Development of a potent melanoma vaccine capable of stimulating CD8 super(+) T-cells independently of dendritic cells in a mouse model

At present, there are no vaccines approved for the prevention or treatment of malignant melanoma, despite the amount of time and resources that has been invested. In this study, we aimed to develop a self-contained vaccine capable of directly stimulating anticancer CD8 super(+) T-cell immune responses. To achieve this, three whole-cell melanoma vaccines were developed expressing 4-1BBL or B7.1 T-cell co-stimulatory molecules individually or in combination. The ability of engineered vaccine cell lines to stimulate potent anticancer immune responses in C57BL/6 mice was assessed. Mice vaccinated with cells overexpressing both 4-1BBL and B7.1 (B16-F10-4-1BBL-B7.1-IFN gamma / beta anticancer vaccine) displayed the greatest increases in CD8 super(+) T-cell populations (1.9-fold increase versus control within spleens), which were efficiently activated following antigenic stimulation, resulting in a 10.7-fold increase in cancer cell cytotoxicity relative to control. The enhanced immune responses in B16-F10-4-1BBL-B7.1-IFN gamma / beta -vaccinated mice translated into highly efficient rejection of live tumour burdens and conferred long-term protection against repeated tumour challenges, which were likely due to enhanced effector memory T-cell populations. Similar results were observed when dendritic cell (DC)-deficient LT alpha super(-/-) mice were treated with the B16-F10-4-1BBL-B7.1-IFN gamma / beta anticancer vaccine, suggesting that the vaccine can directly stimulate CD8 super(+) T-cell responses in the context of severely reduced DCs. This study shows that the B16-F10-4-1BBL-B7.1-IFN gamma / beta anticancer vaccine acted as a highly effective antigen-presenting cell and is likely to be able to directly stimulate CD8 super(+) T-cells, without requiring co-stimulatory signals from either CD4 super(+) T-cells or DCs, and warrants translation of this technology into the clinical setting.