Localization of class II molecules in storage vesicles, endosomes and lysosomes in human dendritic cells.

Class II molecules are a prerequisite for antigen presentation. We studied whether class II molecules can be found in the endocytic and/or lysosomal route of dendritic cells (DC), which are very potent antigen-presenting cells. Therefore first immunolabelling for HLA-DR alpha chain was applied on ultrathin cryosections of cells of which plasma membrane HLA-DR/DQ molecules were labelled in suspension, followed by incubation with the endocytic marker BSA-gold. Second, immunolabelling for HLA-DR alpha chains was applied on ultrathin cryosections of cells on which enzyme cytochemistry for acid phosphatase (APh) was performed to see whether the class II positive vesicles belong to the lysosomal compartment. Third, this immunolabelling was applied on cryosections of cells pretreated with the protein synthesis inhibitor cycloheximide (CHX) to see whether the class II positive vesicles are derived from biosynthesis. We found limited uptake of BSA-gold into endosomes and lysosomes, some of which also contained endocytozed HLA-DR/DQ. APh and HLA-DR were observed in the same vesicles but also vesicles containing either HLA-DR or APh were found. However, many class II positive vesicles were found, which were apparently not accessible to exogenous molecules. Moreover, the amount of class II positive vesicles decreased after treatment of the cells with CHX, suggesting that these vesicles form part of the biosynthetic route. These results imply that there is a cluster of class II positive vesicles, probably a storage compartment, that has connections with the lysosomal system. The concentration of lysosomes and class II positive vesicles in the juxtanuclear area of DC is probably of crucial importance in the processing of antigens.     

The role of MHC class II molecules in susceptibility and resistance to autoimmunity

The mechanism by which particular MHC class II alleles mediate susceptibility to a given autoimmune disease is unknown. During the past year, reports have indicated that the effects of MHC class II alleles which protect against type I diabetes in the nonobese diabetic mouse strain may, in some cases, be due to negative selection of diabetogenic T cell receptors and, in other cases, to positive selection of other T cells with a suppressive action on the diabetic process. Progress towards understanding the mechanisms of susceptibility continues to lag.     

The role of tetraspanin CD63 in antigen presentation via MHC class II

Interactions between MHC class II (MHC II)-positive APCs and CD4(+) T cells are central to adaptive immune responses. Using an Epstein-Barr virus (EBV)-transformed B lymphoblastoid cell line (LCL) as MHC II-positive APCs and CD4(+) T-cell clones specific for two endogenously expressed EBV antigens, we found that shRNA knockdown of the tetraspanin protein CD63 in LCL cells consistently led to increased CD4(+) T-cell recognition. This effect was not due to enhanced antigen processing nor to changes in MHC II expression since CD63 knockdown did not influence the amount or dimerization of MHC II in LCL cells. We therefore investigated the possible involvement of exosomes, small MHC II- and tetraspanin-abundant vesicles which are secreted by LCL cells and which we found could themselves activate the CD4(+) T-cell clones in an MHC II-dependent manner. While equal loadings of exosomes purified from the control and CD63(low) LCLs stimulated T cells to a comparable degree, we found that exosome production significantly increased following CD63-knockdown, suggesting that this may underlie the greater T-cell stimulatory capacity of the CD63(low) LCLs. Taken together, our data reveal a new insight into the mechanisms by which tetraspanins are involved in the regulation of MHC II-dependent T-cell stimulation.     

The structure of MHC class II: a role for dimer of dimers

The MHC class II molecules, expressed by antigen presenting cells, are heterodimers composed of an α and a β chain, which function to present processed antigen to helper T cells. The human MHC class II molecules, HLA-DR1 and HLA-DR3, crystallized not as monomers, but rather dimers of αβ heterodimers. The ‘dimer of dimers’ or ‘superdimer’ structure led to speculation that the binding of T-cell receptors to monomeric class II molecules on the antigen presenting cell surface may affect dimerization and thus initiate signaling both in the T cell and in the antigen presenting cell. Recent biochemical analyses of the mouse MHC class II E^kmolecule provide evidence that dimers of class II heterodimers form in the absence of T cells. Although such dimers were shown to augment T-cell stimulation, the dimerization of class II molecules alone is unlikely to initiate signal transduction. However, dimers may be important in stabilizing weak T-cell receptor/CD4/class II interactions, allowing further multimerization of such complexes, leading to signaling.     

A role for MHC class II antigen processing in B cell development

For mature B cells, the encounter with foreign antigen results in the selective expansion of the cells and their differentiation into antibody secreting cells or memory B cells. The response of mature B cells to antigen requires not only antigen binding to and signaling through the B cell antigen receptor (BCR) but also the processing and presentation of the BCR bound antigen to helper T cells. Thus, in mature B cells, the ability to process and present antigen to helper T cells plays a critical role in determining the outcome of antigen encounter. In immature B cells, the binding of antigen results in negative selection of the B cell, inducing apoptosis, anergy or receptor editing. Negative selection of immature B cells requires antigen induced signaling through the BCR, analogous to the signaling function of the BCR in mature B cells. However, the role of class II antigen processing and presentation in immature B cells is less well understood. Current evidence indicates that the ability to process and present antigen bound to the BCR is a late acquisition of developing B cells, suggesting that during negative selection B cells may not present BCR bound antigen and interact with helper T cells. However, the expression of class II molecules is an early acquisition of B cells and recent evidence indicates that the expression of class II molecules early in development is required for the generation of long lived mature B cells. Here we review our current understanding of the processing and presentation of antigen by mature B cells and the role for antigen processing and class II expression during B cell development.     

Interferon-gamma mediates antigen trafficking to MHC class II-positive late endosomes of enterocytes

MHC class II-positive late endosomes of enterocytes are thought to be involved in antigen presentation to CD4(+) T cells. In contrast to enterocytes of BALB/c mice, severe combined immunodeficiency (SCID) enterocytes lack MHC class II expression and fail to transport internalized ovalbumin (OVA) into late endosomes. IFN-gamma is known to induce MHC class II in enterocytes and antigen targeting to late endosomes in macrophages. In this study, we investigated the influence of IFN-gamma and MHC class II on the processes of antigen traffic in enterocytes. Subcellular targeting of OVA and MHC class II expression within enterocytes were examined in SCID, IFN-gamma-treated SCID, BALB/c and C57BL/6 MHC class II knockout (KO) mice after a single feed with OVA. Sorting of OVA into late endosomes was found in enterocytes from BALB/c, C57BL/6 KO and IFN-gamma-stimulated SCID mice, but not from untreated SCID mice. MHC class II expression was restricted to enterocytes of IFN-gamma-treated SCID and BALB/c mice, present at basolateral membranes and within endosomal compartments. These enterocytes further revealed colocalization of class II antigens and OVA in endosomes. We suggest that antigen trafficking into late endosomes of enterocytes is mediated by IFN-gamma and occurs in the absence of MHC class II.     

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.     

The role of tapasin in MHC class I antigen assembly

The discovery of tapasin has shed new light on the mechanisms of major histocompatibility complex (MHC) class I assembly in the endoplasmic reticulum (ER). Tapasin appears to play an important role in the stable assembly of class I molecules with peptide, however, the precise function of tapasin remains elusive. The pursuit of tapasin function is complicated by the observation that tapasin is not required for successful antigen presentation by all class I molecules. In addition, current data suggest that the putative role of tapasin as a bridging molecule between transporter associated with antigen presentation (TAP) and class I is only of minor importance in tapasin action, and tapasin’s major role appears to be as an active cofactor in the assembly of class I. Furthermore, it is clear that class I molecules can follow multiple pathways for successful assembly in the ER. These pathways may or may not include the interaction of class I molecules with the accessory proteins tapasin, calreticulin, ERp57, or TAP. I would like to suggest that the particular pathway utilized by a given class I molecule depends more upon the availability of appropriate peptides rather than on an intrinsic property of the class I molecule, and that tapasin may serve a peptide editing function.     

The role of tapasin in MHC class I antigen assembly

The discovery of tapasin has shed new light on the mechanisms of major histocompatibility complex (MHC) class I assembly in the endoplasmic reticulum (ER). Tapasin appears to play an important role in the stable assembly of class I molecules with peptide, however, the precise function of tapasin remains elusive. The pursuit of tapasin function is complicated by the observation that tapasin is not required for successful antigen presentation by all class I molecules. In addition, current data suggest that the putative role of tapasin as a bridging molecule between transporter associated with antigen presentation (TAP) and class I is only of minor importance in tapasin action, and tapasin' s major role appears to be as an active cofactor in the assembly of class I. Furthermore, it is clear that class I molecules can follow multiple pathways for successful assembly in the ER. These pathways may or may not include the interaction of class I molecules with the accessory proteins tapasin, calreticulin, ERp57, or TAP. I would like to suggest that the particular pathway utilized by a given class I molecule depends more upon the availability of appropriate peptides rather than on an intrinsic property of the class I molecule, and that tapasin may serve a peptide editing function.