Extended HLA-DQw2 haplotypes: molecular analysis.

The HLA-DQw2 specificity, homogeneous in serology, is strongly associated to two HLA-DR specificities: DR3 and DR7. These alleles are found mainly on DQw2 bearing extended haplotypes with strong linkage disequilibrium. We describe, with BamHI, HindIII and RsaI, two restriction fragments length polymorphisms (RFLP) for the A gene of DQw2. These two subtypes correlated with the DR3 and DR7 specificities. Interestingly, by non-equilibrium pH gradient electrophoresis (NEPHGE), two DQ alpha chains were also found, respectively correlated with the same DR specificities. In addition, HincII polymorphism allowed us to distinguish several patterns of B genes for (DR7) DQw2 haplotypes but without any detectable association with another HLA marker. However, only one DQ beta chain was found by NEPHGE in the (DR7) DQw2 haplotype. Furthermore, HincII discriminated the B genes of the two extended haplotypes: (B8, DR3) DQw2 and (B18, DR3) DQw2. The same result was found by NEPHGE: two DQ beta chains were described, corresponding to the same extended haplotypes. The use of exon-specific DQB probes showed that the genomic polymorphism in DQw2 haplotypes is located, at least, at the 3' end of the gene. These data add new characteristics to the different DQw2 extended haplotypes.     

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.     

Full-length DQβ cDNA sequences of HLA-DR2/DQw1 subtypes: Genetic interactions between two DQβ loci generate human class II HLA diversity

Two-dimensional gel electrophoresis of DQ molecules from three different Dw subtypes (Dw2, Dw12, and Dw21/FJO) of the HLA-DR2/DQw1 haplotype reveals that one β heterodimer of DQ molecule is expressed by each subtype and the DQB chain is electrophoretically variable among the three DR2/DQw1 subtypes. We have constructed cDNA libraries from the same homozygous typing cells used in the two-dimensional polyacrylamide gel electrophoresis analyses (HTC VYT for Dw2, HTC DHO for Dw12, and HTC FJO for Dw21/FJO) and isolated DQβ cDNA clones with full-length coding sequences for each subtype. The deduced amino acid sequences show that the DQβ chains of these three DR2/DQw1 subtypes are highly polymorphic and confirm their electrophoretic heterogeneity: for a mature protein of 229 amino acids, they differ with each other by 10–17 amino acids in the first domain and by 3–7 residues in the C-terminal sequence. Comparison among the available DQβ sequences representing the four major DQ specificities (DQw1, DQw2, DQw3, and DQw4) in the DQ subregion as defined by serologic method suggests that (1) DR2, Dw2, DQw1 and DR3, DQw2 haplotypes probably interact with each other to generate the DQw3 and DQw4 β alleles and (2) an evolutionary scheme may be proposed to relate the various β alleles of the four major DQ specificities.     

Unusual HLA-DR,DQ haplotypes found in South African families of black, Asian Indian, and mixed ancestral origin.

Four non-Caucasoid families with the unusual HLA-DR,DQ haplotypes DRw17,DQw7; DR9,DQw2; DR4,DQw2; and DR4,DQw5 were studied. All four haplotypes showed identical serological patterns to those seen with the equivalent Caucasoid antigens, but no HLA-Dw specificities could be assigned. TaqI restriction fragment length polymorphism (RFLP) patterns observed using DRB, DQB, and DQA probes showed that the DRw17,DQw7 haplotype may have originated from a homologous crossover between a DRw17,DQw2 haplotype and a haplotype with DQw7. The results obtained for the DR9,DQw2 and DR4,DQw2 haplotypes suggest that these could have resulted from recombination events with an ancestral "black" DQw2 haplotype. From the RFLP data, it is difficult to postulate the origin of the DR4,DQw5 haplotype being from a single recombination event.     

Analysis of DR and DQ gene products of the DR4 haplotype in patients with IDDM: Possible involvement of more than one locus

Fifteen DR4-bearing haplotypes from twelve patients with insulin-dependent diabetes mellitus (IDDM) were analyzed serologically, cellularly, and biochemically. The HLA-Dw composition of these DR4-positive haplotypes was Dw4 (46%), Dw14 (22%), and Dw10 (33%). The biochemical analysis by two-dimensional electrophoresis (2D-PAGE) of the DR beta chains showed that each Dw specificity is characterized by a specific DR4 beta chain that appears to be identical in normal and diabetic individuals. Analysis of DQ beta chains in the DR4-bearing haplotypes revealed that certain Dw specificities such as Dw4 are characterized by the presence of either the DQw7 (formerly DQw3.1) or DQw8 (formerly DQw3.2) alleles, which generate the Dw4.1 or Dw4.2 subtypes, respectively. Others such as Dw14 and Dw10 are characterized by the presence of the DQw8 allele. In our sample of 12 patients the Dw4.2 (Dw4, DR4βI-4 DQw8) and Dw10 (Dw10, DR4βI-1, DQw8) subtypes were predominant. It is concluded that individual DR β and DQ β gene products from the DR4-bearing haplotype of IDDM patients are identical to those of normal control subjects and that Dw14 as well as Dw10 are involved in disease susceptibility. We suggest that disease susceptibility may be influenced by more than one locus within the HLA-D region.     

DR and DQ beta cDNA sequences associated with a DR2 haplotype

Three cDNA clones encoding a DQ beta and two DR beta polypeptides have been isolated and sequenced from an American black individual expressing a DR2,DQw1 haplotype. The sequences of the cDNA clones are identical to previously described DR and DQ sequences from a DR2,Dw2 cell. The differences between DQw1-associated beta chains from DR2 and DR1 haplotypes is substantial, although a DQw1-specific sequence can be identified. The identical DQ and DR beta sequences found in unrelated individuals from different racial backgrounds suggests that class II structural polymorphism within the human population will be limited.     

HLA-DR, DQ antigens in North American Caucasians

HLA-DR, DQ specificities are determined by serological methods in 2,586 North American Caucasians. Antigen frequency, gene frequency and haplotype frequency are computed for each phenotype observed. The DR and DQ loci antigen distributions are well-fitted to a Hardy-Weinberg equilibrium (p greater than 0.25 for DR locus, p greater than 0.10 for DQ locus). All World Health Organization (WHO) recognized HLA-DR,DQ specificities were found except HLA-DRw18, which has been identified only in the black population. DR and DQ linkage disequilibria among recently defined splits is observed. The following DR and DQ associations are found: DR1 and DQw5; DR4 and DQw7, DQw8; DR7 and DQw2, DQw9; DR8 and DQw4, DQw6, DQw7; DR9 and DQw2, DQw9; DRw10 and DQw5; DRw11 and DQw6, DQw7; DRw12 and DQw5, DQw7; DRw13 and DQw6, DQw7; DRw14 and DQw5, DQW7; DRw15 and DQw6, DQw7; DRw16 and DQw5; DRw17 and DQw2. In this large study population, the following unusual DR and DQ associations are found: DR4, DQw2; DR4, DQw1; DR1, DQw7; DR7, DQw5; DRw17, DQw6; and other unusual haplotype phenotypes containing DRX, DQX.     

Allogenotypes defined by short DQ alpha and DQ beta cDNA probes correlate with and define splits of HLA-DQ serological specificities

HLA-DR and -DQ serotyped cell lines and peripheral blood leucocytes were analysed by Southern blot allogenotyping. Using a short DQ beta cDNA probe, a DQ beta allelic series was defined by restriction fragment length polymorphism (RFLP) with the restriction endonuclease TaqI. This DQ beta allelic series correlates with, and defines splits of, the HLA-DQ serological specificities DQw1 (DQ beta 1a and DQ beta 1b RFLPs), DQw2 (DQ beta 2a and DQ beta 2b RFLPs) and DQw3 (DQ beta 3a and DQ beta 3b RFLPs). By sequential use of a short DQ alpha cDNA probe a second, DQ alpha allelic series is defined by RFLP. This series correlates to a lesser extent than DQ beta RFLPs with the HLA-DQ serological specificities. Thus, two DQ alpha RFLPs correlate with a single DQ serotype (DQ alpha 1a and DQ alpha 1c with DQw1), but three DQ alpha RFLPs correlate with more than one DQ serotype (DQ alpha 1b with DQw1 and DQw3; DQ alpha 2 with DQw2 and DQw3; DQ alpha 3 with DQw2 and DQw3). Individual DQ beta and DQ alpha RFLP subtypes appear to correlate with single, or associated HLA-DR specificities. Specific combinations of DQ beta with DQ alpha RFLPs also correlate with HLA-Dw splits of DR2 and DRw6. A system for HLA-DNA typing is described, which uses RFLP patterns generated by sequential hybridization of TaqI-digested DNAs with short DR beta, DQ beta and DQ alpha cDNA probes. The DQ beta and DQ alpha probes not only identify the DQ allele, but because of linkage disequilibrium with DR, help to assign the DR allele, which may not always be identified with a DR beta probe alone.     

Cells homozygous for two HLA-DR7-associated HLA-D specificities express highly similar DR molecules but different DQ molecules

The Ia molecules expressed by cells homozygous for two distinct HLA-DR7-associated HLA-D specificities, Dw7S and Dw11L, were compared. The complete Ia phenotypes of these cells are DR7, DRw53, DQw2, Dw7S, DPw4 and DR7, DRw53, DQw3, Dw11L, DPw4, respectively. Immunofluorescence analysis revealed that three DQ-specific monoclonal antibodies (Leu-10, 33.1, and HK-19), which detect polymorphic DQ determinants that do not correspond to known serologic specificities, are nonreactive with DR7, Dw7S cells but are reactive with DR7, Dw11L cells. The DR molecules isolated from Dw7S and Dw11L cells are very similar and comigrate when analyzed together by two-dimensional gel electrophoresis. In contrast, the DQ molecules isolated from these cells are structurally distinct: the DQ beta chains of DQw2-bearing molecules from Dw7S cells are very basic, while those of DQw3-bearing DQ molecules from Dw11L cells are more acidic. The finding that two DR7, D-different cells express indistinguishable DR molecules and structurally distinct DQ molecules documents a unique pattern of Ia molecular organization which is different from those previously described for the DR2-, DR4-, or DRw8-associated HLA-D specificities.     

Functional properties of HLA-DR-BON alleles associated with DQw5(w1) and with DQw7(w3): A family study

Among the DR specificities undefined by serology, DR-BON is peculiar because RFLP cannot distinguish it from the well-defined allele DR1 even if the two specificities are very different functionally. The occurrence of two DR-BON-like alleles in the same family, one associated to the DQw5 split of DQw1 and the other associated to the DQw7 split of DQw3, enabled us to compare the properties of these alleles. The RFLP analysis showed a typical DR1-like picture for both alleles when probed with DR beta, but for one of the alleles the DQ beta probe gave a DQw7 pattern. Primary mixed lymphocyte cultures showed weak to moderate stimulation between cells from individuals identical for one haplotype and differing for the DR-blank haplotypes, but by test with cloned reagents we were not able to define differences between the two DR-blank molecules. Two-dimensional gel electrophoresis and spot-test with a probe covering the third hypervariable region of the DRB1 gene showed no difference between the two alleles. We thus think that the two DR alleles are identical and that the stimulation observed in primary cultures probably is caused by incompatibility for DQ and DP or class I.     

Molecular complexity of HLA-DQw3: The TA10 determinant is located on a subset of DQw3 β chains

In attempts to examine the relationships between serologic and structural polymorphisms of HLA-DQ molecules we have analyzed several monoclonal antibodies generated against polymorphic determinants on HLA-DQ molecules. One antibody, SFR20-DQw3, has a serologic reactivity like that of the previously characterized anti-DQw3-like monoclonal antibody. IVD12, but differs from IVD12 in its affinity for DQw3 molecules associated with DR4 and DRw9 haplotypes. Two other monoclonal antibodies have identical serologic and molecular specificity, and react with a subset of DQw3 positive cells: they have been designated SFR20-DQβ5. Biochemical analysis of the DQ molecules carried by DQw3-positive cell lines associated with different DR haplotypes (DR4, DR5, DRw8, DRw9, DRw12), reveal the presence of at least three different kinds of β chains carrying the DQw3 epitope. All the cell lines bound by SFR20-BQβ5 (DR5, DRw8, and DRw12) possess DQβ chains of indistinguishable electrophoretic mobility, which are different from the DQβ chains of DQw3 cell lines not bound by this antibody while DQw3 β chains carried by DR4 and DRw9 haplotypes are distinct from DQβ5-positive BLCL and from each other. The serologic reactivity of antibody DQβ5 correlates perfectly with in RFLP of the DQ β gene designated DQw3.1 (Kim et al.: PNAS 828139, 1985), and with the serologic specificity TA10 as defined during the Ninth International Workshop (Schreuder GMT et al.: Histocompatibility Testing 1984). SFR20-DQβ5 reacts with a separated β chain by Western blot analysis. The finding of industinguishable β chain electrophoretic mobility for all DQβ5/TA10 positive cell lines tested provide the molecular basis for these specificities, and strongly suggest that antibody SFR26-DQβ5 detects a single allele of the multiple DQβ alleles which can contribute to the formation of the DQw3 specificity.     

HLA and narcolepsy in a German population

In this paper the first MHC data including HLA-A, B, C, DR, DQ and complement BF, C4A, C4B determinants in German narcoleptics are presented together with the first family studies in European Caucasoids. 57 out of 58 unrelated patients (98.3%) were positive for DR2 and DQw1, respectively. In contrast to all other reports, one patient with typical signs of narcolepsy was found to be DR2/DQw1 negative. Data showing significant increase in the frequency of B7, and normal frequencies of B35 were discordant with data from Japanese patients. Definition of the extended DR2 linked haplotypes, deduced from 6 families, revealed that 5 out of 12 were DQw1, DR2, BFS, C4B1, C4A3, B7 (Cw7), while 11/12 had DR2, DQw1, BFS, C4A3, C4B1 in common. In one multiple case family two genotypically different DR2 haplotypes were identified in affected siblings. Results from the family study were concordant with a dominant mode of inheritance with incomplete penetrance of a hypothetical disease susceptibility gene.     

Restriction fragment length polymorphism analysis of HLA haplotypes in families with Type I diabetes mellitus

HLA Class II polymorphisms were analysed in 27 families with at least one Type I diabetic proband using Southern blotting technique according to 10th Histocompatibility Workshop Standards. The probes used were DRB, DQA1, DQB1 and DOB. We have studied 108 haplotypes and performed segregation analysis with HLA serology and restriction fragment length polymorphism (RFLP) data and compared "affected" with "non-affected" haplotypes (not inherited by IDDM patients). RFLPs correlated well with DR and DQ serology and detected additional polymorphisms. In particular, DQB polymorphism analysis showed segregation of the DQw3 splits with 88.5% of the DR4 affected haplotypes bearing the DQw3.2 split (now DQw8) and 11.5% the DQw3.1 split (now DQw7) while in the non-affected DR4 haplotypes 33.3% were DQw3.2 and 66.6% were DQw3.1. Haplotype analysis showed that DR4-DQw3.2 was in strong linkage with the U fragment (2.1 kb Taq I) of DQA2 (DX alpha) and with the L fragment (5.4 kb BamH I) of DOB. This study confirms previous observations of DQB polymorphisms in heterozygous IDDM patients, supports the protective effect of DQw3.1 (DQw7) against the development of the disease and demonstrates the importance of DQw3.2 (DQw8) for susceptibility to Type I diabetes.     

Two variants of DRw52, DR3, and DQw2 specificities distinguish two different DR3-bearing extended haplotypes

HLA-DR beta and DQ beta MHC antigens present on B-lymphoblastoid cell lines homozygous for either [HLA-B8,DR3,SC01] or [HLA-B18,DR3,F1C30] were studied by two-dimensional gel electrophoresis. Comparison of neuraminidase-treated DR proteins from these cells showed that DR3-bearing cells express two DR beta genes. However, one DR beta chain (beta a) is nonpolymorphic, whereas the other beta chain (beta b) is polymorphic. Two variants of DR beta (DR3 or DRw52) and two of DQ beta (DQw2) were found, with all the examples of each extended haplotype carrying only one of these sets of variants. The variants thus absolutely distinguished the two DR3-bearing extended haplotypes. These results support the hypothesis of extended haplotypes at the protein level, and demonstrate the fixity of alleles on them in the HLA-B-D/DR region.     

Multiple epitopes on a single DQ molecule from the DQw3-carrying haplotypes

Multiple polymorphisms on the DQ molecule(s) have been detected by monoclonal antibodies (MoAbs). Among these, TA10 and IIB3 have been described as two new alleles in the DQ region other than the conventional DQw1-w3 allelism. The TA10 specificity is DQw3-related and is in linkage disequilibrium with DR5 and weakly associated with DR4. The IIB3 specificity is DQw1-related and is in linkage disequilibrium with DR2, DR4, DRw9 and DRw13. Thus, the DQw3-carrying haplotypes are either positive with TA10 or IIB3. The molecular and topological analysis has revealed that both TA10 and IIB3 determinants were expressed on a single DQ molecule that also carried the DQw3 determinants on DR5 and DR4 cell lines, respectively. Thus, a single DQ molecule generated multiple epitopes detected by alloantisera and/or MoAbs at least on the DQw3-carrying haplotypes. These would be useful for unraveling the largely unknown functions of the DQ class II molecules.     

HLA-DQw3-related determinants: Analysis of subunit and spatial relationships

More polymorphism exists among DQ region gene products than is suggested by present serologic definitions of these class II molecules. DQ beta polymorphism among haplotypes carrying the DQw3 specificity is considerable. The TA10 specificity is present on one allele of at least three different DQ beta alleles that carry the DQw3 specificity. We have examined a series of monoclonal antibodies directed against different DQ beta alleles carrying the DQw3 specificity to determine subunit and spatial relationship among the epitopes detected by these antibodies. The antibodies were examined by Western blotting and for their ability to inhibit the binding of fluoresceinated antibodies on either TA10+ or TA10- DQw3 haplotypes. Our results reveal that (1) multiple DQw3-related epitopes exist; (2) several anti-DQw3-related antibodies generated against TA10- DQw3 molecules are unable to inhibit the binding of a TA10-specific antibody on a TA10+ haplotype while strongly inhibiting binding of an antibody detecting the reciprocal DQ beta polymorphism on a TA10- DQw3 haplotype; and (3) there is a strong requirement for three-dimensional conformation in the formation of the majority of the epitopes examined here. Analysis of previously published amino acid sequences for the haplotypes investigated here suggest that charge changes at amino acids 45, and 57, respectively, may have a significant effect in changing the spatial relationship between the DQw3-related epitope(s) and other polymorphic determinants on DQ beta chains.     

A new HLA-DR2 extended haplotype is involved in insulin-dependent diabetes mellitus susceptibility

To ascertain why HLA-DR2 seems to confer only a moderate resistance to insulin-dependent diabetes mellitus (IDDM) in the high-incidence population of Sardinia, Italy, 32 families having one individual affected with IDDM (the proband) and 31 families without IDDM history were randomly selected from the same geographical area and serologically and molecularly HLA typed. The 64 haplotypes of the probands were then compared with the 122 haplotypes determined in the parents from the control families. Two haplotypes were found to have the highest percentage in the general population (12.3% and 7.3%, respectively). The first is the already described "Sardinian" extended haplotype A30, Cw5, B18, 3F130, DR3, DRw52, DQw2 (39.0% in IDDM patients). The second is an extended haplotype that has not been identified before (A2, Cw7, B17, 3F31, DR2, DQw1), and, due to the DR2 allele, we expected it to be decreased in IDDM. However, a stratified analysis performed by removing the DR3 and DR4 haplotypes showed that the frequency of this haplotype is significantly increased in IDDM patients. A peculiar feature of this haplotype is its DQw1 allele, which is DQB1*0502 and has serine in position 57 of the DQ beta chain. The absence of an aspartic acid in this position seems to confer susceptibility to IDDM and not resistance. The fact that DQB1*0502 was present in 75% of the Sardinian DR2 haplotypes may explain why, in Sardinia, DR2 is not providing the commonly recognized resistance to IDDM.     

Analysis of MHC class II DNA polymorphisms in Negroid subjects

Study of the MHC class II region is complicated by strong linkage disequilibrium between DR and DQ. Comparison of DR-DQ haplotypes between different races partly resolves this problem. We present the results of an analysis of DRB, DQA and DQB restriction fragment length polymorphisms in serologically DR-typed subjects of Negroid origin. Clearly distinguishable DRB RFLPs were observed for DR1,2,5,7 and w8. DR4,9 and w10 were uncommon in this group. DR3 was associated with two extended haplotypes, one characterised by the DQw4 allele, the other by the DQw2 allele. A recently recognised DQB RFLP (DQB 2c) was associated with DR7 and also occurred on DR5 and DR9 haplotypes. Both DR5 and DRw6 were heterogeneous in their DR-DQ relationships. Negroid subjects exhibit DR-DQ relationships distinct from other races. These provide scope for further study of MHC class II associations with disease.     

Extensive study of DRB, DQA, and DQB gene polymorphism in 23 DR2-positive, insulin-dependent diabetes mellitus patients.

To gain insight into the HLA subregions involved in protection against insulin-dependent diabetes mellitus (IDDM) we investigated the polymorphism of HLA-DR and -DQ genes in 23 DR2 IDDM patients. Results show the following. (1) Fourteen patients (61%) possess the DRB1, DRB5, and DQB1 alleles found in DRw16/DQw5 healthy people. These data contrast with the 5% of DRw16 normally found in DR2 populations and are in agreement with former observations supporting that the DRw16 haplotype is not protective. (2) Nine DR2 patients, i.e., 39% versus 95% in published DR2 controls, possess the DRB alleles found in DRw15 unaffected people. Among them, six patients have also DQA1 and DQB1 alleles identical to those found in DRw15/DQw6 healthy individuals. These data confirm that the DRw15/DQw6 haplotype is protective but indicate that none of the DR or DQ alleles, alone or in association, confers an absolute protection. (3) Our most striking results concern the very high frequency of recombinant haplotypes among the DRw15 patients: 3 of 9. In these three patients recombinations led to the elimination of both DQB1 and DQA1 alleles usually associated with DRw15. This strongly suggests that the occurrence of IDDM in these DRw15 patients is due to the absence of the usual DQ product and thus reinforces the assumption that DQ rather than DR region is involved in the protection conferred by the DRw15/DQw6 haplotype. Finally, analysis of the non-DRw15 haplotypes in heterozygous patients showed that IDDM can occur in the absence of any DQ alpha beta heterodimer of susceptibility.     

Two HLA-DQ-specific human-human hybridoma antibodies (TrG6;TrC5) define epitopes also expressed by a transcomplementing hybrid DQ molecule (DQw7 alpha/DQw4 beta)

We have generated two IgG human-human hybridoma Abs, TrG6 and TrC5, that define subsets of HLA-DQ. TrG6 combined selectively with lymphoblastoid cell lines that expressed DQw1 or DQw4. By sequential immunoprecipitation, competition with other mAbs of defined specificity for binding to antigen, and experiments where HLA antigens from cell lysates crosslinked pairs of mAbs, it was established that TrG6 bound a DQ-molecule. mAb TrC5 specifically recognized DQw2+DR3+ and DQw7+DR5+ cells. The reaction pattern of TrC5 with HLA-loss mutants indicated that TrC5 bound to DQw2 of the DQw2+DR3+ haplotype. Antigens in lysate from DQw7+DR5+ cells crosslinked TrC5 to the murine mAbs Tü22 (anti-DQ monomorphic) and IVD-12 (anti-DQw7 + DQw8 + DQw9), demonstrating that on these cells the TrC5 epitope is located on DQw7 molecules. Lysates from DQw7+DR5+/DQw4+DRw8+ heterozygous cells crosslinked TrG6 and TrC5, and available evidence indicated that the epitopes defined by these two mAbs were expressed by the transcomplementing DQ-molecule DQw7 alpha/DQw4 beta, where the DQw7 alpha chain specifies epitope TrC5 and the DQw4 beta chain specifies epitope TrG6. Taken together with published nucleotide sequences of DQ alpha and beta genes, our data are consistent with the conclusion that the amino acids at positions 69 and/or 75 of the DQ alpha chain of DQw2+DR3+ and DQw7+DR5+ haplotypes are critical for epitope TrC5. The previously reported human-human hybridoma Ab TrB12 reacts with DQw6, DQw8, and DQw9. The specificity of the murine mAb IIB3 is similar to that of TrB12, but, unlike TrB12, IIB3 also binds DQw4+ cells.