A specific, irreversible and cost-effective topical microbicide for HIV prophylaxis will help slow sexual transmission of the pandemic. Here, we propose the development of catalytic antibodies capable of degrading the HIV envelope protein gp120 as candidate HIVcides. The promising features of the antibodies are the permanent destruction of the envelope protein, reuse of a single catalyst molecule to degrade thousands of gp120 molecules and the recognition of a conserved gp120 region, the superantigen region, permitting neutralization of diverse HIV strains. Polyclonal antibody studies from uninfected and HIV infected subjects indicated that high level proteolytic and HIV neutralizing activities is a noteworthy property of IgA class antibodies. In the R21 project phase, characterization of our existing antibodies and their single chain Fv (scFv), IgA and IgG variants is proposed. The existing antibodies were obtained as IgGs by immunization with an electrophilic gp120 analog that induces antibodies with enhanced nucleophilic reactivity, a prerequisite for the catalytic reaction. Using an electrophilic probe to the gp120 superantigen site, additional proteolytic antibodies were obtained as scFv constructs cloned from the immune repertoire of lupus patients, who tend to produce antibodies with proteolytic activity directed to the gp120 superantigen site. The antibodies will be characterized with respect to HIV degrading efficiency; specificity, potency and breadth of HIV neutralization; and the ability to perform these functions in the vaginal milieu. To isolate novel, improved antibodies, we will screen the proteolytic and HIV neutralizing activity of salivary and serum IgAs from HIV-negative and HIV-positive subjects in the R21 project phase. In the R33 phase, monoclonal IgAs with the desired properties will be cloned from lymphocytes by cell-fractionation based on covalent binding of an electrophilic gp120 peptide analog, a property associated with proteolytic antibody-producing cells. Proof-of-principle for in vivo antibody efficacy will be obtained in the R33 phase using the SHIV-macaque model of infection. The Abs will also be examined for activity in vitro as microbicide excipient formulations under conditions simulating the vaginal environment following sexual intercourse. These studies may identify proteolytic antibodies suitable for further development as a topical HIVcide. ? ? ?
Planque, Stephanie A; Mitsuda, Yukie; Nishiyama, Yasuhiro et al. (2012) Antibodies to a superantigenic glycoprotein 120 epitope as the basis for developing an HIV vaccine. J Immunol 189:5367-81 |
Sapparapu, Gopal; Planque, Stephanie; Mitsuda, Yukie et al. (2012) Constant domain-regulated antibody catalysis. J Biol Chem 287:36096-104 |
Hanson, Carl V (2011) Vaccinogenicity. AIDS 25:581-4 |
Planque, Stephanie; Salas, Maria; Mitsuda, Yukie et al. (2010) Neutralization of genetically diverse HIV-1 strains by IgA antibodies to the gp120-CD4-binding site from long-term survivors of HIV infection. AIDS 24:875-84 |
Paul, Sudhir; Planque, Stephanie; Nishiyama, Yasuhiro et al. (2010) Back to the future: covalent epitope-based HIV vaccine development. Expert Rev Vaccines 9:1027-43 |
Paul, Sudhir; Planque, Stephanie A; Nishiyama, Yasuhiro et al. (2009) A covalent HIV vaccine: is there hope for the future? Future Virol 4:7-10 |
Planque, Stephanie; Nishiyama, Yasuhiro; Taguchi, Hiroaki et al. (2008) Catalytic antibodies to HIV: physiological role and potential clinical utility. Autoimmun Rev 7:473-9 |
Nishiyama, Yasuhiro; Mitsuda, Yukie; Taguchi, Hiroaki et al. (2007) Towards covalent vaccination: improved polyclonal HIV neutralizing antibody response induced by an electrophilic gp120 V3 peptide analog. J Biol Chem 282:31250-6 |