PTPN2-KO CAR-T Cells Demonstrate Enhanced Effector Function, CNS Infiltration, and Toxicity in a Non-Human Primate CAR-T Model

B-cell targeting CAR-T cell therapies achieve high remission rates, yet durable responses occur in fewer than 40% of patients. Deletion of negative T-cell regulators, such as PTPN2, a key inhibitor of TCR and cytokine signaling, represents a promising strategy to enhance the efficacy of CAR-T cells. While transfer of PTPN2 knockout (KO) T cells has demonstrated antitumor benefits in murine models, its impact on human-derived CAR-T cells and, importantly, the associated in vivo efficacy and toxicity remain unclear. Here, we demonstrate that PTPN2-KO human CD19 CAR-T cells exhibit enhanced cytokine production, cytotoxicity, TCR and CAR affinity and signaling, leading to superior in vitro elimination of leukemic cells with low CD19 expression. To assess in vivo efficacy and toxicity, we performed a dose-escalation study using a non-human primate (NHP) model of B-cell-targeting CD20 CAR-T cell therapy. We demonstrated that PTPN2-KO CD20 CAR-T cells exhibited superior in vivo expansion and B-cell depletion compared to WT CAR-T cells, in a dose-dependent manner. At the highest dose level, CAR-T expansion was associated with increased toxicities, particularly ICANS, compared to PTPN2 WT CD20 CAR-T cells driven by enhanced CNS-infiltration. Transcriptional profiling revealed a dominant effector and proliferative signature, with cytotoxic CNS-infiltrating CD8+ PTPN2-KO CAR-T cells implicated in ICANS pathogenesis. This study details the comprehensive evaluation of PTPN2-KO CAR-T cells in an immunocompetent model, demonstrating their enhanced on-target functionality, while highlighting increased toxicity risks, underscoring the need for rigorous preclinical assessment of potent genetic modifications in CAR-T therapy.