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.     

HLA-DR4-associated haplotypes are genotypically diverse within HLA

Biochemical diversity among products of class II HLA genes has been observed in individuals who appear to be HLA-D and DR-identical by cellular and serologic typing. We used techniques of restriction enzyme fragment analysis by Southern blotting to analyze this diversity at the level of cellular DNA. A panel of 17 HLA-DR4 homozygous cell lines (HCL) were investigated by using cDNA probes homologous to DQ beta, DQ alpha, and DR beta genes. Each probe was hybridized to cellular DNA digested with a series of different restriction endonucleases. Polymorphisms were observed with the use of the enzymes Pst I, Hind III, and Bam HI: Hybridization of cellular DNA digested with Hind III and Pst I with the DQ beta probe revealed specific polymorphisms, as did hybridization of the Pst I digest with the DQ alpha cDNA probe and the Bam HI digest with the DR beta probe. The observed differences fall into two categories: first, considerable diversity was seen between HLA-DR4 HCL that represent different HLA-D-defined haplotypes; second, diversity was also observed among HCL of the same DR4-associated HLA-D cluster. In contrast to the DQ cDNA probes, hybridization with the DR beta probe revealed relatively limited polymorphism by using a panel of different restriction endonucleases. Thus, although there is a general pattern of polymorphic restriction enzyme fragments homologous to DQ probes within an HLA-D cluster, the pattern seen for any particular cell line was not sufficiently distinct to assign an HLA-D or DR specificity.     

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)     

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.     

The major histocompatibility complex of tassel-eared squirrels

The extent of polymorphism and the rate of divergence of class I and class II sequences mapping to the mammalian major histocompatibility complex (MHC) have been the subject of experimentation and speculation. To provide further insight into the evolution of the MHC we have initiated the analysis of two geographically isolated subspecies of tassel-eared squirrels. In the preceding communication we described the number and polymorphism of TSLA class I and class II sequences in Kaibab squirrels (S. aberti kaibabensis), which live north of the Grand Canyon. In this report we present a parallel analysis of Abert squirrels (S. aberti aberti), which live south of the Grand Canyon in northern Arizona. Genomic DNA from 12 Abert squirrels was digested with restriction enzymes, electrophoresed, blotted, and hybridized with DR alpha, DR beta, DQ alpha, DQ beta, and HLA-B7 probes. The results of these hybridizations were remarkably similar to those obtained in Kaibab squirrels. The majority of class I and class II bands were identical in size and number, suggesting that Abert and Kaibab squirrels have not significantly diverged in the TSLA complex despite their geographical separation. Relative polymorphism of class II sequences was similar to that observed with Kaibab squirrels: beta sequences exhibited higher polymorphism than alpha sequences. As in Kaibab squirrels, a number of alpha and beta sequences were apparently carried on the same fragments. In comparison to class II beta sequences, there was limited polymorphism in class I sequences, although a diverse number of class I genotypes were observed. Attempts to identify segregating TSLA haplotypes were futile in that the only families of sequences with concordant distributions were DQ alpha and DQ beta. These observations and those obtained with Kaibab squirrels suggest that the present-day TSLA haplotypes of both subspecies are derived from a limited number of common, progenitor haplotypes through repeated intra-TSLA recombination.     

Polymorphic class II sequences linked to the rat major histocompatibility complex (RT1) homologous to human DR and DQ sequences

Until recently, the analysis of Class II genes linked to the rat major histocompatibility complex, RT1, has been confined to serologic and electrophoretic analysis of their gene products. To obtain a more definitive estimate of the number and relative polymorphism of RT1 Class II sequences, we performed Southern blot analysis of rat genomic DNA employing human cDNA probes specific for Class II heavy and light chain genes. Southern blots of EcoRI and BamHI digests of genomic DNA from ten inbred strains, expressing eight RT1 haplotypes, were hybridized with the human DQ beta or DR beta cDNA that are homologous to Class II light chain sequences. Four to eight bands were observed to hybridize with the light chain cDNA: band sizes ranged from 2.5 to 28 kb. Restriction fragment patterns were polymorphic; the only identical patterns observed were those associated with RT1 haplotypes with identical RT1.B regions. The number and size of bands hybridizing with DQ beta and DR beta suggested a minimum of four light chain sequences in each haplotype. Southern blots of BamHI and EcoRI digests of genomic DNA from the same strains were hybridized with a DR alpha cDNA that is homologous to Class II heavy chain sequences. All RT1 haplotypes expressed either a 10.0-kb or 13.0-kb band when digested with BamHI, and either a 17-kb or 3.7-kb band when digested with EcoRI. Considerably less polymorphism was detected with the DR alpha probe; this observation is consistent with previously reported limited protein polymorphism of the rat equivalent of the I-E alpha subunit. The size and number of bands hybridizing with the DR alpha probe suggests a minimum of two heavy chain sequences. These observations suggest that the RT1 complex includes more Class II sequences than have been observed in serologic and electrophoretic analyses of Class II gene products. Furthermore, the level of polymorphism of RT1 Class II sequences appears to be comparable with mouse and human Class II sequences.     

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.     

Mapping of the SLA complex of miniature swine: mapping of the SLA gene complex by pulsed field gel electrophoresis.

The overall order of the regions of the swine major histocompatibility complex (MHC), the SLA complex, was determined by pulsed field gel electrophoresis (PFGE). It was found that the order of the regions is class II-class III-class I. A class I probe hybridized to a 420 kb Mlu I and a 420 kb Not I fragment as did a class III probe for C2. None of the class II probes hybridized to these fragments. Thus, linkage of class I to class III was shown. The class III C2, Bf, and C4 genes were found to residue in a 190 kb Not I fragment. Linkage of class III and class II genes was shown when both the class III C4 and the class II DR probes hybridized to the same 195 kb Sac II and 340 kb Not I fragments. The class I probe did not hybridize to these fragments. The order of the regions, class II-class III-class I, is similar to that of human MHC genes and may have been conserved in evolution so that coordinated expression of MHC genes could be achieved.     

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.     

Analysis of the rat major histocompatibility system by Southern blot hybridization

The organization of the rat major histocompatibility complex, RT1, was studied at the DNA level by Southern blot hybridization. Genomic DNA from eight different RT1 congenic rat strains was digested by various restriction enzymes and was hybridized under stringent conditions with probes of mouse class I and class II H-2 genes. Few cross-hybridizing DNA fragments, showing no polymorphism, were seen with class II A alpha and A beta probes. The class I probes allowed for the distinction of about 8 to 19 cross-hybridizing bands, which exhibited extensive polymorphism. With the use of five RT1 recombinants, about 20% of the DNA fragments could be mapped to the RT1.A region, which codes for the ubiquitously expressed class I antigens, and about 80% to the RT1.C region-determining class I-like antigens, which are different from RT1.A antigens with respect to tissue distribution, restriction function in immune responses, and allograft rejection. The number of class I genes present in the rat genome and the possible relationship of RT1.C to H-2Qa, Tla of the mouse are discussed.     

RFLP analysis of HLA-DR and -DQ genes and their linkage relationships in the Pacific

Human genomic DNA samples from Melanesians, Micronesians, and Caucasoids of known HLA-DR type were examined with cDNA probes for HLA-DR alpha, -DR beta, -DQ alpha, and -DQ beta chain genes. DR beta hybridizations with TaqI-digested DNA did not detect any new DR specificities in the Pacific. However, within the DR5 specificity a common DNA subtype was found in Pacific Islanders that was not seen in Caucasoids. Altogether, four DNA subtypes of DR5 are described. With the DQ alpha and DQ beta probes, significantly more variation could be demonstrated between populations. For example, DR2 was associated with a DQ beta TaqI pattern in the Pacific that was very rare in Caucasoids and additional RFLP analysis with other enzymes showed that this pattern is probably associated with the Dw12 subtype of DR2. DRw8-positive samples showed two different DQ alpha TaqI patterns, and these correlated with DQw1 and DQw3 specificities. DR alpha hybridizations with BglII-digested DNA also revealed different linkage relationships of the HLA-class II region genes between Pacific and Caucasoid specimens. The different population linkage disequilibrium relationships have permitted tentative assignment of TaqI fragments to either the DR beta 1 or DR beta 2 genes and are highly suggestive that the DQw1 specificity is encoded by the DQ alpha chain gene. This study shows the value of population comparisons in contributing to knowledge of the genetic organization of the genome.     

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.     

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.     

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.     

Genomic hybridization of bovine class II major histocompatibility genes: 2. Polymorphism of DR genes and linkage disequilibrium in the DQ-DR region

Class II genes of the bovine major histocompatibility complex have been investigated by Southern blot analysis using human cDNA probes for DQ alpha, DQ beta, DR alpha and DR beta. In this report restriction fragment length polymorphisms of DR alpha and DR beta are described. The polymorphisms were interpreted genetically by analysing five paternal half-sib families of the Swedish Red and White Breed, comprising altogether 28 offspring. Using the restriction enzymes BamHI, EcoRI and PvuII, three DR alpha and three DR beta allelic fragment patterns were resolved. The DR alpha and DR beta genes thus appear to be much less polymorphic than the previously described DQ alpha and DQ beta genes. Also, the observed linkage disequilibrium between DR genes was less pronounced than that between DQ genes, whereas the association between DR and DQ haplotypes was very strong. The family data available indicated strongly that the DQ alpha, DQ beta, DR alpha and DR beta genes are all closely linked.     

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.     

Polymorphism of the HLA-D region in American blacks. A DR3 haplotype generated by recombination

The polymorphism of HLA class II molecules in man is particularly evident when comparisons between population groups are made. This study describes a DR3 haplotype commonly present in the American black population. Unlike the Northern European population in which almost all DR3 individuals are DQw2, approximately 50% of DR3-positive American blacks express a serologically undefined DQ allelic product. DNA restriction fragment analysis with the use of several unrelated individuals and an informative family has allowed us to identify unique DQ alpha- and beta-fragments associated with the DR3, DQw- haplotype. Based on fragment size, the DQ alpha genes of the DR3, DQw- and DRw8, DQw- haplotypes are similar as are the DQ beta genes of DR3, DQw-; DRw8, DQw-; and DR4, DQw- haplotypes. In addition, a DX beta gene polymorphism has been identified which is associated with some DR3 haplotypes including the American black DR3, DQw- haplotype. cDNA sequence analysis has revealed a DQw2-like alpha gene and a DQ beta gene which is similar to that previously described for a DR4, DQw- haplotype. It is postulated that recombination between DQ alpha and DQ beta genes and between the DQ and DX subregions has generated the various DR3 haplotypes and has played an important role in creating diversity in the HLA-D region.     

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.     

Restriction fragment length polymorphism of the major histocompatibility complex of the dog

Human major histocompatibility complex (HLA) cDNA probes were used to analyze the restriction fragment length polymorphism (RFLP) of the DLA-D region in dogs. Genomic DNA from peripheral blood leucocytes of 23 unrelated DLA-D-homozygous dogs representing nine DLA-D types (defined by mixed leucocyte reaction) was digested with restriction enzymes (Bam HI, Eco RI, Hind III, Pvu II, Taq I, Rsa I, Msp I, Pst I, and Bgl II), separated by agarose gel electrophoresis, and transferred onto Biotrace membrane. The Southern blots were successively hybridized with radiolabeled HLA cDNA probes corresponding to DR, DQ, DP, and DO beta genes. The autoradiograms for all nine enzyme digests displayed multiple bands with the DRb, DQb, and DPb probes while the DOb probe hybridized with one to two bands. The RFLP patterns were highly polymorphic but consistent within each DLA-D type. Standard RFLP patterns were established for nine DLA-D types which could be discriminated from each other by using two enzymes (Rsa I and Pst I) and the HLA-DPb probe. Cluster analysis of the polymorphic restriction fragments detected by the DRb probe revealed four closely related supertypic groups or DLA-DR families: Dw3+Dw4+D1, Dw8+D10, D7+D16+D9, and Dw1. This study provides the basis for DLA-D genotyping at a population level by RFLP analysis. These results also suggest that the genetic organization of the DLA-D region may closely resemble that of the HLA complex.     

Restriction fragment length polymorphisms in bovine major histocompatibility complex class II ß-chain genes using bovine exon-containing hybridization probes

Restriction fragment length polymorphisms (RFLPs) have been identified in the bovine MHC class II region using five hybridization probes constructed from two bovine genomic clones. Four probes were constructed from a bovine DR beta-like gene, BoLA-DRB2. These included a probe containing the complete beta 1 exon (R2-beta 1), a probe containing the last 129 base pairs of the beta 2 exon (R2-beta 2), a probe containing intron immediately 5' of the beta 2 exon (R2-5' beta 2), and a probe containing the complete transmembrane exon (R2-TM). A fifth probe was constructed from a novel bovine beta-chain gene, BoLA-DIB, and contained the entire TM exon (I1-TM). R2-beta 1 defined very little polymorphism. R2-beta 2 hybridized to several fragments but one or two fragments hybridized much stronger on all Southern blots and it was presumed these corresponded to BoLA-DRB2 fragments. By using R2-5' beta 2 as a probe, these BoLA-DRB2 fragments were confirmed: 6.4 and 2.7-kb Eco RI alleles, 1.7- and 1.5-kb Pvu II alleles, 5.9-, 5.4-, 3.7- and 1.9-kb TaqI alleles, and a non-polymorphic 22.5-kb BamHI fragment. I1-TM identified three alleles with TaqI. To investigate the linkage between the RFLP alleles, 166 offspring of five sires were tested. Complete linkage was found for all RFLPs identified with the BoLA-DRB2 probes. However, the RFLP patterns of 13 calves out of 58 indicated recombination between BoLA-DRB2 and BoLA-DIB.