In silico functional analysis of the human, chimpanzee, and gorilla MHC-A repertoires

T cells recognize peptides displayed on the surface of cells on MHC molecules. Genetic variation in MHC genes alters their peptide-binding repertoire and thus influences the potential immune response generated against pathogens. Both gorillas and chimpanzees show reduced diversity at their MHC class I A (MHC-A) locus compared to humans, which has been suggested to be the result of a pathogen-mediated selective sweep. More specifically, gorillas lack A3 lineage alleles while chimpanzees seem to have lost the A2 lineage. While previous studies showed this using phylogenetic analysis, here, we take an in silico functional approach and use the peptide-MHC binding prediction software NetMHCpan to examine the peptide-binding repertoires of common human, chimpanzee, and gorilla MHC-A molecules. We find that both gorillas and chimpanzees lack the A02 peptide binding specificity (supertype) despite gorillas being expected to have this specificity since they kept the A2 lineage. Additionally, we show that human MHC molecules with the A02 specificity bind fewer virus-derived peptides than other MHC molecules. We also do not find differential presentation of self-peptides by the A02 supertype, making the purpose of maintaining this specificity in high frequencies in the human population unclear. Taken together, we hypothesize that poor presentation of viral peptides by A02 supertype MHC molecules could have resulted in a selective sweep in chimpanzees and/or gorillas, though we could not identify a specific virus that may have caused this sweep.