantly, RhoA couples glycolysis to Th2 cell differentiation and allergic airway inflammation via regulating IL-4 receptor mRNA expression and Th2-specific signaling events. Finally, inhibition of Rho-associated protein kinase (ROCK), an immediate downstream effector of RhoA, blocked Th2 differentiation and allergic airway inflammation.
Conclusion
RhoA is a key component of the signaling cascades leading to Th2-differentiation and allergic airway inflammation, at least in part, through the control of T cell metabolism and via ROCK pathway.
Cdc42 of the Rho GTPase family has been implicated in cell actin organization, proliferation, survival, and migration but its physiological role is likely cell-type specific. By a T cell-specific deletion of Cdc42 in mouse, we have recently shown that Cdc42 maintains naïve T cell homeostasis through promoting cell survival and suppressing T cell activation. Here we have further investigated the involvement of Cdc42 in multiple stages of T cell differentiation. We found that in Cdc42−/− thymus, positive selection of CD4+CD8+ double-positive thymocytes was defective, CD4+ and CD8+ single-positive thymocytes were impaired in migration and showed an increase in cell apoptosis triggered by anti-CD3/-CD28 antibodies, and thymocytes were hyporesponsive to anti-CD3/-CD28-induced cell proliferation and hyperresponsive to anti-CD3/-CD28-stimulated MAP kinase activation. At the periphery, Cdc42-deficient naive T cells displayed an impaired actin polymerization and TCR clustering during the formation of mature immunological synapse, and showed an enhanced differentiation to Th1 and CD8+ effector and memory cells in vitro and in vivo. Finally, Cdc42−/− mice exhibited exacerbated liver damage in an induced autoimmune disease model. Collectively, these data establish that Cdc42 is critically involved in thymopoiesis and plays a restrictive role in effector and memory T cell differentiation and autoimmunity.
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