Chimeric antigen receptors for a universal oncolytic virus vaccine boost in adoptive T cell therapies for cancer

Abstract

Recombinant oncolytic virus (OV) vaccines that encode tumour-associated antigens are potent boosting agents for adoptive transfer of tumor-specific T cells (adoptive T cell therapy or ACT). Current strategies to exploit boosting vaccines for ACT rely on a priori knowledge of targetable tumour epitopes and isolation of matched epitope-specific T cells. Therefore, booster vaccines must be developed on a patient-by-patient basis, which severely limits clinical feasibility. To overcome the requirement for individualized pairing of vaccines and T cells, we propose a “universal” strategy for boosting tumor-specific T cells where the boost is provided through a synthetic receptor that can be engineered into any T cell and a matched vaccine. To this end, we are employing chimeric antigen receptors (CARs), which confer MHC-independent antigen specificity to engineered T cells, and a paired OV vaccine that encodes the CAR target. As proof-of-concept, we have developed and evaluated a model where murine TCR transgenic T cells are engineered with boosting CARs against a surrogate antigen for studies in immunocompetent hosts.

In chapter 3, I optimized a murine CAR-T cell manufacturing protocol that allows for generation of highly-transduced T cells that maintain a predominantly central memory (Tcm) phenotype. This protocol leads to generation of highly functional CAR-T cell products that can be cryopreserved at the end of ex vivo culture for future use in adoptive transfer and vaccination studies.

In chapter 4, I evaluated the in vivo boosting potential of our dual-specific CAR-T cells with paired OV vaccines. Adoptive transfer of these CAR-engineered tumor-specific T cells followed by vaccination with paired oncolytic vesicular stomatitis virus (VSV) vaccine leads to robust, but variable and transient, CAR-mediated expansion of tumour-specific CD8+ T-cells, resulting in delayed tumour progression in aggressive syngeneic tumour models.

In chapter 5, I investigated the role of OV-induced type I interferon (IFN-I) responses on CAR-T cell boosting. I found that CAR-T cell expansion and anti-tumour function following OV vaccination is limited by the IFN-I response and can be further enhanced by blocking interferon alpha and beta receptor subunit 1 (IFNAR1). This IFN-I-mediated T cell suppression was found to be T cell-extrinsic and related to premature termination of OV infection and antigen expression in vivo.

In chapter 6, I investigated the role of CD4+ T cell help in vaccine-mediated T cell boosting and evaluated different genetic engineering strategies to integrate pro-survival STAT5 signaling into the CAR-T cell product in an effort to improve persistence and long-term anti-tumour efficacy.

The work presented herein describes a novel and clinically feasible approach to enhancing adoptive T cell therapies and contributes to the basic understanding of T cell biology in the context of CAR-engineering and cancer vaccination.