Comparison of two cancer vaccines targeting tyrosinase: plasmid DNA and recombinant alphavirus replicon particles.

PURPOSE: Immunization of mice with xenogeneic DNA encoding human tyrosinase-related proteins 1 and 2 breaks tolerance to these self-antigens and leads to tumor rejection. Viral vectors used alone or in heterologous DNA prime/viral boost combinations have shown improved responses to certain infectious diseases. The purpose of this study was to compare viral and plasmid DNA in combination vaccination strategies in the context of a tumor antigen. EXPERIMENTAL DESIGN: Using tyrosinase as a prototypical differentiation antigen, we determined the optimal regimen for immunization with plasmid DNA. Then, using propagation-incompetent alphavirus vectors (virus-like replicon particles, VRP) encoding tyrosinase, we tested different combinations of priming with DNA or VRP followed by boosting with VRP. We subsequently followed antibody production, T-cell response, and tumor rejection. RESULTS: T-cell responses to newly identified mouse tyrosinase epitopes were generated in mice immunized with plasmid DNA encoding human (xenogeneic) tyrosinase. In contrast, when VRP encoding either mouse or human tyrosinase were used as single agents, antibody and T-cell responses and a significant delay in tumor growth in vivo were observed. Similarly, a heterologous vaccine regimen using DNA prime and VRP boost showed a markedly stronger response than DNA vaccination alone. CONCLUSIONS: Alphavirus replicon particle vectors encoding the melanoma antigen tyrosinase (self or xenogeneic) induce immune responses and tumor protection when administered either alone or in the heterologous DNA prime/VRP boost approaches that are superior to the use of plasmid DNA alone.

T-cell responses to multiple antigens presented by RNA-transfected APCs: a possible immunomonitoring tool.

The increasingly deeper understanding of how the immune system recognizes and destroys tumors promises to enable the development of new approaches for gene therapy and immunotherapy. However, a treatment that induces safe and potentially beneficial antitumor responses is expected to require stepwise refinements. As part of this challenge, assays are needed to measure specific antitumor immune responses in patients. This becomes problematic because most tumors express unknown tumor antigens and it is often difficult to obtain sufficient amounts of viable tumor material for in vitro assays. Recently it was demonstrated that RNA derived from tumor cells stimulated T cells in an antigen-specific manner. These studies have formed the basis for the development of dendritic cell vaccines that express tumor antigens following translation of tumor RNA. Therefore, it occurred to us that antigen-presenting cells transfected with total tumor RNA might also be valuable in monitoring the antitumor responses induced in patients who participate in clinical trials. To test this hypothesis, we developed a model in which Epstein-Barr virus (EBV)-transformed lymphoblastoid cell lines were used as a source of RNA. Since this RNA encodes for known EBV antigens, it was possible to determine whether the expected responses were observed. Our results show for the first time that T cells primed to APC transfected with RNA isolated from EBV-infected lymphocytes exhibited a fine specificity that enabled them to recognize individual EBV antigens.