Caspase-1 Inhibition Ameliorates CAR T-Cell Apoptosis and Tumor Cell Pyroptosis to Enhance the Efficacy and Safety of CAR T-Cell Therapy

Chimeric antigen receptor (CAR) T-cell therapy has revolutionized the treatment of hematological malignancies. However, CAR T-cell therapy still has low durable response rates and common associated toxicities such as cytokine release syndrome (CRS). We recently reported that sequential therapy with the CD19 monoclonal antibody tafasitamab and CD19-directed CAR T (CART19, 41BBζ costimulated) cells significantly ameliorated CAR T-cell apoptosis and tumor cell pyroptosis, improving CAR T safety and efficacy (PMID: 37879074). Building on these findings, we hypothesized that controlling massive initial CAR T-cell stimulation by diminishing extensive tumor cell pyroptosis is critical to improve CAR T safety and durability.

To test this hypothesis, we evaluated several caspase (Casp) inhibitors, including Casp1, Casp3, Casp7, and Casp11, in combination with CAR T cells. We found that the Casp1 inhibitor VX765 did not inhibit CAR T antigen-specific cytotoxicity and thus focused on VX765 in subsequent assays.

We first assessed CAR T proliferation upon stimulation with the CD19⁺ JeKo-1 mantle cell lymphoma cell line in the presence of VX765. CAR T with vehicle control showed greater proliferation at day 3, but
CAR T with VX765 showed higher proliferation at day 5 (p=0.03, absolute CD3⁺ counts by flow cytometry). We then co-cultured CAR T and JeKo-1 for 24 hours and observed a significant reduction in apoptotic CAR T (Annexin V⁺ and 7-AAD^- via flow cytometry) in VX765-treated conditions (p=0.05). Additionally, there was significantly reduced pyroptosis (Annexin V⁺ 7-AAD⁺) (p=0.02) but higher apoptosis (Annexin V⁺ 7-AAD^-) in JeKo-1 in VX765-treated conditions (p=0.04). VX765-treated CAR T showed higher Bcl2 expression via flow cytometry (p=0.03). We also studied tumor cell pyroptosis by measuring the level of HMGB-1. CART19, JeKo-1, and VX765 or vehicle control were co-cultured for 24 hours, and the level of HMGB-1 was found to be significantly reduced in VX765-treated conditions, indicating reduced tumor pyroptosis (p=0.006).

We then assessed the impact of Casp1 inhibition in our in vitro model of CAR T exhaustion. We stimulated CAR T with CD19⁺ JeKo-1 every other day for 2 weeks and then assessed CCR7 and CD45RA expression on CAR T. VX765-treated CAR T showed higher central memory (p=0.08) and naïve (p=0.02) and lower terminally differentiated effector memory phenotypes (p=0.03).

We next studied the effect of Casp1 inhibition with VX765 in vivo. To recapitulate CAR T-cell toxicities, including CRS, we utilized an immunocompetent mouse model. First, we generated murine CART19 (mCART19, CD28ζ costimulated) cells. Recipient mice were then engrafted with luciferase⁺ murine CD19⁺ TBL12 cells, a murine lymphoma cell line. Mice were treated 12 days later with cyclophosphamide (300 mg/kg, ip) and 24 hours after mice were imaged and randomized to receive 1 x 10⁷, 1) untransduced T cell control (UTD), 2) mCART19 + vehicle control, or 3) mCART19 + VX765 (25 mg/kg). VX765 was given immediately before the CART19 injection and on day 2 post-CAR T injection. Mice were serially monitored and weighed to assess CAR T-cell toxicity. Tumor burden was assessed via weekly bioluminescent imaging. Mice treated with vehicle control showed a significant reduction in weight compared to the UTD control (p=0.02), while mice treated with VX765 maintained their weight and remained active without signs of CRS, including motor weakness and hunched body. UTD mice reached humane endpoints within 3 weeks after T-cell injection. Three satellite mice from each group were euthanized and spleens were harvested. Flow cytometric analysis showed a significant reduction in apoptotic CAR T (p=) and pyroptotic tumor cells in mice treated with VX765 (p=0.03). Western blot showed lower cleaved GSDME and GSDMD in mice treated with VX765. VX765-treated mice demonstrated prolonged CAR T persistence with durable anti-tumor activity.

In summary, Casp1 inhibition with VX765 significantly reduced CAR T apoptosis, improved memory phenotype, and increased delayed CAR T proliferation. VX765 also reduced tumor cell pyroptosis and CRS incidence without impacting CAR T anti-tumor activity in vivo. Given the favorable preclinical outcomes and existing clinical data on VX765, this approach holds substantial translational potential for enhancing the safety and efficacy of CAR T-cell therapy in patients with large B-cell lymphoma.