Restriction fragment length polymorphisms of horse class II MHC genes observed using various human alpha-and beta-chain cDNA probes

Genomic DNA isolated from 20 horses was digested with up to six restriction endonucleases and subjected to southern blot hybridization analysis using various human class II alpha- and beta-chain cDNA probes. A high degree of restriction fragment length polymorphism (RFLP) was found for the DQ alpha, DP beta, DQ beta and DR beta probes, about 20 polymorphic bands being detected for each. DR alpha showed 2-4 polymorphic bands, whereas no evidence for DP alpha-like genes was found. A number of correlations of RFLPs with individual alloantisera were apparent.     

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.     

Mapping of the rabbit MHC reveals that class I genes are adjacent to the DR subregion and defines an insertion/deletion-related polymorphism in the class II region.

Molecular analyses of genes in the rabbit MHC (RLA) by pulsed field gel electrophoresis have shown that the relative order of class II genes (DP, DO, DQ, DR) is identical to that in humans and similar to that in the mouse. However, a major difference from either HLA or H-2 was observed at the DR end of the RLA class II complex: class I genes are located in close proximity to DR with no interposed class III sequences. A MluI fragment of 180 kb and a 210-kb SalI fragment both hybridized with the DR probe as well as with different class I probes including that for pR27, a class I gene with T cell-limited pattern of expression. Comparison of two different RLA haplotypes, A and B, indicated that the distance between the DQ and DR subregions differs by approximately 700 kb in the two haplotypes. Testing other unrelated rabbits suggested that this difference segregates within the rabbit population and presumably derives from an insertion/deletion event in different haplotypes. A further difference between the A and B haplotypes included variable distance between genes encoding DO beta and DP; the DR end of the complex and the class I genes linkage was conserved in the two haplotypes.     

Restriction fragment length polymorphism of DQ and DR class II genes of the bovine major histocompatibility complex

DQ alpha, DQ beta, DR alpha and DR beta class II genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot hybridizations using human probes. Hybridizations of these probes to genomic DNA, digested with PvuII or TaqI, revealed extensive restriction fragment length polymorphisms (RFLPs). The polymorphisms were interpreted genetically by analysing a family material, comprising five sires, 48 dams and 50 offspring, and a population sample comprising 197 breeding bulls. The analysis resolved 20 DQ alpha, 17 DQ beta, 5 DR alpha and 25 DR beta RFLP types. The segregation data were consistent with simple Mendelian inheritance of the RFLPs. The analysis of the bull sample showed that it is possible to apply the RFLP method for routine typing of class II polymorphism in population samples. The linkage disequilibrium in the DQ-DR region was found to be extremely strong as only about 20 DQ and about 30 DQ-DR haplotypes were observed despite the large number of possible haplotypes. Close linkage to the blood group locus M was also found; the M' allele occurred in strong linkage disequilibrium with the class II haplotype DQ1BDR alpha 4DR beta 1B. A population genetic analysis of the DQ data in the sample of breeding bulls revealed that the frequency of homozygotes was significantly lower than Hardy-Weinberg expectation and that the allele frequency distribution deviated significantly from the one expected for selectively neutral alleles.     

A novel HLA class II molecule

Molecular evidence has been obtained for a novel monomorphic HLA class II molecule distinct from HLA-DP/DQ/DR using a panel of lymphoblastoid cells which include HLA-loss mutants. The expression of this molecule was investigated using monomorphic affinity-purified mouse monoclonal antibodies (mAbs), including one of the IgG_2a subclass designated EDUA. This antibody reacts strongly in a cell-binding radioimmunoassay with HLA-DR and -DQ loss mutants derived from a lymphoblastoid parental cell. The EDU-1 mAb also reacted with a local panel of homozygous Epstein-Barr virus-transformed cell lines. The reactive molecules were further detected on allostimulated T-cell clones and various leukemic cells including those of myeloid origin which lack surface expression of HLA-DQ molecules. Thus the class II molecule described in this study corresponds to a monomorphic HLA class II determinant expressed on a variety of cells of different origin and HLA phenotypes. Moreover, this antigen structure is distinct from that of HLA-DP/DQ/DR as shown by direct immunoprecipitation, serial immunodepletion experiments, and two-dimensional gel electrophoresis. The molecule could be specified by new class II genes between DP and DQ. An alternative explanation for the genetic basis of the novel molecule is the existence of isotypic associations between alpha and beta chains of various class II molecules (DP, DX, DZ, and DO) but not DR and DQ as the mutant cells tested lack the latter genes.     

Giant Panda Genomic Data Provide Insight into the Birth-and-Death Process of Mammalian Major Histocompatibility Complex Class II Genes

To gain an understanding of the genomic structure and evolutionary history of the giant panda major histocompatibility complex (MHC) genes, we determined a 636,503-bp nucleotide sequence spanning the MHC class II region. Analysis revealed that the MHC class II region from this rare species contained 26 loci (17 predicted to be expressed), of which 10 are classical class II genes (1 DRA, 2 DRB, 2 DQA, 3 DQB, 1 DYB, 1 DPA, and 2 DPB) and 4 are non-classical class II genes (1 DOA, 1 DOB, 1 DMA, and 1 DMB). The presence of DYB, a gene specific to ruminants, prompted a comparison of the giant panda class II sequence with those of humans, cats, dogs, cattle, pigs, and mice. The results indicated that birth and death events within the DQ and DRB-DY regions led to major lineage differences, with absence of these regions in the cat and in humans and mice respectively. The phylogenetic trees constructed using all expressed alpha and beta genes from marsupials and placental mammals showed that: (1) because marsupials carry loci corresponding to DR, DP, DO and DM genes, those subregions most likely developed before the divergence of marsupials and placental mammals, approximately 150 million years ago (MYA); (2) conversely, the DQ and DY regions must have evolved later, but before the radiation of placental mammals (100 MYA). As a result, the typical genomic structure of MHC class II genes for the giant panda is similar to that of the other placental mammals and corresponds to BTNL2∼DR1∼DQ∼DR2∼DY∼DO_box∼DP∼COL11A2. Over the past 100 million years, there has been birth and death of mammalian DR, DQ, DY, and DP genes, an evolutionary process that has brought about the current species-specific genomic structure of the MHC class II region. Furthermore, facing certain similar pathogens, mammals have adopted intra-subregion (DR and DQ) and inter-subregion (between DQ and DP) convergent evolutionary strategies for their alpha and beta genes, respectively.     

DO beta: a new beta chain gene in HLA-D with a distinct regulation of expression

The HLA-D region of the human major histocompatibility complex encodes the genes for the alpha and beta chains of the DP, DQ and DR class II antigens. A cDNA clone encoding a new class II beta chain (designated DO) was isolated from a library constructed from mRNA of a mutant B-cell line having a single HLA haplotype. Complete cDNA clones encoding the four isotypic beta chains of the DR1, DQw1, DPw2 and putative DO antigens were sequenced. The DO beta gene was mapped in the D region by hybridization with DNA of HLA-deletion mutants. DO beta mRNA expression is low in B-cell lines but remains in mutant lines which have lost expression of other class II genes. Unlike other class II genes DO beta is not induced by gamma-interferon in fibroblast lines. The DO beta gene is distinct from the DP beta, DQ beta and DR beta genes in its pattern of nucleotide divergence. The independent evolution and expression of DO beta suggest that it may be part of a functionally distinct class II molecule.     

Analysis of cDNA coding MHC class II beta chain of the chimpanzee (Pan troglodytes).

The chimpanzee (Pan troglodytes, Patr) is the closest zoological living relative of humans and shares approximately 98.6% genetic homology to human beings. Although major histocompatibility complex (MHC) plays a critical role in T cell-mediated immune responses in vertebrates, the information on Patr MHC remains at a relatively poor level. Therefore, we attempted to isolate Patr MHC class II genes and determine their nucleotide sequences. The cDNAs encoding Patr MHC class II DP, DQ and DR beta chains were isolated from the cDNA library of a chimpanzee B lymphocyte cell line Bch261. As a result of screening, the clone 6-3-1 as a representative of Patr DP clone, clone 30-1 as a Patr DQ clone, and clones 4-7-1 and 55-1 having different sequences as Patr DR clones were detected. The clone 6-3-1 consisted of 1,062 nucleotides including an open reading frame (ORF) of 777 bp. In the same way, clone 30-1 consisted of 1,172 nucleotides including ORF of 786 bp, clones 4-7-1 and 55-1 consisted of 1,163 nucleotides including ORF of 801 bp. Except for five nucleotide changes, clones 4-7-1 and 55-1 were the same sequence. By comparison with the nucleotide sequences already reported on chimpanzee MHC class II beta 1 genes, clones 6-3-1, 30-1, 4-7-1 and 55-1 were classified as PatrDPB1*16, PatrDQB1*0302, PatrDRB1*0201 and PatrDRB1*0204, respectively. This is the first report to describe complete cDNA sequences of Patr DP and DQ molecules. The nucleotide sequence data of Patr MHC class II genes obtained in this study will be useful for the genotyping of Patr MHC class II genes in individual chimpanzees.     

Rabbit MHC. II. Sequence analysis of the R-DP alpha- and beta-genes

Molecular genetics studies have recently revealed complexity in the MHC class II region that has not been detected by previous serologic and genetic studies. In humans, three subregions, DP, DQ, and DR, of the class II genes as well as the DZ alpha and DO beta genes, have been extensively characterized. Although homologs of these human genes were identified in many species, their expressibility has not been well defined in species other than the mouse. We have previously cloned the rabbit homologs of the HLA-DP alpha and beta genes whose protein products had never been detected. The sequences of rabbit DP alpha 1 and DP beta genes are reported herein and they indicate that the rabbit DP genes encode functional alpha- and beta-chains. Unfavorable nucleotides surrounding the first AUG codon may, however, reduce the translational efficiency of the R-DP beta mRNA and explain the difficulty in generating serologic reagents specific for rabbit DP molecules. A complex mutation in the beta 1 domain of the R-DP beta gene was similar to the one found in the H-2A beta 1 gene of five strains of mice. The origin of this mutation is discussed.     

Molecular genetic analysis of the major histocompatibility complex in an ELA typed horse family

Restriction fragment length polymorphism was studied in an ELA typed horse family which included a stallion, a mare with two full-sibs, another mare with three full-sibs and, in addition, three paternal half-sibs. DNA samples from all individuals were investigated by Southern blot analysis using three restriction enzymes (EcoRI, HindIII or TaqI) and human cDNA class I, class II (DR beta) and class III (C4) probes. In addition, a genomic class II DQ alpha probe was used. Fragments hybridized with the various probes revealed the existence of DNA sequences homologous to HLA class I, DR beta, DQ alpha and C4 genes in the horse. Polymorphic fragments were found when DNA was hybridized with class I and class II probes irrespective of the enzyme used; but hybridization with the C4 probe did not reveal variability. All polymorphic fragments segregated according to the ELA serological specificities, thus indicating a close linkage between the different revealed subregions. Banding patterns suggest that the horse possesses about 20-30 class I genes, probably more than one DR beta and DQ alpha genes and possibly only one C4 gene. The high degree of polymorphism observed suggests that molecular DNA typing may represent a potentially powerful aid to decision in parentage control determination.     

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)     

Synergism of glucocorticoids with granulocyte macrophage colony stimulating factor (GM-CSF) but not interferon gamma (IFN-gamma) or interleukin-4 (IL-4) on induction of HLA class II expression on human monocytes.

Peripheral blood monocytes from up to 13 normal donors were stimulated with the cytokines interferon gamma (IFN-gamma), interleukin 4 (IL-4) and granulocyte macrophage-colony stimulating factor (GM-CSF) in the presence or absence of dexamethasone (Dex), and the effects on HLA class II (HLA-DR, DP and DQ) expression studied. Dex markedly augmented HLA-DR, DP and DQ levels induced by GM-CSF, in all samples tested. Particularly striking were the effects on HLA-DQ expression, since stimulation with a combination of Dex and GM-CSF induced markedly higher levels of HLA-DQ antigen than stimulation with IFN-gamma. Northern blot analysis of samples treated for 40 hours with Dex and GM-CSF indicated that levels of DR alpha, DP alpha and DQ alpha mRNA were also increased. In contrast, despite variation between individual donors, in general Dex weakly inhibited both constitutive and IFN-gamma- or IL-4-induced HLA-DR expression. Variability in the responsiveness of monocytes purified from individual donors to each cytokine was also observed. GM-CSF was less potent than IFN-gamma and IL-4, enhancing HLA class II expression in only seven of 13 donors tested, whereas in the presence of Dex all donors responded to GM-CSF. The differential effects of glucocorticoids in vitro suggest that these cytokines induce HLA class II expression by different mechanisms.     

Duplicated DQ haplotypes increase the complexity of restriction element usage in cattle

The MHC of cattle encodes two distinct isotypes of class II molecules, DR and DQ. Unlike humans, cattle lack the DP locus and about half the common haplotypes express duplicated DQ genes. The number and frequency of DQA and DQB alleles means that most cattle are heterozygous. If inter- and/or intrahaplotype pairing of DQA and DQB molecules occurs, cattle carrying DQ-duplicated haplotypes may express more restriction elements than would be predicted by the number of expressed alleles. We are investigating whether duplicated haplotypes cause differences in immune response, particularly in terms of generating protective immunity. We have analyzed the Ag-presenting function of DQ molecules in two heterozygous animals, one of which carries a duplicated haplotype. We compared the class II isotype specificity of T cell clones recognizing a putative vaccinal peptide from foot-and-mouth disease virus (FMDV15). We show for the first time that bovine T cells can recognize Ag in the context of DQ molecules. We also present evidence that interhaplotype pairings of DQA and DQB molecules form functional restriction elements. Both animals showed distinct biases to usage of particular restriction elements. Mainly DQ-restricted clones were derived from the animal with duplicated DQ genes, whereas the majority of clones from the animal with a single DQ gene pair were DR restricted. Furthermore, haplotype bias was observed with both animals. These experiments show that understanding of class II chain pairing in addition to knowledge of the genotype may be important in vaccine design where effective epitope selection is essential.     

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.