Class II genes of the human major histocompatibility complex. Comparisons of the DQ and DX alpha and beta genes

HLA class II peptide-binding-region analysis reveals funneling of polymorphism in action

BACKGROUND

HLA-class II proteins hold important roles in key physiological processes. The purpose of this study was to compile all class II alleles reported in human population and investigate patterns in pocket variants and their combinations, focusing on the peptide-binding region (PBR).

METHODS

For this purpose, all protein sequences of DPA1, DQA1, DPB1, DQB1 and DRB1 were selected and filtered, in order to have full PBR sequences. Proportional representation was used for pocket variants while population data were also used.

RESULTS

All pocket variants and PBR sequences were retrieved and analyzed based on the preference of amino acids and their properties in all pocket positions. The observed number of pocket variants combinations was much lower than the possible inferred, suggesting that PBR formation is under strict funneling. Also, although class II proteins are very polymorphic, in the majority of the reported alleles in all populations, a significantly less polymorphic pocket core was found.

CONCLUSIONS

Pocket variability of five HLA class II proteins was studied revealing favorable properties of each protein. The actual PBR sequences of HLA class II proteins appear to be governed by restrictions that lead to the establishment of only a fraction of the possible combinations and the polymorphism recorded is the result of intense funneling based on function.

Characterization of the MHC class II α-chain gene in ducks

In humans, classical MHC class II molecules include DQ, DR, and DP, which are similar in structure but consist of distinct α- and β-chains. The genes encoding these molecules are all located in the MHC class II gene region. In non-mammalian vertebrates such as chickens, only a single class II α-chain gene corresponding to the human DRA has been identified. Here, we report a characterization of the duck MHC class II α-chain (Anpl-DRA) encoding gene, which contains four exons encoding a typical signal peptide, a peptide-binding α1 domain, an immunoglobulin-like α2 domain, and Tm/Cyt, respectively. This gene is present in the duck genome as a single copy and is highly expressed in the spleen. Sequencing of cDNA and genomic DNA of the Anpl-DRA of different duck individuals/strains revealed low levels of genetic polymorphism, especially in the same strain, although most duck individuals have two different alleles. Otherwise, we found that the duck gene is located next to class II β genes, which is the same as in humans but different from the situation in chickens.

Sequence-based typing of the complete coding sequence of DQA1 and phenotype frequencies in the Dutch Caucasian population

Typing of DQA1 by sequencing has been a challenge because of a 3-nucleotide deletion in exon 2 in half of the alleles. Furthermore, 19 of the 28 alleles cannot be identified on basis of exon 2 alone, but need additional exon information. With the sequencing strategy presented here the complete exons 1-4 are sequenced heterozygously, enabling identification of all DQA1 alleles by sequence-based typing (SBT). Exons 1-4 were amplified and sequenced separately, the combined sequences were used for automated allele assignment. The method was validated by typing 21 individuals with all possible different allele group combinations. In addition 26 quality control samples were correctly typed by this method. To determine the phenotype frequencies 155 unrelated Dutch Caucasian individuals were DQA1 typed. In total 15 known and two new DQA1 alleles were identified. DQA1*0103 and *0505 were the most frequent alleles with phenotype frequencies of 30% and 29%, respectively. The SBT method presented here is an improvement compared to already existing protocols in that the complete exon sequence is obtained for all coding exons, using identical polymerase chain reaction conditions. Furthermore, all exons are sequenced heterozygously, facilitating allele assignment and reducing the number of amplification reactions.

Allelic polymorphism in introns 1 and 2 of the HLA-DQA1 gene

Human leukocyte antigen (HLA) class II antigens are highly polymorphic membrane glycoproteins, encoded by the A and B genes of DR, DQ, and DP. The polymorphism is mainly located in exon 2, with the exception of DQA1. Of the 27 DQA1 alleles presently known, 18 cannot be identified on the basis of exon 2 alone, but need additional information from the other exons. DQA1 has been reported to be the most ancient class II gene. For evolutionary comparison and to assess the degree of polymorphism outside the exons, the sequences of introns 1 and 2 were determined from 30 different cell lines, encompassing 15 different DQA1 alleles. The sequences revealed major nucleotide differences between the different lineages, whereas within each lineage few differences were present. Phylogenetic analysis of intron and exon sequences confirmed this lineage specificity. Altogether, the present data indicate that the HLA-DQA1 lineages represent ancient entities. The observed variation of the introns in alleles with identical exon sequences implicates conservative selection of the exons within a given lineage. Intron sequences may provide the means to set up an accurate typing system.

Absence of in vivo DNA-protein interactions in the DQA2 and DQB2 promoter regions

The DQ subregion of the human major histocompatibility complex (HLA) contains two pairs of loci: the DQA1/B1 genes (hereafter called DQ1), coding for the DQ molecules, and the DQA2/B2 pseudogenes (hereafter called DQ2). These pseudogenes are highly homologous to the functional DQ1 genes and they have no apparent abnormal features in their sequences that could prevent their activity. Only recently a low expression of the DQA2 gene has been observed whereas the DQB2 transcript was never found. The comparison between the DQ1 and DQ2 regulatory sequences revealed several differences in their W, X, and Y cis-acting elements. To examine the DNA/protein interactions in the DQ promoter regions, we performed in vivo footprinting experiments. Whereas the functional DQ1 loci showed a series of DNA-protein contact points in the X and Y boxes, the promoters of the DQ2 pseudogenes displayed an unoccupied phenotype. These findings suggest that the very low level of DQA2 expression and the apparent lack of DQB2 activity are caused by the reduced binding affinity of specific transcription factors.

A method for HLA-DQA typing by the PCR-SSP technique

There is preliminary evidence that matching for HLA-DQ is important for kidney graft survival. We developed a method for HLA-DQA typing based on the PCR-SSP principle. The procedure consisted of three steps: DNA isolation, PCR amplification and visualization of the PCR product under UV light. For the identification of all currently known DQA1 alleles, we designed 18 different primers that allowed typing for the specificities DQA1*0101, *1012, *0103, *0104, *0201, *03, *0401, *0501 and DQA1*0601. For the typing of a single individual, 12 PCR mixes were needed, each containing a primer pair specific for a certain allele group, and a pair of control primers that amplified a non-polymorphic region. The time required for this procedure was approximately 3 h from the time of blood collection. Comparison of this method with DQA typing by the RFLP method in 151 individuals revealed only a single discrepancy. The method can be easily applied for prospective cadaver donor typing.

Sequence-based typing of HLA class II DQB1

Due to the expanding number of known HLA class II DQB1 alleles, high-resolution oligotyping is becoming ineffective, therefore a sequence-based typing (SBT) strategy was developed to provide rapid and definitive typing of HLA-DQB1. HLA-DQB1*02, *03, *04, *05, and *06 alleles were individually amplified by polymerase chain reaction (PCR) using exon 2 group-specific primers. Forward and reverse PCR primers were tailed with M13 universal and M13 reverse sequences, respectively. Subsequent bi-directional cycle-sequencing was carried out using Cy5.5-labeled M13 universal primer and Cy5.0-labeled M13 reverse primer. Automated sequencing was performed in 30 min using a Visible Genetics, Inc. (VGI) MicroGene Clipper Sequencer. Full concordance was observed between this SBT method and oligotyping among 151 individuals.

Novel associations among HLA-DQA1 and -DQB1 alleles, revealed by high-resolution sequence-based typing (SBT)

Althought it is a valuable tool for the identification of HLA alleles, sequence-based typing (SBT) presents difficulties when used to determine HLA-DQA1 and -DQB1 alleles. Specifically, some HLA-DQA1 alleles have a three-base deletion at codon 56 of exon 2 that interferes with the sequencing read. Moreover, the frequently used primers for HLA-DQB1 may co-amplify the HLA-DQB2 pseudogene. To overcome these problems, we amplified DQA1 exon 2 using five group-specific polymerase chain reactions (PCRs) which allowed separation of deleted from non-deleted DQA1 alleles. DQB1 exon 2 was amplified using two group-specific amplifications. To increase typing resolution, we also analyzed DQA1 exons 1, 3 and 4 and DQB1 exon 3 by PCR using sequence-specific primers (PCR-SSP) or SBT analysis. Using this method we found some important associations between DQA1 and DQB1 alleles: DQA1*05011 and DQB1*0201, DQA1*0505 and DQB1*03011, DQA1*01021 and DQB1*06, DQA1*01022 and DQB1*0502.

High-resolution sequence typing of HLA-DQA1 and -DQB1 exon 2 DNA with taxonomy-based sequence analysis (TBSA) allele assignment

High-resolution DNA sequencing of exon 2 of DQA1 and DQB1 genes that uses a taxonomy-based sequence analysis (TBSA) method to assign alleles was developed. The system uses fewer primers for polymerase chain reaction (PCR) amplification and sequencing than other methods and yields accurate DQA1 and DQB1 typing when either homozygous or heterozygous DNA samples are tested. The approach was initially corroborated by the correct typing of 10 blinded samples that had been previously typed by PCR using sequence-specific oligonucleotide probes (PCR-SSOP) or serology, and subsequently confirmed by sequencing of cloned PCR products. DNA from peripheral blood cell samples of 130 individuals enrolled in a case-control analysis of HLA determinants of abdominal aortic aneurysm were subsequently evaluated. Overall, 8 different DQA1 and 19 DQB1 alleles were identified. All 21 DQA1 heterozygous combinations and 45 of 49 DQB1 heterozygous combinations were successfully resolved with TBSA. The two pairs of heterozygous DQB1 combinations that were not unambiguously typed required sequence specific PCR amplification for correct allele identification. We conclude that the method provides precise analysis for HLA-DQ typing.

Cattle MHC: evolution in action?

Because major histocompatibility complex (MHC) genes play a major role in the development of acquired immune responses, it is essential to obtain comparative information on their organisation, expression and possible functional dichotomies in different species. In human, three classical, polymorphic class I genes (HLA-A, B- and -C) and four expressed A/B class II gene pairs (HLA-DM, -DP, -DQ and -DR) are each present on all haplotypes. With the exception of the HLA-DRB loci, it has been assumed that a similar rigid organisational situation exists in other mammalian species. However, extensive analysis of the bovine MHC (BoLA) at both the genomic and transcriptional levels has revealed a degree of genetic fluidity not described in other species. None of the four (or more) classical class I genes identified is consistently expressed, and haplotypes differ from one another in both the number and composition of expressed class I genes. Similarly, in the class II region, the number of DQ genes varies between haplotypes in both number and composition. These variations in both class I and II (which appear to reflect differences at the genomic level) are likely to play an important role in cattle immune responses. The observed phenotypic differences in cattle demonstrate very clearly the dynamic nature of the MHC region. This review addresses the functional impact of such variation in different breeds and populations, and its significance in terms of MHC evolution.

High-resolution HLA typing for the DQB1 gene by sequence-based typing

The ideal high-resolution typing strategy for polymorphic genes is sequence-based typing. SBT of genomic DNA has been developed for the HLA class II genes DRB1, DRB3/4/5 and DPB1. For the DQB1 gene the sequence-based typing method was shown to cause a number of problems. To resolve those problems, different primers to amplify and sequence exon 2 of DQB1 were designed and tested. With several primer combinations, preferential amplification was observed in individuals heterozygous for DQB1*02/*03 and DQB1*02/*04. The preference was for DQB1*02 in many instances but could also be demonstrated for DQB1*03 or *04 and resulted occasionally in allelic drop-out. The best primer combination was selected and successfully used to type individuals heterozygous for DQB1*02, *03 and *04. To distinguish DQB1*0201 and *0202, primers for amplification and sequencing of exon 3 were developed and correct subtyping was obtained. The ambiguous typing DQB1*0301/*0302 and DQB1*0303/*0304 was resolved by allele-specific amplification and sequencing. A total of 258 individuals were fully typed for their DQB1 subtypes. All samples had been previously typed by PCR-SSP and serology. Concordant typing results were obtained for all individuals tested. The DQB1 alleles detected included *0501, *0502, *0503, *0601, *0602, *0603, *0604, *0609, *0201, *0202, *0301, *0302, *0303, *0304, *0401 and *0402. Sequence-based typing of the DQB1 gene proved a reliable typing strategy for assignment of the different DQB1 alleles after intensive selection of primers and test conditions.

HLA-DR5 and DQB1*03 class II alleles are associated with cutaneous T-cell lymphoma

Cutaneous T-cell lymphoma (CTCL) may present with eczematous lesions, mycosis fungoides (MF), or as exfoliative erythroderma with circulating atypical cells, Sezary syndrome (SS). The "malignant" T cells are epidermotropic and clonal, but whether they respond to antigen stimulation is unknown. Because CD4+ lymphocytes recognize antigen presented by histocompatibility locus antigen (HLA) class II molecules, and HLA association have been found in autoimmune skin diseases, we determined by allele-specific oligonucleotide typing whether HLA-DR or DQ alleles were associated with CTCL and its two variants MF (n = 47) and SS (n = 23). Phenotypic frequencies were compared by chi-square and Fisher exact test, and p values were corrected independently for either 12 DR or 15 DQ alleles. HLA-DR5, previously associated with MF, was significantly increased in all 70 CTCL patients (31.5%) versus controls (11%) (uncorrected p value [Pnc] = 0.000038, odds ratio [OR] = 3.9, 1.9 < OR < 8.1), in MF patients (34%) (Pnc = 0.000047, OR = 3.62, 1.9 < OR < 10), and in SS patients (26%) (Pnc = 0.03, OR = 3, 0.9 < OR < 9.3). HLA-DQB1*03 alleles (0301, 0302, and 0303) were increased in 72% of all CTCL patients versus 49% of controls (corrected p value [Pc] = 0.014, OR = 2.7, 1.4 < OR < 5.1), in SS (82%) (Pc = 0.05, OR = 4.7, 1.4 < OR < 5), and in MF (67%) (Pnc = 0.024, OR = 2.15, 1 < OR < 4.5). DQB1*0502 was strongly increased in SS patients (Pc = 0.045, OR = 7.75, 1.25 < OR < 48). Although HLA-DQB1*0603 and HLA-DR6 (1301, 1302, and 1402) were decreased in all groups, the decreases were not statistically significant. These data suggest that certain HLA-DRB and DQB1 alleles, also associated with other T-cell-mediated skin diseases, may participate in the pathogenesis of or susceptibility to CTCL.

The human leukocyte antigen TAP2 gene defines the centromeric limit of melanoma susceptibility on chromosome 6p

A single human leukocyte antigen (HLA) class II allele, DQB1*0301, is strongly associated with melanoma, and the HLA-DR locus provides the telomeric boundary for melanoma susceptibility in the HLA class II region of chromosome 6. However, the centromeric boundary is unknown. This study was designed to determine whether the adjacent upstream transporter associated with antigen processing (TAP) locus, TAP2, constitutes the centromeric boundary of disease susceptibility in melanoma. Molecular oligotyping of TAP2 genes was performed for 36 Caucasian patients with melanoma and for 32 Caucasian control individuals by both amplification refractory mutation system (ARMS) polymerase chain reaction (PCR) and PCR-sequence-specific oligonucleotide (SSO) typing. TAP2 allele frequencies in the melanoma patients were compared to those in non-melanoma Caucasian control populations, and to HLA-DQ allele frequencies determined by molecular oligotyping. While HLA-DQB1*0301 was more common in this group of 36 melanoma patients compared to a group of 200 controls (56 percent vs. 27 percent, Bonferoni-corrected chi-square p < = 0.01), no significant differences were observed in TAP2 allele frequencies between melanoma patients and controls. The TAP2 locus represents the centromeric boundary of disease susceptibility for melanoma in the class II region of chromosome 6p. These results support an etiologic role for HLA-DQB1*0301 in melanoma susceptibility.

The distribution of the HLA-DQ alpha alleles and genotypes in the Turkish population as determined by the use of DNA amplification and allele-specific oligonucleotides

Allele and genotype frequencies for the HLA-DQ alpha locus were determined for use in forensic analyses in Turkey. The polymerase chain reaction and the reverse dot blot format were employed to detect six different HLA DQ alpha alleles, which were detected among 150 unrelated individuals with allele frequencies ranging from 7% to 26.7%. The distribution of the observed genotypes was in Hardy-Weinberg equilibrium. The discrimination power of this system in the Turkish population sample was 0.94, and the allelic diversity was 0.81. This study provides support for the validity of the HLA-DQ alpha procedure for typing forensic samples.

Genetic typing with HUMTH01, HUMVWA31A and HUMFES/FPS short tandem repeat loci, D1S80 variable number tandem repeat locus and HLA-DQ alpha of recent and from XII-XIII centuries spongy bone

The genetic analysis of ancient populations through DNA from bone remains, requires use of short sized loci that can be amplified by polymerase chain reaction (PCR) for which the short tandem repeat (STR) loci are most suitable. These techniques can also be applied to genetic identification in forensic casework. In this study three STR loci, HUMFES/FPS, HUMTH01, and HUMVWA31A, were selected to estimate their usefulness when applied to recent and ancient spongy bone DNA typing. In addition, loci D1S80 and HLA DQ alpha were also tested in the analysis of recent spongy bone DNA. The recent remains studied were constituted by ten spongy bone samples of postmortem material from one individual buried for 1 year. The ancient remains are composed by 8 spongy bone samples from the heads of left femurs from a XII-XIII Centuries Basque Country population. Adequate amplification and typing results could only be obtained with cetyltrimethyl ammonium bromide (CTAB)-extracted DNA, without any further purification after precipitation. Genotypes of the one year post-mortem material and those of his son and his wife were obtained at the D1S80, HLA-DQ alpha, and STR loci. In all these systems, no exclusion was observed, with a combined probability of paternity of 0.9997. This demonstrates the reliability of the obtained results. The genetic typing of HUMTH01 in spongy bone from the XII-XIII Centuries Basque Country individuals was also performed. This will allow the genetic analysis of ancient bone remains and therefore, to carry out evolutionary population studies.

HLA-DQA1 typing in Danes by two polymerase chain reaction (PCR) based methods

A total of 280 persons were HLA-DQA1 typed by two different polymerase chain reaction (PCR) based methods; (i) a reverse dot-blot (RDB) method, which can differentiate between six alleles, and (ii) a combined PCR-restriction fragment length polymorphism (PCR-RFLP) and allele-specific amplification (ASA) method, which together recognise eight alleles. In 146 unrelated Danish individuals, the HLA-DQA1 alleles were in Hardy-Weinberg equilibrium. For identity testing, the power of discrimination (PD) of HLA-DQA1 was 0.932 with the RDB method and 0.942 with the PCR-RFLP/ASA method. For paternity testing, the theoretical chance of exclusion in HLA-DQA1 of non-fathers was 0.634 with the RDB method and 0.660 with the PCR-RFLP/ASA method.

Characterization of three separated exons in the HLA class II DR region of the human major histocompatibility complex

The human major histocompatibility complex, HLA, is a highly polymorphic gene region which includes the DRA and DRB genes. The number of DRB genes differs between haplotypes. The DR4 haplotype seems to be one of the most complex with five DRB loci, DRB1, DRB4, DRB7, DRB8, and DRB9, in addition to the single DRA locus. We determined the nucleotide sequences of three separated DRB exons located between the DRB4 locus and the DRA locus in the DR4 haplotype, two DRB signal-peptide exons (S1 and S3) and one DRB first-domain exon (locus designation DRB9). Sequence comparisons suggest the following order of events for the origin of these exons: DRB9 seems to be the oldest exon and has previously been detected in multiple HLA haplotypes. DRB9 is more divergent than the three other known DRB pseudogenes, all of which have been found in apes. This suggests that DRB9 arose prior to the hominoid divergence. An L1 repeat has been inserted 3' to DRB9. Subsequently, a LTR of the ERV9 retrovirus-like family was inserted into the L1 repeat. Such LTRs have recently been observed in some of the other DRB genes. The pseudogenes DRB7 and DRB8 (containing only exons 3-6) arose after DRB9. Finally, the separated signal peptide exons S1 and S3 were formed. The molecular characterization of these separated DRB exons and insertion elements further clarifies the complex evolutionary history of the HLA-DR region. These selectively neutral exons may serve as useful markers for tracing the phylogeny of HLA haplotypes.

Limited polymorphism of the HLA-DQA2 promoter and identification of a variant octamer

Previous studies have suggested that the HLA-DQA2 gene may be associated with IDDM. The apparently limited allelism at this locus prompted us to investigate whether this association might be with the level of gene expression rather than with specific alleles. The proximal promoter region of HLA-DQA2 was sequenced in three homozygous DR4;DQ8 subjects with IDDM, six homozygous DR3;DQ2 subjects (three healthy controls and three with IDDM), and selected DR4 and DR6 cell lines. This 388-bp region encompassed the known control W/Z/H/S, X, and Y boxes and included a previously unremarked variant octamer sequence 40 bp upstream of the transcription start site. Only one polymorphic site was present among these 15 sequences, found in one DR3;DQ2 subject and a DR6;DQ6 cell line. This indicates that any disease association with HLA-DQA2, at least among DR3;DQ2 individuals, cannot be accounted for solely by polymorphism of the proximal promoter region.

Isolation, characterization and evolution of ovine major histocompatibility complex class II DRA and DQA genes

Four full-length ovine major histocompatibility complex (MHC) class II A cDNA clones coding for new alleles of DRA, DQA1 and DQA2 genes were isolated from two ovine lambda gt10 cDNA libraries. The derived amino acid sequences of these clones resemble class II A molecules from other species in both size and structure. Restriction fragment length polymorphism analysis, using an Ovar-DRA probe on DNA from Merino and Romney sheep revealed only limited polymorphism in contrast to the high levels of polymorphism revealed by Ovar-DQA probes. Comparison of the predicted amino acid sequences for the three ovine A genes with class II A genes from five other species revealed that the most variable region of the molecule is the signal peptide. Although virtually every amino acid site shows variation, within or between species, there are some blocks of highly conserved residues. Within gene comparisons of nucleotide differences reveal that the greatest number of changes is found between the alleles of Ovar-DQA1 and -DQA2 genes and the least between Ovar-DRA1 alleles. Phylogenetic analysis of class II A sequences from several species place DRA and DQA genes on two distinct branches, with Ovar-DRA1 and BOLA-DRA, and Ovar-DQA1 and BOLA-DQA being most similar on their respective branches.

Structure and evolution of the promoter regions of the DQA genes

HLA-DQ antigens are unique among the class II antigens in that their alpha chains are highly polymorphic. In the present study, we characterized the general structure of the promoter regions of the DQA genes derived from different DR haplotypes and defined their nucleotide sequence polymorphisms. The promoter of each DQA1 allele contains three sequence motifs which are not present in non-DQA related class II genes: one identical to a tumor necrosis factor (TNF alpha) response element, one similar to an NF kappa B binding element, and one similar to a W motif. All DQA alleles lack TATA and CCAAT boxes in the proximal promoter region but carry other sequence elements characteristic of MHC class II genes, including S, X, X2, and Y boxes, and a pyrimidine-rich tract upstream of the X box. Nucleotide sequence polymorphisms among the various DQA1 alleles were noted within the promoter region, with some of the differences mapping within, or close to, regulatory elements that are important for the expression of MHC class II genes. All DQA1 alleles carry an unrearranged, full length, Alu-Sx related repeat immediately upstream of the proximal promoter region. This repeat was not present in the DQA2 (DXA) genes analyzed, confirming that DQ locus duplication probably occurred before integration of the Alu repeat into the primordial DQA1 locus, some 31-43 million years (myr) ago. The DQA2 promoter region is highly conserved between DR4 and DR3 haplotypes, with the degree of conservation exceeding that expected from the neutral mutation rate.

MHC class II haplotypes and linkage disequilibrium in primates

The loci encoding the major histocompatibility class II cell surface antigens DR, DQ, and DP exhibit a remarkable degree of allelic polymorphism. Strong linkage disequilibrium is also found between these loci in the human population. To study the evolutionary conservation of this disequilibrium the DQA1, DQB1, and DRB1-6 loci were analyzed in chimpanzee and gorilla by sequencing or/and oligonucleotide hybridization of PCR-amplified DNA. This analysis revealed several new DRB sequences. The distribution of DRB loci differs between human and nonhuman primate haplotypes, and the strong disequilibrium found on human haplotypes between alleles at DQA1 and DQB1 as well as between the DQ loci and the DRB1 locus was not detected in the nonhuman hominoids. Extensive recombination within and between the DR and DQ region appears to have occurred during the 3-7 million years since the divergence of the three species, resulting in little similarity of haplotypes between species. The strong disequilibrium found in the human species between these loci may either reflect haplotype-specific barriers to recombination, recent founder effects in the evolution of humans, or selection for specific haplotypes.

Nucleotide sequencing of HLA-DQ gene second exons in Chinese homozygous cells

Six HLA class I and class II-homozygous Chinese cell lines with unique HLA-Dw types were studied. Since the majority of HLA class II nucleotide sequence polymorphism is localized within the second exons of the genes, we used the polymerase chain reaction (PCR) to amplify these regions in HLA-DQA and DQB genes and subsequently determined the nucleotide sequences. No unique DQA1 or DQB1 alleles were found. However, a new haplotype of DQA1*0601-DQB1*0301-DRB1*1202 was found in two cells; and DQA1*03011 was found in association with DR9 in another two cells. This indicates that new DR-DQ associations may explain the observed new HLA-Dw types. The DQB2 sequences were identical in all six cells and were identical to a sequence previously reported in a DR6 haplotype. The DQA2 sequences from two clones obtained from two cells differed from each other and from previously reported sequences. The results show that the DQA1 and DQB1 alleles in the Chinese individuals studied are as previously reported in Caucasian populations and as such may be typed by restriction fragment-length polymorphism (RFLP) or PCR-sequence-specific oligonucleotide typing (PCR-SSO) or PCR-RFLP using conventional probe or restriction enzyme sets.

Structural similarity of the HLA-DQ region in DQ3 and DQ4 haplotypes and structural diversity of the HLA-DQ region in HLA-DR7 haplotypes

Genomic DNA obtained from a B lymphoblastoid cell line was digested with appropriate restriction endonuclease and hybridized with several probes specific for genes encoding HLA-DQ. Southern hybridization with a DQA1 3'untranslated (UT) region probe showed DQ2-type hybridization pattern in DR7DQ3 haplotype. On the contrary, DQB1 3'UT probe showed DQ3-type pattern in the same haplotype. Gene cloning and DNA sequencing analysis revealed a repetitive sequence, (TG)19, between DQA1 and DQB1 gene in the DR7DQ3 haplotype. These results suggest that a recombination event has occurred near this potential Z-DNA structure in the haplotype, DR7DQ3. The 3'UT region probes of DQA1 and DQB1 genes failed to detect restriction fragment length polymorphism (RFLP) differences between DR4DQ3 and DR4DQ4 haplotypes in this experiment, suggesting that the gene structure between DQA1 and DQB1 is conserved in these haplotypes.

Evolutionary relationships among the primate Mhc-DQA1 and DQA2 alleles

The variation of the Mhc-DQA1 and DQA2 loci of ten different primate species (hominoids and Old World monkeys) was studied in order to obtain an insight in the processes that generate polymorphism of major histocompatibility complex (Mhc) class II genes and to establish the evolutionary relationships of their alleles. To that end nucleotide sequences of 36 Mhc class II DQA1 and seven DQA2 second exons were determined and phylogenetic trees that illustrate their evolutionary relationships were constructed. We demonstrate the existence of four primate Mhc-DQA1 allele lineages, two of which probably existed before the separation of the ancestors of the hominoids and Old World monkeys (approximately 22-28 million years ago). Mhc-DQA2 sequences were found only in the hominoid species and showed little diversity. We found no evidence for a major contribution of recombinational events to the generation of allelic diversity of the primate Mhc-DQA1 locus. Instead, our data suggest that the primate Mhc-DQA1 and DQA2 loci are relatively stable entities that mutated primarily as a result of point mutations.

Molecular linkage of the HLA-DR, HLA-DQ, and HLA-DO genes in yeast artificial chromosomes

Eight major histocompatibility complex (MHC) class II loci and the newly defined Y3/Ring 4 locus were isolated in overlapping yeast artificial chromosome (YAC) clones defining a 420-kb segment of human chromosome 6p21.3. YAC B1D12 spanning 320 kb contained seven of these loci from HLA-DRA to HLA-DQB2. A 330-kb YAC, A148A7, spanned from the HLA-DQA1 locus through the Y3/Ring 4 locus and extended at least 130 kb centromeric of YAC B1D12. Southern blotting demonstrated that YAC B1D12 derived from the HLA-DR3 haplotype and that YAC A148A7 derived from the HLA-DR7 haplotype of the heterozygous library donor. A third 150-kb YAC, A95C5, lay within this contig and contained only the HLA-DRA locus. A fourth 300-kb YAC, A76F11, was isolated by chromosome walking from the telomeric end of YAC B1D12. Probes isolated from the ends of the YAC genomic inserts have been used to confirm overlaps between the clones. These analyses demonstrated that the centromeric end of YAC A76F11 used the same genomic EcoRI cloning site as the telomeric end of YAC A95C5. YAC B1D12 used an EcoRI site only 2.1 kb telomeric of the aforementioned EcoRI site. These data suggest that certain EcoRI sites are used preferentially during construction of the library. These YACs complete the linkage of the DR and DQ subregions of the HLA complex in cloned DNA and provide the substrate for precise analysis of this portion of the class II region.

New class II-like genes in the murine MHC

Major histocompatibility complex (MHC) class I molecules present endogenous antigens to CD8+ (cytotoxic) T cells. MHC class II molecules present primarily exogenously derived antigens to CD4+ T cells. Three new genes (Ma, Mb1 and Mb2) located between the Pb and Ob genes of the murine MHC have properties indicating that they are members of the MHC class II gene family, but they are the most divergent class II members so far identified and are almost as closely related in sequence to class I genes as they are to the known class II genes.

The structure of human MHC class II genes

The class II molecules of the human major histocompatibility complex bind intracellularly processed peptides and present them to T-helper cells. They therefore have a critical role in the initiation of the immune response. A salient feature of the class II molecules is their polymorphism. It has been shown that some autoimmune diseases are associated with certain class II alleles. This article reviews the basic structural features of class II molecules, and the genes encoding them as well as mechanisms governing the development of their extraordinary polymorphism.

Antigen-specific T cells restricted by HLA-DQw8: importance of residue 57 of the DQ beta chain

CD4+ T-lymphocyte clones reactive with antigen from herpes simplex virus type 1 were established from a DQw8+ donor. One T-lymphocyte clone was able to recognize HSV antigen only when presented by antigen presenting cells expressing DQw8, and only HLA-DQ-specific mAbs could inhibit the response. Using antigen presenting cells from an extensive panel of donors whose HLA-DQ molecules and genes had been established, it could be demonstrated that alanine at residue 57 of the DQ beta chain played a critical role in presentation of herpes simplex virus--derived antigen(s) to T cells. The results are interesting, since the amino acids present at residue 57 of the DQ beta chains seems to play an important role in determining susceptibility to develop or protection against insulin-dependent diabetes mellitus.

Application of long synthetic oligonucleotides for gene analysis: effect of probe length and stringency conditions on hybridization specificity

Two different lengths of long unique synthetic oligonucleotide probes (37- and 48-mers) specific for human major histocompatibility complex (MHC) class II beta genes were synthesized. These oligonucleotides were utilized to examine factors influencing hybridization specificity. Both probe length and stringency of washing conditions were found to be crucial factors for sequence-specific hybridization.

HLA class II genes: typing by DNA analysis

A detailed understanding of the structure and function of the human major histocompatibility complex (MHC) has ensued from studies by molecular biologist during the last decade. Virtually all of the HLA genes have now been cloned, and the nucleotide sequences of their different allelic forms have been determined. Typing for these HLA alleles is a fundamental prerequisite for tissue matching in allogeneic organ transplantation. Until very recently, typing procedures have been dominated by serological and cellular methods. The availability of cloned DNA from HLA genes has now permitted the technique of restriction fragment length polymorphism (RFLP) analysis to be applied, with remarkable success and advantage, to phenotyping of both HLA Class I and Class II determinants. For the HLA Class II genes DR and DQ, a simple two-stage RFLP analysis permits the accurate identification of all specificities defined by serology, and of many which are defined by cellular typing. At the present time, however, RFLP typing of HLA Class I genes is not as practicable or as informative as that for HLA Class II genes. The present clinical applications of HLA-DR and DQ RFLP typing are predominantly in phenotyping of living donors, including selection of HLA-matched volunteer bone marrow donors, in allograft survival studies, and in studies of HLA Class II-associated diseases. However, the time taken to perform RFLP analysis precludes its use for the typing of cadaveric kidney donors. Nucleotide sequence data for the alleles of HLA Class II genes have now permitted the development of allele-specific oligonucleotide (ASO) typing, a second category of DNA analysis. This has been greatly facilitated by the ability to amplify specific HLA Class II DNA 'target' sequences using the polymerase chain reaction (PCR) technique. The accuracy of DNA typing techniques should ensure that this methodology will eventually replace conventional HLA phenotyping.

Aspartic acid at position 57 of the HLA-DQ beta chain is not protective against insulin-dependent diabetes mellitus in Japanese people

Insulin-dependent diabetes mellitus (IDDM) in Caucasians is closely associated with the HLA-DQ gene, especially the residue 57 of the DQ beta chain. Aspartic acid at this position provides protection against IDDM, and substitution of this residue by alanine, valine or serine increases susceptibility to IDDM. To determine whether this is a common feature of IDDM in different ethnic groups, we studied DQB1 DNA in Japanese patients with IDDM by polymerase chain reaction and non-radioactive restriction site analysis. In contrast to Caucasian patients with IDDM, most Japanese patients with IDDM possessed at least one aspartic acid at position 57 of DQ beta. This finding strongly suggests that aspartic acid at position 57 of DQ beta does not protect the Japanese from IDDM.

DQ polymorphism: an analysis of DQw4 alpha and beta membrane proximal regions

The complete coding sequences of cDNA clones encoding the DQw4 alpha and beta polypeptides have been determined from two individuals expressing the DRw18(3), DQw4 haplotype. Although the first domain nucleotide sequence of the DQ alpha cDNA is very similar to the DQw2 alpha sequence, the sequence of the membrane proximal region (encoding second domain, transmembrane, and cytoplasmic segments) is more similar to DQw3-like alpha-gene sequences. The nucleotide sequence of the membrane proximal region of the DQw4 beta gene is identical to the DQw8 sequence in contrast to the extensive differences in the region encoding the first domains of these polypeptides. These sequences have been used to determine the evolutionary relationships among DQ alpha and beta genes.