In vivo plasmid DNA electroporation generates exceptionally high levels of epitope-specific CD8+ T-cell responses.

Based on observations that DBA/2 mice develop a highly specific response towards an HLA-Cw3-derived epitope, consisting entirely of CD8+CD62L-Vbeta10+ cells, we have established an in vivo mouse model for screening a variety of immunization approaches. Responder cells were readily detectable in small samples of the peripheral blood using three-color FACS analysis. This permitted multiple, sequential determination of CD8+ T-cell responses in living animals at a very high degree of precision.

In vivo plasmid electroporation induces tumor antigen-specific CD8+ T-cell responses and delays tumor growth in a syngeneic mouse melanoma model.

Plasmid DNA-based molecular cancer vaccines generally suffer from suboptimal immunogenicity. One of the key limitations is insufficient level of gene expression, which was surmounted in our approach by using the novel technique of in vivo plasmid electroporation-enhanced vaccination (electrovaccination). Electrovaccination with plasmids encoding the full-length autologous melanocyte antigen tyrosinase-related protein-2 induced limited melanocyte destruction in a subset of mice.

Structural elements of a protein antigen determine immunogenicity of the embedded MHC class I-restricted T cell epitope.

Substantial effort has been invested into optimization of vector structure, DNA formulation, or delivery methods to increase the effectiveness of DNA vaccines. In contrast, it has been only insufficiently explored how the higher order structure of an antigenic protein influences immunogenicity of embedded epitopes in vivo. Potent CD8+ T cell responses specific for a single immunogenic epitope are induced upon electrovaccination with plasmid DNA encoding the full-length heavy chain of the human HLA-Cw3 molecule.

Activation requirements of circulating antigen-specific human CD8(+) memory T cells probed with insect cell-based artificial antigen-presenting cells.

We sought to define the molecular setup of an antigen-presenting cell that elicits antigen-specific T cell responses in vitro using insect cells that were infected with recombinant baculoviruses. Expression of single-chain HLA was complemented step-by-step with costimulatory molecules, including CD54 and CD80, by co-infection with the relevant viruses. Role of CD8 was assessed by introducing hybrid class I molecules where the alpha-3 domain of the HLA heavy chain molecule was replaced by its murine K(b) counterpart.