Characterization of an HLA DR beta pseudogene

Partial nucleotide sequence of a bovine major histocompatibility class II DR beta-like gene

A genomic clone containing a bovine DR beta-like gene, BoDR beta II, was isolated from a bovine genomic library and characterized by restriction enzyme mapping and nucleotide sequencing of exon regions. Alignment of this sequence with the human DR beta cDNA sequence allowed identification of exon/intron boundaries. The clone contains a 13.3-kilobase (kb) insert, and includes 1.3 kb 5' of the beta 1 exon and 6.7 kb 3' of the transmembrane (TM) exon. Open reading frames were present in the BoDR beta exons sequenced. Nucleotide identities of the bovine beta 1, beta 2 and TM exons with the corresponding human DR beta exons were 73, 91 and 83%, respectively. Nucleotide identities of these exons with those of a previously described bovine DR beta-like pseudogene, BoDR beta I, were 69, 95 and 81%, respectively. Although a limited amount of sequence data was obtained for the intron regions, a 71% identity was found within a 514-nucleotide region immediately 3' to the beta 2 exons in BoDR beta I and BoDR beta II. A series of GT residues followed by a longer series of GA residues began about 35 nucleotides 3' of the beta 1 exon in both BoDR beta I and BoDR beta II.

Impact of endogenous intronic retroviruses on major histocompatibility complex class II diversity and stability

The major histocompatibility complex (MHC) represents a multigene family that is known to display allelic and gene copy number variations. Primate species such as humans, chimpanzees (Pan troglodytes), and rhesus macaques (Macaca mulatta) show DRB region configuration polymorphism at the population level, meaning that the number and content of DRB loci may vary per haplotype. Introns of primate DRB alleles differ significantly in length due to insertions of transposable elements as long endogenous retrovirus (ERV) and human ERV (HERV) sequences in the DRB2, DRB6, and DRB7 pseudogenes. Although the integration of intronic HERVs resulted sooner or later in the inactivation of the targeted genes, the fixation of these endogenous retroviral segments over long time spans seems to have provided evolutionary advantage. Intronic HERVs may have integrated in a sense or an antisense manner. On the one hand, antisense-oriented retroelements such as HERV-K14I, observed in intron 2 of the DRB7 genes in humans and chimpanzees, seem to promote stability, as configurations/alleles containing these hits have experienced strong conservative selection during primate evolution. On the other hand, the HERVK3I present in intron 1 of all DRB2 and/or DRB6 alleles tested so far integrated in a sense orientation. The data suggest that multigenic regions in particular may benefit from sense introgressions by HERVs, as these elements seem to promote and maintain the generation of diversity, whereas these types of integrations may be lethal in monogenic systems, since they are known to influence transcript regulation negatively.

Detection of single nucleotide variations by a hybridization proximity assay based on molecular beacons and luminescence resonance energy transfer

A powerful combination of molecular beacon and luminescence resonance energy transfer technology reveals alterations in nucleic acid structure by as little as a single nucleotide in a novel hybridization proximity assay. The assay measures the length of a single-stranded target when a terbium chelate-labeled molecular beacon hybridizes to one side of the nucleic acid segment to be measured and an acceptor probe carrying a convention fluorophore hybridizes to the opposite end of the target. Using a test sequence shortened incrementally by deleting single nucleotides, this assay reports a nearly linear relationship between sequence length and the distance separating acceptor and donor probes. Consequently, this assay can be used to detect alternative splicing, allele types, rearrangements, insertion, and deletion events by measuring separation distances within a predefined region. Furthermore, the use of terbium chelates in molecular beacons can produce exceptionally high signal-to-background ratios compared to the use of conventional fluorophores. Principles of optimal probe design are investigated experimentally and by computational simulations of plausible molecular beacon folding. Some molecular beacon designs form dimers that reduce their maximal response to target sequences. A simple assay to detect such dimers is reported as a tool to help improve the design of molecular beacons. Optimally designed molecular beacons with terbium chelates and hybridization proximity assays are expected to expand their applications in the analysis and screening of genetic diseases.

Pseudogenes: are they "junk" or functional DNA?

Pseudogenes have been defined as nonfunctional sequences of genomic DNA originally derived from functional genes. It is therefore assumed that all pseudogene mutations are selectively neutral and have equal probability to become fixed in the population. Rather, pseudogenes that have been suitably investigated often exhibit functional roles, such as gene expression, gene regulation, generation of genetic (antibody, antigenic, and other) diversity. Pseudogenes are involved in gene conversion or recombination with functional genes. Pseudogenes exhibit evolutionary conservation of gene sequence, reduced nucleotide variability, excess synonymous over nonsynonymous nucleotide polymorphism, and other features that are expected in genes or DNA sequences that have functional roles. We first review the Drosophila literature and then extend the discussion to the various functional features identified in the pseudogenes of other organisms. A pseudogene that has arisen by duplication or retroposition may, at first, not be subject to natural selection if the source gene remains functional. Mutant alleles that incorporate new functions may, nevertheless, be favored by natural selection and will have enhanced probability of becoming fixed in the population. We agree with the proposal that pseudogenes be considered as potogenes, i.e., DNA sequences with a potentiality for becoming new genes.

DNA polymorphism in the beta-Esterase gene cluster of Drosophila melanogaster

We have analyzed nucleotide polymorphism within a 5.3-kb region encompassing the functional Est-6 gene and the psiEst-6 putative pseudogene in 28 strains of Drosophila melanogaster and one of D. simulans. Two divergent sequence types were detected, which are not perfectly associated with Est-6 allozyme variation. The level of variation (pi) is very close in the 5'-flanking region (0.0059) and Est-6 gene (0.0057), but significantly higher in the intergenic region (0.0141) and putative pseudogene (0.0122). The variation in the 3'-flanking region is intermediate (0.0083). These observations may reflect different levels of purifying selection in the different regions. Strong linkage disequilibrium occurs within the region studied, with the largest values revealed in the putative pseudogene and 3'-flanking region. Moreover, recombination is restricted within psiEst-6. Gene conversion is detected both within and (to a lesser extent) between Est-6 and psiEst-6. The data indicate that psiEst-6 exhibits some characteristics that are typical of nonfunctional genes, while other characteristics are typically attributed to functional genes; the same situation has been observed in other pseudogenes (including Drosophila). The results of structural entropy analysis demonstrate higher structural ordering in Est-6 than in psiEst-6, in accordance with expectations if psiEst-6 is indeed a pseudogene. Taking into account that the function of psiEst-6 is not known (but could exist) and following the terminology of J. Brosius and S. J. Gould, we suggest that the term "potogene" may be appropriate for psiEst-6, indicating that it is a potential gene that may have acquired some distinctive but unknown function.

Induction of murine AIDS virus-related sequences after burn injury

To better understand the molecular signaling events leading to systemic inflammatory response syndrome (SIRS) and multiple organ failure (MOF), changes in gene expression profiles after burn injury were investigated by differential display. C57BLKS/J mice were subjected to 18% total body surface area (TBSA) full-thickness burn and various tissues were harvested at multiple time points after injury. Initial differential display revealed that retroviral transcripts similar to the envelope sequence of murine AIDS (MAIDS) virus were rapidly and transiently up-regulated after injury. Subsequent RT-PCR and DNA sequencing analyses confirmed the transient up-regulation of retroviral sequences similar to those of the MAIDS virus. In addition, the presence and induction of the subgenomic envelope transcripts of these MAIDS virus-related sequences, including a novel double spliced message, were identified after burn injury. These data suggest that the transcriptional efficiency of the integrated retroviral DNA and reactivation of defective MAIDS virus-related sequences may be affected by pathophysiological signals, such as burn injury. The elevated expression of these MAIDS virus-related retroviral sequences may affect the transcriptional activities of the flanking genes at the integration sites and may be a cause of altered local and systemic immune responses to burn-related stress.

Phylogenetic history of hominoid DRB loci and alleles inferred from intron sequences

The evolutionary relationships among the MHC class II DRB4, DRB5 and DRB6 loci as well as the allelic lineages and alleles of the DRB1 locus were studied based on intron 1 and intron 2 sequences from humans, chimpanzee (Pan troglodytes), bonobo (Pan paniscus) and gorilla (Gorilla gorilla). The phylogenetic trees for these sequences indicate that most of the DRB1 allelic lineages predate the separation of the hominoid species studied, consistent with previous analysis of the coding sequences of these lineages. However, the intron sequence variation among alleles within DRB1 allelic lineages is very limited, consistent with the notion that the majority of the contemporary alleles have been generated within the last 250,000 years. The clustering of the DRB1 allelic lineages *08 and *12 with *03 supports a common ancestry for the DR8 and DR52 haplotypes. Similarly, the clustering of DRB1 allelic lineages *15 and *01 with the DRB3 locus is consistent with a common ancestry for the DR1 and DR51 haplotypes. Two cases of recombination around the second exon were observed: 1) the HLA-DRB6 locus appears to have been generated through a recombination between a DRB5 allele and an ancestral DRB6 allele, and 2) the gorilla sequence Gogo-DRB1 *03 appears to have been generated through a recombination between the DRB3 locus and an allele from the DRB1 *03 allelic lineage. The nucleotide substitution rate of DRB introns was estimated to 0.85-1.63 x 10(-9) per site per year, based on comparisons between the most closely related sequences from different hominoid species. This estimate is similar to the substitution rate for other intronic regions of the primate genome.

Beneficial role of human endogenous retroviruses: facts and hypotheses

Human endogenous retroviruses (HERVs) have recently been suggested as mediators of normal biological processes such as cellular differentiation and regulation of gene expression. Moreover, a direct role for HERVs in pathogenesis and the development of disease is now better appreciated. Elucidation of the mechanisms regulating HERV biology should provide information about fundamental cellular activities and the pathogenesis of multifactorial diseases such as cancer and autoimmune disease. The importance of understanding the roles of HERVs is underscored by the recently obtained insight that activation of endogenous retroviruses poses potential risks following xenotransplantation and in gene therapy using retroviral vectors. Furthermore, HERV-encoded superantigens have recently been implicated as causes of autoimmune disease. This review discusses the established and possible biological roles of HERVs, and proposes hypotheses concerning their involvement as mediators of fundamental cellular responses. We propose that the evolutionary persistence of endogenous retroviruses in the genomes of eukaryotic cells reflects their indispensability in important normal functions in specialized cellular environments. HERVs can also be potentially hazardous through their involvement in the development of disease. In addition, the creation of new retroviruses can occur through recombination, between different HERVs and between HERVs and exogenous retroviruses.

Detection of Microchimerism After Allogeneic Blood Transfusion Using Nested Polymerase Chain Reaction Amplification With Sequence-Specific Primers (PCR-SSP): A Cautionary Tale

In bone marrow transplantation, the detection of chimerism is an important adjunct to the repertoire of tests available for determining acceptance of the graft. In solid organ transplantation, there is currently intense interest in the role that chimerism plays in both short- and long-term host reactivity to the graft. Allogeneic blood transfusion has been associated with a subtle immunosuppressive effect in renal transplantation and chimerism is implicated as a possible mechanism for this effect. To assess the survival of allogeneic cells after blood transfusion or transplantation, we have developed a technique based on molecular typing for HLA class II alleles, which enables the detection of donor-derived cells in patients receiving blood transfusions. While developing this technology, we investigated why we and others observe false amplification. Sequencing of false products has shown that they arise from amplification of both pseudogenes and non-pseudogenes present in the DNA under test. Elucidation of this phenomenon allows the amplification of these false products to be predicted in any given combination and hence avoided by the judicious selection of primers. Validation has been achieved by following donor alleles after transfusion of blood containing defined numbers of leukocytes expressing selected mismatched antigens.

Detection of Microchimerism After Allogeneic Blood Transfusion Using Nested Polymerase Chain Reaction Amplification With Sequence-Specific Primers (PCR-SSP): A Cautionary Tale

In bone marrow transplantation, the detection of chimerism is an important adjunct to the repertoire of tests available for determining acceptance of the graft. In solid organ transplantation, there is currently intense interest in the role that chimerism plays in both short- and long-term host reactivity to the graft. Allogeneic blood transfusion has been associated with a subtle immunosuppressive effect in renal transplantation and chimerism is implicated as a possible mechanism for this effect. To assess the survival of allogeneic cells after blood transfusion or transplantation, we have developed a technique based on molecular typing for HLA class II alleles, which enables the detection of donor-derived cells in patients receiving blood transfusions. While developing this technology, we investigated why we and others observe false amplification. Sequencing of false products has shown that they arise from amplification of both pseudogenes and non-pseudogenes present in the DNA under test. Elucidation of this phenomenon allows the amplification of these false products to be predicted in any given combination and hence avoided by the judicious selection of primers. Validation has been achieved by following donor alleles after transfusion of blood containing defined numbers of leukocytes expressing selected mismatched antigens.

Retroelements in the human MHC class II region

Molecular genetic studies of the human major histocompatibility complex (MHC) have led to the identification of more than 200 genes. Besides the large number of genes in the MHC, densely clustered areas of retroelements have been identified. These include short and long interspersed elements (SINEs and LINEs), and human endogenous retroviruses (HERVs). The presence of retroelements in the MHC provides a clear example of how these elements affect the genome plasticity of the host. Comparative analyses of these retroelements have proven highly useful in evolutionary studies of the MHC. Recently, HERV-encoded superantigens have been implicated as candidate autoimmune genes in type I diabetes and multiple sclerosis. In addition, genetic analyses have revealed that autoimmune diseases show strong associations with MHC class II genes. The intriguing correlations between retroviral encoded antigens, MHC class II genes and the development of autoimmune disease merit intense future investigations of retroelements, in particular those endogenous retroviruses located in the MHC class II region proper.

Presence of retroelements reveal the evolutionary history of the human DR haplotypes

Comparison of intron sequences has been a successful tool for drawing major conclusions about the evolutionary relationship of DRB genes. This complex family of genes is discussed in this review as well as a proposed model for the evolution of HLA-DR haplotypes. The model is based both on phylogenetic analysis of intron sequences as well as presence of ERV9 LTR elements located at identical position in intron 5 of a number of DRB genes. According to this model, two main evolutionary branches of DR haplotypes exist. The DR53 haplotype represents one branch, and the second branch contains the DR51, DR52, DR1, and DR8 haplotypes. After the divergence of the DR53 haplotype, an ERV9 LTR element was inserted in a primordial gene. Consequently, all DRB1 genes as well as the DRB3 gene within haplotypes of the second branch, contain this LTR element. In addition, conserved regulatory sequence motifs are found present within these LTR elements that might regulate DRB gene expression. Novel haplotypes are generated by recombinations and the maintenance of the DR haplotype variation as well as the frequent genetic rearrangements observed might be evolutionary advantageous.

Possible involvement of endogenous retroviruses in the development of autoimmune disorders, especially multiple sclerosis

Endogenous retroviruses are normal elements in vertebrate genomes. Many aspects concerning these genomic elements are still uncertain. In mice some endogenous retroviral sequences seem to be involved in the regulation of immune responses and there is even evidence that a retroviral element is responsible for the development of an autoimmune disease in a mouse strain. Whether endogenous retroviruses also contribute to the development of autoimmune diseases in humans is not known, but it is an interesting possibility. Below we briefly review endogenous retroviruses as potential etiological factors in autoimmunity and we discuss a possible association between MS and endogenous retroviruses on the basis of results from our laboratory.

Fingerprinting of HLA class I genes for improved selection of unrelated bone marrow donors

The degree of matching of HLA genes between the selected donor and recipient is an important aspect of the selection of unrelated donors for allogeneic bone marrow transplantation (UBMT). The most sensitive methods currently used are serological typing of HLA class I genes, mixed lymphocyte culture (MLC), IEF and molecular genotyping of HLA class II genes by direct sequencing of PCR products. Serological typing of class I antigenes (A, B and C) fails to detect minor differences demonstrated by direct sequencing of DNA polymorphic regions. Molecular genotyping of HLA class I genes by DNA analysis is costly and work-intensive. To improve compatibility between donor and recipient, we have set up a new rapid and non-radioisotopic application of the 'fingerprinting PCR' technique for the analysis of the polymorphic second exon of the HLA class I A, B and C genes. This technique is based on the formation of specific patterns (PCR fingerprints) of homoduplexes and heteroduplexes between heterologous amplified DNA sequences. After an electrophoretic run on non-denaturing polyacrylamide gel, different HLA class I types give allele-specific banding patterns. HLA class I matching is performed, after the gel has been soaked in ethidium bromide or silver-stained, by visual comparison of patients' fingerprints with those of donors. Identity can be confirmed by mixing donor and recipient DNAs in an amplification cross-match. To assess the technique, 10 normal samples, 22 related allogeneic bone marrow transplanted pairs and 10 unrelated HLA-A and HLA-B serologically matched patient-donor pairs were analysed for HLA class I polymorphic regions. In all the related pairs and in 1/10 unrelated pairs, matched donor-recipient patterns were identified. This new application of PCR fingerprinting may confirm the HLA class I serological selection of unrelated marrow donors.

Evolutionary relationship between human major histocompatibility complex HLA-DR haplotypes

HLA-DR haplotypes of the human major histocompatibility complex are organized in five different groups. They can be identified based on the serological specificity expressed by the polymorphic DRB1 locus and by the presence of a characteristic set of DRB genes. The nucleotide sequences of introns 4 and 5 of the two DRB genes (DRB1(*)01 and DRB6(*)01 ) from a DR1 haplotype and the three DRB genes (DRB1(*)15, DRB6(*)15 , and DRB5(*)15 ), from a DR51 haplotype were determined. This study identified endogenous retroviral long terminal repeat elements (ERV9 LTR) located at identical positions in intron 5 of the DRB1 genes in both the DR1 and DR51 haplotypes. Phylogenetic analyses revealed a close evolutionary relationship between these two haplotypes. The DRB5 gene, unique for the DR51 haplotype, may have been lost by a recent gene deletion event creating the DR1 haplotype. A model for the evolution of the human DR haplotypes involving separate duplication and contraction events is presented.

Exonic MHC-DRB polymorphisms and intronic simple repeat sequences: Janus' faces of DNA sequence evolution

The evolution of highly polymorphic gene loci is following routes that cannot be extrapolated from the existing knowledge of single copy genes. In addition, interpreting the evolution of the most polymorphic loci in vertebrates requires a plethora of data from different taxa. We evaluate here the rules for the evolution of Major Histocompatibility Complex (MHC-)DRB genes recently established in humans and other primates on the basis of sequences from several artiodactyl species. MHC genes encode essential molecules for self/altered-self/non-self discrimination in the interaction of the organism with its environment. The necessity to effectively present various different antigens to immunocompetent cells causes positive selection pressure on the variability of these genes in the population. Artiodactyls represent the third mammalian order in which this phenomenon was evidence independently. A further incentive to investigate also the surroundings of MHC-DRB loci was the presence of a particular repetitive sequence stretch in the vicinity of the polymorphic exon--in addition to the evolutionarily old alleles, ancient polymorphisms and the mechanisms for their generation and/or maintenance. Besides their utility for indirect gene diagnosis (MHC-DRB typing), the closely linked stretches of simple repetitive DNA in the neighborhood of the highly polymorphic MHC-DRB genes are also interesting remains of the evolutionary history. Evolutionary development is different in genetically inert intronic DNA compared to the exonic counterparts, despite their close vicinity. The persistence of these simple repeats over nearly 100 million years in one location preserving the same basic motif structure is startling. Indirect evidence is weighed that biological meaning should be considered for these elements. The combined analysis of the polymorphic DRB genes and the (highly variable but persistent) simple repeat stretches deepen our understanding of the complexities within a unique genomic compartment encoding essential molecules for self/non-self differentiation in the interaction of the organism with its environment.

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 as 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 dichotomous size variation of human complement C4 genes is mediated by a novel family of endogenous retroviruses, which also establishes species-specific genomic patterns among Old World primates

The human complement C4 genes in the HLA exhibit an unusual, dichotomous size polymorphism and a four-gene, modular variation involving novel gene RP, complement C4, steroid 21-hydroxylase (CYP21), and tenascin-like Gene X (RCCX). The C4 gene size dichotomy is mediated by an endogenous retrovirus, HERV-K(C4). Nearly identical sequences for this retrotransposon are present precisely at the same location in the long C4 genes from the tandem RCCX Module I and Module II. Specific nucleotide substitutions between the long and short C4 genes have been identified and used for diagnosis. Southern blot analyses revealed that HERV-K(C4) is present at more than 30 locations in the human genome, exhibits variations in the population, and its analogs exist in the genomes of Old World primates with species-specific patterns. Evidence of intrachromosomal recombination between the two long terminal repeats of HERV-K(C4) is found near the huntingtin locus on chromosome 4. It is possible that members of HERV-K(C4) are involved in genetic instabilities including the RCCX modules, and in protecting the host genome from retroviral attack through an antisense strategy.

Mapping cis-acting defects in promoters of transcriptionally silent DQA2, DQB2, and DOB genes

Defects in promoters of the nonexpressed DQA2, DQB2, and DOB genes from the class II major histo-compatibility complex were mapped by placing Z and X boxes of these silent genes into a synthetic DRA promoter. These conserved upstream sequences confer B-cell-specific and gamma-interferon-inducible expression to the DRA gene. Since DRA promoters containing the X box from the DQA2 gene and Z boxes from DQA2, DQB2, and DOB genes were neither expressed constitutively in B cells nor inducible by gamma interferon in fibroblastic cells, these conserved upstream sequences are implicated in the transcriptional defects of these silent genes.

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 these genes. We found locus-specific and allele-specific 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.

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

The beta 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.

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 position 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 years old. Predictions of major chimpanzee DRB haplotypes are made.

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 human 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 sequenced. 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 their 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 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 long 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.

Alleles at four HLA class II loci determined by oligonucleotide hybridization and their associations in five ethnic groups

The use of polymerase chain reaction (PCR) and oligonucleotide hybridization offers a new approach for the definition of HLA class II alleles. It has been possible to determine 43 alleles of DRB1, four of DRB3, two of DRB4, four of DRB5, eight of DQA1, and 14 of DQB1. These alleles are inherited together in members of families and form closely associated groups which are found repeatedly and in characteristic patterns in different populations. We have determined the HLA class II alleles and analyzed their association in 431 healthy unrelated subjects including 161 North American Caucasians, 53 Latin Americans, 61 Blacks, 88 Chinese, and 68 Israeli Jews. For-locus haplotypes (DRB1; DRB3/4/5; DQA1; DQB1) were derived from 79 B cell lines and the analysis of segregation in 34 nuclear families. The B-cell lines yielded 37 and the families showed the same, and 20 other, haplotypic combinations. In addition to these 57 haplotypes, associated alleles were assigned in the unrelated panels following certain rules. The resulting haplotypes were assigned to groups known to share associated alleles. The groups were: 1) DR1, DR2, and DRw10 (13 haplotypes); 2) DR3 and DRw6 (26 haplotypes); 3) DR5 and DRw8 (24 haplotypes); 4) DR4, DR7, and DR9 (24 haplotypes). Their distribution in populations with different ethnic backgrounds was analyzed. The expressed DRB4 allele and its null mutant were determined by PCR and oligonucleotide hybridization. The different DR7 haplotypes resulting from these determinations were analyzed in a panel of 130 North American Caucasoids. This comprehensive analysis of class II HLA haplotypes in human populations should be useful in understanding the role of these genes and in various applications including anthropology, disease susceptibility, and transplantation of allogeneic organs and tissues.

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

The HLA-DR2 haplotype contains three beta-chain encoding DRB genes and one alpha-chain encoding DRA gene. Of the three DRB genes, two are presumably functional (HLA-DRB1 and HLA-DRB5), whereas the third (HLA-DRBVI) 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 DR1 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 and evolution of ovine MHC class II B genes: DQB and DRB

The nucleotide sequences of one Ovar-DQB gene, excluding exon 1 and parts of the introns, and one Ovar-DRB pseudogene are presented. The structure of the Ovar-DQB gene is typical of a major histocompatibility complex (MHC) class II B gene and demonstrates considerable sequence similarity with that of humans including such characteristics as the less common polyadenylation signal, ATTAAA. The ovine sequence has a typical 5' acceptor splice signal for exon 5, thus potentially encoding a full length cytoplasmic tail. The Ovar-DRB gene identified in this study was found to be a pseudogene, lacking a defined exon 2 and containing premature termination codons in both exons 3 and 4. The 3' donor splice site of exon 3 is also atypical. A purine-pyrimidine microsatellite repeat, (dC.dA)15, in the 3' region of the pseudogene may be a hotspot for recombination within the ovine DR subregion.

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 beta 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.

The nucleotide sequence of bovine MHC class II DQB and DRB genes

The nucleotide sequences of most of the exons and parts of the introns of two BoLA-DQB genes and two BoLA-DRB genes have been determined. The structure of these genes is very similar to that of human major histocompatibility complex (MHC) class II genes. The two DQB genes probably represent true alleles. Based on the exons sequenced, both DQB genes and one of the DRB genes seem to be functional. The other DRB gene is a pseudogene; stopcodons are found in the exons encoding the second and transmembrane domain and, furthermore, a 2 base pair (bp) deletion has occurred in the leader exon which places the initiation start codon out of frame. Also in this pseudogene, an almost perfect inverted repeat of 200 bp is found flanking the exon encoding the first domain, which might have been the result of a duplication/inversion event. The sequences presented in this paper do not contain any repetitions. Therefore, DNA fragments containing these sequences can be used as homologous bovine probes in restriction fragment length polymorphism (RFLP) analysis to study disease associations in cattle.

DNA binding of the mouse class II major histocompatibility CCAAT factor depends on two components

A CCAAT-binding factor that recognizes a CCAAT sequence (Y box) located upstream of the major histocompatibility class II gene I-A beta has been partially purified. This CCAAT-binding factor was found to consist of two components, designated factors A and B, both of which were required for efficient binding to the DNA. Factor A had an apparent molecular size of 34 kilodaltons, and factor B had an apparent molecular size of 42 to 46 kilodaltons.

Mapping and nucleotide sequence of a new HLA class II light chain gene, DQB3

A genomic clone specifying a new HLA class II antigen beta chain, DQB3, was isolated from a human genomic phage library using a DQB1 cDNA probe under low stringency conditions. Southern hybridization and nucleotide sequence analyses identified the beta 2 domain exon (exon 3) with several deleterious mutations and the CP-TM-CY exon [connecting peptide, transmembrane, and cytoplasmic regions, (exon 4)], but the first, second, and fifth exons encoding the 5' UT-leader, the beta 1 domain, and the 3' UT domain of normal beta chains, respectively, were entirely missing. The nucleotide sequences of these two exons were distinct from those of other class II beta chain genes, but slightly more related to the DQB1 and DQB2 genes than to other class II genes. The DQB3 sequence mapped between DQA2 and DQB1, 15 kb upstream from DQA2, by analysis of overlapping cosmid clones. This mapping was supported by the fact that Taq I, Msp I, and Bam HI DQB3 polymorphisms were perfectly correlated with the DQA2 polymorphism and not with any polymorphisms in the DR or DQ subregion, suggesting the presence of a hot spot for recombination between DQB3 and DQB1.

DNA binding of the mouse class II major histocompatibility CCAAT factor depends on two components

A CCAAT-binding factor that recognizes a CCAAT sequence (Y box) located upstream of the major histocompatibility class II gene I-A beta has been partially purified. This CCAAT-binding factor was found to consist of two components, designated factors A and B, both of which were required for efficient binding to the DNA. Factor A had an apparent molecular size of 34 kilodaltons, and factor B had an apparent molecular size of 42 to 46 kilodaltons.