A modular approach to assembly of totally synthetic self-adjuvanting lipopeptide-based vaccines allows conformational epitope building.

The technology described here allows the chemical synthesis of vaccines requiring correctly folded epitopes and that contain difficult or long peptide sequences. The final self-adjuvanting product promotes strong humoral and/or cell-mediated immunity. A module containing common components of the vaccine (T helper cell epitope and the adjuvanting lipid moiety S-[2,3-bis(palmitoyloxy)propyl]cysteine) was assembled to enable a plug and play approach to vaccine assembly. The inclusion within the module of a chemical group with chemical properties complementary and orthogonal to a chemical group present in the target epitope allowed chemoselective ligation of the two vaccine components. The heat-stable enterotoxin of enterotoxigenic Escherichia coli that requires strict conformational integrity for biological activity and the reproductive hormone luteinizing hormone-releasing hormone were used as the target epitopes for the antibody vaccines. An epitope from the acid polymerase of influenza virus was used to assemble a CD8(+) T cell vaccine. Evaluation of each vaccine candidate in animals demonstrated the feasibility of the approach and that the type of immune response required, viz. antibody or cytotoxic T lymphocyte, dictates the nature of the chemical linkage between the module and target epitope. The use of a thioether bond between the module and target epitope had little or no adverse effect on antibody responses, whereas the use of a disulfide bond between the module and target epitope almost completely abrogated the antibody response. In contrast, better cytotoxic T lymphocyte responses were obtained when a disulfide bond was used.

Modular platforms for the assembly of self-adjuvanting lipopeptide-based vaccines for use in an out-bred population.

To facilitate the preparation of synthetic epitope-based self-adjuvanting vaccines capable of eliciting antibody responses in an out-bred population, we have developed two modular approaches. In the first, the Toll-like receptor 2 agonist Pam2Cys and the target antibody epitope are assembled as a module which is then coupled to a carrier protein as a source of antigens to stimulate T cell help. A vaccine candidate made in this way was shown to induce a specific immune response in four different strains of mice without the need for extraneous adjuvant. In the second approach, three vaccine components in the form of a target antibody epitope, a T helper cell epitope and Pam2Cys, were prepared separately each carrying different chemical functional groups. By using pH-mediated chemo-selective ligations, the vaccine was assembled in a one-pot procedure. Using this approach, a number of vaccine constructs including a lipopeptide-protein conjugate were made and also shown to elicit immune responses in different strains of mice. These two modular approaches thus constitute a powerful platform for the assembly of self-adjuvanting lipopeptide-based vaccines that can potentially be used to induce robust antibody responses in an outbred population. Finally, our study of the impact of chemical linkages on immunogenicity of a lipopeptide vaccine shows that a stable covalent bond between Pam2Cys and a B cell epitope, rather than between Pam2Cys and T helper cell epitope is critical for the induction of antibody responses and biological efficacy, indicating that Pam2Cys functions not only as an adjuvant but also participates in processing and presentation of the immunogen.