Localization of a critical restriction site on the I-A beta chain that determines susceptibility to collagen-induced arthritis in mice

Type II collagen-induced arthritis (CIA) in mice is an autoimmune experimental model for rheumatoid arthritis. Susceptibility to CIA is associated with certain major histocompatibility complex class II haplotypes. The two very closely related haplotypes H-2q and H-2p differ in susceptibility to CIA. Only mice of H-2q (DBA/1, B10G strains) but not mice of H-2p-expressing strains (like strain B10P) develop CIA and an autoimmune response to type II collagen (CII) after immunization with CII. In contrast to H-2p, the H-2q haplotype does not express I-E molecules. The purpose of the present study was to identify, at the molecular level, the structures on major histocompatibility complex class II molecules determining susceptibility to CIA and CII responsiveness. We first excluded the possible suppressive involvement of Ep or Ap molecules by showing that F1 hybrids between H-2p and H-2q haplotype strains, expressing Ep and Ap, are responders to CII and fully susceptible to CIA. Secondly, because A alpha chains appear identical, we sequenced the A beta first-domain exons of p and q allotypes and found only four diverging amino acids in the predicted amino acid sequence. These variable residues were closely located at positions 85, 86, 88, and 89 at the end of the postulated alpha-helix, which is of importance for interactions with the antigenic peptide and the T-cell receptor. We suggest that this region is a critical major histocompatibility complex restriction site for CIA and CII responsiveness in H-2q mice as compared with H-2p mice. The CIA will now be an excellent autoimmune model for studies on interactions between autoantigenic peptide, autoreactive T cells, and a particular major histocompatibility complex molecule, as has been postulated to be the initial event also in rheumatoid arthritis.

Selection for polymorphism in the antigen recognition site of major histocompatibility complex class II molecules

The genetic basis for the extensive polymorphism of major histocompatibility complex (MHC) class II molecules was investigated by statistical analysis. Nucleotide sequences of human DQA1, DQB1, DRB1, and DRB3 genes and murine A alpha, A beta, and E beta genes were used. The results show that polymorphism is selected for in the antigen recognition site of class II molecules since replacement substitutions in this region were found to occur at a significantly higher frequency than expected in the absence of selection. In contrast, replacement substitutions are selected against in the remaining part of the first domain exon and in the second domain exon. Furthermore, comparing the sequence variability pattern among different class II alpha and beta sequences, using a variability index for each residue, showed that, with few exceptions, highly polymorphic residues occur in the antigen recognition site. There was a strong and highly significant correlation in the variability pattern in the homologous DRB/E beta sequences but not for DQB/A beta or DQA/A alpha sequences. This difference may be related to the fact that both alpha and beta chains of DQ/A molecules are polymorphic, while only beta chains of DR/E molecules vary.

A cellular and functional split in the DRw8 haplotype is due to a single amino acid replacement (DR beta ser 57- asp 57)

The single DR beta chain gene of the DRw8 haplotype has been suggested to carry both the DRw8 and the DRw52 epitopes. Cellular typing has shown that the DRw8 haplotype can be split into three subtypes, Dw8.1, Dw8.2, and Dw8.3, presumably due to a polymorphism in the DRw8 beta chain. Furthermore, Dw8.1 and Dw8.2 cells present influenza virus antigen to different T-cell clones. In the present study, DRw8/Dw8.2 beta chain cDNA was cloned and characterized. A comparison of this sequence with a partial DRw8/Dw8.1 beta chain gene suggested that the DRw8 split is due to a single amino acid replacement of ser57-asp57 caused by three nucleotide substitutions in the same codon. In most DR haplotypes, two expressed DR beta chain genes exist. Comparing the nucleotide sequence of the single beta gene in the DRw8 haplotype to those of other DR beta genes revealed that the DRw8 beta gene sequence is most closely related to the DRB1 genes of the DR3, 5, and w6 haplotypes. However, the comparisons also showed that it was not possible from sequence similarities to divide the DR beta genes into two or more distinct allelic series.

The single DR beta gene of the DRw8 haplotype is closely related to the DR beta 3III gene encoding DRw52

In most individuals two HLA-DR beta genes are expressed from each chromosome. One of these genes encodes one of the classical DR specificities, while the other encodes either of the supertypic DRw52/DRw53 specificities. In addition to these genes usually one or two DR beta pseudogenes are present. In contrast, the DRw8 chromosomal region only contains a single DR beta gene. To determine the relationship of this single gene to the multiple DR beta genes of other DR specificities, comparisons of Southern genomic blots were carried out. In this analysis genomic clones for each individual DR beta chain locus were included. The DR beta w8 gene was indistinguishable from the DR beta III gene of DR3 cells (encoding DRw52), suggesting that it is closely related to the latter gene. The functional implications of this finding are discussed.

Family relationships of murine major histocompatibility complex class I genes. Sequence of the T2Aa pseudogene, a member of gene family 3

The major histocompatibility complex of the mouse contains numerous class I genes, most of which are encoded in the Qa and Tla regions. By hybridizations, the murine class I genes have been classified into three major families (Rogers, J. H. (1985a) Immunogenetics 21, 343-353). As yet, complete sequences are available only for members of family 1 (several H-2 and Qa genes) or family 2 (the pseudoallelic Tla genes T3b and T13c). We here present the complete nucleotide sequence of a gene from the Tla region that belongs to family 3. This gene, T2Aa, is a pseudogene by several criteria. The general structure of the gene is nonetheless well preserved. A comparison of the T2Aa sequence to those of other murine class I genes confirms the classification into three gene families. Members of gene families 2 and 3, located in the Tla region, are no more similar to each other than to family 1 (the H-2 and Qa2,3 genes). This suggests that families 2 and 3 were both created by ancient duplications of the functionally important family 1 genes. The fact that families 2 and 3 have diverged extensively both from family 1 and from each other may suggest that they are devoid of function.

Isolation and characterization of a cDNA clone corresponding to bovine cellular retinoic-acid-binding protein and chromosomal localization of the corresponding human gene

A bovine adrenal cDNA library was constructed and a clone corresponding to cellular retinoic-acid-binding protein (CRABP) mRNA was isolated and sequenced. The insert of the clone corresponds to 75 bp of the 5' untranslated portion, the whole translated and the complete 3' untranslated portion of the bovine CRABP mRNA. A genomic Southern blot, probed with CRABP cDNA, indicated that only one copy of the gene is present in the human genome. Hybridizing bands in restricted chicken and fish DNA were also observed. Using the CRABP cDNA as probe we have located the human CRABP gene to chromosome 3 in hybridizations to mouse-human, hamster-human and rat-human cell hybrids. In situ hybridizations on rat testis cells probed with CRABP and cellular retinol-binding protein antisense mRNA indicate that both proteins are expressed in tubuli cells.

Human cellular retinol-binding protein gene organization and chromosomal location

The gene encoding the human cellular retinol-binding protein (CRBP) has been isolated from genomic libraries and its structure determined. Only one copy of the gene is present in the human genome. We have located the CRBP gene to segment 3p11-3qter on human chromosome 3 using hybridizations to mouse-human, rat-human and hamster-human cell hybrids. The gene harbors four exons encoding 24, 59, 33, and 16 amino acid residues respectively. The second intervening sequence alone occupies 19 kb of the 21 kb of the CRBP gene. The nucleotide sequence of the gene has been determined with the exception of the second intron. The positions of the introns agree with those in the rat CRBPII, the rat liver fatty-acid-binding protein and the mouse adipose P2 protein genes encoding molecules belonging to the same protein family as CRBP. In contrast to the other sequenced members of this family the promoter of the CRBP gene resembles those found in the 'housekeeping' genes in that it is (G + C)-rich, contains multiple copies of the CCGCCC sequence and lacks TATA box. A 9-bp homology containing the core sequence of the simian virus 40 enhancer repeat was found in the 5' upstream region. A genomic Southern blot probed with CRBP cDNA revealed hybridizing bands in restricted chicken and frog DNA.

Linkage relationships in the bovine MHC region. High recombination frequency between class II subregions

Class II genes of the bovine major histocompatibility complex (MHC) have been investigated by Southern blot analysis using human DNA probes. Previous studies revealed the presence of bovine DO beta, DQ alpha, DQ beta, DR alpha, and DR beta genes, and restriction fragment length polymorphisms for each of these genes were documented. In the present study, the presence of three additional class II genes, designated DZ alpha, DY alpha, and DY beta, are reported. DZ alpha was assumed to correspond to the human DZ alpha gene while the other two were designated DY because their relationship to human class II genes could not be firmly established. The linkage relationships among bovine class II genes and two additional loci, TCP1B and C4, were investigated by family segregation analysis and analysis of linkage disequilibrium. The results clearly indicated that all these loci belong to the same linkage group. This linkage group is divided into two subregions separated by a fairly high recombination frequency. One region includes the C4, DQ alpha, DQ beta, DR alpha, and DR beta loci and the other one is composed of the DO beta, DY alpha, DY beta, and TCP1B loci. No recombinant was observed within any of these subregions and there was a strong or fairly strong linkage disequilibrium between loci within groups. In contrast, as many as five recombinants among three different families were detected in the interval between these subregions giving a recombination frequency estimate of 0.17 +/- 0.07. The fairly high recombination frequency observed between class II genes in cattle is strikingly different from the corresponding recombination estimates in man and mouse. The finding implies either a much larger molecular distance between some of the bovine class II genes or alternatively the presence of a recombinational "hot spot" in the bovine class II region.

Characterization of the MHC class II region in cattle. The number of DQ genes varies between haplotypes

The organization of the major histocompatibility complex (MHC) class II region in cattle was investigated by Southern blot analysis using human probes corresponding to DO, DP, DQ, and DR genes. Exon-specific probes were also employed to facilitate the assessment of the number of different bovine class II genes. The results indicated the presence of single DO beta and DR alpha genes, at least three DR beta genes, while the number of DQ genes was found to vary between MHC haplotypes. Four DQ haplotypes, DQ alpha 1 beta 1 to DQ alpha 2 beta 4, possessed a single DQ alpha and a single DQ beta gene whereas both these genes were duplicated in eight other haplotypes, DQ alpha 3 beta 5 to DQ alpha 9 beta 12. No firm evidence for the presence of bovine DP genes was obtained. The same human probes were also used to investigate the genetic polymorphism of bovine class II genes. DQ alpha, DQ beta, DR alpha, DR beta, and DO beta restriction fragment length polymorphisms (RFLPs) were resolved and in particular the DQ restriction fragment patterns were highly polymorphic. Comparison of the present result with the current knowledge of the class II region in other mammalian species suggested that the DO, DP, DQ, DR, and DZ subdivision of the class II region was established already in the ancestor of mammals. The DP genes appear to be the least conserved class II genes among mammalian species and may have been lost in cattle. The degree of polymorphism of different class II genes, as revealed by RFLP analyses, shows striking similarities between species.

Structural relationship between alpha 1-microglobulin from man, guinea-pig, rat and rabbit

Rabbit alpha 1-microglobulin was purified from the urine of sodium-chromate-treated animals by the use of gel chromatography on Sephadex G-100, affinity chromatography on concanavalin-A--Sepharose and ion-exchange chromatography on DEAE-Sephadex. Rabbit alpha 1-microglobulin had a molecular mass of 25.6 kDa on SDS/polyacrylamide gel electrophoresis. Alpha 1-microglobulin has previously been purified from the urine of humans, guinea-pigs and rats by similar methods, and the molecular masses of the four homologues were compared by SDS/polyacrylamide gel electrophoresis and gel chromatography in a denaturing medium. By these two methods the human homologue was 6 kDa and 3 kDa larger, respectively, than the other three proteins. Endoglycosidase F digestion of alpha 1-microglobulin, followed by SDS/polyacrylamide gel electrophoresis, revealed three protein bands in the human alpha 1-microglobulin sample, and only two bands in guinea-pig, rat and rabbit alpha 1-microglobulin, with a gap between each band of 2.6--2.9 kDa. The amino-terminal amino acid sequences of the four homologues were determined and between 72% and 81% homology was seen. The five amino-terminal amino acids present in the other species were missing in guinea-pig alpha 1-microglobulin. Our results indicate that human alpha 1-microglobulin is substituted with two N-linked oligosaccharides, while only one is attached to each of the other alpha 1-microglobulins, and that the extra glycosylamine-linked oligosaccharide in the human protein is attached to asparagine in position 17. Finally it is shown that all four homologues inhibit antigen stimulation of human lymphocytes, a finding which is consistent with our previous suggestion that the N-linked oligosaccharides carry the immunosuppressive activity of alpha 1-microglobulin.

Structure of a gene encoding the 1.7 S storage protein, napin, from Brassica napus

A rapeseed chromosomal region containing a gene (napA), which encodes the 1.7 S seed storage protein (napin), was isolated in several overlapping recombinant clones from a phage lambda genomic library. Following restriction enzyme mapping of the genomic region, a subclone containing the napA coding region as well as some 1.1 and 1.4 kilobases of DNA from the 5' and 3' regions, respectively, was mapped and sequenced. The gene turned out to lack introns. Southern blotting analyses utilizing a napin cDNA clone as a probe revealed the presence of on the order of 10 napin genes in the rapeseed genome. The major polyadenylated transcript encoded by these genes was shown to be an 850-nucleotide species, the initiation site of which was mapped onto the napA gene. The major initiation site for transcription is located some 33 nucleotides downstream from a sequence perfectly conforming to the consensus sequence of a TATA box. Further analyses of the sequence revealed several features that may be of relevance for the expression of the napin genes.

The extracellular portion of HLA-DR alpha chain is composed of two compactly folded domains

A truncated form of the class II antigen DR alpha chain of the human major histocompatibility complex was produced in bacteria. A cDNA clone encoding the intact chain was modified so that the segment encoding the signal sequence was replaced by an ATG codon and the 3' region downstream to the part corresponding to the third exon was replaced by a stop codon. The new construct was put under the control of the Tac promoter in a bacterial expression vector. The distance between the Shine-Delgarno sequence and the initiation codon was randomized so that clones with optimal expression of the truncated DR alpha chain could be obtained after induced expression and immunoscreening. The truncated DR alpha chain was subjected to limited proteolysis with chymotrypsin, and the resulting cleavage products were analysed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Two fragments were visualized by western blotting. Electrophoresis in the absence and presence of reducing agents suggested that one of the proteolytic fragments contained a disulphide bridge. It is concluded that the extracellular portion of the DR alpha chain is composed of two compactly folded domains connected by an extended stretch of the polypeptide chain.

Matching of host genotype and serotypes of Coxsackie B virus in the development of juvenile diabetes

Thirty-six consecutive paediatric patients (0-16 years old) with recently contracted juvenile diabetes (IDDM) during 1982-84 were included in the study. Sera were assayed for recent or current Coxsackie B virus (CBV) infection using a specific and sensitive IgM RIA. Eighteen patients (50%) had IgM against CBV 1-5. The patients were also assayed for restriction fragment length polymorphism (RFLP) patterns with DNA probes coding for HLA-DR and DQ beta chains. The CBV-positive patients (n = 18) had either RFLP patterns associated with HLA-DR 3 or 4 or HLA-DQ patterns III or IV beta. Two of the CBV negative patients had neither HLA-DR 3 nor DR 4 and four of them had neither DQ patterns III nor IV. Eleven out of 18 CBV-positive patients had HLA-DQ III and DR 3 (61%) versus 5 out of 18 (28%) of the CBV-negative patients. All 11 patients with serology positive for CBV 2, 3, and 5 had HLA-DR 4 and DQ IV patterns. This was significantly (P less than 0.01) different from all five CBV 4-positive patients, who in contrast all had HLA-DR 3 or HLA-DQ III patterns. CBV 1-positive patients (n = 2) all had HLA-DR 3, 4, and HLA-DQ III, IV patterns. Thus CBV 4 seems to be significantly associated with a different host genetic constitution from at any rate CBV 2, 3, and 5, and possibly CBV 1.

Class II genes of the human major histocompatibility complex. Evolution of the DP region as deduced from nucleotide sequences of the four genes

The DP region of the human major histocompatibility complex contains two alpha genes and two beta genes. The DP alpha 1 and beta 1 genes encode the expressed DP histocompatibility antigen molecule, while the DP alpha 2 and beta 2 genes are inactive in the haplotypes examined. Here we present the sequence of the two DP beta genes and of the expressed DP alpha 1 gene. Nucleotide sequence comparisons reveal a considerably greater degree of similarity between the two beta genes than between the two alpha genes. We propose that a duplication giving rise to the DP alpha gene pair evolutionarily preceded the corresponding DP beta gene duplication. We also propose, based on the orientation of other class II gene pairs, that the original DP molecule was encoded by the DP beta 1 and DP alpha 2 genes. At some stage during the evolution of the DP region both of the two pseudogenes appear to have been expressed.

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

The human major histocompatibility complex, HLA, contains the genes of several class II molecules. We present here the molecular maps of the DQ and DX subregions and analyze the sequences of the polymorphic DQ alpha and DQ beta genes as well as the DX alpha and DX beta genes. The DQ alpha and DQ beta genes are oriented in opposite directions, approximately 12 kilobases apart. The DX alpha and DX beta genes are similarly oriented about 8 kilobases. The exon-intron organizations of the DQ alpha and DX alpha genes are analogous to those of other class II alpha genes. Comparison of the DQ alpha gene sequence to three DQ alpha cDNA clones shows that amino acid replacements are predominantly located between residues 45 and 80 in the amino-terminal domain. Analysis of the frequency of silent and replacement substitutions indicates that there is little selection against replacements in DQ alpha first domains. The exons encoding the second domains of DQ alpha and DX alpha are virtually identical, suggesting that a gene conversion event has occurred between these genes. The DX beta gene is very similar to the DQ beta gene but differs in the cytoplasmic portion. The DX beta gene contains a separate exon of 24 nucleotides encoding the core of the cytoplasmic tail. This exon is not expressed in the DQ beta genes due to a nonfunctional splice junction. Comparison of the number of nucleotide substitutions in the DQ beta first and second domain exons suggests that little or no phenotypic selection acts on the first domain whereas the second domain is under strong selection.

Class II genes of the human major histocompatibility complex. Organization and evolutionary relationship of the DR beta genes

The genes of the polymorphic HLA-DR molecules are located within the human major histocompatibility complex. We have studied the HLA-DR genes of an HLA homozygous individual typed to be DR4, Dw4, and DRw53. Fourteen cosmid and phage clones from genomic libraries were isolated and grouped into three clusters comprising a total of 165 kilobases. These clusters contain four DR beta genes. Nucleotide sequence determination showed that two of the genes encode beta chains that carry the DR4 and DRw53 specificities, respectively, while the other two genes are presumably pseudogenes. Comparisons of the nucleotide sequences of all four DR beta genes of the DR4 haplotype show that the genes are extensively similar, approximately 90% in both exons and introns. All four genes are equally similar to each other. These observations are consistent with the notion that the genes arose by duplications that were followed by homogenization through gene conversion. The existence of more than one DR beta gene homologue but only a single DR alpha gene homologue in mouse, rabbit, and cattle suggests that the DR beta gene duplications occurred at or early during mammalian speciation.

Class II genes of the human major histocompatibility complex. The DO beta gene is a divergent member of the class II beta gene family

A novel class II beta chain gene is described. This gene, tentatively called DO beta, displays considerably less polymorphism than beta genes of the DP, DQ, and DR loci. The nucleotide sequence of the DO beta gene is strikingly similar to that of the previously identified murine A beta 2 gene. The DO beta gene displays the same exon/intron organization as other beta genes although the fifth exon and the translated portion of the sixth exon are longer than in other genes. A striking feature of the amino acid sequence deduced from the DO beta gene sequence is the pronounced hydrophobicity of the NH2-terminal region. This feature distinguishes the putative DO beta chain from other class II beta chains and raises the possibility that DO beta chains may interact with an alpha chain that is structurally different from those of the DP, DQ, and DR loci. It further suggests that the putative DO molecule may have a function different from those of other class II antigens.