RFLP analysis of theHLA-, ChLA-, andRhLA-DQ alpha chain gene regions: Conservation of restriction sites during evolution

Genomic DNA samples, derived from a panel of 60 chimpanzees and 45 rhesus monkeys, were digested with the restriction enzymesTaq I andBgl II and hybridized with an HLA-DQ alpha chain cDNA probe. The results were compared with the data available on a human reference panel. Use of the restriction enzymeTaq I and the DQ alpha chain probe allows the detection of fiveHLA-DQA1 and twoHLA-DQA2 gene-associated fragments within the human population. For the ChLA and RhLA systems, 3 and 7 different DQA1-associated restriction patterns were detected, respectively, while for the chimpanzee a nonpolymorphicDQA2 (DX alpha) gene-associated fragment was also observed. The equivalent of theHLA- andChLA-DQA2 genes appears to be absent in the rhesus monkey. TheChLA-DQA1 and-DQA2 gene-associated RFLP patterns are identical in man and chimpanzee, whereas such restriction site conservation is not seen in the rhesus monkey. The conclusion drawn is that the genetic organization of theHLA-DQA andChLA-DQA gene regions, and possibly some of their allelic variabilities, already existed before man and chimpanzee separated in evolution. Moreover, the particular duplication which led to the generation of theHLA- andChLA-DQA2 genes must have happened before speciation of members belonging to the superfamily Hominoidea (man, chimpanzee, etc), but probably after the separation of superfamily Cercopitecoidea (rhesus monkeys, baboons, etc.) from Hominoidea.     

Allelic diversity at the primate major histocompatibility complex DRB6 locus

The HLA-DRB6 gene (also called DRB/V1) has been found only in about 26% of human HLA haplotypes, i.e.; DR1, DRw10, and DR2-bearing ones (Corell et al. 1991). In contrast, exon-2 DRB6 sequences have been obtained from all tested primates: nine chimpanzees (Pan troglodytes), three gorillas (Gorilla gorilla) and three orangutans (Pongo pygmaeus); other apes which had already been sequenced (one gorilla and one chimpanzee) also had the DRB6 gene. Thus, all apes tested from three different species, some of them evolutionary separated by at least 14–16 million years, bear the DRB6 gene. In addition, more than one gene copy per haplotype has been found in one chimpanzee; this, together with the apparent loss of this gene in some of the human DR haplotypes, may indicate that the DR genome has undergone evolutionary changes more recently and more actively than class I or III genes. In addition, ten different and presumably allelic DRB6 exon-2 sequences have been obtained, and some of them coming from different species are more similar to each other than the one from the same species; this finding goes in favor of the trans-species theory of major histocompatibility complex polymorphism generation. Also, data are presented supporting that DRB6 may be one of the eldest genes of the DRB family, thus one of the first to diverge from the ancestral DRB gene.The contribution to this paper by A. Corell and P. Morales is equal, and the order of the authorship is arbitrary.     

Novel detection of restriction fragment length polymorphisms in the human major histocompatibility complex

Cosmid genomic DNA clones have been used as hybridization probes in genomic Southern blot analysis to define restriction fragment length polymorphisms (RFLPs) in the major histocompatibility complex (MHC). Using 14 different enzymes and three overlapping cosmid clones we have detected six RFLPs in a 100 kilobase (kb) segment of DNA in the class III region extending centromeric of theTNFA gene towardHLA-DR. Four of the five RFLPs, defined using the enzymesTaqI,Rsa I,Hinc II, andHind III, and detected by the cosmid clone cosM7B, map to a 29 kb segment of DNA that includes all of the recently described G2 (BAT2) gene and a large portion of the 3 end of the G3 (BAT3) gene. The different RFLP variants were established by analyzing the DNA from three informative families and a panel of 51HLA-homozygous typing cell lines. CosM7B detectsTaq I variants of 4.3 kb, and 2.9 kb or 2.8 kb, Rsa I variants of 2.9 kb or 2.4 kb,Hinc II variants of 5.8 kb or 3.8 kb and 1.4 kb, and aHind III variant of 4.8 kb, while cosOT2 detects Taq I variants of 4.5 kb or 4 kb. The distribution of theRsa 1, Hinc II and Taq I RFLPs detected by cosM7B, and theTaq I RFLP detected with cosOT2, within the panel of cell line DNAs was assessed by Southern blotting. The 4.3 kbTaq I variant was observed in only one cell line with the extended haplotypeHLA-A29, C-, B44, SC30, DR4. The other RFLPs, however, occurred much more frequently. The 2.8 kb Taq I variant was observed in 20 % of haplotypes, the 2.9 kbRsa I variant was observed in 42% of haplotypes, and the 5.8 kbHinc I variant was observed in 12 % of haplotypes analyzed. The 4.5 kbTaq I variant detected by the overlapping cosmid cosOT2 was present in 21 % of haplotypes. Analysis of the RFLP variants with each other revealed seven different haplotypic combinations. Three of the haplotypic combinations were each subdivided into two subsets on the basis of the Nco I RFLP variant they carried at theTNF-B locus. These haplotypic combinations potentially allow differentiation among different extended haplotypes such asHLA-B8, SC01, DR3, HLA-B18, F1 C30, DR3, andHLA-B44, FC31, DR7. The RFLPs detected by the cosmid clones thus provide new tools which will be useful in the further genetic analysis of the MHC class III region.     

Mhc-DRB diversity of the chimpanzee (Pan troglodytes)

Fifty-four chimpanzee Patr-DRB and five human HLA-DRB second exons were cloned and sequenced from thirty-five chimpanzees and four B-cell lines and compared with known Mhc-DRB sequences of these two species. Equivalents of the HLA-DRB1 ^* 02,-DRB1 ^* 03, -DRB1 ^* 07 allelic lineages and the HLA-DRB3,-DRB4, -DRB5, -DRB6, and -DRB7 loci were all found in the chimpanzee. In addition, two chimpanzee Patr-DRB lineages (Patr-DRBX and -DRBY) were found for which no human counterparts have been described. None of the Patr-DRB sequences is identical to known HLA-DRB sequences. The Patr-DRB1 ^* 0702 and HLA-DRB1 ^* 0701 alleles are the most similar sequences in a comparison between the two species and differ by only two nucleotides out of 246 sequences. Equivalents of the HLA-DRB1 ^* 01,-DRB1 ^* 04, and -DRB1 ^* 09 alleles were not found in our sample of chimpanzees. A per locus comparison of the number of Patr-DRB alleles with the HLA-DRB alleles shows that the Patr-DRB3, -DRB4, -DRB5, and -DRB6 locus are, thus far, more polymorphic than ther human homologs. The polymorphism of the Patr-DRB1 locus seems to be less extensive than that reported for the HLA-DRB1 locus. Nevertheless, the Patr-DRB1 locus seems to be the most polymorphic of the Patr-DRB loci. Phylogenetic analyses indicate that the HLA-DRB1 ^* 09 allele may have originated from a recombination between a Mhc-DRB5 allele and the DRB1 allele of a Mhc-DR7 haplotype. Although recombination seems to increase the diversity of the Patr-DRB alleles, its contribution to the generation of Patr-DRB variation is probably low. Hence, most Patr-DRB diversity presumably accumulated via recurrent point mutations. Finally, two distinct PAtr-DRB haplotypes are deduced, one of which (the chimpanzee equivalent of the HLA-Dr7 haplotype) is probably older than 6–8 million years.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide database and have been assigned the accession numbers Mg6074-Mg6132. Correspondence to: M. Kenter.     

HLA-DQ RFLP variants of five HLA-DQw2-bearing major histocompatability complex extended haplotypes

We have analyzed genomic DNA in a large number of independent examples of five HLA-DQw2-bearing extended haplotypes for their associated subtypes by restriction fragment length polymorphism (RFLP) using DRB, DQA, and DQB probes after Taq I and Pst I digestion and Southern blotting. In addition to three previously described HLA-DQw2 subtypes, DQw2a, DQw2b, and DQw2c, we observed a fourth subtype, HLA-DQw2d, characterized by 5.8 kilobase (kb) DRB/Taq I, 2.4, 2.3, and 1.8 kb DQB/Taq I, and 8.0 and 2.3 kb DQA/Pst I fragments. All 22 independent examples of the extended haplotype [HLA-B8,SCO1,DR3] carried DQw2a and all 11 independent examples of [HLA-B18,F1C30,DR3] carried DQw2b. In addition, all independent examples (21 and 4, respectively) of two DR7-carrying extended haplotypes, [HLA-B44,FC31,DR7] and [HLA-Bw47,FC91,0,DR7], carried DQw2c and all independent examples of [HLA-Bw57,SC61,DR7] carried DQw2d. Our results show that the DNA in the DR/DQ region of extended haplotypes is relatively fixed and that different DQw2 subtypes characterize different DQw2-bearing extended haplotypes.     

Primate DRB6 pseudogenes: clue to the evolutionary origin of the HLA-DR2 haplotype

The HLA-DR2 haplotype contains three \-chain encoding DRB genes and one -chain encoding DRA gene. Of the three DRB genes, two are presumably functional (HLA-DRB1 and HLA-DRB5), whereas the third (HLA-DRBV1) is a pseudogene. A pseudogene closely related to HLA-DRBVI is present in the chimpanzee (Patr-DRB6) and in the gorilla (Gogo-DRB6). We sequenced the HLA-DRBVI and Patr-DRB6 pseudogenes (all exons and most of the introns), and compared the sequence to that of the Gogo-DRB6 gene (of which only the exon sequence is available). All three pseudogenes seem to lack exon 1 and contain other deletions responsible for shifts in the translational reading frame. At least the HLA-DRBVI pseudogene, however, seems to be transcribed nevertheless. The chimpanzee pseudogene contains two inserts in intron 2, one of which is an Alu repeat belonging to the Sb subfamily, while the other remains unidentified. These inserts are lacking in the human gene. A comparison with sequences published by other investigators revealed the presence of the HLA-DRBVI pseudogene also in the DRI and DRw10 haplotypes. Measurements of genetic distances indicate DRB6 to be closely related to the DRB2 pseudogene and to the HLA-DRB4 functional gene. In humans, gorillas, and chimpanzees, the DRB6 pseudogene is associated with the same functional gene (DRB5) indicating that this linkage disequilibrium is at least six million years old and that DR2 is one of the oldest DR haplotypes in higher primates.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M77284-M77295. Address correspondence and offprint requests to: J. Klein.     

Primate DRB genes from the DR3 and DR8 haplotypes contain ERV9 LTR elements at identical positions

The HLA-DRB genes of the human major histocompatibility complex constitute a multigene family with a varying number of DRB genes in different haplotypes. To gain further knowledge concerning the evolutionary relationship, the complete nucleotide sequence was determined for a region spanning introns 4 and 5 of the three DRB genes (DRB1*0301, DRB2 and DRB3*0101) from a DR52 haplotype and the single DRB gene (DRB1*08021) in the DR8 haplotype. These analyses identified an endogenous retroviral long terminal repeat element (ERV9 LTR3), inserted at identical positions in intron 5 of the functional DRB genes in these two haplotypes. Comparison of the nucleotide sequence from introns 4 and 5 including the ERV9 LTR elements revealed a strong similarity between the three expressed DRB genes. The DRB3*0101 and DRB1*08021 genes were most similar in this comparison. These findings provide further evidence for a separate duplication in a primordial DR52 haplotype followed by a gene contraction event in the DR8 haplotype. A homologous element was found in a chimpanzee DRB gene from a DR52 haplotype. This represents the first characterized ERV9 LTR element in a nonhuman species. The corresponding introns of the DRB genes in the DR4 haplotype contain no ERV9 LTRs. In contrast, these genes have insertions of distinct Alu repeats, implying distinct evolutionary histories of DR52 and DR53 haplotypes, respectively. Phylogenetic analyses of DRB introns from DR52, DR53, and DR8 haplotypes showed a close relationship between the DRB2 and DRB4 genes. Thus, the ancestral DR haplotype that evolved to generate the DR52 and DR53 haplotypes most likely shared a primordial common DRB gene.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession numbers X82660–X82663     

Transcription and diversity of immunoglobulin lambda chain variable genes in the rat

The DRB region of the human major histocompatibility complex displays length polymorphism: Five major haplotypes differing in the number and type of genes they contain have been identified, each at appreciable frequency. In an attempt to determine whether this haplotype polymorphism, like the allelic polymorphism, predates the divergence of humansfrom great apes, we have worked out the organization of the DRB region of the chimpanzee Hugo using a combination of chromosome walking, pulsed-field gel electrophoresis, and sequencing. Hugo is a DRB homozygote whose single DRB haplotype is some 440 kilobases (kb) long and contains five genes. At least one and possibly two of these are pseudogenes, while three are presumably active genes. The genes are designated DRB ^* A0201, DRB2 ^* 0101, DRB3 ^* 0201, DRB6 ^* 0105, and DRB5 ^* 0301, and are arranged in this order on the chromosome. The DRB2 and DRB3 genes are separated by approximately 250 kb of sequence that does not seem to contain any additional DRB genes. The DRB ^* A0201 gene is related to the DRB1 gene of the human DR2 haplotype; the DRB2 ^* 0101 and DRB3 ^* 0201 genes are related to the DRB2 and DRB3 genes of the human DR3 haplotype, respectively; the DRB6 ^* 0105 and DRB5 ^* 0301 genes are related to the DRBVI and DRB5 genes of the human DR2 haplotype, respectively. Thus the Hugo haplotype appears to correspond to the entire human DR2 haplotype, into which a region representing a portion of the human DR3 haplotype has been inserted. Since other chimpanzees have their DRB regions organized in different ways, we conclude that, first, the chimpanzee DRB region, like the human DRB region, displays length polymorphism; second, some chimpanzee DRB haplotypes are longer than the longest known human DRB haplotypes; third, in some chimpanzee haplotypes at least, the DRB genes occur in combinations different from those of the human haplotypes; fourth, and most importantly, certain DRB gene combinations have been conserved in the evolution of chimpanzees and humans from their common ancestors. These data thus provide evidence that not only allelic but also haplotype polymorphism can be passed on from one species to another in a given evolutionary lineage.     

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

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

Hypervariability of intronic simple (gt)n(ga)m repeats in HLA-DRB genes

We have investigated the extent of DNA variability in intronic simple (gt)_n(ga)_m repeat sequences and correlated this to sequence polymorphisms in the flanking exon 2 of HLA-DRB genes. The polymerase chain reaction (PCR) was used to amplify a DNA fragment containing exon 2 and the repeat region of intron 2. The PCR products were separated on sequencing gels in order to demonstrate length hypervariability of the (gt)_n(ga)_m repeats. In a parallel experiment, the PCR products were cloned and sequenced (each exon 2 plus adjacent simple repeats) to characterize the simple repeats in relation to the HLA-DRB sequences. In a panel of 25 DRB1, DRB4, and DRB5 alleles new sequences were not detected. Restriction fragment length polymorphism (RFLP) subtyping of serologically defined haplotypes corresponds to translated DNA sequences in 85% of the cases, the exceptions involving unusual DR/DQ combinations. Many identical DRB1 alleles can be distinguished on the basis of their adjacent simple repeats. We found group-specific organization of the repeats: the DRw52 supergroup repeats differ from those of DRB1*0101, DRB4*0101, and DRB5*0101 alleles and from those of pseudogenes. Finally, we amplified baboon DNA and found a DRB allele with extensive similarity to DRB1 sequences of the DRw52 supergroup. The simple repeat of the baboon gene, however, resembles that of human pseudogenes. In addition to further subtyping, the parallel study of polymorphic protein and hypervariable DNA alleles may allow conclusions to be drawn on the relationships between the DRB genes and perhaps also on the theory of trans-species evolution.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M 34258.     

Organization and evolution of C4 and CYP21 genes in primates: importance of genomic segments

The evolutionary relationship between two central major histocompatibility complex (MHC) genes, C4 and CYP21, was investigated by employing pulsed field gel electrophoresis (PFGE) and conventional restriction fragment length polymorphism (RFLP) analyses in human and nonhuman primates. Using Taq I in conjunction with C4 and CYP21 probes, it has been found that there are four major types of C4 genes [defined by 7.0, 6.4, 6.0, and 5.4 kilobases (kb) Taq I fragments] and two major types of CYP21 genes (3.7 and 3.2 kb fragments) in human and nonhuman primates including chimpanzee, gorilla, and orangutan. All of the eight possible combinations of C4 and CYP21 genes can be identified on one or more human ancestral haplotypes (AH). It is concluded that each of the major types of C4 and CYP21 (and each of the combinations between these) predated human speciation. PFGE analysis with Mlu I and Pvu I suggested that each C4 + CYP21 segment has a specific length of 30–50 kb and that each AH carries one, two, three, or even more segments. In the case of C4, it is important to note that there is no simple relationship between the RFLP and the protein classifications. Thus, at least some of the expressed polymorphisms could be relatively recent in that they are carried by the same or different gene types. These findings are consistent with the hypothesis that M MHC AHs have been formed from a large pool of specific genomic segments and that further haplospecific polymorphism has developed subsequently.     

Polymorphism in the regulatory region of HLA-DRB genes correlating with haplotype evolution

Class II genes of the human major histocompatibility complex (MHC) are polymorphic. Allelic variation of the coding region of these genes is involved in the antigen presentation and is associated with susceptibility to certain autoimmune diseases. The DR region is unique among human class II regions in that multiple DRB genes are expressed. Differential expression of the different DRB loci has been demonstrated, and we sequenced the proximal promoter region of the HLA-DRB genes, known to be involved in the regulation of nucleotide variations in their regulatory regions and we determined the relationship between the regulatory regions of HLA-DRB genes. This polymorphism found in the regulatory conserved boxes could be involved in the observed differential expression of DRB loci. In addition, we found a polymorphism between the regulatory regions of DRB1 alleles which might be involved in an allele-specific regulation and therefore could be considered as an additional factor in susceptibility to autoimmune diseases.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession numbers X64436–X64442, X64544, X64546–X64549, X65558–X65569, and X65585–X65587. Correspondence to: J. F. Eliaou.     

Major histocompatibility complex class I diversity in a West African chimpanzee population: implications for HIV research

 Human immunodefiency virus (HIV) poses a major threat to humankind. And though, like humans, chimpanzees are susceptible to HIV infection, they are considered to be resistant to the development of the acquired immune deficiency syndrome (AIDS). Little is known about major histocompatibility complex (MHC) class I diversity in chimpanzee populations and, moreover, whether qualitative aspects of Patr class I molecules may control resistance to AIDS. To address these questions, we assayed MHC class I diversity in a West African chimpanzee population and in some animals from other subspecies of chimpanzee. Application of different techniques allowed the detection of 17 full-length Patr-A, 19 Patr-B, and 10 Patr-C alleles. All Patr-A alleles cluster only into the HLA-A1/A3/A11 family, which supports the idea that chimpanzees have experienced a reduction in their repertoire of A locus alleles. The Patr-B alleles do not cluster in the same lineages as their human equivalents, due to frequent exchange of polymorphic sequence motifs. Furthermore, polymorphic motifs may have been exchanged between Patr-A and Patr-B loci, resulting in convergence. With regard to evolutionary stability, the Patr-C locus is more similar to the Patr-A locus than it is to the Patr-B locus. Despite the relatively low number of animals analyzed, humans and chimpanzees were ascertained as sharing similar degrees of diversity at the contact residues constituting the B and F pockets in the peptide-binding side of MHC class I molecules. Our results indicate that within a small sample of a West African chimpanzee population, a high degree of Patr class I diversity is encountered. This is in agreement with the fact that chimpanzees display more mitochondrial DNA variation than humans. In addition, population analyses demonstrated that particular Patr-B molecules, with the capacity to bind conserved HIV-1 epitopes, are characterized by high gene frequencies. These findings have important implications for evaluating immune responses in HIV vaccine studies and, more importantly, may help in understanding the relative resistance of chimpanzees to AIDS. Received: 8 December 1999 / Accepted: 30 December 1999     

A novel, nonclassical MHC class I molecule specific to the common chimpanzee

All expressed human MHC class I genes (HLA-A, -B, -C, -E, -F, and -G) have functional orthologues in the MHC of the common chimpanzee (Pan troglodytes). In contrast, a nonclassical MHC class I gene discovered in the chimpanzee is not present in humans or the other African ape species. In exons and more so in introns, this Patr-AL gene is similar to the expressed A locus in the orangutan, Popy-A, suggesting they are orthologous. Patr-AL/Popy-A last shared a common ancestor with the classical MHC-A locus >20 million years ago. Population analysis revealed little Patr-AL polymorphism: just three allotypes differing only at residues 52 and 91. Patr-AL is expressed in PBMC and B cell lines, but at low level compared with classical MHC class I. The Patr-AL polypeptide is unusually basic, but its glycosylation, association with beta(2)-microglobulin, and antigenicity at the cell surface are like other MHC class I. No Patr-AL-mediated inhibition of polyclonal chimpanzee NK cells was detected. The Patr-AL gene is present in 50% of chimpanzee MHC haplotypes, correlating with presence of a 9.8-kb band in Southern blots. The flanking regions of Patr-AL contain repetitive/retroviral elements not flanking other class I genes. In sequenced HLA class I haplotypes, a similar element is present in the A*2901 haplotype but not the A*0201 or A*0301 haplotypes. This element, 6 kb downstream of A*2901, appears to be the relic of a human gene related to Patr-AL. Patr-AL has characteristics of a class I molecule of innate immunity with potential to provide common chimpanzees with responses unavailable to humans.     

Structural comparison of the genes of two HLA-DR supertypic groups: The loci encoding DRw52 and DRw53 are not truly allelic

The organization and sequence of the HLA-DR chain genes are compared in the two supertypic groups, DRw52 and DRw53, which together account for more than 80% of HLA-DR alleles. From the structural data, we conclude that these two groups represent distinct lineages which have followed different patterns of evolution. The fine structure of the chain locus encoding the DRw53 specificity corresponds most closely to the DR II pseudogene in the DRw52 haplotypes. Concomitantly, the DR I locus in DRw53 haplotypes is more closely related to both of the two expressed DR loci of theDRw5 haplotypes (DR I and DR III). These two loci are the result of a recent duplication. This leads to the proposal that both expressed DR chain genes in the DRw52 haplotypes (DR I and DR III) are derived from a single precursor locus, while the two loci expressed in the DRw53 haplotypes are derived from distinct ancestral loci. The genes encoding DRw52 and DRw53 are therefore not true alleles of the same original locus. A scheme is proposed that accounts for the evolution of DR specificities within the DRw52 and DRw53 groups of haplotypes. It is evident that the differentHLA-DR alleles are not structurally equidistant and that one must take into consideration different degrees of heterozygosity or mismatch among the DR alleles.     

Ten HLA-DR4 alleles defined by sequence polymorphisms within the DRB1 first domain

We have studied DRB1 sequence polymorphisms associated with DR4 subtypes using DR4-specific DNA amplification and sequence-specific oligonucleotide probe (SSOP) hybridization. The 5 amplification primer was designed to hybridize with a unique sequence in the first hypervariable region (HVR) of the DRB1 second ex-on of all known DR4 alleles; the 3 primer was designed to hybridize with an intron sequence common to all DRB1 alleles. The specificity of the amplification step was demonstrated by double-blind testing of 105 selected DNA samples. Prospective SSOP typing of DR4 alleles was performed in 104 unrelated individuals known to be DR4-positive, including 13 who were DR4-homozygous. A DRB1 subtype corresponding with the previously defined DR4-associated specificities Dw4, Dw10, Dw13.1, Dw13.2, Dw14.1, Dw14.2, Dw15, and DwKT2 could be assigned for each of the 117 DR4 haplotypes tested. In most cases, DR4-homozygous, DRB1-heterozygous individuals could be genotyped with the panel of probes. In the course of our analysis, we identified two new DR4-related alleles, DRB1*04.CB (DRB1*0410)¹ and DRB1*04.EC (DRB1*, 0411)² which were recognized by their novel hybridization patterns. The DRB1 second exon sequence of DRB1*04.CB, is identical to DRB1*0405 except at codon 86 where GTG encodes valine instead of GGT encoding glycine. DRB1*04.EC is identical to DRB1*04.CB except at codon 74 where GAG encodes glutamic acid instead of GCG encoding alanine. Our results provide further evidence that SSOP hybridization is the most effective approach available for subtyping DR4 haplotypes and identifying unrecognized variants. A similar approach should be equally informative for subtyping other DR alleles.     

A hypervariable repeated sequence on human chromosome 1p36

Summary When used to probe Southern blots of TaqI-digested DNAs from unrelated individuals, p1–79, a 900 bp subclone of a random human cosmid, revealed at least 50 fragments, many of which were polymorphic. Each of 27 unrelated individuals tested with p1–79 displayed a distinct band pattern. Similar variation was seen with several other enzymes, including HaeIII, MspI, PstI and PvuII, whereas other enzymes yielded primarily large fragments of greater than 40 kb. In situ hybridization of p1–79 showed that the loci of hybridization are clustered on human chromosome band 1p36; localization of all TaqI fragments to chromosome 1 was confirmed with a human-rodent somatic cell hybrid panel. DNA sequencing of p1–79 revealed several copies of a 39 bp repeat whose variation in copy number might be the basis of the observed length polymorphisms. Studies of 3-generation Utah families suggest that the numerous restriction fragments homologous to p1–79 are inherited as haplotypes, implying that recombination within this cluster of loci is rare and allowing the cluster to serve as a useful marker for human gene mapping.     

Multiplication of Mhc-DRB5 loci in the orangutan: implications for the evolution of DRB haplotypes

The chain-encoding (B) class II genes of the primate major histocompatibility complex belong to several families. The DRB family of class II genes is distinguished by the occurrence of haplotype polymorphism—the existence of multiple chromosomal forms differing in length, gene number, and gene combinations, each form occurring at an appreciable frequency in the population. Some of the haplotypes, or fragments thereof, are shared by humans, chimpanzees, and gorillas. In an effort to follow the DRB haplotype polymorphism further back in time, we constructed DRB contig maps of the two chromosomes present in the orangutan cell line CP81. Two types of genes were found in the two haplotypes, Popy-DRB5 and Popy-DRB1 ^*03, the former occurring in two copies and one gene fragment in each haplotype, so that the CP81 cell line contains four complete DRB5 genes and two DRB5 fragments altogether. Since the four genes are more closely related to one another than they are to other DRB5 genes, they must have arisen from a single ancestral copy by multiple duplications. At the same time, however, the two CP81 haplotypes differ considerably in their restriction enzyme sites and in the presence of Alu elements at different positions, indicating that they have been separated for a length of time that exceeds the lifespan of a primate species. Moreover, a segment of about 100 kilobase pairs is shared between the orangutan CP81-1 and the human HLA-DR2 haplotype. These findings indicate that part of the haplotype polymorphism may have persisted for more than 13 million years, which is the estimated time of human-orangutan divergence.     

Two distinct subtypes of theHLA-DRw12 haplotypes in the Japanese population detected by nucleotide sequence analysis and oligonucleotide genotyping

We determined the DNA sequence of the enzymatically amplified second exon of theDRB1 gene of theDRw12 haplotypes derived from three Japanese donors and found two distinct subtypes of theDRw12 haplotype. The two subtypes, designatedDRw12a andDrw12b, had single-base substitutions that predicted one amino acid change at residue number 67. The sequence of theDrw12a andDRw12b subtypes differed from those of the otherDR haplotypes, but in the first hypervariable region of theDRB1 gene the sequences were identical to those of theDRw8(Dw8.1) andDRw8(Dw8.3) haplotypes. TheDRw12a andDRw12b subtypes were detected in a wide range of Japanse donors by genotyping with sequence-specific oligonucleotide probes synthesized according to the DNA sequence of the two subtypes. Results of this study demonstrated that theDRw12 haplotypes in the Japanese population are genetically diverse, as many otherDR haplotypes are. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M27509, M27510, M27511.