Analysis of the molecular specificities of anti-class II monoclonal antibodies by using L cell transfectants expressing HLA class II molecules

Expressible HLA class II alpha- and beta-chain cDNA were used for DNA-mediated gene transfer to produce L cell transfectants expressing single types of human class II molecules. Cloned transfectants expressing nine different class II molecules were isolated: DR alpha: DR1 beta I, DR alpha: DR4 beta I, DR alpha: DR5 beta I, DR alpha: DR5 beta III (DRw52), DR alpha: DR7 beta I, DR alpha: DR4/7 beta IV (DRw53), DQ7 alpha: DQw2 beta, DQ7 alpha: DQw3 beta, and DPw4 alpha: DPw4 beta. These class II-expressing transfectants were used to analyze by flow cytometry the molecular specificities of 20 anti-class II mAb. These analyes indicate that some mAb are more broadly reactive than was previously thought based on immunochemical studies. In contrast, the narrow molecular specificities of other anti-class II mAb were confirmed by this approach. Transfectants expressing human class II molecules should be valuable reagents for studies of B cell and T cell defined epitopes on these molecules.     

A novel method for generating stable high-level transfectants involving direct immunomagnetic selection for cell-surface epitopes: expression of HLA class-II genes in HeLa cells.

A versatile method that allows efficient detection and selection of both transient and stable transfectants expressing exogenous cell-surface molecules is described and used to generate stable HeLa transfectants expressing each of the human HLA class-II isotypes, specifically the DR1, DQw8 and DPw2 heterodimers. The method combines use of the strong mammalian expression vector, CDM8, and a highly efficient transfection protocol with the powerful technique of immunomagnetic selection. It offers significant advantages in comparison to standard procedures involving co-selection with drug-resistance markers. The transfection efficiency can be assessed 60 h after transfection rather than after three weeks of drug selection. Repeated rounds of immunomagnetic selection applied over the subsequent ten days result in homogeneous populations which express the surface marker of interest stably at high levels, making further subcloning or fluorescence-activated cell sorting unnecessary. Any number of surface products can be transfected into the same cell, the only limitation being the availability of specific monoclonal antibodies (a DP/DR double transfectant is described expressing four exogenous gene products simultaneously). The high sensitivity of immunomagnetic selection and its applicability to large samples allows rescue of transfectants present at very low frequencies. Finally, the technique can be used as a coselection procedure, by analogy with drug coselection, to achieve expression even of non-cell surface products.     

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.     

Isolation and characterization of the cDNA clone and genomic clones of a new HLA class II antigen heavy chain, DO alpha

From a human cDNA library constructed from a consanguineous HLA-homozygous cell line, AKIBA (HLA-A24, Bw52, DR2, Dw12, DQw1, and Cp63) (Cp63, a new SB type), a cDNA clone encoding a new HLA class II antigen heavy chain named DQ alpha was isolated, and was analyzed by Southern blot hybridization and by nucleotide sequence determination. The nucleotide sequence of the DO alpha cDNA was distinct from those of the DR alpha, the DQ alpha, and the DP alpha cDNA, but showed some characteristic features of the class II antigen alpha-chains. We also isolated and identified genomic clones specifying the DO alpha gene. Genomic analyses of cell lines with different HLA-DR serotypes with the use of the DO alpha cDNA as a probe indicated the existence of a single DO alpha gene that exhibited little restriction enzyme polymorphism.     

Analysis of the donor-specific cytotoxic T lymphocyte repertoire in a patient with a long term surviving allograft. Frequency, specificity, and phenotype of donor-reactive T cell receptor (TCR)-alpha beta+ and TCR-gamma delta+ clones

In the present study the transplant specific CTL repertoire of a patient (HLA:A1,3, B8,18, Cw5,7 DR3, DQw2, DPw3) with a long term surviving HLA mismatched kidney graft (HLA: A1,24 B8,27 Cw2,7, DR3, w13 DQw2,6 DPw1,3) has been investigated. This patient was unable to generate specific cytolytic activity against donor-derived PHA-blasts in the MLC in which donor spleen cells or B lymphoblastoid cell line were used as stimulator cells. In addition, the CTL precursor frequencies against donor alloantigens were very low (1/67,000). The patient had otherwise normal immune responses in vivo and in vitro and no signs of transplant rejection. Transplant specific CTL clones were generated in high frequencies (1/195) from T cell bulk cultures activated by PHA in the absence of any sensitization by donor Ag in vitro. The repertoire of 14 donor-reactive CTL clones (12 TCR-alpha beta+ and 2 TCR-gamma delta+) was analyzed. Two TCR-alpha beta+ CD8+ clones were specific for B27. Ten TCR-alpha beta+ CTL clones directed against class II HLA Ag were isolated. Seven of these were CD4+ and recognized DRw13 (3), DQw6 (3), and DPw1 (1), whereas three of these clones were CD4-CD8+ recognizing DRw13 (1) and DQw6 (2). In addition, two donor-specific TCR-gamma delta+ CTL clones were obtained recognizing HLA-A9(23,24) and DQw6. Our data indicate that the precursors of CTL clones specifically directed against donor class I or II HLA Ag are not deleted from the repertoire and that part of this reactivity resides in the TCR-gamma delta+ fraction.     

A newly characterized HLA-DP beta-chain allele. Evidence for DP beta heterogeneity within the DPw4 specificity

cDNA clones corresponding to the DPw4 alpha- and DPw4 beta-chains were isolated from a cDNA library prepared from a DPw4 homozygous cell line, their nucleotide sequences were determined, and the corresponding amino acid sequences were deduced. This DPw4 alpha-chain is identical to the conserved DP alpha-chains from DPw4 and DPw2 haplotypes, although the DPw4 beta-chain (referred to as DPw4b beta) differs from all reported DP beta-chain sequences. The DPw4b beta-chain differs from the reported DPw4 beta sequence (referred to as DPw4a beta) at three amino acid positions in the first domain (36, 55, and 56). The DPw4b beta-chain sequence differs from the DPw2 beta-chain sequence only at position 69 in the first domain, suggesting that the lysine at position 69 in DPw4b beta and the glutamic acid at position 69 in DPw2 beta contribute to the epitopes that define "DPw4-ness" and "DPw2-ness," respectively. In addition, the patterns of sequence identities and differences among the DPw4b beta-, DPw4a beta-, DPw2 beta-, and DPw3 beta-chains suggest that the DPw4b beta sequence arose via a gene conversion event or a point mutation. The I-LR1 mAb, which was previously found to bind only to DPw2, DPw3, and DR5 molecules, binds to an L cell transfectant expressing the DPw4 alpha:DPw4b beta molecule. The DPw4b beta sequence provides the first evidence for structural heterogeneity within the DPw4 specificity.     

Refinement of HLA gene mapping with induced B-cell line mutants

The lymphoma cell line BJAB.B95.8.6 was gamma-irradiated to induce mutations of major histocompatibility complex (MHC) encoded genes. Cloned wild-type cells were phenotyped HLA-A1, A2, B 13, 1335, Bw4, Bw6, Cw4, DR5, DRw52, DQwl, DQw3, DPw2, DPw4, GLO1^*1, PGM3^*2-1, and ME1^*0 and possessed two apparently normal chromosome 6s prior to mutagenesis. Loss mutants were selected 5 days after 3 Gy gamma-irradiation employing three complement-fixing monoclonal antibodies specific for HLA-A2 (TÜ101) and Bw4 (TÜ48, TÜ109). Fifteen independently arising mutants were isolated and cloned. Typing with monospecific alloantisera and cell-mediated lympholysis revealed the presence of HLA-A1, 835, Bw6, Cw4, DR5. DRw52, DQw3, and DPw4 specificities on all mutant clones. HLA-A2, B13, and Bw4 were absent. Mutants differed in their expression of class 11 antigens. One group retained DQw1 and DPw2, another was DQw1^–, DPw2⁺, and a third was DQw1^–, DPw2^–. Karyotyping of the wild-type line and selected mutant clones showed that the loss of HLA specificities correlated with deletions which map the HLA-A and -B loci directly to the distal part of the 6p2l.33 region and the class II genes to the region 6p21.33 (proximal) to 6p21.31 (distal) on the short arm of chromosome 6.Abbreviations used in this paper: CML cell-mediated lympholysis - CTX cytotoxicity - DBBA direct bacterial binding assay - EBV Epstein-Barr virus - GLO glyoxalase - IBBA indirect bacterial binding assay - LU lytic units - ME1 cytoplasmic malic enzyme - MHC major histocompatibility complex - MOAB monoclonal antibody - NADP nicotinamide-adenine dinucleotide phosphate - PGM3 phosphoglucomutase isozyme 3 In partial fulfillment of Ph.D. thesis requirements.     

HLA-DQ-restricted CD4+ T cells specific to streptococcal antigen present in low but not in high responders.

We have found that the low immune response to streptococcal cell wall Ag (SCW) was inherited as a dominant trait and was linked to HLA, as deduced from family analysis. In the present report, HLA class II alleles of healthy donors were determined by serology and DNA typing to identify the HLA alleles controlling low or high immune responses to SCW. HLA-DR2-DQA1*0102-DQB1*0602(DQw6)-Dw2 haplotype or HLA-DR2-DQA1*0103-DQB1*0601(DQw6)-DW12 haplotype was increased in frequency in the low responders and the frequency of HLA-DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15 haplotype or HLA-DR9-DRw53-DQA1*0301-DQB1*0303(DQw3)-Dw23 haplotype was increased in the high responders to SCW. Homozygotes of either DQA1*0102 or DQA1*0103 exhibited a low responsiveness to SCW and those of DQA1*0301 were high responders. The heterozygotes of DQA1*0102 or 0103 and DQA1*0301 showed a low response to SCW, thereby confirming that the HLA-linked gene controls the low response to SCW, as a dominant trait. Using mouse L cell transfectants expressing a single class II molecule as the APC, we found that DQw6(DQA1*0103 DQB1*0601) from the low responder haplotype (DR2-DQA1*0103-DQB1*0601(DQw6)-Dw12) activated SCW-specific T cell lines whereas DQw4(DQA1*0301 DQB1*0401) from the high responder haplotype (DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15) did not activate T cell lines specific to SCW. However, DR4 and DR2 presented SCW to CD4+ T cells in both the high and low responders to SCW, hence the DR molecule even from the low responder haplotype functions as an restriction molecule in the low responders. Putative mechanisms linked to the association between the existence of DQ-restricted CD4+ T cells specific to SCW, and low responsiveness to SCW are discussed.     

Effect of isotypes and allelic polymorphism on the binding of staphylococcal exotoxins to MHC class II molecules

Interaction of staphylococcal exotoxins (SE) with MHC class II molecules plays a central role in the activation of immune cells by SE. We have recently demonstrated directly that toxic shock syndrome toxin-1 (TSST-1) binds to MHC class II molecules with high affinity, and similar results have been reported for SEA and SEB. The ability of T cells to respond to individual SE is associated with the expression of particular TCR-V beta gene elements. In the present study we have examined the effect of polymorphism on the ability of MHC class II molecules to bind SEB and TSST-1. We have used a panel of L cell transfectants that express different allelic forms of each of the three human class II isotypes. Radioligand binding assays detected binding of SEB and TSST-1 to most, but not all of the MHC class II molecules examined. Toxin-driven MHC class II-dependent T cell proliferation occurred with all transfectants examined even in the absence of detectable toxin binding. These results indicate that SE can bind to human MHC class II molecules of diverse phenotypes.     

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.     

Stimulation of human naive and memory T helper cells with bacterial superantigen. Naive CD4+45RA+ T cells require a costimulatory signal mediated through the LFA-1/ICAM-1 pathway.

The role of the accessory molecule ICAM-1 in activation of subpopulations of human T cells was examined using the bacterial superantigen staphylococcal enterotoxin A (SEA) as a MHC class II and TCR-dependent polyclonal T cell activator. Human T cells responded with different sensitivity to SEA when presented on mouse accessory cells expressing a human transfected MHC class II gene product. Mouse L cells cotransfected with both MHC class II (DR2A or DR7) and ICAM-1-stimulated T cells at 100-fold lower concentrations of SEA as compared to the single transfected cells. mAb reacting with the CD11a, CD18, or ICAM-1 molecules efficiently inhibited T cell activation with the cotransfected HLA-DR2A/ICAM-1 cell but did not influence T cell activation with the HLA-DR2A single transfected cell. Analysis of the ICAM-1 requirement on CD4+ memory (CD4+45RO+) and naive (CD4+45RA+) T cells revealed that CD4+45RA+ naive Th cells were hyporesponsive to SEA-induced activation with the HLA-DR2A single transfectant. However, cotransfection of ICAM-1 enabled these cells to respond to low doses of SEA implicating that they are more dependent on accessory molecules than the CD4+45RO+ cells. rICAM-1 immobilized on a plastic surface, was able to strongly costimulate SEA-induced T cell activation with the HLA-DR2A single transfectant, suggesting that costimulatory signals mediated to the T cells through LFA-1 can be delivered physically separated from the TCR signal. CD4+45RO+ memory and CD4+45RA+ naive Th cells apparently differ in their capacities to be activated by SEA bound to HLA-DR. Although the TCR molecule densities are similar in these two subsets, costimulation with ICAM-1 is required for activation of the CD4+45RA+, but not the CD4+45RO+ T cell subset at 1 to 10,000 ng/ml concentrations of SEA. This observation indicates different activation thresholds of naive and memory Th cells when triggering the TCR over a wide dose interval of superantigen.     

Activation of murine T cells by toxic shock syndrome toxin-1. The toxin-binding structures expressed on murine accessory cells are MHC class II molecules

Toxic shock syndrome toxin-1 (TSST-1)-binding structures present on murine lymphoid tissues were investigated by using 125I-TSST-1. T-depleted C57BL/6 spleen cells incubated with TSST-1 for 3 h at 0 degree C were mitogenic to splenic T cells, indicating that the former cells bind and present TSST-1 to T cells. TSST-1-binding activity was observed in C57BL/6 splenic B cells and L cells transfected with I-Ab genes, but not in splenic T cells and control L cells. Scatchard plot analysis showed that these B cells and transfectants bound TSST-1 with similar binding affinity. SDS-PAGE analysis showed that lysates of C57BL/6 spleen cells and the I-Ab-positive transfectants contain a single band which bound TSST-1 and comigrated with I-Ab heterodimers. TSST-1-binding activity observed clearly in C57BL/6. BALB/c, and C3H/HeN spleen cells and L cells transfected with I-Ab or I-Ak genes was not reduced by paraformaldehyde fixation. Binding of 125I-TSST-1 to the three spleen cells was markedly reduced by anti-I-A antibodies, but not by anti-I-E antibodies. C57BL/6, C3H/HeN, and (C3H/HeN x C57BL/6) F1 T cells were activated by TSST-1 to proliferate and produce IL-2 in the presence of FT6.2 cells, LT1-30-3 cells and either of them, respectively, but not in the presence of control L cells. These results indicate that I-A molecules function as the structures via that accessory cells directly bind TSST-1 on the cell surface and present a triggering signal of TSST-1 to T cells.     

HLA-DR2a is the dominant restriction molecule for the cytotoxic T cell response to myelin basic protein in DR2Dw2 individuals.

The HLA-DR2 restriction of the T cell response to myelin basic protein (MBP) was studied using murine L cells transfected with DRalpha and either DR2a or DR2b beta-chain cDNA. DR2a and DR2b represent the two isotypic DRbeta chains expressed in DR2Dw2 haplotypes. Eleven MBP-specific cytolytic T cell lines derived from patients with multiple sclerosis were isolated. Two of these cell lines recognized MBP-pulsed DR2-expressing L cell transfectants and four of them could only recognize the L cells if the adhesion molecule ICAM-1 was expressed in addition to HLA-DR2. Five of the six lines were restricted by HLA-DR2a; one line recognized Ag in conjunction with DR2b, but only if ICAM-1 was coexpressed. The remaining five lines did not lyse MBP-pulsed L cells. The ability of the DR2b molecules on transfected cells to stimulate T cells was confirmed with DR2b-allospecific T cell clones. Although five MBP-specific lines were restricted by DR2a, they recognized different parts of the MBP molecule, as demonstrated by the presentation of shorter peptides. Thus, our results suggest that DR2a is a dominant restriction molecule in MBP-specific responses by DR2+ MS patients. The results also indicate that the reported heterogeneity in MBP epitopes recognized by DR2-restricted T cells, may not be due to the use of different restriction elements but rather to the binding of different MBP peptides to DR2a molecules.     

H2-restricted recognition of cloned HLA class I gene products expressed in mouse cells

Long-term syngeneic mouse cytolytic T lymphocyte (CTL) clones were obtained from DBA/2 (H2d) mice immunized with P815 (H2d) cells transfected with cloned human class I histocompatibility genes, HLA-CW3 or HLA-A24. Three distinct patterns of specificity were defined on P815 HLA transfectant target cells. One clone lysed HLA-CW3 but not -A24 transfectants, and a second lysed HLA-A24 but not -CW3 transfectant target cells. The third clone lysed P815 targets transfected with either HLA gene. None of the CTL clones lysed L cells (H2k) transfected with the same HLA genes or human targets that expressed these HLA specificities. Several lines of evidence indicated that recognition of HLA transfectants by these CTL clones was H2 restricted. First, lysis of P815 HLA transfectants could be inhibited by anti-H2Kd monoclonal antibody. In addition, the anti-P815-HLA CTL clones could lyse a (human X mouse) hybrid target that expressed both HLA class I and H2Kd antigens, but not a clonal derivative that no longer expressed H2Kd. The most direct evidence for H2-restricted recognition of P815-HLA transfectants by the syngeneic CTL clones was obtained by double transfection of mouse L cells (H2k) with both HLA and H2 class I genes. L cells transfected with HLA and H2Kd genes were susceptible to lysis by the same CTL clones that lysed the corresponding P815-HLA transfectant targets. Thus under certain conditions, CTL recognition of xenogeneic class I histocompatibility gene products can be restricted by other class I gene products.     

Immunochemical analysis of the Ia polymorphisms among the family of DR7-associated HLA-D specificities

Among cells that bear the serologically defined Ia alloantigen DR7, four T cell-defined HLA-D specificities have been described: Dw7, Dw17, Dw11, and Dw7L. Ia molecules expressed by cells homozygous for these specificities have been compared by using immunofluorescence and two-dimensional gel electrophoresis in order to identify the DR and DQ polymorphisms among the family of DR7-associated HLA-D specificities. Cells homozygous for each of the four HLA-D specificities have in common one DR molecule that is indistinguishable by these methods. Two DR-specific monoclonal antibodies, IIIE3 and 109d6, detect a second distinct DR molecule on Dw7, Dw17, and Dw7L cells. This second DR molecule is also very similar from cells of the three specificities. In contrast, a second DR molecule was not detected on four Dw11 homozygous cells. Therefore, these data raise the possibility that all DR homozygous cells do not express the same number of DR molecules. The DQ molecules expressed by DQw2-positive Dw7, Dw17, and Dw7L cells are also very similar, whereas DQw3-positive Dw11 DQ molecules are structurally different. Therefore, no DR or DQ structural polymorphisms were detected to correlate with the Dw7, Dw17, and Dw7L T cell-defined Ia polymorphisms.     

Comparison of the N-linked glycopeptides of DQw1 and DR1 molecules

HLA class II molecules have been isolated from a [3H]mannose-labeled GM3104 B lymphoblastoid cell line with the phenotype DQw1, DR1. The DQw1 molecules were purified by affinity to 77-34 IgG specifically reactive with the DQw1 specificity. The DR1 molecules were separated into two subsets, DR1a (70 to 80%) and DR1b (20 to 30%), by sequential affinity to 21r5-IgG and 21w4-IgG Sepharose. The alpha- and beta-chains of [3H]mannose-labeled DQw1, DR1a, and DR1b molecules were separated by SDS-PAGE and were recovered by electrophoretic elution. The isolated chains were digested with pronase and the glycopeptides were fractionated by sequential lectin chromatography on immobilized concanavalin A (Con A), Lens culinaris (Lens), and Ricinus communis agglutinin type I (RCA). The N-linked glycopeptides derived from the alpha-chains of DQw1, DR1a, or DR1b showed similar profiles on Con A Sepharose: 45% unbound (ConA I), 25% weakly bound (ConA II), and 30% tightly bound (ConA III). The glycopeptides derived from the beta-chains of DQw1 or DR1 molecules were found almost exclusively (80%) in the fraction unbound to Con A Sepharose, with only 11% and 9% in ConA II and ConA III fractions, respectively. The observation that most of the binding to Con A is associated with the alpha-chain glycopeptides suggests that binding of membrane-associated class II molecules to that lectin must be mediated by the alpha-chains. Binding to Lens Sepharose was higher for beta-(50%) than for alpha-(15%) chain glycopeptides, suggesting that within the intact glycoproteins, the beta-chains are responsible for the interaction with Lens. The ConA I fractions derived from the alpha-chain glycopeptides of either DQw1 or DR1 molecules were separated on RCA-agarose as follows: 60% unbound, 17% retarded, and 20% bound and eluted with 0.1 M galactose. The ConA I fractions derived from the beta-chain glycopeptides of either subset of class II molecules also had a similar profile on RCA-agarose: 70% unbound, 16% retarded, and 10% bound and eluted specifically. After removal of sialic acid residues, all of the ConA I fractions of alpha- and beta-chains bound to RCA-agarose. A high degree of similarity was observed between the corresponding glycopeptides of the three subsets of class II molecules and between the complex N-linked structures of alpha- and beta-chains. Minor variations were observed between DR1a and DR1b glycopeptides which appear greater than those observed between DR1 and DQw1 glycopeptides.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Complete sequence of the HLA DQ alpha and DQ beta cDNA from a DR5/DQw3 cell line

The HLA-D region is composed of three subregions termed DR, DQ, and DP. We previously reported the sequence of a DR5 beta I and two DR5 beta III cDNA from the DR5 cell line Swei. We now report on the nucleotide and deduced amino acid sequence of the DQ alpha and DQ beta cDNA from the same DR5 cell line, which also types as DQw3. Comparison with other available DQ sequences indicates that DQ alpha has one region of major variability, whereas DQ beta appears to have four regions of variability. In addition, these comparisons indicate that DQw3 alpha from DR5 is different from DQw3 alpha from DR4, but identical to DQw2 alpha from DR3. In contrast, DQw3 beta from DR5 is very similar to DQw3 beta from DR4. These data indicate that at least for DQw2 and DQw3 it is the DQ beta chain that is responsible for DQ typing. Most sequence differences in DQ alleles can be attributed to point mutations; however, codon additions/deletions in the DQ alpha chain may contribute to variability. In addition, regions of possible gene conversion in the DQ alpha and DQ beta chains is suggested by the presence of a chi-like sequence in each chain. Finally, comparison of available haplotypes suggest recombination events may take place between DQ beta and DQ alpha, between DQ alpha and DR beta I, and between DR beta I and DR beta III.     

Expression of the human MHC, HLA-DQW6 genes alters the immune response in C57BL/6 mice

In an attempt to obtain direct evidence for the critical role of HLA class II molecules in regulating the immune response, genomic genes for alpha- and beta-chains of HLA-DQw6 from HLA-Dw12 haplotype were introduced into the C57BL/6 (B6) strain of mouse and a line of HLA-DQw6 transgenic mouse was obtained. Tissue specificity of the expression of the transgenes was much the same as that of murine I-Ab genes. DQw6 molecules were expressed on B cells and macrophages in spleen cells and about 30 to 40% of the I-Ab+ spleen cells were positive for DQw6. The HLA-DQw6 transgenic B6 mouse became tolerant to the DQw6 molecules, as evidenced by the MLR and antibody production specific to the DQw6 molecules. The HLA-DQw6 transgenic B6 mouse showed a strong immune response to streptococcal cell wall antigen (SCW), whereas the B6 mouse was a low responder to SCW. The SCW-specific T cell line was established from the transgenic mouse and this T cell line recognized SCW in the context of HLA-DQw6 molecules expressed on the mouse L cell transfectant or on human monocytes. The proliferative response to SCW of primed lymph node T cells and the SCW-specific T cell line derived from the transgenic mice was inhibited by anti-HLA-DQ mAb. Thus, it is clear that the HLA-DQw6 genes acted as major histocompatibility genes in these transgenic mice.