Antagonizing vasoactive intestinal peptide (VIP) receptors with Muc16CD-directed armored CAR T cells for pancreatic cancer.

Abstract

2558 Background: Chimeric antigen receptor (CAR) T therapies for pancreatic ductal adenocarcinoma (PDAC) still face significant immunosuppressive obstacles in the tumor microenvironment (TME). We hypothesize that an optimal CAR T cell for PDAC combines targeting an ideal tumor-associated antigen (TAA) and overcomes unique immunosuppression in the PDAC TME. The retained ectodomain of Muc16 (Muc16CD) is a known TAA in ovarian cancer but has yet to be explored in pancreatic cancer. Vasoactive intestinal peptide (VIP) is an emerging checkpoint pathway for T cell function, which expresses VIP receptors (VIPR) and is abundantly expressed by PDAC. In this work, we present a novel armored CAR T cell that targets Muc16CD and antagonizes VIPRs (CAR/VIPRa) to overcome the immunosuppressive PDAC TME. Methods: Patient expression data was assessed based on data generated by the TCGA Research Network. Primary human T cells from healthy donors or PDAC patients were retrovirally transduced to express Muc16CD-directed CARs with or without secretion of novel, potent VIPR antagonist peptides. In vivo, PDAC PDX tumors were engrafted into SCID/Beige mice and treated with CAR T cells. Results: PDAC tumors have significantly increased expression of Muc16 compared to normal pancreas tissue and patients with high Muc16 expression have a significantly decreased overall survival. PDAC patient-derived tumors show robust expression of both Muc16CD and VIP. CAR/VIPRa T cells reveal that VIPR antagonism metabolically reprograms CAR T cells and drives a memory-rich product. CAR/VIPRa T cells are less activated and less exhausted by the manufacturing process, which lends to better viability and a metabolically quiescent phenotype at baseline. These distinct features allow CAR/VIPRa T cells, when antigen-stimulated, to have enhanced activation and expansion with repeated stimulation. To investigate clinical relevance, CAR/VIPRa T cells manufactured from PDAC patient blood are also significantly enriched for memory phenotypes. In vivo, CAR/VIPRa T cells have enhanced expansion, phenotype, infiltration, and persistence, which ultimately reduces PDAC tumor burden. In a patient-derived PDAC preclinical mouse model where CAR T is typically ineffective, CAR/VIPRa T cells significantly reduce tumor burden. Conclusions: This work demonstrates Muc16CD as a clinically relevant TAA target for CAR T therapy in PDAC. Furthermore, antagonizing the previously undescribed VIP checkpoint pathway in CAR T cells produces enhanced phenotypic and functional profiles. Collectively, this data demonstrates that novel CAR/VIPRa T cells create an advantageous cellular therapy product capable of treating PDAC. The long-term goal of this work is translating CAR/VIPRa T cells for the treatment of PDAC and expanding these preclinical findings of cellular therapies for other VIP-abundant tumors.