Fusogenic activity of vesicular stomatitis virus glycoprotein plasmid in tumors as an enhancer of IL-12 gene therapy.

We have characterized the fusogenic activity of a plasmid expression system encoding vesicular stomatitis virus G protein (VSVG) in vitro and in vivo. Over 70% of murine colon and renal carcinoma cells (MC38 and Renca, respectively) transfected with VSVG plasmid in vitro fused and formed polykaryons upon incubation with pH 5.5 media. Using a plasmid expression system encoding VSVG and bacterial green fluorescent protein (GFP) formulated in a polyvinyl pyrrolidone (PVP) delivery system, diffusion of GFP throughout the VSVG-induced syncytia was shown in vivo in MC38 and Renca tumors. Moreover, tumor-bearing mice showed tumor growth inhibition following in vivo transfection with VSVG plasmid at an optimal dose of 48 microg. We have previously shown that direct injection of interleukin -12 (IL -12) plasmid complexed with PVP into tumors induces a strong immune response. In the current study, we assessed the ability of VSVG to elicit an antitumor response by enhancing cytokine gene delivery within the tumor mass. Tumor-bearing mice treated intratumorally with both VSVG/PVP and IL-12/PVP (48 and 24 microg, respectively) showed increase in tumor rejection when compared to IL- 12 plasmid alone (75% vs. 50%, respectively). These data suggest that VSVG gene therapy can be used in combination with other therapeutic genes to induce an antitumor response in vivo by enhancing the expression of the gene of interest.

Therapeutic tumor immunity induced by polyimmunization with melanoma antigens gp100 and TRP-2.

To improve the immunogenicity of melanoma self-antigens, we used a novel strategy of nonviral genetic vaccination coupled with muscle electroporation. Electroporation-enhanced immunization with plasmids encoding either human gp100 or mouse TRP-2 antigens induced only partial rejection of B16 melanoma challenge. However, immunization with a combination of these two antigens caused tumor rejection in 100% of the immunized mice. Splenocytes from combination-immunized animals killed syngeneic targets loaded with peptides derived from both gp100 and TRP-2. Immune cell depletion experiments identified CD8+ T lymphocytes as the primary effectors of antitumor immunity. Most importantly, polyimmunization led to the generation of a therapeutic immune response that significantly improved the mean survival time of mice bearing established lung metastases. These results validated the usefulness of electroporation-enhanced, nonviral genetic immunization for the active immunotherapy of cancer and indicated that using a combination of different tumor antigens may be a decisive strategy for a successful therapeutic vaccination.