The NOTCH-FOXM1 Axis Plays a Key Role in Mitochondrial Biogenesis in the Induction of Human Stem Cell Memory-like CAR-T Cells.

Abstract

Recent studies have shown that stem cell memory T (TSCM) cell-like properties are important for successful adoptive immunotherapy by the chimeric antigen receptor-engineered-T (CAR-T) cells. We previously reported that both human and murine-activated T cells are converted into stem cell memory-like T (iTSCM) cells by coculture with stromal OP9 cells expressing the NOTCH ligand. However, the mechanism of NOTCH-mediated iTSCM reprogramming remains to be elucidated. Here, we report that the NOTCH/OP9 system efficiently converted conventional human CAR-T cells into TSCM-like CAR-T, "CAR-iTSCM" cells, and that mitochondrial metabolic reprogramming played a key role in this conversion. NOTCH signaling promoted mitochondrial biogenesis and fatty acid synthesis during iTSCM formation, which are essential for the properties of iTSCM cells. Forkhead box M1 (FOXM1) was identified as a downstream target of NOTCH, which was responsible for these metabolic changes and the subsequent iTSCM differentiation. Like NOTCH-induced CAR-iTSCM cells, FOXM1-induced CAR-iTSCM cells possessed superior antitumor potential compared with conventional CAR-T cells. We propose that NOTCH- or FOXM1-driven CAR-iTSCM formation is an effective strategy for improving cancer immunotherapy. SIGNIFICANCE: Manipulation of signaling and metabolic pathways important for directing production of stem cell memory-like T cells may enable development of improved CAR-T cells.