A new DNA marker (D4S90) is located terminally on the short arm of chromosome 4, close to the Huntington disease gene

Genetic linkage studies have mapped Huntington's disease (HD) to the distal portion of the short arm of chromosome 4 (4p16.3), 4 cM distal to D4S10 (G8). To date, no definite flanking marker has been identified. A new DNA marker, D4S90 (D5); which maps to the distal region of 4p16.3, is described. The marker was used in a genetic linkage study in the CEPH reference families with seven other markers at 4p16. The study, together with knowledge of the physical map of the region, places D4S90 as the most distal marker, 6 cM from D4S10. A provisional linkage study with HD gave a maximum lod score of 2.14 at a theta of 0.00 and no evidence of linkage disequilibrium. As D4S90 appears to be located terminally, it should play an important role in the accurate mapping and cloning of the HD gene.     

Construction of a NotI linking library and isolation of new markers close to the Huntington''s disease gene.

Linking clones contain sequences flanking recognition sites for enzymes cutting rarely in mammalian DNA. They can be used to obtain and correlate both physical and genetic mapping information over subregions of mammalian chromosomes. We have constructed and used a NotI linking clone library representing unmethylated NotI sites from HHW693 DNA, a hamster hybrid cell line containing 4p15-4pter and a fragment of 5p as its only human chromosome contribution. Human clones were identified by hybridisation with a cloned human repeat sequence, and localised further to subregions of human chromosome 4p15-4pter using a panel of additional hybrids. Clones from the region distal to the DNA probes (D4S10, D4S43, D4S95) linked to the Huntington's disease mutation, were further analysed. Four markers close to the HD gene: D4S111, D4S113, D4S114 and clone 417 are described here. In addition to serving as markers in physical and genetic mapping experiments, these linking clones provide probes next to cleavable NotI sites, and can therefore be used to screen NotI based chromosome jumping libraries. They also provide indications for potential gene sequences, identifiable as evolutionarily conserved sequences.     

A new DNA marker (D4S90) is located terminally on the short arm of chromosome 4, close to the Huntington disease gene

Genetic linkage studies have mapped Huntington's disease (HD) to the distal portion of the short arm of chromosome 4 (4p16.3), 4 cM distal to D4S10 (G8). To date, no definite flanking marker has been identified. A new DNA marker, D4S90 (D5), which maps to the distal region of 4p16.3, is described. The marker was used in a genetic linkage study in the CEPH reference families with seven other markers at 4p16. The study, together with knowledge of the physical map of the region, places D4S90 as the most distal marker, 6 cM from D4S10. A provisional linkage study with HD gave a maximum lod score of 2.14 at a θ of 0.00 and no evidence of linkage disequilibrium. As D4S90 appears to be located terminally, it should play an important role in the accurate mapping and cloning of the HD gene.     

Isolation and regional localization of a large collection (2,000) of single-copy DNA fragments on human chromosome 3 for mapping and cloning tumor suppressor genes

Summary A collection of 2,000 lambda phage-carrying human single-copy inserts (> 700 bp) were isolated from two chromosome-3 flow-sorted libraries. The single-copy DNA fragments were first sorted into 3p and 3q locations and about 700 3p fragments were regionally mapped using a deletion mapping panel comprised of two humanhamster and two-human-mouse cell hybrids, each containing a chromosome 3 with different deletions in the short arm. The hybrids were extensively mapped with a set of standard 3p markers physically localized or ordered by linkage. The deletion mapping panel divided the short arm into five distinct subregions (A-E). The 3p fragments were distributed on 3p regions as follows: region A, 26%; B, 31%; C, 4%; D, 4% and E, 35%. We screened 300 single-copy DNA fragments from the distal part of 3p (regions A and B) with ten restriction endonucleases for their ability to detect restriction fragment length polymorphisms (RFLPs). Of these fragments 110 (36%) were found to detect useful RFLPs: 35% detected polymorphisms with frequency of heterozygosity of 40% or higher, and 25% with frequency of 30% or higher. All polymorphisms originated from single loci and most of them were of the base pair substitution type. These RFLP markers make it possible to construct a fine linkage map that will span the distal part of chromosome 3p and encompasses the von Hippel-Lindau disease locus. The large number of single-copy fragments (2,000) spaced every 100–150 kb on chromosome 3 will make a significant contribution to mapping and sequencing the entire chromosome 3. The 300 conserved chromosome 3 probes will increase the existing knowledge of man-mouse homologies.     

Segregation of the Huntington disease region of human chromosome 4 in a somatic cell hybrid

We have developed an X-irradiation:cell fusion procedure that segregates segments of human chromosomes lacking selectable markers and have used this approach to construct somatic cell hybrids retaining fragments of human chromosome 4 as the only human material. To identify hybrids retaining a small chromosomal fragment in the region of the Huntington disease (HD) gene, we used Southern blot analysis to screen 72 hybrid lines for the presence or absence of seven chromosome 4 single-copy loci. These data, combined with in situ hybridization experiments, identified three hybrids of interest. One of these cell lines, C25, stably retains a 10,000- to 20,000-kb fragment of distal 4p in the vicinity of the HD gene, translocated to a hamster chromosome. Field-inversion gel electrophoresis revealed no evidence of rearrangements in the human DNA present in C25. In combination with similar radiation hybrids, C25 is a valuable tool for isolating DNA probes near the HD gene.     

Isolation and characterization of new highly polymorphic DNA markers from the Huntington disease region.

The defect causing Huntington disease (HD) has been mapped to 4p16.3, distal to the DNA marker D4S10. Subsequently, additional polymorphic markers closer to the HD gene have been isolated, which has led to the establishment of predictive testing programs for individuals at risk for HD. Approximately 17% of persons presenting to the Canadian collaborative study for predictive testing for HD have not received any modification of risk, in part because of limited informativeness of currently available DNA markers. Therefore, more highly polymorphic DNA markers are needed, which will further increase the accuracy and availability of predictive testing, specifically for families with complex or incomplete pedigree structures. In addition, new markers are urgently needed in order to refine the breakpoints in the few known recombinant HD chromosomes, which could allow a more accurate localization of the HD gene within 4p16.3 and, therefore, accelerate the cloning of the disease gene. In this study we present the identification and characterization of nine new polymorphic DNA markers, including three markers which detect highly informative multiallelic VNTR-like polymorphisms with PIC values of up to .84. These markers have been isolated from a cloned region of DNA which has been previously mapped approximately 1,000 kb from the 4p telomere.     

Isolation and field-inversion gel electrophoresis analysis of DNA markers located close to the Huntington disease gene

A radiation-induced hybrid cell line containing 10-20 million base pairs of DNA derived from the terminal part of human 4p16 in a background of hamster chromosomes has been used to construct a genomic library highly enriched for human sequences located close to the Huntington disease (HD) gene. Recombinant phage containing human inserts were isolated from this library and used as hybridization probes against two other radiation hybrids containing human fragments with chromosomal breaks in 4p16 and against a human-hamster somatic cell hybrid that retains only the 4p15-4pter part of chromosome 4. Of 121 human phage tested, 6 were mapped distal to the HD-linked D4S10 locus. Since the HD gene is located between D4S10 and the 4p telomere, all of these sequences are likely to be closer to HD than D4S10, and any one of them may be a distal flanking marker for the disease locus. Long-range restriction map analysis performed with a field-inversion gel system shows that the six new loci are distributed in different places within 4p16. Although it is not possible to establish an order for the six sequences with the FIGE data, the results demonstrate that the region detected by these probes must span at least 2000 kb of DNA.     

Isolation of a novel mildly repetitive DNA sequence that is predominantly located at the terminus of the short arm of chromosome 4 near the Huntington disease gene

A novel mildly repetitive DNA sequence that is reiterated approximately 20 times in the human genome has been isolated and characterized. Most of the repeat units are localized very near the terminus of the short arm of chromosome 4 (4p) in the region known to contain the Huntington disease (HD) gene. A cloned probe that detects the repeated sequence reveals a restriction fragment length polymorphism that is close to and/or distal to the most distal genetic locus on 4p. This probe, therefore, provides a new genetic marker very close to and possibly flanking the HD gene. In addition, this probe should prove very useful for detailed physical mapping of the most distal region of 4p around the HD gene. The few (two or three) copies of this repeat not located near the terminus of 4p are located near the ends of two other chromosomes, 14 and 21.     

Isolation and high-resolution mapping of new DNA markers from the pericentromeric region of chromosome 10.

The gene responsible for multiple endocrine neoplasia type 2A (MEN 2A) has been localized to the pericentromeric region of chromosome 10. Several markers that fail to recombine with MEN2A have been identified, including D10Z1, D10S94, D10S97, and D10S102. Meiotic mapping in the MEN2A region is limited by the paucity of critical crossovers identified and by the dramatically reduced rates of recombination in males. Additional approaches to mapping loci in the pericentromeric region of chromosome 10 are required. We have undertaken the generation of a detailed physical map by radiation hybrid mapping. Here we report the development of a radiation hybrid panel and its use in the mapping of new DNA markers in pericentromeric chromosome 10. The radiation-reduced hybrids used for mapping studies all retain small subchromosomal fragments that include both D10S94 and D10Z1. One hybrid was selected as the source of DNA for cloning. One hundred five human recombinant clones were isolated from a lambda library made with pp11A DNA. We have completed regional mapping of 22 of those clones using our radiation hybrid mapping panel. Seven markers have been identified and, when taken together with previously meiotically mapped markers, define eight radiation hybrid map intervals between D10S34 and RBP3. The identical order is found for a number of these using either the radiation hybrid mapping panel or the meiotic mapping panel. We believe that this combination cloning and mapping approach will facilitate the precise positioning of new markers in pericentromeric chromosome 10 and will help in refining further the localization of MEN2A.     

Recombination events suggest potential sites for the Huntington's disease gene

The Huntington's disease gene (HD) maps distal to the D4S10 marker in the terminal 4p16.3 subband of chromosome 4. Directed cloning has provided several DNA segments that have been grouped into three clusters on a physical map of approximately 5 X 10(6) bp in 4p16.3. We have typed RFLPs in both reference and HD pedigrees to produce a fine-structure genetic map that establishes the relative order of the clusters and further narrows the target area containing the HD gene. Despite the large number of meiotic events examined, the HD gene cannot be positioned relative to the most distal cluster. One recombination event with HD suggests that the terminal-most markers flank the disease gene; two others favor a telomeric location for the defect. Efforts to isolate the HD gene must be divided between these two distinct intervals until additional genetic data resolve the apparent contradiction in localization.     

Identification and regional localization of DNA markers on chromosome 7 for the cloning of the cystic fibrosis gene

To facilitate mapping of the cystic fibrosis locus (CF) and to isolate the corresponding gene, we have screened a flow-sorted chromosome 7-specific library for additional DNA markers in the 7q31-q32 region. Unique ("single-copy") DNA segments were selected from the library and used in hybridization analysis with a panel of somatic cell hybrids containing various portions of human chromosome 7 and patient cell lines with deletion of this chromosome. A total of 258 chromosome 7-specific single-copy DNA segments were identified, and most of them localized to subregions. Fifty three of these corresponded to DNA sequences in the 7q31-q32 region. Family and physical mapping studies showed that two of the DNA markers, D7S122 and D7S340, are in close linkage with CF. The data also showed that D7S122 and D7S340 map between MET and D7S8, the two genetic markers known to be on opposite sides of CF. The study thus reaffirms the general strategy in approaching a disease locus on the basis of chromosome location.     

Increased recombination adjacent to the Huntington disease-linked D4S10 marker.

Huntington disease (HD) is caused by a genetic defect distal to the anonymous DNA marker D4S10 in the terminal cytogenetic subband of the short arm of chromosome 4 (4p16.3). The effort to identify new markers linked to HD has concentrated on the use of somatic cell hybrid panels that split 4p16.3 into proximal and distal portions. Here we report two new polymorphic markers in the proximal portion of 4p16.3, distal to D4S10. Both loci, D4S126 and D4S127, are defined by cosmids isolated from a library enriched for sequences in the 4pter-4p15.1 region. Physical mapping by pulsed-field gel electrophoresis places D4S126 200 kb telomeric to D4S10, while D4S127 is located near the more distal marker D4S95. Typing of a reference pedigree for D4S126 and D4S127 and for the recently described VNTR marker D4S125 has firmly placed these loci on the existing linkage map of 4p16.3. This genetic analysis has revealed that the region immediately distal to D4S10 shows a dramatically higher rate of recombination than would be expected based on its physical size. D4S10-D4S126-D4S125 span 3.5 cM, but only 300-400 kb of DNA. Consequently, this small region accounts for most of the reported genetic distance between D4S10 and HD. By contrast, it was not possible to connect D4S127 to D4S125 by physical mapping, although they are only 0.3 cM apart. A more detailed analysis of recombination sites within the immediate vicinity of D4S10 could potentially reveal the molecular basis for this phenomenon; however, it is clear that the rate of recombination is not continuously increased with progress toward the telomere of 4p.     

Mapping of recombinants near the Huntington disease locus by using G8 (D4S10) and newly isolated markers in the D4S10 region.

Genetic linkage between the marker G8 (D4S10) and Huntington disease (HD) was studied in six Dutch pedigrees. The informativeness of the D4S10 locus was increased by isolation of a cosmid, C5.5, with a G8 subclone used as probe. We present a restriction map of 70 kb in the D4S10 region. Two subclones of C5.5, H5.52 and F5.53, detect MspI and SinI RFLPs, respectively. These probes increase the informativeness of D4S10 in the Dutch HD population from 55% to 95%. Seven recombinations were found in 124 informative meioses in which multipoint segregation of D4S10 haplotypes and the HD locus was studied. Two of the recombinations occurred within the D4S10 region. The other five recombinations are highly valuable for the mapping of present and future markers relative to each other and to the HD gene. In addition, several recombinations between markers in meioses from unaffected parents were noted, which will also be useful in ordering new markers. On the basis of our three-point recombination data, the orientation of the D4S10 region relative to HD is HD-H5.52-G8-F5.53, which independently confirms the previously derived polarity for D4S10.     

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

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

Evidence from family studies that the gene causing Huntington disease is telomeric to D4S95 and D4S90.

A DNA probe (D4S95) that detects a variable number of tandem repeats and a single-site-variation polymorphism after digestion with a single restriction enzyme, AccI, has previously been described. The order of this probe relative to the gene for Huntington disease (HD) and other previously described markers has not been established. Analysis of 24 affected families with HD has shown that D4S95 is in tight linkage with the gene causing HD, with a maximal Lod score of 12.489 at a theta of .03. D4S90 is a probe which maps to 4p16.3, telomeric to D4S95, and detects polymorphisms with HincII and other enzymes. In one affected person, recombination has occurred between D4S10 and HD, between D4S95 and HD, and in all likelihood also between D4S90 and HD, which strongly suggests that the gene for HD is telomeric to all these DNA probes. This suggests that the gene causing HD is located in the most distal region of the short arm of chromosome 4, flanked by D4S90 and the telomere, and supports the locus order D4S10-D4S95-D4S90-HD-telomere. D4S95 is a most useful DNA marker for predictive testing programs, while D4S90 will serve as a useful starting point for identifying DNA fragments closer to the gene for HD.     

Mapping of D4S98/S114/S113 confines the Huntington''s defect to a reduced physical region at the telomere of chromosome 4.

The dominant gene defect in Huntington's disease (HD) is linked to the DNA marker D4S10, near the telomere of the chromosome 4 short arm. Two other markers, D4S43 and D4S95, are closer, but still proximal to the HD gene in 4p16.3. We have characterized a new locus, D4S114, identified by cloning the end of a NotI fragment resolved by pulsed-field gel electrophoresis. D4S114 was localized distal to D4S43 and D4S95 by both physical and genetic mapping techniques. The "end"-clone overlaps a previously isolated NotI "linking" clone, and is within 150 kb of a second "linking" clone defining D4S113. Restriction fragment length polymorphisms for D4S113 and D4S114, one of which is identical to a SacI polymorphism detected by the anonymous probe pBS731B-C (D4S98), were typed for key crossovers in HD and reference pedigrees. The data support the locus order D4S10-(D4S43, D4S95)-D4S98/S114/S113-HD-telomere. The D4S98/S114/S113 cluster therefore represents the nearest cloned sequences to HD, and provides a valuable new point for launching directional cloning strategies to isolate and characterize this disease gene.     

Nonrandom association between Huntington disease and two loci separated by about 3 Mb on 4p16.3.

The gene for Huntington disease (HD) has been localized close to the telomere on the short arm of chromosome 4. However, refined mapping using recombinant HD chromosomes has resulted in conflicting findings and mutually exclusive candidate regions. Previously reported significant nonrandom allelic association between D4S95 and HD provided support for a more proximal location for the defective gene. In this paper, we have analyzed 17 markers, spanning approximately 6 Mb of DNA distal to locus D4S62, for nonrandom association to HD. We confirm the previous findings of nonrandom allelic association between D4S95 and HD. In addition, we provide new data showing significant nonrandom association between HD and 3 markers at D4S133 and D4S228, which are approximately 3 Mb telomeric to D4S95.     

Regional localization of chromosome 3-specific DNA fragments by using a hybrid cell deletion mapping panel.

A series of human chromosome 3-specific DNA fragments isolated and characterized from a lamda phage genomic library were regionally localized on human chromosome 3. This was accomplished using filter hybridization blot analysis of a human chromosome 3 hybrid cell deletion mapping panel. Twenty-three new anonymous DNA fragments were assigned to one of four physical regions of chromosome 3. Seventeen DNA fragments were mapped to the long arm of chromosome 3, including one DNA fragment that demonstrated a restriction fragment length polymorphism (RFLP). Five DNA fragments were assigned to 3p14.2----pter, including one highly polymorphic fragment sublocalized at 3p25----pter by in situ hybridization. This DNA fragment is the second reported distal 3p polymorphic probe. One DNA fragment was localized to 3p14----p14.2. In addition, three fragments previously assigned to chromosome 3 were confirmed. Polymorphic DNA probes DNF15S2 (formerly D1S1) and D3S2 were mapped to 3p14.2----pter. The previous 3p25 in situ localization of the c-raf-1 oncogene was supported by deletion panel mapping. The physical localization of these twenty-three new DNA fragments has more than doubled the number of cloned DNA fragments assigned to chromosome 3. These and future regional assignments of DNA fragment probes will facilitate construction of both a physical and genetic linkage map of chromosome 3. They may also be useful in characterizing the chromosomal and molecular aberrations involved in small-cell lung cancer (SCLC), renal cell carcinoma, other malignancies, and the 3p14.2 common fragile site.     

Radiation hybrid map of 13 loci on the long arm of chromosome 5.

Radiation hybrid mapping was used in conjunction with a natural deletion mapping panel to predict the order of and distance between 13 loci in the distal portion of the long arm of human chromosome 5. A panel of irradiation hybrids containing fragments of 5q was generated from an HPRT+ Chinese hamster-human cell hybrid containing a derivative chromosome 5 [der(5)t(4;5)(5qter----5p15.1::4p15.1----4pter)] as its only human DNA. One hundred nine radiation hybrids containing human DNA were screened with polymerase chain reaction primer sets representing nine genes encoding growth factors, growth factor receptors, or hormone receptors (IL3, IL4, IL5, CSF1R, FGFA, ADRB2, GRL, GABRA1, and DRD1) as well as four other loci (FER, SPARC, RPS14, and CD14) to generate a radiation hybrid map of the area 5q21-q35. A physical map predicting the order of and distance between the 13 loci was constructed based on segregation of the 13 loci in hybrid clones. The radiation hybrid panel will be useful as a mapping tool for determining the location and order of other genes and polymorphic loci in this region as well as for generating new DNA probes from specific regions.