A DR3-related DX alpha gene polymorphism strongly associates with insulin-dependent diabetes mellitus

Enteroviruses, type 1 diabetes and hygiene: a complex relationship

Type 1 diabetes (T1D) is an autoimmune disease in which the immune system mounts an attack on the host's insulin‐producing β cells. Because most cases of T1D cannot be attributed only to individual genetics, it is strongly inferred that there is a significant environmental contribution, such as infection, impacting disease development. The human enteroviruses (HEV) are common picornaviruses often implicated as triggers of human T1D, although precisely which of the numerous HEV may be involved in human T1D development is unknown. Experiments using non‐obese diabetic (NOD) mice, commonly used to model T1D, show that induction of T1D by HEV infection in NOD mice is a multifactorial process involving both the virus and the host. Interestingly, results demonstrate that HEV infection of NOD mice can also induce long‐term protection from T1D under certain conditions, suggesting that a similar mechanism may occur in humans. Based upon both experimental animal and observational human studies, we postulate that HEV have a dual role in T1D development and can either cause or prevent autoimmune disease. Whichever outcome occurs depends upon multiple variables in the host‐virus equation, many of which can be deduced from results obtained from NOD mouse studies. We propose that the background to the sharply rising T1D incidences observed in the 20th century correlates with increased levels of hygiene in human societies. Viewing T1D in this perspective suggests that potential preventative options could be developed. Copyright © 2009 John Wiley & Sons, Ltd.

The MHC type 1 diabetes susceptibility gene is centromeric to HLA-DQB1

HLA-DQB1 is widely considered to be the major histocompatibility complex (MHC) susceptibility gene for type 1 diabetes (T1D). However, since inheritance of the gene in T1D is recessive, the presence of the protective HLA-DQB1 0602 allele with normal nucleotide sequence in some patients raises the question of whether HLA-DQB1 is not the susceptibility locus itself but merely a good marker. HLA-DQB1 0602 is part of a conserved extended haplotype (CEH) [HLA-B7, SC31, DR2] (B7, DR2) with fixed DNA over more than 1Mb of genomic DNA that normally carries a protective allele at the true susceptibility locus. We postulated that, in patients with HLA-DQB1 0602, the protective allele at the susceptibility locus has been replaced by a susceptibility allele through an ancient crossover at meiosis centromeric to HLA-DQB1. We analyzed single nucleotide polymorphisms (SNPs) distinguishing the HLA-DQA2 (the first expressed gene centromeric to HLA-DQB1) allele on the normal HLA-B7, DR2 CEH from those on susceptibility CEHs in T1D patients and controls with HLA-DQB1 0602. All but 1 of 20 healthy control HLA-DQB1 0602 haplotypes had identical (consensus) first intron HLA-DQA2 5-SNP haplotypes. Fifteen of 19 patients with HLA-DQB1 0602 were homozygous for 1 or more HLA-DQA2 SNPs differing from consensus HLA-DQA2 SNPs, providing evidence of crossover involving the HLA-DQA2 locus. The remaining 4 patients were heterozygous at all positions and therefore uninformative. The loss of dominant protection usually associated with HLA-DQB1 0602 haplotypes is consistent with a locus centromeric to HLA-DQB1 being a major determinant of MHC-associated susceptibility, and perhaps the true T1D susceptibility locus.

HLA-DQ gene polymorphism in primary IgA nephropathy in three European populations

MHC Class II genes may contribute to susceptibility to IgA nephropathy (IgAN). We have previously identified a restriction fragment length polymorphism (RFLP) of the DQB1 region that associated with IgAN in British Caucasoids. However, another group, while demonstrating a DQB1 association, was unable to confirm our finding. MHC molecules are heterodimers consisting of an alpha and beta chain, and thus polymorphism of the DQA1 alpha chain may also be important to disease pathogenesis in IgAN. Therefore, we have determined DQA1 alleles and re-examined DQB1 alleles in British Caucasoids with IgAN using an approach that can differentiate between the common DQ alleles; we have also extended our studies to Caucasoid populations from Northern and Southern Europe, thereby addressing the possibility of variation in genetic susceptibility between populations. DNA was prepared from IgAN patients (British, N = 105; Italian, N = 71; Finnish, N = 48) and healthy controls (British, N = 111; Italian, N = 63; Finnish, N = 41). DQA1 alleles were identified by TaqI RFLP and Southern blotting; alleles that could not be fully resolved by Taq Southern blotting were identified by PCR-RFLP. DQB1 alleles were identified by polymerase chain reaction (PCR) based technique (PCR-RFLP). No consistent association of DQ alleles were found between the populations studied. In British patients a decreased frequency of DQB1*0201 was observed (P = 0.008), in Finnish patients a decreased frequency of DQB1*0602 was observed (P = 0.01), and in Italian patients no association between DQ markers and IgAn was found. These data demonstrate population variation in disease association, but no strong or consistent association in the DQ region.

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.

The role of genetic predisposition to type I (insulin-dependent) diabetes mellitus

The aetiology of insulin-dependent diabetes (IDDM) involves genetic predisposition, a major component of which has been mapped in the HLA complex, near to or identical with genes encoding class II molecules. In Caucasian populations IDDM is strongly associated with the serologically defined HLA-DR3 and DR4 antigens, which are widely recognised as markers of susceptibility. The particularly high risk of DR3/DR4 heterozygotes suggests that susceptibility is determined by two genes acting synergistically. The development of recombinant DNA technology has allowed a finer description of the class II region and provided evidence that DQ rather than DR determinants may primarily influence IDDM susceptibility. The search for specific structural changes of the DQA and DQB genes has shown that susceptibility correlates with the absence of aspartic acid at position 57 on the DQ beta chain (DQ beta 57 Asp--) and/or the presence of arginine at position 52 on the DQ alpha chain (DQ alpha 52 Arg+). In Caucasians the formation of a putative DQ susceptibility molecule (DQ alpha 52 Arg+, DQ beta 57 Asp-) accounts best for the disease associations when transcomplementation molecules consisting of DQ alpha and beta chains encoded by different haplotypes are postulated to explain the excess risk of heterozygotes. The HLA-IDDM associations in the Japanese, however, are not explained by this model. These and other unresolved questions indicate that other residues of the DQ alpha and beta chains or other class II molecules (DR beta chains), as well as non-MHC genes, may also contribute to the susceptibility.

Genetics of diabetes. Trans-racial gene mapping studies

A major component of inherited susceptibility to IDDM is associated with one or more loci in the MHC. Identification of the primary susceptibility genes has been complicated by the low frequency of recombination, i.e. linkage disequilibrium, within the MHC. It is difficult to distinguish whether a detected genetic association with the disease is primary, or secondary due to linkage disequilibrium with an allele at another locus which is directly predisposing. During the evolution of different races, however, recombination within the MHC has occurred and population-specific MHC haplotypes exist. Primary susceptibility allels should be associated with disease in all racial groups, regardless of genetic background. It is unlikely that disease associations secondary to linkage disequilibrium will be consistent in these groups. This chapter reviews the known associations of candidate class II susceptibility alleles with IDDM in the five largest racial groups; white Caucasians, Asian Indians, Negroids, Japanese and Chinese. These trans-racial studies suggest that the DQ molecule has a primary role in predisposition to IDDM. There are consistent findings of a positive association with the DQA1*0301 allele and negative associations with the DQB1*0602 and DQB1*0603 alleles. These two alleles differ by a single codon and so the encoded DQ beta chains are likely to have similar functions. DR4-associated susceptibility is associated with the DQA1*0301 allele in all races tested so far but this allele cannot be the only susceptibility factor on this haplotype. The identity of the DR3-associated susceptibility factor remains unclear but the DQB1*0201 allele is a candidate. If DQB1*0201 is involved, the existence of a protective factor on the neutral DR7-DQB1*0201 haplotypes is indicated. Analysis of DR9 associated susceptibility implicates a non-DR/DQ predisposing factor.

HLA-DQA2 (DX alpha) polymorphism and insulin dependent diabetes

A certain HLA-DQA2 locus TaqI fragment, DX alpha"U", has been reported to be associated with insulin-dependent diabetes mellitus (IDDM). Reports of various studies in this vein have ranged from stating that the association of DQA2"U" with IDDM exists even among subjects positive for HLA-DR3 and -DR4 to stating that the association of DQA2"U" with diabetes can be attributed to linkage disequilibrium between the DQA2"U" and some component(s) on the affected haplotypes. Using a synthetic 97-base probe corresponding to a portion of an intron of DQA2, in a Southern blot analysis of IDDM and control subjects from Wisconsin, we were able to confirm the association of DQA2"U" with diabetes. However, among DR3 subjects there was no significant association between DQA2"U" and diabetes (p = 0.26). Although there was a (nonsignificant) association of IDDM with DQA2"U" among DR4-positive subjects (p = 0.14), this can be completely attributed to linkage disequilibrium between DQA2"U" and DQw8. We also sequenced most of the second exon (corresponding to the alpha 1 domain of the DQA2 glycoprotein) from five individuals that were homozygous for either DQA2"U" or DQA2"L." The only polymorphisms observed were a "silent" mutation at position 36 and one example of a difference that would result in a change of amino acid at position 41.

Multiple sclerosis in French Canadians: evidence for HLA class II susceptibility and resistance genes

HLA class II DRB1, DQB1 and DQA1 gene probes were used to study DNA from unrelated French Canadian multiple sclerosis (MS) patients and controls by restriction fragment length polymorphism (RFLP) analysis. An MS-associated and linked series of allele-specific RFLPs or allogenotypes was identified among this relatively homogeneous ethnic group; the allogenotypes include DRw15, DQw6 and a DQA1 allogenotype termed DQ alpha 1b. An additional allogenotype which cross-hybridizes with DQA1 and is termed DQA2 upper (DQA2U), was shown not only to be part of the MS-associated extended haplotype, but also to be independently associated with MS in DRw15-negative patients. Conversely a second DQA2 allogenotype, termed DQA2 lower (DQA2L) and a DQB1 allogenotype (DQw7) linked to DQA2L showed negative correlations with MS. It seems likely that the relationship of the HLA class II gene region to MS is complex and that MS susceptibility may reflect interaction between disease susceptibility and resistance genes.

Implication of the HLA-DRB3 gene in Graves' disease: predominance of allele Dw24

Using RFLP, the present study sets off to determine the MHC class II gene polymorphism in Graves' disease, in order to define the HLA-related genetic susceptibility. Considering the preferential link between Graves' disease and the HLA-DR3 antigen, 42 HLA-DR3 Graves' disease patients were studied and compared with 42 HLA-DR-matched controls. Hybridization with a DQ alpha probe of DNAs digested by Taq I revealed a polymorphism of the DR3 haplotype with an overrepresentation of a 2.1 kb(U) fragment in patients, but this was merely a sign of the linkage disequilibrium between U and B8DR3. Hybridization with the DR beta probe of DNAs digested by Taq I yielded more facts. It revealed the overrepresentation of the Dw24 specificity (Taq I:9.8 kb) in DR3 Graves' disease patients. This study thus enabled us to determine precisely the susceptibility linked to the DR3 haplotype, implicating the DRB3 gene and its Dw24 allele, which appear to be the most reliable markers of the disease, providing a higher relative risk than B8DR3.

Frequency and associations of HLA class II TaqI allogenotypes in the Northern Ireland population

HLA-DR allogenotyping was performed on a panel of 1019 Caucasian individuals from the Northern Ireland population, of whom 150 were also HLA-DQ allogenotyped, using a single enzyme (TaqI)/multiple probe system. TaqI/DR beta restriction fragment length polymorphisms correlate well with the serologically defined specificities and in addition detect further subtypes of these associated with DQ or Dw specificities. The most frequent DR beta allogenotypes were DR beta 15, DR beta 4, and DR beta 17 (Dw24). The frequency of the subtypes of DR beta 4 associated with DQ beta 3 (TA10+) was higher than that reported elsewhere for Caucasian populations, whereas the frequency of the subtypes of DR4 beta associated with DQ beta 3(TA10-) was subsequently reduced. The subtypes of DR beta 4 associated with DQ beta 3 (TA10+) were strongly associated with B44. The TaqI/DX alpha gene polymorphisms, as revealed by the DQ alpha cDNA probe, were found to be associated with DR beta allogenotypes.

Identification of susceptibility loci for type 1 (insulin-dependent) diabetes by trans-racial gene mapping

A major component of inherited susceptibility to Type 1 (insulin-dependent) diabetes mellitus has been mapped to the major histocompatibility complex. Certain gene alleles in this region determine susceptibility and resistance to the disease. Mapping of susceptibility is hindered by the limitations of conventional tissue typing techniques, and by strong linkage disequilibrium within this part of the genome. Recombinant DNA technology and trans-racial studies have been used to allow finer mapping of genetic predisposition to Type 1 diabetes. These techniques have localised alleles encoding susceptibility and resistance to the DQ region. Other alleles determining disease susceptibility remain poorly localised.

Multiple sclerosis and HLA class II susceptibility and resistance genes

Probes to the HLA class II genes DR beta, DQ beta, and DQ alpha were used to study DNA from unrelated Caucasian multiple sclerosis (MS) patients by sequential restriction fragment length polymorphism (RFLP) analysis in Taq 1 restriction enzyme digests. Comparison of 104 patients and 108 controls, who were not matched for DR type, has identified for the first time a linked series of allele-specific RFLPs or allogenotypes which form an extended haplotype that is preferentially associated with MS. These allogenotypes include DRw15 or DR2(15); DQ beta lb, which corresponds at the DNA level to the DQwl(DQw6) serotype; a DQA1 allogenotype termed DQ alpha lb; and a 2.2 kb DX (DQA2) allogenotype termed DX alpha U (DQA2U). The role of HLA class II genes in susceptibility to MS was found to be complex. First, 23 of 104 MS patients showed DR-DQ linkages which were not observed in our control population. We suggest these anomalous associations may be important in the pathogenesis of MS. Second, homozygosity of a 2.0 kb DX (DQA2) gene, termed DX alpha L (DQA2L), showed a strong negative association with MS. DX alpha L (DQA2L) is in strong linkage disequilibrium with DR1, 5(w11) 7, and a subset of DR4, all of which also showed a negative association with MS. Since DX alpha L (DQA2L) does not code for any known product, DR1, 5(11), 4, and 7 become candidates for disease resistance genes.(ABSTRACT TRUNCATED AT 250 WORDS)

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

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

DQA1 restriction fragment length polymorphisms and insulin-dependent diabetes mellitus: a BglII fragment labels a subset of B8,DR3 haplotypes uniquely associated with insulin-dependent diabetes mellitus

Class II restriction fragment length polymorphism studies of 38 pedigrees with multiple cases of insulin-dependent diabetes mellitus revealed the existence of a DQA1-related polymorphism that distinguishes two kinds of HLA-B8,DR3 haplotypes. One of these, characterized by the presence of DQA1-BglII 7.20 kb, was present in all 14 examples inherited by patients and in 6 of the 12 B8,DR3 haplotypes not so inherited. The apparently complete association between the presence of this fragment and the "affected" status of B8,DR3 haplotypes (p = 0.004) was confirmed in a separate group of 26 simplex pedigrees selected for the presence of this haplotype in the respective probands (combined p less than 0.0001).

HLA-DR beta, -DQ alpha, and -DQ beta restriction fragment length polymorphisms in multiple sclerosis

Restriction fragment length polymorphism (RFLP) studies were performed on DNA from unrelated Caucasian patients with multiple sclerosis (MS) using cDNA probes to the HLA class II genes DR beta, DQ alpha, and DQ beta. In a study of 34 patients and 34 controls who were not matched for DR type, we found that the DQ beta allele-specific RFLP or allogenotype, termed DQ beta lb, which corresponds at the molecular level to the DQwl serotype, is preferentially associated with MS. A significant disease association with DR2 was demonstrated by serology but this was not confirmed using DR2/Dw2-specific RFLPs. We suggest that DQ beta lb is largely responsible for HLA-associated susceptibility to MS and that the apparent MS-DR2 serological association is due to the strong linkage disequilibrium between DR2 and DQ beta lb. Homozygosity of one of the two allelic bands of the DX alpha gene, usually termed the DX alpha lower (DX alpha L) band (which cross-hybridizes with the DQ alpha probe), correlated with reduced susceptibility to MS. Similarly a 5.3 kb band identified by the DQ alpha probe in Mspl digests showed a negative correlation with MS. In an analysis of 27 DR2+ controls and 26 DR2+ patients it was found that these individuals all had DR2/Dw2-specific RFLPs and all had identical DR2/Dw2-associated DQ beta (DQ beta lb) and DQ alpha (DQ alpha lb) allogenotypes. We detected no polymorphisms of DR beta, DQ alpha, or DQ beta genes among the DR2+ MS patients which distinguished them from normals.(ABSTRACT TRUNCATED AT 250 WORDS)

Definition of IDDM-associated HLA DQ and DX RFLPs by segregation analysis of multiplex sibships

Genetic variation of the DQ alpha and beta and of the DX alpha genes, detectable as RFLP in genomic DNA digests, has been suggested to improve the identification of individuals at high risk for insulin-dependent diabetes mellitus (IDDM). DNA from all members of 32 IDDM multiplex families was digested with six restriction endonucleases and the resulting fragments analyzed in Southern blots for hybridization with labeled cDNA probes for those genes. A computerized segregation analysis procedure was then used to assign fragments to haplotypes. Associations among fragments and between fragments and haplotypes characterized serologically and biochemically for their class II genes and IDDM-carrier status were calculated. The results indicate that the alleles of the DX alpha polymorphism maintain linkage disequilibrium with those of the DQ beta genes responsible for the well-known DQ beta 3.2-IDDM association, so that IDDM-carrier haplotypes carry disproportionally often both DQ beta 3.2 and DX alpha-TaqI-2.2kb. Thus, these RFLPs identify a DR-DQ-DX haplotype in high linkage disequilibrium, rather than the locus or loci that account for their high relative risk. However, four DR4-DQ beta 3.2 haplotypes that lack DX alpha-TaqI-2.2kb were encountered, two of which are "affected." These haplotypes suggest that the identification of the "disease locus" can be facilitated by the study of unusual haplotypes in which distinct IDDM-associated alleles occur separated from their neighbors of the standard genetic configurations.

RFLP analysis of HLA-DR beta and -DQ beta genes in the Korean patients with insulin-dependent diabetes mellitus

Human genomic DNA samples from 19 Korean patients and 31 controls of known serological DR antigen specificity were studied for insulin-dependent diabetes mellitus (IDDM)-associated variation in HLA-DR beta and -DQ beta restriction fragment length polymorphisms (RFLPs). Genotyping allowed for accurate assignment of HLA-DR types. For HLA-DRw6, a 12kb/DR beta/Taq I fragment was decreased in Korean IDDM (p less than 0.05). However, we could not find an increased frequency of a 12kb/DQ beta/Bam HI fragment or decreased frequency of a 3.7kb/DQ beta/Bam HI fragment in Korean IDDM. These results suggest a possible protective role of the HLA-DRw6 specificity in IDDM, irrespective of ethnic background, the absence of a specific DQ beta RFLP pattern associated with IDDM in Koreans, and the difference of the Korean population in the genetic of IDDM, compared to the Caucasoid population.

The major histocompatibility complex and insulin dependent (type 1) diabetes

The majority of the genetic component in insulin dependent (Type 1) diabetes mellitus can be explained by associations with genes on short arm of chromosome 6 located in the major histocompatibility complex. With the advent of cloning of the HLA Class II region genes it has been possible to refine the previous known association of HLA-DR3 and DR4 with this disease. Strong associations of IDDM have now been shown to exist with the DQB1 gene and/or linked genes, although this does not completely explain the HLA susceptibility to this disease.

Oligonucleotide probes for HLA-DQA and DQB genes define susceptibility to type 1 (insulin-dependent) diabetes mellitus

We have typed 27 Caucasoid families for DNA restriction fragment length polymorphisms and specific sequences using HLA class II specific cDNA, genomic and oligonucleotide probes. DNA haplotypes were identified by restriction fragment length polymorphism analysis that correlated with previously serologically-defined extended major histocompatibility haplotypes. These DNA haplotypes sort into positive, neutral or negative associations with Type 1 (insulin-dependent) diabetes mellitus. The DNA susceptibility haplotypes are even more simply and specifically defined by oligonucleotide probes for sequences of DQA and DQB genes. Our oligonucleotide probes define variabilities in nucleotide sequences coding for amino acid residues 26, 37 and 38 in the DQ beta-chain. Probes defining DQA sequences are also important for defining susceptibility since certain DQA genes appear to modify DQB susceptibility by conferring resistance. Thus, major histocompatibility conferred susceptibility to diabetes cannot be adequately explained by an amino acid change at a single position in the DQ beta-chain. These probes allow the direct identification of major histocompatibility susceptibility genes in Type 1 diabetes without the necessity of determining full haplotypes.

Class II HLA DNA polymorphisms in type 1 (insulin-dependent) diabetic patients of north Indian origin

Genetic associations with Type 1 (insulin-dependent) diabetes may be primary or secondary to linkage disequilibrium. Studies of different racial groups should allow these to be distinguished. We have reported that Type 1 diabetes is associated with HLA-DR3 and -DR4 in subjects of North Indian (Punjab) origin and now present the results of a study of HLA class II DNA polymorphisms in this group and in white caucasoid subjects. DR4 in North Indian Type 1 diabetic patients was associated with DQ beta and DX alpha DNA polymorphisms identical to those found in DR4-positive white caucasoid patients. This DQ beta/DX alpha pattern was increased in frequency in North Indian diabetic patients vs control subjects (33.3% vs 8.5%, p less than 0.001, relative risk = 5.12 (95% confidence limits: 1.96-13.4)). A DQ beta polymorphism with very low relative risk for Type 1 diabetes in white caucasoid subjects was also markedly reduced in North Indian diabetic patients vs control subjects (2.3% vs 24.7%, p less than 0.02, relative risk = 0.10 (95% confidence limits: 0.02-0.46)). This pattern was associated with DR2 in white caucasoid subjects, but with DRw6 in North Indians. A DR3-associated DR beta polymorphism was markedly increased in North Indian diabetic patients vs control subjects (90.2% vs 40.7%, p less than 10(-6), relative risk = 12.1 (95% confidence limits: 4.32-33.9)). The DQ subregion may be a primary site of genetic influence on susceptibility to Type 1 diabetes. Further studies in different racial groups will clarify the HLA associations of Type 1 diabetes.

DNA polymorphism and the study of disease associations

Recombinant DNA approaches to disease analysis may be as applicable to studies of disease association as they are to the analysis and diagnosis of single-gene defects. Population and/or family association analyses, using restriction fragment length polymorphisms around candidate genes as markers, have been employed to study conditions such as atherosclerosis and disease with an HLA-association. Progress made to date in disease-association studies using recombinant DNA methodology is reviewed, the rationale behind such studies is examined and associated problems and pitfalls discussed.

HLA-D region RFLPs indicate that susceptibility to insulin-dependent diabetes in South India is located in the HLA-DQ region

Recently close markers for insulin-dependent diabetes mellitus in Western 'Caucasoid' subjects have been defined from DQ region (both alpha and beta genes) restriction fragment length polymorphisms. In order to define the genetic contribution to insulin-dependent diabetes mellitus in an Indian population we have analysed 58 unrelated Dravidian (South Indian) insulin-dependent diabetic patients and 43 controls. In insulin-dependent diabetes an increased frequency of the Taq 1 DQ beta restriction fragment length polymorphisms designated T2 omega/T6 (relative risk = 10.6), and of homozygotes for Taq 1 DQ alpha 4.6 kb (relative risk = 11), was found in the patients. The highest relative risk for insulin-dependent diabetes mellitus was obtained by comparing patients and control subjects who either (a) co-inherited DQT2 omega/T6 with certain DQ alpha restriction fragment length polymorphisms or (b) were DQ alpha 4.6 kb homozygotes, the combination of (a) and (b) accounting for 55.5% of insulin-dependent diabetes mellitus subjects and none of the controls (relative risk = 101; 95% confidence limits 93-109).

HLA-DR alpha, -DX alpha, and DR beta III gene association studies in DR3 individuals

In this study we have examined the results of probing with synthetic oligomers at the DR beta III locus, together with restriction fragment length polymorphisms defined by BglII digestion and a cDNA DR alpha probe, and Taq 1 digestion and a genomic DQ alpha probe. We have demonstrated heterogeneity of the human leukocyte antigen DR3 and close association of the DR alpha, DR beta III, and DX alpha genes. Two DR3-related preferential allelic associations have been identified, which may prove useful in family analysis as well as for investigations of DR3-related diseases.

Analysis of HLA-D micropolymorphism by a simple procedure: RNA oligonucleotide hybridization

Recent progress in the molecular genetics of HLA class II antigens has revealed the existence of multiple loci and of a large degree of polymorphism, with more individual alleles than was expected. An accurate detection and analysis of this extensive polymorphism is essential for optimal HLA typing for transplantation and for a reevaluation of HLA-disease association. Because of the limitations of the current typing methods, including restriction fragment length polymorphisms, we have proposed a DNA typing procedure based on hybridization with loci- and allele-specific oligonucleotides. Here we present a much simpler way of analyzing class II micropolymorphism down to the level of single nucleotide differences. RNA oligonucleotide typing (ROT) relies on RNA dot blots and requires 10-20 ml of blood. It is shown that with appropriate oligonucleotide probes, ROT can reliably and unambiguously identify any polymorphism at any of the HLA loci, including new alleles, not identified with previous methods. This illustrates the importance of oligonucleotide typing to optimize HLA matching, in particular for transplantation involving unrelated donors.

Functional and biochemical subtypes of the haplotype HLA-DR3 in patients with celiac disease or idiopathic membranous nephropathy

HLA class II beta-chain polymorphism was investigated in the haplotype HLA-DR3 to determine if patients with HLA-DR3-associated diseases express normal or variant class II polymorphisms. Analysis was carried out by two-dimensional gel electrophoresis of immunoprecipitated HLA class II molecules, DNA hybridization with DR beta and DQ beta gene probes on Taq 1, Bam H1, or Rsa 1 digests, and mixed lymphocyte culture. Two subtypes of HLA-DR3 were identified in normal homozygous DR3 individuals on the basis of polymorphism in one of two DR beta chains detected, corresponding to differences in DR beta restriction fragment patterns. These polymorphisms exhibited significant linkage disequilibrium with the A1,B8,DR3 and B18,DR3 haplotypes, respectively. In proliferative experiments, cells with the B18,DR3-associated polymorphism strongly stimulated cells from donors with the B8,DR3-related polymorphism, suggesting that a T-cell epitope recognized by B8,DR3 cells lies on the B18,DR3-associated DR beta chain. In seven HLA-DR3 homozygous patients with celiac disease and three HLA-DR3-homozygous patients with idiopathic membranous nephropathy, only the normal patterns of HLA class II molecules were displayed, the B8,DR3 type occurring in all patients and the B18,DR3 type in one patient. These data suggest that celiac disease and idiopathic membranous nephropathy are not related to disease-specific HLA-DR beta or -DQ beta gene variants within the DR3 population that are revealed by these methods.

RFLP of the HLA-DQ alpha region: a diallelic DX alpha polymorphism, not linked to DR and DQ specificities

HLA-DQ alpha DNA polymorphism was studied by Southern blot analysis in a panel of 117 individuals, consisting of 56 randomly selected and 61 HLA-DR homozygous individuals. Hybridizing fragments representing DQ alpha genes correlate with DR specificities owing to linkage disequilibrium between DQ and DR. Two fragments representing DX alpha genes were identified with the restriction enzymes PvuII and TaqI and a DQ alpha cDNA probe. The two fragments of PvuII-DQ alpha hybridization (a 7200 and a 7000 basepair fragment) and the two of TaqI-DQ alpha (2200 and 1900 basepairs) have an identical distribution in the panel, and reveal gene frequencies of 49.1% and 50.9%; they behave as alleles of the putative DX alpha locus. The panel study shows that the DX alpha fragments are not linked with the DR or DQ specificities but segregate along with HLA as shown in family studies.

HLA DQ alpha and DQ beta restriction fragment length polymorphisms associated with Felty's syndrome and DR4-positive rheumatoid arthritis

HLA DQ alpha and DQ beta cDNA probes were used to study TaqI generated restriction fragment length polymorphisms (RFLPs) in DR4-positive patients with Felty's syndrome (FS), seropositive rheumatoid arthritis (RA), and in HLA-DR4 positive controls. The results of this analysis revealed two DQ beta RFLP patterns (DQ beta 3a and DQ beta 3b) associated with DR4, of which DQ beta 3b was found at significantly higher frequency in patients with FS (73%) or with RA (52%) than in DR4 controls (29%). Hind III generated RFLPs provide evidence that DQ beta 3b is in strong linkage disequilibrium with the gene encoding the serologically recognized epitope TA10. Results obtained using a DQ alpha chain probe revealed polymorphic differences between DQ alpha chain genes associated with different DR types, thereby providing a possible explanation for the lack of association between RA and other DR haplotypes in linkage disequilibrium with TA10. We conclude that both DQ alpha and DQ beta genes may be important in determining HLA-linked susceptibility to severe forms of RA.

Molecular biology of the HLA system in insulin-dependent diabetes mellitus

Genetic studies indicate that the IDDM susceptibility genes in the HLA region are closely linked to the DR3 and DR4 specificities; however, these specificities do not define the actual susceptibility genes. Molecular studies confirm this hypothesis by demonstrating restriction fragment length polymorphism between DNA's of identical DR specificities and thereby separating the DR haplotypes into those strongly or weakly associated with IDDM. Further studies at the nucleotide sequence level demonstrate further heterogeneity, with DR4 being associated with at least three different DQ beta genes and five different genes of the DR beta-1 locus. However, the majority of these subtypes are now recognized either serologically or by T-cell responses in mixed lymphocyte cultures. Furthermore, the sequences associated with IDDM are those most commonly found in DR4 individuals, ie, Dw4 and DQw3.2. Clearly, these and other class II genes must be studied for additional DNA polymorphism and their relevance for IDDM. For example, the DX alpha, 2.1-kb Taql polymorphism shows a stronger correlation with IDDM than DR3. However, it is not even known if the DX alpha genes are expressed. In addition, little is known of the DQ beta and DR beta genes associated with different DR3-associated haplotypes. Furthermore, an IDDM susceptibility gene may contain important differences in flanking or intron sequences controlling expression of these genes. The methods of recombinant DNA technology are enabling these unanswered questions to be addressed.

Genomic HLA-DQ beta polymorphism associated with insulin-dependent diabetes mellitus. Analysis of possible functional significance

Twelve insulin-dependent diabetes mellitus (IDDM) patients and healthy controls, who all carried the serologically defined DR3 and DR4 antigens, were compared with respect to other HLA polymorphisms. No significant differences between patients and controls were found by typing for HLA-Dw determinants by homozygous cell typing, nor by studies of their genomic DR beta polymorphism using different restriction enzymes. In contrast, certain DR beta polymorphism using different restriction enzymes. In contrast, certain DR4-associated genomic DQ beta fragments had a significantly different distribution among the IDDM patients than among the controls. Furthermore, when the distribution of all DQ beta-specific fragments which demonstrated polymorphism in our material was taken into account, nine of the 12 DR3, 4 IDDM patients demonstrated a similar DQ beta polymorphism compared with only two out of the 12 DR3, 4 controls (P = 0.006; corrected P = 0.037). Cells from patients and controls who demonstrated this IDDM-associated DQ beta polymorphism stimulated each other significantly less in reciprocal MLC tests, compared with the responses seen when their cells were confronted with cells from the DR3, 4 individuals with other genomic DQ beta polymorphisms.

HLA class II alpha chain gene polymorphisms in patients with insulin-dependent diabetes mellitus, dermatitis herpetiformis, and celiac disease

We have investigated DNA polymorphism of the class II alpha chain genes in HLA typed patients with insulin dependent diabetes mellitus (IDDM; n = 79), celiac disease (CD; n = 46), dermatitis herpetiformis (DH; n = 53), and controls (n = 86). Preferential allelic associations of HLA genes and gene products have thus been constructed for susceptibility to these diseases. DR alpha and DQ alpha gene polymorphisms indicated heterogeneity of HLA DR3, DRw6, and DR7, and HLA DR2 and DRw6, respectively. In DR7 positive CD patients a 3.8-kilobase (kb) DR alpha fragment, which correlated with DQw3, was found in only 11% of patients compared with 45% of corresponding controls (P less than 0.05). An increased frequency of a DX alpha genotype UU in all three diseases was found (IDDM 59%, DH 45%, CD 48%, compared to 21% in controls, P less than 0.001), which is not explained solely by the increased frequencies of DR3-DX alpha U. We therefore conclude part of the genetic susceptibility for these three conditions is encoded by genes within the DQ-DX subregion.

Structure and expression of HLA-DQ alpha and -DX alpha genes: interallelic alternate splicing of the HLA-DQ alpha gene and functional splicing of the HLA-DQ alpha gene using a retroviral vector

The nucleotide sequences of the two closely related HLA-DQ alpha and HLA-DX alpha genes have been determined. Exons coding for the signal peptide, alpha 2 and transmembrane domains are 94-99% homologous, whereas the alpha 1 exon and the promoter region have diverged as much as or more than introns and the 3' untranslated region. The promoter regions of both genes contain two short sequences thought to be important for regulation of transcription by gamma-interferon. Transfection studies established that the DQ alpha and DQ beta genes encode the HLA-DQ antigen. Transcripts of varying length are produced from different alleles as the result of the use of alternate splice and polyadenylation signals at the 3' end of the DQ alpha gene. Thus typing at the DQ alpha locus can be achieved by Northern blot analysis. No transcript of DX alpha was detected in B lymphocytes. The DX alpha gene was accurately spliced when introduced into a retroviral vector, suggesting that the lack of expression of DX alpha is not due to aberrant splice signals.

New HLA DNA polymorphisms associated with autoimmune diseases

Certain class II determinants of the human histocompatibility locus antigens (HLA) have been implicated in the aetiology of several autoimmune diseases, including rheumatoid arthritis (RA) and insulin-dependent diabetes mellitus (IDDM). HLA-Dw4 was the first HLA determinant found to be significantly increased in RA patients compared with controls, while Dw4 and Dw3 were found to be significantly increased in IDDM patients. When the HLA-DR system was defined, RA patients were found to have an increased frequency of DR4 and IDDM patients an increased incidence of both DR4 and DR3 compared with controls. As the HLA-Dw specificities are narrower than the serologically defined DR specificities, it was of specific interest to the present study that Dw4, Dw10, Dw13, Dw14, Dw15 and DKT2 are included in DR4. We describe here new restriction fragment length polymorphisms (RFLPs) and, together with the newly described serologically defined DQ specificity TA10, test their prevalence and associations in controls and diseased patients. We find that the newly characterized DNA bands are present at a much higher frequency in RA and IDDM patients than in controls. These findings may lead to a greater understanding of the pathogenesis of such diseases.

Radioimmunoassay typing gives a more precise definition of the HLA association of type 1 (insulin-dependent) diabetes

The problem of the HLA association of Type 1 (insulin-dependent) diabetes was re-examined by testing Class II antigenic specificities detectable by radioimmunoassay. Established (DRw53, DQw1, DQw2, DQw3) as well as newly described (DC5, DCalpha3) specificities were typed. The data obtained suggest that the association with DR3 and DR4 is secondary to that with DQ specificities in linkage disequilibrium with DR3 and DR4.