Immune response of HLA-DQ8 transgenic mice to peptides from the third hypervariable region of HLA-DRB1 correlates with predisposition to rheumatoid arthritis.

The major histocompatibility complex class II genes play an important role in the genetic predisposition to many autoimmune diseases. In the case of rheumatoid arthritis (RA), the human leukocyte antigen (HLA)-DRB1 locus has been implicated in the disease predisposition. The "shared epitope" hypothesis predicts that similar motifs within the third hypervariable (HV3) regions of some HLA-DRB1 alleles are responsible for the class II-associated predisposition to RA. Using a line of transgenic mice expressing the DQB1*0302/DQA1*0301 (DQ8) genes in the absence of endogenous mouse class II molecules, we have analyzed the antigenicity of peptides covering the HV3 regions of RA-associated and nonassociated DRB1 molecules. Our results show that a correlation exists between proliferative response to peptides derived from the HV3 regions of DRB1 chains and nonassociation of the corresponding alleles with RA predisposition. While HV3 peptides derived from nonassociated DRB1 molecules are highly immunogenic in DQ8 transgenic mice, all the HV3 peptides derived from RA-associated DRB1 alleles fail to induce a DQ8-restricted T-cell response. These data suggest that the role of the "shared epitope" in RA predisposition may be through the shaping of the T-cell repertoire.

HLA-DQ8 transgenic mice are highly susceptible to collagen-induced arthritis: a novel model for human polyarthritis.

Genetic studies have indicated that susceptibility to rheumatoid arthritis (RA) maps to the HLA-DR locus of the major histocompatibility complex. Strong linkage disequilibrium between certain HLA-DQ genes and HLA-DR genes associated with RA, however, suggests that HLA-DQ molecules may also play a role in RA susceptibility. To examine the role of HLA-DQ molecules in arthritis, we generated transgenic mice expressing the DQA1*0301 and DQB1*0302 genes from an RA predisposing haplotype (DQ8/DR4Dw4). The transgenes were introduced into mouse class II-deficient H-2Ab0 mice, and their susceptibility to experimental collagen-induced arthritis was evaluated. The HLA-DQ8+,H-2Ab0 mice displayed good expression of the DQ8 molecule, while no surface expression of endogenous murine class II molecules could be detected. The DQ8 molecule also induced the selection of CD4+ T cells expressing a normal repertoire of V beta T cell receptors. Immunization of HLA-DQ8+,H-2Ab0 mice with bovine type II collagen (CII) induced a strong antibody response that was cross-reactive to homologous mouse CII. Also, in vitro proliferative responses against bovine CII, which were blocked in the presence of an antibody specific for HLA-DQ and mouse CD4, were detected. Finally, a severe polyarthritis developed in a majority of HLA-DQ8+,H-2Ab0 mice, which was indistinguishable from the disease observed in arthritis susceptible B10.T(6R) (H-2Aq) controls. In contrast, HLA-DQ8-,H-2Ab0 fullsibs did not generate CII antibody and were completely resistant to arthritis. Therefore, these results strongly suggest that HLA-DQ8 molecules contribute to genetic susceptibility to arthritis and also establish a novel animal model for the study of human arthritis.

Linkage disequilibrium within the HLA complex does not extend into HLA-DP.

It is well known that certain alleles from different loci within the Human Leucocyte Antigen (HLA) complex are in linkage disequilibrium. This linkage phenomenon is relatively well characterized for haplotypes that include specific class I and class II alleles such as HLA-B8 and HLA-DR3. However, the HLA-DP genes are located at the centromeric end of the HLA complex and are less well characterized with regard to linkage disequilibrium. The availability of a large population of healthy subjects and sequence-specific oligonucleotide (SSO) typing enabled us to assess the degree of linkage between HLA-DPB1 and HLA-DQB1 genes. Using the polymerase chain reaction and a series of oligonucleotide probes which define seven DQ beta alleles and twenty DP beta alleles, we studied 180 unrelated, normal Caucasian individuals and found only weak or negative associations between HLA-DPB1 and HLA-DQB1. These data demonstrate that the association between HLA-DQ and DP is weak and also imply that DP extended haplotypes related to particular diseases may not reflect normal associations. Implications of these results might impact on the concept of linkage disequilibrium in general as well as the evolution of the HLA complex. In addition, extensions of this work may have clinical ramifications with regard to bone marrow transplantation and founder effects in certain diseases.

Analysis of HLA genotypes and susceptibility to insulin-dependent diabetes mellitus: HLA-DQ alpha complements HLA-DQ beta.

It is well known that certain genes in the HLA-D region confer increased susceptibility to insulin-dependent diabetes mellitus (IDDM). Previous studies have documented an increased risk associated with the HLA-DR beta chain alleles, DR3 and DR4, and the DQ beta chain allele DQB1*0302 (formerly DQw8). Since DQ alpha is also polymorphic and has been strongly implicated as the primary IDDM susceptibility locus in other races, we wanted to assess the contribution of DQ alpha to IDDM in Caucasians. This information would enable us to define more precisely the class II association with IDDM as well as gain insight into issues of cis versus trans association of DQ heterodimers in this disease. To this end, the DQ alpha genotype was determined for a large group of diabetic and normal Caucasian individuals who had been HLA-DQ beta and HLA-DR typed previously. Using the polymerase chain reaction and a set of twelve oligonucleotide probes, we determined the DQ alpha genotype of 323 patients with IDDM and 182 normal subjects. We found that certain DQ alpha alleles are decreased in the diabetic population compared with normal subjects (i.e. DQA1*0102 and *0103), while others are significantly increased in patients with IDDM (i.e. DQA1*0301 and *0501). In addition, certain combinations of DQ alpha alleles are associated with increased susceptibility to disease (i.e. DQA1*0301, *0501). These results parallel our findings at the DQ beta locus; however, because of the various associations between DQ alpha and DQ beta chains, the risks conferred by DQ alpha are generally lower than those at DQ beta. Moreover, our data indicate that, in Caucasians, no single DQ alpha allele accounts for the highest degree of susceptibility to IDDM as in other races, although DQ alpha analysis may be informative in a few cases. When done in combination, however, oligonucleotide analyses at both DQ alpha and DQ beta complement each other and provide a more complete assessment of the HLA-associated component of disease susceptibility in IDDM.

Analysis of HLA genotypes and susceptibility to insulin-dependent diabetes mellitus: association maps telomeric to HLA-DP.

There is convincing evidence that certain combinations of alleles within the human leucocyte antigen (HLA) complex, particularly within HLA-DQ, are associated with either resistance or susceptibility to insulin-dependent diabetes mellitus (IDDM). A previous study conducted on a large, well-defined group of patients demonstrated that DQB1*0302 (DQw8) conferred 'dominant susceptibility' to IDDM while DQB1*0602 (DQw1.2) conferred 'dominant protection'. The availability of this population enabled us to further assess susceptibility associated with other class II alleles in an effort to map an outside HLA boundary of disease association. Using a group-specific polymerase chain reaction protocol and a series of oligonucleotide probes which define over twenty DP beta alleles, we studied 286 unrelated Caucasian patients with IDDM and 184 normal subjects. We found that while several alleles are increased (DPB1*0201, DPB1*0301, DPB1*0402) or decreased (DPB1*0101, DPB1*0202) in the diabetic population compared with the normal subjects, the HLA association with IDDM is considerably weaker at the DP locus. These data define the centromeric boundary for the HLA-associated susceptibility gene in IDDM, localizing susceptibility to the region telomeric to HLA-DP up to and including HLA-DQ.

Analysis of HLA-DQ genotypes and susceptibility in insulin-dependent diabetes mellitus.

There is evidence that certain alleles at the HLA-DQ locus are correlated with susceptibility to insulin-dependent diabetes mellitus (IDDM) and in particular that DQ beta-chain alleles containing aspartic acid at position 57 are protective. The availability of a large group of patients with IDDM enabled us to assess the role of HLA-DQ alleles in susceptibility to the disease in order to confirm and extend recent observations derived from studies of smaller numbers of patients. Using allele-specific oligonucleotide probes and the polymerase chain reaction, we studied 266 unrelated patients with IDDM and 203 unrelated normal subjects for eight HLA-DQ beta-chain alleles. Two major findings emerged from these studies. First, the presence of an HLA-DQw1.2 allele was protective. Only 6 of the 266 patients with IDDM (2.3 percent) were positive for HLA-DQw1.2, as compared with 74 of the 203 normal subjects (36.4 percent; P less than 0.001). Thus, persons with the HLA-DQw1.2 allele, which is one of the polymorphic forms of the beta chain of the HLA-DQ molecule, rarely had IDDM, no matter which other HLA-DQ beta-chain allele they inherited ("dominant protection"). Second, the presence of the HLA-DQw8 allele increased the risk of IDDM. The relative risk of IDDM was 5.6 in persons homozygous for HLA-DQw8, and it was similar in persons with the HLA-DQw1.1/DQw8 or HLA-DQw2/DQw8 haplotype ("dominant susceptibility"). However, the relative risk of IDDM in persons who had the HLA-DQw1.2/DQw8 haplotype was 0.37, demonstrating that the protective effect of HLA-DQw1.2 predominated over the effect of HLA-DQw8. We conclude that the presence of the HLA Class II antigen DQw1.2 is strongly protective against the development of IDDM, and that complete HLA-DQ typing is necessary for accurate assessment of susceptibility to IDDM.