Diphtheria Toxoid-Derived T-Helper Epitope and α-galactosylceramide Synergistically Enhance the Immunogenicity of Glycopeptide Antigen.

The tumor-associated antigen MUC1 is an attractive target for immunotherapy, however, its weak immunogenicity limits the induction of antitumor immune responses. To overcome this limitation, in this study, MUC1 glycopeptide was covalently linked with a diphtheria toxin-derived T-helper epitope (DT). Subsequently, the resulting DT-MUC1 glycopeptide was physically mixed with natural killer T cell agonist αGalCer to explore their immunomodulatory synergy. Biological results demonstrated that compared to MUC1+αGalCer and DT-MUC1 groups, the specific IgG antibody titer of DT-MUC1+αGalCer group increased by 189- and 3-fold, respectively, indicating that the diphtheria toxin-derived T-helper epitope synergistically enhanced MUC1 immunogenicity with αGalCer. Moreover, the DT-MUC1+αGalCer vaccine induced potent cellular immune responses and significantly inhibited the growth of B16-MUC1 tumors in vivo. Furthermore, it was found that the -MUC1 IgG antibody titer induced by DT-MUC1+αGalCer was equivalent to that induced by palmitoylated DT-MUC1+αGalCer (P1-DT-MUC1+αGalCer) and significantly higher than that induced by doubly palmitoylated DT-MUC1+αGalCer (P2-DT-MUC1+αGalCer), suggesting that the easily synthesized DT-MUC1 may not require lipid chain modification and already possess good amphiphilicity. This is the first time that a diphtheria toxin-derived helper T-helper epitope was covalently linked to a glycopeptide antigen to enhance its immunogenicity, and this study may provide an effective vaccine design strategy for MUC1-targeted antitumor vaccines and offer novel insights into the design of fully synthetic peptide vaccines.