Mapping of the class II region of the human major histocompatibility complex by pulsed-field gel electrophoresis

Mechanisms of genetically-based resistance to malaria

Malaria remains one of the most prevalent parasitoses worldwide. About 350 to 500 million febrile episodes are observed yearly in African children alone and more than 1 million people die because of malaria each year. Multiple factors have hampered the effective control of this disease, some of which include the complex biology of the Plasmodium parasites, their high polymorphism and their increasingly high resistance to antimalarial drugs, mainly in endemic regions. The ancient interaction between malarial parasites and humans has led to the fixation in the population of several inherited alterations conferring protection against malaria. Some of the mechanisms underlying protection against this disease are described in this review for hemoglobin-inherited disorders (thalassemia, sickle-cell trait, HbC and HbE), erythrocyte polymorphisms (ovalocytosis and Duffy blood group), enzymopathies (G6PD deficiency and PK deficiency) and immunogenetic variants (HLA alleles, complement receptor 1, NOS2, tumor necrosis factor-α promoter and chromosome 5q31-q33 polymorphisms).

Prenatal diagnosis: current status and future trends

Many of the major single-gene disorders in man can now be detected in utero using restriction fragment length polymorphisms (RFLPs). This approach is based on the knowledge of established linkage between RFLPs and mutations in an adjacent gene. The development of the polymerase chain reaction has altered the available approaches to this problem. This technique permits very rapid detection of the specific mutation from small amounts of starting material and may enable us to detect the genotype from fetal cells in maternal blood or from single cells in embryos before implantation. This may lead to the selection of embryos that lack a defect before they are implanted, avoiding the need for termination of pregnancy. Perhaps the greatest ethical challenge related to the application of these techniques will come with the understanding of the genetic basis for common polygenic disorders. The clarification of the multiple genetic factors responsible for a large part of susceptibility to diseases such as diabetes mellitus, rheumatoid arthritis or ischaemic heart disease will be greatly facilitated by a one-centimorgan genetic map. The strategy involved in establishing such a map, using the polymerase chain reaction, and then the identification of genetic loci responsible for susceptibility to a typical polygenic disease (insulin-dependent diabetes mellitus), is discussed. The ability to identify individuals at high risk of developing such diseases may present opportunities for early intervention.

The molecular genetics of HLA-related disorders

The HLA region on the short arm of chromosome 6 contains a set of highly polymorphic loci responsible for regulating the immune response. Particular haplotypes, defined serologically, have been associated with a risk of developing certain autoimmune diseases such as insulin-dependent (juvenile-onset) diabetes mellitus, multiple sclerosis and rheumatoid arthritis. Recent developments in molecular biology have permitted an improved resolution of the locus and of the sequential arrangement of the susceptibility determinants on these haplotypes. Restriction fragment length polymorphisms have allowed subdivisions of serological haplotypes to be made. These correlate with disease susceptibility in some cases. Amplification of specific HLA class II alleles and nucleic acid sequencing have resulted in the identification of the structural determinants in the HLA that underlie some of these diseases.

Sequence-based typing of HLA class II DQB1

Due to the expanding number of known HLA class II DQB1 alleles, high-resolution oligotyping is becoming ineffective, therefore a sequence-based typing (SBT) strategy was developed to provide rapid and definitive typing of HLA-DQB1. HLA-DQB1*02, *03, *04, *05, and *06 alleles were individually amplified by polymerase chain reaction (PCR) using exon 2 group-specific primers. Forward and reverse PCR primers were tailed with M13 universal and M13 reverse sequences, respectively. Subsequent bi-directional cycle-sequencing was carried out using Cy5.5-labeled M13 universal primer and Cy5.0-labeled M13 reverse primer. Automated sequencing was performed in 30 min using a Visible Genetics, Inc. (VGI) MicroGene Clipper Sequencer. Full concordance was observed between this SBT method and oligotyping among 151 individuals.

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.

High-resolution HLA typing for the DQB1 gene by sequence-based typing

The ideal high-resolution typing strategy for polymorphic genes is sequence-based typing. SBT of genomic DNA has been developed for the HLA class II genes DRB1, DRB3/4/5 and DPB1. For the DQB1 gene the sequence-based typing method was shown to cause a number of problems. To resolve those problems, different primers to amplify and sequence exon 2 of DQB1 were designed and tested. With several primer combinations, preferential amplification was observed in individuals heterozygous for DQB1*02/*03 and DQB1*02/*04. The preference was for DQB1*02 in many instances but could also be demonstrated for DQB1*03 or *04 and resulted occasionally in allelic drop-out. The best primer combination was selected and successfully used to type individuals heterozygous for DQB1*02, *03 and *04. To distinguish DQB1*0201 and *0202, primers for amplification and sequencing of exon 3 were developed and correct subtyping was obtained. The ambiguous typing DQB1*0301/*0302 and DQB1*0303/*0304 was resolved by allele-specific amplification and sequencing. A total of 258 individuals were fully typed for their DQB1 subtypes. All samples had been previously typed by PCR-SSP and serology. Concordant typing results were obtained for all individuals tested. The DQB1 alleles detected included *0501, *0502, *0503, *0601, *0602, *0603, *0604, *0609, *0201, *0202, *0301, *0302, *0303, *0304, *0401 and *0402. Sequence-based typing of the DQB1 gene proved a reliable typing strategy for assignment of the different DQB1 alleles after intensive selection of primers and test conditions.

Zooming in on the human-mouse comparative map: genome conservation re-examined on a high-resolution scale

Over the past decade, conservation of genetic linkage groups has been shown in mammals and used to great advantage, fueling significant exchanges of gene mapping and functional information especially between the genomes of humans and mice. As human physical maps increase in resolution from chromosome bands to nucleotide sequence, comparative alignments of mouse and human regions have revealed striking similarities and surprising differences between the genomes of these two best-mapped mammalian species. Whereas, at present, very few mouse and human regions have been compared on the physical level, existing studies provide intriguing insights to genome evolution, including the observation of recent duplications and deletions of genes that may play significant roles in defining some of the biological differences between the two species. Although high-resolution conserved marker-based maps are currently available only for human and mouse, a variety of new methods and resources are speeding the development of comparative maps of additional organisms. These advances mark the first step toward establishment of the human genome as a reference map for vertebrate species, providing evolutionary and functional annotation to human sequence and vast new resources for genetic analysis of a variety of commercially, medically, and ecologically important animal models.

A new HLA-DQB1*0306 allele sharing motifs from DQB1*03032 and DQB1*04 sequences

We have discovered a new HLA-DQB1 allele in a Japanese family, MAT. In the family the new allele segregates in three generations and demonstrates the positive association with DRB1*0901. We observed a novel RFLP pattern in the course of examining the modified PCR-RFLP method for HLA-DQB1 genotyping. The PCR-SSOP analysis also showed a new hybridized pattern. Sequence analysis of the allele indicates that it was generated by a gene conversion-like event between the HLADQB1*03032 and one of DQB1*04 contemporary alleles. This new allelic product did not react with all of allosera and monoclonal antibodies against DQ1, DQ2, DQ3, DQ4 and DQ7. The HLA molecule encoded by the allele is not defined by serology. This new allele was officially recognized and named DQB1*0306 by the WHO Nomenclature Committee in November 1995.

Is decreased blood plasma concentration of the complement C4B protein associated with attention-deficit hyperactivity disorder?

OBJECTIVE

The complement system is a group of blood proteins that play an important role in defending against viral and bacterial infections. The objective of this investigation was to study the plasma levels of the C4B protein in attention-deficit hyperactivity disorder (ADHD) in an attempt to associate infections with the development of some cases of this disorder.

METHOD

C4B plasma protein levels were studied using an enzyme-linked immunosorbent assay in a group of 23 subjects meeting DSM-III-R criteria for ADHD and a similar number of age- and sex-matched controls. Also studied were parents of the ADHD subjects.

RESULTS

C4B plasma levels (157.0 micrograms/mL) in the ADHD subjects were significantly (p < .01) lower than those (239.3 micrograms/mL) in the normal age-matched subjects. Mothers of the ADHD subjects also had significantly lower C4B values compared with mothers of normal children. On the other hand, C4B values in the fathers were not significantly altered.

CONCLUSIONS

Decreased C4B levels in ADHD, if replicated, may represent an important marker for ADHD (or a subgroup of ADHD). It also seems plausible that C4B levels are an important etiological factor for ADHD.

Genes, genes and more genes in the human major histocompatibility complex

The human major histocompatibility complex (MHC), on the short arm of chromosome 6, represents one of the most extensively characterised regions of the human genome. This approximately 4 Mb segment of DNA contains genes encoding the polymorphic MHC class I and class II molecules which are involved in antigen presentation during an immune response. Recently the whole of the MHC has been cloned in cosmids and/or yeast artificial chromosomes (YACs) and large portions have been characterised for the presence of novel genes. Many unrelated genes, both housekeeping and tissue specific, have been identified and the gene density in some regions is now approaching one gene every few kilobases. Some of the novel genes encode proteins involved in the intracellular processing and transport of antigens that are presented by MHC class I molecules. Others, however, have no obvious role in the immune response. The MHC is located in the chromosome band 6p21.3 which is a Giemsa (G)-light band. The detection of such a large number of functional genes (at least 70) in this region is compatible with the idea that both housekeeping and tissue-specific genes are localised predominantly in G-light bands.

Association of primary biliary cirrhosis with the allele HLA-DPB1*0301 in a German population

The major histocompatibility complex class II alleles at the HLA-DPB1 locus were investigated in 32 German Caucasoid patients with primary biliary cirrhosis (PBC) and compared with those from 47 normal control patients using molecular genotyping techniques. The second exon of the HLA-DPB1 gene was amplified by polymerase chain reaction (PCR) and hybridized with 25 sequence-specific oligonucleotides (SSOs) to assign the HLA-DPB1 alleles on the basis of known sequence variations, according to the protocols of the Eleventh International Histocompatibility Workshop. A strong association of PBC was found with the allele HLA-DPB1*0301. The allele HLA DPB1*0301 was present in 50% (16 of 32) of the patients with PBC compared with 13% (6 of 47) of normal controls (P corrected < .015), whereas the other HLA-DPB1 alleles showed no significant differences in both groups. The relative risk (RR) estimate for the allele HLA-DPB1*0301 was 6.8 (95% confidence limits: 2.27 to 20.57). In summary, this study clearly demonstrates an association of PBC with the HLA-DPB1*0301 allele in German Caucasoids and may add new data to the immunogenetic background of PBC, suggesting a contribution of the HLA-DPB1 gene to the genetic susceptibility of the disease.

Gene frequencies and haplotypic associations within the HLA region in 916 unrelated Japanese individuals

The gene frequencies and haplotypic associations within the HLA region have been investigated in 916 unrelated Japanese individuals. HLA class I and class II antigens were studied by conventional serology, and class II alleles, DRB1, DRB3, DQA1, DQB1 and DPB1 were typed by using polymerase-chain reaction amplification and sequence-specific oligonucleotide probe (PCR-SSOP) method. Thirty DRB1, 3 DRB3, 8 DQA1, 15 DQB1 and 13 DPB1 alleles were found in our population. DR-NJ25, a characteristic antigen in the native American and Asian populations, was observed at 3.0%. This antigen was observed mainly with the DRB1*1403 and 1406 alleles. Twenty-seven out of 30 DRB1 alleles found in this study had a high positive linkage disequilibrium with DQB1 alleles and 20 of them had an exclusive association with one specific DQA1-DQB1 combination. The strong association between DRB1 alleles and HLA-B antigens was the most striking finding in this study. Twenty-eight out of 30 DRB1 alleles had a positive linkage disequilibrium with 24 HLA-B antigens (p < 0.01). The other two alleles, DRB1*0404 and 1402, were very rare, and their frequencies were 0.2% and 0.1%, respectively. The data presented in this population study should be useful for the studies on anthropology, organ transplantation and disease susceptibility.

Analysis of restriction fragment length polymorphism for the HLA-DR gene in Japanese patients with sarcoidosis

BACKGROUND

It is commonly assumed that some immunological disorder may play a part in the pathogenesis of sarcoidosis. Previous studies by several groups have shown a significant association with HLA-DR antigens in patients with sarcoidosis. In this study, restriction fragment length polymorphism (RFLP) analysis of the HLA-DR gene was designed to confirm the association at the gene level and to look for a gene rearrangement which may influence susceptibility to sarcoidosis.

METHODS

Thirty two unrelated Japanese patients with sarcoidosis were tested for HLA antigens and subjected to RFLP analysis after digestion with Eco RI, Pst I, Bam HI, Pvu II, and Hind III by using an HLA-DR beta cDNA probe. A group of 47 unrelated healthy Japanese subjects served as controls. Frequencies of each restriction fragment were compared between the patients and the control subjects. Correlation between fragment frequencies and clinical features were also analysed.

RESULTS

No restriction fragments of HLA-DR beta gene were found specific to the patients with sarcoidosis. The RFLP analysis could detect polymorphism of HLA-DR beta genes that was not distinguishable by conventional serological methods. Several restriction fragments of the DR beta gene were seen only in DRw52 positive individuals, and showed higher frequencies in the patients than in control subjects. The patients with these DNA fragments were likely to have limited stage disease with no ophthalmic involvement.

CONCLUSIONS

An association between HLA and sarcoidosis was noted at the DNA level, although no restriction fragments were specific for this disease. RFLP analysis of the HLA gene is a more useful method than the usual HLA typing, and should be the first step in identifying the gene sequence which is connected with susceptibility to sarcoidosis.

Comparison of restriction enzyme analysis versus pulsed-field gradient gel electrophoresis as a typing system for Torulopsis glabrata and Candida species other than C. albicans

Candida species have recently emerged as important nosocomial pathogens. Because of the lack of a reliable system for detecting differences within the same species, little is known about the epidemiology of infection with Candida species. We describe a typing system for Torulopsis glabrata and the non-C. albicans Candida species that uses contour-clamped homogeneous electric field electrophoresis (CHEF), a version of pulsed-field gradient gel electrophoresis, and compared it with restriction enzyme analysis (REA) of genomic DNA. One hundred seventeen clinical isolates from 40 patients were evaluated. CHEF and REA were performed on each of the isolates, and the results of the two procedures were compared. The REA procedure revealed 8 different types of Candida lusitaniae, 20 of Torulopsis glabrata, 5 of Candida tropicalis, 3 of Candida parapsilosis, and 7 of Candida kefyr, whereas the CHEF method revealed 14 different types of C. lusitaniae, 16 of T. glabrata, 10 of C. tropicalis, 10 of C. parapsilosis, and 7 of C. kefyr. The CHEF technique yielded unique patterns of electrophoretic karyotypes that could be used to distinguish intraspecies variations. When compared with REA, CHEF demonstrated greater sensitivity in recognizing subtle strain-to-strain variations in most isolates and will be a useful epidemiologic tool for studying non-C. albicans Candida species and T. glabrata.

MHC-extended haplotypes in families of patients with Graves' disease

MHC-extended haplotypes were investigated in multiplex families of patients with hyperthyroid GD. Using a combination of both phenotypic (serology and protein electrophoresis) and genotypic (DNA-RFLP) markers, 159 MHC-extended haplotypes extending from HLA-A across the MHC class III (C2, Bf, C4A, and C4B) toward the HLA-DR/DQ complex were deduced from 217 (51 and 166 affected and unaffected) members of 21 families of patients with GD. Thyroid autoantibodies were measured and found positive in 27.1% of 166 clinically euthyroid unaffected members. Extended haplotypes were classified into four categories--affected (n = 40), Aff/Ab + ve (shared haplotype between affected and Ab + ve members, n = 31), Ab + ve (n = 29), and Ab - ve (n = 59)--based on the presence and absence of these haplotypes in 51 affected members with GD and 45 and 121 unaffected members who were respectively positive and negative for thyroid autoantibodies. Five recombinations were detected: three were found between HLA-A and B and two between HLA-B and the MHC class III. No recombination was found between or within the MHC class III and class II complex. Though the HLA-DR17 (DR beta 17(1) and DR beta 17(2)) allele was found to be significantly increased in both the affected and the Aff/Ab + ve when compared with the Ab - ve haplotypes (p < 0.042 and p < 0.018), the frequency of the HLA-B8, 2.7-kb SstI-4.5-kb TaqI/C2 Bf*S, 6.4-kb TaqI/C4A*Q0C4B*1, HLA-DR beta 17(1)/DQ alpha 2-DQ beta 2a extended haplotype was found to be significantly increased only in the affected haplotype (p < 0.05). These results suggest that while HLA-DR17 is a susceptibility allele shared between GD and individuals with positive thyroid autoantibodies, the HLA-B8, 2.7-kb SstI-4.5-kb TaqI/5'-3'C2 Bf*S, 6.4-kb TaqI/C4A*Q0B*1, DR beta 17(1)/DQ alpha 2-DQ beta 2a is a disease susceptibility-extended haplotype for Graves' disease.

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.

Family study on HLA-DPB1 polymorphism: Linkage analysis with HLA-DR/DQ and two “new” alleles

An extensive family study on HLA-DPB1 was performed in 105 families living in northeastern Japan. In a linkage study between HLA-DPB1 and other HLA loci, five apparent recombinations between DPB1 and DR/DQ loci were observed. The recombination frequency (theta) with maximum probability was estimated to be 0.017 by the lod score method. DPB1 allele and haplotype frequencies in unrelated parents were determined by direct counting. The most common allele was DPB1*0501 with the frequency of 41.2% and the second was DPB1*0201 with 24.0%. Nine DPB1-DR and six DPB1-DQ haplotypes were in significant linkage disequilibrium. Seven kinds of extended haplotypes were observed to be over 1%, in which the most common haplotype A24-B52-DR15-DQ6-DPB1*0901 occurred at 6.0%. Moreover, we found two "new" DPB1 alleles in this study. The first one possesses a single base substitution from DPB1*0501 resulting in an amino acid change. The other is most likely to be formed by an intraexonic recombination between DPB1*0301 and DPB1*0501.

Structural similarity of the HLA-DQ region in DQ3 and DQ4 haplotypes and structural diversity of the HLA-DQ region in HLA-DR7 haplotypes

Genomic DNA obtained from a B lymphoblastoid cell line was digested with appropriate restriction endonuclease and hybridized with several probes specific for genes encoding HLA-DQ. Southern hybridization with a DQA1 3'untranslated (UT) region probe showed DQ2-type hybridization pattern in DR7DQ3 haplotype. On the contrary, DQB1 3'UT probe showed DQ3-type pattern in the same haplotype. Gene cloning and DNA sequencing analysis revealed a repetitive sequence, (TG)19, between DQA1 and DQB1 gene in the DR7DQ3 haplotype. These results suggest that a recombination event has occurred near this potential Z-DNA structure in the haplotype, DR7DQ3. The 3'UT region probes of DQA1 and DQB1 genes failed to detect restriction fragment length polymorphism (RFLP) differences between DR4DQ3 and DR4DQ4 haplotypes in this experiment, suggesting that the gene structure between DQA1 and DQB1 is conserved in these haplotypes.

Trans-species evolution of Mhc-DRB haplotype polymorphism in primates: organization of DRB genes in the chimpanzee

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

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.

HLA and disease

Many human diseases are associated with HLA class I, class II and class III antigens. It appears that the class III antigen disease associations can be explained by a direct defect operating at the level of either the class III gene or its gene product. The mechanism underlying class I and class II antigen disease associations is at present unknown. In this review we have considered thirty diseases which have been ranked according to their relative risk as defined by the frequency of a given HLA antigen in patient and control populations. The chronic inflammatory disorder, ankylosing spondylitis and its association with HLA B27 has been used as a model to study the HLA linked diseases. We have suggested that the disease may be caused by the Gram-negative microorganism Klebsiella which has antigenic similarity to HLA B27. It is proposed that some antibodies made against Klebsiella bind to HLA B27, thereby acting as autoantibodies leading to the pathological sequelae of chronic inflammatory arthritis. This is the crosstolerance hypothesis or molecular mimicry model and it has been compared to the receptor model. It is further suggested that the crosstolerance hypothesis can be utilised as a general theory to explain the association of other diseases with the class I and class II antigens, and offer a possible explanation for the polymorphism of HLA.

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.

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.

Orientation of HLA-DNA gene and identification of a CpG island-associated gene adjacent to DNA in human major histocompatibility complex class II region

We have constructed the detailed physical map of the HLA class II gene region by the pulsed field gel electrophoresis (PFGE) and cosmid walking technique. In this process, the DNA gene was found to be located telomeric to DPA1 with the 5'----3' orientation which is the same as the DPA1 and DPA2 genes, but opposite to the DQA1, DQA2 and DRA genes. This orientation is reverse to that of the counterpart gene in the rabbit major histocompatibility complex region. About 30 kb downstream from the DNA gene towards DOB, a CpG island characterized by clustered sites for rare cutting restriction enzymes and frequently associated with the 5' end of housekeeping genes was identified by PFGE and cosmid walking. From a complementary DNA (cDNA) library constructed from a Epstein-Barr virus-transformed B-cell line, a cDNA clone was isolated using the genetic probe from this CpG island. Its nucleotide sequences suggested that it represented a new non-HLA gene with a single copy which was of little genetic polymorphism and named NAT (DNA-associated transcript). Northern blot analysis showed that the NAT gene was expressed with a 4-kb transcript in all of tissues examined so far.

HLA DQB1*0301 allele is involved in the susceptibility to erythema multiforme

Erythema multiforme (EM) is an acute, episodic inflammatory disorder of the skin and mucous membranes of various etiology that could be related to immunologic hypersensitivity response. EM has been previously reported to be associated with serologically defined HLA-DRw53 and DQw3 antigens. In this report, we reevaluate the role of HLA class II alleles in EM manifestations. With use of the polymerase chain reaction, followed by sequence-specific oligonucleotide hybridization, 35 unrelated Caucasian EM patients and 80 randomly selected healthy subjects were studied, and the DRB3, DRB4, DQA1, and DQB1 alleles were analyzed. The comparison of frequencies of these alleles indicates that (i) susceptibility to EM disease is more associated with the HLA-DQ than the HLA-DR subregions and (ii) that the DQB1*0301 is the most frequent allele among EM patients. Sixty-six percent of the patients had the DQB1*0301 allele compared to 31% of the controls (RR = 4.1; p less than 0.001). An even stronger DQB1*0301 association was found in the patient group with herpes-associated EM (76%; RR = 6.5; p less than 0.001). Our data demonstrate a clear association between an HLA-DQB1 allele and susceptibility to EM.

Long-range physical mapping of the alpha-amylase-1 (alpha-Amy-1) loci on homoeologous group 6 chromosomes of wheat

Long-range physical maps of the small multigene family of the malt alpha-amylase genes (alpha-Amy-1) located on the long arms of wheat chromosomes 6A (the alpha-Amy-A1 locus) and 6B (alpha-Amy-B1) were generated by pulsed-field gel electrophoresis analysis. By using three methylation-sensitive rare-cutter restriction endonucleases, NotI, NruI and MluI, and an alpha-Amy-1 cDNA probe and four gene-specific genomic probes from the alpha-Amy-B1 locus, the size of the alpha-Amy-A1 locus was estimated to be about 700 kb and of the alpha-Amy-B1 locus to be about approximately 4300 kb. These two maps indicate clustering of GC-rich and C-methylation-sensitive restriction enzyme recognition sites. At least five regions reminiscent of 'CpG islands' are apparent in alpha-Amy-B1, and three in alpha-Amy-A1. Correlation between recombination frequency and physical distance within the alpha-Amy-B1 locus suggests that 1 cM approximates to 1 Mb in physical distance.

Purification of BsuE methyltransferase and its application in genome mapping

We have used a combination of BsuE methyltransferase (M-BsuE) and NotI restriction enzyme to cut genomic DNA at a subset of NotI sites. The usefulness of this system is shown in a re-examination of the restriction map of the human MHC. Combinations of methylases and restriction enzymes can be used to generate cuts at different frequencies in genomic DNA, such that they generate ends complementary to NotI ends, and can be used in conjunction with NotI linking clones in chromosome jumping experiments. These enzyme combinations have the potential to produce cutting sites in genomic DNA spaced at intervals favorable for extensive mapping, fragment enrichment, and cloning efforts.

Colinearity of novel genes in the class II regions of the MHC in mouse and human

To examine the degree of conservation of gene organization in and around the class II regions of the major histocompatibility complexes of mouse and human, we have established the positions of sequences homologous to five human non-class II genes (RING1-5) in mouse, and the positions of sequences homologous to three mouse non-class II genes (KE3-5) in human. The resulting comparative map reveals that the organization of genes in the entire proximal region of the MHCs of mouse and human is remarkably conserved, apart from the H-2K gene pair in mouse, which can be accounted for by a 60 kilobase (kb) insertion. The characterization of the novel human gene RING5 is also presented. This gene, which is widely expressed, maps 85 kb proximal to the DPB2 gene. Partial nucleotide sequencing of a RING5 cDNA clone reveals that it is the human homolog of the mouse KE4 gene.

New genes in the class II region of the human major histocompatibility complex

A detailed map of the class II region of the human major histocompatibility complex has been constructed by pulsed-field gel electrophoresis. This map revealed clusters of sites for enzymes that cut preferentially in unmethylated CpG-rich DNA often found at the 5' ends of genes. Three of these clusters have been cloned by cosmid walking and chromosome jumping. Analysis of the clones encompassing these regions through the use of zoo blots, Northern blots, and cDNA libraries resulted in the discovery of four novel genes. The D6S111E and D6S112E genes are centromeric to the HLA-DPB2 gene, while D6S113E and D6S114E are between HLA-DNA and HLA-DOB. Preliminary characterization of the new genes indicates that they are unrelated to the class II genes themselves, although D6S114E expression, like class II expression, is inducible with interferon. In addition, the HLA-DNA gene has been accurately positioned and oriented for the first time.

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.

Comparison of restriction enzyme analysis and pulsed-field gradient gel electrophoresis as typing systems for Candida albicans

Candida species are an important cause of infection in immunocompromised hosts and the leading cause of nosocomial fungal infections. Study of the epidemiology of Candida infection has been difficult because of lack of a reliable typing system. We describe a typing system utilizing contour-clamped homogeneous electric fields (CHEF), which is a modified version of pulsed-field gradient gel electrophoresis, and compared it with restriction enzyme analysis (REA) of genomic DNA. The study was done with 35 Candida albicans clinical isolates from separate patients. CHEF and REA were performed on each isolate, and the patterns were compared. The REA procedure revealed 17 strain types while the CHEF procedure was able to distinguish 23 strain types of C. albicans. The CHEF technique yields unique patterns of chromosomal bands that can be used to distinguish clinical isolates and demonstrates greater sensitivity than REA.

The structure of human MHC class II genes

The class II molecules of the human major histocompatibility complex bind intracellularly processed peptides and present them to T-helper cells. They therefore have a critical role in the initiation of the immune response. A salient feature of the class II molecules is their polymorphism. It has been shown that some autoimmune diseases are associated with certain class II alleles. This article reviews the basic structural features of class II molecules, and the genes encoding them as well as mechanisms governing the development of their extraordinary polymorphism.

Mapping of the SLA complex of miniature swine: mapping of the SLA gene complex by pulsed field gel electrophoresis

The overall order of the regions of the swine major histocompatibility complex (MHC), the SLA complex, was determined by pulsed field gel electrophoresis (PFGE). It was found that the order of the regions is class II-class III-class I. A class I probe hybridized to a 420 kb Mlu I and a 420 kb Not I fragment as did a class III probe for C2. None of the class II probes hybridized to these fragments. Thus, linkage of class I to class III was shown. The class III C2, Bf, and C4 genes were found to residue in a 190 kb Not I fragment. Linkage of class III and class II genes was shown when both the class III C4 and the class II DR probes hybridized to the same 195 kb Sac II and 340 kb Not I fragments. The class I probe did not hybridize to these fragments. The order of the regions, class II-class III-class I, is similar to that of human MHC genes and may have been conserved in evolution so that coordinated expression of MHC genes could be achieved.

HLA-DQA2 (DX alpha) polymorphism and insulin dependent diabetes

A certain HLA-DQA2 locus TaqI fragment, DX alpha"U", has been reported to be associated with insulin-dependent diabetes mellitus (IDDM). Reports of various studies in this vein have ranged from stating that the association of DQA2"U" with IDDM exists even among subjects positive for HLA-DR3 and -DR4 to stating that the association of DQA2"U" with diabetes can be attributed to linkage disequilibrium between the DQA2"U" and some component(s) on the affected haplotypes. Using a synthetic 97-base probe corresponding to a portion of an intron of DQA2, in a Southern blot analysis of IDDM and control subjects from Wisconsin, we were able to confirm the association of DQA2"U" with diabetes. However, among DR3 subjects there was no significant association between DQA2"U" and diabetes (p = 0.26). Although there was a (nonsignificant) association of IDDM with DQA2"U" among DR4-positive subjects (p = 0.14), this can be completely attributed to linkage disequilibrium between DQA2"U" and DQw8. We also sequenced most of the second exon (corresponding to the alpha 1 domain of the DQA2 glycoprotein) from five individuals that were homozygous for either DQA2"U" or DQA2"L." The only polymorphisms observed were a "silent" mutation at position 36 and one example of a difference that would result in a change of amino acid at position 41.

Physical mapping by PFGE localizes the COL3A1 and COL5A2 genes to a 35-kb region on human chromosome 2

The genes encoding the alpha 1 chain of Type III collagen (COL3A1) and the alpha 2 chain of Type V (COL5A2) collagen have been mapped to the long arm of human chromosome 2. Linkage analysis in CEPH families indicated that these two genes are close to each other, with no recombination in 37 informative meioses. In the present study, DNA probes from the 3' ends of each gene have been physically mapped by pulsed-field gel electrophoresis. The probes recognized 11 macrorestriction fragments in common, ranging from greater than 1000 kb MluI and NotI fragments to a 35-kb SfiI fragment. Therefore, the COL3A1 and COL5A2 genes appear to exist as a gene cluster on chromosome 2. This is the third example of a collagen gene cluster. Other examples include the COL4A1-COL4A2 genes on chromosome 13q and the COL6A1-COL6A2 genes on chromosome 21q. The physical proximity of these genes may indicate common evolution and/or regulation.

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.

Rapid HLA-DPB typing using enzymatically amplified DNA and nonradioactive sequence-specific oligonucleotide probes

A simple and rapid method for characterizing the polymorphism at the HLA-DPB1 locus has been developed. The procedure involves the selective amplification of the polymorphic second exon of the DPB1 locus by the polymerase chain reaction (PCR), followed by hybridization of the amplified DNA with 15 nonisotopic sequence-specific oligonucleotide probes. There are no sequences within the second exon of the DPB1 locus that uniquely define an allele; rather, each allele appears to arise from the shuffling of a limited number of polymorphic nucleotide sequences in six regions of variability. Consequently, individual alleles are identified by the pattern of hybridization of the 15 probes. Two formats for typing are described. In Format I (the dot-blot), the amplified DNA is ultraviolet (UV) cross-linked to a nylon membrane and hybridized with the oligonucleotide probes which are covalently labeled with horseradish peroxidase (HRP). In Format II (the reverse dot-blot), the oligonucleotides, which have poly-T tails, are bound to the membrane and the immobilized array of probes is hybridized to the PCR product which has incorporated biotinylated primers during the amplification process. In both formats, hybridization is detected by a simple colorimetric reaction. The application of this technology to the fields of tissue typing and individual identity is discussed.

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.

Endogenous retroviral long terminal repeats within the HLA-DQ locus

Two endogenous retroviral long terminal repeats (LTRs) were found in the human major histocompatibility complex locus HLA-DQ. The solo LTRs, unlinked to retrovirus structural genes, are located approximately 5 kilobases apart from each other and in the same transcriptional orientation, which is opposite to that for the HLA-DQB1 gene. These elements exhibit greater than 90% homology to the LTRs of the human endogenous retrovirus HERV-K10. The conservation of putative regulatory elements found within the LTRs and their position relative to the HLA-DQB1 gene suggest that these elements may confer distinct regulatory properties on genes in the HLA-DQ region. Polymorphic variation between different HLA haplotypes for the presence of the LTRs at this location and of the molecular architecture within this subregion is supported by polymerase chain reaction and Southern blot analysis. Comparisons of chromosomes with and without the LTRs in this region will provide a unique opportunity in the human genome to analyze transposition or integration of retroviral sequences.