Localization of seven new genes around the HLA-A locus

ERVK9, transposons and the evolution of MHC class I duplicons within the alpha-block of the human and chimpanzee

The genomic sequences within the alpha-block (approximately 288-310 kb) of the human and chimpanzee MHC class I region contains ten MHC class I genes and three MIC gene fragments grouped together within alternating duplicated genomic segments or duplicons. In this study, the chimpanzee and human genomic sequences were analyzed in order to determine whether the remnants of the ERVK9 and other retrotransposon sequences are useful genomic markers for reconstructing the evolutionary history of the duplicated MHC gene families within the alpha-block. A variety of genes, pseudogenes, autologous DNA transposons and retrotransposons such as Alu and ERVK9 were used to categorize the ten duplicons into four distinct structural groups. The phylogenetic relationship of the ten duplicons was examined by using the neighbour joining method to analyze transposon sequence topologies of selected Alu members, LTR16B and Charlie9. On the basis of these structural groups and the phylogeny of the duplicated transposon sequences, a duplication model was reconstructed involving four multipartite tandem duplication steps to explain the organization and evolution of the ten duplicons within the alpha-block of the chimpanzee and human. The phylogenetic analysis and inferred duplication history suggests that the Patr/HLA-F was the first MHC class I gene to have been fixed and not required as a precursor for further duplication within the alpha-block of the ancestral species.

Nasopharyngeal carcinoma-susceptibility locus is localized to a 132 kb segment containing HLA-A using high-resolution microsatellite mapping

Nasopharyngeal carcinoma (NPC) is an epithelial tumor uniquely prevalent in southern Chinese. HLA-A2 is associated with NPC. In a previous study, we showed that the genes associated with susceptibility to NPC are primarily located within the HLA-A locus in Taiwanese NPC patients. However, the pathogenic genes causing NPC susceptibility remain unknown. Here, 8 polymorphic microsatellite markers distributed over a 1 megabase region surrounding the HLA-A locus were subjected to genetic analysis for the NPC-susceptibility locus. Statistical studies of associated alleles detected on each microsatellite locus showed that the NPC- susceptibility genes are most likely located between the D6S510 and D6S211 markers within a 132 kb segment containing the HLA-A locus. These results undoubtedly would facilitate the further positional cloning of the NPC-susceptibility locus, which has been elusive for the past 30 years.

A 356-Kb sequence of the subtelomeric part of the MHC Class I region

The subtelomeric part of the MHC Class I region contains 11 of the 21 genes described on chromosome 6 at position 6p21.3. The general organization of those and other genes resident in the region was revealed by determining a 356,376 bp sequence. Potential exons for new genes were identified by computer analysis and a large number of ESTs were selected by testing the sequence by the BLAST algorithm against the GenBank nonredundant and EST databases. Most of the ESTs are clustered in two regions. In contrast, the whole HLA-gene region is crammed with LINE and SINE repeats, fragments of genes and microsatellites, which tends to hinder the identification of new genes.

Human release factor eRF1: structural organisation of the unique functional gene on chromosome 5 and of the three processed pseudogenes

In lower and higher eukaryotes, a family of tightly related proteins designated eRF1 (for eukaryotic release factor 1) catalyses termination of protein synthesis at all three stop codons. The human genome contains four eRF1 homologous sequences localised on chromosomes 5, 6, 7 and X. We report here the cloning and the structural analysis of the human eRF1 gene family. It appears that the gene located on chromosome 5 alone is potentially functional, whereas the other three sequences resemble processed pseudogenes. This is the first description of the structural organisation of the human eRF1 gene, which has been remarkably conserved during evolution and which is essential in the translation termination process.

Haemochromatosis: a gene at last?

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Cloning of a human homologue of the mouse Tctex-5 gene within the MHC class I region

Using a positional cloning strategy to identify the hemochromatosis gene (HFE), we isolated seven cDNAs by cDNA selection from a region of 400 kilobases (kb) located near the HLA-A and HLA-F loci. In this paper, we report the study of one of the corresponding genes, referred to as HCG V (hemochromatosis candidate gene), localized 150 kb centromeric to HLA-A. This gene was found to be expressed ubiquitously in the form of a 1.8 kb transcript, and to be apparently well conserved during evolution. The gene spanned 3.1 kb and is organized in three exons and two introns. The cDNA of 1620 base pairs (bp) showed an open reading frame of 378 bp, encoding for a 126 amino acid polypeptide which displayed a strong identity with the predicted product of a mouse Tctex-5 gene (t complex, testis expressed) localized in the t complex on chromosome 17. The HCG V gene was assessed as a potential candidate for hemochromatosis in regard to its localization in the linkage disequilibrium area between HFE and polymorphic markers. The study of deletions and point mutations in hemochromatosis patients revealed a single bp polymorphism within the coding region; however, no associated disease changes were found. Therefore we conclude that HCG V is unlikely to be involved in the pathogenesis of hemochromatosis.

Structure and content of the major histocompatibility complex (MHC) class I regions of the great anthropoid apes

The origins of the functional class I genes predated human speciation, a phenomenon known as trans-speciation. The retention of class Ia orthologues within the great apes, however, has not been paralleled by studies designed to examine the pseudogene content, organization, and structure of their class I regions. Therefore, we have begun the systematic characterization of the Old World primate MHCs. The numbers and sizes of fragments harboring class I sequences were similar among the chimpanzee, gorilla, and human genomes tested. Both of the gorillas included in our study possessed genomic fragments carrying orthologues of the recently evolved HLA-H pseudogene identical to those found in the human. The overall megabase restriction fragment patterns of humans and chimpanzees appeared slightly more similar to each other, although the HLA-A subregional megabase variants may have been generated following the emergence of Homo sapiens. Based on the results of this initial study, it is difficult to generate a firm species tree and to determine human's closest evolutionary neighbor. Nevertheless, an analysis of MHC subregional similarities and differences in the hominoid apes may ultimately aid in localizing and identifying MHC haplotype-associated disease genes such as idiopathic hemochromatosis.

A new non-HLA multigene family associated with the PERB11 family within the MHC class I region

In an effort to initiate steps designed to characterize the idiopathic hemochromatosis disease gene, the HLA-A/HLA-F region where this gene is in disequilibrium linkage with some polymorphic markers has been overlapped by a yeast artificial chromosome (YAC) contig. In order to achieve the physical mapping of these YACs and of the corresponding genomic region, we subcloned one of the YACs involved. A computer-assisted analysis of the sequence of one subclone led to the isolation of a potential exon that proved to belong to a new expressed messenger named HCGIX. After Southern blot analysis, the corresponding cDNA clone was found to belong to a new multigene family whose members are dispersed throughout the HLA class I region and are closely associated with members of another recently described multigene family designated PERB11. The data reported here suggest that these two multigene families form a cluster that have been dispersed together throughout the telomeric part of the major histocompatibility complex and have been involved in the genesis of this human class I region.

Physical map of the HLA-A/HLA-F subregion and identification of two new coding sequences

As part of an effort to characterize the hemochromatosis gene, we selected three non-chimeric yeast artificial chromosomes (YACs) overlapping with the YAC B30 previously described and forming an 800 kilobase contig covering the HLA-A/HLA-F region. The precise physical map of these YACs and of the corresponding genomic region were established. Nine concentrated sites of CpG cutter elements, potentially HTF islands, were mapped. In addition, several probes have been generated as tools for mapping and examining transcripts produced in the region. This allowed for the characterization and localization of two new coding sequences, provisionally named HCG (for hemochromatosis candidate gene) and numbered VIII and IX.

Allelic association of microsatellites of 6p in Italian hemochromatosis patients

Hemochromatosis (HC) is an inherited disorder of iron metabolism and is frequently seen in Caucasians. The biochemical defect and the responsible gene are unknown, but the HC locus is closely linked to HLA-A on human chromosome 6 in the region 6p21.3. Although extensive studies have been performed in several populations, the precise location of the gene is still undefined. Linkage disequilibrium with HC has been detected for loci that are 3 cM apart: HLA class I and D6S105, which is located on the telomeric side of HLA-A. We have analyzed the inheritance of several multi-allele polymorphisms that map to 6p (D6S265, Y52, HLA-F, D6S306, D6S105, D6S464, D6S299) in 34 Italian HC families and in 17 unrelated patients. Significant association with HC was shown for alleles of multiple markers in the HLA-A region, for the distant marker D6S105, but not for the D6S299 marker at 4 cM from HLA-A on the telomeric side. HC status was unambiguously assigned to 70 affected and 63 unaffected chromosomes from family studies. Thirty five different haplotypes were found in 70 HC chromosomes when considering four markers most tightly associated with the disease. A predominant haplotype comprising alleles 1-3-1-8 (marker order D6S265, HLA-A, Y52, D6S105) accounted for 30% of the HC chromosomes and was absent in normals. A minority of other HC haplotypes could be related to the major haplotype by assuming single crossover events. Results of haplotype studies suggest a founder effect in the Italian population, as previously shown in Australian patients, and a possible common mutation shared with affected individuals of Celtic origin.

Allelic associations and homozygosity at loci from HLA-B to D6S299 in genetic haemochromatosis

Haemochromatosis (GH) is an autosomal recessive disorder in which increased iron absorption causes iron overload. The gene (HFE) is closely linked to HLA-A on chromosome 6 (6p21.3) but has not yet been identified. We have examined eight polymorphic loci, HLA-B (most centromeric), I82, D6S265, HLA-A, D6S128, HLA-F, D6S105, and D6S299 (most telomeric) in 37 unrelated patients and 60 control subjects. There are also significant positive associations between GH and alleles at all loci except D6S299. Analysis of 48 GH chromosomes in which haplotypes could be established showed that the most common haplotype was I82-2:D6S265-1:HLA-A3:D6S128-2:HLA-F1:D6S105-8. This was present in 28 of 48 chromosomes. In 14 the haplotype included HLA-B7 but only in seven did this extend beyond the telomere to D6S299-2 (the most common allele on GH chromosomes at this locus). In 36 out of 48 chromosomes the two locus haplotype, F1:D6S105-8 was present. Since haemochromatosis appears to originate from a founder mutation we have examined linkage disequilibrium between these various loci and GH using calculations of pexcess. The maximum value (0.72, 95% CI 0.55-0.85) is given by D6S105-8 but is not significantly different from values for HLA-A3 and HLA-F1 (0.50, 95% CI 0.34-0.61 and 0.49, 0.25-0.66 respectively). However, both HLA-A and D6S105 give a value for pexcess which is significantly higher than that for the most centromeric marker, HLA-B (0.17, 95% CI 0.02-0.30). We have counted the number of patients who are homozygous for the common allele at each locus. At D6S105, 22 patients are homozygous for allele 8, with 18 homozygous for HLA-F1 and 10 homozygous for A3. The pattern of cumulative homozygosity suggests a gene location closer to D6S105 than HLA-A. We have also analysed our data for divergence from the apparent founder haplotype (A3:F1:105-8) and have calculated the theoretical frequencies of crossovers between loci. These data suggest a location telomeric to D6S105. A more precise localisation of the gene may be possible with the identification of new markers around D6S105.

Localization of new genes and markers to the distal part of the human major histocompatibility complex (MHC) region and comparison with the mouse: new insights into the evolution of mammalian genomes

We have refined and extended the map of the distal half of the human major histocompatibility complex. The map is continuous from HLA-E to 1000 kb telomeric of HLA-F and includes six new markers and genes. In addition, the corresponding sequences that were not previously mapped in the mouse genome have been located. The human and the mouse organizations have therefore been compared. This comparison allows us to demonstrate that the structure of the distal part of the MHC is similar in the two species. In addition, this comparison shows the presence of a breakpoint of synteny telomeric of the distal part of the H-2 region. Indeed, the region telomeric of HLA in human is found on a chromosome different from that carrying H-2 in mouse. The mapping analysis of paralogous genes (structurally related genes) around the breakpoint shows that the human organization probably represents the putative human/mouse ancestral one. This evolutionary breakpoint was precisely mapped in human, and the surrounding region was cloned into yeast artificial chromosomes. Finally, we show that the region found around the breakpoint was involved several times in chromosome recombinations in the mouse lineage, as it seems to correspond also to the t-complex distal inversion point.

Non-homologous recombination within the major histocompatibility complex creates a transcribed hybrid sequence

The P5-1 cDNA clone maps to the human MHC class I region (Vernet et al. 1993a). In this paper, we show that the P5-1 cDNA represents a chimeric transcript in which the first exon of an MHC class I gene has been spliced to an unrelated sequence. The corresponding gene P5-1 is composed of the 5' sequence of an MHC class I gene including the promoter region, the first exon, and the half of the first intron fused to an unrelated intron, followed by a large exon. Furthermore, the non-class I part of P5-1 is present within the MHC class I region in multiple copies, defining the P5 family. Another member of the P5 family is fused to a class I gene, although by a type of rearrangement different from P5-1. These two fusion events between members of HLA class I and P5 families reflect the existence of a duplication unit including two class I genes and a P5 sequence. These data shed light on the MHC class I evolution and on the creation and evolution of new genes.

Genetics of haemochromatosis

This review is largely concerned with the frequency of genetic haemochromatosis (GH) and attempts to find the gene responsible. Studies of disease prevalence are reviewed along with the association of GH with other inherited disorders. The high prevalence of the disorder found in a number of surveys of populations of European origin along with the relatively few patients presenting with the clinical features of the advanced disease remains a paradox. The tight linkage between HLA-A and GH has been known since 1975 but it has not been possible to distinguish between a telomeric or centromeric location for the gene (HFE) relative to HLA-A. The recent explosion in detailed knowledge of the genetic map of the region telomeric of HLA-A on chromosome 6p has made it possible to examine new genetic markers. The very strong association between GH and D6S105-8 suggests a gene location telomeric to HLA-A. The lack of a precise location, and uncertainty about either the primary biochemical abnormality or the tissues involved has delayed the identification of the gene but expressed genes in the region around HLA-A are now being isolated and tested.

Isolation of genes from cloned DNA

During the past year, improvements in the physical and genetic maps of the human genome, in combination with more efficient methods to isolate genes from cloned DNA, have made an increasing impact on the identification of disease genes. Sequence analysis of genomic DNA and the random sequencing and mapping of cDNA clones is helping to integrate the transcript map with the developing physical and genetic maps.

Alleles at D6S265 and D6S105 define a haemochromatosis-specific genotype

Hereditary haemochromatosis is an HLA-linked, recessive disorder with HLA-A3 a strong marker for the gene. We have identified molecular markers for two serologically indistinguishable subtypes of HLA-A3 and examined these in 42 patients with haemochromatosis. The common HLA-A3 subtype HLA-A*0301 (highly correlated with allele 1 of D6S265) was a slightly better marker for haemochromatosis (RR = 10.1, Chi2 = 30) than the serologically recognized A3 antigen (RR = 9.1; Chi2 = 27.3). Allele 8 of the more telomeric locus D6S105 was also strongly associated with haemochromatosis (RR = 13.0; Chi2 = 21.1) but alleles at this locus were not in strong linkage disequilibrium with HLA-A alleles in the control subjects. The co-occurrence of D6S265-1 and D6S105-8 alleles yielded a higher risk (RR = 16.9; Chi2 = 44). Homozygosity for the haplotype including these markers was specific for haemochromatosis, i.e. did not occur in 376 healthy subjects but was observed in 21.4% of patients. These results refine the HLA-A3 association with haemochromatosis, suggest that the haemochromatosis gene is located on the telomeric side of HLA-A and define a possible haplotype in which the first mutation may have occurred.

Genes in one megabase of the HLA class I region

To define the gene content of the HLA class I region, cDNA selection was applied to three overlapping yeast artificial chromosomes (YACs) that spanned 1 megabase (Mb) of this region of the human major histocompatibility complex. These YACs extended from the region centromeric to HLA-E to the region telomeric to HLA-F. In addition to the recognized class I genes and pseudogenes and the anonymous non-class-I genes described recently by us and others, 20 additional anonymous cDNA clones were identified from this 1-Mb region. We also identified a long repetitive DNA element in the region between HLA-B and HLA-E. Homologues of this element were located at several sites in the human genome outside of the HLA complex. The portion of the HLA class I region represented by these YACs shows an average gene density as high as the class II and class III regions. Thus, the high gene density portion of the HLA complex is extended to more than 3 Mb.

MHC genes in autoimmunity

In the last year progress has been made towards elucidating the roles of the MHC gene products in autoimmunity. A major advance has been the recent determination of the crystallographic structure of the human MHC class II molecule, which will be invaluable in delineating the minimum structural requirements for peptides that induce autoimmune disease. In addition, the use of animal models and transgenic mouse technology is continuing to increase our understanding of the involvement of the MHC gene products in immunopathogenesis.

A cosmid library specific for human chromosome regions 6p21.3 and 6q27

We have explored the potential of irradiation-fusion gene transfer (IFGT) hybrids as a source of well-defined human chromosome fragments from which probes can be derived. Extensive characterization of the IFGT hybrid 4J4 with a full panel of markers from Chromosome (Chr) 6 showed that the human DNA content derives largely from 6p21.3 and 6q27. A cosmid library has been constructed from 4J4 DNA, and 370 recombinants containing human DNA have been isolated and overlapping clones ordered into 20 contigs. Regional localization of representative clones from each contig, determined by fluorescent in situ hybridization (FISH), places 13 contigs in 6q27 and 6 in 6p21.3. Preliminary screening of cDNA libraries with selected cosmids has identified two expressed sequences. Since there are a number of medically important genes in both these regions of human Chr 6 with several disease loci linked to the HLA-A region in 6p21.3 and various tumor suppressor genes to 6q27, this library will provide a valuable resource to aid the isolation of candidate genes for these diseases. In addition, unique markers for detailed physical and genetic mapping of these regions of human Chr 6 can be easily obtained.