First of all, we have broadened the space of neoepitope repertoire beyond point mutations by developing software tools that can detect structural variants, fusion genes and alternative splicing variants in individual patient samples. Furthermore, we have shown that these newly discovered epitopes can elicit an effective T cell response, thus enhancing the options for vaccine design. Also, we have investigated a second crucial step in any discovery pipeline for anti-tumor vaccines, namely the prediction or selection of relevant targets out of the individual mutanome. Both procedures will enable improved vaccine desings for a greater number of patiens.
Secondly, by characterizing tumor heterogeneity and tumor evolution, we have further improved our neoepitope selection algorithms, which will ultimately ensure a more effective vaccine design by adapting to the changed individual mutanome which changes over time through tumor evolution.
Thirdly, we have explored how to counteract tumor resistance to vaccine-induced T-cells. Inhibiting the resistance against T-cell killing will improve vaccine efficacy and lead to a more sustained immune response.