An analysis of variation in the long-range genomic organization of the human major histocompatibility complex class II region by pulsed-field gel electrophoresis

Genetic analysis of completely sequenced disease-associated MHC haplotypes identifies shuffling of segments in recent human history

The major histocompatibility complex (MHC) is recognised as one of the most important genetic regions in relation to common human disease. Advancement in identification of MHC genes that confer susceptibility to disease requires greater knowledge of sequence variation across the complex. Highly duplicated and polymorphic regions of the human genome such as the MHC are, however, somewhat refractory to some whole-genome analysis methods. To address this issue, we are employing a bacterial artificial chromosome (BAC) cloning strategy to sequence entire MHC haplotypes from consanguineous cell lines as part of the MHC Haplotype Project. Here we present 4.25 Mb of the human haplotype QBL (HLA-A26-B18-Cw5-DR3-DQ2) and compare it with the MHC reference haplotype and with a second haplotype, COX (HLA-A1-B8-Cw7-DR3-DQ2), that shares the same HLA-DRB1, -DQA1, and -DQB1 alleles. We have defined the complete gene, splice variant, and sequence variation contents of all three haplotypes, comprising over 259 annotated loci and over 20,000 single nucleotide polymorphisms (SNPs). Certain coding sequences vary significantly between different haplotypes, making them candidates for functional and disease-association studies. Analysis of the two DR3 haplotypes allowed delineation of the shared sequence between two HLA class II-related haplotypes differing in disease associations and the identification of at least one of the sites that mediated the original recombination event. The levels of variation across the MHC were similar to those seen for other HLA-disparate haplotypes, except for a 158-kb segment that contained the HLA-DRB1, -DQA1, and -DQB1 genes and showed very limited polymorphism compatible with identity-by-descent and relatively recent common ancestry (<3,400 generations). These results indicate that the differential disease associations of these two DR3 haplotypes are due to sequence variation outside this central 158-kb segment, and that shuffling of ancestral blocks via recombination is a potential mechanism whereby certain DR-DQ allelic combinations, which presumably have favoured immunological functions, can spread across haplotypes and populations.

Complete MHC haplotype sequencing for common disease gene mapping

The future systematic mapping of variants that confer susceptibility to common diseases requires the construction of a fully informative polymorphism map. Ideally, every base pair of the genome would be sequenced in many individuals. Here, we report 4.75 Mb of contiguous sequence for each of two common haplotypes of the major histocompatibility complex (MHC), to which susceptibility to >100 diseases has been mapped. The autoimmune disease-associated-haplotypes HLA-A3-B7-Cw7-DR15 and HLA-A1-B8-Cw7-DR3 were sequenced in their entirety through a bacterial artificial chromosome (BAC) cloning strategy using the consanguineous cell lines PGF and COX, respectively. The two sequences were annotated to encompass all described splice variants of expressed genes. We defined the complete variation content of the two haplotypes, revealing >18,000 variations between them. Average SNP densities ranged from less than one SNP per kilobase to >60. Acquisition of complete and accurate sequence data over polymorphic regions such as the MHC from large-insert cloned DNA provides a definitive resource for the construction of informative genetic maps, and avoids the limitation of chromosome regions that are refractory to PCR amplification.

Comparative Genomic Analysis of Two Avian (Quail and Chicken) MHC Regions

We mapped two different quail Mhc haplotypes and sequenced one of them (haplotype A) for comparative genomic analysis with a previously sequenced haplotype of the chicken Mhc. The quail haplotype A spans 180 kb of genomic sequence, encoding a total of 41 genes compared with only 19 genes within the 92-kb chicken Mhc. Except for two gene families (B30 and tRNA), both species have the same basic set of gene family members that were previously described in the chicken "minimal essential" Mhc. The two Mhc regions have a similar overall organization but differ markedly in that the quail has an expanded number of duplicated genes with 7 class I, 10 class IIB, 4 NK, 6 lectin, and 8 B-G genes. Comparisons between the quail and chicken Mhc class I and class II gene sequences by phylogenetic analysis showed that they were more closely related within species than between species, suggesting that the quail Mhc genes were duplicated after the separation of these two species from their common ancestor. The proteins encoded by the NK and class I genes are known to interact as ligands and receptors, but unlike in the quail and the chicken, the genes encoding these proteins in mammals are found on different chromosomes. The finding of NK-like genes in the quail Mhc strongly suggests an evolutionary connection between the NK C-type lectin-like superfamily and the Mhc, providing support for future studies on the NK, lectin, class I, and class II interaction in birds.

A male-specific increase in the HLA-DRB4 (DR53) frequency in high-risk and relapsed childhood ALL

Previous studies reported significant HLA-DR associations with various leukemias one of which is with HLA-DRB4 (DR53) family in male patients with childhood ALL. We have HLA-DR-typed 212 high-risk or relapsed patients with childhood (n=114) and adult (n=98) ALL and a total of 250 healthy controls (118 children, 132 adult) by PCR-SSP analysis. The members of the HLA-DRB3 (DR52) family were underrepresented in patients most significantly for HLA-DRB1*12 (P=0.0007) and HLA-DRB1*13 (P=0.0001). In childhood ALL, the protective effect of DRB3 was evident in homozygous form (P=0.001). The DRB4 marker frequency was increased in males with childhood ALL (67.4%) compared to age- and sex-matched controls (42.1%, P=0.003) and female patients (35.7%, P=0.004). Besides being a general marker for increased susceptibility to childhood ALL in males, HLA-DRB4 is over-represented in high-risk patients. These results further suggest that the HLA system is one of the components of genetic susceptibility to leukemia but mainly in childhood and in boys only.

Extensive genetic alterations of the HLA region, including homozygous deletions of HLA class II genes in B-cell lymphomas arising in immune-privileged sites

In B-cell lymphomas, loss of human leukocyte antigen (HLA) class I and II molecules might contribute to immune escape from CD8+ and CD4+ cytotoxic T cells, especially because B cells can present their own idiotype. Loss of HLA expression and the possible underlying genomic alterations were studied in 28 testicular, 11 central nervous system, and 21 nodal diffuse large B-cell lymphomas (DLCLs), the first two sites are considered as immune-privileged sites. The analysis included immunohistochemistry, loss of heterozygosity analysis, and fluorescent in situ hybridization (FISH) on interphase cells and isolated DNA fibers. Total loss of HLA-A expression was found in 60% of the extranodal cases and in 10% of the nodal cases (P < .01), whereas loss of HLA-DR expression was found in 56% and 5%, respectively (P < .01). This was accompanied by extensive loss of heterozygosity within the HLA region in the extranodal DLCLs. In 3 cases, retention of heterozygosity for D6S1666 in the class II region suggested a homozygous deletion. This finding was confirmed by interphase FISH that showed homozygous deletions in the class II genes in 11 of the 18 extranodal lymphomas but in none of the 7 nodal DLCLs (P < .001). Mapping by fiber FISH showed variable deletions that always included HLA-DQ and HLA-DR genes. Hemizygous deletions and mitotic recombinations often involving all HLA genes were found in 13 of 18 extranodal and 2 of 7 nodal lymphomas. In conclusion, a structural loss of HLA class I and II expression might help the B-cell lymphoma cells to escape from immune attack.

Extensive genetic alterations of the HLA region, including homozygous deletions of HLA class II genes in B-cell lymphomas arising in immune-privileged sites

In B-cell lymphomas, loss of human leukocyte antigen (HLA) class I and II molecules might contribute to immune escape from CD8+ and CD4+ cytotoxic T cells, especially because B cells can present their own idiotype. Loss of HLA expression and the possible underlying genomic alterations were studied in 28 testicular, 11 central nervous system, and 21 nodal diffuse large B-cell lymphomas (DLCLs), the first two sites are considered as immune-privileged sites. The analysis included immunohistochemistry, loss of heterozygosity analysis, and fluorescent in situ hybridization (FISH) on interphase cells and isolated DNA fibers. Total loss of HLA-A expression was found in 60% of the extranodal cases and in 10% of the nodal cases (P &lt; .01), whereas loss of HLA-DR expression was found in 56% and 5%, respectively (P &lt; .01). This was accompanied by extensive loss of heterozygosity within the HLA region in the extranodal DLCLs. In 3 cases, retention of heterozygosity for D6S1666 in the class II region suggested a homozygous deletion. This finding was confirmed by interphase FISH that showed homozygous deletions in the class II genes in 11 of the 18 extranodal lymphomas but in none of the 7 nodal DLCLs (P &lt; .001). Mapping by fiber FISH showed variable deletions that always included HLA-DQ and HLA-DR genes. Hemizygous deletions and mitotic recombinations often involving all HLA genes were found in 13 of 18 extranodal and 2 of 7 nodal lymphomas. In conclusion, a structural loss of HLA class I and II expression might help the B-cell lymphoma cells to escape from immune attack.

Recombination within the human MHC

Recombination (crossing over) in the human MHC is thought to have played a role in generation of novel alleles at various HLA loci. It is also responsible for the diversity observed at the haplotype level, although the functional consequences of this activity are not clear. Historic and family studies of recombination have provided estimations of recombination fractions across the MHC and identified potential hotspots for recombination in the class II region. Other characteristics of recombination in the human MHC such as haplotype specificity in recombination frequency and localized sequence motifs involved in recombination have been considered, but have been difficult to address given the constraints of human population studies. Single-sperm typing holds promise in overcoming some of the limitations inherent in the study of recombination in human populations. Both family-based and sperm typing analyses of recombination, along with our knowledge of linkage disequilibrium patterns in the MHC, may provide novel information regarding the evolution of HLA haplotypes that will be difficult to obtain by other means.

DQA-DQB linkage in Old World monkeys

The MHC DQ region in nonhuman primates, as in humans, consists of alpha and beta chains that are polymorphic with strong linkage disequilibrium between certain DQA-DQB alleles. Not only are contemporary HLA class II allelic variants present in evolutionarily distant species, but we demonstrate that linkages between loci also bear ancient roots. In unrelated baboons (Papio cynocephalus anubis) and family segregation analysis of pigtailed macaques (Macaca nemestrina) we found cis-linkages between DQA1*01 and DQB1*05 or *06, between DQA1*05 and DQB1*03, and between DQA1*03 and DQB1*03 alleles, all of which are also prominent in modern humans. In contrast, one linkage that has not been seen in humans, between DQA1*05 and DQB1*06 alleles, was also found. These patterns of selective linkage disequilibrium imply evolutionary mechanisms following the divergence of species that constrain the diversity of haplotypes which evolve.

The gene G13 in the class III region of the human MHC encodes a potential DNA-binding protein

G13 is a single-copy gene lying approx. 75 kb centromeric of the complement gene cluster in the class III region of the human MHC. The gene spans approx. 17 kb of DNA and has been shown to encode mRNA of approx. 2.7 kb that is present in cell lines representing lymphoid and non-lymphoid tissues, indicating that it is ubiquitously expressed. The complete nucleotide sequence of the 2.7 kb mRNA has been derived from cDNA and genomic clones. The longest open reading frame obtained for G13 codes for a 703 amino acid protein of approx. 77 kDa in molecular mass. Comparison of the putative G13 amino acid sequence with the protein databases revealed significant similarities with DNA-binding proteins of the leucine zipper class, including a human cAMP response element binding protein. G13 contains a bZIP motif, a region rich in basic amino acids adjacent to a coiled-coil leucine zipper domain, common to this class of proteins that is known to be involved in dimerization and DNA binding. Antibodies raised against a fragment encoding the C-terminal half of the putative G13 protein recognized a major polypeptide of approx. 86 kDa and a minor polypeptide of approx. 78 kDa on immunoblotting of U937 cell extracts; this has been confirmed by immunoprecipitation experiments. Even though it contained at least one potential bipartite nuclear localization signal, the G13 protein was present both in the cytoplasm and the nucleus of the fibroblast cells. Thus G13 might be a novel DNA-binding protein that is perhaps translocated to the nucleus in a regulated manner.

Extended HLA profile of an inbred isolate: the Schmiedeleut Hutterites of South Dakota

HLA-A, -B, -C, -DR, and -DQ typings of the Schmiedeleut Hutterites of South Dakota were collected as part of an ongoing genetic-epidemiologic study of HLA and fertility. A total of 1,082 individuals, including 852 married adults representative of the reproductive population of this isolate, were characterized for five-locus HLA haplotypes. HLA-A1, A2, A3, and A24 accounted for 75% of observed HLA-A alleles and HLA-B27, B35, B51, and B62 accounted for 55% of observed HLA-B alleles. S-leut Hutterites are derived from 68 or fewer ancestors. However, only 48 ancestral HLA haplotypes were observed and nine of these accounted for over 52% of the observed haplotypes. Measures of two-locus linkage disequilibrium derived from these haplotypes indicated that one-third to half of the observed HLA-A/B, B/DR, and A/DR allele combinations exhibited highly statistically significant linkage disequilibrium. Allele and haplotype frequencies did not differ between males and females. Recombination rates of 0.004% and 0.005% between HLA-A and -C and between HLA-B and -DR, respectively, were observed. This HLA profile points out a paucity of HLA alleles and haplotypes in this population and marked linkage disequilibrium among the HLA alleles that are present.

The minimal polymorphism of class II E alpha chains is not due to the functional neutrality of mutations

Given the extensive allelic amino acid sequence polymorphism present in the first domain of A alpha, A beta, and E beta chains and its profound effects on class II function, the minimal polymorphism in the mouse E alpha chain (and in its human homologue DR alpha) is paradox. Two possible explanations for the lack of polymorphism in E alpha are: (1) the E alpha chain plays such a uniquely critical structural/functional role in antigen presentation, T-cell activation, repertoire selection, and/or pairing with E beta or other proteins for expression that it cannot vary, and mutations are selected against; (2) the E alpha chain plays a less significant role than the outer domains of other major histocompatibility complex (MHC) proteins in determining the interactions with processed peptides or with T-cell receptor (TCR), so there is no selective pressure to maintain new mutations. To explore this question we compared the ability of transfectants expressing wild type (wt) E alpha E beta d and mutant E alpha wt E beta d proteins to present peptides and bacterial superantigens to T-cell hybridomas. Mutations at the E alpha amino acid positions 31, 52, and 65&66, to residues that represent allelic alternatives in A alpha chains, significantly reduced activation of peptide-specific T hybridomas, and mutations at 71 sometimes enhanced T-cell stimulation. None of the E alpha mutations reduced, and some enhanced, superantigen stimulation of T-cell hybridomas. These results argue against the hypothesis that E alpha chains are minimally polymorphic because mutations in E alpha are functionally neutral.

The G9a gene in the human major histocompatibility complex encodes a novel protein containing ankyrin-like repeats

The class III region of the human major histocompatibility complex spans approx. 1.1 Mbp on the short arm of chromosome 6 and is known to contain at least 36 genes. The complete nucleotide sequence of a 3.4 kb mRNA from one of these genes, G9a (or BAT8), has been determined from cDNA and genomic DNA clones. The single-copy G9a gene encodes a protein product of 1001 amino acids with a predicted molecular mass of 111,518 Da. The C-terminal region (residues 730-999) of the G9a protein has been expressed in Escherichia coli as a fusion protein with the 26 kDa glutathione S-transferase of Schistosoma japonicum (Sj26). The fusion protein has been used to raise antisera which, in Western-blot analysis, cross-react specifically with an intracellular protein of approx. 98 kDa. The function of the G9a protein is unknown. However, comparison of the derived amino acid sequence of G9a with the protein databases has revealed interesting similarities with a number of other proteins. The C-terminal region of G9a is 35% identical with a 149 amino acid segment of the Drosophila trithorax protein. In addition the G9a protein has been shown to contain six contiguous copies of a 33-amino acid repeat. This repeat, originally identified in the Notch protein of Drosophila and known as the cdc10/SW16 or ANK repeat, is also found in a number of other human proteins and may be involved in intracellular protein-protein interactions.

MHC class II haplotypes and linkage disequilibrium in primates

The loci encoding the major histocompatibility class II cell surface antigens DR, DQ, and DP exhibit a remarkable degree of allelic polymorphism. Strong linkage disequilibrium is also found between these loci in the human population. To study the evolutionary conservation of this disequilibrium the DQA1, DQB1, and DRB1-6 loci were analyzed in chimpanzee and gorilla by sequencing or/and oligonucleotide hybridization of PCR-amplified DNA. This analysis revealed several new DRB sequences. The distribution of DRB loci differs between human and nonhuman primate haplotypes, and the strong disequilibrium found on human haplotypes between alleles at DQA1 and DQB1 as well as between the DQ loci and the DRB1 locus was not detected in the nonhuman hominoids. Extensive recombination within and between the DR and DQ region appears to have occurred during the 3-7 million years since the divergence of the three species, resulting in little similarity of haplotypes between species. The strong disequilibrium found in the human species between these loci may either reflect haplotype-specific barriers to recombination, recent founder effects in the evolution of humans, or selection for specific haplotypes.

Rheumatoid arthritis

Rheumatoid arthritis is often considered to be an autoimmune disease in which the abnormal immunological response is triggered by an infectious agent(s) but progress towards identifying such extrinsic factors has so far been unrevealing. In contrast, the genetic component of host susceptibility is slowly becoming clearer. In particular, the nature of the HLA class II association with the disease has led to new insights into its pathogenesis and possible novel forms of therapy.

Comparative anatomy of the primate major histocompatibility complex DR subregion: evidence for combinations of DRB genes conserved across species

The class II region of the human major histocompatibility complex (HLA) is made up of three major subregions designated DR, DQ, and DP. With the aim of gaining an insight into the evolution and stability of DR haplotypes, a total of 63 cosmid clones were isolated from the DR subregion (Gogo-DR) of a western lowland gorilla. All but one of these cosmid clones were found to fall into two clusters. The larger cluster, A, was defined by 41 overlapping cosmid clones and contained a DRB gene segment made up of exons 4 through 6 and four DRB genes, designated Gogo-DRB6, Gogo-DRB5*01, Gogo-DRB8, and Gogo-DRB3*01. The total length of this cluster was approximately 180 kb. The second cluster, B, encompassed a contiguous DNA stretch of approximately 145 kb and was composed of 21 overlapping cosmid clones. Cluster B contained three DRB genes, designated Gogo-DRB1*08, Gogo-DRB2, and Gogo-DRB3*02. One cosmid clone (WP1-9) containing a DRB pseudogene could not be linked to either cluster A or B. Neither the organization of cluster A nor that of cluster B was identical to that of known HLA-DR haplotypes. However, two gorilla DRB genes, Gogo-DRB6 and Gogo-DRB5*01, the human counterparts of which are linked in the HLA-DR2 haplotype, were found to be located next to each other in cluster A. The arrangement of the Gogo-DRB genes in cluster B, which is presumed to be the gorilla DR8 haplotype, was similar to that of HLA-DR3/DR5/DR6 haplotypes and to that of the presumed ancestral HLA-DR8 haplotype.(ABSTRACT TRUNCATED AT 250 WORDS)

Complexity in the major histocompatibility complex

The human major histocompatibility complex (MHC) is one of the most intensively studied regions of the human genome, containing over 70 known genes and spanning about 4 million base pairs (4 Mbp) of DNA on chromosome 6p21.3 (Klein, 1986). It can be divided up into three regions: the class I region (telomeric), the class II region (centromeric), and the class III region (between class I and II), which includes the complement component genes C2, C4, and Bf (Trowsdale & Campbell, 1988). The MHC has been mapped in detail using pulse field gel electrophoresis (PFGE) and by cloning in yeast artificial chromosome (YAC) and cosmid vectors, revealing long stretches of DNA between the regions as well as between individual class I and class II genes. Novel genes, that have no sequence relationships with class I, class II or complement components, have recently been found in these areas, and we will present an update on these after reviewing the more established loci.

Molecular linkage of the HLA-DR, HLA-DQ, and HLA-DO genes in yeast artificial chromosomes

Eight major histocompatibility complex (MHC) class II loci and the newly defined Y3/Ring 4 locus were isolated in overlapping yeast artificial chromosome (YAC) clones defining a 420-kb segment of human chromosome 6p21.3. YAC B1D12 spanning 320 kb contained seven of these loci from HLA-DRA to HLA-DQB2. A 330-kb YAC, A148A7, spanned from the HLA-DQA1 locus through the Y3/Ring 4 locus and extended at least 130 kb centromeric of YAC B1D12. Southern blotting demonstrated that YAC B1D12 derived from the HLA-DR3 haplotype and that YAC A148A7 derived from the HLA-DR7 haplotype of the heterozygous library donor. A third 150-kb YAC, A95C5, lay within this contig and contained only the HLA-DRA locus. A fourth 300-kb YAC, A76F11, was isolated by chromosome walking from the telomeric end of YAC B1D12. Probes isolated from the ends of the YAC genomic inserts have been used to confirm overlaps between the clones. These analyses demonstrated that the centromeric end of YAC A76F11 used the same genomic EcoRI cloning site as the telomeric end of YAC A95C5. YAC B1D12 used an EcoRI site only 2.1 kb telomeric of the aforementioned EcoRI site. These data suggest that certain EcoRI sites are used preferentially during construction of the library. These YACs complete the linkage of the DR and DQ subregions of the HLA complex in cloned DNA and provide the substrate for precise analysis of this portion of the class II region.

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

Cosmid genomic DNA clones have been used as hybridization probes in genomic Southern blot analysis to define restriction fragment length polymorphisms (RFLPs) in the major histocompatibility complex (MHC). Using 14 different enzymes and three overlapping cosmid clones we have detected six RFLPs in a 100 kilobase (kb) segment of DNA in the class III region extending centromeric of the TNFA gene toward HLA-DR. Four of the five RFLPs, defined using the enzymes Taq I, Rsa I, Hinc II, and Hind III, and detected by the cosmid clone cosM7B, map to a 29 kb segment of DNA that includes all of the recently described G2 (BAT2) gene and a large portion of the 3' end of the G3 (BAT3) gene. The different RFLP variants were established by analyzing the DNA from three informative families and a panel of 51 HLA-homozygous typing cell lines. CosM7B detects Taq I variants of 4.3 kb, and 2.9 kb or 2.8 kb, Rsa I variants of 2.9 kb or 2.4 kb, Hinc II variants of 5.8 kb or 3.8 kb and 1.4 kb, and a Hind III variant of 4.8 kb, while cosOT2 detects Taq I variants of 4.5 kb or 4 kb. The distribution of the Rsa I, Hinc II and Taq I RFLPs detected by cosM7B, and the Taq I RFLP detected with cosOT2, within the panel of cell line DNAs was assessed by Southern blotting. The 4.3 kb Taq I variant was observed in only one cell line with the extended haplotype HLA-A29, C-, B44, SC30, DR4. The other RFLPs, however, occurred much more frequently. The 2.8 kb Taq I variant was observed in 20% of haplotypes, the 2.9 kb Rsa I variant was observed in 42% of haplotypes, and the 5.8 kb Hinc II variant was observed in 12% of haplotypes analyzed. The 4.5 kb Taq I variant detected by the overlapping cosmid cosOT2 was present in 21% of haplotypes. Analysis of the RFLP variants with each other revealed seven different haplotypic combinations. Three of the haplotypic combinations were each subdivided into two subsets on the basis of the Nco I RFLP variant they carried at the TNF-B locus. These haplotypic combinations potentially allow differentiation among different extended haplotypes such as HLA-B8, SC01, DR3, HLA-B18, F1C30, DR3, and HLA-B44, FC31, DR7. The RFLPs detected by the cosmid clones thus provide new tools which will be useful in the further genetic analysis of the MHC class III region.

Molecular analysis of the MHC class II region in DR4, DR7, and DR9 haplotypes

Within the class II region of the major histocompatibility complex (MHC) the amount of DNA in the DR-DQ interval has been shown to be haplotype dependent, with those carrying the DR4, DR7, and DR9 specificities having been reported to contain 110-160 kilobases (kb) more DNA than haplotypes carrying the DR3 specificity. Certain subtypes of haplotypes carrying particular DR specificities are more closely associated with autoimmune diseases than others. With the prospect of the DNA perhaps containing a disease susceptibility locus, we have mapped eight DR4 and two DR7 homozygous cell lines and a DR7/9 heterozygous cell line together with a control DR3 cell line using pulsed field gel electrophoresis (PFGE) with the enzymes Bss H II, Pvu I, and Not I/Nru I. Our results, however, show that the presence and amount of the extra DNA is constant irrespective of the subtype. We have also tried to narrow down the position of insertion of the extra DNA using eight further rare-cutting enzymes but, due to the polymorphic nature of sites and/or differences in methylation in this region, it was not possible to refine it further than between DRA and DQA1/B1. This polymorphic nature of the DR-DQ region is unusual, considering the uniformity of rare cutter sites that has been observed within the rest of the class II, and class III, regions. The presence of this, and other, haplotype dependent variations in the DNA content of the DR subregion may be important with respect to recombination and will be particularly interesting if the additional DNA is found to contain novel genes.

Nucleotide sequence, polymorphism, and evolution of ovine MHC class II DQA genes

The nucleotide sequence of all exons and introns, excluding exon 1, of the ovine major histocompatibility complex (MhcOvar) genes analogous to the HLA-DQA1 and -DQA2 genes has been determined and the gene structure found to be similar to that reported for other species. The predicted amino acid sequences of the Ovar-DQA genes have been compared with the equivalent DQA genes in man, mouse, rat, rabbit, and cattle and used to determine the evolutionary relationships of the sheep class II genes to these other species. Northern blot analysis of sheep mRNA using exon specific probes for each of the two Ovar-DQA genes show that both genes are transcribed, whereas in humans there is no evidence that HLA-DQA2 is transcriptionally active. Restriction fragment length polymorphisms (RFLPs) have been used to define a polymorphic series of alleles in both Ovar-DQA genes and have indicated that the number of DQA genes is not constant in sheep as it is in humans, but varies with the haplotype.

Physical mapping of the human genome by pulsed field gel analysis

Detailed physical maps of large regions of the human genome are important for locating and cloning genes responsible for human hereditary diseases, as well as for obtaining a more detailed understanding of chromosome structure and evolution. Pulsed field gel electrophoresis provides one method for generating physical maps of non-methylated rare restriction endonuclease sites. This review summarizes recent progress in the isolation of region-specific mapping probes and in their application for the physical mapping of selected regions of the human genome.

Cloning of the HLA class II region in yeast artificial chromosomes

Yeast artificial chromosomes (YACs) have been applied to clone the entire class II region of the human major histocompatibility complex (MHC), including its flanking regions, in a contig over 1.5 million base pairs (bp) long. The human DNA inserts in the YACs have a size between 60 and 1300 kbp and were isolated from two EcoRI partial digest libraries. The gaps between DRA and DRB, DRB and DQA, and DOB and DPA, which had not been cloned by other means, have been bridged with YAC clones. The contig extends through the 400 kpb of DNA between the DRA and C4 genes, thus linking the class II region with the complement gene cluster in the class III region. The cloning in YACs has been supported by a conventional cosmid walk of 290 kbp in the C4-DRA region. Restriction enzyme sites in the YAC clones were compared to the sites in the cosmid walk, to published cosmid clones, and to the already existing physical maps, leading to a detailed characterization of a region of the human genome over 1500 kbp. The YAC clones will be valuable for functional analysis of the MHC.

Human major histocompatibility complex contains a new cluster of genes between the HLA-D and complement C4 loci

A new cluster of genes has been defined in the human Major Histocompatibility Complex class III region. The seven novel genes, G12 to G18, are localised in a 160 kb segment of DNA extending from the complement gene cluster towards HLA-DR. The genes were identified by isolation of cDNA clones using cosmid genomic inserts as hybridisation probes, and by the detection of the corresponding transcripts in Northern blot analysis. Characterisation of the cosmid genomic DNA inserts, in conjunction with pulsed field gel electrophoresis analysis of uncloned DNA, for the presence of clustered sites for infrequently cutting restriction endonucleases has revealed that at least 5 of the 7 genes are associated with HTF-islands. These unmethylated CpG-rich sequences are frequently found at the 5' ends of ubiquitously expressed genes. Together with previously published data 36 genes have now been defined in a 680kb stretch of DNA within the MHC. With one gene approximately every 20kb of DNA this represents the most densely packed region of the human genome so far characterised, and is of major significance in relation to the mapping and sequence analysis of the rest of the genome.

A gene in the human major histocompatibility complex class II region controlling the class I antigen presentation pathway

Major histocompatibility complex (MHC) class I molecules export peptides to the cell surface for surveillance by cytotoxic T lymphocytes. Intracellular peptide binding is critical for the proper assembly and transport of class I molecules. This mechanism is impaired as a result of a non-functional peptide supply factor gene (PSF) in several human mutant cell lines with genomic lesions in the MHC. We have now identified PSF in the MHC class II region by deletion mapping in mutants and chromosome-walking. PSF is homologous to mammalian and bacterial ATP-dependent transport proteins, suggesting that it operates in the intracellular transport of peptides.

Characterization of MHC ancestral haplotypes associated with insulin-dependent diabetes mellitus: evidence for involvement of non-HLA genes

Insulin-dependent diabetes mellitus (IDDM) is associated with several DR3- or DR4-containing ancestral haplotypes (AHs). Using pulsed field gel electrophoresis (PFGE), long range maps of 35 haplotypes have been derived and classified. Two diabetogenic DR3-containing AHs (8.1 and 18.2) possess deletions in the central non-HLA region; these have not been found on non-diabetogenic AHs tested to date. In addition, 8.1 and 18.2 also carry other deletions not found on other AHs. Three DR4 containing AH lack a Not I site, which may imply excision of an unidentified gene. These and other data suggest that deletions may be relevant to the pathogenesis of autoimmune disease, possibly through causing quantitative differences in autoimmune responses involved in IDDM. The MHC contains several regions of potential interest in relation to susceptibility to IDDM; these may explain the association with only certain DR3- and DR4-carrying AH and DR3,4 heterozygosity in terms of cis and trans interactions. On the other hand, the class II region may be particularly important in protection.

Megabase scale restriction fragment length polymorphisms in the human major histocompatibility complex

Pulsed-field gel electrophoresis of human peripheral blood lymphocyte DNA was used to ascertain the extent of megabase restriction fragment length variation in the HLA region of human chromosome 6 and to determine whether previously reported diversity was due to experimental variation or DNA polymorphism. Polymorphism was found to predominate in the vicinity of the class II DR, class III complement, and the class I A genes and to be limited or absent near the class II DP genes, the TNF genes, and the class I B and C genes. Thus, the MHC region is characterized by both fine and large-scale structural diversity.

Characterization of the class III region in different MHC haplotypes by pulsed-field gel electrophoresis

The class III region of the human major histocompatibility complex (MHC) in seven HLA haplotypes has been analyzed using pulsed-field gel electrophoresis (PFGE), restriction enzymes that cut genomic DNA infrequently, and Southern blotting. In particular, extensive mapping with the enzyme Bss HII, which generates fragments in the size range 8-280 kilobases (kb), has revealed that in the haplotypes studied the DNA content of the class III region does not appear to vary other than as previously observed at the C4 and CYP21 loci.

Large haplotype-specific differences in inter-genic distances in human MHC shown by pulsed field electrophoresis mapping of healthy and type 1 diabetic subjects

Type 1 diabetes is associated with extended haplotypes defined by combinations of specific alleles of genes in the MHC. We have used pulsed field gel electrophoresis mapping to examine the gross structure of the Class II region of the MHC and its relationship to susceptibility to Type 1 diabetes. We have studied heterozygous members of a family in which susceptibility to Type 1 diabetes is associated with an A1/B8/DR3 haplotype and resistance with A2/B7/DR2, an unrelated diabetic DR3,4 patient and a healthy DR4,w10 subject and a DR2/Dw2 cell line. Digestion was performed with the enzymes Sst II, Mlu I, and Pvu I and hybridization with 21-hydroxylase, DRA, DQB, DOB and DPA probes. Within the DQ/DR region the DR4- and DR7-bearing haplotypes studied contain insertions of 140-150kb relative to the DR3 haplotypes whilst the DR2 haplotype in the family was smaller than the DR3 haplotypes by 130kb, whilst that in the cell line was smaller by up to 220kb. This cell line, previously thought to be homozygous by consanguinity, was also shown to be heterozygous in the DP region. Although no differences between diabetic and healthy subjects were observed within the family, these differences in long-range structure may be of importance to the etiology of Type 1 diabetes, as well as to the evolution of the MHC.