Dynamic features of tapasin as revealed by structures of two tapasin/Fab complexes

Abstract

Abstract Intracellular loading of major histocompatibility complex class I (MHC-I) molecules occurs within the peptide loading complex and is accomplished through the concerted action of several proteins, including the chaperone/catalyst tapasin. In the absence of tapasin, peptide loading is compromised, resulting in decreased cell surface expression of some, though not all, MHC-I allelomorphs. To gain a mechanistic understanding of tapasin’s function we have produced recombinant Fab fragments of two anti-tapasin antibodies, PaSta1 and PaSta2, and investigated their binding to human recombinant soluble tapasin by surface plasmon resonance methods and X-ray crystallography. Both antibody Fabs bind with nanomolar affinities characterized by slow off rates. PaSta1 and PaSta2 recognize distinct epitopes as tapasin captured on a surface immobilized with one PaSta Fab binds the other PaSta Fab with nanomolar affinity. However, tapasin captured on a PaSta2 Fab surface is not able to bind peptide/HLA-B*44:05/beta-2 microglobulin complexes while tapasin captured on a PaSta1 Fab surface can, indicating that PaSta2 sterically competes for the MHC-I binding site. This finding was echoed in the structural characterization of PaSta Fab-tapasin complexes by X-ray crystallography. PaSta1 binds to an extended N-terminal region of tapasin, a site accessible even in the tapasin/ERp57 complex. By contrast, PaSta2 binds at the junction of the N-terminal and C-terminal domains of tapasin, where tapasin may interact with HLA-I molecules. Comparison of conformations of tapasin in complex with PaSta1, PaSta2, HLA-B*44:05, and ERp57 reveals the dynamic nature of tapasin, a versatile chaperone and catalyst. Supported by the intramural research program of the NIAID, NIH