A murine anti-I-A monoclonal antibody recognizes human DR (I-E-like) antigens

A monoclonal antibody, H39-49.5, originally raised against the murine I-A^k antigen, recognizes a nonpolymorphic determinant on HLA-DR-like molecules from human cells. These HLA-DR-like molecules have been characterized by amino acid sequencing and have been found to be homologous to the murine I-E antigens rather than the murine I-A antigens. These results suggest a common origin for the murine I-E, I-A, and HLA-DR antigens and caution that serological cross-reactivity alone cannot be used to reliably establish the presence of structural homologues of I-E or I-A-like molecules in other species.     

Xenogeneic recognition of soluble and cell surface HLA class II antigens by proliferative murine T cells

In order to characterize the murine anti-human xenogeneic mixed lymphocyte reactions (MLR), we studied T cell proliferative responses against various human lymphoid cells by immunization of mice either with cellular or purified HLA-DR antigens. Data presented here indicated that small amounts of soluble HLA-DR antigen were able to prime mice, and that the xenogeneic MLR depends on the expression of HLA class II antigens on the stimulating cells. Experiments using a mutant cell line clearly showed that HLA-DP molecules were also sufficient in eliciting a primary or a secondary xenogeneic MLR while no secondary proliferative response was obtained with cells expressing only HLA class I molecules. Using a large panel of human cells with various haplotypes, our results also showed that (a) nonpolymorphic determinants of HLA class II antigens trigger dominantly the murine T cells and (b) the xenogeneic response required I-E and L3T4 accessory molecules and was not inhibited with anti I-A and monomorphic anti-HLA class II antigen monoclonal antibodies. Altogether these results suggest that HLA class II antigens act as nominal antigens in triggering a murine anti-human proliferative response.     

Role of the first external domain of I-A beta chain in immune responses and diabetes in non-obese diabetic (NOD) mice.

Diabetes in the non-obese diabetic (NOD) mouse is a multigenic autoimmune disease and is possibly controlled by three recessive loci, including one that is linked to the major histocompatibility complex (MHC). The first external domain of the Class II MHC I-A beta chain in these mice is unique and has been suggested as being responsible for autoimmunity. The I-A alpha chain in these mice is I-A alpha d, and they lack the expression of I-E molecules. We have investigated immune responses to various Ir gene control antigens in NOD mice to determine the influence of the NOD Ia and particularly the I-A beta chain. We find that sheep insulin is highly immunogenic while other insulins are weakly immunogenic in these mice. Hen egg lysozyme, pigeon cytochrome C and the synthetic polypeptide Poly 18, Poly EYK(EYA)5 antigen produce good antibody responses. Apart from H-2d, NOD are the only mice where Poly 18 antigen is immunogenic. In these mice Poly 18 induced good T-cell proliferative response, which was inhibited by anti-Ia antibody, and the mice were able to respond to tyrosine-containing polypeptide Poly EYA but not to the phenylalanine-containing antigen Poly EFA. We also found that synthetic peptide 48-60 of the NOD I-A beta chain is highly immunogenic in syngeneic NOD mice both for T cells and B cells. Using an I-A beta chain-specific monoclonal antibody, we are able to prevent induction of diabetes when the antibody was administrated in prediabetic, young mice. Our results suggest that the immune response to various antigens and autoimmune diabetes in NOD mice is directly influenced by the I-A beta chain.     

Replacement of the membrane proximal region of I-A(d) MHC class II molecule with I-E-derived sequences promotes production of an active and stable soluble heterodimer without altering peptide-binding specificity

The MHC class II molecule I-A is the murine homologue of HLA-DQ in humans. The I-A and DQ heterodimers display considerable heterodimer instability compared with their I-E and HLA-DR counterparts. This isotype-specific behavior makes the production of soluble I-A and DQ molecules very difficult. We have developed a strategy for production of soluble I-A^d molecules involving expression of I-A^d as a glycosil phosphatidyl inositol (PI) anchored chimera in Chinese Hamster Ovary (CHO) cells. The regions comprising the membrane proximal segments of I-A^d alpha and beta chains were substituted for the corresponding regions of I-E, and the derived constructs were expressed in CHO cells. Procedures for purification of the soluble class II molecules were optimized and the WT and chimeric molecule were compared for structure, biochemical stability and functionality. Our analysis revealed that the substitutions in the membrane proximal domains improved cell surface expression and thermal stability of I-A^d without altering the peptide binding specificity of the class II molecule. The results suggest that similar strategies could be used to increase the stability of other unstable class II molecules for in vitro studies.     

Immunochemical analysis of a cell transfected with an HLA-DR gene reveals a new alloantigenic specificity within HLA-DRw52

The HLA-DR antigen has been prepared from the surface of a mouse fibroblast cell line transfected with a single HLA-DR beta-chain gene as well as single HLA-DR alpha and invariant chain gene. Since the HLA-DR beta chain gene studied corresponds to the DR beta III locus, the DR serological specificities detected on the transformed cells can be assigned to this locus. The use of the HLA-DR-producing mouse cell line has led to the identification of a new serological specificity included within DRw52 and associated with some DR3, some DRw6 and all DR5 haplotypes studied. Most likely this new specificity corresponds to an allelic polymorphism at the DR beta III locus of DRw52 individuals and can serve as a new serological marker for this subset of DR3, DR5 and DRw6 haplotypes.     

The MT4 Allodeterminant Is Borne on an HLA-DS Molecule on DR5 Cells

Human HLA-DR molecules have been shown to be structurally homologous to the murine I-E subregion molecules by amino acid sequence analysis. Recent studies have demonstrated the isolation of an I-A subregion-homologous molecule (HLA-DS) from human B-cell lines with the rabbit antiserum RbO3, made against a marmoset I-A-like Ia molecule. Previous work from our laboratory has demonstrated that the DR5 homozygous lymphoblastoid cell line Swei expresses at least two different Ia alpha chains and four different Ia beta chains, which associate to form four distinct human Ia molecules, alpha 1 beta 2, alpha 1 beta 3, alpha 2 beta 1, and alpha 2 beta 4, and that the alpha 2 beta 1 molecule bears the allodeterminants MB3 and MT4. To determine whether the MT4-bearing alpha 2 beta 1 molecule was an HLA-DS molecule, the alpha 2 beta 1 molecule reactive with an anti-MT4 alloserum was compared with the Ia molecule reactive with the rabbit xenoantiserum RbO3 by two-dimensional gel electrophoresis and sequential immunoprecipitation. The alpha 2 chain and the RbO3-reactive alpha chain yielded essentially similar spot patterns. The beta 1-chain spot pattern was a subset of the RbO3-reactive beta-chain spot pattern. Sequential immunoprecipitation indicated that RbO3 removed all molecules reactive with MGH88B. These results indicate that on DR5 cells the allosera-reactive alpha 2 beta 1 molecule, which bears MT4, is an HLA-DS molecule.     

The importance of cross-reactions between species: mouse allo-anti-Ia monoclonal antibodies as a powerful tool to define human Ia subsets

Three mouse allo-anti-Ia monoclonal antibodies recognizing epitopes specific for either I-E gene products (H81.98.21 and H40.315.7 Mabs) or shared between I-E and I-A gene products (H82.246.3 Mab) were used to analyze the human Ia molecules against which they cross-react. The results indicated that in the Ia pool of the human B cell line Raji the three Mabs were able to recognize at least three distinct subsets differing each other both in their alpha as well as in their beta subunits. The comparison with the previously defined human Ia subsets NG1, NGe, and DC1 suggested the following similarities: H81.98.21 specific Ia molecules similar to NG1; H82.246.3 specific Ia molecules similar to NG2, and including probably NG1; H40.315.7 specific molecules similar to DC1 in their alpha subunits and probably heterogeneous in their beta subunits with characteristics of the DC1, NG1, and NG2 subunits altogether. The heterogeneity of the human Ia molecules and the possible similarities with the mouse Ia system were discussed.     

Inhibition of autologous mixed lymphocyte reaction by monoclonal antibodies specific for the beta chain of HLA-DR antigens

Recent studies using rabbit antisera to the separated HLA-DR alpha and beta subunits have suggested that alpha chain-specific, but not beta chain-specific, antisera inhibit T cell proliferative responses in primary and secondary human autologous mixed lymphocyte reaction (AMLR). In the present study, with the aid of sequential co-precipitation assays and Western blotting methods, a monoclonal rat alloantibody 1E4, specific for the beta chain of rat class II molecules carrying an Ia determinant Ba-2.7, was characterized to recognize a monomorphic determinant located on the beta chain of DR antigens. This antibody and a murine monoclonal antibody HU-4, also specific for the beta chain of DR antigens, strongly inhibited both primary and secondary AMLR through a mechanism distinct from an antibody-dependent cell-mediated cytotoxicity reaction. These results indicate that the inhibition of AMLR is not a unique feature of DR alpha-specific antibodies.     

Biochemical characterization of an invariant polypeptide associated with Ia antigens in human and mouse

Ii, a 31,000 mol. wt polypeptide chain associated with murine and human Ia antigens was investigated for its labeling pattern, carbohydrate content and structural polymorphism. Two-dimensional gel electrophoretic analysis of tunicamycin treated cells from mouse and human lymphocytes shows that Ii contains two N-linked carbohydrate chains. Ii is a methionine rich polypeptide. Tryptic and chymotryptic two dimensional peptide maps of Ii chain associated with I-A and I-E subregion products are identical. This absence of polymorphism holds true when Ii chain is isolated from different mouse haplotypes. Human Ii chains from different HLA-DR types appear also invariant by peptide map analysis. By molecular weight, carbohydrate content, charge and tryptic and chymotryptic maps criteria, Ii of mouse and human are strikingly homologous.     

Production of monoclonal human antibody to HLA-DR5 (DRw11) by mouse/human heterohybridomas

We describe here the production of a human monoclonal antibody to the HLA-DR5 antigen. A human B-cell line secreting cytotoxic antibody that reacted preferentially with DR5-positive targets was fused to the mouse myeloma P3X63Ag8.653 and the resulting heterohybridomas cloned twice. The clones secreted human IgM (lambda light chain), which showed specificity for the DR5 antigen in cytotoxicity assays and reacted with DRw11-positive but not DRw12-positive targets. These results demonstrate the potential of this approach to the production of human monoclonal antibodies to transplantation antigens.     

Binding of toxic shock syndrome toxin-1 to murine major histocompatibility complex class II molecules

The staphylococcal exotoxin toxic shock syndrome toxin-1 (TSST-1) has potent stimulatory effects on murine and human lymphocytes. This is the consequence of TSST-1 binding to major histocompatibility complex (MHC) class II molecules and the engagement in a V beta-restricted fashion of the T cell receptor by the TSST-1-MHC class II complex. Using radioligand and functional assays we have recently shown that TSST-1 binds to all HLA-DR (n = 14), HLA-DQ (n = 2) and HLA-DP (n = 2) phenotypes tested. In this study, we have examined the ability of murine MHC class II molecules to bind TSST-1. Specific high-affinity binding of TSST-1 was detectable to unfractionated BALB-c (H-2d) and C57BL/6 (H-2b), but not to C3H (H-2k) spleen cells. The Kd of this binding estimated from Scatchard analysis was in the same nanomolar range as the Kd of binding of TSST-1 to HLA-DR. Binding of 125I-labeled TSST-1 to BALB/c-derived B cell lymphoma lines and to L cell transfectants correlated with the expression of I-A molecules, but not with the expression of I-E molecules. Furthermore, I-A+, I-E- cells but not I-A-, I-E+ cells were able to support TSST-1-induced T cell proliferation. The binding affinity of TSST-1 for I-Ak appears to be much lower than for I-Ad. L cell transfectants expressing hybrid DR alpha: I-E beta k molecules, but not those expressing I-E alpha k: DR1 beta molecules, could bind TSST-1 and efficiently support TSST-1-induced T cell proliferation. This suggests that minor differences in the highly homologous I-E alpha and DR alpha chains are critical in determining the affinity of the MHC class II molecule for TSST-1. These results demonstrate that the binding of TSST-1 to MHC class II molecules in the mouse, in contrast to humans, is strongly influenced by phenotype. Analysis of the molecular basis of these differences may help to localize staphylococcal exotoxin binding sites on MHC class II molecules.     

Monoclonal antibodies detect polymorphic determinants shared by I-A and I-E antigens

Binding data on inbred mouse strains and immunochemical isolation of Ia antigens with subsequent separation on non-reduced/reduced two-dimensional gels provide evidence for the cross-reactivity of monoclonal antibodies with I-A and I-E products. Thus two monoclonal antibodies were found to react with A alpha A beta as well as E alpha E beta dimers. One of these mAbs, K22 -42, reacts with the precursor form of E beta chain of B10.GD mice which is associated with the invariant chain (Ii). This indicates that the respective determinant on E beta is formed prior to association of E beta with E alpha.     

HLA-DR-DQ haplotypes defined by restriction fragment analysis. Correlation to serology

Through the analysis of RFLP (restriction fragment length polymorphism) of the HLA-DR beta, -DQ alpha, and -DQ beta genes from 70 serologically well-characterized individuals, we have established unique HLA-DR-DQ RFLP haplotypes correlating to all of the DR1-w14 specificities. The RFLP of DR beta, DQ alpha, and DQ beta genes is very high using the restriction enzyme TaqI and 21 DR-DQ RFLP haplotypes were defined with this restriction enzyme. Our analysis confirms the strong linkage disequilibrium between alleles in the DR and DQ loci. DR beta RFLP indicates a common ancestor for the DR alleles within either of the supertypic DRw52 and DRw53 specificities. The DQ beta gene shows a high degree of RFLP, and the RFLP alleles partly reflect the serologic DQw1-w3 specificities. The results presented here also demonstrate the heterogeneity of DRw6 (DRw13 and DRw14) associated haplotypes, and the DRw13 related Dw18 and Dw19 specificities were found to have distinct DR-DQ haplotypes. The DQw1 positive haplotypes DR1, 2, w10, w13, and w14 are related with regard to DQ alpha and DQ beta RFLPs and the DRw52 positive haplotypes DR3, w11, and w12, as well as the DRw53 positive haplotypes DR4, 7, and w9, are related with regard to DR beta and DQ alpha RFLPs. These findings indicate that polymorphic sequences around the DQ alpha gene are associated with DR beta and DQ beta polymorphism, which suggests a location of the DQ alpha gene between DR beta and DQ beta.     

Self-nonself discrimination and repertoire selection of human T cells differentiated in an HLA-semiallogeneic environment following bone marrow transplantation for severe combined immunodeficiency.

We have analyzed allorecognition, HLA restriction and T cell receptor (TcR) diversity in an HLA-heterozygous (HLA-DRw6,7) severe combined immunodeficiency (SCID) patient whose T cell system had been repopulated by HLA-homozygous (HLA-DRw6) paternal T cells following T cell-depleted bone marrow transplantation (BMT). Donor origin of T cells and host origin of antigen-presenting cells (APC) in peripheral blood and BM is shown by HLA typing of separated cell populations and two-color immunofluorescence using an anti-HLA monoclonal antibody (mAb). Peripheral blood lymphocytes (PBL) from the chimeric patient proliferate normally against PHA, anti-TcR/CD3 mAb, pooled allogeneic PBL, and also against the recall antigen (Ag) tetanus toxoid and purified protein derivative of tuberculin (PPD) following immunization, suggesting recognition by donor (DRw6) T cells of Ag presented by host (DRw6,7) APC. PPD-specific cytotoxic T lymphocytes generated in vitro from patient PBL post-BMT display specific cytotoxicity against targets expressing DRw6 and DR7, but not against DR-mismatched targets, suggesting that HLA restriction of Ag recognition may occur through determinants expressed by the host and not by the donor. Donor T cells differentiated in the HLA-semiallogeneic host show specific proliferative and cytotoxic responses against HLA-mismatched stimulators, but not against stimulators taken from the host, expressing the host-specific HLA-haplotype, or expressing the host-specific HLA-DR7 antigens. Compared to T cells directly taken from the donor, differentiation of donor T cells in the host is associated with a significant decrease of T cells expressing TcR V beta 5 and V alpha 2 determinants, while no differences in the abundance of of TcR V beta 6, V beta 8 and V beta 12 subsets were noticed. We conclude that allorecognition, major histocompatibility complex (MHC) restriction and TcR diversity generation of human T cells can be modulated through differentiation in an MHC-different environment, as had been previously shown to be the case in murine model systems.     

Functional polymorphism of the HLA-DR beta III chain

Several clusters of class II HLA genes contribute to variation in human antigen-presenting capacity. In the HLA-DR cluster, most of the variation is due to the highly polymorphic DR beta I gene. Recent work by others has shown some nucleotide and implied amino acid sequence variation in DR beta III chains, but this variation is not known to be functionally significant. We show here that two proliferating human T-cell clones define three allelic variants of DR beta III (assignment to DR beta III based on blocking of proliferation by selected monoclonal antibodies). Thus, the DR beta III locus encodes at least three alleles that are distinguishable by human T cells and most probably contribute to the human antigen-presenting repertoire. The three DR beta III alleles subdivide the "supertypic" HLA antigen DRw52 into subtypes provisionally called DRw52.1-52.3. The DR3 haplotypes studied to date have been either DRw52.1 or 52.2; DR5 haplotypes have all (23 of 23) been 52.2; DRw6 haplotypes have included all three DRw52 subtypes, nearly half being 52.3. Our data, combined with other published data, imply that DRw8 must either have a fourth DRw52 subtype or be DR beta III null.     

Two-dimensional gel analysis of the polypeptides precipitated by a polymorphic HLA-DR1,2,w6 monoclonal antibody: evidence for a third locus

The SDR1 monoclonal antibody reacts only with cells which express the HLA-DR1, 2,w6 or w8 allogeneic specificities. Two-dimensional nonequilibrium pH gradient/sodium dodecyl sulfate polyacrylamide gel electrophoretic analyses of SDR1 immunoprecipitates from [35S]methionine biosynthetically labeled cells revealed the typical pattern of Ia antigens, namely two polypeptides of about 34kDa and 29kDa (designated epsilon and beta-3) as well as the "basic invariant spot" of about 31 kDa. The epsilon and beta-3 polypeptides were only weakly represented in similar analyses of immunoprecipitates performed using a monomorphic HLA-DR monoclonal antibody, TDR31.1. The epsilon and beta-3 polypeptides of B lymphoblastoid cell lines homozygous for HLA-DR2 and w6 were structurally polymorphic as judged by two-dimensional gel analyses. This polymorphism was independent of the HLA-DR specificity. It is concluded that the SDR1 antibody recognizes a polymorphic set of Ia antigens that are coded by a locus other than HLA-DR. These antigens probably also express the MT1 (DC1, LB12) alloantigenic specificity and are most likely the human equivalent of the murine I-A subregion antigens.     

An overview of the restriction fragment length polymorphism of the HLA-D region: its application to individual D-, DR- typing by computerized analyses

HLA-D/DR alleles as defined by cellular and serological typing can also be identified by biochemical methods. The Southern blot technique provides an additional typing facility which can be applied to DNA obtained from any source of nucleated cells. The polymorphism revealed by Southern blot analyses, the so-called restriction fragment length polymorphism (RFLP), depends upon the restriction enzyme and cDNA probes used. To identify HLA-DR specificities a protocol was developed based on the use of the results of southern blot analyses with several restriction enzymes and cDNA probes within a panel of HLA-D/DR homozygous cells representing the DR1 to DRw8 alleles. First, hybridizations with the 3' untranslated sequence of the DR beta cDNA probe, after digestion of the DNA with PvuII (PvuII-DR beta 3') allows the selective identification of DR1, DR2 and DRw8; DR3, DR5 and DRw6 are found as one group as well as DR4 and DR7 as another. Second, TaqI-DQ alpha hybridization allows the splitting of DRw6-Dw18, DRw6-Dw19 and DRw6-Dw9 from the DR3, DR5 and DRw6 group. The other alleles DR3, DR4, DR5, DRw6-Dw16 and DR7 are revealed by dehybridization and rehybridization of the blot with a DR beta cDNA probe. This protocol was used to test whether in a panel of 30 randomly chosen individuals the HLA-DR typing could be performed. The results were highly concordant to the serotyping. Furthermore by adding the Pst-DR beta and TaqI-DQ alpha RFLPs, most of the MLC defined Dw specificities could also be identified. An overview of the specific fragments described here has been summarized in matrices which can be used as references for DNA-typing in computerized analyses.     

A new supertypic HLA class II determinant (PL2) differentially expressed with DR7, DRw11(5), DRw13(w6), DRw14(w6), DR3, and DR2 and biochemically localized to DR7 molecules

A monoclonal antibody, PL2, has been produced that reacts with a new supertypic determinant expressed on the peripheral blood B lymphocytes and B-leukemic cells (B-CLL) from all individuals who are HLA-DR7 and some individuals who are HLA-DR5 positive. The genetic linkage of the PL2 determinant to the HLA region was demonstrated by family segregation studies. When cultured Epstein-Barr virus (EBV) transformed B cell lines were examined, PL2 was again found to be expressed on all cell lines homozygous for HLA-DR7 and the DRw11(5) subtype of HLA-DR5 positive cells, while one DRw12(5) cell line was negative, suggesting PL2 may distinguish between these DR5 subtypes. In addition, using the panel of EBV-transformed B-cell lines, PL2 was also found to be weakly expressed on HLA-DRw14(w6), -DRw13(w6), -DR3, and -DR2 positive cells but was completely absent from HLA-DR1 and -DR4 positive cells, and is probably absent also from DRw8- and DRw10-positive cells. From titration analysis and quantitative absorption studies the PL2 determinant was found to be expressed at quantitatively different levels in the following order: DR7 greater than DRw11, DRw14 greater than DRw13 greater than DR3 greater than DR2. The molecules carrying the PL2 determinant on DR7 cells have been characterized biochemically to be a subpopulation of HLA class II molecules recognized by the DR specific monoclonal antibody, L243. Furthermore, by two-dimensional gel analysis, PL2 immunoprecipitated only two of three beta chains associated with the DR-apha chain, which are the same two chains that carry the DR7 allodeterminants.(ABSTRACT TRUNCATED AT 250 WORDS)     

Different functions and associations of HLA-DR and HLA-DQ(DC) antigens shown by serological, cellular and DNA assays

Two consanguineous Caucasoid HTCs, DHI and FPA, were investigated, the latter having an unusual HLA-DR/DQ(DC) association. Both these HTCs typed clearly as HLA-DRw11. However, while DHI typed as DRw11/DQw3(DC4) as expected, FPA typed as DRw11/DQw1(DC1) instead. Although extremely rare in Caucasoids, DRw11/DQw1 is a common pattern of association in Nigerian Negroids. Southern blots of DNA extracted from EBV cell line derived from FPA, hybridized with HLA-DC alpha and HLA-DC beta probes, confirmed this unusual DRw11/DQw1(DC1) association. In addition the DC alpha probe showed a unique additional restriction fragment length polymorphism (8 kb) attributable to the DX gene in the FPA DNA. When DHI and FPA were used as stimulators in MLC, the patterns to typing responses obtained were not completely concordant although they overlap to some extent. For this reason FPA has been locally designated Dw'F5', distinct from Dw5. Furthermore, the HLA-DQ antigens of the responder cells were not necessarily the same as those of the HTCS to which they gave typing responses (FPA and DHI). Functional studies using these two HTCs showed that the DQ(DC) antigens probably have no direct lymphocyte activating properties but rather have a regulatory role in controlling responses to allodeterminants in MLC.     

HLA-DR and -DQ DNA polymorphisms: new linkage relationships established by RFLP genomic typing in Polynesians and Melanesians

Class II restriction fragment length polymorphisms (RFLPs) of DR beta, DQ beta, and DQ alpha loci were examined in Polynesians of the southwest Pacific and in non-Austronesian-speaking Melanesians from the Papua New Guinean Highlands. Polynesians, previously considered to have a restricted set of HLA-DR antigens, showed class II gene heterogeneity associated with DR2, DR5, DRw6, and DRw8 RFLPs. Furthermore, Melanesians and Polynesians share certain antigens such as DRw6 and DRw8, but the DR beta 2 genes associated with DRw6 and the DQ genes associated with DRw8 are population-specific and show little or no overlap. This study has shown that genetic analysis of closely linked polymorphic genes is a powerful anthropological tool and supports the view that Polynesians represent an independent colonizing group in the Pacific, rather than a group evolved from within Melanesia.