Trans-species origin of Mhc-DRB polymorphism in the chimpanzee

Trans-specific evolution of allelic polymorphism at the major histocompatibility complex loci has been demonstrated in a number of species. Estimating the substitution rates and the age of trans-specifically evolving alleles requires detailed information about the alleles in related species. We provide such information for the chimpanzee DRB genes. DNA fragments encompassing exon 2 were amplified in vitro from genomic DNA of ten chimpanzees. The nucleotide sequences were determined and their relationship to the human DRB alleles was evaluated. The alleles were classified according to their positioni in dendrograms and the presence of lineage-specific motifs. Twenty alleles were found at the expressed loci Patr-DRB1,-DRB3, -DRB4, -DRB5, and at the pseudogenes Patr-DRB6, -DRB7; of these, 13 are new alleles. Two other chimpanzee sequences were classified as members of a new lineage tentatively designated DRBX. Chimpanzee counterparts of HLA-DRB1 ^* 01 and ^* 04 were not detected. The number of alleles found at individual loci indicates asymmetrical distribution of polymorphism between humans and chimpanzees. Estimations of intra-lineage divergence times suggest that the lineages are more than 30 million year old. Predictions of major chimpanzee DRB haplotypes are made.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M94937-M94954.     

Diversity associated with the second expressed H L A - D R B locus in the human population

Although diversity within the HLA-DRB region is predominantly focused in the DRB1 gene, the second expressed DRB loci, DRB3, DRB4, and DRB5, also exhibit variation. Within DRB1 ^* 15 or DRB1 ^* 16 haplotypes, four new variants were identified: 1) two new DRB5 alleles, DRB5 ^* 0104 and DRB5 ^* 0204, 2) a haplotype carrying a DRB1 ^* 15 or ^* 16 allele without the usual accompanying DRB5 allele, and 3) a haplotype carrying a DRB5^* 0101 allele without a DRB1 ^* 15 or ^* 16 allele. The evolutionary origins of these haplotypes were postulated based on their associations with the DRB6 pseudogene. Within HLA haplotypes which carry DRB3, a new DRB3 ^* 0205 allele and one unusual DRB3 association were identified. Finally, two new null DRB4 alleles are described: DRB4 ^* 0201N, which exhibits a deletion in the second exon, and a second allele, DRB4 ^* null, which lacks the second exon completely. Gene conversion-like events and variation in the number of functional genes through reciprocal recombination and inactivation contribute to the diversity observed in the second expressed HLA-DRB loci. Received: 2 November 1996 / Revised: 23 December 1996     

The evolutionary origin of the HLA-DR3 haplotype

The human HLA-DR3 haplotype consists of two functional genes (DRB1*03 and DRB3*01) and one pseudogene (DRB2), arranged in the order DRB1... DRB2... DRB3 on the chromosome. To shed light on the origin of the haplotype, we sequenced 1480 nucleotides of the HLA-DRB2 gene and aong stretches of two other genes, Gogo-DRB2 from a gorilla, Sylvia and Patr-DRB2 from a chimpanzee, Hugo. All three sequences (HLA-DRB2, Gogo-DRB2, Patr-DRB2) are pseudogenes. The HLA-DRB2 and Gogo-DRB2 pseudogenes lack exon 2 and contain a twenty-nucleotide deletion in exon 3, which destroys the correct translational reading frame and obliterates the highly conserved cysteine residue at position 173. The Patr-DRB2 pseudogene lacks exons 1 and 2; it does not contain the twenty-nucleotide deletion, but does contain a characteristic duplication of that part of exon 6 which codes for the last four amino acid residues of the cytoplasmic region. When the nucleotide sequences of these three genes are compared to those of all other known DRB genes, the HLA-DRB2 is seen as most closely related to Gogo-DRB2, indicating orthologous relationship between the two sequences. The Patr-DRB2 gene is more distantly related to these two DRB2 genes and whether it is orthologous to them is uncertain. The three genes are in turn most closely related to HLA-DRBVI (the pseudogene of the DR2 haplotype) and Patr-DRB6 (another pseudogene of the Hugo haplotype), followed by HLA-DRB4 (the functional but nonpolymorphic gene of the DR4 haplotype). These relationships suggest that these six genes evolved from a common ancestor which existed before the separation of the human, gorilla, and chimpanzee lineages. The DRB2 and DRB6 have apparently been pseudogenes for at least six million years (myr). In the human and the gorilla haplotype, the DRB2 pseudogene is flanked on each side by what appear to be related genes. Apparently, the DR3 haplotype has existed in its present form for more than six myr.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M86691–94.     

Evolutionary relationship ofHLA-DRB genes inferred from intron sequences

The major histocompatibility complex (Mhc) consists of class I and class II genes. In the humanMhc (HLA) class II genes, nineDRB loci have been identified. To elucidate the origin of these duplicated loci and allelic divergences at the most polymorphicDRBI locus, introns 4 and 5 as well as the 3′ untranslated region (altogether approximately 1,000 base pairs) of sevenHLA-DRB loci, threeHLA-DRBI alleles, and nine nonhuman primateDRB genes were examined. It is shown that there were two major diversification events inHLA-DRB genes, each involving gene duplications and allelic divergences. Approximately 50 million years (my) ago,DRBI ^*04 and an ancestor of theDRB1 ^*03 cluster (DRBI ^*03, DRBI^*15, andDRB3) diverged from each other andDRB5, DRB7, DRB8, and an ancestor of theDRB2 cluster (DRB2, DRB4, andDRB6) arose by gene duplication. Later, about 25 my ago,DRBI ^*15 diverged fromDRBI*03, andDRB3 was duplicated fromDRBI ^*03. Then, some 20 my ago, the lineage leading to theDRB2 cluster produced two new loci,DRB4 andDRB6. TheDRBI ^*03 andDRBI ^*04 allelic lineages are extraordinarily old and have persisted longer than some duplicated genes. The orthologous relationships ofDRB genes between human and Old World monkeys are apparent, but those between Catarrhini and New World monkeys are equivocal because of a rather rapid expansion and contraction of primateDRB genes by duplication and deletion. Correspondence to: Y. Satta     

The chimpanzee major histocompatibility complex class II DR subregion contains an unexpectedly high number of beta-chain genes

The major histocompatibility complex (MHC) class II DR subregion of the chimpanzee was studied by restriction fragment length polymorphism (RFLP) analysis. Genomic DNA obtained from a panel of 94 chimpanzees was digested with the restriction enzyme Taq I and hybridized with an HLA-DR probe specific for the 3' untranslated (UT) region. Such a screening revealed the existence of 14 distinct DRB/Taq I gene-associated fragments allowing the definition of 11 haplotypes. Segregation studies proved that the number of chimpanzee class II DRB/Taq I fragments is not constant and varies from three to six depending on the haplotype. Comparison of these data with a human reference panel manifested that some MHC DRB/Taq I fragments are shared by man and chimpanzee. Moreover, the number of HLA-DRB/Taq I gene-associated fragments detected in a panel of homozygous typing cells varies from one to three and corresponds with the number of HLA-DRB genes present for most haplotypes. However, a discrepancy is observed for the HLA-DR4,-DR7, and -DR9 haplotypes since a fourth HLA-DRB pseudogene present within these haplotypes lacks its 3' UT region and thus is not detected with the probe used. These results suggest that chimpanzees have a higher maximum number of DRB genes per haplotype than man. As a consequence, some chimpanzee haplotypes must show a dissimilar organization of the MHC DR subregion compared to their human equivalents. The implications of these findings are discussed in the context of the trans-species theory of MHC polymorphism. Address correspondence and offprint requests to: R. E. Bontrop.     

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.     

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.     

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.     

Sequence analysis and HLA-DR genotyping of a novel HLA-DRw14 allele

Analysis of a Japanese population by oligonucleotide genotyping revealed that one Japanese HLA-DRw14 allele had a DRB1 genotype different from that of the known HLA-DRw14-related alleles, DRB1 ^* 1401 (DRw14-Dw9) and DRB1 ^* 1402 (DRw14-Dw16). The second exon of the DRB1 gene of the novel DRw14 allele (designated DRB1-14c) was amplified enzymatically and sequenced after cloning intto a plasmid vector. The amino acid sequence of the first domain in the DR1 chain encoded in the DRB1-14c allele was more similar to that of the DRB1 ^* 1401 allele (three amino acid substitutions).than to that of the DRB1 ^* 1402 allele (six amino acid substitutions). No polymorphic amino acid residue that could explain the common serologic HLA-DRw14 specificity was identified among the sequences of the three DRw14-related alleles. Sequence-specific oligonucleotides (SSOs) were synthesized on the basis of the DRB1-14c nucleotide sequence and used for genotyping of the Japanese population. These SSOs served as useful probes for identifying the DRB1-14c allele in a wide range of donors.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M33693.     

Recent divergence of the<Emphasis Type="Italic"> HLA-DRB1*04</Emphasis> allelic lineage from the<Emphasis Type="Italic"> DRB1*0701</Emphasis> lineage after the separation of the human and chimpanzee species

Conventional phylogenetic trees for the human leukocyte antigen (HLA)-DRB1 alleles constructed by the neighbor-joining (Saitou and Nei 1987) and UPGMA (Sneath and Sokal 1973) methods using nucleotide sequences of the DRB1 alleles suggest that DRB1*0701 may have diverged from other DRB1 alleles before the separation of the human and chimpanzee species, because of a large number of nucleotide changes in DRB1*0701 compared with any of the other DRB1 alleles. Here we show new evidence that the haplotypes centering on DRB1*0701 and DRB1*04 alleles are the most homologous. This suggests that these haplotypes have derived from the common ancestral haplotype, and that they have likely retained complete linkage disequilibrium even after the divergence of the DRB1*0701 and DRB1*04 allelic lineages. Together with the corresponding haplotype carrying chimpanzee DRB1*0701, which has a high sequence homology to HLA-DRB1*0701, these haplotypes reveal that: (1) the DRB1*04 allelic lineage may have been generated from the DRB1*0701 lineage after the separation of the human and chimpanzee species; (2) the DRB1*04 allelic lineage possibly has a higher substitution rate of DRB1 compared with pseudogene and neutral region; (3) there could be a significant difference in the substitution rate of DRB1 between the DRB1*0701 and DRB1*04 allelic lineages. Based on the difference between the present and previous results, we would like to propose that phylogenetic studies using not only nucleotide sequences of the DRB1 alleles but also haplotypes centering on the alleles should be conducted for understanding detailed phylogenetic relationships of the DRB1 alleles.     

Distribution of <Emphasis Type="Italic">BoLA-DRB3</Emphasis> allelic frequencies and identification of a new allele in the Iranian cattle breed Sistani (<Emphasis Type="Italic">Bos indicus</Emphasis>)

The distribution of the frequencies of BoLA-DRB3 gene alleles in the Iranian cattle breed Sistani was studied by the PCR-RFLP (“hemi-nested”) assay using restriction endonucleases RsaI, HaeIII and BstYI. In the examined cattle breed (65 animals) 32 alleles have been identified one of which being described for the first time (6.15% frequency). The nucleotide sequence of the polymorphic region of exon 2 of this allele has been determined and submitted in the GenBank database under accession number DQ486519. The submitted sequence has maximum homology (92%) with the previously described sequence DRB3-mRNA from Bos indicus (AccN X79346) and differs from it by 24 nucleotide substitutions which result in 16 amino acid substitutions. The peptide (on the basis of the reconstructed amino acid sequence) has 89% identity to the sequence encoded by the BIDRBF 188 locus (Bos indicus). The results obtained permit the sequence described by us to be considered as a new allele of the BoLA-DRB3 gene (DRB3.2 ^* X). The total frequency of the main six alleles (DRB3.2*8, *10, *11, *20, *34 and *X) occurring with a frequency of over 5% is about 60% in Iranian Sistani cattle. Fifteen alleles have <1% frequency. The highest frequency was observed for DRB3.2*8 allele (21.54%) like in other previously described breeds of Bos indicus (up to 23.07%). The Iranian breed Sistani has a high level of similarity by the spectrum of BoLA-DRB3 alleles and their frequencies to other Bos indicus breeds and significantly differs by these criteria from the Bos Taurus breeds. The Iranian Sistani herd under study includes alleles associated with to resistance to leukemia (DRB3.2*11 and *23) and to different forms of mastitis (DRB3.2* 2, *7, *11, *23 and *24) although their frequencies are low (from 0.77 to 5.37%). On the whole, a high level of diversity of BoLA-DRB3 gene alleles and the availability of alleles associated with resistance to different diseases makes this breed of interest for breeding practice. The article is published in the original.     

Heterogeneity inHLA-DR2-relatedDR,DQ haplotypes in eight populations of Asia-Oceania

The relative distributions of 480DR2-relatedDR, DQ haplotypes have been determined in Australian Aborigines, Papua New Guinean Highlanders, coastal Melanesians, Micronesians, Polynesians, Javanese, and Southern and Northern Chinese. Using sequence-specific oligonucleotides (SSOs) for hybridization of polymerase chain reaction (PCR) products from DRBI,DRBS,DQA1, andDQBI genes, 15 differentDR2-related haplotypes were identified. The predominantDR2 haplotype in Oceania involved a novel combination ofDRBI ^* 1502,DRB5 ^* 0101 alleles; this haplotype occurred sporadically in Java, but not in China. In Southern China, the most frequent DR2 haplotype involved the unusual arrangementDRB1 ^* 1602,DRB5 ^* 0101; alternatively,DRB1 ^* 1602 was associated with a newDRB5 SSO pattern. This study has important implications for molecular HLA-typing protocols that assume particularDRB1 DRB5 orDR,DQ linkage relationships. Further, the novelDRBI,DRB5 haplotype in Oceania suggests that the mixed lymphocyte culture (MLC) determinants Dw2 and Dw12 are discriminated by codon 86 at theDRBI locus.     

A phylogenetic analysis of cattle DRB3 alleles with a deletion of codon 65

 One of the most common cattle major histocompatibility complex DRB3 alleles, ^* 0201, includes a deletion of codon 65 encoding one residue in the α-helical chain. The mutation is functionally interesting and is likely to influence peptide binding. Exon 2 of two additional del65 alleles, ^* 3301 and ^* 4101, have now been sequenced with the aim to investigate the evolutionary relationship of this allelic group. Despite a fairly large genetic distance between the three alleles (11–17 nucleotide substitutions causing 8–11 amino acid substitutions) we found clear indications of a common ancestry. The α-helical region was very similar or identical among the alleles whereas the β-strand region was quite divergent. The results indicated that interallelic recombination has contributed to the diversification of the del65 group. Deletion of codon 65 has also been found in a roe deer DRB1 allele and a cattle DQB3 allele. Sequence comparisons of the cattle and roe deer DRB del65 alleles refuted the possibility of a trans-species persistence of a del65 allelic lineage but the two species may share a short ancestral sequence motif including del65. In addition to del65, the cattle DQB3 allele did not show any striking sequence similarities to the DRB alleles. Received: 20 March 1997 / Revised: 17 June 1997     

Association of HLA-DRB1 and DQB1 alleles with red blood cell alloimmunization in Chinese

Few systematic investigations have assessed the correlations between red blood cell (RBC) antibodies and human leukocyte antigen (HLA)-DRB1 alleles in the Chinese population. In this case-control study, we investigated whether specific HLA-DRB1 alleles were associated with RBC alloimmunization by calculating the odds ratios for the frequencies of HLA alleles associated with alloimmunization to different RBC antigens. Three hundred and eight patients harboring RBC alloantibodies were analyzed as the case group, and the frequencies of the HLA-DRB1and HLA-DQB1 alleles in control individuals were analyzed by collecting data from the China Marrow Donor Program (including more than 1.6 million healthy people). HLA alleles were genotyped by single specific primer-polymerase chain reaction. The development of anti-C was associated with DRB1*07, DQB1*06, and DQB1*08; anti-C,e was associated with DRB1*07 and DQB1*06; and anti-E and anti-M were associated with DQB1. Other associations were identified between anti-E and DRB1*09 and between anti-Le^a and DRB1*01. Thus, our findings confirmed that HLA-DRB1 and DQB1 restriction played an important role in the generation of RBC alloantibodies in Chinese individuals.     

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     

Comparison of allele O sequences of the human and non-human primate ABO system

 Like humans, non-human primates express the antigens A and B of the ABO histoblood group system. In chimpanzees, only A and O types are found, while the types A, B, AB, and O are found in macaques. The sequences of exons 6 and 7 of two chimpanzee O alleles (O ^del and O ^x ), two macaque species O alleles (rhesus monkey and crab-eating macaque), and sequences of exon 7 of two major chimpanzee A alleles (A ^1ch and A ^2ch ) were established. The sequences of cDNAs corresponding to the chimpanzee and rhesus monkey O alleles were characterized from exon 1 to 7 and from exon 4 to 7, respectively. A comparison of our results with ABO gene sequences already published by others demonstrates that human and non-human primate O alleles are species-specific and result from independent silencing mutations. These observations reinforce the hypothesis that the maintenance of the ABO gene polymorphism in primates reflects convergent evolution more than transpecies inheritance of ancestor alleles. Received: 30 July 1998 / Revised: 12 December 1998     

Mhc-DRB genes of platyrrhine primates

The two infraorders of anthropoid primates, Platyrrhini (New World monkeys) and Catarrhini (Old World monkeys and the hominoids) are estimated to have diverged from a common ancestor 37 million years ago. The major histocompatibility complex class II DRB gene and haplotype polymorphism of the Catarrhini has been characterized in several recent studies. The present study was undertaken to obtain information on the DRB polymorphism of the Platyrrhini. Fifty-five complete exon 2 DRB sequences were obtained from six species of Platyrrhini representing both the Callitrichidae and the Cebidae families. Combined with the results of a parallel contig mapping study, our data indicate that at least three loci (DRB1*03, DRB3, and DRB5) are shared by the Catarrhini and the Platyrrhini. However, the three loci are occupied by functional genes in the former infraorder and mostly by pseudogenes in the latter. Instead of the pseudogenes, the Platyrrhini have evolved a new set of apparently functional genes — DRB11 and DRB*W12 through DRB*W19, which have thus far not been found in the Catarrhini. The DRB*W13, *W14, *W15, *W17, *W18, and *W19 genes seem to be restricted to the Cebidae family, whereas the DRB*W16 locus has so far been documented in the Callitrichidae family only. The DRB alleles of the cotton-top tamarin, and perhaps also those of the common marmoset (both members of the family Callitrichidae), are characterized by low nucleotide diversity, possibly indicating that they diverged from a common ancestral gene relatively recently. Correspondence to: J. Klein.     

HLA-G gene polymorphism in a Japanese population

 Polymorphism of the HLA-G gene in a Japanese population was investigated employing polymerase chain reaction (PCR)-single-strand conformation polymorphism (SSCP) analysis, PCR sequence-specific oligonucleotide (SSO) analysis, and DNA direct sequencing. Nucleotide sequence variations in exons 2, 3, and 4 of the HLA-G gene in 54 healthy Japanese individuals were examined. In addition, seven Japanese samples carrying common HLA haplotypes were analyzed. In total, nine single-base substitutions compared with the sequence of G ^* 01011 were identified: one in intron 1 (nucleotide position 970), one in exon 2 (the third base of codon 57: G → A), three in intron 2 (1264, 1276, and 1292), three in exon 3 (the third base of codon 93: C → T, the third base of codon 107: A → T, and the first base of codon 110: C → A), and one in intron 3 (2334). The substitution at codon 110 was non-synonymous and led to an amino acid substitution from leucine to isoleucine. The other three nucleotide substitutions in exons were synonymous. Through analysis of combinations of the exon 2, 3, and 4 nucleotide sequences we identified four alleles, which we provisionally designated GJ1, GJ2, GJ3, and GJ4. The allele frequencies were estimated to be 0.33, 0.16, 0.45, and 0.06, respectively. Nucleotide sequences of GJ1, GJ2, and GJ4 were identical to G ^* 01011, the clone 7.0E, and G ^* 01013, respectively. GJ3 was a newly observed allele and was officially designated G ^* 0104 by the WHO Nomenclature Committee in January 1996. Strong positive associations were observed between HLA-G alleles and HLA-A, -B, or -DRB1 alleles. Received: 15 February 1996 / Revised: 26 March 1996     

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.