Faculty Bibliography

Our understanding of HLA class II polymorphism has undergone a rapid evolution in the last few years. As in so many areas of modern biology, this progress has depended largely on the application of recombinant DNA techniques to the study of this gene family. In particular, the recent development of methods of gene amplification by means of the polymerase chain reaction has allowed for the rapid assessment of polymorphism in the human population. In addition, the elucidation by x-ray crystallographic analysis of the three-dimensional structure of an HLA molecule has been a major step. These areas of progress have now begun to converge to allow a more detailed approach to the problem of class II polymorphism and disease susceptibility. As discussed in this review, the data so far indicate that a few amino acid substitutions in class II molecules may exert a critical influence on susceptibility to autoimmune diseases such as RA and IDDM. The mechanism by which these class II polymorphisms predispose to autoimmune disease is still unknown. It is tempting to speculate that differences in the binding affinity of HLA molecules for autoantigens might be involved; however, as yet no specific autoantigen has been identified for either RA or IDDM. Intriguingly, sequence similarities have been observed between some viral proteins and class II molecules, raising the possibility that these infectious agents might induce autoimmunity by 'molecular mimicry.' Examples include the human cytomegalovirus protein, IE2 as well as the Epstein Barr virus gp110 protein. Other possible mechanisms involve more complex immunoregulatory effects, such as the absence of suppressor functions that appear to be under the influence of the HLA genes. To some extent, the persistent ignorance about the cause of autoimmunity reflects a general lack of knowledge concerning exactly how HLA polymorphisms exert immunoregulatory effects. For example, in addition to influencing antigen presentation, MHC molecules also affect the overall T cell repertoire during thymic selection. The relative importance of HLA class II polymorphism in exerting immunoregulatory effects by means of thymic selection of the T cell repertoire is unknown. For autoimmune diseases such as RA and IDDM, there is a need to identify a specific functional abnormality that is causing the disease before the etiological significance of the emerging associations with class II polymorphisms become clear.(ABSTRACT TRUNCATED AT 400 WORDS)

The polymorphism of HLA class II molecules in man is particularly evident when comparisons between population groups are made. This study describes a DR3 haplotype commonly present in the American black population. Unlike the Northern European population, in which almost all DR3 individuals are DQw2, approximately 50% of DR3-positive American blacks express a DQw4 allelic product. This study characterizes the DR subregion of that haplotype. cDNA sequence analysis has revealed a DR beta gene which differs at several positions from previously described DR3 beta 1 genes. It is postulated that a gene-conversion-like event with a DRw52 beta gene as donor has generated some of these differences. The haplotype carries a DRw52a allele as defined by oligonucleotide hybridization studies. DNA restriction fragment analysis using a family and several unrelated individuals has allowed us to identify DR alpha and beta fragments associated with the DR3(w18),DQw4 haplotype. The most striking observation is that the DR3(w18),DQw4 haplotype differs from DR3(w17),DQw2 haplotypes at multiple class II loci. Several genetic mechanisms including reciprocal recombination, gene conversion, and point mutation were involved in generating the differences between these haplotypes. Once established, the DR3(w18),DQw4 haplotype appears to be relatively stable in the population

The complete DNA sequence of a DR beta chain cDNA encoding the DRw12 allele has been determined. The sequence of this DRB1 allele reveals a structural relationship to the group of other DRB1 genes found on DRw52 haplotypes, such as DR3, -w11, -w13, -w14, and -w8. The structural similarities among this group of alleles are particularly evident in the first hypervariable as well as in the 3' untranslated region. The second hypervariable region contains a unique sequence not identified in any other DRB1 allele. The third hypervariable region appears to have arisen by gene conversion events involving two DRB1 chain genes, DR7 and DR1 or DR2/Dw21

We have compared the sequence polymorphism of HLA class II genes of two distinct DRw6 haplotypes. cDNA libraries were constructed from two lymphoblastoid cell lines: CB6B (10w9060) which types as DRw13 DQw1, and AMALA (10w9064) which types as DRw14 DQw3. Multiple sequence differences were found at the DR beta I, DQ alpha, and DQ beta loci when these two haplotypes were compared. The DR beta I allele found in the DRw14 DQw3 haplotype appears to have diverged primarily as a result of a gene conversion event with a DR1 allele acting as donor. In contrast, the DRw13 DQw1 haplotype appears to have arisen by means of a recombination event between the DR and DQ subregions. Thus, multiple genetic mechanisms, including point mutation, gene conversion, and recombination, have generated diversity among DRw6 haplotypes

The DR1 and DRw10 beta 1 chain genes were isolated from each of 2 individuals with rheumatoid arthritis who were heterozygous for these class II major histocompatibility complex specificities. The sequences of the DR1 beta 1 chains from both patients were identical, differing from previously reported DR beta 1 chains of individuals without RA by 2 amino acid substitutions, at positions 85 (Val-Ala) and 86 (Gly-Val), and by a silent mutation at the last nucleotide of codon 78 (C-T), resulting in the loss of a Pst I restriction endonuclease site. Identical DRw10 beta 1 chain genes were found in both patients. These were shown to encode the epitope recognized by monoclonal antibody 109d6. This antibody also recognizes an epitope on the DRw53 beta 2 chain of the DR4 haplotype. The third diversity regions of the DR1 beta (amino acids 67-74) and the DRw10 beta 1 chains (amino acids 67-73) were identical, respectively, with those of the DR4 (Dw14) beta 1 and beta 2 chains, raising the possibility that in these patients, the third diversity regions of the two DR beta 1 chain genes present in trans are conformationally equivalent to the cis-encoded third diversity regions of the DR4 (Dw14), DR beta 1, and beta 2 chains. The nucleotide sequences of the DQ beta complementary DNA clones were identical to that of the DQw1 beta chain, and no DR beta 2 complementary DNA clones were identified

Genetic susceptibility for rheumatoid arthritis has been associated with both human leukocyte antigen (HLA)-DR4 and HLA-DR1, depending on the ethnic origin of the population under study. Furthermore, various subtypes of DR4 exist, only some of which appear to be associated with rheumatoid arthritis. DNA sequence analysis of the DR-beta chain genes encoding the DR4 subtypes as well as DR1 has led to the observation that similar third hypervariable region sequences are found on rheumatoid arthritis-associated DR-beta chain alleles. The data indicate that third hypervariable region sequence polymorphisms strongly influence T cell recognition as well as risk for rheumatoid arthritis. This has led to the hypothesis that genetic susceptibility for rheumatoid arthritis is due to a group of similar third hypervariable region sequences that may share conformational determinants important in antigen presentation and/or immune regulation

Expressible HLA class II alpha- and beta-chain cDNA were used for DNA-mediated gene transfer to produce L cell transfectants expressing single types of human class II molecules. Cloned transfectants expressing nine different class II molecules were isolated: DR alpha: DR1 beta I, DR alpha: DR4 beta I, DR alpha: DR5 beta I, DR alpha: DR5 beta III (DRw52), DR alpha: DR7 beta I, DR alpha: DR4/7 beta IV (DRw53), DQ7 alpha: DQw2 beta, DQ7 alpha: DQw3 beta, and DPw4 alpha: DPw4 beta. These class II-expressing transfectants were used to analyze by flow cytometry the molecular specificities of 20 anti-class II mAb. These analyes indicate that some mAb are more broadly reactive than was previously thought based on immunochemical studies. In contrast, the narrow molecular specificities of other anti-class II mAb were confirmed by this approach. Transfectants expressing human class II molecules should be valuable reagents for studies of B cell and T cell defined epitopes on these molecules

We have analyzed DNA sequence polymorphisms of DQ alpha and DQ beta chains from three haplotypes from the DRw52 family: DR5 DQw1 (FPA, GM3106), DRw6 DQw1 (CB6B, 10w9060), and DRw6 DQw3 (AMALA, 10w9064). The results indicate that the DR5 DQw1 and DRw6 DQw1 haplotypes have arisen by recombination between the DR beta 1 and DQ alpha loci. This contrasts with our previous analysis of DR4 DQ'Wa', DR3 DQ'Wa', and DR7 DQw3 haplotypes, all of which appear to have arisen by virtue of recombination between DQ alpha and DQ beta. Thus, there appear to be at least two different sites where recombination has occurred within the DR and DQ subregions. These differing patterns of recombination were interpreted in the context of the three major family groups of class II haplotypes, the DRw53, DRw52, and DR1/2 haplotype families. The data indicate that haplotypes from these family groups tend to undergo recombination at different locations. We propose that these differences in site of recombination are a reflection of differences in the molecular organization of the haplotypes belonging to each family group

Three cDNA clones encoding a DQ beta and two DR beta polypeptides have been isolated and sequenced from an American black individual expressing a DR2,DQw1 haplotype. The sequences of the cDNA clones are identical to previously described DR and DQ sequences from a DR2,Dw2 cell. The differences between DQw1-associated beta chains from DR2 and DR1 haplotypes is substantial, although a DQw1-specific sequence can be identified. The identical DQ and DR beta sequences found in unrelated individuals from different racial backgrounds suggests that class II structural polymorphism within the human population will be limited