Abstract
Although neutralizing epitopes have been identified on the HIV-1 gp120/gp41 envelope complex, efforts to exploit this information through the construction of synthetic peptide vaccines have been largely unsuccessful. Unfortunately, synthetic peptides tend to be poorly immunogenic, and most often lack the conformational characteristics of the corresponding epitope in the native protein. In an effort to circumvent these difficulties, we have utilized an anti-class II MHC antibody as a molecular scaffold for the construction of two conformationally constrained neutralizing HIV-1 epitopes. Previously we demonstrated that anti-class II MHC antibodies can function as vectors for the induction of adjuvant-independent antibody responses to incorporated epitopes. In this instance, one epitope, IHIGPGRAFYT, is the crown of the V3 loop from gp 120, and the other, ELDKWAS, is a neutralizing epitope from gp41. The insertion of these epitopes into a specific loop region of the immunoglobulin heavy chain FR3 was found to preserve the anti-class II MHC-binding activity of these recombinant antibodies, and the inserts were recognized by epitope specific monoclonal antibodies. When utilized as immunogens, each of these epitope insertion antibodies was able to induce high-titer anti-HIV-1 gp160 responses in guinea pigs. These responses were conformation specific in that the anti-gp160 binding was not inhibited by the synthetic peptide corresponding to the epitope in question. These data demonstrate the potential to construct conformationally constrained HIV-1 epitope immunogens, and thus establish an alternative approach to the design of an effective HIV-1 subunit vaccine.
Get full access to this article
View all access options for this article.