Processing of antigens for presentation to helper T cells by MHC class II involves HLA-DM (DM) and HLA-DO (DO) accessory molecules. A mechanistic understanding of DO in this process has been missing. The leading model on its function proposes that DO inhibits the effects of DM. To directly study DO functions, we designed a recombinant soluble DO and expressed it in insect cells. The kinetics of binding and dissociation of several peptides to HLA-DR1 (DR1) molecules in the presence of DM and DO were measured. We found that DO reduced binding of DR1 to some peptides, and enhanced the binding of some other peptides to DR1. Interestingly, these enhancing and reducing effects were observed in the presence, or absence, of DM. We found that peptides that were negatively affected by DO were DM-sensitive, whereas peptides that were enhanced by DO were DM-resistant. The positive and negative effects of DO could only be measured on binding kinetics as peptide dissociation kinetics were not affected by DO. Using Surface Plasmon Resonance, we demonstrate direct binding of DO to a peptide-receptive, but not a closed conformation of DR1. We propose that DO imposes another layer of control on epitope selection during antigen processing.
Helper T cells are stimulated to fight infections or diseases upon recognition of peptides from antigens that are processed and presented by the proteins of Major Histocompatibility Complex (MHC) Class II molecules. Degradation of a full protein into small peptide fragments is a lengthy process consisting of many steps and chaperones. Malfunctions during any step of antigen processing could lead to the development of self-reactive T cells or defective immune response to pathogens. Although much has been accomplished regarding how antigens are processed and presented to T cells, many questions still remain unanswered, preventing the design of therapeutics for direct intervention with antigen processing. Here, we review published work on the discovery and function of a MHC class II molecular chaperone, HLA-DO, in human, and its mouse analog H2-O, herein called DO. While DO was originally discovered decades ago, elucidating its function has proven challenging. DO was discovered in association with another chaperone HLA-DM (DM) but unlike DM, its distribution is more tissue specific, and its function more subtle.
HLA-DM is now known to have a major contribution to the selection of immunodominant epitopes. A better understanding of the mechanisms controlling epitope selection can be achieved by examination of the biophysical behavior of major histocompatibility complex (MHC) class II molecules upon binding of antigenic peptides and the effect of DM on the interactions. Using purified soluble molecules, in this chapter, we describe several in vitro methods for measuring peptide binding to HLA-DR molecules and the effects of HLA-DM on the interactions. A simple qualitative method, Gentle SDS-PAGE Assay, would assess the ability of peptides to form tight complexes with MHC class II molecules. Measuring binding kinetics is among the most informative approaches to understanding molecular mechanisms, and here we describe two different methods for measuring binding kinetics of peptide-MHC complexes. In one method, rates of association and dissociation of fluorescently labeled peptides to soluble MHC class II molecules can be determined using G50 spin columns to separate unbound peptides from those in complex with MHC molecules. In another method, association and dissociation of unlabeled peptides and MHC class II molecules can be determined in real time using BIAcore surface plasmon resonance (SPR). We also have described an Intrinsic Tryptophan Fluorescence Assay for studying transient interactions of DM and MHC class II molecules.
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