MHC class I multimers

T lymphocytes play a key role in the immune response to both foreign and self peptide antigens, which they recognize in combination with MHC molecules. In the past it has been difficult to analyse objectively the specificity, frequency and intensity of T cell responses. The recent application of fluorescent-labelled MHC class I multimers, however, has provided a powerful experimental approach to the direct visualisation of antigen-specific T cells. As a result, our perspective of how T cells respond to both viruses and other antigens in vivo has been greatly enhanced.     

Rethinking peptide supply to MHC class I molecules

The notion that peptides bound to MHC class I molecules are derived mainly from newly synthesized proteins that are defective, and are therefore targeted for immediate degradation, has gained wide acceptance. This model, still entirely hypothetical, has strong intuitive appeal and is consistent with some experimental results, but it is strained by other findings, as well as by established and emerging concepts in protein quality control. While not discounting defectiveness as a driving force for the processing of some proteins, we propose that MHC-class-I-restricted epitopes are derived mainly from nascent proteins that are accessed by the degradation machinery prior to any assessment of fitness, and we outline one way in which this could be accomplished.     

Involvement of CD45 in MHC class II-allospecific cytotoxicity

Twenty-seven different CD45 monoclonal antibodies (mAb) were assessed for their ability to block cytotoxicity of alloreactive CD4+ MHC class II-specific or CD8+ class I-specific human T cell clones (n = 3 and 5, respectively). Twelve of 27 blocked the former but only 1/27 the latter, although all 27 significantly inhibited MHC-unrestricted lysis of K562 cells by either CD4+ or CD8+ clones. MAb pretreatment of effector cells but not target cells resulted in retention of blocking. Crosslinking the CD45 with goat anti-mouse Ig serum did not result in blockade of lysis by class I-specific clones or reveal blocking of class II-specific clones not inhibited by mAb alone. These results suggest that CD45 molecules may be predominantly involved in MHC class II-specific but not class I-specific allocytotoxicity as well as MHC-unrestricted natural killer-like cytotoxicity.     

Processed antigen binds to newly synthesized MHC class II molecules in antigen-specific B lymphocytes

We describe the direct detection of radiolabeled antigen fragments bound to class II MHC molecules following immunoglobulin-mediated endocytosis and processing of native antigen in B lymphoblastoid cells. Tris-Tricine SDS gels revealed six distinct iodinated processing products that could be detected on class II MHC 1 hr after antigen endocytosis and persisted for at least 20 hr. These physiological processed antigen-class II complexes were remarkably stable, as judged by the fact that class II alpha beta dimers, which remain associated in SDS, became labeled with the same set of processed peptides. Using a lectin-binding assay, we show that these physiological processing products bind to the newly maturing population of MHC molecules rather than binding to the preexisting cell surface population; in contrast, an exogenous peptide binds predominantly to the latter population. A direct T cell-independent assay for processed peptide-MHC complex formation should facilitate additional studies on the exogenous antigen processing pathway.     

Analysis of MHC class I genes across horse MHC haplotypes

The genomic sequences of 15 horse major histocompatibility complex (MHC) class I genes and a collection of MHC class I homozygous horses of five different haplotypes were used to investigate the genomic structure and polymorphism of the equine MHC. A combination of conserved and locus-specific primers was used to amplify horse MHC class I genes with classical and nonclassical characteristics. Multiple clones from each haplotype identified three to five classical sequences per homozygous animal and two to three nonclassical sequences. Phylogenetic analysis was applied to these sequences, and groups were identified which appear to be allelic series, but some sequences were left ungrouped. Sequences determined from MHC class I heterozygous horses and previously described MHC class I sequences were then added, representing a total of ten horse MHC haplotypes. These results were consistent with those obtained from the MHC homozygous horses alone, and 30 classical sequences were assigned to four previously confirmed loci and three new provisional loci. The nonclassical genes had few alleles and the classical genes had higher levels of allelic polymorphism. Alleles for two classical loci with the expected pattern of polymorphism were found in the majority of haplotypes tested, but alleles at two other commonly detected loci had more variation outside of the hypervariable region than within. Our data indicate that the equine major histocompatibility complex is characterized by variation in the complement of class I genes expressed in different haplotypes in addition to the expected allelic polymorphism within loci.     

Oligocarbamates as MHC class I ligands

New ligands for major histocompatibility complex (MHC) class I molecules were prepared using a flexible automated synthesis of oligocarbamates. An efficient solution-phase synthesis was found for Fmoc-amino alcohols which are required as building blocks. The biological activity of the oligomeric peptidomimetics was demonstrated in a stabilizing assay with MHC class I presenting cells.     

Oligocarbamates as MHC class I ligands

Summary New ligands for major histocompatibility complex (MHC) class I molecules were prepared using a flexible automated synthesis of oligocarbamates. An efficient solution-phase synthesis was found for Fmoc-amino alcohols which are required as building blocks. The biological activity of the oligomeric peptidomimetics was demonstrated in a stabilizing assay with MHC class I presenting cells.     

Technologies for MHC class I immunoproteomics

T cell epitopes are peptides, for instance derived from foreign, mutated or overexpressed proteins, that are displayed by MHC molecules on the cell surface and that are recognized by T lymphocytes. Knowledge of the identity of epitopes displayed by MHC molecules is of high value for diagnostic purposes and for the development of prophylactic and therapeutic immunotherapy regimens. Here we review key techniques in MHC class I epitope definition and we discuss recent developments in epitope discovery and their implications. Developments in epitope discovery strategies should ultimately lead to the definition of the MHC-associated peptidome.     

Recognition of MHC class I allodeterminants regulates the generation of MHC class II-specific CTL

We have analyzed the signals influencing the generation of major histocompatibility complex (MHC) class II allospecific cytolytic T lymphocytes (CTL) and have found that the development of these CTL is actively regulated in primary in vitro cultures by Lyt-2+ T cells triggered in response to MHC class I alloantigens. Class II allospecific CTL can be readily stimulated in primary cultures, but the presence of a simultaneous class I MHC stimulus in these cultures causes a marked reduction of class II-specific CTL activation. This reduction can be prevented by adding to culture a dose of monoclonal anti-Lyt-2 antibody (in the absence of complement) that does not block the generation of class I-specific CTL. The role of MHC class I alloantigens in the regulation of class II allospecific responses illustrates that T cells recognizing class I and class II MHC antigens in mixed leukocyte cultures interact in a complex and nonreciprocal manner to influence the final effector T cell repertoire elicited by this complex immunogenic challenge.     

Towards a systems understanding of MHC class I and MHC class II antigen presentation

The molecular details of antigen processing and presentation by MHC class I and class II molecules have been studied extensively for almost three decades. Although the basic principles of these processes were laid out approximately 10 years ago, the recent years have revealed many details and provided new insights into their control and specificity. MHC molecules use various biochemical reactions to achieve successful presentation of antigenic fragments to the immune system. Here we present a timely evaluation of the biology of antigen presentation and a survey of issues that are considered unresolved. The continuing flow of new details into our understanding of the biology of MHC class I and class II antigen presentation builds a system involving several cell biological processes, which is discussed in this Review.     

Molecular modelling of MHC class I carbohydrates

In this article we present the results of molecular modelling of four complex carbohydrates which have been found in the MHC class I proteins. Though these proteins show diversity in their sequences, the glycosylation sites are highly conserved indicating a possible structural/functional role of the glycan chain. Similar glycan chains have been found linked with other proteins of completely different function, such as IgG, and erythropoeitin. Thus, the molecular modelling of these carbohydrates will not only provide structural/dynamic information of these complex molecules but will also provide conformational information which can be utilised to build the glycoprotein models. The results presented here indicate that although several linkages show less conformational flexibility, terminal linkages can be quite flexible.     

Processing of MHC class I presented antigens

The immune defences of our organism against pathogens and malignant transformation rely to a large extent on surveillance by cytotoxic T lymphocytes. This surveillance in turn depends on the antigen processing system, which provides peptide samples of the cellular protein composition to MHC (major histocompatibility complex) class I molecules displayed on the cell surface. To continuously and almost in real time provide a representative sample of the array of proteins synthesized by the cell, this system exploits some fundamental pathways of the cellular metabolism, with the help of several dedicated players acting exclusively in antigen processing. Thus, a key element in the turnover of cellular proteins, protein degradation by cytosolic proteasome complexes, is exploited as source of peptides, by recruiting a minor fraction of the produced peptides as ligands for MHC class I molecules. These peptides can be further processed and adapted to the precise binding requirements of allelic MHC class I molecules by enzymes in the cytosol and endoplasmic reticulum. The latter compartment is equipped with several dedicated players helping peptide assembly with class I molecules. These include the TAP (transporter associated with antigen processing) membrane transporter pumping peptides into the ER, and tapasin, a chaperone with a structure similar to MHC molecules that tethers class I molecules awaiting peptide loading to the TAP transporter, and mediates optimization of MHC class I ligand by a still somewhat mysterious mechanism. Additional "house-keeping" chaperones that are known to act in concert in ER quality control, assist and control correct folding, oxidation and assembly of MHC class I molecules. While this processing system handles exclusively endogenous cellular proteins in most cells, dendritic cells employ one or several special pathways to shuttle exogenous, internalized proteins into the system, in a process referred to as cross-presentation. Deciphering the cell biological mechanism creating the link between the endosomal and secretory pathways that enables cross-presentation is one of the challenges faced by contemporary research in the field of MHC class I antigen processing.     

Susceptibility of amphibians to chytridiomycosis is associated with MHC class II conformation

The pathogenic chytrid fungus Batrachochytrium dendrobatidis (Bd) can cause precipitous population declines in its amphibian hosts. Responses of individuals to infection vary greatly with the capacity of their immune system to respond to the pathogen. We used a combination of comparative and experimental approaches to identify major histocompatibility complex class II (MHC-II) alleles encoding molecules that foster the survival of Bd-infected amphibians. We found that Bd-resistant amphibians across four continents share common amino acids in three binding pockets of the MHC-II antigen-binding groove. Moreover, strong signals of selection acting on these specific sites were evident among all species co-existing with the pathogen. In the laboratory, we experimentally inoculated Australian tree frogs with Bd to test how each binding pocket conformation influences disease resistance. Only the conformation of MHC-II pocket 9 of surviving subjects matched those of Bd-resistant species. This MHC-II conformation thus may determine amphibian resistance to Bd, although other MHC-II binding pockets also may contribute to resistance. Rescuing amphibian biodiversity will depend on our understanding of amphibian immune defence mechanisms against Bd. The identification of adaptive genetic markers for Bd resistance represents an important step forward towards that goal.     

Receptor glycosylation regulates Ly-49 binding to MHC class I

Murine NK cells express the Ly-49 family of class I MHC-binding receptors that control their ability to lyse tumor or virally infected host target cells. X-ray crystallography studies have identified two predominant contact sites (sites 1 and 2) that are involved in the binding of the inhibitory receptor, Ly-49A, to H-2D(d). Ly-49G2 (inhibitory) and Ly-49D (activating) are highly homologous to Ly-49A and also recognize H-2D(d). However, the binding of Ly-49D and G(2) to H-2D(d) is of lower affinity than Ly-49A. All Ly-49s contain N-glycosylation motifs; however, the importance of receptor glycosylation in Ly-49-class I interactions has not been determined. Ly-49D and G(2) contain a glycosylation motif (NTT (221-223)), absent in Ly-49A, adjacent to one of the proposed binding sites for H-2D(d) (site 2). The presence of a complex carbohydrate group at this critical site could interfere with class I binding. In this study, we are able to demonstrate for the first time that Ly-49D binds H-2D(d) in the presence of mouse beta(2)-microglobulin. We also demonstrate that glycosylation of the NTT (221-23) motif of Ly-49D inteferes with recognition of H-2D(d). Alteration of the Ly-49D-NTT (221-23) motif to abolish glycosylation at this site resulted in enhanced H-2D(d) binding and receptor activation. Furthermore, glycosylation of Ly-49G2 at NTT (221-23) also reduces receptor binding to H-2D(d) tetramers. Therefore, the addition of complex carbohydrates to the Ly-49 family of receptors may represent a mechanism by which NK cells regulate affinity for host class I ligands.     

Peptide presentation by MHC class I molecules

The presentation of peptides by class I histocompatibility molecules plays a central role in the cellular immune response to virally infected or transformed cells. The main steps in this process include the degradation of both self and 'foreign' proteins to short peptides in the cytosol, translocation of peptides into the lumen of the endoplasmic reticulum, binding of a subset of peptides to assembling class I molecules and expression of class-I-peptide complexes at the cell surface for examination by cytotoxic T cells. A molecular understanding of most of these steps is emerging, revealing a remarkable coordination between the processes of peptide translocation, delivery and binding to class I molecules.     

Molecular cloning of bovine class I MHC cDNA

Two cDNA cloned from a Hereford cow B cell line (BL-3) have allowed the determination of the complete coding region for two class I molecules encoded by the bovine MHC (BoLA). The predicted protein sequences have all the features expected of expressed class I molecules that present peptide Ag to cytotoxic T cells. Comparison with class I molecules from other species strongly suggests these cDNA are derived from different genes and provides evidence for the existence of a second expressed class I BoLA locus. The BoLA proteins show greater similarity to HLA than to H-2 molecules, correlating with the cross-reactions of W6/32 and other murine anti-HLA-A,B,C mAb with BoLA molecules. The basis for the W6/32 epitope and the preferential association of H-2 class I H chains with bovine beta 2-m is examined.     

Carbohydrate moieties of rat MHC class I antigens

The rat major histocompatibility complex class I antigens RT1.A^u and RT1.E^u from the u haplotype and RT1.Aⁿ from the n haplotype were labeled with ¹⁴C-asparagine or with ³H-fucose, mannose, galactose, and N-acetylglucosamine. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed complete removal of radioactivity from the sugar-labeled antigen heavy chains by digestion with glycopeptidase F, an enzyme that removes N-linked glycans completely. High performance liquid chromatography analysis of the tryptic digests of the mixed sugar-labeled and asparagine-labeled antigens demonstrated that all the sugar-labeled peptides were coincident with asparagine-labeled peptides. The Aⁿ antigen showed three glycopeptides, each of which had different amounts of sugar radioactivity. The antigens A^u and E^u showed two glycopeptides with different amounts of radioactivity but at identical positions in the two antigens. Antigen E^u had an additional glycopeptide with a lower amount of radioactivity. The positions of the glycopeptides from the A^u and E^u antigens were different from those of the Aⁿ antigen. The peptide profiles of the ¹⁴C-asparagine-labeled A^u and E^u antigens demonstrated distinct differences between the molecules. The results of this study show that: (a) all the glycans on rat class I antigens are N-linked, as they are on H-2 and HLA class I antigens; (b) there are compositional differences among the glycans in each of the three antigens; (c) the glycosylation pattern of the rat class I antigens is similar to that of the mouse class I antigens, which contain two or three glycans, in contrast to that of the human class I antigens, which contain only one glycan; and (d) the antigens A^u and E^u from the same haplotype are more closely related to each other than they are to the Aⁿ antigen.