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.     

Isolation and regional mapping of NotI and EagI clones from human chromosome 21

NotI and EagI boundary libraries were constructed for human chromosome 21. One hundred forty-seven clones were isolated from the somatic cell hybrid 72532X-6 and localized using a hybrid mapping panel. After identification of those clones, which were isolated more than once, as well as those probes derived from a previously unrecognized integrated non-chromosome-21 fragment, 58 individual boundary clones (plus 2 additional NotI-EcoRI clones isolated from a flow-sorted library) were localized to 11 separate regions. The distribution of these probes is highly nonrandom, with 50% of the clones located in the distal band 21q22.3. Two probes, Not50 and Eag101, map to regions in the very proximal long arm which may contain the gene responsible for familial Alzheimer's disease (AD1), and Not50 would appear to be more proximal than D21S16 (E9). Twenty-eight probes map to the region between superoxide dismutase (SOD1) and the ETS2 oncogene, which appears to contain genes responsible for many of the phenotypic features of Down syndrome. Twenty clones contain (GT)n repeats, as determined by hybridization to a CA polymer, and should provide additional highly polymorphic probes. Closure of gaps in the physical linkage map of chromosome 21 should be facilitated by the isolation of these probes, as they identify many of the unmethylated CpG-rich islands that have hindered pulsed-field gel analysis. They will also be useful in identifying a set of genes in proximity to NotI and EagI restriction sites, as well as conserved DNA sequences for comparative mapping studies.     

New strategy for mapping the human genome based on a novel procedure for construction of jumping libraries

A novel procedure for construction of jumping libraries is described. The essential features of this procedure are as follows: (1) two diphasmid vectors (lambda SK17 and lambda SK22) are simultaneously used in the library construction to improve representativity, (2) a partial filling-in reaction is used to eliminate cloning of artifactual jumping clones and to obviate the need for a selectable marker. The procedure has been used to construct a representative human NotI jumping library (220,000 independent recombinant clones) from the lymphoblastoid cell line CBMI-Ral-STO, which features a low level of methylation of its resident EBV genomes. A human chromosome 3-specific NotI jumping library (500,000 independent recombinant clones) from the human chromosome 3 x mouse hybrid cell line MCH 903.1 has also been constructed. Of these recombinant clones 50-80% represent jumps to the neighboring cleavable NotI site. With our previously published method for construction of linking libraries this procedure makes a new genome mapping strategy feasible. This strategy includes the determination of tagging sequences adjacent to NotI sites in random linking and jumping clones. Special features of the lambda SK17 and lambda SK22 vectors facilitate such sequencing. The STS (sequence tagged site) information obtained can be assembled by computer into a map representing the linear order of the NotI sites for a chromosome or for the entire genome. The computerized mapping data can be used to retrieve clones near a region of interest. The corresponding clones can be obtained from the panel of original clones, or necessary probes can be made from genomic DNA by PCR.     

Development of a somatic cell hybrid mapping panel and molecular probes for human chromosome 3

A somatic cell hybrid mapping panel and molecular probes have been developed for human chromosome 3. This panel defines 11 regions for the short and long arms of the chromosome. Four hundred thirty-two probes have been mapped using these hybrids. One hundred thirty-one of these probes were derived from EcoRI and HindIII flow-sorted libraries. The remaining 301 probes were isolated from NotI boundary and random (partial MboI) libraries constructed from a hybrid that provided a relative enrichment in 3p DNA sequences. For some regions of the chromosome, significant differences in the distribution of probes were noted. This was observed for both the unique sequence flow-sorted and NotI probes. These differences are in agreement with previous suggestions that Giemsa light bands are GC-rich, and therefore gene-rich (especially housekeeping genes), and that the Giemsa dark bands may contain DNA that is more highly condensed. The isolation of probes from different types of libraries, or by different screening strategies, appears to reduce deficiencies that might arise from the use of probes derived with a more limited approach. These hybrids and probes should facilitate the construction of physical and genetic linkage maps to identify various disease loci involving chromosome 3.     

Human chromosome 17 NotI linking clones and their use in long-range restriction mapping of the Miller-Dieker chromosome region (MDCR) in 17p13.3

A NotI linking library constructed from flow-sorted human chromosome 17 material was screened to aid in construction of a long-range restriction map of the Miller-Dieker chromosome region (MDCR) in 17p13.3. A total of 66 clones were mapped to one of eight regions of chromosome 17 using a somatic cell hybrid panel, and 44/66 (67%) of these clones cross-hybridized to rodent DNA on Southern blots. Of these, 24 clones were tested and all mapped to mouse chromosome 11, the homolog of human chromosome 17. Four linking clones mapped to 17p13.3 and were used for pulsed-field gel electrophoresis studies along with six other anonymous probes previously mapped to this region. Clone L132 was found to be deleted in all Miller-Dieker patients tested (n = 15) and therefore lies within the critical region for this disorder. It detects two NotI fragments (180 and 320 kb), one of which (320 kb) was shared by YNZ22 and YNH37, two probes previously shown to be co-deleted in all patients with the Miller-Dieker syndrome (MDS). These results indicate that all MDS patients share a minimum deletion region of greater than 370 kb. Two other NotI clones, L53 and L125, mapped telomeric to the MDS critical region and share a 600-kb MluI fragment with each other and with YNZ22/YNH37. This provides a 930-kb MluI map that encompasses the distal boundary of the MDS critical region but does not include the proximal boundary. A total of over 2 Mbp is represented in the MluI fragments by probes in subband p13.3, a cytogenetic region estimated to be 3-4 Mbp.     

Direct construction of a chromosome-specific NotI linking library from flow-sorted chromosomes.

A linking library consists of genomic DNA fragments which contain a specific rare restriction enzyme site; such clones are very useful as probes in pulsed field gel electrophoresis and in mapping and cloning large regions of DNA. However, identifying those linking clones which map to a certain chromosomal region can be laborious. Therefore, we have developed a straightforward procedure for constructing a linking library directly from flow-sorted chromosomes. As a test of the approach, a NotI linking library was constructed from the chromosome 17 fraction of a flow-sort of human chromosomes, using only 70 ng of DNA. Thirteen of sixteen linking clones were mapped to chromosome 17, suggesting that the library is highly enriched for this chromosome. This method should be generally applicable to other chromosomes and enzymes as well.     

Rapid generation of region-specific genomic clones by chromosome microdissection: isolation of DNA from a region frequently deleted in malignant melanoma.

Malignant melanoma is frequently characterized by the deletion of the long arm of chromosome 6 (usually encompassing 6q16-q21). In an effort to saturate this region with DNA markers, microdissection and molecular cloning of DNA from banded human metaphases recent development of a novel chromosome microdissection scheme that omits microchemical manipulation of DNA. Microdissection was targeted on band 6q21. Direct PCR amplification of dissected DNA was first used as a probe in chromosomal in situ hybridization of normal metaphases to confirm the specificity of material excised for cloning. A genomic library of 20,000 clones, which is highly enriched for sequences encompassing 6q21, was then constructed. Clones from this library have been mapped against a human-rodent somatic cell hybrid mapping panel that divides chromosome 6 into seven regions, confirming the localization of probes within the target region. Direct PCR amplification of DNA excised by microdissection greatly simplifies and facilitates this chromosome band-specific cloning strategy. The isolation of microclones from this region of chromosome 6 should assist in establishing a physical map of the melanoma deletion region.     

Construction and analysis of linking libraries from the mouse X chromosome

A hybrid cell line containing the mouse X chromosome on a human background has been used to construct linking libraries from the mouse X chromosome, and approximately 250 unique EagI and NotI clones have been identified. Seventy-three clones have been sublocalized onto the X chromosome using interspecific Mus spretus/Mus domesticus crosses and a panel of somatic cell hybrids carrying one-half of reciprocal X-autosome translocations. The average spacing of the linking clones mapped to date is about one every 2 Mb of DNA. Two clones from the central region of the chromosome have been physically linked by pulsed-field gel electrophoresis. A large number of clones contain conserved sequences, indicating the presence of CpG-rich island-associated genes. The clones isolated from these libraries provide a valuable resource for comparative mapping between man and mouse X chromosomes, isolation of X-linked disease loci of interest by reverse genetics, and analysis of the long-range structure and organization of the chromosome.     

Regional localisation of X chromosome short arm probes

Summary Nine human X chromosome-specific clones have been isolated by screening an X-chromosomal genomic library with fetal muscle cDNA. Five of the clones have been localised to the short arm and four to the long arm. The short arm probes have been regionally assigned using a panel of somatic cell hybrids. They have been mapped further using a series of DNA samples from male patients with different deletions of the region Xp21, and having complex phenotypes including Duchenne muscular dystrophy. The use of these probes in the mapping of the short arm of the X chromosome is discussed.     

Construction and characterization of a NotI linking library of human chromosome 21

Effective procedures have been developed for constructing NotI linking libraries starting from chromosome-specific genomic libraries. Fifteen different single copy and two rDNA NotI linking clones from human chromosome 21 were identified in two libraries. Their chromosomal origin was confirmed, and regional location established using hybrid cell panels. Hybridization experiments with these probes revealed pairs of genomic NotI fragments, each ranging in size from less than 0.05 to 4.0 Mb. Many fragments displayed cell type variation. The total size of the NotI fragments detected in a human fibroblast cell line (GM6167) and mouse hybrid cell containing chromosome 21 as its only human component (WAV17) were approximately 32 and 34 Mb, respectively. If these fragments were all non-overlapping, this would correspond to about 70% of the 50-Mb content estimated for the whole chromosome. The linking clones will be enormously useful in the subsequent construction of a NotI restriction map of this chromosome. Characterization of these clones indicates the presence of numerous additional sites for other enzymes that recognize sequences containing CpG. Thus most NotI linking clones appear to derive from CpG islands and probably identify the 5' end of genes.     

Toward a long-range map of human chromosomal band 22q11

Human chromosome band 22q11 is involved in numerous chromosomal rearrangements. A long-range molecular map of this region would allow the more precise localization of the various breakpoints of these rearrangements. Toward this goal we have constructed a genomic DNA library that allows the isolation of DNA clones that are directly adjacent to NotI sites. NotI was chosen because it is a restriction enzyme that digests infrequently in the human genome. The genomic DNA used in this library was from a human/hamster hybrid cell line that has a chromosome 22 as the only visible human chromosome. Two clones were isolated and mapped to different regions of 22q11 using a somatic cell hybrid mapping panel. A long-range restriction map flanking the NotI site of each of these two clones was produced using NotI and other infrequently cutting enzymes. Both NotI sites analyzed were located in HTF islands, regions often associated with the 5' end of genes. Thus, the NotI map of 22q11 may also aid in the cloning of undiscovered genes, giving a starting point for the study of duplication/deficiency syndromes of the region.     

Localization of 616 human chromosome 3-specific cosmids using a somatic cell hybrid deletion mapping panel.

A total of 5700 human chromosome 3-specific cosmid clones was isolated from a series of cosmid libraries constructed from somatic cell hybrids whose only human component was an entire chromosome 3 or a chromosome 3 containing an interstitial deletion removing 50% of long arm sequences. Several unique sequence chromosome 3-specific hybridization probes were isolated from each of 616 of these cosmids. These probes were then used to localize the cosmids by hybridization to a somatic cell hybrid deletion mapping panel capable of resolving chromosome 3 into nine distinct subregions. All 616 of the cosmids were localized to either the long or short arm of chromosome 3 and 63% of the short arm cosmids were more precisely localized. We have identified a total of 87 cosmids that contain fragments that are evolutionarily conserved. Fragments from these cosmids should prove useful in the identification of new chromosome 3-specific genes as well as in comparative mapping studies. The localized cosmids should provide excellent saturation of human chromosome 3 and facilitate the construction of physical and genetic linkage maps to identify various disease loci including Von Hippel Lindau disease and renal and small cell lung carcinoma.     

Isolation, characterization, and regional mapping of microclones from a human chromosome 21 microdissection library.

Thirty-four unique-sequence microclones were isolated from a previously described microdissection library of human chromosome 21 and were regionally mapped using a cell hybrid mapping panel which consists of six cell hybrids and divides chromosome 21 into eight regions. The mapping results showed that the microclones were unevenly distributed along chromosome 21, with the majority of microclones located in the distal half portion of the long arm, between 21q21.3 and 21qter. The number of unique-sequence clones began to decrease significantly from 21q21.2 to centromere and extending to the short arm. This finding is consistent with those reported in other chromosome 21 libraries. Thus, it may be inferred that the proximal portion of the long arm of chromosome 21 contains higher proportions of repetitive sequences, rather than unique sequences or genes. The microclones were also characterized for insert size and were used to identify the corresponding genomic fragments generated by HindIII. In addition, we demonstrated that the microclones with short inserts can be efficiently used to identify YAC (yeast artificial chromosome) clones with large inserts, for increased genomic coverage for high-resolution physical mapping. We also used 200 unique-sequence microclones to screen a human liver cDNA library and identified two cDNA clones which were regionally assigned to the 21q21.3-q22.1 region. Thus, generation of unique-sequence microclones from chromosome 21 appears to be useful to isolate and regionally map many cDNA clones, among which will be candidate genes for important diseases on chromosome 21, including Down syndrome, Alzheimer disease, amyotrophic lateral sclerosis, and one form of epilepsy.     

Construction and regional localization of clones from a NotI linking library from human chromosome 17q

A NotI linking library was constructed from a somatic cell hybrid containing chromosome 17q as its only human material. A total of 112 human clones were assigned to nine regions of 17q using a somatic cell hybrid mapping panel. The library includes clones that detect the acute promyelocytic leukemia and von Recklinghausen neurofibromatosis translocation breakpoints at 17q11.2-12 and 17q11.2, respectively, on pulsed-field gel electrophoresis. The mapped clones represent over 50% of the estimated number of NotI sites on 17q, and therefore constitute an important resource for long-distance mapping.     

Chromosomal localization of seven HSA3q13-->q23 NotI linking clones on chicken microchromosomes: orthology of GGA14 and GGA15 to a gene-rich region of HSA3

Double-color fluorescence in situ hybridization was performed on chicken chromosomes using seven unique clones from the human chromosome 3-specific NotI linking libraries. Six of them (NL1-097, NL2-092, NL2-230, NLM-007, NLM-118, and NLM-196) were located on the same chicken microchromosome and NL1-290 on another. Two chicken microchromosome GGA15-specific BAC clones, JE024F14 containing the IGVPS gene and JE020G17 containing the ALDH1A1 gene, were cytogenetically mapped to the same microchromosome that carried the six NotI linking clones, allowing identification of this chromosome as GGA15. Two GGA14-specific clones, JE027C23 and JE014E08 containing the HBA gene cluster, were co-localized on the same microchromosome as NL1-290, suggesting that this chromosome was GGA14. The results indicated that the human chromosomal region HSA3q13-->q23 is likely to be orthologous to GGA15 and GGA14. The breakpoint of evolutionary conservation of human and chicken chromosomes was detected on HSA3q13.3-->q23 between NL1-290, on the one hand, and six other NotI clones, on the other hand. Considering the available chicken-human comparative mapping data, another breakpoint appears to exist between the above NotI loci and four other genes, TFRC, EIF4A2, SKIL and DHX36 located on HSA3q24-->qter and GGA9. Based on human sequences within the NotI clones, localization of the six new chicken coding sequences orthologous to the human/rodent genes was suggested to be on GGA15 and one on GGA14. Microchromosomal location of seven NotI clones from the HSA3q21 T-band region can be considered as evidence in support of our hypothesis about the functional analogy of mammalian T-bands and avian microchromosomes.     

Analysis of human chromosome 21: correlation of physical and cytogenetic maps; gene and CpG island distributions.

Human chromosome 21 has been analyzed by pulsed-field gel electrophoresis using somatic cell hybrids containing limited regions of the chromosome and greater than 60 unique sequence probes. Thirty-three independent NotI fragments have been identified, totalling 43 million bp. This must account for essentially the entire long arm, and therefore gaps remaining in the map must be small. The extent of the pulsed-field map has allowed the direct correlation of the physical map with the cytogenetic map: translocation breakpoints can be unambiguously positioned along the long arm and the distances between them measured in base pairs. Three breakpoints have been identified, providing physical confirmation of cytogenetic landmarks. Information on sequence organization has been obtained: (i) 60% of the unique sequence probes are located within 11 physical linkage groups which can be contained in only 20% of the long arm; (ii) 9/21 genes are clustered within 4%; (iii) translocation breakpoints appear to occur within CpG island regions, making their identification difficult by pulsed-field techniques. This analysis contributes to the human genome mapping effort, and provides information to guide the rapid investigation of the biology of chromosome 21.     

Regional mapping of unique DNA sequences from human chromosome 3 derived from a flow-sorted chromosome library

Eight single-copy DNA probes specific for human chromosome 3 were isolated by screening a human chromosome 3-derived genomic library. Southern blot analyses of DNAs isolated from a panel of somatic cell hybrids allowed us to regionally assign all probes to subregions on chromosome 3. Three clones were localized to the short arm of chromosome 3 (3p21----pter), two to the long arm (3q21----qter), and three to the 3q21----3p21 subregion. Six of these DNA sequences map to regions overlapping a segment of chromosome 3 (3p14----p23) frequently deleted in small cell lung cancer cells. Restriction fragment length polymorphism analyses indicate that at least three of the eight single-copy probes studies show MspI or BglII polymorphisms. This library is a useful source of chromosome 3-specific probes.     

A long-range restriction map between the alpha-globin complex and a marker closely linked to the polycystic kidney disease 1 (PKD1) locus

Two polymorphic loci and two additional probes that map close to CMM65, which is tightly linked to the polycystic kidney disease 1 (PKD1) locus in chromosome band 16p13.3, are described. These new probes were isolated from a library that was enriched by preparative pulsed-field gel electrophoresis (PFGE) for sequences from a 320-kb NotI fragment that includes CMM65. Through the use of a panel of somatic cell hybrids and PFGE, the new polymorphic loci, PNL56S and NKISP1, were localized within 60 kb and approximately 250 kb distal to CMM65, respectively. A long-range restriction map linking these new probes and the distal markers EKMDA2, CMM103, and alpha-globin was constructed. These latter probes have been localized to regions approximately 900 kb, 1.2 Mb, and 1.9 Mb distal to CMM65, respectively. The entire region was found to be unusually rich in CpG dinucleotides. The new polymorphic probes and the long-range map will aid both the search for the PKD1 locus and the detailed characterization of this distal region of 16p.     

Allelic loss mapping and physical delineation of a region harboring a thymic lymphoma suppressor gene on mouse chromosome 16

Our previous mapping of allelic loss in gamma-ray induced thymic lymphomas in F(1) hybrid and backcross mice between BALB/c and MSM strains identified three regions with high frequencies of allelic loss which probably harbor a tumor suppressor gene. One region, Tlsr7, exists near the D16 Mit122 locus on chromosome 16. This study has further localized Tlsr7 by constructing a physical map and scanning a total of 587 thymic lymphomas. The map consists of 13 overlapping BAC clones and isolation of BAC-derived polymorphic probes leads to fine mapping of allelic losses. Eleven lymphomas show informative breakpoints of allelic loss regions relative to the flanking markers on the map. Pulsed-field gel electrophoresis of NotI digests of the clones shows that the commonly lost region is localized within an approximately 300 kb interval near D16Mit192. This map is invaluable to facilitate the identification of genes in the Tlsr7 region.     

Cosmid linking clones localized to the long arm of human chromosome 11.

Molecular probes that contain DNA flanking CpG-rich restriction sites are extremely valuable in the construction of physical maps of chromosomes and in the identification of genes associated with hypomethylated HTF (HpaII tiny fragment) islands. We describe a new approach to the isolation and characterization of linking clones in arrayed chromosome-specific cosmid libraries through the large-scale semiautomated restriction mapping of cosmid clones. We utilized a cosmid library representing human chromosome 11q12-11qter and carried out automated restriction enzyme analysis, followed by regional localization to chromosome 11q using high-resolution in situ suppression hybridization. Using this approach, 165 cosmid linking clones containing one or more NotI, BssHII, SfiI, or SacII sites were identified among 960 chromosome-specific cosmids. Furthermore, this analysis allowed clones containing a single site to be distinguished from those containing clusters of two or more rare sites. This analysis demonstrated that more than 75% of cosmids containing a rare restriction site also contained a second rare restriction site, suggesting a high degree of CpG-rich restriction site clustering. Thirty chromosome 11q-specific cosmids containing rare CpG-rich restriction sites were regionally localized by high-resolution fluorescence in situ suppression hybridization, demonstrating that all of the CpG-rich sites detected by this method were located in bands 11q13 and 11q23. In addition, the distribution of (CA)n repetitive sequences was determined by hybridization of the arrayed cosmid library with oligonucleotide probes, confirming a random distribution of microsatellites among CpG-rich cosmid clones. This set of reagent cosmid clones will be useful for physical linking of large restriction fragments detected by pulsed-field gel electrophoresis and will provide a new and highly efficient approach to the construction of a physical map of human chromosome 11q.