Additional complexity within the HLA-D region: sequence analysis of two new DRw13-DQw7 haplotypes.

HLA-DRB1 is by far the most polymorphic locus within the HLA-D region with now well over 40 alleles. Nearly one fourth of these alleles are subtypes of DRw6, and these are in most cases undetectable by routine typing procedures. In this paper we present the molecular characterization of two new Caucasian DRw13-DQw7 haplotypes by DNA sequencing of the polymorphic first domain exons of DRB1 and DRB3 loci. The first haplotype, DRB1*1301-DRB3*0101-DQB1*0301, has arisen by a recombination between locus DRB1 from a DRw13-DQw6 haplotype and DQA1 from a DR4-DQw7 haplotype, as determined by DNA sequencing, DQ oligotyping, and restriction fragment length polymorphism typing. The second haplotype, DRB1*1305-DQB1*0301, is characterized by the novel DRB1*1305 allele differing from DRB1*1301 by three amino acids. It probably arose by a gene conversion event between a DRw13-DQw6 allele and DRB1*1101. This allele represents a DRw11/DRw13 hybrid DR molecule with a DRw13 serological epitope in the second hypervariable region and a Dw5 cellular epitope in the third hypervariable region. As determined by sequencing of locus DRB3, this allele is associated with DRw52b. Our molecular analysis of the complex HLA-DRw13 group now allows unambiguous DNA typing of all five DRw13 alleles with seven oligonucleotides, a significant improvement in the context of organ transplantation.     

Association between autoantibody markers and subtypes of DR4 and DR4-DQ in Swedish children with insulin-dependent diabetes reveals closer association of tyrosine pyrophosphatase autoimmunity with DR4 than DQ8

Abstract: HLA DQA1*0301-DQB1*0302 (DQ8) and DQA1*0501-DQB1*0201 (DQ2) are positively and DQA1*0102-DQB1*0602 (DQ6) negatively associated with IDDM. In DQA1*0301-DQB1*0302 (DQ8)-positive patients, susceptibility is also mediated by DRB1*0401. The aim of the study was to determine the association between HLA-DR4 and DQ and the presence of GAD65, ICA512, and insulin autoantibodies as well as ICA in 425 Swedish children with IDDM and 367 controls in the age group of 0–15 years. We found that ICA512 autoantibodies were associated primarily with DRB1*0401 and not with DQA1*0301-DQB1*0302 (DQ8). No such hierarchy could be demonstrated for insulin autoantibodies, which were associated with both DQA1*0301-DQB1*0302 (DQ8) and DRB1*0401. GAD65 autoantibodies, known to be closely associated with DQA1*0501-DQB1*0201 (DQ2)-DRB1*0301 haplotype, also showed no preferential association with DQA1*0301-DQB1*0302 (DQ8) versus DRB1*04. These results suggest that the immune response to different β-cell autoantigens may be mediated via HLA class II molecules from different loci. Design of the antigen-specific immuno-intervention trials should take into account these HLA-DR and DQ subtype associations.     

HLA-DP antigen and Takayasu arteritis

Sixty-four patients with Takayasu arteritis and 317 healthy individuals in the Japanese population were examined for HLA-A, -B and -C alleles by serological typing and for HLA-DR, DQ and DP alleles by DNA typing using PCR/SSOP analysis. The frequencies of HLA-Bw52, DRB1*1502, DRB5*0102, DQA1*0103, DQB1*0601 and DPB1*0901 alleles were significantly increased and the frequencies of HLA-Bw54, DRB1*0405, DRB4*0101, DQA1*0301, DQB1*0401 alleles were significantly decreased. Strong linkage disequilibria among the increased alleles and among the decreased alleles were evident in the Japanese population. Therefore, the combination or haplotype of HLA-Bw52-DRB1*1502-DRB5*0102-DQA1*0103-DQB1*0601 -DPA1*02-DPB1*0901 may confer susceptibility to Takayasu arteritis while another combination or haplotype of HLA-Bw54-DRB1*0405-DRB4*0101-DQA1*0301-DQB1++ +*0401 may confer resistance to the disease. Because this is the first evidence for the association between an HLA-DP allele and Takayasu arteritis, we examined the nucleotide sequences of the DPB1*0901 allele from a patient and her healthy relatives and found no difference. The disease is therefore not caused by a mutated DPB1 gene.     

The distribution of HLA class II susceptible/protective haplotypes could partially explain the low incidence of type 1 diabetes in continental Italy (Lazio region)

HLA class II is the primary susceptibility gene to type 1 diabetes and the analysis of HLA class II association could help to clarify the relative weight of genetic contribution to the incidence of the disease. Here we present an extensive typing for HLA class II alleles and their haplotypes in a homogenous population of type 1 diabetic patients (n=134) and controls (n=128) and in simplex (n=100) and multiplex families (n=50) from continental Italy (Lazio region). Among the various haplotypes tested, the DRB1*0301-DQA1*0501-DQB1*0201 was the most frequent found in type 1 diabetic patients and was transmitted in 82% of affected siblings, whereas DRB1*0402-DQA1*0301-DQB1*0302 appeared to have the highest odds ratio (10.4), this haplotype was transmitted in 96.3% of affected siblings, followed by DRB1*0405-DQA1*0301-DQB1*0302, DRB1*0405-DQA1*0301-DQB1*0201, DRB1*0401-DQA1*0301-DQB1*0302 and DRB1*0404-DQA1*0301-DQB1*0302. The following haplotypes showed a significant decreased transmission to diabetic siblings: DRB1*0701-DQA1*0201-DQB1*0303, DR2-DQA1*01-DQB1*0602, DR5-DQA1*0501-DQB1*0301. We suggest that the HLA DR/DQ haplotype/genotype frequencies observed could in part explain the low incidence of type 1 diabetes registered in Lazio region (8.1/100.000/year), for a number of reasons: i) the low frequency, in the general control population, of the most susceptible haplotypes and genotype for type 1 diabetes DRB1*0301-DQA1*0501-DQB1*0201 (14%), and DR4-DQA1*0301-DQB1*0302 (9%) and DRB1*0301-DQA1*0501-DQB1*0201/DR4-DQA1*0301-DQB1*0302 (0.8%) compared to other countries characterised by high incidence rate of the disease, Sardinia and Finland, respectively; ii) a significant lower ratio, in the control population, between the susceptible DRB1*0301-DQA1*0501-DQB1*0201 and the neutral DRB1*0701-DQA1*0501-DQB1*0201 haplotypes compared to the Sardinian population; iii) the high frequency of protection haplotypes/genotypes as the DR5-DQA1*0501-DQB1*0301, and DR5-DQA1*0501-DQB1*0301/DR5-DQA1*0501-DQB1*0301 very common in the control population of Lazio region and the DRB1*1401-DQA1*0101-DQB1*0503 haplotype.     

HLA associations in type 1 diabetes among patients not carrying high-risk DR3-DQ2 or DR4-DQ8 haplotypes

Type 1 diabetes is a complex disease where numerous genes are involved in the pathogenesis. Genes that account for approximately 50% of the familial clustering of the disease are located within or in the vicinity of the HLA complex on chromosome 6. Some DRB1, DQA1 and DQB1 genes are known to be involved, in addition to as yet unidentified HLA-linked genes. The DR4-DQ8 and DR3-DQ2 haplotypes are known to confer high risk for developing the disease, particularly when occurring together. Approximately 10% of patients, however, do not carry any of these high-risk HLA class II haplotypes. We have performed genotyping of DRB1, DQA1 and DQB1 alleles in non-DR3-DQ2/non-DR4-DQ8 patients and controls from Sweden and Norway to test if any HLA associations were observed in these patients. Our results clearly demonstrate several statistically significant differences in the frequency of HLA haplotypes between patients and controls. Case-control analysis including the relative predispositional effect test, and transmission disequilibrium test (TDT) analysis in Norwegian type 1 diabetes families revealed that the DQA1*03-DQB1*0301, DQA1*0401-DQB1*0402, DQA1*0101-DQB1*0501, DQA1*03-DQB1*0303 and DQA1*0102-DQB1*0604 haplotypes may also confer risk. Our analyses also supported independent risks of certain DRB1 alleles. The study clearly demonstrates that HLA associations in type 1 diabetes extends far beyond the well-known associations with the DR4-DQ8 and DR3-DQ2 haplotypes. Our data suggest that there is a hierarchy of HLA class II haplotypes conferring risk to develop type 1 diabetes.     

HLA-Bw54-DR4-DRw53-DQw4 haplotype controls nonresponsiveness to hepatitis-B surface antigen -via CD8-positive suppressor T cells

We have previously reported that in nonresponders to hepatitis-B (HB) vaccine there was an HLA-linked immune suppression gene for hepatitis-B surface antigen (Is-HBsAg) controlling the nonresponsiveness to HBsAg, through HBsAg-specific suppressor T cells, and that the Is-HBsAg was in strong linkage disequilibrium with the HLA-Bw54-DR4-DRw53 haplotype (1). We have now done the HLA typing on an additional 6 nonresponders, and using the system of T-cell proliferative response to HBsAg we found that the Is-HBsAg controlled the nonresponsiveness to HBsAg through HBsAg-specific suppressor T cells in nonresponders to HB vaccine who have HLA-Bw54-DR4-DRw53-DQw4 haplotype. T- and B-cell recognition of HB vaccines might play an important role at 3 to 5 weeks after the last immunization. Use of an anti-HLA monoclonal antibody has shown that the HLA-DR molecule plays an important role in helper T-cell proliferation in nonresponders, although the role of HLA-DQ molecule in nonresponders was unclear.     

T cells recognizing an HLA-DQ alpha beta heterodimer encoded in cis by the DR4DQw4 haplotype and in trans by DR4DQw8/DRw8DQw4 heterozygous cells

We generated alloreactive DQ-specific CD4+ T-lymphocyte clones. One of these (TLC HH58) was only restimulated with cells having the DR4DQw4 haplotype or cells being DR4DQw8/DRw8DQw4 heterozygous. The former cells carry the DQA1*0301 and DQB1*0401 alleles in cis position while the latter cells carry DQA1*0301 and DQB1*0402 alleles (DQB1*0402 is identical to DQB1*0401 except for codon 23) in trans position. Thus, very similar DQ alpha beta heterodimers are encoded by these genes in both cis and trans positions, which are recognized by the same T cells.     

HLA polymorphism in a Mataco South American Indian tribe: Serology of class I and II antigens: Molecular analysis of class II polymorphic variants

In the present study, HLA-A, B, C, DR, DQ, and DP loci were analyzed in a group of Mataco Amerindians of Argentina. Using reagents from the 11th International Histocompatibility Workshop (11th IHW), class I specifities such as Bw70, Bw75, and Bw48 were found in this population, other than the HLA determinants commonly described in South American Indians. The class II antigens found were DR4, DRw14, and DRw8 at the DR locus, and DQw4 and DQw7 at the DQ locus. The analysis of DRB1-DR4 related alleles, performed by PCR amplification and oligonucleotide probe hybridization, showed the presence of DRB1*0403, *0404, *0405, and *0411 in individuals from this ethnic group. By the analysis of DRB1-DRw14 related alleles, two variants were found: DRB1*1402 and DRB1*1406, the latter provisionally called DRB1 14.6 in 11th IHW. The DRw8-related allele present was DRB1*0802. The analysis of DRB3 gene revealed only the presence of DRB3*0101 allele in DRw14 individuals. DPB1 locus was also analyzed in unrelated individuals of the same population. Only five DPB1 alleles were found: DPB1*0201, *0301, *0402, *0501, and *1301 over the 19 previously described in the literature. These findings emphasize the restricted HLA class I and II variation observed in this ethnic group as it has been previously shown in other American groups. Some particular haplotypes in this Mataco tribe are described in this work.     

DNA polymorphism of HLA class II genes in pauciarticular juvenile rheumatoid arthritis.

We investigated the DNA restriction fragment length polymorphism (RFLP) of the major histocompatibility complex (MHC) class II genes: HLA-DRB, -DQA, -DQB, DPA, and -DPB in 54 patients with pauciarticular juvenile rheumatoid arthritis (PJRA) and in healthy Danes. The frequencies of DNA fragments associated with the following HLA class II genes were increased in PJRA when compared to normal controls: DRB1*08 (DRw8) (35.2% vs 10.3%, RR = 4.6, p less than 10(-3), DRB3*01/02/03 (DRw52) (76.3% vs 48.1%, RR 3.5, p less than 10(-3)), DQA1*0401 (41.0% vs 7.4%, RR = 7.9, p less than 10(-3)), DQA1*0501 (55.6% vs 29.7%, RR = 3.0, p less than 10(-2), DQB1*0301 (DQw7) (46.2% vs 17.5%, RR = 4.0; p less than 10(-2)), DPA1*0201 (44.2% vs 7.9%, RR = 8.7, p less than 10(-5)), and DPB1*02 (DPw2) (40.7% vs 7.1%, RR = 8.5, p less than 10(-6)). The frequency of DRB1*11 was not significantly increased. The frequencies of DNA fragments associated with the following HLA class II genes were decreased in PJRA although not statistically significantly so after 'correction' of p values: DRB1*04 (14.8% vs 40.2%, RR = 0.27; p less than 10(-3)), DRB1*07 (0% vs 25.9%, RR = 0.04, p less than 10(-3)), DRB4*0101 (DRw53) (25.9% vs 53.6%, RR = 0.31, p less than 10(-3)), DQA1*0102 (11.6% vs 36.0%, RR = 0.25, p less than 10(-4)), and DQA1*0201 (2.6% vs 34.2%, RR = 0.05, p less than 10(-2)).(ABSTRACT TRUNCATED AT 250 WORDS)     

Motif analysis of HLA class II molecules that determine the HPV associated risk of cervical carcinogenesis

In previous studies, the HLA class II haplotype HLA DRB1*0401-DQB1*0301 was shown to correlate with susceptibility to HPV infection, CIN and cervical cancer while DRB1*0101-DQB1*0501 indicated protection. The present study was designed to identify naturally processed peptide sequences bound to the susceptibility and protective HLA DR-DQ molecules, and use this for T-helper epitope prediction from HPV 16. The HLA class II molecules were obtained by immuno-affinity purification of Epstein-Barr virus B lymphoblastoid cell lines (BCL) homozygous for HLA DQA1*0301-DQB1*0301 and HLA DQA1*0101-DQB1*0501. Peptide pools eluted from the HLA molecules were sequenced by Edman degradation. On the basis of the peptide sequence data obtained, the E6, E7, L1 and L2 proteins of HPV 16 were examined to identify sequences which are likely to bind to HLA DQB1*0301 and DQB1*0501. In addition, motif prediction as well as the binding affinity of predicted peptide motifs for HLA DRB1*0401 and DRB1*0101, the DR alleles associated with susceptibility and protection respectively, was accomplished using published data and a prediction algorithm for the naturally processed peptide sequences bound to these molecules. The HLA DQB1*0501 peptide ligand sequence showed that proline gives an outstanding signal at position 2, Asn/Arg at P1, aliphatic/aromatic amino acids in the central portion, a hydrophobic cluster at P5 with a small contribution by small polar residues and another cluster of aromatic residues towards the C-terminus. The HLA DQB1*0301 sequence also showed that proline gives an outstanding signal at position 2, Thr/Arg at P1, aliphatic/aromatic amino acids in the central portion and an aliphatic cluster with a small contribution by small polar residues at P5. There were no differences in the number of HPV peptides that were predicted as being capable of binding to HLA DQB1*0301 and HLA DQB1*0501, but more HPV peptide motifs were predicted to bind with high affinity to HLA DRB1*0101 than DRB1*0401. The results suggest that HPV 16 peptide epitopes bind with higher affinity to the protective than to susceptible HLA DR-DQ molecules which may lead to a more effective immune response.     

HLA-DQA1 and MLC among HLA (generic)-identical unrelated individuals

We modified a previously published PCR-RFLP for DQA1 typing (1) and examined the predictive value of HLA-DQA1 in mixed lymphocyte cultures (MLC) among matched (HLA generic types) pairs of unrelated individuals. There were 61/102 (60%) pairs with positive MLC, one-third of which could be predicted by DQA1* typing alone. DQA1 matching and MLC reactions were classified into 3 groups: 1) DQA1 mismatches showing positive MLC: 19/102 (19%); 2) DQA1 matches showing negative MLC: 41/102 (40%); 3) DQA1 identical showing positive MLC: 42/102 (41%). Five different HLA haplotypes that result from non-random association of HLA generic types (high delta haplotypes) were overrepresented in the individuals tested. One of these haplotypes carrying HLA-B7, DR2 was found associated with three different DQA1 alleles (*0201, *0103, *0102). The remaining four high delta haplotypes were associated with one DQA1 allele in all independent examples tested: HLA-A1, B8, DR3 with DQA1*0501; HLA-A26, B38, DR4 with DQA1*0301; HLA-A2, Bw62, DR4 with DQA1*0301 and HLA-A1, Bw57, DR7 with DQA1*0201. Forty per cent of the negative MLC were explained in part by the excessive number of individuals carrying two of these four haplotypes, which probably carry determinants in linkage disequilibrium with HLA. Nineteen per cent of HLA-identical (generic types) unrelated pairs show positive MLC reactions and all of them are DQA1* mismatched, suggesting that DQA1* allele typing should be used to screen samples prior to performing MLC.     

A high frequency of the A30, B18, DR3, DRw52, DQw2 extended haplotype in Sardinian celiac disease patients: Further evidence that disease susceptibility is conferred by DQ A1*0501, B1*0201

This study characterizes by serological and molecular methods the HLA class I and class II alleles in a group of celiac disease children, their parents and a control group of Sardinian descent. We found the DR3-DQw2 haplotype in all patients which was, in almost all cases (84%), associated with the HLA-A30, B18, DR3, DRw52, DQw2 extended haplotype named "Sardinian haplotype" because of its frequency (12-15%) in this Caucasian population. This is the first time that this DQw2-linked haplotype has been reported with such a high frequency in CD. However, no different distribution of "Sardinian haplotype" was found comparing CD patients with 91 haplotyped DQw2-positive controls. This finding indicates that the DQw2 antigen in Sardinians is almost always associated with the A30, B18, DR3, DRw52, DQw2 extended haplotype. The DQA1 and DQB1 second exon sequence analysis of the B18,DR3 and B8,DR3 haplotypes showed the DQA1*0501 and DQB1*0201 alleles which shared the already published sequences. DPB1 subtyping showed the DPB1*0301 allele more frequently (p less than 0.005) in CD patients but this difference was no longer significant when patients and controls, both heterozygous for the DR3-DQw2 haplotype, were compared. We suggest that the divergent HLA extended haplotypes and DP allele associated with CD, described in different Caucasian populations, can be explained by the particular DQw2 linkage disequilibrium in each population.     

DQA103 subtypes have different associations with DRB1 and DQB1 alleles

Polymorphisms outside the hypervariable regions of HLA class II alleles that do not affect the peptide-binding site are probably not under selective pressure and could therefore be useful as markers of the evolutionary pathways of the HLA class II haplotypes. We have analyzed such a polymorphism in the variants of DQA1^*03, which differ at residue 160 encoded in exon 3. Our study included homozygous BCLs of the 10th IHWS and samples of a multiracial panel of 723 unrelated subjects which were also typed for allelic variations in exon 2 by hybridization with SSOP. BCLs having DQA1^*03 and 131 selected DQA1^*03-positive samples were typed for the dimorphism in exon 3 that distinguishes DQA1^*0301 and DQA1^*0302. DQA1^*0301 was found to be exclusively associated with DQB1^*0302, while samples carrying DQB1^*0201, 0301, 0303, and 0401 always had DQA1^*0302. A few haplotypes carrying DQB1^*0302 had DQA1^*0302. The fact that DQA1^*0301 is completely included in DQB1^*0302, and not vice versa, suggests that DQA1^*0301 may have arisen from a mutation in a haplotype containing DQA1^*0302-DQB1^*0302. DQB1^*0302 was found to be associated with all DR4 subtypes, suggesting possibly that the current variants of DRB1-DR4 may be of more recent origin. DRB1^*0405 was the only subtype of DR4 which was not associated with DQA1^*0301 and had multiple associations with the DQB1 alleles, therefore, perhaps representing the oldest allele of this group.     

Molecular analysis of HLA allelic frequencies and haplotypes in Jordanians and comparison with other related populations.

Twenty alleles for the locus human leukocyte antigen (HLA-A) and 46 for the HLA-B locus were detected in Jordanians. This indicates the existence of high polymorphism in this area. The most frequent HLA class I alleles found were A*0201 (0.1344), B*0713 (0.1724), and C*0502 (0.1793). Twenty-six different alleles in the Jordanian population were identified for the DRB1 locus being the DRB1*0704 (0.2552), DRB1*0401 (0.1965), and DRB1*1501 (0.0896) the most frequent. Common DQA1 alleles were DQA1*0201 (0.2690), DQA1*0301 (0.2414), and DQA1*0501 (0.1724). Three-loci haplotype heterogeneity was common: 38 HLA class II haplotypes were identified, of which the most frequently observed was DRB1*0401-DQA1*0301-DQB1*0302 (0.1793). In addition, as expected, 220 different five-loci haplotypes with several unusual allelic combinations were observed, although many of them are pan-European haplotypes. The most frequent five-loci haplotype was the A30-B7-DRB1*03-DQA1*0501-DQB1*0201 (0.0138). It seems that the specific Jordanian haplotypes are the following: the A31-B7-DRB1*04/07-DQA1*0301/0201-DQB1*0302/0202 haplotypes (0.0103) and the A1-B7-DRB1*07-DQA1*0201-DQB1*0202, A2-B7-DRB1*04-DQA1*0301-DQB1*0302, A11-B7-DRB1*07-DQA1*0201-DQB1*0201 haplotypes but at lower frequencies (0.007). A tree analysis of HLA class I and class II alleles were made for several Caucasian populations and individual genetic distances calculated. The haplotype frequencies, genetic distances, and dendrograms do not reveal great differences as compared with those in other Mediterranean countries and Western Europeans populations. Our results suggest that both HLA class I and class II polymorphism (but especially the former) of the Jordanian population demonstrates considerable heterogeneity, which reflects ancient and recent admixture with neighboring populations, and important human migratory trends throughout the history.     

Polymorphism of DQA1 promoter in Italian population

We have investigated polymorphism in the 5′-URR of the DQA1 gene by PCR-SSO method in a group of 55 Italian healthy individuals olygotyped for DRB1, DQA1, DQB1 genes and in 20 10th IHWS cell lines as controls. We used primers and oligos (X and Y box) supplied by 12th IHWS and a DIG-11-ddUTP/AMPPD method. We have detected eight QAP variants (1.1,1.2,1.3,1.4,2.1,3.1,4.1,4.2) in our samples. As far as the association of DR/DQ haplotype and QAP sequences, we observed cases of one to one relationship (DQA1^*0201 and QAP2.1, DQA1^*0301 and QAP3.1, DQA1^*0401 and QAP4.2, DQA1^*0501 and QAP4.1); cases in which the same QAP allele was present in different DQA1-DRB1 haplotypes (QAP1.2 with DQA1^*0102 in DRB1^*15-DQB1^*0602 and DRB1^*16-DQB1^*0502 haplotypes or with DQA1^*0103 in the DRB1^*15-DQB1^*0601 haplotypes; QAP1.3 linked to DQA1^*0102, DQA1^*0103 or DQA1^*0104 in different haplotypes; QAP4.1 linked to DQA1^*0501 in DRB1^*11-DQB1^*0301, DRB1^*0301-DQB1^*0201, DRB1^*1303-DQB1^*0301 haplotypes or to DQA1^*0601 in DRB1^*0803-DQB1^*0301); cases where the same DQA1 allele is associated with different QAP sequences according to the DRB1 specificity (DQA1^*0102 allele with QAP1.2 or QAP1.4 in DRB1^*1302). Besides, we have observed that the QAP1.3, previously reported associated with DQA1^*0101-DRB1^*1401 haplotype, is really linked to DQA1^*0104-DRB1^*1401 haplotype. An intriguing data is that sometimes the same QAP is linked to different DQA1 alleles but to the same generic DRB1 allele: DRB1^*02 haplotype includes always the QAP1.2 variant but can bring different DQA1 alleles (^*0102 or ^*0103) and DRB1^*08 haplotype has always the QAP4.2 variant with different DQA1 alleles (^*0401 or ^*0601). The variability of linkage QAP-DQA1 can give further informations about HLA susceptibility in autoimmune diseases and in regulation of immune response in transplantation and oncology.     

Serology, restriction fragment length polymorphism, and sequence analysis of a unique HLA class II antigen, DR5x6.

We analyzed a new class II HLA haplotype, which we have designated DR5x6, by serology, restriction fragment length polymorphism (RFLP), and sequence analysis. As the name DR5x6 implies, the antigen is serologically closely related to both DR5 and DRw6. RFLP analysis of this haplotype suggests a close similarity with DRw11 haplotypes. The DNA sequences encoded by the second exon of its DRB1, DRB3, and DQB1 genes were also determined. Comparison of these sequences with those of alleles at these loci in other haplotypes suggests that this haplotype could have evolved from a DRw11 ancestor haplotype (DRw11-DRw52b (Dw25)-DQw7) by means of: (a) a gene conversion at the DRB1 locus involving DRw8 (Dw8.3) as the sequence donor, plus a point mutation or a gene conversion involving DR4-Dw4; and (b) a recombination event by which this haplotype would have acquired the DRw5a (Dw24) allele at the DRB3 locus.     

HLA CLASS II AND SUSCEPTIBILITY AND RESISTANCE TO INSULIN-DEPENDENT DIABETES MELLITUS IN A POPULATION FROM THE NORTHWEST OF SPAIN

The role of HLA class II alleles in genetic predisposition to insulin-dependent diabetes mellitus(IDDM) was examined using Polymerase Chain Reaction/oligonucleotide probe typing (PCR/SSOs) of eight HLA class II loci in 58 IDDM patients and 50 healthy controls from the Northwest of Spain (Asturias). We compared the distribution of HLA class II alleles, haplotypes and genotypes between IDDM patients and controls, and tested three recently proposed HLA-IDDM susceptibility theories. By using the aetiologic fraction (δ) as an almost absolute measure of the strongest linkage of disequilibrium of a HLA marker to the putative Type I susceptibility locus, it has been found that the strength of association of the HLA markers may be quantified as follows: DQA1 *03-DQB1 *0302 or DQA1 *0501-DQB1 *0201 > DR3 or DR4; presence of more than one dimer DQαβ of the six proposed by Rønningen > non-Asp57 DQβ and Arg52 DQα > Arg52 DQα > non-Asp57 DQβ/non-Asp57 DQβ > DRB1*0301; DQA1*0501-DQB1*0201 > DQA1*03-DQB1*0302; DQB1*0302. The presence of at least one Asp57 DQβ allele was the best protection HLA marker to IDDM in our population. Therefore, the above data confirm that IDDM susceptibility to HLA locus is linked more to DQ than DR.     

Human leukocyte antigen class II allele frequencies and haplotype association in Iranian normal population.

The polymorphism of the HLA class II genes DRB1, DQA1, and DQB1 was investigated in 100 unrelated Iranian individuals from Fars province in Southern Iran, using the restriction fragment length polymorphism (RFLP) method. Subtyping of DRB1*04, *15, and *16 alleles was performed using PCR amplification with sequence specific primes (PCR-SSP). The allele and the haplotype frequencies were calculated. The most common DRB1 alleles were DRB1*11, DRB1*15, and DRB1*04 with a frequency of 25.0%, 14.5%, and 10.5%, respectively. In contrast, the allelic frequency of DRB1*12 and DRB1*08 was very low (1.5% for each). In the DR15 group DRB1*1501 was the most prevalent variant (6.0%). Concerning DR4, the most common alleles were DRB1*0405 and DRB1*0402 (3.5% for each). Interestingly, DRB1*0402 was associated with DQB1*0302 and DRB1*0405 was associated with DQB1*0302 and DQB1*02, the latter being a rare DRB1/DQB1 haplotype in Caucasian individuals. The most frequent DQB1 alleles were DQB1*0301 (31.0%), and DQB1*05 (22.0%). The most frequent DQA1 variants were DQA1*0501 (39.0%) and DQA1*0102 (14.5%). The most common haplotype was DRB1*11-DQB1*0301-DQA1*0501 (25.0%) followed by DRB1*0301-DQB1*02-DQA1*0501 (10%) and DRB1*0701- DQB1*02-DQA1*0201 (6.5%). Data presented in this study suggest that the Iranian population shares some HLA components with populations resident in eastern and southern European countries.     

Complex interaction between HLA DR and DQ in conferring risk for childhood type 1 diabetes.

Type 1 (insulin-dependent) diabetes mellitus is associated with HLA DR and DQ factors, but the primary risk alleles are difficult to identify because recombination events are rare in the DQ-DR region. The risk of HLA genotypes for type 1 diabetes was therefore studied in more than 420 incident new onset, population-based type 1 diabetes children and 340 age, sex and geographically matched controls from Sweden. A stepwise approach was used to analyse risk by relative and absolute risks, stratification analysis and the predispositional allele test. The strongest relative and absolute risks were observed for DQB1*02-DQA1*0501/DQB1*0302-DQA1*0301 heterozygotes (AR 1/46, P < 0.001) or the simultaneous presence of both DRB1*03 and DQB1*0302 (AR 1/52, P < 0.001). Stratification analysis showed that DQB1*0302 was more frequent among DRB1*04 patients than DRB1*04 controls (P < 0.001), while DRB1*03 was more frequent among both DQA1*0501 (P < 0.001) and DQB1*02 (P < 0.001) patients than respective controls. The predispositional allele test indicated that DRB1*03 (P < 0.001) would be the predominant risk factor on the DRB1*03-DQA1*0501-DQB1*02 haplotype. In contrast, although DQB1*0302 (P < 0.001) would be the predominant risk factor on the DRB1*04-DQA1*0301-DQB1*0302 haplotype, the predispositional allele test also showed that DRB1*0401, but no other DRB1*04 subtype, had an additive risk to that of DQB1*0302 (P < 0.002). It is concluded that the association between type 1 diabetes and HLA is due to a complex interaction between DR and DQ since (1) DRB1*03 was more strongly associated with the disease than DQA1*0501-DQB1*02 and (2) DRB1*0401 had an additive effect to DQB1*0302. The data from this population-based investigation suggest an independent role of DR in the risk of developing type 1 diabetes, perhaps by providing diseases-promoting transcomplementation molecules.     

Similar incidence of type 1 diabetes in two ethnically different populations (Italy and Slovenia) is sustained by similar HLA susceptible/protective haplotype frequencies

The incidence of type 1 diabetes (T1DM) seems to depend in part on the population frequencies of susceptible and protective HLA haplotypes. The present study aimed to (i): characterize the genetic susceptibility to T1DM in the Slovenian population, (ii) test the general hypothesis that T1DM incidence is related to the frequencies of susceptible/protective haplotypes, (iii) compare allele, haplotype and genotype frequencies in Slovenians and Italians that represent two white populations with a similar incidence of T1DM (7.9/100,000/year and 8.1/100,000/year, respectively). The haplotype found most frequently among Slovenian T1DM patients was DRB1*0301-DQA1*0501-DQB1*0201 (53%). The DR4-DQA1*0301-DQB1*0302 haplotypes conferring susceptibility to T1DM were those bearing DRB1*0401 (OR = 12), DRB1*0404 (OR = 4.7) and DRB1*0402 (OR = 4.5). Negative associations with the disease were found for the following haplotypes: DRB1*1501-DQA1*0102-DQB1*0602, DRB1*1301-DQA1*0102-DQB1*0603, DRB1*1101/1104-DQA1*0501-DQB1*0301, and DRB1*1401-DQA1*0101-DQB1*0503. Our findings indicate that the low frequencies of susceptible genotypes, in particular, DR3-DQA1*0501-DQB1*0201/DR4-DQA1*0301-DQB1*0302, together with a high frequency of protective haplotypes, could in part explain the low incidence of T1DM in the Slovenian population. The combined frequencies of susceptible genotypes were similar in the two populations (Slovenia = 19.2%, Italy = 17.6%), and the 95% confidence limits of the OR values for each genotype in the two populations overlapped, indicating no significant differences between the values. We conclude that the similar incidences of T1DM in Italian and Slovenian populations are in part a reflection of similar frequencies of HLA susceptible/protective haplotypes.