Class II genes of miniature swine

Genomic clones corresponding to class II genes of theSLA ^c haplotype of miniature swine have been isolated and characterized. These genes have been grouped into seven non-overlapping clusters on the basis of restriction mapping. Ordering of exons within each cluster was accomplished by hybridization of Southern blots of restriction fragments with exon-specific probes. The two clusters (clusters 2 and 3) encoding theDRB andDQB genes were identified on the basis of hybridization with locus-specific 3 untranslated cDNA probes. Cluster 4 contained exons of bothDOB andDQB genes, the basis for which remains to be determined. The remaining four clusters (1, 5, 6, 7) were identified as containingDP, DR, andDO coding sequences, respectively, on the basis of sequence analysis. The porcine class II region appears very similar to that of man in number and nature of the class II genes identified and in the intron/exon organization of corresponding genes.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the association number M29944. Address correspondence and offprint requests to: C. LeGuern.     

Class II major histocompatibility complex genes of the sheep

The class II genes of the sheep major histocompatibility complex (MHC) have been cloned from two unrelated heterozygous sheep into cosmid vectors. By restriction mapping and hybridization with a number of class II probes of human and mouse origin, the cloned genetic material has been assigned to seven distinct alpha genes, 10 distinct beta genes and 14 beta-related sequences. It was difficult to identify homologues of specific HLA class II genes because of a tendency for the ovine genes to cross-hybridize between HLA probes representing different loci. Such cross-hybridization was especially marked among the beta genes. While DQ and DR homologues have been tentatively identified by several criteria, no genes corresponding to DP have been identified. Cosmids containing class II alpha and beta genes have been transfected into mouse LTK- cells, and surface expression of a sheep class II molecule has been obtained.     

Organization and polymorphism of bovine major histocompatibility complex class II genes as revealed by genomic hybridizations with bovine probes

Previous studies on restriction fragment length polymorphism of bovine major histocompatibility complex class II genes have primarily been based on the use of human probes. In the present study bovine probes for DQA, DQB, DRB and DYA were used for RFLP analysis of cattle genomic DNA digested with PvuII and TaqI. There was an excellent agreement between the RFLP results obtained with homologous and heterologous probes. Although a few 'new' restriction fragments were revealed with the bovine probes there was no discrepancy with regard to the classification of allelic types with the two types of probes. The major advantages of using bovine probes were a better hybridization signal and reduced cross-hybridization between loci. Hybridization experiments with DQA probes for the first domain exon from two different genomic clones revealed the presence of two distinct types of bovine DQA genes. Surprisingly, these probes did not cross-hybridize at high stringency, indicating that the two genes are quite divergent. Hybridization with a recently described genomic clone for a novel bovine alpha-chain gene confirmed that it corresponds to the DYA gene which had previously been identified by cross-hybridization to a human DQA probe.     

Mapping and nucleotide sequence of a newHLA class II light chain gene,DQB3

A genomic clone specifying a new HLA class II antigen β chain,DQB3, was isolated from a human genomic phage library using aDQB1 cDNA probe under low stringency conditions. Southern hybridization and nucleotide sequence analyses identified the β2 domain exon (exon 3) with several deleterious mutations and the CP-TM-CY exon [connecting peptide, transmembrane, and cytoplasmic regions, (exon 4)], but the first, second, and fifth exons encoding the 5′ UT-leader, the β1 domain, and the 3′ UT domain of normal β chains, respectively, were entirely missing. The nucleotide sequences of these two exons were distinct from those of other class II β chain genes, but slightly more related to theDQB1 andDQB2 genes than to other class II genes. TheDQB3 sequence mapped betweenDQA2 andDQB1, 15 kb upstream fromDQA2, by analysis of overlapping cosmid clones. This mapping was supported by the fact thatTaq I,Msp I, andBam HIDQB3 polymorphisms were perfectly correlated with theDQA2 polymorphism and not with any polymorphisms in theDR orDQ subregion, suggesting the presence of a hot spot for recombination betweenDQB3 andDQB1. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M26577.     

Cloning of the bovine major histocompatibility complex class II genes

Class II genes of the bovine major histocompatibility complex (MHC) have been cloned from a genomic library. The library was constructed in the bacteriophage lambda vector EMBL3 and comprises approximately 10 times the equivalent of the haploid genome. Half the library was screened with the human DQA, DQB, DRA and DRB cDNA probes. Of the 100 positively hybridizing phage clones, 37 were eventually fully characterized and mapped by means of Southern blot analysis. The exons encoding the first, second and transmembrane domain of all different A and B genes were subcloned and mapped in more detail. These analyses showed that these 37 clones were derived from five different A and 10 different B genes. The hybridization studies indicate that we have cloned and mapped two DQA genes, one DRA gene, two other A genes, four DQB genes, three DRB genes and three other B genes. Since the library was made from a heterozygous animal, this would suggest that there are at least one DQA, one DRA one other undefined A, two DQB, two DRB and one or two other undefined B genes in the haploid genome of Holstein Friesian cattle.     

DNA polymorphism in the major histocompatibility complex of man and various farm animals

In the past few years it has been possible by combining enzymatic cleavage of genomic DNA and the Southern blot hybridization technique to explore the endonuclease recognition site polymorphism of the MHC. HLA class I and DR and DQ alpha and beta class II specific probes as well as human C4 and Bf class III probes were used. All these probes were shown to cross-hybridize with DNA from pigs, cattle, sheep and horses. Hybridization of human genomic DNA with a class I probe showed 15-25 bands per genome depending on the enzyme used. Distinct endonucleases generated clusters of restriction fragments (RF) in HLA-informative families which correlated with HLA specificities. While numerous clusters were found associated with HLA-A alleles almost no cluster was related to HLA B or C specificities. Similarly, class II probes provided a large number of clusters. The existence of these clusters suggested that some polymorphic restriction sites are found in strong linkage disequilibrium and that the underlying mechanism might be gene conversion with heteroduplex correction. Since the degree of polymorphism detected by RF appears to be greater than the polymorphism defined by more traditional methods stronger associations between RF and pathological conditions are to be expected. Southern blot analysis was applied to unrelated pigs and sheep, as well as to families. Preliminary studies have also been performed on a few unrelated cattle and horses. Depending on the endonuclease used the HLA class I probe hybridized with around 15 bands in MHC heterozygous pigs and ruminants while up to 20 bands were found in horses. Therefore, a several-fold greater number of potential class I genes exist compared to those actually expressed. With the class II beta probe, cattle and sheep showed around 10 bands whereas 15 were observed in pigs and around 20 in horses. Based on limited results obtained with DQ alpha and beta probes and with the DR alpha probe there appeared to be fewer of these respective genes. Only one C4 gene has been detected in pig and this gene maps within the SLA region. Hybridization with the human C4 probe in cattle, sheep and horses revealed two to four bands which could possibly account for two C4 genes. To date their linkage to the MHC has not been established. The Southern blot hybridization technique represents a powerful tool for future immunogenetic studies.(ABSTRACT TRUNCATED AT 400 WORDS)     

Restriction fragment length polymorphism of DQB and DRB class II genes of the ovine major histocompatibility complex

The ovine major histocompatibility complex (MhcOvar) class II region was investigated by Southern blot hybridizations using ovine probes specific for the second exons of Ovar-DRB and Ovar-DQB genes. Multiple bands were revealed when genomic DNA was digested with each of five restriction enzymes (Bam HI, Eco RI, Hin dIII, PvuII and TaqI), and successively hybridized with the two radiolabeled ovine probes. Restriction fragment length polymorphisms (RFLPs) were analysed in 89 sheep originating from six inbred families and the inheritance of the fragment patterns was determined. Forty-one fragments were recorded with the DQB probe; 32 were detected with the DRB probe. They constituted 9 DQB and 10 DRB allelic patterns. Twelve DQB-DRB haplotypes were resolved in this study.     

Cloning of the bovine major histocompatibility complex class II genes

Summary. Class II genes of the bovine major histocompatibility complex (MHC) have been cloned from a genomic library. The library was constructed in the bacteriophage Λ vector EMBL3 and comprises approximately 10 times the equivalent of the haploid genome. Half the library was screened with the human DQA, DQB, DRA and DRB cDNA probes. Of the 100 positively hybridizing phage clones, 37 were eventually fully characterized and mapped by means of Southern blot analysis. The exons encoding the first, second and transmembrane domain of all different A and B genes were subcloned and mapped in more detail. These analyses showed that these 37 clones were derived from five different A and 10 different B genes. The hybridization studies indicate that we have cloned and mapped two DQA genes, one DRA gene, two other A genes, four DQB genes, three DRB genes and three other B genes. Since the library was made from a heterozygous animal, this would suggest that there are at least one DQA, one DRA one other undefined A, two DQB, two DRB and one or two other undefined B genes in the haploid genome of Holstein Friesian cattle.     

Structural similarity of the HLA-DQ region in DQ3 and DQ4 haplotypes and structural diversity of the HLA-DQ region in HLA-DR7 haplotypes.

Genomic DNA obtained from a B lymphoblastoid cell line was digested with appropriate restriction endonuclease and hybridized with several probes specific for genes encoding HLA-DQ. Southern hybridization with a DQA1 3'untranslated (UT) region probe showed DQ2-type hybridization pattern in DR7DQ3 haplotype. On the contrary, DQB1 3'UT probe showed DQ3-type pattern in the same haplotype. Gene cloning and DNA sequencing analysis revealed a repetitive sequence, (TG)19, between DQA1 and DQB1 gene in the DR7DQ3 haplotype. These results suggest that a recombination event has occurred near this potential Z-DNA structure in the haplotype, DR7DQ3. The 3'UT region probes of DQA1 and DQB1 genes failed to detect restriction fragment length polymorphism (RFLP) differences between DR4DQ3 and DR4DQ4 haplotypes in this experiment, suggesting that the gene structure between DQA1 and DQB1 is conserved in these haplotypes.     

Analysis by molecular cloning of the human class II genes

The HLA class II genes control immune responsiveness to defined antigens; they encode cell surface heterodimers composed of alpha and beta glycopeptides. Recently, cDNA and genomic clones encoding these chains have been isolated, which allows molecular analysis of the class II genes. cDNA clones encoding the alpha chain of the HLA-DR antigen as well as that of another HLA class II antigen have been identified and characterized by nucleotide sequence analysis. These clones have been used as probes to isolate additional class II alpha cDNA clones in cDNA libraries and to identify polymorphisms in genomic DNA. Polymorphic restriction sites have been localized within the HLA-DR alpha gene and used as genetic markers in the analysis of families and of disease (insulin-dependent diabetes mellitus) and control populations. In addition, cDNA clones encoding the DR beta and DC beta chains were used as hybridization probes to identify DNA polymorphism. cDNA clones encoding the DR gamma (Ii) chain have also been identified; unlike the DR alpha and DR beta loci, the DR gamma gene is located on some chromosome other than chromosome 6. The genetic complexity of the human class II alpha and beta loci, as revealed by analysis with cDNA and genomic clones, is greater than that of the murine class II genes. The extent of that complexity will be defined by future work in this area.     

Gene duplications and sequence polymorphism of bovine class II DQB genes

The genetic diversity of bovine class II DQB genes was investigated by polymerase chain reaction amplification and DNA sequencing. The first domain exon was amplified from genomic DNA samples representing 14 class II haplotypes, defined by restriction fragment length polymorphism (RFLP) analysis. The presence of a polymorphism in the copy number of DQB genes was confirmed since two DQB sequences were isolated from certain haplotypes. Four subtypes of bovine DQB genes were found. DQB1 is the major type and was found in almost all haplotypes. DQB2 is very similar to DQB1 but was found only in the duplicated haplotypes DQ9 to 12. DQB3 and DQB4 are two quite divergent genes only present in certain duplicated haplotypes. The bovine DQB complexity thus resembles that in the human DRB region. Bovine DQB genes were found to be highly polymorphic as ten DQB1 alleles and four DQB2 alleles were identified. The observed sequence polymorphism correlated well with previously defined DQB RFLPs. Bovine and human DQB alleles show striking similarities at the amino acid level. In contrast, the frequency of silent substitutions is much higher in comparisons of DQB alleles between species than within species ruling out the possibility that any of the contemporary DQB alleles have been maintained since the divergence of humans and cattle. The frequency of silent substitutions between DQB alleles was markedly lower in cattle than in humans, in agreement with a previous comparison of human and bovine DRB alleles.     

DNA polymorphism in the major histocompatibility complex of man and various farm animals*

Summary. In the past few years it has been possible by combining enzymatic cleavage of genomic DNA and the Southern blot hybridization technique to explore the endonuclease recognition site polymorphism of the MHC. HLA class I and DR and DQ alpha and beta class II specific probes as well as human C4 and Bf class III probes were used. All these probes were shown to cross-hybridize with DNA from pigs, cattle, sheep and horses. Hybridization of human genomic DNA with a class I probe showed 15–25 bands per genome depending on the enzyme used. Distinct endonucleases generated clusters of restriction fragments (RF) in HLA-informative families which correlated with HLA specificites. While numerous clusters were found associated with HLA-A alleles almost no cluster was related to HLA B or C specificities. Similarly, class II probes provided a large number of clusters. The existence of these clusters suggested that some polymorphic restriction sites are found in strong linkage disequilibrium and that the underlying mechanism might be gene conversion with heteroduplex correction. Since the degree of polymorphism detected by RF appears to be greater than the polymorphism defined by more traditional methods stronger associations between RF and pathological conditions are to be expected. Southern blot analysis was applied to unrelated pigs and sheep, as well as to families. Preliminary studies have also been performed on a few unrelated cattle and horses. Depending on the endonuclease used the HLA class I probe hybridized with around 15 bands in MHC heterozygous pigs and ruminants while up to 20 bands were found in horses. Therefore, a several-fold greater number of potential class I genes exist compared to those actually expressed. With the class II beta probe, cattle and sheep showed around 10 bands whereas 15 were observed in pigs and around 20 in horses. Based on limited results obtained with DQ alpha and beta probes and with the DR alpha probe there appeared to be fewer of these respective genes. Only one C4 gene has been detected in pig and this gene maps within the SLA region. Hybridization with the human C4 probe in cattle, sheep and horses revealed two to four bands which could possibly account for two C4 genes. To date their linkage to the MHC has not been established. The Southern blot hybridization technique represents a powerful tool for future immunogenetic studies. This is even more so in large farm animals where for various reasons it is almost impossible to conduct certain types of investigation that are easily performed in rodents or in man. Although the data are still preliminary, they already extend our knowledge of the MHC in domestic animals far beyond what could have been reasonably anticipated using conventional methods.     

Mapping of C2, Bf, and C4 genes to the swine major histocompatibility complex (swine leukocyte antigen)

Three miniature swine lines, inbred for swine leukocyte antigen (SLA) haplotypes, a, c, and d, and a recombinant line, haplotype g, were analyzed for possible restriction fragment length polymorphisms (RFLP) by Southern blot hybridization with human C2, factor B (Bf), and C4 specific probes. The search for RFLP by using a human C2 probe failed to reveal any variants. However, a Taq I polymorphism was identified with the human Bf probe and Bam HI and Pvu II polymorphisms were identified with the human C4 probe. Overlapping restriction fragments were found with the C2 and Bf probes, which strongly suggests close linkage of C2 and Bf genes in swine. Segregation analyses of the Bf and C4 polymorphisms indicated that the polymorphic fragments followed a Mendelian pattern of inheritance. The recombinant haplotype g, which expresses class I genes of haplotype c and class II genes of haplotype d, was shown to produce an identical RFLP pattern, by using the Bf and C4 probes, as haplotype d, but different from that of haplotype c. This indicates that there is a close association of [C4-Bf-C2] and class II genes in miniature swine. Although these data do not show conclusively the location of the [C4-Bf-C2] genes, it is hypothesized that swine [C4-Bf-C2] genes are located between the class II and class I genes, as has been demonstrated in mouse and man.     

Comparative sequence analysis of equine and human MHC class II DQB genes

The MHC class II DQB gene of horse was isolated and characterized. No obvious mutations causing frame shifts, or destruction of putative protein structure and splicing machinery were detected. Nucleotide sequence of exon 2 was consistent with an allelic sequence of the W23 haplotype. The cytoplasmic region of the equine DQB gene comprised two exons and an intron. A novel fragment of the gene was identified at the 3' intergenic region proximal to the ELA-DQB gene by sequence comparison between the human and horse DQB genes. This sequence showed the highest identity to exon 3 region of the DQB gene, however the 5' half of this exon was truncated as compared with the intact exon. This gene fragment was also identified in the same site of the HLA-DQB gene.     

Expression and characterization of ovine major histocompatibility complex class II (OLA-DR) genes

Previous work made use of nucleic acid probes corresponding to different subtypes of the class II regions of the human and murine major histocompatibility complex (MHC) to isolate seven different alpha and 24 different beta genes of the ovine MHC from two cosmid libraries. In an attempt to identify pairs of alpha and beta genes capable of cell surface expression, all permutations of alpha and beta genes were in turn transfected into mouse L-cells. Two pairs of alpha and beta genes co-expressed and stable ovine MHC class II L-cell lines were developed. The expressed alpha genes had previously been defined as DR-alpha homologues (DRA) by differential Southern hybridization to human subtype specific class II probes. The expressed ovine beta genes were also assigned as ovine DR-beta homologues (DRB) on the basis of their sequence having a higher degree of similarity with human DRB than any other subtype. A total of eight out of 23 anti-sheep class II specific monoclonal antibodies were typed OLA-DR specific by FACScan analysis using the L-cell lines.     

Partial nucleotide sequence of a novel bovine major histocompatibility complex class II β-chain gene, BoLA-DIB

A bovine genomic clone that hybridized to HLA-DQ beta cDNA was isolated and fragments containing the beta 1, beta 2 and transmembrane (TM) exons subcloned. The nucleotide sequences of the exons and flanking intron regions were determined. Comparisons of these exon nucleotide sequences and derived amino acid sequences to human class II beta-chain sequences showed that this gene is only 77% identical to HLA-DQ beta and about 75% identical to bovine DQ beta-like genes. The exon sequences were more divergent from other class II beta-chain genes. However, structural features such as conserved cysteines and regions of amino acids strongly suggest this to be a class II beta-chain gene. When exon-containing fragments were used as hybridization probes on Southern blots of bovine genomic DNA digested with Eco RI or Pvu II, each exon hybridized to a single band. Based on these results we have referred to this gene as a novel bovine class II beta-chain gene, BoLA-DIB.     

High-risk genotype for type 1 diabetes: a new simple microtiter plate-based ELOSA assay

The main contribution to genetic susceptibility for type 1 diabetes (T1D) is conferred by the HLA class II genes, with a major involvement of the DQB1*02 and 0302 alleles. The aim of our study was to develop a simple and rapid method suitable for identifying individuals with an HLA-associated T1D risk using whole blood as a source of DNA and reverse hybridization on microtiter plates (ELOSA). DNA was extracted from whole blood using various extraction methods. The PCR-amplified second exon of the DQB1 gene was hybridized at 37 degrees C for 1 hr to a set of 11 capture probes immobilized on a microtiter plate (eight-well strip per test) and corresponding to T1D susceptibility (S), protection (P), or neutral (N) alleles. Colorimetric analysis was then performed using specific oligonucleotides coupled to horseradish peroxidase and OrthoPhenyl Peroxidase (OPD) substrate. DNA samples corresponding to French (Rh?ne-Alpes area) T1D patients (n = 128) have been genotyped with the HLA-T1D prototype. A strong correlation is observed between susceptible genotypes and the disease, because 92.2% of the T1D individuals screened have at least one susceptible allele (DQB1*02 or *0302), thereby strengthening interest in analyzing DQB1 alleles as HLA-linked T1D markers in our Rh?ne-Alpes area population. Interestingly, clear T1D-associated genotyping results have been observed when using DNA samples extracted from dried blood spots, making it possible to envisage such genotyping in geographically dispersed affected families, for large-scale newborn screening, and for the inclusion of high-risk patients in clinical trials aimed at preventing the disease.     

Marsupial MHC class II beta genes are not orthologous to the eutherian beta gene families

The major histocompatibility complex (MHC) class II DRB, DQB, DPB, and DOB gene clusters are shared by different eutherian orders. Such an orthologous relationship is not seen between the beta genes of birds and eutherians. A high degree of uncertainty surrounds the evolutionary relationship of marsupial class II beta sequences with eutherian beta gene families. In particular, it has been suggested that marsupials utilize the DRB gene cluster. A cDNA encoding an MHC class II beta molecule was isolated from a brushtail possum mesenteric lymph node cDNA library. This clone is most similar to Macropus rufogriseus DBB. Our analysis suggests that all known marsupial beta-chain genes, excluding DMB, fall into two separate clades, which are distinct from the eutherian DRB, DQB, DPB, or DOB gene clusters. We recommend that the DAB and DBB nomenclature be reinstated. DAB and DBB orthologs are not present in eutherians. It appears that the marsupial and eutherian lineages have retained different gene clusters following gene duplication events early in mammalian evolution.     

Detection of novel sequence heterogeneity and haplotypic diversity of HLA class II genes

Nucleic acid sequences of the second exons of HLA-DRB1, –DRB3/4/5, –DQB1, and –DQA1 genes were determined from 43 homozygous cell lines, representing each of the known class II haplotypes, and from 30 unrelated Caucasian subjects, comprising 60 haplotypes. This systematic sequence analysis was undertaken in order to a) determine the existence of sequence microheterogeneity among cell lines which type as identical by methods other than sequencing; b) determine whether direct sequencing of class II genes will identify the presence of more extensive sequence polymorphism at the population level than that identified with other typing methods; c) accurately determine the molecular composition of the known class II haplotypes; and d) study their evolutionary relatedness by maximum parsimony analysis. The identification of seven previously unidentified haplotypes carrying five new allelic amino acid sequences suggests that sequence microheterogeneity at the population level may be more frequent than previously thought. Maximum parsimony analysis of these haplotypes allowed their evolutionary classification and indicates that the higher mutation rate at DRB1 compared to DQB1 loci in most haplotypic groups is inversed in specific haplotype lineages. Furthermore, the extent and localization of gene conversions and point mutations at class II loci in the evolution of these haplotypes is significantly different at each locus. Identification of additional HLA class II molecular microheterogeneity suggests that direct sequence analysis of class II HLA genes can uncover new allelic sequences in the population and may represent a useful alternative to current typing methodologies to study the effects of sequence allelism in organ transplantation.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M35890 through M35953.