A cell-free antigen processing system reveals antigenic factors critical for HIV-1 epitope dominance and informs vaccine design

Abstract Certain CD4+T cell epitopes have been associated with immune control of HIV-1 replication and the presence of anti-Env neutralizing antibodies. However, it remains unclear what antigen-dependent factors influence the dominance of certain epitopes in HIV-1 proteins. To study HIV-1 epitope dominance, we used a cell-free antigen processing system previously developed by our group that utilizes soluble HLA-DR1*01:01 (DR1), HLA-DM (DM), protein antigen and three cathepsins in a reducing and low pH environment to allow for antigen binding and cleavage. We subjected HIV-1 antigens from Gag, Pol, Env and accessory proteins Vif, Nef, Tat, and Rev to this system. Immunoprecipitation of pMHC-II complexes followed by peptide elution and identification via LC-MS/MS revealed a map of DR1-bound epitopes across the near-full length HIV-1 proteome. Most identified epitopes were DM-resistant, and in some cases, DM narrowed the epitope diversity to one species. Importantly, we identified 28 novel epitopes, including several glycopeptides eluted from DR1. We noted epitope “hot spots” in HIV-1 antigens and striking similarities in epitopes from HIV polyproteins (Gag precursor) versus individual subunits (Gag capsid). Analysis of the location of several epitopes from smaller HIV-1 proteins based on their known crystal structures mapped to regions of low protein stability and higher solvent accessibility. Finally, we found that several epitopes induced memory CD4+T cell responses in persons living with HIV-1. Thus, by using a minimalist in vitro processing system, we can interrogate novel HIV-1 epitopes and understand how DM-resistance and antigen structure influence epitope dominance, which has important implications for vaccine design.