Analysis of a horse family with a crossing-over between the ELA complex and the A blood group system

A horse family in which a recombination occurred in the chromosome region coding for the serological specificities of the ELA complex and those of the A blood group system of a mare was further analysed by mixed lymphocyte reaction (MLR) and Southern blot hybridization. This family consisted of a stallion, a mare and five full sibs. The stallion and the mare were heterozygous for internationally recognized ELA specificities while only the mare was heterozygous for the A blood group system. MLR between all members of the family confirmed that the stallion possessed two different ELA haplotypes and suggested that recombination in the mare occurred outside the segment delimited by the ELA-A locus and the MLR region. DNA samples from all individuals were investigated by Southern blot analysis using three restriction enzymes (EcoRI, HindIII or TaqI), three human HLA probes (one of class I cDNA and two of class II probes), one cDNA (DR beta) and one genomic (DQ alpha). Class I and class II restriction fragments of the mare segregated in accordance to the ELA specificities and thus clearly confirming that the crossing-over did not occur between the ELA-A gene and the class I, class II region nor between DR beta and DQ alpha subsets. The A blood group genetic determinants would thus be situated outside the ELA region defined by class I and class II genes.     

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.     

Characterization of specific HLA-DQ alpha allospecificities by genomic, biochemical, and serologic analysis

Bgl II restriction endonuclease digestion of genomic DNA from lymphoblastoid cell lines homozygous for HLA DR and DQ serological specificities, followed by hybridization with a DQ alpha cDNA probe, identified a genomic polymorphism characterized by two reciprocal patterns, one associated with DR 3, 5 and 8 and the other with DR 1, 2, 4, 7, and 9. The former pattern corresponded precisely to the reactivity of monoclonal antibody SFR20-DQ alpha 5, shown by Western blotting to react with isolated alpha-chains, but not with beta-chains. Additional variants of the DQ alpha genes were identified by using a locus-specific oligonucleotide probe for the DQ alpha gene, indicating differences among the DQ alpha 5-negative set of alleles. This analysis defines a set of DQ alpha allelic markers that are distinct from the well-established DQ serologic specificities DQw1, 2, 3 or "blank." Although most DQ alpha 5+ cells carry the DRw52 specificity associated with the DR beta 2 gene, analysis of DQ alpha polymorphisms on DR5, DQw1; DR8, DQw1; and DRw13, DQw1 cells verified that this DQ alpha family of alleles was not invariably linked to the DR beta 2 locus.     

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.     

Selection, trans-species polymorphism, and locus identification of major histocompatibility complex class IIβ alleles of New World ranid frogs

Genes encoded by the major histocompatibility complex (MHC) play key roles in the vertebrate immune system. However, our understanding of the evolutionary processes and underlying genetic mechanisms shaping these genes is limited in many taxa, including amphibians, a group currently impacted by emerging infectious diseases. To further elucidate the evolution of the MHC in frogs (anurans) and develop tools for population genetics, we surveyed allelic diversity of the MHC class II β1 domain in both genomic and complementary DNA of seven New World species in the genus Rana (Lithobates). To assign locus affiliation to our alleles, we used a “gene walking” technique to obtain intron 2 sequences that flanked MHC class IIβ exon 2. Two distinct intron sequences were recovered, suggesting the presence of at least two class IIβ loci in Rana. We designed a primer pair that successfully amplified an orthologous locus from all seven Rana species. In total, we recovered 13 alleles and documented trans-species polymorphism for four of the alleles. We also found quantitative evidence of selection acting on amino acid residues that are putatively involved in peptide binding and structural stability of the β1 domain of anurans. Our results indicated that primer mismatch can result in polymerase chain reaction (PCR) bias, which influences the number of alleles that are recovered. Using a single locus may minimize PCR bias caused by primer mismatch, and the gene walking technique was an effective approach for generating single-copy orthologous markers necessary for future studies of MHC allelic variation in natural amphibian populations.     

Chicken cardiac tropomyosin and a low-molecular-weight nonmuscle tropomyosin are related by alternative splicing

We have isolated and characterized complementary DNAs (cDNAs) encoding chicken cardiac muscle tropomyosin and a low-molecular-weight nonmuscle tropomyosin. The cardiac muscle cDNA (pCHT-4) encodes a 284-amino acid protein that differs from chicken skeletal muscle alpha- and beta-tropomyosins throughout its length. The nonmuscle cDNA (pFT-C) encodes a 248-amino acid protein that is most similar (93-94%) to the tropomyosin class including rat fibroblast TM-4, equine platelet tropomyosin, and human fibroblast TM30pl. The nucleotide sequences of the cardiac and nonmuscle cDNAs are identical from the position encoding cardiac amino acid 81 (nonmuscle amino acid 45) through cardiac amino acid 257 (nonmuscle amino acid 221). The sequences differ both 5' and 3' of this region of identity. These comparisons suggest that the chicken cardiac tropomyosin and low-molecular-weight "platelet-like" tropomyosin are derived from the same genomic locus by alternative splicing. S1 analysis suggests that this locus encodes at least one other tropomyosin isoform.     

Joint Report of the Fifth International Workshop on Lymphocyte Alloantigens of the Horse, Baton Rouge, Louisiana, 31 October-1 November 1987

Six laboratories participated in the Fifth International Workshop on Lymphocyte Alloantigens of the Horse, testing 132 alloantisera against lymphocytes of 880 horses chosen to represent different families and breeds. Most of the alloantisera were produced by lymphocyte immunization between horses matched at the ELA-A locus. All horses were also tested with antisera contributed to the workshop by participating laboratories which identified ELA specificities A1-A10 and W12-W21. Previously identified workshop specificities ELA-W14, W15 and W19 were accepted as products of the ELA-A locus based on family and population studies by the workshop. Their designations were changed to ELA-A14, ELA-A15 and ELA-A19, respectively. Two new specificities were identified, namely ELA-W22 (W22) and ELA-W23 (W23). Population and family studies indicated that W22 and W23 as well as W13 are products of an ELA locus other than ELA-A. The presence of these specificities was correlated with the presence of certain ELA-A locus specificities, e.g. W13 with A3, W22 with A2 and W23 with A5. However, the association was not complete and W13, W22 and W23 also segregated with other ELA-A specificities in some families. Evidence for recombination was found between the ELA-A locus and the locus or loci encoding these specificities resulting in seven recombinant haplotypes found among the data presented in this workshop. Further studies are required for definitive assignment of the specificities to a class I or class II locus.     

Analysis of the equine lymphocyte antigen system by Southern blot hybridization

Fourteen Standardbred horses homozygous for one of six equine lymphocyte antigen (ELA) specificities (A1, A3, A4, A5, A6, or A10) were analyzed by Southern blot hybridization using DNA probes derived from the mouse major histocompatibility complex (MHC). Total genomic DNA from peripheral lymphocytes was digested with the restriction enzymes Hind III, Pvu II, or Eco RI. Twenty-three to thirty-three bands were generated for individual horses with the class I cDNA probe. The resulting band patterns revealed 12-14 nonpolymorphic fragments, which is consistent with the highly conservedQa/Tla genes seen in other species. The remaining 10–19 bands displayed significant polymorphism; no two animals had identical band patterns when studied with all three enzymes. The polymorpism was markedly decreased between animals of the same ELA serotypes. Unique bands were identified in both Al horses and all four A6 animals. Pvu II digestions of lymphocyte DNA were hybridized with mouse MHC class II probes. A cDNA probe for theE gene revealed only a single nonpolymorphic band. In contrast, a cDNA probe for theH-2 A locus displayed three to five strong bands in each animal with polymorphism that was most pronounced between horses of different ELA serotypes. Genomic DNA probes forAandE genes both revealed multiple polymorphic bands. However, cross-hybridization between these two probes prevented distinction betweenA andE equivalent loci. The reduced polymorphism evident within ELA specificities is consistent with the concept that the equine lymphocyte antigen system includes two families of closely linked MHC genes.     

Close association between DNA polymorphism of bovine major histocompatibility complex class I genes and serological BoLA-A specificities

Class I genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot hybridization and by serological analysis. A large number of class I restriction fragments and an extensive polymorphism were revealed when genomic DNA samples, digested with the restriction enzyme PvuII, were hybridized with a human cDNA probe. The result indicated the presence of multiple class I genes in cattle. The extensive restriction fragment length polymorphism (RFLP) was interpreted genetically by analysing five paternal half-sib families comprising, besides the bulls, 50 offspring and their dams. No less than 21 RFLP types were distinguished in this limited sample. The class I polymorphism was also analysed using a serological test with sera corresponding to four workshop specificities (w2, w6, w10 and w16) and three locally defined specificities (SRB1, SRB2 and SRB3). There was an excellent agreement between the two typing methods since no RFLP type was associated with more than one specificity and five of the seven specificities were associated with a single RFLP type. Evidence for close genetic linkage between class I and DQ class II genes was obtained since no recombinant was found among 45 informative offspring. Linkage disequilibrium among class I, DQ class II and C4 genes was also observed. The blood group specificity M' was completely associated with the w16 class I specificity and with the haplotype I1DQ1BC4(2) in this material.     

Patterns of variation in MHC class II beta loci of the little greenbul (Andropadus virens) with comments on MHC evolution in birds

We have isolated major histocompatibility complex (MHC) class II beta loci from the little greenbul (Andropadus virens), an African songbird. We utilized preexisting information about conserved regions of the avian MHC to design primers to amplify a pool of sequences representing multiple loci. From this pool, a unique locus spanning 1109 bp that we designate as Anvi-DAB1 was cloned and sequenced. We designed locus-specific primers based on this sequence information and amplified six alleles from seven individuals. Compared to other A. virens MHC sequences obtained from genomic DNA or cDNA, the variability of sequences from Anvi-DAB1 was low and the ratio of nonsynonymous to synonymous substitution was much less than one, suggesting that Anvi-DAB1 may either be a pseudogene or a nonclassical MHC locus. Phylogenetic analysis revealed that the Anvi-DAB1 locus was highly divergent when compared with other passerine or A. virens genomic or transcribed MHC sequences. The use of conserved MHC primers followed by analysis of cloned sequences allows rapid isolation of MHC loci from exotic species and avoids laborious large-scale cloning and sequencing.     

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.     

Identification of equine major histocompatibility complex haplotypes using polymorphic microsatellites

A system for identifying equine major histocompatibility complex (MHC) haplotypes was developed based on five polymorphic microsatellites located within the MHC region on ECA 20. Molecular signatures for 50 microsatellite haplotypes were recognized from typing 353 horses. Of these, 23 microsatellite haplotypes were associated with 12 established equine leucocyte antigen (ELA) haplotypes in Thoroughbreds and Standardbreds. Five ELA serotypes were associated with multiple microsatellite subhaplotypes, expanding the estimates of diversity in the equine MHC. The strong correlations between serological and microsatellite typing demonstrated a linkage to known MHC class I protein polymorphisms and validated this assay as a useful supplement to ELA serotyping, and in some applications, a feasible alternative method for MHC genotyping in horse families and in population studies.     

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.     

Genomic hybridization of bovine class II major histocompatibility genes: 1. Extensive polymorphism of DQα and DQβ genes

Summary. Class II genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot analysis using human cDNA probes for DQα, DQβ, DRβ and DRβ. The presence of a DQ-like and a DR-like subregion in cattle was clearly indicated. Highly polymorphic restriction fragment patterns were obtained when genomic DNA, digested with any one of the Bam HI, Eco RI or Pvu II restriction enzymes, was hybridized with the DQα and the DQβ probe. The polymorphisms were interpreted genetically by analysing five paternal half-sib families of the Swedish Red and White breed. The material comprised, besides the bulls, 28 offspring and their dams. The analysis resolved 9 and 12 allelic variants of DQα and DQβ respectively. Thus, this investigation establishes a method for routine typing of MHC class II gene polymorphism in cattle. The results were entirely consistent with close linkage of DQα and DQβ since no recombinant was found and since alleles at these loci occurred in complete linkage disequilibrium in the material investigated. Close linkage between DQ and the blood group locus M, which has previously been found to be closely linked to the serologically defined BOLA-A locus, was also indicated. In this study DNA was isolated from frozen semen samples of dead bulls, which shows that this type of analysis will be useful in genetic investigations in cattle breeds, where artificial insemination is practised.