Vaccine engineering: enhancement of immunogenicity of synthetic peptide vaccines related to hepatitis in chemically defined models consisting of T- and B-cell epitopes

Abstract

We report the development of two models for synthetic hepatitis B vaccines. The models were based on the multiple antigen peptide (MAP) system and contained the relevant B- and T-cell epitopes without any macromolecular carrier. Two peptides, representing the a determinant of the S region (S protein) of hepatitis B surface antigen, a dominant serotype of hepatitis B virus infection found in humans, and residues 12-26 of the pre-S(2) region of the middle protein were incorporated as either monoepitope or diepitope MAP models. Immunizations of outbred rabbits with the monoepitope MAP that contains the pre-S(2) antigen resulted in high-titered antibody response to the middle protein, but the other monoepitope, containing only the a-determinant peptide antigen, resulted in poor immune responses to either the peptide antigens or to the S protein. The diepitope MAPs containing both the a and the pre-S(2) determinants produced high-titer antibodies reactive to the a-synthetic peptide and the S protein, as well as to the middle proteins. Thus, our results show that the diepitope MAP models eliminate the need for a protein carrier and that the pre-S(2) peptide determinant serves as a T-helper cell epitope that enhances the immune response of the S region and overcomes the poor immunogenicity encountered with a single epitope of the S region.