Modulation of the Btla-HVEM Axis to Enhance CAR T Cell Immunotherapy Against Cancer

Introduction: The efficacy of adoptive T cell immunotherapies against cancer, such as chimeric antigen receptor (CAR) T cells, is severely blunted by the immunosuppressive tumor microenvironment (TME). We sought to investigate the role of the TME in cancer resistance to effector T cells in order to define actionable targets to enhance CAR T cell immunotherapies. We initially used Hodgkin lymphoma (HL) as an ideal tumor model since it is characterized by a TME that is profoundly infiltrated by immunosuppressive cells, and then we expanded our findings to multiple cancer models.

We first sought to identify the dominant interactions of immunosuppressive cellular compartments and effector T cells by analyzing single-cell RNA sequencing data on a total of 26 (4 exploratory + 22 validation) HL patient tumor biopsies. Using the CellPhoneDB algorithm, we inferred that the ligand B- and T-lymphocyte attenuator (BTLA) on effector T cells and the receptor Herpesvirus entry mediator (HVEM, TNFRSF14) on immunosuppressive cells (e.g., regulatory T cells, monocytes) strongly interact in the TME and promote T cell dysfunction (Fig 1a). Akin to the canonical checkpoint PD1, BTLA recruits two potent tyrosine phosphatases, SHP-1 and SHP-2, to disable early T cell activation. Thus, we rationalized that BTLA expression on T cells might reduce their anti-tumor function. We hypothesized that deleting BTLA in CAR T cells would abolish BTLA-HVEM trans interactions at the immunological synapse and unleash the cytotoxic potential of CAR T cells.

Methods and Results: We first generated BTLA KO anti-CD30 CAR T (CART30) cells against HL. To test their function in vivo, 15x10⁶ HDLM-2 (CD30+HVEM+ HL) cells were subcutaneously implanted into NSG mice on day 0, and on day 62, 3x10⁵ CAR30+ T cells were infused intravenously. Our results demonstrated that BTLA KO significantly enhances the function of anti-CD30 CAR T cells in HVEM+ HL (Fig 1b), as assessed via tumor size (caliper) and CART30 expansion in the peripheral blood (flow cytometry). Additionally, we generated BTLA KO 4-1BBζ CART19 cells, which showed greater in vivo anti-tumor function in a subcutaneous tumor model of DLBCL (CD19+ HVEM+ OCI-Ly18). Serum collected from OCI-Ly18-bearing NSG mice infused with BTLA KO CART19 was enriched in effector cytokines (e.g., TNF, IFNγ, IL-2) as measured by Luminex. We then extended these findings into HVEM+ solid tumor models. BTLA KO improved tumor control in vitro in short-term killing experiments (Incucyte SX5) for both CAR and TCR T cells, respectively directed against prostate cancer (HER2+ PC-3) and melanoma (GP-100+ DM-6). Importantly, we demonstrated that BTLA KO in primary BALB/c-derived murine CAR T cells enhances tumor control in A20 murine lymphoma. In this model, BTLA KO tumor-infiltrating CAR T cells showed substantially reduced exhaustion in the TME relative to wild-type CAR T cells.

Mechanistically, we showed that targeted mutations in BTLA intracellular tyrosine motifs effectively reduce the recruitment of SHP-1/2 and preserve the docking domain of the pro-stimulatory Grb2, thus maintaining high NFAT signaling and increased persistence in vivo. These effects were dependent on the expression of HVEM on tumor cells. Finally, we found that high BTLA RNA expression in tisagenlecleucel infusion products correlates with poor response to treatment in patients with DLBCL and FL (NCT02030834).

Conclusion: Our results reveal a critical role of the BTLA-HVEM axis in inhibiting CAR T cell function, and demonstrate that CRISPR-Cas9 deletion of BTLA leads to enhanced anti-tumor efficacy in multiple models of cancer. The key mechanism is the reduction of SHP-1/2 recruitment and the consequent increase in CAR T cell activation. The results of this study will be translated into a first in human clinical trial of BTLA-deficient CAR T cells for relapsed or refractory cancer.