Abstract A73: Optogenetic regulation of T cell metabolism in the tumor microenvironment

The tumor microenvironment presents significant metabolic challenges to T cells by depleting oxygen and glucose, as well as limiting the uptake of key nutrients. Therefore, T cells and tumor cells engage in fierce metabolic competition, as the demand for both oxygen and glucose in the niche is extremely high. The transition from a resting naive T cell into an activated and highly proliferative effector T cell requires substantial metabolic reprogramming from relying primarily on oxidative phosphorylation (OxPhos) to the rapid induction of aerobic glycolysis. However, evidence suggests that tumor infiltrating CD8 + T cells show defects in glycolytic functions. In addition, our data indicates that actively migrating effector CD8 + T cells have greater levels of OxPhos activity than stationary cells, imposing an increasing demand for oxygen during T cell migration to the tumor site. To overcome the glycolytic deficiency of the tumor-targeting T cells and boost anti-tumor effector functions at the tumor microenvironment, we developed a genetically encoded light-activated proton pump (fungal proton pump, “Mac”), namely photoactivatable OxPhos (PA-OxPhos) that is expressed in the inner mitochondrial membrane. During OxPhos, electrons enter the electron transport chain (ETC), causing protons to be pumped across the inner mitochondrial membrane to establish a proton gradient. The gradient is then used to generate ATP through complex V (CxV). Therefore, the outward proton pumping through the inner mitochondrial membrane by light stimulation of PA-OxPhos mimics the ETC function and boosts ATP generation in T cells, even in the presence of low levels of oxygen and substrates, giving T cells a metabolic competitive advantage in the tumor microenvironment. PA-OxPhos is tagged with GFP and is expressed in the mitochondria of transfected 293T cells and in activated mouse CD8 + T cells. When cells were treated with Rotenone (an inhibitor of complex I of the ETC), ATP production was decreased after 90 minutes. Importantly, light stimulation of 293T cells expressing PA-OxPhos successfully increased ATP production even in the presence of Rotenone. Our data suggests that PA-OxPhos can remotely provide a competitive metabolic advantage and boost T cell functions in the tumor microenvironment. The utilization of an alternative mechanism for ATP production in T cells could potentially dissipate the failures of T-cell-based cancer immunotherapies in destroying malignant cells of solid tumors. Citation Format: Andrea Amitrano, Brandon Walling, Kyun Do Kim, Brandon Berry, Adam Trewin, Andrew Wojtovich, Minsoo Kim. Optogenetic regulation of T cell metabolism in the tumor microenvironment [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2018;6(9 Suppl):Abstract nr A73.