MHC class II signaling in antigen-presenting cells

The MHC class II molecules have been recognized as signaling receptors for more than a decade, and recent work has revealed the importance of their signaling for the immune response. Today, we know that the function of MHC class II molecules on antigen-presenting cells (APCs) is not limited to their role as antigen-presenting structures; they are flexible receptors that, by triggering a variety of signaling pathways, can regulate APC activities from proliferation and maturation to apoptosis. Recent advances have provided insights into how these molecules might accommodate such regulation.     

MHC class II signaling function is regulated during maturation of plasmacytoid dendritic cells

Dendritic cells (DC) play a central role in the immune response, linking innate and adaptative responses to pathogens. Myeloid DC (MDC) produce interleukin-12 in response to bacterial stimuli, whereas plasmacytoid DC (PDC) produce high levels of type I interferon upon viral infection. Human leukocyte antigen (HLA)-DR engagement has been shown to induce apoptosis in various antigen-presenting cells (APC). We now report the consequences of HLA-DR molecule engagement in human PDC, which had thus far not been studied as a result of the difficulty in isolating such cells. HLA-DR engagement on PDC, obtained using a two-step, immunomagnetic separation, led to recruitment of HLA-DR molecules at the site of engagement in mature but not immature PDC. In contrast, relocalization of protein kinase C (PKC) isoenzymes, indicating PKC activation, was observed at the site of HLA-DR engagement and was accompanied by relocalization of a lipid raft marker, the ganglioside M1 staining, in immature and mature PDC. Similar to MDC, HLA-DR-mediated apoptosis was regulated throughout PDC maturation. Freshly isolated PDC were resistant, whereas CD40 ligand-matured PDC were sensitive to HLA-DR-mediated apoptosis. Neither caspase activation nor PKC activation was required for HLA-DR-mediated apoptosis. However, the intrinsic pathway of apoptosis was implicated as mature PDC underwent mitochondrial depolarization in response to HLA-DR engagement. These data provide further arguments for considering HLA-DR-mediated apoptosis as a conserved mechanism of regulating survival of diverse APC and support the ongoing development of humanized ligands for HLA class II molecules as therapeutic tools for use in lymphoproliferative disease.     

Structural principles of MHC class II antigen presentation

Normal immune surveillance depends on the ability of MHC class II molecules to bind peptide antigens and carry them to the cell surface for display to T cells. To do this efficiently, class II molecules must be able to bind peptides from a broad array of antigen sequences and retain them at the cell surface long enough for T-cell recognition to occur. Class II molecules accomplish this task through a combination of clever structural biochemistry and the help of at least two different molecular chaperones: the class II-associated invariant chain (Ii); and a non-peptide binding class II molecule termed H2-DM in mouse and HLA-DM in man (DM). Here, we compare the existing 3-dimensional structures of class II-peptide complexes in order to review the general principles of peptide binding and presentation. We extend this analysis to include the structures of proteins known to interact with MHC class II, focusing primarily on the Ii chain and DM.     

MHC class II isotype-specific signaling complex on human B cells

The highly polymorphic human major histocompatibility complex (HLA) class II molecules are acknowledged as signaling receptors although their coupling to signaling pathways is not yet fully elucidated. In this study, we investigated how HLA class II can be coupled to protein tyrosine kinase (PTK) signaling pathway in B cells and whether there might be differences depending on HLA class II isotype. Using the human B cell line Ramos, we demonstrate that CD19 and CD20 are two HLA class II-associated receptors that couple HLA class II to PTK signaling pathway where CD20 appears to be amajor component of HLA class II-mediated activation of Src kinases. Both HLA-DR and HLA-DP co-immunoprecipitate tyrosine-phosphorylated proteins (p-Tyr) whereas only activation through HLA-DR increases the tyrosine phosphorylation of these proteins. Indeed, in contrast to HLA-DR, cross-linking HLA-DP induces neither tyrosine phosphorylation nor homotypic adhesion, and induces ERK1/2 activation. Differential association of these isotypes with CD20 appears to be one of the mechanisms underlying their differential signaling. We provide an experimental evidence for a mechanism by which HLA class II molecules can be coupled to PTK signaling pathway and, underscores their isotypes differential signaling. Further investigation of these mechanisms is likely to provide new insights into how isotype specific MHC class II signaling can contribute to the regulation of the immune response.     

MHC class II compartment subtypes: structure and function

Reports from the past couple of years point to an emerging association of the biogenesis, composition and ultrastructural morphology of MHC class II compartments (MIICs) with their functions in antigen processing and loading. Growth factors and cytokines involved in dendritic cell maturation have been shown to regulate MIIC biogenesis, and the MHC-class-II-associated invariant chain chaperone has been reported to regulate endosomal morphology and vacuolation. Differences among ultrastructurally distinct MIICs have begun to be appreciated with regard to variation in antigen loading capacity and to polarization of MHC class II conformational variants among different compartments. Finally, the MIIC ultrastructure organizes the mechanism of MHC class II surface trafficking. Together, these findings begin to shed light on the connection between MIIC protein content, MIIC morphology and MHC class II-related antigen processing.     

B cell MHC class II signaling: A story of life and death

MHC class II regulates B cell activation, proliferation, and differentiation during cognate B cell-T cell interaction. This is, in part, due to the MHC class II signaling in B cells. Activation of MHC Class II in human B cells or “primed” murine B cells leads to tyrosine phosphorylation, calcium mobilization, AKT, ERK, JNK activation. In addition, crosslinking MHC class II with monoclonal Abs kill malignant human B cells. Several humanized anti-HLA-DR/MHC class II monoclonal Abs entered clinical trials for lymphoma/leukemia and MHC class II-expressing melanomas. Mechanistically, MHC class II is associated with a wealth of transmembrane proteins including the B cell-specific signaling proteins CD79a/b, CD19 and a group of four-transmembrane proteins including tetraspanins and the apoptotic protein MPYS/STING. Furthermore, MHC class II signals are compartmentalized in the tetraspanin-enriched microdomains. In this review, we discuss our current understanding of MHC class II signaling in B cells focusing on its physiological significance and the therapeutic potential.     

Mutations of class II MHC molecules

It remains unclear how the tertiary interaction of T-cell receptor, la molecule and foreign antigen results in the extensive diversity of the helper T cell repertoire. Here Laurie Glimcher and Irwin Griffith focus on what has been learned about the relationship between structure and function of the la molecule from the use of mouse strains with mutations in the genes coding for these glycoproteins.     

Structural requirements for the interaction between class II MHC molecules and peptide antigens

Previous work from our and other laboratories indicates that T cells recognize a complex between the MHC restriction element and peptide antigen fragments. This paper reviews the structural characteristics of the formation of such a complex. By analyzing in detail the interactions between purified IA(d) and IE(d) molecules and their peptide ligands, we found that some structural characteristics apply to both antigen-MHC interactions. In particular, we found: 1) each MHC molecule is capable of binding many unrelated peptides through the same peptide-binding site; 2) despite this permissiveness of binding, it is possible to define certain structural features of peptides that are associated with the capacity to bind to a particular MHC specificity (IA(d) or IE(d)); 3) IA(d) and IE(d) molecules recognize different and independent structures on the antigen molecule; 4) only about 10% of the single amino acid substitutions tested on two IA(d)- and IE(d)-binding peptides had significant effect on their MHC-binding capacities, while over 80% of these substitutions significantly impaired T cell recognition of the Ia-peptide complex; 5) based on the segregation between residues that are crucial for T cell activation and Ia binding, the easiest model for the antigen-Ia-T-cell-receptor complex pictures the antigen molecule sandwiched in a planar conformation between the MHC and the T cell.     

Direct mapping of MHC class II epitopes

Despite technical improvements, the mapping of MHC class II epitopes within complex antigens by genetic or biochemical methods is still laborious and expensive. Here, we describe a simple and fast procedure to directly map T helper cell epitopes within known antigens by bacterial expression cloning. Short antigenic fragments, created by digestion of the coding sequence of the antigen with frequently cutting restriction enzymes, are randomly ligated to the coding sequence of GFP in a bacterial expression vector. Bacteria expressing antigen-GFP fusion proteins are then fed directly to MHC II+ antigen-presenting cells and probed with antigen-specific T cells. Bacterial colonies recognized by T cells are expanded, and the antigenic fragments identified by plasmid extraction and sequence analysis. This direct epitope identification (DEPI) approach offers several advantages. First, bacterial colonies expressing the antigen in frame with GFP are easily detectable by virtue of their green appearance and thereby reduce the screening effort significantly. Second, short antigenic peptides normally unstable in bacteria are highly expressed when fused to GFP. Third, the uniformly high level of expression of short antigenic peptides fused to GFP permits the identification of epitopes even within proteins which are difficult to express in bacteria. Furthermore, by fusing double-stranded oligonucleotides to the GFP gene, crucial amino acids within T cell epitopes may be defined. Thus, this method not only facilitates the identification of T cell epitopes, but also makes it possible to assess the role of individual amino acids for MHC binding or T cell recognition.     

Structural and functional characteristics of a dominant-negative isoform of porcine MHC class II transactivator.

The MHC class II transactivator, CIITA, is critical for MHC class II gene expression in all species studied to date. We isolated an interferon (IFN)-gamma-inducible isoform of porcine CIITA (pCIITA') encoding a protein of 566 amino acids (aa) with significant homology to human CIITA (hCIITA). Analysis indicated that pCIITA' lacks the entire GTP-binding domain that is important for nuclear translocation and activation of target genes by hCIITA. In pCIITA' this region is replaced by a 14-aa motif with homology to several signalling peptide sequences. Expression of pCIITA' in porcine (ST-IOWA) and human (HeLa) cell lines resulted in suppression of IFN-gamma-stimulated MHC class II gene expression, at the protein and mRNA levels. We also identified two IFN-gamma-inducible variants of hCIITA, hCIITAlo and hCIITA' from Hela cells, both exhibiting dominant-negative suppression of MHC class II gene expression. Interestingly, hCIITA' encodes a predicted protein of 546 aa with a strikingly similar organization to pCIITA' including the 14-aa GTP-binding domain-replacement motif in which 10 out of 14 amino acids are identical to the pig sequence. Expression of hCIITA' and hCIITAlo sequences in Hela cells suppressed IFN-gamma-induced MHC class II gene expression. hCIITAlo, a predicted 303-aa protein with deleted GTP-binding and carboxy-terminal domain, displayed a more subtle suppression of IFN-gamma-induced MHC class II expression. These in vitro data indicate that there may be a role in vivo for isoforms of CIITA that can suppress full-length CIITA-mediated MHC class II gene expression. Both humans and now, potentially, pigs are candidate donors for organ and tissue allografts and xenografts, respectively. Regulation of MHC class II gene expression by manipulation of CIITA isoform expression in humans and pigs may provide a useful strategy for attenuation of T-cell-mediated cellular rejection.     

Sheep MHC class II molecules. II. Identification and characterization of four distinct subsets of sheep MHC class II molecules

A panel of seven monoclonal antibodies, sequential immunoprecipitation and two-dimensional NEPHGE/SDS-PAGE analyses were used to identify and characterize subsets of sheep MHC class II molecules. Using sequential immunoprecipitation four distinct subsets of class II molecules were identified by the monoclonal antibodies SBU.II 28-1, 37-68, 38-27 and 42-20, while another monoclonal antibody, SBU.II 49-1, recognized all four subsets of class II molecules. These four subpopulations of sheep class II molecules displayed different two-dimensional gel profiles and, using splenocytes from four outbred sheep, the class II molecules recognized by SBU.II 28-1, 37-68 and 42-20 showed structurally detectable allelic polymorphism in their beta polypeptides, but no detectable variation in their alpha polypeptides. In contrast, the class II molecules recognized by SBU.II 38-27 showed allelic variation in both their alpha and beta polypeptides. Two-dimensional (2-D) gel analyses of non-glycosylated class II molecules immunoprecipitated by SBU.II 49-1 suggested that approximately 10-12 different class II molecules were expressed by a single sheep. The results of this study show that sheep express class II molecules that can be divided into four structurally and serologically distinct subsets, and provide additional evidence for the subdivision of the sheep MHC class II genetic region into at least three distinct subregions.     

Evidence for accessory cell function by class II MHC antigen-expressing airway epithelial cells

Expression of major histocompatibility complex (MHC) class II antigens is a requirement for accessory cell function in antigen presentation. Recent reports have demonstrated the presence of class II antigens on human bronchial epithelial cells. In the present study, immunohistochemical staining revealed HLA-DR on human airway epithelial cells obtained from two different mucosal sites (lobar bronchus and nasal turbinates). To determine whether airway epithelial cells bear functional class II molecules that allow for their cognate interaction with T lymphocytes, cells isolated from these sites were used in mixed lymphocyte cultures (MLR), as an in vitro model of accessory cell function. Freshly isolated cells (11 bronchi/3 turbinates) stimulated allogeneic T lymphocytes (stimulation index [S.I.] = 9.3 [mean]; P less than 0.001 compared to T cells alone). In order to assess the potential role of contaminating conventional accessory cells, bronchial epithelial cell isolates were first preincubated in a serum-free, growth factor-supplemented medium that functionally eliminates potential non-epithelial stimulators prior to MLR culture. Conventional accessory cell-depleted epithelial cells were still capable of stimulating allogenic T lymphocytes in 18 of 23 MLR cultures (S.I. = 5.5 [mean]; P less than 0.0005 compared to T cells alone). The addition of an anti-class II monoclonal antibody (VG2.2) at the onset of culture completely inhibited the MLR response (n = 10). No shift in the CD4+/CD8+ ratio was detected between lymphocytes harvested from airway epithelial cell MLR (1.42 +/- 1.29) and the ratio from T lymphocytes cultured alone (1.3 +/- 0.75), suggesting that both CD4+ and CD8+ T lymphocytes were proliferating in response to stimulation from alloepitopes recognized on airway epithelial cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

B-cell antigen receptor signaling requirements for targeting antigen to the MHC class II presentation pathway

The ability of B lymphocytes to capture, process and present antigens to T cells is requisite for normal humoral immune responses and contributes to the pathogenesis of both B- and T-cell-mediated autoimmune diseases. B lymphocytes preferentially capture polyvalent antigens, which are capable of eliciting a coordinated series of cellular responses that ensure that even low-affinity antigens are productively captured. Polyvalency not only accelerates transit through the endocytic pathway but also induces a reorganization of the antigen-processing compartment, activates degradative pathways and determines how antigenic peptides are presented to T cells. Similar changes are observed in maturing dendritic cells, indicating that some cellular responses to foreign antigens are conserved.