Atom-level mechanism of tapasin-independent peptide editing by Major Histocompatibility Complex class I molecules

Peptide binding to major histocompatibility complex class I molecules (MHC-I) and their presentation to cytotoxic immune cells is a keystone of the adaptive immune system. The selection of MHC-I bound peptides is facilitated by the chaperone tapasin, which allows MHC-I to iteratively sample peptides until they are loaded with optimal binding peptides, known as peptide editing. However, some MHC-I allotypes can select high affinity binding peptides independently of tapasin, and the molecular mechanism(s) for such peptide editing are unknown. Here, we used enhanced sampling molecular dynamics simulations of peptide-deficient MHC-I to investigate tapasin-independent peptide editing. Our simulations revealed transient disruption of hydrogen bonds between MHC-I and the peptide backbone could allow for peptide editing, a process we term "active displacement". Destabilisation of interactions with the peptide backbone, necessitates sequence-specific sidechain interactions to maintain peptide binding. Our active displacement model predicts surface expression levels for multiple MHC-I allotypes and accounts for the presentation of an immunogenic mutant KRAS-G12D neoepitope by HLA-C*08:02, but not by closely related HLA-C*05:01. Together our data provide a molecular mechanism for tapasin-independent MHC-I peptide editing, influencing the surface immunopeptidome and anti-tumour immunity.