Anti-CD3 Mono-Fab co-potentiates TCR antigen recognition in human T cells

Abstract

Abstract TCR mediated antigen recognition results in a signaling cascade leading to T cell activation. Antigen binding to its cognate TCR drives receptor aggregation and conformational changes that trigger signaling from the receptor. Conformational change in the CD3 complex (CD3Δc) is required for robust signaling and productive T cell responses. In contrast, weakly recognized antigens do not induce CD3Δc and the resulting T cell response is poor. Thus, T cell responses to weak antigens may be improved by induction of CD3Δc. We previously described an anti-mouse CD3ɛ monovalent Fab (Mono-7D6-Fab) that induced CD3Δc and synergized with weak antigens to enhance the T cell response, a process we termed co-potentiation. However, Mono-7D6-Fab did not induce classical T cell signaling in the absence of antigenic ligation. Mono-7D6-Fab effectively co-potentiated T cells against murine B16-F10 melanoma cells and reduced tumor burden in vivo in a T cell dependent manner. We exploited a model of human cytomegalovirus (CMV) to generate proof of concept that co-potentiation may enhance T cell antigen recognition in humans. Anti-human CD3ɛ monovalent Fab (Mono-OKT3-Fab) improved the CD8 T cell response to the CMV pp65495–503 peptide as measured by increased T cell proliferation, cytokine production, and the ability to kill target cells. Co-potentiation was dependent on antigen specificity, as 1) the effects were dampened when antigen recognition was impaired and 2) sequencing of the TCRs revealed a restricted number of expanded TCR clones. Our results suggest that Mono-OKT3-Fab may have therapeutic clinical applications to achieve a more robust antigen-specific T cell response in the context of diverse human disease, from cancer to chronic infection.