Targeting Cancer Associated Fibroblasts in the Bone Marrow Prevents Resistance to Chimeric Antigen Receptor T Cell Therapy in Multiple Myeloma

Introduction Cellular immunotherapy is a rapidly progressing field in multiple myeloma (MM). Multiple clinical trials have reported impressive efficacy of B cell maturation antigen (BCMA) directed chimeric antigen receptor cell therapy (BCMA CART) in MM. While trials demonstrated a high response rate, the durable response rate is around 30%. Most patients lose their CART cells, and the disease relapses within the first year, suggesting an inhibition by the MM tumor microenvironment (TME). Therefore strategies to overcome this inhibition would represent a major advance in this field. Cancer associated fibroblasts (CAFs) within the TME play a critical role in promoting tumor growth and immunosuppression. Objective CAFs from MM patients lead BCMA CART cell dysfunction and targeting both MM cells and CAFs can overcome this resistance. Methods CAFs were isolated from the bone marrow (BM) of MM patients and purified using anti fibroblast beads. MM-TME mouse model was established by injecting a 1:1 ratio of BCMA+ OPM2 (MM cell line) to CAFs. Five different CART cells were tested in this study. For single transduced CAR: BCMA, CS1, and fibroblast activation protein (FAP). For dual transduced CAR: BCMA-CS1 and BCMA-FAP CART. These were generated through the double transduction of two lentiviral vectors. Results BCMA CART cell proliferation assay showed inhibition of CART expansion in the presence of CAFs, and this was mediated by TGF-β (Fig A). MM-TME mouse model revealed a significant acceleration of MM progression (Fig B). To identify targets, we verified FAP expression on CAFs. Interestingly, there was a low level of CS1, but not BCMA expressed on CAFs (Fig C). Then, we evaluated the impact of CAFs on functions of BCMA CART cells compared to dual CART cells. When CART cells were stimulated with the BCMA+ MM cell line MM1S, in the presence of CAFs, the proliferation of BCMA CART cells, but not the dual CART cells was significantly inhibited (Fig A). Similarly, in the presence of CAFs, the production of key effector cytokines by BCMA CART cells, but not the dual CART cells was reduced (Fig D). Finally, we studied the impact of CAFs on CART cell functions in vivo. First, using OPM2 xenografts, treatment with BCMA CART cells was able to eradicate MM (Fig E). Then, the MM-TME model was used to assess the effect of targeting CAFs. Mice were treated with 1) control T cells, 2) BCMA CART cells, 3) BCMA-FAP CART cells, or 4) BCMA-CS1 CART cells. A low dose (1 × 106 iv) of CART cell was used to induce relapse. BCMA CART cells led to a transient antitumor activity in this model (mice died within 2 weeks), while dual CART cells resulted in durable remissions, a higher number of circulating T cells, and long term survival (Fig F). Conclusion We demonstrate for the first time that dual targeting both malignant plasma cells and the CAFs within the TME is a novel strategy to overcome resistance to CART cell therapy in MM.