Mechanism of Peptide Loading as Revealed by Structure of tapasin/MHC-I Complex

Abstract MHC-I molecules loaded with peptide for subsequent cell surface expression are critical for adaptive immunity. Tapasin, a component in the Peptide Loading Complex (PLC), serves as an MHC-I chaperone, and it facilitates peptide loading onto MHC-I in the endoplasmic reticulum (ER). Although the structure of TAPBPR (a homolog of tapasin) complexed with MHC-I was reported several years ago, the detailed mechanism of peptide loading by tapasin remains unclear. Here, we report the structure of a complex of tapasin with the MHC-I molecule, HLA-B* 44:05. The model of tapasin/HLA-B*44:05 compared with that of unliganded HLA-B*44:05 and to the structure of tapasin bound to ERp57 reveals dramatic changes that refect both chaperone and catalytic activities. Tapasin cradles the MHC-I molecule through contacts with the N-terminal alpha1 and alpha2 domains, as well as with alpha3 and beta-2 microglobulin interaction via its C-terminal IgC domain. Thus the MHC-I molecule is stabilized in a peptide accessible form. We compare this tapasin/HLA-B*44:05 structure with our previously determined structure of TAPBPR/H2-D(d). Although the general dispositions of tapasin and TAPBPR are the same in their complexes with MHC-I, the structural details of their interactions differ. Analyses of tapasin mutants that disrupt the interaction with MHC-I are consistent with the X-ray crystal structure. Thus, the two MHC-I dedicated chaperones, tapasin and TAPBPR, although acting at distinct stages of the MHC-I loading pathway, show broadly conserved binding modes and similar mechanisms of peptide loading in antigen presentation. Supported by the intramural research program of the NIAID, NIH