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

Major histocompatibility complex class II-restricted antigen presentation across a species barrier: conservation of restriction determinants in evolution

The existence of at least three alleles of the HLA-DRB3 gene within the human population is evident. These alleles express DRw52 determinants and react with monoclonal antibody (mAb) 7.3.19.1. The polymorphic epitope recognized by 7.3.19.1 is not only present on human cells but is also expressed on chimpanzee (Pan troglodytes) class II-positive cells. The 7.3.19.1 determinant already existed before speciation of man and chimpanzee, and is at least 5,000,000 yr old. Two-dimensional gel electrophoresis demonstrated that the various HLA- and Patr-DRw52 molecules that are reactive with 7.3.19.1 exhibit isoelectric point differences due to primary amino acid heterogeneity, as was confirmed by sequencing data. Sequence comparison allowed us to map the binding site of mAb 7.3.19.1 to the alpha helix of the major histocompatibility complex (MHC) class II DRB1 domain surrounding the antigen-binding cleft. Despite MHC sequence variation, chimpanzee antigen-presenting cells can present antigen (purified protein derivative) to human T cell lines and vice versa. Only the HLA- and Patr-DRw52 molecules were shown to function as restriction elements for antigen presentation across this species barrier. It is concluded that these particular restriction determinants probably have been conserved in evolution. The HLA- and Patr-DRw52 molecules represent alleles displaying polymorphism that has been selected for in evolution. Such "biomutants" may thus be more useful to study the biological significance of MHC molecules than MHC variants that have been generated by in vitro mutagenesis experiments.

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.

Complotypes in pemphigus vulgaris: differences between Jewish and non-Jewish patients

Haplotypes of alleles of the major histocompatibility complex (MHC) complement genes BF, C2, C4A, and C4B are inherited as single highly polymorphic genetic units called complotypes. There are about a dozen complotypes with frequencies above about 0.01 in Caucasians. In the blistering disease pemphigus vulgaris, the complotypes SC21 and SB45 were found to be markedly elevated in patients compared with general Caucasian controls. The SC21 increase was in Ashkenazi Jewish patients exclusively (relative risk = 17 in that population), whereas SB45 was found solely in non-Jewish Caucasians (specific population relative risk = 57). Although these are unusually high relative risks, it is most unlikely that these complotypes represent susceptibility genes for pemphigus vulgaris. Rather, it is probable that they mark extended major histocompatibility complex haplotypes with fixed DNA so that independent examples in the population have the same alleles. It is likely that it is the class II genes on these haplotypes that confer susceptibility.

Congenital immunodeficiencies associated with absence of HLA class II antigens on lymphocytes result from distinct mutations in trans-acting factors

Coordinate regulation of HLA class II gene expression during development and coinduction of class II genes by soluble factors suggests that common trans-acting factor(s) control expression of these genes. In B-lymphoblastoid cell lines derived from two independent class II-deficient bare lymphocyte syndrome patients, we observed a drastic decrease in transcription rates of the class II genes. When these cell lines are fused, class II genes are reexpressed, indicating that immunodeficiencies in bare lymphocyte syndrome patients are the result of two distinct mutations. Further studies show that genes governing the expression of class II antigens fall into at least three complementation groups; two of these were previously unidentified in mutant cell lines generated in vitro. In addition, we report the identification of two discrete complexes, NFX1.1 and NFX1.2, that bind to the DRA X consensus element. Though the mutation in at least one mutant line generated in vitro (RJ2.2.5) affects products functioning via interaction with the X box, clear alterations in either NFX1.1 or NFX1.2 are not found in any of the mutant cell lines.

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

The class II region of the human major histocompatibility complex in seven common HLA haplotypes has been analyzed using pulsed-field gel electrophoresis, restriction enzymes that cut genomic DNA infrequently, and Southern blotting. This analysis has revealed that there are differences in the amount of DNA present in the DQ and DR subregions dependent on the haplotype. The class II region of the DR3 haplotype spans approximately 750 kb and has the same amount of DNA as the class II region of the DR5 and DR6 haplotypes. However, the DR2 haplotype has approximately 30 kb more DNA within the DR subregion. The DR4 haplotype has an additional approximately 110 kb of DNA within the DQ or DR subregions compared to the DR3, DR5, and DR6 haplotypes. These haplotype-specific differences could have some bearing both on the analysis of disease susceptibility and on the ability of chromosomes possessing different HLA haplotypes to recombine within the DQ/DR subregions.

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

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

Subtypes of HLA-DQ and -DR defined by DQB1 and DRB1 RFLPs: allele frequencies in the general population and in insulin-dependent diabetes (IDDM) and multiple sclerosis patients

We have used the HLA-DQB1 gene as a Southern hybridization probe with TaqI-digested genomic DNA in a study of 600 haplotypes from unrelated individuals and have characterized HLA-DQB1 RFLP patterns associated with the DR specificities DR1-DRw10 and DN1. For six of the specificities (DR2, 4, w6, 7, w8 and 9), we have also identified subtypes (multiple DQB1 band patterns). In a previous study (Cox et al. 1988), we identified RFLPs and subtypes with a DRB1 probe. Using the present results from DQB1 RFLPs to supplement those from DRB1 RFLPs, it was possible to discriminate among all the DR specificities with the exception of a minority of DR7 and DR9 subtypes. A comparison of DQB1 and DRB1 subtypes in the same subjects showed strong linkage disequilibrium for subtypes of some but not all DR specificities. We have also determined the allele frequencies of the DQB1 subtypes in controls and in patients with insulin-dependent diabetes mellitus (IDDM) or multiple sclerosis (MS). A consideration of subtypes in patients and controls indicated that for most DR specificities, neither IDDM nor MS was more strongly associated with any of the DQB1 subtypes than with the serologically defined DR antigens. The exceptions were the DQB1 patterns corresponding to the DQw3.2 subtype of DR4 and the rarer subtype of DR2, which were found in higher frequency in IDDM patients, as has been previously reported.

Monoclonal antibody definition of the DRB3 allele, HLA-Dw25

Monoclonal antibodies are powerful tools for analyzing HLA antigen polymorphism. We have investigated the serological and biochemical nature of the DRw52-related antigen defined by the monoclonal antibody NDS10. A detailed analysis of the population distribution of NDS10 reactivity revealed that the epitope was present on a subpopulation of DRw52 positive cells. A distinct pattern of reactivity was found within DR3 individuals: all of the B18,DR3 cells were NDS10 positive, whereas the A1,B8,DR3 cells were negative. All of the DR5(w11) cells and two of three DRw12 cells reacted with NDS10. NDS10 reactivity with DRw6 was not restricted to either of the serologically defined subtypes; three of 17 DRw13 and nine of 10 DRw14 cells were NDS10 positive. NDS10 was unreactive with all of the DRw8 cells tested. Two-dimensional gel analyses revealed that the NDS10 molecule precipitated from DR3, DR5(w11) and DRw6(w14) cell lines had an identical beta chain profile. These data indicate that NDS10 recognises the Dw25 allele of the DRw52 complex.

Large DNA separation using field alternation agar gel electrophoresis

The techniques for large DNA separation have developed from a seminal idea for field alternation which has transformed the field of DNA electrophoresis. This single innovation of pulsed field-gradient electrophoresis (PFGE) and the subsequent modifications have made a significant impact on molecular biology, eukaryote genetics, biopolymer research and diagnostic research. The apparatus types used for large DNA separation are depicted and critically compared with relation to molecular mass separation capabilities, straight-lane migration of samples, band sharpness and ease of operation. With these criteria in mind PFGE and orthogonal field alternation gel electrophoresis systems had a number of drawbacks, the principle one being the inability of these systems to give straight-lane migration. To a large extent this has restricted the widespread use of these systems. Field inversion gel electrophoresis produces straight-lane migration but was subject to an upper molecular mass limitation of 2 megabase pairs and tended to produce broader bands in the higher-molecular-mass areas. Transverse alternating field electrophoresis, rotating gel electrophoresis and contour-clamped homogeneous electric field electrophoresis systems where superior to all the other systems. They gave straight-lane migration, separation of chromosomes up to 10 megabase pairs, good resolution of bands and were all relatively simple to operate. Very little was found to separate these three electrophoresis systems. Field alternation electrophoresis has enabled a 500-fold increase in the size of DNA molecules that can be resolved in agar gels. Consequently, electrophoretic karyotypes of a number of organisms have been produced, while genome maps, gene locations and sequences of large areas of mammalian genomes are now being undertaken. The ability to separate entire chromosomes or large DNA fragments has, in conjunction with novel molecular biology techniques, enabled scientists to work backwards from large purified fragments or entire chromosomes to construct long-range genetic maps. The time saving alone when compared with the old techniques of using very small fragments to construct a picture of the gene or gene complex is commendable. The diagnostic role of large DNA separation and electrophoretic karyotyping is beginning to be explored, while the use of this technique for clinical studies of genetic disorders is well advanced. Very few innovations in nucleic acid separation have had as marked an influence on as many areas as field alternation electrophoresis. These techniques have brought mapping of the mammalian genome into the realms of possibility and is contributing in many sphere

A method for two-dimensional DNA electrophoresis (2D-DE): application to the immunoglobulin heavy chain variable region

The scarcity of single-copy probes creates difficulty in the generation of large-scale physical maps of mammalian gene families. A simple method of two-dimensional DNA electrophoresis (2D-DE) has been developed to overcome this problem. DNA (2 micrograms) is digested with a rare-cutting restriction endonuclease and size separated by pulsed-field gel electrophoresis (PFGE). The DNA, still contained within the lane of the PFGE gel, is digested with a second frequent-cutting restriction enzyme and is subjected to an electrical field perpendicular to that of the PFGE. 2D-DE allows the simultaneous mapping, to large restriction fragments, of all the genes detected by a particular probe. The human immunoglobulin variable region was used as an example for this procedure. Two VH5 genes, on 8- and 9-kb EcoRI fragments, were mapped to 200- and 65-kb SfiI fragments, respectively, by 2D-DE. This technique will be particularly useful in the generation of physical maps of complex human gene families and of repeat families.

Inherited immunodeficiency with a defect in a major histocompatibility complex class II promoter-binding protein differs in the chromatin structure of the HLA-DRA gene

A defect in a trans-regulatory factor which controls major histocompatibility complex class II gene expression is responsible for an inherited form of immunodeficiency with a lack of expression of human leukocyte antigen (HLA) class II antigens. We have recently described and cloned an HLA class II promoter DNA-binding protein, RF-X, present in normal B cells and absent in these class II-deficient regulatory mutants. Here we report that these in vitro results correlate with a specific change in the chromatin structure of the class II promoter: two prominent DNase I-hypersensitive sites were identified in the promoter of the HLA-DRA gene in normal B lymphocytes and found to be absent in the class II-deficient mutant cells. The same two prominent DNase I-hypersensitive sites were observed in normal fibroblastic cells induced by gamma interferon to express class II genes. Interestingly, they were also observed in the uninduced class II-negative fibroblastic cells, which have also been shown to have a normal RF-X binding pattern. We conclude that the two DNase I-hypersensitive sites in the HLA-DRA promoter reflect features in chromatin structure which correlate with the binding of the trans-acting factor RF-X and which are necessary but not sufficient for the expression of class II genes.

Disease resistance and immune response genes in cattle: strategies for their detection and evidence of their existence

The possibility of breeding or genetically engineering cattle for resistance to disease has tremendous potential for increasing the efficiency of milk and meat production. In cattle and other species, major genes that control humoral and cellular immune responses to a variety of antigens have been mapped to a chromosomal region known as the major histocompatibility complex. However, resistance or susceptibility to viral, bacterial, and parasitic diseases in noninbred species is often a complex phenotype, with age, stress, and physiologic status all being important factors in the outcome of infection. This paper reviews the function of major histocompatibility complex gene products and the relationship between polymorphism of these genes and infectious diseases. A discussion of strategies for detecting immune response genes and disease associations is presented, with particular reference to the problems and advantages of working with cattle. The present knowledge of the bovine major histocompatibility complex and its relationship to immune responsiveness and disease resistance are also reviewed, with special consideration given to enzootic bovine leukosis because of the significant relationship between alleles of the bovine lymphocyte antigen system and resistance or susceptibility to subclinical progression of bovine leukemia virus infection. Finally, potential applications of this research to genetic improvement and animal health are considered.

Saturation of human chromosome 3 with unique sequence hybridization probes

We have generated chromosome 3-specific recombinant libraries in both lambda and cosmid cloning vectors starting with somatic cell hybrids (hamster/human) containing either an intact chromosome 3 or a chromosome 3 with an interstitial deletion removing 75% of long-arm sequences. The libraries contained between 2 X 10(5) and 5 X 10(6) independent recombinants. Approximately 2% of the recombinants in these libraries contain inserts of human DNA. These were identified by hybridizing the recombinants to radioactively labeled total human DNA. Over 2500 recombinants containing human DNA were isolated from these various libraries and DNA was prepared from each of them. This represents 80,000 kb of cloned chromosome 3 sequences. One-third of the DNAs were digested with EcoRI or HindIII, and fragments free of repetitive sequences were radioactively labeled using random hexanucleotide primers and tested as unique sequence hybridization probes. Over 6500 of the fragments were tested and of these 758 were unique sequence probes with minimal or no background hybridization. Their hybridization only to chromosome 3 was verified. These probes, which were derived from 452 independent recombinants, should provide an effective saturation of human chromosome 3.

The DR3(w18),DQw4 haplotype differs from DR3(w17),DQw2 haplotypes at multiple class II loci

The polymorphism of HLA class II molecules in man is particularly evident when comparisons between population groups are made. This study describes a DR3 haplotype commonly present in the American black population. Unlike the Northern European population, in which almost all DR3 individuals are DQw2, approximately 50% of DR3-positive American blacks express a DQw4 allelic product. This study characterizes the DR subregion of that haplotype. cDNA sequence analysis has revealed a DR beta gene which differs at several positions from previously described DR3 beta 1 genes. It is postulated that a gene-conversion-like event with a DRw52 beta gene as donor has generated some of these differences. The haplotype carries a DRw52a allele as defined by oligonucleotide hybridization studies. DNA restriction fragment analysis using a family and several unrelated individuals has allowed us to identify DR alpha and beta fragments associated with the DR3(w18),DQw4 haplotype. The most striking observation is that the DR3(w18),DQw4 haplotype differs from DR3(w17),DQw2 haplotypes at multiple class II loci. Several genetic mechanisms including reciprocal recombination, gene conversion, and point mutation were involved in generating the differences between these haplotypes. Once established, the DR3(w18),DQw4 haplotype appears to be relatively stable in the population.

Transverse alternating field electrophoresis and applications to mammalian genome mapping

The transverse alternating field electrophoresis system is a pulsed field gel apparatus that has been used to separate DNA molecules that range in size from a few thousand to approximately 7 million base pairs. This apparatus uses a vertical gel and a simple electrode arrangement to produce electric fields that are uniform across all lanes of the gel. The velocity of identical molecules does not vary from lane to lane, and hence there is no distortion in the paths of the DNA. The performance of this system is illustrated here using the chromosomes from S. pombe and S. cerevisiae, and restriction enzyme digested mammalian DNA. The mobility of molecules up to 1100 kilobase pairs is linear with size and can be accomplished in overnight runs. Resolution of very large molecules requires electrophoresis for several days, but molecules from 200 to 7000 kilobase pairs can be separated on a single gel. This electrophoresis system has been used extensively in the construction of a physical map of human chromosome 21, and examples of this application are discussed.

A physical map including a new class I gene (cda12) of the human major histocompatibility complex (A2/B13 haplotype) derived from a monosomy 6 mutant cell line

To avoid interpretative problems due to restriction fragment length polymorphisms, the monosomy 6 mutant cell line BM19.7 was employed to establish a molecular map of the human major histocompatibility (HLA) complex in the A2,B13,Bw4,DRw6,DRw52,DQw1,DPw2 haplotype. Results were obtained mainly by field-inversion gel electrophoresis and Southern blotting techniques. The map extends to 4800 kb and includes the HLA complex with a length of 4200 kb. Five HTF islands could be positioned on the map. The class I region has a size of about 2000 kb and includes nonclassical HLA class I genes, some of which must be localized within 200 kb telomeric of HLA-A. A new class I gene, cda12, distinct from HLA-A, HLA-B, or HLA-C, has been localized within 50 kb from HLA-A. The class I region contains a gap of about 500 kb, just telomeric of HLA-C, in which further class I genes could not be detected. The class II region has a size of 1000 kb, which is separated from the class I region by about 1200 kb. The 5' end of the HLA-B gene is situated centromeric, giving an orientation opposite to that of the TNFA and TNFB loci. The estimated length of the HLA complex correlates well with its size determined cytogenetically using mutant cell lines with interstitial deletions.

Pulsed field gel electrophoresis techniques for separating 1- to 50-kilobase DNA fragments

Conventional agarose gel electrophoresis separates DNA using a static electric field. The maximum size limit for separation of DNA by this method is about 20 kilobase pairs (kb). A number of new electrophoretic techniques which employ periodic reorientation of electric fields permit separation of DNA well beyond this size limit. We sought to determine whether the use of very fast (millisecond) field switching could improve separation of DNA in the size range of 1 to 50 kb. Additionally, we have compared the resolution obtained with each of the different field switching regimens for DNA in this size range. Switching intervals of from 0.2 to 900 ms were used with unidirectional pulsing of a single electric field, with pulsed field gels, and with field inversion gel electrophoresis. Plotting the mobility of DNA as a function of size demonstrates that under the conditions used, each of these techniques offers comparable resolution. We also have examined the separation obtained when field inversion gels are run with forward and reverse fields of equal voltage and different durations, versus using fields of equal duration and different voltages. Field inversion which uses forward and reverse fields of different voltages yields resolution which is superior to the other methods examined.

A 12 megabase restriction map at the cystic fibrosis locus

We have constructed a physical map of the chromosomal region containing the cystic fibrosis locus using seven DNA markers and pulsed-field gel electrophoresis methods. The map includes cleavage sites for 8 rare-cutting restriction enzymes and spans over 12 megabases (Mb) of DNA, with one unlinked probe covering an additional 5 Mb. To our knowledge, this is the largest segment of human DNA which has been restriction-mapped to date. We can identify thirteen putative HTF islands spaced at intervals of 0.3-3.2 Mb. The region between loci D7S8 and MET, where the CF gene lies, includes 1.4-1.9 Mb of DNA.

Inherited immunodeficiency with a defect in a major histocompatibility complex class II promoter-binding protein differs in the chromatin structure of the HLA-DRA gene

A defect in a trans-regulatory factor which controls major histocompatibility complex class II gene expression is responsible for an inherited form of immunodeficiency with a lack of expression of human leukocyte antigen (HLA) class II antigens. We have recently described and cloned an HLA class II promoter DNA-binding protein, RF-X, present in normal B cells and absent in these class II-deficient regulatory mutants. Here we report that these in vitro results correlate with a specific change in the chromatin structure of the class II promoter: two prominent DNase I-hypersensitive sites were identified in the promoter of the HLA-DRA gene in normal B lymphocytes and found to be absent in the class II-deficient mutant cells. The same two prominent DNase I-hypersensitive sites were observed in normal fibroblastic cells induced by gamma interferon to express class II genes. Interestingly, they were also observed in the uninduced class II-negative fibroblastic cells, which have also been shown to have a normal RF-X binding pattern. We conclude that the two DNase I-hypersensitive sites in the HLA-DRA promoter reflect features in chromatin structure which correlate with the binding of the trans-acting factor RF-X and which are necessary but not sufficient for the expression of class II genes.

Remarkable sequence conservation of the HLA-DQB2 locus (DX beta) within the highly polymorphic DQ subregion of the human MHC

The HLA-D region of the major histocompatibility complex (MHC) is characterized by a remarkable diversity. Most of the HLA class II genes are highly polymorphic, and in addition, the number and organization of individual loci in that region varies in different haplotypes. This extensive allelic polymorphism of immune response genes has well-known functional implications. Within the HLA-D region, two loci, DQA2 and DQB2 (formerly called DX alpha and DX beta), represent a very special case: the detailed structure of these two genes is entirely compatible with expression, yet their expression has never been demonstrated in any tissue. Consequently, there exists no known corresponding protein product. Pseudogenes are known to accumulate mutations, as observed for instance in the case of HLA-DPA2,-DPB2, or -DRB2 genes. We have therefore investigated the extent of DQ2 genes' polymorphism by DNA sequence comparison and by oligonucleotide hybridization across a large number of different haplotypes, and compared it with other genes in the HLA-D region. We show here that, contrary to the adjacent DQ1 genes, DQ2 genes exhibit little and possibly no polymorphism. This conservation of DQ2 genes in many haplotypes indicates that the DQ1-DQ2 duplication event must have preceeded the extensive diversification of DQ1 genes and raises the puzzling question of why DQ2 genes have remained nonpolymorphic. This suggests that either these genes correspond to an unusually invariant region of the MHC or they are under a strong selective pressure for the conservation of the amino acid sequence of a putative DQ2 gene product. The latter would imply that the HLA-DQ2 genes are expressed into a protein product endowed with essential functional properties.

The molecular genetics of components of the complement system

Rapid progress has been made recently on the elucidation of the structural components of the complement system by the application of recombinant DNA techniques. The derived amino acid sequences of most of the complement proteins are now available through cDNA cloning, and significant progress has been made in the discovery of the genetic organization of the corresponding genes. The linkage of some of the complement component genes has been established through the study of phenotypic genetics. Of particular interest has been the mapping of two clusters of genes which encode proteins involved in the activation of C3. C2, C4 and factor B, three of the structural components of the classical and alternative pathway C3 convertases, are encoded by genes which map to the MHC on human chromosome 6. The linkage of the genes with each other in a 100 kb segment of DNA has been established through the isolation of overlapping cosmid clones of genomic DNA, and PFGE has defined the molecular map position of these genes within the class III region of the MHC. The regulatory proteins factor H, C4BP, CR1 and DAF, which are involved in the control of C3 convertase activity, are encoded by closely-linked genes (termed the regulators of complement activation or RCA linkage group) that have been mapped to human chromosome 1. PFGE has defined the linkage of the CR1, C4BP and DAF genes, together with the CR2 gene in an 800 kb segment of DNA, and it is clear that this technique will eventually be applied to the molecular mapping of other complement genes in relation to their flanking loci. Polymorphism is a feature of many of the complement proteins, especially those encoded by genes in the MHC class III region. Of these, C4 is by far the most polymorphic, and differences in gene size and gene number, in addition to the functional and antigenic differences in the gene products, have been recognized. Null alleles at either of the C4 loci are rather common and may be important susceptibility factors in some HLA-associated diseases, particularly SLE. The molecular basis of complement deficiency states has begun to be elucidated. In many cases, the deficiency is not caused by a major gene deletion or rearrangement, and techniques which detect single point mutations in DNA (Cotton et al, 1988) will have to be applied to fully characterize the nature of the defect.

Physical linkage of a human immunoglobulin heavy chain variable region gene segment to diversity and joining region elements

Antibody genes are assembled from a series of germ-line gene segments that are juxtaposed during the maturation of B lymphocytes. Although diversification of the adult antibody repertoire results in large part from the combinatorial joining of these gene segments, a restricted set of antibody heavy chain variable (VH), diversity (DH), and joining (JH) region gene segments appears preferentially in the human fetal repertoire. We report here that one of these early-expressed VH elements (termed VH6) is the most 3' VH gene segment, positioned 77 kilobases on the 5' side of the JH locus and immediately adjacent to a set of previously described DH sequences. In addition to providing a physical map linking human VH, DH, and JH elements, these results support the view that the programmed development of the antibody VH repertoire is determined in part by the chromosomal position of these gene segments.

Physical linkage of the genes for platelet membrane glycoproteins IIb and IIIa

The fibrinogen receptor on human platelets is a prototypic member of the integrin family and is composed of subunit glycoproteins IIb (gpIIb) and IIIa (gpIIIa) in a 1:1 stoichiometric ratio. We have isolated cDNA clones for gpIIb and gpIIIa and localized both genes to chromosome 17. In the current study, several approaches were used to localize and map the genes for gpIIb and gpIIIa. A preliminary evaluation of subchromosomal localization was performed by using a panel of mouse-human somatic cell hybrids that contain different amounts of the long arm of human chromosome 17. Southern hybridization to the DNA of these hybrids shows that both genes map near the thymidine kinase gene. In situ hybridization to intact human chromosomes localized both genes to the 17q21-22 region. To better define the physical distance between the two genes, we examined the genomic hybridization pattern of each cDNA probe to high molecular weight restriction fragments separated by pulsed-field gel electrophoresis. Serial hybridizations of the same filter have allowed construction of long-range Mlu I and Sfi I restriction maps spanning more than 500 kilobases. Finally, nonoverlapping portions of the cDNAs for both gpIIb and gpIIIa were used to probe Sfi I digests of genomic DNA separated by field-inversion gels. This confirmed that the genes are physically linked within the same 260-kilobase Sfi I fragment and suggests that the gene for gpIIb is located on the 3' side of the gene for gpIIIa. These results suggest that coordinate expression of gpIIb and gpIIIa may depend on physical proximity.

Characterization of class II alpha genes and DLA-D region allelic associations in the dog

Human major histocompatibility complex (HLA) cDNA probes were used to analyze the restriction fragment length polymorphism (RFLP) of the alpha genes of the DLA-D region in dogs. Genomic DNA from peripheral blood leucocytes of 23 unrelated DLA-D homozygous dogs representing nine DLA-D types (defined by mixed leucocyte reaction) was digested with restriction enzymes (BamHI, EcoRI, Hind III, Pvu II, Taq I, Rsa I, Msp I, Pst I and Bgl II), separated by agarose gel electrophoresis and transferred onto Biotrace membrane. The Southern blots were successively hybridized with radiolabelled HLA cDNA probes corresponding to DQ, DP, DZ and DR alpha genes. Clear evidence was obtained for the canine homologues of DQ and DR alpha genes with simple bi- or tri-allelic polymorphism respectively. Evidence for a single, nonpolymorphic DP alpha gene was also obtained. However, the presence of a DZ alpha gene could not be clearly demonstrated in canine genomic DNA. This report extends our previous RFLP analysis documenting polymorphism of DLA class II beta genes in the same panel of homozygous typing cell dogs, and provides the basis for DLA-D genotyping at a population level. This study also characterizes the RFLP-defined preferential allelic associations across the DLA-D region in nine different homozygous typing cell specificities.

Macrorestriction mapping of COL4A1 and COL4A2 collagen genes on human chromosome 13q34

The genes for the alpha-1 and alpha-2 chains of type IV collagen (COL4A1 and COL4A2) map to the same chromosomal band (13q34) and have a high degree of nucleotide homology. We have used pulsed field gel electrophoresis and cloned COL4A1 and COL4A2 DNA fragments as molecular probes to construct a 1200-kb macrorestriction map which encompasses both genes. The two genes are located within a 340-kb region with the 3' end of COL4A2 and the 5' region of COL4A1 separated by at least 100 kb but not more than 160 kb. These genes, therefore, are two members of a gene cluster on chromosome 13q34.

A novel instrument for separating large DNA molecules with pulsed homogeneous electric fields

A new instrument has been developed for the electrophoretic separation of large DNA molecules that can independently regulate the voltage of each of 24 electrodes and allow the magnitude, orientation, homogeneity, and duration of the electric field to be precisely controlled. Each parameter can be varied at any time during the electrophoretic process. Thus distinct sets of conditions can be combined to optimize the separation of various fragment sizes in a single run. Independent control of electrode voltage allows all of the fields to be generated with electrodes arranged in a closed contour, independent of a particular geometry. This device increases both the resolution in any size range and the speed of separation, especially for DNA molecules larger than 3 megabases.

Extensive deletions and insertions in different MHC supratypes detected by pusled field gel electrophoresis

The genomic organization of the human MHC was examined in multiple examples of six different supratypes using pulsed field electrophoresis (PFGE) after digestion of genomic DNA with infrequency cutting restriction endonucleases. Differences in restriction fragment length and band intensity were shown to be specific for each supratype. Mapping of the MHC revealed that each supratype contains previously undescribed deletions and insertions between HLA B and DQ regions.

Calcium influx and the Ca2+-calmodulin complex are involved in interferon-gamma-induced expression of HLA class II molecules on HL-60 cells

Background

Gene silencing due to aberrant DNA methylation is a frequent event in hepatocellular carcinoma (HCC) and also in hepatocellular adenoma (HCA). However, very little is known about epigenetic defects in fibrolamellar carcinoma (FLC), a rare variant of hepatocellular carcinoma that displays distinct clinical and morphological features.

Methodology/Principal Findings

We analyzed the methylation status of the APC, CDH1, cyclinD2, GSTπ1, hsa-mir-9-1, hsa-mir-9-2, and RASSF1A gene in a series of 15 FLC and paired normal liver tissue specimens by quantitative high-resolution pyrosequencing. Results were compared with common HCC arising in non-cirrhotic liver (n = 10). Frequent aberrant hypermethylation was found for the cyclinD2 (19%) and the RASSF1A (38%) gene as well as for the microRNA genes mir-9-1 (13%) and mir-9-2 (33%). In contrast to common HCC the APC and CDH1 (E-cadherin) genes were found devoid of any DNA methylation in FLC, whereas the GSTπ1 gene showed comparable DNA methylation in tumor and surrounding tissue at a moderate level. Changes in global DNA methylation level were measured by analyzing methylation status of the highly repetitive LINE-1 sequences. No evidence of global hypomethylation could be found in FLCs, whereas HCCs without cirrhosis showed a significant reduction in global methylation level as described previously.

Conclusions

FLCs display frequent and distinct gene-specific hypermethylation in the absence of significant global hypomethylation indicating that these two epigenetic aberrations are induced by different pathways and that full-blown malignancy can develop in the absence of global loss of DNA methylation. Only quantitative DNA methylation detection methodology was able to identify these differences.

Molecular characterization and genetic mapping of class I and class II MHC genes of the domestic cat

The major histocompatibility complex (MHC) of the domestic cat has been poorly characterized to date, primarily because of numerous difficulties in the preparation of allotypic sera. We present here a comparative analysis of class I and class II genes in domestic cat populations using molecular probes of the MHC from man and mouse. The cat possesses a minimum of 20 class I loci and 5 class II genes per haploid genome. Class I genes of the domestic cat expressed limited restriction fragment length polymorphism. The average percent difference of the size of DNA fragments between individual cats was 9.0%, a value five times lower than the value for mice, but comparable to the human DNA polymorphism level. Class I and class II genes were both genetically mapped to feline chromosome B2 using a panel of rodent x cat somatic cell hybrids. Since feline chromosome B2 is syntenically homologous to human chromosome 6 and mouse chromosome 17, these results affirm the linkage conservation of the MHC-containing linkage group in the three mammalian orders.

A molecular basis for MHC class II--associated autoimmunity

Class II major histocompatibility (MHC) molecules have an immunoregulatory role. These cell-surface glycoproteins present fragments of protein antigens (or peptides) to thymus-derived lymphocytes (T cells). Nucleotide sequence polymorphism in the genes that encode the class II MHC products determines the specificity of the immune response and is correlated with the development of autoimmune diseases. This study identifies certain class II polymorphic amino acid residues that are strongly associated with susceptibility to insulin-dependent diabetes mellitus, rheumatoid arthritis, and pemphigus vulgaris. These findings implicate particular class II MHC isotypes in susceptibility to each disease and suggest new prophylactic and therapeutic strategies.

T-cell-defined DR4 subtypes as markers for type 1 diabetes

In most populations studied, HLA-DR4, a DRB1 (formerly DR beta I) allele, is increased in frequency among patients with insulin-dependent diabetes mellitus (IDDM). Using T-cells, one can distinguish five subtypes of DR4 (Dw4, Dw10, Dw13, Dw14, and Dw15). Two of these (Dw4 and Dw10) are IDDM-associated in the populations studied here. Therefore, Dw4 and Dw10 could be causative or merely markers for a linked diabetes allele. If they are causative, one might expect them to share some unique structural element or at least to associate consistently with IDDM in different populations. Published sequence data show no structural element unique to Dw4 and Dw10; moreover, the associations of these DR4-Dw subtypes with diabetes vary considerably in different populations. Thus the DRB1 locus probably cannot account for the DR4 association in IDDM. The strong linkage disequilibrium between IDDM and Dw4 and Dw10 suggests that the diabetes susceptibility locus should be in the vicinity of the DR region or the DQ region of the HLA complex. Alternative hypotheses are discussed, relating DR- and DQ-region alleles to IDDM. We further postulate that the evolutionary event that produced the Dw10 allele occurred on a Dw4 haplotype that happened to carry a diabetes susceptibility allele at another locus.

Calcium influx and the Ca2+-calmodulin complex are involved in interferon-gamma-induced expression of HLA class II molecules on HL-60 cells

Interferon gamma (IFN-gamma) induces HLA-DR and -DQ molecules and causes an accumulation of transcripts in HL-60 cells. Experiments were, therefore, designed to investigate the intracellular signaling molecules regulating the appearance of HLA class II molecules. The expression of HLA class II (DR and DQ) molecules induced by IFN-gamma was blocked by a calmodulin antagonist, W7, but not by a protein kinase C inhibitor, H7. Furthermore, a direct activator of protein kinase C, phorbol 12-myristate 13-acetate, was unable to induce HLA class II (DR) molecule expression. These results suggest that IFN-gamma induces HLA class II molecules on HL-60 cells by way of a calcium-calmodulin pathway and not by way of a protein kinase C pathway. Calmodulin is activated by a transient rise in the cytosolic free calcium. In fact, IFN-gamma evoked a calcium influx into HL-60 cells, whereas depletion of Ca2+ from culture medium resulted in a failure of IFN-gamma to induce DR expression. Furthermore, the calcium ionophore A23187 by itself induced DR molecule expression. These results suggest that IFN-gamma stimulates calcium influx by a so-called receptor-mediated calcium channel and activates the calmodulin branch of the calcium messenger system, resulting in the induction of DR molecules on the surface of HL-60 cells.

High recombination between two physically close human basement membrane collagen genes at the distal end of chromosome 13q

Two basement membrane collagen genes coding for the pro alpha 1 chain and pro alpha 2 chain of type IV collagen map to 13q34 and are linked with a maximum likelihood estimate of recombination of 0.028 at a logarithm of odds (lod) score of 19.98. The single-copy sequence that identifies the locus D13S3 is also closely linked to both collagen genes. Four enzymes reveal polymorphisms with COL4A1, and 10 haplotypes have been observed in Caucasoids. Within COL4A1 a nonrandom association of alleles exists only between alleles defined by Hae III and those defined by the other three enzymes. A random association of alleles of COL4A1 and COL4A2 is observed. Between the two collagen genes were detected three meiotic recombination events that contributed to the estimate of 2.8% recombination. This is higher than expected for two genes that lie within 650 kilobases of each other. The lack of linkage disequilibrium between COL4A1 and COL4A2 is in agreement with the relatively high recombination that is observed.

Linkage relationships in the bovine MHC region. High recombination frequency between class II subregions

Class II genes of the bovine major histocompatibility complex (MHC) have been investigated by Southern blot analysis using human DNA probes. Previous studies revealed the presence of bovine DO beta, DQ alpha, DQ beta, DR alpha, and DR beta genes, and restriction fragment length polymorphisms for each of these genes were documented. In the present study, the presence of three additional class II genes, designated DZ alpha, DY alpha, and DY beta, are reported. DZ alpha was assumed to correspond to the human DZ alpha gene while the other two were designated DY because their relationship to human class II genes could not be firmly established. The linkage relationships among bovine class II genes and two additional loci, TCP1B and C4, were investigated by family segregation analysis and analysis of linkage disequilibrium. The results clearly indicated that all these loci belong to the same linkage group. This linkage group is divided into two subregions separated by a fairly high recombination frequency. One region includes the C4, DQ alpha, DQ beta, DR alpha, and DR beta loci and the other one is composed of the DO beta, DY alpha, DY beta, and TCP1B loci. No recombinant was observed within any of these subregions and there was a strong or fairly strong linkage disequilibrium between loci within groups. In contrast, as many as five recombinants among three different families were detected in the interval between these subregions giving a recombination frequency estimate of 0.17 +/- 0.07. The fairly high recombination frequency observed between class II genes in cattle is strikingly different from the corresponding recombination estimates in man and mouse. The finding implies either a much larger molecular distance between some of the bovine class II genes or alternatively the presence of a recombinational "hot spot" in the bovine class II region.

Close physical linkage of the murine Ren-1 and Ren-2 loci

In addition to the Ren-1 gene common to all mice, some inbred strains carry a second copy of the renin structural gene, Ren-2. These two loci are tightly linked genetically on mouse chromosome one. We have used pulsed field gel electrophoresis (PFGE) to study the physical arrangement of the two renin genes in the inbred strain DBA/2. PFGE mapping permitted the construction of a restriction map of the Ren loci spanning roughly 120 Kb. The results indicate that the genes are transcribed in the same relative direction, that Ren-2 lies upstream relative to Ren-1, and that the respective coding sequences are separated by approximately 20 Kb.

Characterization of the MHC class II region in cattle. The number of DQ genes varies between haplotypes

The organization of the major histocompatibility complex (MHC) class II region in cattle was investigated by Southern blot analysis using human probes corresponding to DO, DP, DQ, and DR genes. Exon-specific probes were also employed to facilitate the assessment of the number of different bovine class II genes. The results indicated the presence of single DO beta and DR alpha genes, at least three DR beta genes, while the number of DQ genes was found to vary between MHC haplotypes. Four DQ haplotypes, DQ alpha 1 beta 1 to DQ alpha 2 beta 4, possessed a single DQ alpha and a single DQ beta gene whereas both these genes were duplicated in eight other haplotypes, DQ alpha 3 beta 5 to DQ alpha 9 beta 12. No firm evidence for the presence of bovine DP genes was obtained. The same human probes were also used to investigate the genetic polymorphism of bovine class II genes. DQ alpha, DQ beta, DR alpha, DR beta, and DO beta restriction fragment length polymorphisms (RFLPs) were resolved and in particular the DQ restriction fragment patterns were highly polymorphic. Comparison of the present result with the current knowledge of the class II region in other mammalian species suggested that the DO, DP, DQ, DR, and DZ subdivision of the class II region was established already in the ancestor of mammals. The DP genes appear to be the least conserved class II genes among mammalian species and may have been lost in cattle. The degree of polymorphism of different class II genes, as revealed by RFLP analyses, shows striking similarities between species.

An extended HLA-D region haplotype associated with celiac disease

Celiac disease has one of the strongest associations with HLA (human leukocyte antigen) class II markers of the known HLA-linked diseases. This association is primarily with the class II serologic specificities HLA-DR3 and -DQw2. We previously described a restriction fragment length polymorphism (RFLP) characterized by the presence of a 4.0-kilobase Rsa I fragment derived from an HLA class II beta-chain gene, which distinguishes the class II HLA haplotype of celiac disease patients from those of many serologically matched controls. We now report the isolation of this beta-chain gene from a bacteriophage genomic library constructed from the DNA of a celiac disease patient. Based on restriction mapping and differential hybridization with class II cDNA and oligonucleotide probes, this gene was identified as one encoding an HLA-DP beta chain. This celiac disease-associated HLA-DP beta-chain gene was flanked by HLA-DP alpha-chain genes and, therefore, was probably in its normal chromosomal location. The HLA-DP alpha-chain genes of celiac disease patients also were studied by RFLP analysis; 84% of HLA-DR3, -DQw2 patients had a 16-kb Xba I fragment that was present in only 36% of HLA-DR3, -DQw2 controls. Moreover, 79% of these patients had both alpha- and beta-chain polymorphisms in contrast to 27% of controls. Thus, celiac disease is associated with a subset of HLA-DR3, -DQw2 haplotypes characterized by HLA-DP alpha- and beta-chain gene RFLPs. Within the celiac-disease patient population, the joint segregation of these HLA-DP genes with those encoding the serologic specificities HLA-DR3 and -DQw2 indicates: (i) that the class II HLA haplotype associated with celiac disease is extended throughout the entire HLA-D region, and (ii) that celiac-disease susceptibility genes may reside as far centromeric on this haplotype as the HLA-DP subregion.

HLA-D region RFLPs indicate that susceptibility to insulin-dependent diabetes in South India is located in the HLA-DQ region

Recently close markers for insulin-dependent diabetes mellitus in Western 'Caucasoid' subjects have been defined from DQ region (both alpha and beta genes) restriction fragment length polymorphisms. In order to define the genetic contribution to insulin-dependent diabetes mellitus in an Indian population we have analysed 58 unrelated Dravidian (South Indian) insulin-dependent diabetic patients and 43 controls. In insulin-dependent diabetes an increased frequency of the Taq 1 DQ beta restriction fragment length polymorphisms designated T2 omega/T6 (relative risk = 10.6), and of homozygotes for Taq 1 DQ alpha 4.6 kb (relative risk = 11), was found in the patients. The highest relative risk for insulin-dependent diabetes mellitus was obtained by comparing patients and control subjects who either (a) co-inherited DQT2 omega/T6 with certain DQ alpha restriction fragment length polymorphisms or (b) were DQ alpha 4.6 kb homozygotes, the combination of (a) and (b) accounting for 55.5% of insulin-dependent diabetes mellitus subjects and none of the controls (relative risk = 101; 95% confidence limits 93-109).