T Cells Engineered with a Novel Chimeric Receptor Demonstrate Durable In Vivo Efficacy Against Disseminated Multiple Myeloma
Abstract Despite recent therapeutic developments, multiple myeloma remains an incurable plasma cell malignancy. Poor prognosis for myeloma patients relapsing post-transplant calls for the need for novel treatment options. Immunotherapy with engineered T cells has proven highly efficacious against B-cell cancers, and early-phase clinical trials suggest that multiple myeloma is susceptible to this form of therapy. We designed a new chimeric T cell receptor, T cell antigen coupler (TAC), which relies upon activation through endogenous T cell receptor complex, thus allowing engineered T cells to auto-regulate their activity (Helsen et al, Nat. Comm., 2018). Using published single-chain antibody fragments (scFvs) C11D5.3 and J22.9-xi, we generated B cell maturation antigen (BCMA)-specific TAC receptors for targeting multiple myeloma. Primary human T cells were transduced with lentiviral vectors carrying different BCMA TAC constructs and assessed for in vitro functionality via cytokine production, cytotoxicity, and proliferation assays. In vivo efficacy and T cell tracking were performed in an established orthotopic xenograft mouse model based on a BCMA-positive KMS-11 cell line. C11D5.3 and J22.9-xi TAC T cells demonstrated comparable in vitro performance with both types of cultures efficiently killing BCMA-expressing targets, producing IFN-γ, TNF-α, and IL-2 cytokines, and undergoing multiple rounds of proliferation. In vivo, TAC T cells carrying either scFv were capable of curing mice bearing disseminated myeloma; however, the TAC T cells carrying J22.9-xi scFv were more potent on a per-cell basis (Figure 1A, top panel). Mice in remission 3 months post-treatment with a single dose of 106 TAC-positive T cells showed evidence of sustained anti-tumor protection upon rechallenge with a fresh dose of 106 KMS-11 tumor cells (Figure 1B). Mice treated with low-dose J22.9-xi T cells were more resistant to rechallenge than mice treated with a comparable dose of C11D5.3 TAC T cells. Tracking of the TAC T cells in vivo revealed that the J22.9-xi TAC T cells expanded to a much larger extent than the C11D5.3 TAC T cells (Figure 1A, bottom panel), indicating that there were likely more J22.9-xi TAC T cells present at the time of tumor rechallenge. To understand whether biological aspects of BCMA may influence the proliferative response of the TAC T cells, we explored the influence of APRIL, the soluble ligand for BCMA, on TAC T cell proliferation in vitro. Strikingly, despite comparable proliferation of both TAC T cell populations following stimulation with KMS-11 tumor cells in the absence of APRIL in vitro, the presence of APRIL had a strong inhibitory effect on proliferation of C11D5.3 TAC T cells and only a modest inhibitory effect on J22.9-xi TAC T cells. Our preclinical findings support further development of TAC T cells for the treatment of multiple myeloma and underscore the importance of T cell expansion in determining the therapeutic activity of engineered T cells. This work further reveals a novel observation that the natural ligand of BCMA can impair the therapeutic impact of T cells engineered with chimeric receptors directed against BCMA and provide a basis for advancing BCMA-specific TAC T cells into the clinic. Disclosures Denisova: Triumvira Immunologics: Patents & Royalties. Afsahi:Triumvira Immunologics: Patents & Royalties. Helsen:Triumvira Immunologics: Employment, Patents & Royalties. Bramson:Triumvira Immunologics: Employment, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding.