DNA sequence analysis of the HLA-DRw12 allele

Identification of sequence errors in HLA-DRB1*0801 and HLA-DRB1*12011

We report the identification of previously unrecognised errors in the nucleotide sequences of two long established HLA-DRB1 alleles, DRB1*0801 and DRB1*12011. The errors were detected during development of sequencing based typing (SBT) methods for the HLA-DRB1 locus and were confirmed by sequencing cell lines from the 10th International Histocompatibility Workshop (IHW).

New DR5 sequences: a novel DRB1*11122 allele identified in Paiwan tribe members of Taiwan and a corrected sequence for the DRB1*1201 allele

We report herein the identification of a new DRB1 allele using sequence-based typing (SBT). This novel allele, HLA-DRB1*11122, was found in an aboriginal individual (SWP71) from the Paiwan tribe in the southern part of Taiwan. This individual was typed by SBT method as having an HLA genotype of HLA-A*24021/24021, HLA-B*4001/4002, HLA-DRB1*11122/15011, HLA-DRB3*0202, and HLA-DRB5*01011. This new allele differs from DRB1*1112 in the polymorphic exon 2 only at codon 34 (CAA-->CAG; both specify glutamine) and from DRB1*1110 in the exon 2 sequence only at codon 32 (CAT-->TAT; H32T). The most likely candidate allele which is found in the aboriginal populations of Taiwan and which may mutate into this new allele is DRB1*11011. DRB1*11122 allele differs from DRB1*11011 allele in the polymorphic exon 2 at both codon 34 (CAA-->CAG) and codon 37 (TAC-->TTC; T37F). This novel HLA-DRB1*11122 allele was also found in another aboriginal individual (SWP90) from the same Paiwan tribe. This SWP90 individual was typed by SBT method as having an HLA genotype of HLA-A*24021/24021, HLA-B*4002/5502, HLA-DRB1*11122/1201, and HLA-DRB3*01011/0202. However, the original DRB1*1201 sequence from HERLUFF was found to be erroneously reported and the corrected sequence from SWP90 is now presented herein.

A novel HLA-DR12 allele (DRB1*1206) found in a Korean B-cell line

At least 6 HLA-DRB1*12 alleles have been identified to date with nucleotide polymorphism occurring at codons 37, 57-58, 60, 67, 85 and 87. In this report, we describe the identification of another new HLA-DRB1*12 allele: DRB1*1206. This novel allele was found in an Epstein-Barr virus (EBV)-transformed Korean B-cell line "K-KT" having the HLA-phenotype A3, 24; B44, 61; Cw3; Bw4, 6; DR12, 13 during full-length cDNA isolation for cell line characterization and for production of HLA-DR recombinant proteins. The allele was identified initially by cycle sequencing of subcloned HLA-DRB full-length cDNA.

HLA-DRB1 gene sequences in HLA-DR4 positive and negative patients with rheumatoid arthritis

The second exon of the DRB1 gene encoding for the first domain of the HLA-DR beta 1-chain was sequenced in 16 patients (10 DR4/DR1 positive, 6 DR4/DR1 negative) with seropositive rheumatoid arthritis (RA). We could confirm the strong association of susceptibility to RA with functionally equivalent conformations on otherwise distinct MHC molecules. At least one HLA-DR allele in all of the analysed DR4 or DR1 positive patients showed such an epitope with a minimal variability limited to residue 71. However, in HLA-DR4 and -DR1 negative patients such a similar epitope could not be detected.

Mhc-DRB and -DQA1 nucleotide sequences of three lowland gorillas. Implications for the evolution of primate Mhc class II haplotypes

Mhc-DRB and -DQA1 second-exon and -DRB 3'-untranslated-region nucleotide sequences of three lowland gorillas with no known family relationship with each other and of two HLA homozygous typing cell lines were determined and compared with published primate Mhc-DRB and -DQA1 sequences. Eleven distinct MhcGogo-DRB second-exon sequences were found, which represent the gorilla counterparts of the HLA-DRB1*03, -DRB1*10, -DRB3, -DRB5, and -DRB6 allelic lineages. One Gogo-DRB second-exon sequence does not have an obvious human counterpart and is tentatively designated Gogo-DRBY*01. The gorilla equivalents of the HLA-DRB2 and -DRB8 loci were identified as judged on Mhc-DRB 3'-untranslated-region sequences. In addition, four different Gogo-DQA1 alleles belonging to three different allelic lineages were detected. The Mhc-DRB-DQA1 haplotypes of these gorillas were deduced based on the obtained Mhc-DRB and -DQA1 sequences and the two published Mhc-DRB haplotypes of the lowland gorilla Sylvia. All deduced Gogo-DRB-DQA1 haplotypes show gene constellations different from known HLA-DRB-DQA1 haplotypes, while some of the Gogo-DRB haplotypes presented here contain more DRB genes than the HLA-DRB haplotypes. Based on phylogenetic trees, bootstrap analyses, and the gorilla, chimpanzee, and human Mhc-DRB haplotypes described, we propose that at least two Mhc-DRB loci, here tentatively designated Mhc-DRBI and -DRBII, existed on an ancient primate Mhc-DRB haplotype. The Mhc-DRB1*01, -DRB1*02 (-DRB1*15 and -DRB1*16), -DRB1*03 (-DRB1*03, -DRB1*08, -DRB1*11, -DRB1*12, -DRB1*13, and DRB1*14), and -DRB1*10 allelic lineages and -DRB3 and -DRBY loci probably evolved from the hypothetical primate Mhc-DRBI locus, whereas the present primate Mhc-DRB2, -DRB4, and -DRB6 loci originate from the ancient Mhc-DRBII locus of this core primate Mhc-DRB haplotype.

Comparative anatomy of the primate major histocompatibility complex DR subregion: evidence for combinations of DRB genes conserved across species

The class II region of the human major histocompatibility complex (HLA) is made up of three major subregions designated DR, DQ, and DP. With the aim of gaining an insight into the evolution and stability of DR haplotypes, a total of 63 cosmid clones were isolated from the DR subregion (Gogo-DR) of a western lowland gorilla. All but one of these cosmid clones were found to fall into two clusters. The larger cluster, A, was defined by 41 overlapping cosmid clones and contained a DRB gene segment made up of exons 4 through 6 and four DRB genes, designated Gogo-DRB6, Gogo-DRB5*01, Gogo-DRB8, and Gogo-DRB3*01. The total length of this cluster was approximately 180 kb. The second cluster, B, encompassed a contiguous DNA stretch of approximately 145 kb and was composed of 21 overlapping cosmid clones. Cluster B contained three DRB genes, designated Gogo-DRB1*08, Gogo-DRB2, and Gogo-DRB3*02. One cosmid clone (WP1-9) containing a DRB pseudogene could not be linked to either cluster A or B. Neither the organization of cluster A nor that of cluster B was identical to that of known HLA-DR haplotypes. However, two gorilla DRB genes, Gogo-DRB6 and Gogo-DRB5*01, the human counterparts of which are linked in the HLA-DR2 haplotype, were found to be located next to each other in cluster A. The arrangement of the Gogo-DRB genes in cluster B, which is presumed to be the gorilla DR8 haplotype, was similar to that of HLA-DR3/DR5/DR6 haplotypes and to that of the presumed ancestral HLA-DR8 haplotype.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleotide sequences of the HLA-DRw12 and DRw8 B1 chains from an Australian aborigine

To gain a more detailed understanding of the molecular structure of the HLA genes in Australian aborigines, the polymorphic first-domain sequences of the DR B alleles were determined in an aborigine who was tissue typed as HLA-DRw8 and a probable DRw12; DRw52; DQw1,7. Both peripheral blood leukocytes and a lymphoblastoid cell line were reactive with the majority of DRw12-specific sera, but also with half of the DRw11-specific sera. With the use of primers specific for the conserved regions flanking the first domain, the polymerase chain reaction technique was used to amplify first-strand synthesis products prepared from the cell line. Two distinct DRB1 sequences were obtained. One was virtually identical to the reported DRw8,Dw8.3 sequence present in an Asian haplotype, differing only by a single silent nucleotide substitution at the third position of codon 36 (A to G). A second DRB allele was closely related to two recently published and nearly identical sequences for DRw12, with amino acid differences at positions 67 and 85 of the first domain. DRB RFLP studies on this cell line using the Taq I restriction enzyme indicated bands previously described for the DRw8 and DRw12 haplotypes.

Molecular analysis of HLA-DRB1*08/12 alleles: identification of two additional alleles

A nonradioactive oligotyping method that takes advantage of selective amplification using the polymerase chain reaction (PCR) and oligonucleotide probe hybridization was developed to distinguish all reported HLA-DRB1*08/12 alleles. Selective amplification was achieved using a primer complementary to the sequence encoding YSTGECY at positions 10-16 in the first hyperpolymorphic region (HPMR). This selective amplification of the HLA-DRB1*08/12 subset of alleles provides a refinement in HLA oligotyping that permits unambiguous oligotyping of many heterozygotes that cannot be resolved using less selective amplification alternatives. The amplified DNA was hybridized with a panel of then digoxigenin-labeled probes to resolve oligotypes that correspond to all reported HLA-DRB1*08/12 alleles. Oligotyping of HLA-DRB1*08/12 samples revealed two previously unknown HLA-DRB alleles. One allele, DRB1*0805, differs from DRB1*0801 by a leucine to alanine substitution at position 74. This allele is of particular interest because it is very similar to HLA-DRB1*08 alleles (YSTGECY and lack of an associated HLA-DRB3 gene), but it lacks leucine at position 74, which is characteristic of all previously reported DRB1*08 alleles. The second HLA-DRB1*08 allele, DRB1*0804, differs from DRB1*0802 by a glycine to valine substitution at position 86.

Differential effects of cyclosporin A on diverse B cell activation phenomena triggered by crosslinking of membrane IgM

Cyclosporin A (CsA) was tested for its modulatory effects on the mIgM-mediated signaling of G0*-associated increases in class II MHC expression, G1-related RNA synthesis, and S phase-related DNA synthesis in human B cells. While CsA at concentrations as low as 10-100 ng/ml could completely ablate anti-IgM-induced DNA synthesis, earlier G1-associated RNA synthesis was only partially inhibited, and signaling of increased membrane class II MHC expression was unaffected by up to 1000 ng/ml of CsA. Similar phenomena were observed in a clonal population of leukemic B lymphocytes susceptible to anti-IgM-mediated activation in the absence of T cells and T cell factors indicating (a) that the inhibitory effects are not due to CsA-mediated suppression of cytokine production by contaminating T cells, and (b) that the varying effects of CsA on the diverse activation phenomena do not reflect B cell subpopulation diversity. Pulsing studies revealed that while maximal suppression of anti-IgM-induced G1-associated RNA synthesis required CsA at culture initiation, near maximal suppression of DNA synthesis occurred when CsA, or soluble human IgM, was added up to 30 hr after the initial exposure of resting B cells to the anti-IgM ligand. These latter findings are consistent with the possibility that the CsA-mediated suppression of S phase entry is due to the inhibition of a signaling event proximal to mIgM ligation which must be repeatedly initiated throughout the first 30 hr of activation.

The evolutionary origin of the HLA-DR3 haplotype

The human HLA-DR3 haplotype consists of two functional genes (DRB1*03 and DRB3*01) and one pseudogene (DRB2), arranged in the order DRB1...DRB2...DRB3 on the chromosome. To shed light on the origin of the haplotype, we sequenced 1480 nucleotides of the HLA-DRB2 gene and long stretches of two other genes, Gogo-DRB2 from a gorilla, "Sylvia" and Patr-DRB2 from a chimpanzee, "Hugo". All three sequences (HLA-DRB2, Gogo-DRB2, Patr-DRB2) are pseudogenes. The HLA-DRB2 and Gogo-DRB2 pseudogenes lack exon 2 and contain a twenty-nucleotide deletion in exon 3, which destroys the correct translational reading frame and obliterates the highly conserved cysteine residue at position 173. The Patr-DRB2 pseudogene lacks exons 1 and 2; it does not contain the twenty-nucleotide deletion, but does contain a characteristic duplication of that part of exon 6 which codes for the last four amino acid residues of the cytoplasmic region. When the nucleotide sequences of these three genes are compared to those of all other known DRB genes, the HLA-DRB2 is seen as most closely related to Gogo-DRB2, indicating orthologous relationship between the two sequences. The Patr-DRB2 gene is more distantly related to these two DRB2 genes and whether it is orthologous to them is uncertain. The three genes are in turn most closely related to HLA-DRBVI (the pseudogene of the DR2 haplotype) and Patr-DRB6 (another pseudogene of the Hugo haplotype), followed by HLA-DRB4 (the functional but nonpolymorphic gene of the DR4 haplotype). These relationships suggest that these six genes evolved from a common ancestor which existed before the separation of the human, gorilla, and chimpanzee lineages. The DRB2 and DRB6 have apparently been pseudogenes for at least six million years (myr). In the human and the gorilla haplotype, the DRB2 pseudogene is flanked on each side by what appear to be related genes. Apparently, the DR3 haplotype has existed in its present form for more than six myr.

Primate DRB6 pseudogenes: clue to the evolutionary origin of the HLA-DR2 haplotype

The HLA-DR2 haplotype contains three beta-chain encoding DRB genes and one alpha-chain encoding DRA gene. Of the three DRB genes, two are presumably functional (HLA-DRB1 and HLA-DRB5), whereas the third (HLA-DRBVI) is a pseudogene. A pseudogene closely related to HLA-DRBVI is present in the chimpanzee (Patr-DRB6) and in the gorilla (Gogo-DRB6). We sequenced the HLA-DRBVI and Patr-DRB6 pseudogenes (all exons and most of the introns), and compared the sequence to that of the Gogo-DRB6 gene (of which only the exon sequence is available). All three pseudogenes seem to lack exon 1 and contain other deletions responsible for shifts in the translational reading frame. At least the HLA-DRBVI pseudogene, however, seems to be transcribed nevertheless. The chimpanzee pseudogene contains two inserts in intron 2, one of which is an Alu repeat belonging to the Sb subfamily, while the other remains unidentified. These inserts are lacking in the human gene. A comparison with sequences published by other investigators revealed the presence of the HLA-DRBVI pseudogene also in the DR1 and DRw10 haplotypes. Measurements of genetic distances indicate DRB6 to be closely related to the DRB2 pseudogene and to the HLA-DRB4 functional gene. In humans, gorillas, and chimpanzees, the DRB6 pseudogene is associated with the same functional gene (DRB5) indicating that this linkage disequilibrium is at least six million years old and that DR2 is one of the oldest DR haplotypes in higher primates.

Production of two human hybridomas secreting antibodies to HLA-DRw11 and--DRw8+w12 specificities

In this study we describe the production of two human monoclonal antibodies (mAbs) HMP12 and HMP14, that recognize polymorphic HLA-DR specificities. These mAbs have been produced by hybridization of antibody-secreting Epstein-Barr virus-transformed cells with SHM-D33 human-mouse heteromyeloma. By microcytotoxicity assay HMP12 mAb was found to react with all DRw11-positive cells and HMP14 mAb with all cells bearing the DRw8 or the DRw12 specificity. Cytotoxic activity of HMP14 was completely removed after absorption with DRw8- or DRw12-positive cells and unaffected by absorption with cells carrying different DR specificities. The HLA specificity was further analyzed by cytofluorometry on mouse transfectant cells. The reactivity of the two mAbs was correlated with the presence of a particular polymorphic amino acid residue in the DR beta chain and by this approach the epitopes possibly involved in the antibody binding sites were predicted.

The complexity of DRw6 and DR5 haplotypes in American blacks demonstrated by serology, cellular typing, and restriction fragment length polymorphism analysis

This study describes the diversity of DRw6 and DR5 haplotypes in the American black population using serology, cellular typing, and restriction fragment length polymorphism (RFLP) analysis. DRw6 (DRw13 and DRw14) and DR5 (DRw11 and DRw12) haplotypes are observed at a high frequency in this population (DRw6: 32%, DR5: 30%). Many of these haplotypes express undefined HLA-D specificities and unusual DQ and DRw52 associations which previously have not been well characterized or reported (e.g., DRw13, DQw5, DRw52c, D-; DRw13, DQw2, DRw52a, D-; DRw11, DQw5, DRw52c, D-). Serologic analysis of class II alleles in American blacks suggests the presence of DRw13, DRw11 and DQw6 allelic variants and demonstrates the difficulty in defining DRw6 and DR5 in this population. The class II genes from four American black families expressing many of the novel DRw13, DRw14, DRw11, and DRw12 haplotypes defined by serology and mixed leukocyte culture were further characterized by RFLP analysis. The data presented here along with other published data identify at least eight DRw13 haplotypes (DRw13A-DRw13H) in the human population. Five of these haplotypes exhibit an undefined HLA-D specificity. Three DRw14 haplotypes (DRw14A-DRw14C) and eight DR5 haplotypes (DRw11A-DRw11E and DRw12A-DRw12C) were also identified. The novel DRw6 and DR5 haplotypes observed in American blacks may arise from differences in DRB1, DQA1, and DQB1 genes as well as from differences in the combinations of alleles of these genes encoded by a haplotype. The serologic and RFLP analyses suggest that some DRw13 and DRw11 haplotypes represent transitional steps between DRw13 and DRw11 in the evolutionary pathway which generated the DRw52 family.

Alloreactive T-cell clones raised in an HLA-B/D crossing-over family dissect HLA-DR5 and HLA-DQw3 subtypes

This study was undertaken to resolve a positive mixed lymphocyte reaction between HLA-ABC identical, HLA-D different siblings. Three CD3+ CD4+ CD8- alloreactive T-lymphocyte clones, called 2/6, 7/1, and 7/2, were generated and extensively studied. Proliferation of 2/6 cells and 7/2 cells was blocked by anti-DQ monoclonal antibodies (mAbs), whereas anti-DR and DP were not effective. Stimulation of 7/1 cells was inhibited by anti-DR, but not by anti-DQ and DP mAbs. Testing on a well-characterized panel of reference B-lymphoblastoid cell lines showed that the DQ-specific clones 2/6 and 7/2 were able to proliferate upon stimulation by cells carrying the DQw7 and DQw8 but not the DQw9 subtype of DQw3. Clone 7/1 was proliferative towards cells expressing DRw11.1 but not towards DRw11.2- or DRw12-positive cells. Moreover, this clone detected determinants present on some DRw8 cells. Correlation of the reactivity of clone 7/1 with available sequence data suggests that amino acids 67, 71, and 86 of DR beta 1 molecules played a crucial role in forming the epitope recognized by this clone. In contrast, sharing of T-cell epitopes between DQw7 and DQw8 subtypes was not inferable from specific amino acid residues. The implication of these findings for T-cell allorecognition is discussed.

Direct sequencing of a HLA-DRB gene by polymerase chain reaction: sequence variation in DRw8 specificity

The nucleotide sequence of a HLA-DRB gene with a predominant subtype of DRw8 specificity in Japanese (DR8.1) was determined with single-stranded DNA enzymatically amplified by polymerase chain reaction (PCR). The sequence differs at a single amino acid from both of the published DRw8/Dw8.1 and DRw8/Dw8.2 sequences: isoleucine67(AUC) instead of phenylalanine67(TTC) in DRw8/Dw8.1 and serine57(AGC) instead of aspartic acid57(GAT) in DRw8/Dw8.2. On the other hand the DR8.1 and DRw8/Dw8.3 have the same amino acid sequence although one silent nucleotide substitution has occurred between the two sequences. These results indicate that Japanese DR8.1 specificity corresponds to DRw8/Dw8.3. Furthermore, an oligonucleotide probe specific for this sequence was synthesized and hybridized with 33 HLA-typed controls. This probe clearly distinguished the particular subtype from other DRw8 subtypes and specificities.

DNA typing for class II HLA antigens with allele-specific or group-specific amplification. II. Typing for alleles of the DRw52-associated group

Codons 9-12 of the first domain of DRB1, which encode the amino acid sequence EYST (in single-letter code), served as the basis for the construction of a polymerase chain reaction primer specific for DRB1 of the whole DRw52 group. Using this primer for the 5' end and a primer for a conserved region at the 3' end, we could amplify selectively the DRB1 genes of DRw17-, w18-, w11-, w13-, w14, and w8-positive haplotypes. DRB3 genes of DR3,DR5 and DRw6 were also specifically amplified, separately. This selectively amplified DNA could then be used in a blotting procedure for hybridization with oligonucleotide probes chosen to define the polymorphisms that characterize these alleles and their subsets. Patterns of hybridization for groups of related specificities have been described, and their frequencies were determined in representative panels available in our laboratory. The results presented illustrate the extraordinary power of this new DNA typing procedure. Using these relatively simple methods it is possible to define, with certainty, allelic forms of DRB1 and DRB3 associated with the DRw52 group. The ability to type extends far beyond the capabilities of present serology; the precision achieved with this method in panel typings is unprecedented.

Sequence analysis and oligonucleotide genotyping of HLA-DR"JX6", a DR"blank" haplotype found in the Japanese population

We analyzed one of the HLA-DR"blank" haplotypes found in the Japanese population using serologic studies, sequence determination, and genotyping with sequence-specific oligonucleotide (SSO) probes. The DR"blank" haplotype, designated DR"JX6", segregated in a family in association with the DRw52 and the DQw7 specificities. The cDNA and genomic DNA of the DRB1 gene originating from the DR"JX6" haplotype were amplified enzymatically and sequenced after cloning into a plasmid vector. The amino acid sequence of the first domain in the DR beta 1 chain of the DR"JX6" haplotype was different from those of other DR haplotypes sequenced so far, but in the first hypervariable region, the sequence was identical to those of the DRw11, DRw13, DRw14, and DRw17 haplotypes. SSO probes were synthesized on the basis of the DR"JX6" haplotype sequence as well as known sequences of the DRB1, DRB3, and DRB4 genes of other DR haplotypes. These SSO probes were used for the genotyping of Japanese donors whose DRB genes were amplified enzymatically and found to show a hybridization profile that was consistent with the results of serologic studies on the DR"JX6" haplotype.

Evolution of the class II major histocompatibility complex alleles in higher primates

We have shown that chimpanzees and gorillas have DRB alleles very similar to those of humans. The existence of similar DRB alleles in the different species of higher primates cannot be accounted for by convergent evolution of unrelated alleles that arose independently after the speciation. We therefore conclude that ancestral DRB alleles, that had existed before the speciation, were transmitted to the ancestors of humans, chimpanzees, and gorillas. This conclusion indicates that the diversification of MHC alleles does not start at the inception of a species, but rather proceeds beyond the lifespan of a species. A high degree of sequence similarity found between certain human and non-human primate DRB alleles shows that MHC alleles do not diversify rapidly. The bulk of the contemporary DRB polymorphism seems to have been generated by accumulation of random point mutations during long evolutionary periods preceding the divergence of humans, chimpanzees, and gorillas.

A new HLA-DRB1 allele within the DRw52 supertypic specificity (DRw13-DwHAG): sequencing and direct identification by oligonucleotide typing

Molecular analysis of HLA class II polymorphism represents a crucial parameter for HLA matching in transplantation immunology, for the study of HLA-disease association and for the understanding of major histocompatibility complex (MHC)-restricted antigen presentation. We report here the DNA sequence and the deduced amino acid sequence of the polymorphic first domain exon of the DRB1 and DRB3 alleles of the homozygous cell line HAG (DRw13-DwHAG-DQw7). The DRB1 sequence represents a new DRB allele, which clearly shows a close relationship to other DRB1 genes from the DRw52 group and is now officially named DRB1* 1303. The DRB1* 1303 allele is very similar to the two DRw13 alleles we have described earlier, with only five amino acid differences at positions 32, 37, 47, 57 and 71. Furthermore, its sequence in the third hypervariable region is unique among all known DRB1 and DRB3 alleles. The sequence of the DRB3 gene of HAG shows that it corresponds to the previously described DRB3* 0101 (DRw52a) allele. In addition we present analyses of a panel of healthy blood donors and leukemic patients by oligonucleotide typing showing that this new HLA-DR specificity can now be unequivocally identified in routine oligotyping with an allele-specific oligonucleotide probe.

Arg74 in HLA-DRB1 and DRB3 controls a DR3-related epitope

TR81 is a specificity closely related to or identical with DR3. In Caucasoids two amino acids, Tyr at position 26 and Arg at position 74 of HLA class II DR beta chains, have been found to be associated with the presence of TR81. Recently, a variant of DRB1*03 identified in American Blacks has been shown to possess Arg at position 74 but Phe at position 26. This codon combination is found to be present in four other cell lines where it still specifies the TR81 determinant. This suggests that the TR81 specificity is uniquely dependent on the presence of Arg at position 74.

A simple and rapid method for HLA-DRB and -DQB typing by digestion of PCR-amplified DNA with allele specific restriction endonucleases

The polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) method, which we previously reported as an efficient and convenient typing technique for accurate definition of the HLA-DQA1 and -DPB1 alleles, is now extended and applied to HLA-DRB and -DQB typing. The second exon of the HLA-DRB (B1 and B3 or B4) and DQB (B1 and B2) genes was selectively amplified from genomic DNAs of 70 HLA-homozygous B cell lines by PCR. Amplified DNAs were digested with the restriction endonucleases, which can recognize allelic variations specific for HLA-DR, -DQ, and -Dw allospecificities and then subjected to electrophoresis in polyacrylamide gel. Of DRB genes, FokI, HinfI, HhaI, HphI, KpnI and SacII were selected and the 20 different polymorphic patterns of the restriction fragments thus obtained were found to correlate with each HLA-DR and -Dw type defined by serological and cellular typing. Of the DQB genes, FokI, HaeIII, HhaI, RsaI and Sau3AI produced nine different polymorphic patterns of the restriction fragments, correlating with the HLA-DQ and -Dw types. This PCR-RFLP method provides a simple and rapid technique for accurate definition of the HLA-DR, -DQ and -Dw types at the nucleotide level, eliminating the need for radioisotope as well as allele specific oligonucleotide probes.

HLA-DR and -DQ epitopes and monoclonal antibody specificity

The polymorphism of the HLA system-originally studied serologically using antisera from multiparous women and cellularly using the mixed lymphocyte reaction-has now been further revealed by the use of monoclonal antibodies and, at the most basic level, by the nucleotide and amino acid sequences of the different alleles. In this article, Steven Marsh and Julia Bodmer examine the specificity of mainly well-known HLA-DR and HLA-DQ monoclonal antibodies and postulate the positions of their binding sites, or at least of the polymorphic sites determining their patterns of reactivity. The publication together of all available amino acid sequences of the first domain of the DR beta and DQ alpha and the DQ beta chains (updated and corrected where necessary in collaboration with their authors) provides a useful tool with which to identify binding sites of other antibodies and perhaps to attempt to correlate their position in the structure with their function. Outlines of strategies to produce a wider range of polymorphic antibodies are discussed.