IMMU-05. TARGETING THE DYSREGULATED DNA METHYLOME DURING CAR T CELL MANUFACTURING IMPROVES THEIR FITNESS IN IMMUNOCOMPETENT BRAIN TUMOR MODELS

Abstract

Abstract BACKGROUND Epigenetic reprogramming and T-cell exhaustion are key factors impacting the effectiveness of chimeric antigen receptor (CAR) T-cell immunotherapies in brain tumors. These processes are regulated by DNA methylation, an epigenetic modification that is crucial for gene regulation. Here, we investigated whether targeting the dysregulated DNA methylome in engineered immune cells can improve their anti-tumor efficacy. METHODS We optimized a transduction protocol that incorporates adding DNA methyltransferase inhibitors (DNMTi) early during the manufacturing process of murine CAR T-cells targeting B7-H3. We then used standard in vitro assays and immunocompetent glioma models to evaluate whether DNMTi treatment improved CAR T-cell effector functions by regulating activation, memory differentiation, and cytokine responses in adoptive T-cells. RESULTS In repeated-stimulation assays, CAR T-cells generated in the presence of DNMTi exhibited significantly higher levels of expansion and persistence compared to CAR T-cells without DNMTi exposure. Notably, CAR T-cells manufactured in the presence of DNMTi persisted up to 12 repeat stimulations, in contrast to a maximum of 7 stimulations for CAR T-cells generated without DNMTi treatment. Moreover, DNMTi-treated CAR T-cells expanded up to 55-fold higher than T-cells generated without DNMTi treatment upon repeated-stimulation with B7-H3-positive glioma cells. This was also associated with remarkably enhanced secretion of immune-stimulatory cytokines that persisted across repetitive stimulations. Furthermore, DNMTi-treated CAR T-cells exhibited greater cytotoxicity at lower effector-to-target ratios compared to untreated CAR T-cells, with sustained differential cytotoxicity even after the 4th stimulation. Preliminary in vivo data from immunocompetent glioma models further support the potential of DNMTi pre-treatment, showing improved T-cell persistence and reduced dose requirements. Mechanistic studies suggest that DNMT inhibition enhances B7-H3 CAR T-cell anti-tumor activity by regulating memory differentiation of CAR T-cells early in the production phase. CONCLUSION This study proposes that DNMTi pre-treatment may offer a promising approach for optimizing CAR T-cell manufacturing and enhancing performance in brain tumors.