All human monocytes have the capability of expressing HLA-DQ and HLA-DP molecules upon stimulation with interferon-gamma

We have simultaneously studied expression of all three classes of human Ia (HLA-DR, DP, and DQ) on normal human B cells and monocytes (M phi) by using two-color immunofluorescence and flow cytometry. Expression was investigated on freshly isolated cells and after incubation of cells for 48 and 96 hr in interferon-gamma (IFN-gamma). All freshly isolated B cells express high levels of DR, DQ, and DP, and these levels are unchanged by incubation with IFN-gamma for 48 hr and 96 hr. In contrast, freshly isolated M phi are on the average 91% DR+, 32% DQ+, and 15% DP+. Incubation with IFN-gamma increases Ia expression on M phi to 98% DR+, 75% DQ+, and 58% DP+ at 48 hr, with virtually all cells becoming positive for all three Ia antigens at 96 hr. Furthermore, after the 96-hr incubation, antigen density increases 10-fold for DR, 15-fold for DQ, and 15-fold for DP in M phi to reach levels of expression comparable with B cells. These studies demonstrate that all peripheral blood monocytes have the capacity to become HLA-DQ and HLA-DP positive; IFN-gamma regulates expression of all three classes of human Ia in M phi; and IFN-gamma does not significantly modulate Ia expression in B cells.     

DO beta: a new beta chain gene in HLA-D with a distinct regulation of expression

The HLA-D region of the human major histocompatibility complex encodes the genes for the alpha and beta chains of the DP, DQ and DR class II antigens. A cDNA clone encoding a new class II beta chain (designated DO) was isolated from a library constructed from mRNA of a mutant B-cell line having a single HLA haplotype. Complete cDNA clones encoding the four isotypic beta chains of the DR1, DQw1, DPw2 and putative DO antigens were sequenced. The DO beta gene was mapped in the D region by hybridization with DNA of HLA-deletion mutants. DO beta mRNA expression is low in B-cell lines but remains in mutant lines which have lost expression of other class II genes. Unlike other class II genes DO beta is not induced by gamma-interferon in fibroblast lines. The DO beta gene is distinct from the DP beta, DQ beta and DR beta genes in its pattern of nucleotide divergence. The independent evolution and expression of DO beta suggest that it may be part of a functionally distinct class II molecule.     

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.     

Mapping of the rabbit MHC reveals that class I genes are adjacent to the DR subregion and defines an insertion/deletion-related polymorphism in the class II region.

Molecular analyses of genes in the rabbit MHC (RLA) by pulsed field gel electrophoresis have shown that the relative order of class II genes (DP, DO, DQ, DR) is identical to that in humans and similar to that in the mouse. However, a major difference from either HLA or H-2 was observed at the DR end of the RLA class II complex: class I genes are located in close proximity to DR with no interposed class III sequences. A MluI fragment of 180 kb and a 210-kb SalI fragment both hybridized with the DR probe as well as with different class I probes including that for pR27, a class I gene with T cell-limited pattern of expression. Comparison of two different RLA haplotypes, A and B, indicated that the distance between the DQ and DR subregions differs by approximately 700 kb in the two haplotypes. Testing other unrelated rabbits suggested that this difference segregates within the rabbit population and presumably derives from an insertion/deletion event in different haplotypes. A further difference between the A and B haplotypes included variable distance between genes encoding DO beta and DP; the DR end of the complex and the class I genes linkage was conserved in the two haplotypes.     

A novel HLA class II molecule

Molecular evidence has been obtained for a novel monomorphic HLA class II molecule distinct from HLA-DP/DQ/DR using a panel of lymphoblastoid cells which include HLA-loss mutants. The expression of this molecule was investigated using monomorphic affinity-purified mouse monoclonal antibodies (mAbs), including one of the IgG_2a subclass designated EDUA. This antibody reacts strongly in a cell-binding radioimmunoassay with HLA-DR and -DQ loss mutants derived from a lymphoblastoid parental cell. The EDU-1 mAb also reacted with a local panel of homozygous Epstein-Barr virus-transformed cell lines. The reactive molecules were further detected on allostimulated T-cell clones and various leukemic cells including those of myeloid origin which lack surface expression of HLA-DQ molecules. Thus the class II molecule described in this study corresponds to a monomorphic HLA class II determinant expressed on a variety of cells of different origin and HLA phenotypes. Moreover, this antigen structure is distinct from that of HLA-DP/DQ/DR as shown by direct immunoprecipitation, serial immunodepletion experiments, and two-dimensional gel electrophoresis. The molecule could be specified by new class II genes between DP and DQ. An alternative explanation for the genetic basis of the novel molecule is the existence of isotypic associations between alpha and beta chains of various class II molecules (DP, DX, DZ, and DO) but not DR and DQ as the mutant cells tested lack the latter genes.     

Functional classification of class II human leukocyte antigen (HLA) molecules reveals seven different supertypes and a surprising degree of repertoire sharing across supertypes

Previous studies have attempted to define human leukocyte antigen (HLA) class II supertypes, analogous to the case for class I, on the basis of shared peptide-binding motifs or structure. In the present study, we determined the binding capacity of a large panel of non-redundant peptides for a set of 27 common HLA DR, DQ, and DP molecules. The measured binding data were then used to define class II supertypes on the basis of shared binding repertoires. Seven different supertypes (main DR, DR4, DRB3, main DQ, DQ7, main DP, and DP2) were defined. The molecules associated with the respective supertypes fell largely along lines defined by MHC locus and reflect, in broad terms, commonalities in reported peptide-binding motifs. Repertoire overlaps between molecules within the same class II supertype were found to be similar in magnitude to what has been observed for HLA class I supertypes. Surprisingly, however, the degree to which repertoires between molecules in the different class II supertypes also overlapped was found to be five to tenfold higher than repertoire overlaps noted between molecules in different class I supertypes. These results highlight a high degree of repertoire overlap amongst all HLA class II molecules, perhaps reflecting binding in multiple registers, and more pronounced dependence on backbone interactions rather than peptide anchor residues. This fundamental difference between HLA class I and class II would not have been predicted on the basis of analysis of either binding motifs or the sequence/predicted structures of the HLA molecules.     

Immunochemistry of the HLA class II molecules isolated from a mouse cell transfected with DQ alpha and beta genes from a DR4 haplotype

Cells from a mouse B lymphoma were transfected by DQ alpha and DQ beta genes derived from a DR4 haplotype. Quantitatively, the resulting expression of human class II molecules was similar to that of human B lymphoblastoid cell lines. Qualitatively, the transformant class II molecules differed from normal class II molecules in their carbohydrate moiety. As for their antigenic specificity, they were shown to carry two determinants previously identified on DQ molecules controlled by DR4 haplotypes, i. e., DQw3 and DCHON. The transformant molecules did not carry a third DR4-associated specificity, DC5 (equivalent to TA10), and must possess a structure allelic to DC5. However, no corresponding alloantigenic specificity was detected by a screening of relevant alloantisera.     

Redundancy in antigen-presenting function of the HLA-DR and -DQ molecules in the multiple sclerosis-associated HLA-DR2 haplotype

The three HLA class II alleles of the DR2 haplotype, DRB1*1501, DRB5*0101, and DQB1*0602, are in strong linkage disequilibrium and confer most of the genetic risk to multiple sclerosis. Functional redundancy in Ag presentation by these class II molecules would allow recognition by a single TCR of identical peptides with the different restriction elements, facilitating T cell activation and providing one explanation how a disease-associated HLA haplotype could be linked to a CD4+ T cell-mediated autoimmune disease. Using combinatorial peptide libraries and B cell lines expressing single HLA-DR/DQ molecules, we show that two of five in vivo-expanded and likely disease-relevant, cross-reactive cerebrospinal fluid-infiltrating T cell clones use multiple disease-associated HLA class II molecules as restriction elements. One of these T cell clones recognizes >30 identical foreign and human peptides using all DR and DQ molecules of the multiple sclerosis-associated DR2 haplotype. A T cell signaling machinery tuned for efficient responses to weak ligands together with structural features of the TCR-HLA/peptide complex result in this promiscuous HLA class II restriction.     

Differential induction by immune interferon of the gene products of the HLA-D region on the melanoma cell line MeWo and its metastatic variant MeM 50-10

This study has shown for the first time an association between the metastatic properties of two autologous melanoma cell lines and their susceptibility to induction of HLA class II Ag by IFN-gamma. After in vitro incubation with IFN-gamma the melanoma cell line MeWo did not acquire reactivity with anti-HLA class II antibodies, whereas its metastatic variant MeM 50-10 did. The differential susceptibility to induction of HLA class II Ag on the two cell lines cannot be accounted for by either differences in the number and affinity of IFN-gamma receptors or in the sensitivity to IFN-gamma, but most likely reflects an intrinsic property of each cell line. Serologic and immunochemical investigations with anti HLA-DR, DQ, and DP mAb have indicated that only HLA-DR Ag are induced by IFN-gamma on MeM 50-10 cells. Northern blot analysis with HLA-DR beta, DQ beta, and DP beta probes suggest that different mechanisms underlie the differential susceptibility to induction by IFN-gamma of the gene products of the HLA-D region. The regulatory mechanism(s) that control the expression of HLA class II Ag appear to be different from those controlling the expression of the melanoma-associated Ag tested, inasmuch as the modulation of the latter by IFN-gamma did not differ on the two melanoma cell lines.     

Molecular, serologic, and functional evidence for an apparent HLA-DR triplet

During routine typing procedures the individual GER was demonstrated to possess an unusual class II phenotype exhibiting three DR serotypes (DR1, DR2, DRw6). Closer serologic examination on this person's family showed that the DR1 and DR2 antigens segregated together on one haplotype. Biochemical evidence will be presented that the B cell line derived from the individual GER expresses five distinct types of DR molecules. Antigen presentation studies proved that the DR molecules carrying either DR1, DR2, or DRw6 (DRw13) allodeterminants are not only coordinately expressed but also are functional. No evidence could be found for altered DQ expression. The implications of these findings for the evolutionary aspects of the MHC class II region will be discussed.     

Expression of class II antigens by subsets of activated T cells

Gene products coded for within the HLA complex play an important role in the control of immune responses. Class I antigens, coded for by the HLA-A, B, and C loci, are expressed by virtually all mononuclear blood cells. Class II antigens, coded for by the DR, DQ, and DP loci, have a more limited tissue distribution. They are expressed by B cells, monocytes, and by activated, but not by resting, T cells. The class II molecules of B cells and antigen-presenting cells have long been of interest to immunologists, since they are involved in the presentation of antigen, in communication between T cells and B cells and between T cells and adherent cells, and in susceptibility to certain diseases. The class II antigens expressed by activated T cells, however, remain largely uncharacterized in terms of their specificity, functional significance, and molecular nature. We have studied the expression of DR and DQ antigens by activated T cells and then examined the expression of DR versus DQ antigens by Leu 2a and Leu 3a subsets of mitogen-activated populations. Our results demonstrated that, as for class II-positive macrophages, the intensity of staining with monoclonal antibodies directed against DR antigens was much greater than that obtained with those directed against DQ antigens. Interestingly, the percentages of Leu 2a- and Leu 3a-positive cells which expressed DR antigens were quite similar, as were the percentages of Leu 2a and Leu 3a cells which expressed DQ. Thus, there does not seem to be preferential expression of DR versus DQ antigens by mitogen-activated T-cell subsets. Finally, though both DR-positive-DQ-positive and DR-positive-DQ-negative populations were detected, few or no DR-negative-DQ-positive cells were observed in these populations.     

The beta-chains of DP4 molecules from different haplotypes are encoded by the same gene

The nucleotide sequence of a complete cDNA gene from a DP4-positive HLA-homozygous cell line, PGF, has been determined. This sequence is identical to the exon sequences in a genomic clone derived from another DP4-positive cell line, Priess. In contrast, our DP cDNA sequence shares only limited homology with partial cDNA sequences obtained from clones of three DP4-negative cell lines. On the basis of these results, we conclude that the phenotypic variation of DP alleles is directly attributable to the nucleotide sequence heterogeneity of DP-beta genes. That is, each phenotypic allelic form of DP antigen corresponds to a distinctly different DP-beta gene. Furthermore, this correspondence is found to be unaffected by the markers present at the DQ and DR loci, since the haplotypes of the PGF and Priess cell lines are, respectively, DR2,DQw1,DP4 and DR4,DQw3,DP4.     

Transfected human B lymphoblastoid cells express the mouse Ad beta-chain in association with DR alpha

The human EBV-transformed cell line TOM was transfected with plasmid DNA containing a complete genomic copy of the murine class II Ad beta gene. Drug resistant transfectant clones showed cell surface expression of the Ad beta gene product, as detected by flow microfluorimetry when using a mouse monoclonal antibody (MKD6) specific for Ad beta. Immunoprecipitation and two-dimensional gel electrophoretic analysis of the Ad beta-containing molecules from the transfected cells revealed that the mouse beta-chain was expressed in noncovalent association with the human DR alpha-chain rather than with DQ alpha, the human A alpha homologue. The implications of this unexpected pairing for our understanding of the processes controlling the association of class II alpha and beta gene products and of the roles of Ia molecules in normal and pathologic immune function are discussed.