Peptide binding to active class II MHC protein on the cell surface

Solution studies have demonstrated the existence of two functionally distinct isomers of empty class II MHC: an active isomer that binds peptide and an inactive isomer that does not. Empty MHC molecules on the surface of APCs can load antigenic peptides directly from the extracellular medium, facilitating the generation of a diverse peptide repertoire for T cell presentation. In this report, we examine I-Ek on the surface of Chinese hamster ovary cells with respect to the active and inactive isomers. As in the case of purified soluble active I-Ek, active I-Ek on the cell surface is unstable, decaying to the inactive form in approximately 14 min. Evidence is presented suggesting that at steady state <1% of the total cell surface I-Ek is active and that a significant fraction of these active molecules originates from intracellular pools as well as reactivation of inactive cell surface I-EK.     

MHC class II invariant chains in antigen processing and presentation

Most protein antigens cannot elicit a T-cell response unless they are processed to peptides, which are then presented to T lymphocytes by surface MHC class II molecules. Recent evidence supports an essential role of the invariant chain associated with class II MHC polypeptides in antigen processing.     

Hydrogen bond integrity between MHC class II molecules and bound peptide determines the intracellular fate of MHC class II molecules.

MHC class II molecules associate with peptides through pocket interactions and the formation of hydrogen bonds. The current paradigm suggests that the interaction of side chains of the peptide with pockets in the class II molecule is responsible for the formation of stable class II-peptide complexes. However, recent evidence has shown that the formation of hydrogen bonds between genetically conserved residues of the class II molecule and the main chain of the peptide contributes profoundly to peptide stability. In this study, we have used I-A(k), a class II molecule known to form strong pocket interactions with bound peptides, to probe the general importance of hydrogen bond integrity in peptide acquisition. Our studies have revealed that abolishing hydrogen bonds contributed by positions 81 or 82 in the beta-chain of I-A(k) results in class II molecules that are internally degraded when trafficked through proteolytic endosomal compartments. The presence of high-affinity peptides derived from either endogenous or exogenous sources protects the hydrogen bond-deficient variant from intracellular degradation. Together, these data indicate that disruption of the potential to form a complete hydrogen bond network between MHC class II molecules and bound peptides greatly diminishes the ability of class II molecules to bind peptides. The subsequent failure to stably acquire peptides leads to protease sensitivity of empty class II molecules, and thus to proteolytic degradation before export to the surface of APCs.     

Endosomal sorting of MHC class II determines antigen presentation by dendritic cells

Dendritic cells (DCs) initiate primary immune responses by presenting pathogen-derived antigens in association with major histocompatibility Class II molecules (MHC II) to T cells. In DCs, MHC II is constitutively synthesized and loaded at endosomes with peptides from hydrolyzed endogenous proteins or exogenously acquired antigens. Whether peptide loaded MHC II (MHC II-p) is subsequently recruited to and stably expressed at the plasma membrane or degraded in lysosomes is determined by the status of the DC. In immature DCs, MHC II-p is ubiquitinated after peptide loading, driving its sorting to the luminal vesicles of multivesicular bodies. These luminal vesicles, and the MHC II-p they carry, are delivered to lysosomes for degradation. MHC II-p is inefficiently ubiquitinated in DCs that are activated by pathogens or inflammatory stimuli, thus allowing its transfer to and stable expression at the plasma membrane.     

Early human T cell activation events with engagement of surface MHC class II

Major histocompatibility complex (MHC) class II are expressed on most activated human lymphocytes. They direct antigen presentation events in dendritic cells and B cells (collectively called antigen presenting cells), but the role for MHC class II in human T cells is not well understood. To understand the role of surface MHC class II and to identify the molecules involved in signaling, we have defined the early activation sequence in T cells when MHC class II are engaged by a specific antibody. Specifically, we have characterized the involvement of phosphotyrosine kinases, phospholipase C (PLC), and Ca²⁺ mobilization. With the engagement by either whole anti-class II antibody or its Fab fragments, the enzymatic activity of p56^lck and ZAP-70 increased, but there was no increase in p59^fyn activity. In addition, the intracellular free Ca²⁺ increased, which was due to enhanced influx and not to the mobilization of intracytoplasmic Ca²⁺. These events did not require cross-linking because they were not significantly augmented by the addition of antispecies antibody. The coimmunoprecipitation of tyrosine phosphorylated PLC-γ1 with surface MHC class II suggested that PLC-γ1 could be recruited to MHC class II after engagement. These results show the complexities of the early signals transduced by the engagement of surface MHC class II on T cells. J. Cell. Biochem. 70:346–353, 1998. © 1998 Wiley-Liss, Inc.     

Immunodominance: intermolecular competition between MHC class II molecules by covalently linked T cell epitopes.

The T cell response to complex protein Ag typically focuses on a few, and frequently a single, immunodominant epitope. Several groups have proposed that the mechanism of immunodominance is determined by the steps of Ag processing and presentation including protein unfolding, the sites of proteolytic cleavage, and the affinity of binding to MHC molecules. Also, the failure of the TCR repertoire to recognize MHC-bound peptides, termed a hole in the repertoire, can prevent recognition of a potentially dominant processed peptide. In the present study, we demonstrate that immunodominance can be determined by intermolecular competition for binding to MHC class II molecules between covalently linked T cell epitopes. In addition, we have analyzed the factors controlling T cell recognition of the covalently linked epitopes. In our system, T cell recognition of the dominant epitope is not altered by Ag processing, and is not simply a function of MHC-binding affinity. We propose that adjacent sequences can subtly alter the conformation of an epitope, creating significant changes in T cell recognition. These observations are discussed in terms of the mechanisms of immunodominance and in terms of the development of synthetic peptide vaccines.     

Polymorphism of the MHC class II Eb gene determines the protection against collagen-induced arthritis

Collagen-induced arthritis (CIA) is an animal model of auto immune polyarthritis, sharing similarities with rheumatoid arthritis (RA). Paradoxally, susceptibility to mouse CIA is controlled by the H2A loci (DQ homologous) while RA is linked to HLA.DR genes (H2E homologous). We recently showed that the E^d molecule prevents CIA development in susceptible H2 ^q mice. We addressed the question of whether H2Eb polymorphism will influence CIA incidence as HLA.DRB1 polymorphism does in RA. In F₁ mice, only H2Eb^d and H2Eb^s molecules showed protection. Using recombinant B10.RDD (Eb ^d/b) mice, we found that CIA protection was mediated by the first domain of the E^d molecule. Using peptides covering the third hypervariable region of the E chain, we found a perfect correlation between presentation of E peptides by the H2A^q molecule and protection on CIA. Therefore, the mechanism by which H2Eb protects against CIA seems to rely on the affinity of E peptides for the H2A_q molecule.     

Direct vesicular transport of MHC class II molecules from lysosomal structures to the cell surface

Newly synthesized MHC class II molecules are sorted to lysosomal structures where peptide loading can occur. Beyond this point in biosynthesis, no MHC class II molecules have been detected at locations other than the cell surface. We studied this step in intracellular transport by visualizing MHC class II molecules in living cells. For this purpose we stably expressed a modified HLA-DR1 beta chain with the Green Fluorescent Protein (GFP) coupled to its cytoplasmic tail (beta- GFP) in class II-expressing Mel JuSo cells. This modification of the class II beta chain does not affect assembly, intracellular distribution, and peptide loading of the MHC class II complex. Transport of the class II/ beta-GFP chimera was studied in living cells at 37 degrees C. We visualize rapid movement of acidic class II/beta- GFP containing vesicles from lysosomal compartments to the plasma membrane and show that fusion of these vesicles with the plasma membrane occurs. Furthermore, we show that this transport route does not intersect the earlier endosomal pathway.     

MHC class II tetramers

MHC class II tetramers have emerged as an important tool for characterization of the specificity and phenotype of CD4 T cell immune responses, useful in a large variety of disease and vaccine studies. Issues of specific T cell frequency, biodistribution, and avidity, coupled with the large genetic diversity of potential class II restriction elements, require targeted experimental design. Translational opportunities for immune disease monitoring are driving the rapid development of HLA class II tetramer use in clinical applications, together with innovations in tetramer production and epitope discovery.     

Dendritic cell activation prevents MHC class II ubiquitination and promotes MHC class II survival regardless of the activation stimulus

The expression of MHC class II (MHC-II) on the surface of antigen-presenting cells, such as dendritic cells (DCs), is tightly regulated during cellular activation. Many cells, including DCs, are activated following stimulation of innate Toll-like receptors (TLRs) by products of microorganisms. In the resting (immature) state, MHC-II is ubiquitinated in immature DCs and is rapidly degraded; however, after activation of these cells with MyD88-dependent TLR ligands, MHC-II ubiquitination is blocked, and MHC-II survival is prolonged. We now show that DC activation using MyD88-dependent TLR ligands, MyD88-independent TLR ligands, and even infection with the intracellular parasite Toxoplasma gondii leads to identical changes in MHC-II expression, ubiquitination, and surface stability, revealing a conserved role for enhanced MHC-II stability after DC activation by different stimuli.     

Newly synthesized class II MHC chains are required for VSV G presentation to CTL clones.

Mechanisms of antigen processing and presentation to thymus-derived lymphocytes have been under intense study for several years, focusing on both Class I-restricted antigen presentation and Class II-MHC restricted responses. The studies described here examine the processing and presentation of exogenously provided soluble glycoprotein of the vesicular stomatitis virus and as well as newly synthesized viral glycoprotein. Evidence is provided that newly synthesized Class II MHC chains are required for cell surface expression of processed glycoprotein determinants irrespective of the origin of the viral antigen. Inhibitors of distinct cellular processes, including ammonium chloride, emetine, and Brefeldin A, have been used to dissect the pathways utilized.     

Anchor side chains of short peptide fragments trigger ligand-exchange of class II MHC molecules

Class II MHC molecules display peptides on the cell surface for the surveillance by CD4+ T cells. To ensure that these ligands accurately reflect the content of the intracellular MHC loading compartment, a complex processing pathway has evolved that delivers only stable peptide/MHC complexes to the surface. As additional safeguard, MHC molecules quickly acquire a 'non-receptive' state once they have lost their ligand. Here we show now that amino acid side chains of short peptides can bypass these safety mechanisms by triggering the reversible ligand-exchange. The catalytic activity of dipeptides such as Tyr-Arg was stereo-specific and could be enhanced by modifications addressing the conserved H-bond network near the P1 pocket of the MHC molecule. It affected both antigen-loading and ligand-release and strictly correlated with reported anchor preferences of P1, the specific target site for the catalytic side chain of the dipeptide. The effect was evident also in CD4+ T cell assays, where the allele-selective influence of the dipeptides translated into increased sensitivities of the antigen-specific immune response. Molecular dynamic calculations support the hypothesis that occupation of P1 prevents the 'closure' of the empty peptide binding site into the non-receptive state. During antigen-processing and -presentation P1 may therefore function as important "sensor" for peptide-load. While it regulates maturation and trafficking of the complex, on the cell surface, short protein fragments present in blood or lymph could utilize this mechanism to alter the ligand composition on antigen presenting cells in a catalytic way.     

Invariant chain alters the malignant phenotype of MHC class II+ tumor cells.

T lymphocytes usually recognize endogenously encoded Ag in the context of MHC class I molecules, whereas exogenous Ag is usually presented by MHC class II molecules. In vitro studies in model systems suggest that presentation of endogenous Ag by class II molecules is inhibited by the association of class II with its invariant chain (Ii). In the present study we test this hypothesis in an in vivo system in which endogenously encoded tumor peptides are presented by tumor cell MHC class II molecules. In this system, transfection of syngeneic MHC class II genes (Aak and Abk) into a highly malignant, Ii negative, mouse tumor (SaI sarcoma) produces an immunogenic tumor (SaI/Ak) that is rejected by the autologous host. The class II+ transfectants also effectively immunize autologous A/J mice against a subsequent challenge of wild-type class II- tumor cells. We have hypothesized that the SaI/Ak transfectants induce protective immunity because they function as APC for endogenously synthesized tumor peptides, and thereby stimulate tumor-specific Th cells, by-passing the need for professional APC. To test the role of Ii as an inhibitor of presentation of endogenous peptides, SaI/Ak tumor cells were supertransfected with Ii gene (SaI/Ak/Ii cells), and the tumorigenicity of the resulting cells determined. Nine SaI/Ak/Ii clones were tested, and their malignancy compared with that of SaI/Ak and SaI cells. Seven of the nine class II+/Ii+ tumor cells are more malignant than class II+/Ii- tumor cells in autologous A/J mice. Expression of Ii therefore restores the malignant phenotype, presumably by preventing presentation of endogenously synthesized tumor peptides. Ii therefore regulates Ag presentation and can be a critical parameter for in vivo tumor immunity.     

Physical association between MHC class I and class II molecules detected on the cell surface by flow cytometric energy transfer

The physical association of HLA class I and class II Ag in the membranes of PGF and JY lymphoblastoid cell lines was studied using flow cytometric energy transfer. This technique measures the proximity of cell surface molecules in the nm range and provides a distribution histogram of the average proximity of molecules on each cell of a population. HLA Ag were labeled with mAb conjugated to fluorescein, serving as donor, or tetramethylrhodamine, serving as acceptor molecules. Significant fluorescence energy transfer was detected between various combinations of class I and class II molecules indicating that these molecules are within 10 nanometers of each other. Specifically, energy transfer was observed between class I molecules and DR, DQ, or DP class II HLA molecules. In addition, energy transfer between all combinations of DR, DQ, and DP molecules was observed. No transfer was observed among class I molecules or among DR or among DP molecules. Among DQ molecules, subpopulations transferred fluorescence energy to each other. The close contact measured between class I and class II Ag correlates with previous reports of cocapping and may reflect an immunologically significant interaction or the reported tendency of class I Ag to associate with other cell surface receptors, including growth factor receptors. The energy transfer between fluorescent antibodies to class II Ag suggests the existence of heterodimers formed from the different locus products, as well as possible quaternary surface interactions between alpha/beta complexes from separate loci.     

Type analysis of oligosaccharide chains on human and murine MHC class II alpha chains by the lectin-nitrocellulose sheet method

1. The microheterogeneous alpha molecules of class II antigen, DR molecules obtained from human B cell line and I-A molecules from mouse B cell hybridoma cell line, were separated by 2-D PAGE, transferred onto NC sheets and N-linked oligosaccharide types were analyzed by staining with P.O./lectins. 2. This is the first report to show directly the type of oligosaccharide chain corresponding to each spot separated by 2-D PAGE. The glycosylation patterns of class II alpha chains in human and mouse were compared.