Polymorphisms within the HLA-DRw6 haplotype. I. Restriction fragment length variation and its correlation with serology

The Dw6/DRw6 complex, one of the MHC class II specificities that can be defined by cellular techniques and by serology, probably has one or more immunoregulatory functions. To obtain information on the molecular structure of the DRw6 region, we studied several DRw6 homozygous cell lines, of which three were of consanguineous origin. DNA-DNA hybridization comprised the use of seven restriction enzymes in combination with three DR beta cDNA probes. The obtained results were compared with similar analyses of an HLA homozygous cell panel, expressing DR1-w8 specificities. This comparison indicated that in DRw6 homozygous individuals the coding potential for DR beta chains resembles closely that of all other DR specificities, thus identifying DRw6 as a regular DR region. In addition, we found a restriction fragment length pattern unique for DRw6, indicating the possibility to type for DRw6 by DNA-DNA hybridization. Comparisons within the DRw6 cell panel revealed the occurrence of several HLA class II DNA subtypes. These subdivisions partly correlated with serologically obtained reaction patterns. No correlation, however, could be observed between the different DNA subtypes and cellular reaction patterns as obtained by MLC and T cell cytotoxicity.     

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.     

Molecular mapping class II polymorphisms in the human major histocompatibility complex. II. DQ beta

The restriction fragment length polymorphisms have been determined for six restriction enzymes (Bam HI, Bg1 II, Eco RI, Hinc II, Hind III, and Pvu II) and a DQ beta probe on 25 cell lines that are homozygous by consanguinuity at the MHC. These patterns reflect both DR haplotypes and DQ types of the cells tested. At least one non-polymorphic band is present in all the cell lines with every restriction enzyme except Hinc II. This band most probably represents DX beta hybridization. The polymorphic bands indicate that more polymorphism exists in the DQ subregion than is predicted serologically. Each DR haplotype is associated with a unique set of restriction fragments except for DR2 and DR6. The patterns are largely consistent within each DR haplotype. In addition, some bands reflect the established DQ specificities DQw1 and DQw2. Individual bands can be identified that are unique to the haplotypes DR1, DR4, DR5, and DR6 and the DQw1- and DQw2-associated haplotypes. Subdivisions of haplotypes can be identified with this probe. In particular, MVL (DR1), Akiba (DR2), QBL (DR3), FPF (DR5), and APD (DR6) have polymorphisms that distinguish them from other members of their DR haplotype.     

A novel association of DQ alpha and DQ beta genes in the DRw10 haplotype. Determination of a DQw1 specificity by the DQ beta-chain

The association of the class II genes of the DRw10 haplotype from a cell line, NASC, initiated from a member of a well characterized family, was analyzed by sequencing cDNA clones corresponding to DR beta I, DQ alpha, and DQ beta genes. An identical haplotype was also identified in the Raji cell line. In addition to typing as DRw10 and DQw1 with HLA typing sera both, the NASC and Raji cell lines were shown to react strongly with the monoclonal antibodies 109d6 (specific for DRw10 beta 1 and DRw53 beta 2 gene products) and Genox 3.5.3 (specific for DQw1) and exhibited the restriction fragment length polymorphism indicative of a DRw10, DQw1 haplotype. The DR beta 1 gene corresponding to the DRw10 specificity was found to have a first domain sequence different from all other DR beta I genes. Sequence analysis of the 3'-untranslated region of this DR beta-chain gene showed a significant divergence from the 3' untranslated region of the DRw53 family of haplotypes and a lesser divergence from that of the DRw52 and DR1/DR2 families. The sequence of the DQ beta genes corresponding to the DQw1 specificity in the DRw10 haplotype was found to be identical to the DQ beta gene from a DR1, DQw1 haplotype. Surprisingly, however, the DQ alpha gene did not resemble other DQw1-like DQ alpha genes, but was identical in sequence to the DQ alpha gene found in DR4 haplotypes. The novel association of DQ alpha and DQ beta genes in the DRw10 haplotype revealed in these studies may result from a double recombinational event. More consequentially, these studies strongly suggest that the DQw1 specificity recognized by Genox 3.5.3 is determined by the DQ beta chain and is not affected by the DQ alpha-chain.     

Recombination sites in the HLA class II region are haplotype dependent

We have analyzed DNA sequence polymorphisms of DQ alpha and DQ beta chains from three haplotypes from the DRw52 family: DR5 DQw1 (FPA, GM3106), DRw6 DQw1 (CB6B, 10w9060), and DRw6 DQw3 (AMALA, 10w9064). The results indicate that the DR5 DQw1 and DRw6 DQw1 haplotypes have arisen by recombination between the DR beta 1 and DQ alpha loci. This contrasts with our previous analysis of DR4 DQ"Wa", DR3 DQ"Wa", and DR7 DQw3 haplotypes, all of which appear to have arisen by virtue of recombination between DQ alpha and DQ beta. Thus, there appear to be at least two different sites where recombination has occurred within the DR and DQ subregions. These differing patterns of recombination were interpreted in the context of the three major family groups of class II haplotypes, the DRw53, DRw52, and DR1/2 haplotype families. The data indicate that haplotypes from these family groups tend to undergo recombination at different locations. We propose that these differences in site of recombination are a reflection of differences in the molecular organization of the haplotypes belonging to each family group.     

HLA-DR typing "at the DNA level": RFLPs and subtypes detected with a DR beta cDNA probe

The HLA-DR beta gene, used as a hybridization probe, detects RFLPs that correlate with HLA-DR specificities. Using genomic DNA from more than 200 individuals, we have carried out a population study with a cDNA probe for the DR beta chain, which, under appropriate conditions, does not cross-hybridize with genes from other HLA-D subregions (e.g., DP and DQ). We first assessed the correspondence between serologically defined HLA-DR types and DNA patterns obtained after digestion with TaqI and found that DNA patterns allowed us to identify most specificities. Only two pairs of antigens are not distinguishable: with the DR beta probe alone we cannot distinguish DR3 from DRw6 or DR7 from DRw9. However, the correct assignment can always be made for the first pair by hybridizing the same digests with a DQ alpha or DQ beta probe. Thus DR typing from the DNA patterns is practical and accurate. We also looked for serologically undetectable subtypes. RFLPs revealed high-frequency subtypes for the specificities DR 2, 3, 5, w6, 7, and w9. Some of these are more accurately viewed as variant haplotypes, since the relevant variation is probably not at the DR beta locus that determines the serological specificities but rather at other closely linked and highly homologous DR beta loci such as DR beta-III. Nevertheless, the existence of variant haplotypes for so many specificities indicates a wealth of polymorphic variation beyond that detected serologically and provides more specific markers for studies of various diseases associated with HLA-DR specificities.     

Evolution of the HLA-DR1 gene family. Structural and functional analysis of the new allele "DR-BON".

The molecules of the MHC are highly polymorphic and involve in Ag presentation; their striking genetic polymorphism allows probable interactions with a large variety of antigenic fragments when these are presented to the TCR. It is therefore of interest to explore the extent of this polymorphism and the mechanisms of its generation. We have studied the class II HLA-DR blank allele DR-BON that has been previously defined by MLR, restriction fragment length polymorphism, and two-dimensional gel electrophoresis. A cDNA library was constructed from a DR-BON homozygous typing cell and cDNA corresponding to DR alpha- and DR beta-chains were sequenced. By comparison with other known alpha- and beta-chain sequences it is shown that the alpha-chain is invariant and the beta-chain differs from DR1 by only six nucleotides, clustered in the third variable region with three amino acid changes at position 67, 70, and 71. The short DNA stretch of sequence encoding the 67-71 region is also present in other DR alleles: DR4/Dw10, DRw13, and some DRw11 specificities. Therefore we propose that a gene conversion-like event has occurred between the DRB1 *0101 (DR1/Dw1) gene and one of these three DRB1 genes. Extensive typing has been performed with a DR-BON-specific 17-mer oligonucleotide. Cross-hybridization with other genes than the ones expected from DNA sequence comparison was not observed. A selected panel of DR-BON reactive T cell clones shows three patterns of reactivity. Some clones are strictly DR-BON specific; some cross-reacted with DRw13 and a few cross-reacted with other haplotypes. The role of different epitopes of the third variable region of HLA-DR beta chain in allo-reaction is discussed.     

Structural relationships between the DR beta 1 and DR beta 2 subunits in DR4, 7, and w9 haplotypes and the DRw53 (MT3) specificity

The class II molecules of DR4, DR7, and DRw9 haplotypes were analyzed by immunoprecipitation, followed by two-dimensional gel electrophoresis and N-terminal amino acid sequencing. By using HLA-DR chain-specific monoclonal antibodies, two distinct DR beta-chains were identified. One beta-chain, designated DR beta 2, had a characteristic acidic mobility. In all three DR types the DR beta 2-chains were indistinguishable by two-dimensional gel electrophoresis and partial N-terminal sequencing. A second DR beta-chain designated beta 1 had a more basic mobility on two-dimensional gel electrophoresis, and differed from the DR beta 2-chains by the consistent presence of phenylalanine at position 18. In contrast to the DR beta 2-chains, the DR beta 1-chains were clearly polymorphic, with specific amino acid sequence differences characteristic of each DR type. The monoclonal antibodies 109d6 and 17-3-3S, recognizing distinct polymorphic epitopes similarly correlated with the DRw53 allospecificity, were found to react with different DR beta-chains. The epitope recognized by monoclonal antibody 109d6 was identified on the DR beta 2-chain in the prototypic DR4, DR7, and DRw9 cell lines. However, the DR7, Dw11, DQw3 cell line BEI was unreactive with antibody 109d6 by either immunofluorescence or immunoprecipitation despite the presence of the DRw53 allodeterminant on this cell line. The other DRw53-like monoclonal antibody, 17-3-3S, reacted with the DR beta 1-rather than the DR beta 2-chain in all DR4 and DR7 cell lines tested, including the cell line BEI. However, antibody 17-3-3S did not react with the DRw53-positive DRw9 cell line ISK. These studies suggest that the DRw53 allospecificity is more complex than previously thought and may comprise a number of distinct epitopes encoded by two different DR beta loci.     

DNA typing of HLA-DR β chain genes can discriminate between undetected alleles and real homozygotes

The polymorphism of HLA-DR antigens has been studied by Southern blot hybridization under conditions specific for the detection of the DR chain genes. Haplotype-specific patterns were defined with DNA from DR1, 2, 3, 4, 7, w8, w11, w12, and W13 homozygous typing cells, with restriction enzymes Eco RI, Bgl I, and Pvu II. Certain serological specificities, such as DR2, DR3, and DR7, can be encoded by distinct allelic forms of DR chain genes. The procedure of DNA typing was applied to family analysis of individuals expressing only a single DR specificity upon serological typing. Three cases are described here: (1) in family GR, phenotypic DR 7 homozygotes correspond to genomic heterozygotes, and a novel DR7 allele is described: (2) in family RU, the genes corresponding to a serologically undetected (blank) DR allele were identified by restriction fragment length polymorphism (RFLP); this novel DR haplotype has an RFLP pattern similar to those of the DRw52 family, even though this specificity was not expressed on the DR-blank lymphocytes; (3) in family RG, there is no blank allele, but a homozygote RFLP situation at the DR subregion.     

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 of the molecular specificities of anti-class II monoclonal antibodies by using L cell transfectants expressing HLA class II molecules

Expressible HLA class II alpha- and beta-chain cDNA were used for DNA-mediated gene transfer to produce L cell transfectants expressing single types of human class II molecules. Cloned transfectants expressing nine different class II molecules were isolated: DR alpha: DR1 beta I, DR alpha: DR4 beta I, DR alpha: DR5 beta I, DR alpha: DR5 beta III (DRw52), DR alpha: DR7 beta I, DR alpha: DR4/7 beta IV (DRw53), DQ7 alpha: DQw2 beta, DQ7 alpha: DQw3 beta, and DPw4 alpha: DPw4 beta. These class II-expressing transfectants were used to analyze by flow cytometry the molecular specificities of 20 anti-class II mAb. These analyes indicate that some mAb are more broadly reactive than was previously thought based on immunochemical studies. In contrast, the narrow molecular specificities of other anti-class II mAb were confirmed by this approach. Transfectants expressing human class II molecules should be valuable reagents for studies of B cell and T cell defined epitopes on these molecules.     

Analysis of DR beta and DQ beta chain cDNA clones from a DR7 haplotype

A cDNA library was constructed from a DR7, DRw53, DQw2 homozygous cell line, cDNA clones corresponding to DR beta and DQ beta chains were isolated, and the nucleotide sequences of the polymorphic first domains of these chains were determined. A novel screening strategy allowed rapid and simple identification of cDNA clones corresponding to both DR beta chains (DR7 beta1 and DR7 beta2): DR7 beta2 clones have a recognition site for the enzyme BssHII, whereas DR7 beta1 clones do not. The DR7 beta 1 sequence differs significantly from all previously described DR beta chains. As predicted by the presence of the BssHII site in DR7 beta 2 clones, the DR7 beta 2 sequence differs from the DR7 beta 1 sequence. The sequence of the DRw53-associated DR7 beta 2 chain is identical to the reported sequence of the DRw53-associated DR4 beta 2 chain. In addition, the sequence of the DQ beta chain from the DR7, DQw2 cell line is identical to the reported sequence of a DQ beta chain from a DR3, DQw2 cell. These findings raise interesting questions about the evolution of the DR3, DR4, and DR7 haplotypes.     

Molecular analysis of the HLA class II genes in two DRw6-related haplotypes, DRw13 DQw1 and DRw14 DQw3

We have compared the sequence polymorphism of HLA class II genes of two distinct DRw6 haplotypes. cDNA libraries were constructed from two lymphoblastoid cell lines: CB6B (10w9060) which types as DRw13 DQw1, and AMALA (10w9064) which types as DRw14 DQw3. Multiple sequence differences were found at the DR beta I, DQ alpha, and DQ beta loci when these two haplotypes were compared. The DR beta I allele found in the DRw14 DQw3 haplotype appears to have diverged primarily as a result of a gene conversion event with a DR1 allele acting as donor. In contrast, the DRw13 DQw1 haplotype appears to have arisen by means of a recombination event between the DR and DQ subregions. Thus, multiple genetic mechanisms, including point mutation, gene conversion, and recombination, have generated diversity among DRw6 haplotypes.     

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.     

HLA-DR beta genes vary in number between different DR specificities, whereas the number of DQ beta genes is constant

Probes isolated from DR and DQ beta cDNA and genomic clones were used in hybridizations to restriction enzyme-digested DNA from human homozygous typing cells (HTC) as well as other DR homozygous cells in order to estimate the number of beta genes in the DR/DQ class II region. Varying numbers of DR beta genes were found in HTC of different DR specificities, from possibly one in DR 8 cells to three in cells of DR 2 to 7. The DR beta genes of different specificities seem to be related to one another in a distinct fashion. In contrast, all HTC contain two DQ beta genes per chromosome. The restriction site polymorphism of DQ beta genes is considerably more extensive than that of DQ serology, although one of the genes seems to be nonpolymorphic. In addition to the two DP beta genes identified previously, a minimum of three to five DQ and DR beta genes exist in the human haploid genome.     

Joint Report of the Fourth International Bovine Lymphocyte Antigen (BoLA) Workshop, East Lansing, Michigan, USA, 25 August 1990

Blood samples from 54 animals were exchanged between 15 laboratories in nine countries to improve and expand BoLA class I and class II typing. A total of 27 out of 33 (82%) of previously accepted BoLA-w specificities were represented within the cell panel. Seventeen new serum-defined BoLA specificities were accepted by the workshop participants, thus expanding the number of internationally recognized BoLA specificities to 50. The large number of new specificities detected resulted from the number of serological reagents used (n = 1139) and the genetic diversity of the cell panel. Confidence derived from the high percentage of agreement between the laboratories on antigen detection (97.3%; r = 0.84) permitted the removal of the workshop (w) notation from 23 BoLA-w specificities and their acceptance as full status BoLA-A antigens. Two new non-BoLA antigens were also detected, one completely included within the red blood cell factor S' (BoLy-S'), whereas a second (BoLy-w1) did not show any association with tested red blood cell factors. A comparison between serological, isoelectric focusing (IEF) and DNA typing for BoLA class II polymorphism was conducted with a subset of workshop cells. Correlation between the three methods was significant for three combinations of alleles. Three other serologically defined class II specificities were correlated with DR and/or DQ restriction fragment length polymorphism (RFLP) types, whereas six additional IEF types were correlated with DR and/or DQ RFLP types (r greater than or equal to 0.50). Several new IEF, DRB, DQA and DQB RFLP patterns were identified. In 46 animals that were typed for BoLA-DR and DQ genes by RFLP analysis, 46 different BoLA haplotypes were tentatively defined. These 46 haplotypes were distinguished by 31 serologically-defined BoLA-A alleles (and 2 'blanks'), 15 DRB RFLP types (plus up to 10 new DRB RFLP patterns) and 23 DQA-DQB haplotypes.     

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

Human HLA cDNA probes were used to analyze the restriction fragment length polymorphism (RFLP) of the SLA major histocompatibility complex in swine. Cellular genomic DNA from 19 SLA homozygous pigs representing 13 different haplotypes was digested with restriction endonucleases Eco RI, Hind III, or Bam H1, separated by electrophoresis, and transferred onto diazobenzyloxymethyl paper by the Southern blot technique. The blots were probed with ³²P-labeled class I or beta-DR class II cDNA. Depending on the haplotypes and the endonucleases used, seven to ten restriction fragments hybridized with the class I probe, and five to seven with the beta-DR probe. Their sizes ranged from 3.4 to 22 kilobase-pairs. Few bands were common to all 13 haplotypes. With all but one haplotype, identical autoradiogram patterns were obtained from unrelated, but phenotypically SLA-identical pigs, suggesting that most of the RFLP revealed were controlled by the SLA region. Further polymorphism was found in a group of seven unrelated pigs which typed serologically as SLA A15 CI B18 homozygotes but could be divided into two subgroups, with five animals in one subgroup and two in the other, when the genomic DNA was hybridized with the class I probe. When the class 11 beta-DR probe was tested on the same seven pigs, another subdivision was seen, and this correlated with MLR data. These results demonstrate that HLA class I and class II probes can be used to identify certain well-established SLA haplotypes and to identify subclasses within at least one SLA haplotype.Abbreviations MHC major histocompatibility complex - MLR mixed lymphocyte reaction - kbp kilobase pair(s) - RFLP restriction fragment length polymorphism     

Two divergent routes of evolution gave rise to the DRw13 haplotypes

The HLA class II genes and haplotypes have evolved over a long period of evolutionary time by mechanisms such as gene conversion, reciprocal recombination and point mutation. The extent of the diversity generated is most clearly evident in an analysis of the HLA class II alleles present within DRw13 haplotypes. This study uses cDNA sequencing to examine the first domains of DRB1, DRB3, DQA1, and DQB1 alleles from several American black individuals expressing seven different DRw13 haplotypes, five with undefined HLA-D specificities (i.e., not Dw18 or Dw19). Two new DRw13 alleles described in this study are the first examples of convergent evolution of DR alleles in which gene conversion has apparently combined segments of DRB1 alleles encoding DRw11 and DRw8 to generate two new DRB1 alleles, DRB1*1303 and DRB1*1304, that encode molecules bearing serologic determinants of a third allele, DRw13. These new DRw13 alleles are found embedded in haplotypes of DRw11 origin distinct from haplotypes encoding previously identified DRw13 alleles, DRB1*1301 and DRB1*1302. These data suggest that two evolutionary pathways may have given rise to two subgroups of alleles encoding molecules that share DRw13 serologic determinants yet which possess different structural and, likely, functional motifs. Reciprocal gene recombination events resulting in different DR, DRw52 and DQ allele combinations also appear to have played a crucial role in augmenting the level of diversity found in DRw13 haplotypes. Recombination has resulted in the association of one of the new DRw13 alleles with a DQw2 allele normally found associated with DR7 and the association of the DRw52c-associated DRw13 allele (DRB1*1302) with three different DQw1 alleles. The seven DRw13 haplotypes that have resulted from the effect of recombination on haplotypes formed by the two pathways of DRw13 allelic diversification have resulted in different repertoires of class II molecules and, most likely, different immune response profiles in individuals with these haplotypes.     

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.     

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.