Characterization of Two Chromosome 12 Cosmid Libraries and Development of STSs from Cosmids Mapped by FISH

We have constructed and characterized two related human chromosome 12-specific cosmid libraries. DNA from flow-sorted chromosomes from a somatic cell hybrid was cloned into a cosmid vector. Approximately 61% of the cosmids in the nearly 26,200 member arrayed libraries (LLt2NC01 and LLt2NC02) contain human DNA inserts, and 31% of the cosmids derived from human DNA contain CA repeats. One hundred and fifty-two cosmids isolated from the libraries have been mapped by fluorescence in situ hybridization (FISH). Cosmids containing human DNA inserts were localized by FISH exclusively to chromosome 12, confirming the chromosomal specificity of the libraries. The cosmids have been localized to all parts of this chromosome, although some regions are more highly represented than others. Partial sequence information was obtained from 44 mapped cosmids, and oligonucleotide primer pairs were synthesized that define unique sequence tagged sites (STSs). These mapped cosmids, and unique STSs derived from them, provide a set of useful clones and primer pairs for screening YAC libraries and developing contigs centered on regions of interest within chromosome 12. In addition, 120 of the mapped cosmids contain CA repeats, and thus they also provide a useful resource for defining highly polymorphic simple tandem repeat elements that serve as genetic markers for linkage analysis and disease gene localization.     

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 and mapping of cosmid markers on human chromosome 22, including one within the submicroscopically deleted region of DiGeorge syndrome

A genomic cosmid library was constructed from a Chinese hamster/human hybrid cell containing human intact chromosome 22 as its only human component. Of 1000 cosmids with inserts derived from human chromosome 22, 191 were tested for restriction fragment length polymorphisms (RFLPs). As a result, 64 clones detected RFLPs, including five variable number of tandem repeats systems. Of the remaining 127 cosmids, 111 detected a single copy sequence on human chromosome 22. Five somatic cell hybrids allowed us to assign all of the 64 polymorphic cosmids and 44 non-polymorphic cosmids to four different regions of human chromosome 22. In two patients with DiGeorge syndrome, one of the cosmids that had been sublocalized to 22pter-q11 detected hemizygosity. These 108 cosmid markers regionally assigned to human chromosome 22 should be useful for the construction of long-range physical maps and the identification of genetic alterations on the chromosome.     

Cosmid clones derived from both euchromatic and heterochromatic regions of the human Y chromosome.

Clones containing sequences derived from the human Y chromosome have been isolated from cosmid libraries of a human-mouse hybrid cell line. These libraries were constructed in the new expression vectors Homer V and Homer VI. The collection of cosmids isolated is enriched for unique sequence DNA and only a few of the cosmids contain the tandemly repeated sequences which constitute a major portion of the Y chromosome. Three cosmids have been studied in detail. One cosmid shows extensive homology over at least 20 kb with the long arm of the X chromosome; this homology is outside the predicted homology region required for sex chromosome pairing. The other two clones contain unique sequences specific to the Y chromosome and both map to the heterochromatic region of the Y chromosome long arm.     

Progress towards construction of a total restriction fragment map of a human chromosome.

We present an approach to the construction of an overlapping restriction fragment map of a single human chromosome. A genomic cosmid library genome was constructed from a mouse-human hybrid cell line containing chromosome 17 as its only human genetic component. Cosmids containing human inserts were isolated by hybridisation to a human Alu sequence. DNAs from ninety-six randomly chosen cosmids were digested with either EcoRI or HindIII, end-labelled with 35S-dATP and analysed using agarose gel electrophoresis. Comparison of the restriction fragment patterns revealed two pairs of overlapping clones, that were confirmed by cross-hybridization of the overlapping fragments. The two pairs of cosmids both mapped to human chromosome 17, as shown by hybridization to a panel of somatic cell hybrids. These data demonstrate that the generation of an overlapping cosmid map along a human chromosome is feasible, representing an intermediate step towards the complete sequencing of a human chromosome.     

Identification and purification of overlapping cosmid clones of the region Xq24-qter of human X chromosome using HPLC.

The assembly of a large physical map of genomes requires simultaneous analysis of many cosmid clones for overlapping regions. The search for overlapping regions may be achieved by various means. High-performance liquid chromatography (HPLC) provides an alternative to gel electrophoresis since microgram amounts of each DNA fragment may be collected into individual test tubes for further analysis. HPLC has been used to identify overlapping cosmid clones from a pool of cosmid DNA containing the terminal portion of the long arm of the human X chromosome (Xq24-qter). Among 400 cosmids analyzed, 3 were shown to overlap.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide exicision repair gene ERCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

Isolation and mapping of 62 new RFLP markers on human chromosome 11.

To obtain new RFLP markers on human chromosome 11 for a high-resolution map, we constructed a cosmid library from a Chinese hamster x human somatic hybrid cell line that retains only human chromosome 11 in a Chinese hamster genomic background. A total of 3,500 cosmids were isolated by colony hybridization with labeled human genomic DNA. DNA was prepared from 130 of these cosmid clones and examined for RFLP. In 62 of them, polymorphism was detected with one or more enzymes; four RFLPs were VNTR systems. All polymorphic clones were assigned to one of 22 intervals obtained by mapping on a deletion panel of 15 somatic hybrid cell lines containing parts of chromosome 11; 11 clones were finely mapped by in situ hybridization. Although RFLP markers were scattered on the whole chromosome, they were found predominantly in the regions of R-banding. These DNA markers will contribute to fine mapping of genes causing inherited disorders and tumor-suppressor genes that reside on chromosome 11. Furthermore, as one-third of the cosmid clones revealed a band or bands in Chinese hamster DNA, indicating sequence conservation, this subset of clones may be useful for isolating biologically important genes on chromosome 11.     

Studies on locus expansion, library representation, and chromosome walking using an efficient method to screen cosmid libraries

We have developed an efficient screening method to search for clones in cosmid libraries prepared from human genomic DNA. Genomic, cDNA, and cosmid probes have been used to isolate homologous cosmids from human chromosomes 7, 10, 16, 17 and X as part of a search for polymorphic nucleotide sequences. This method has been successfully applied to chromosome walking experiments at the interstitial retinol-binding protein locus on chromosome 10, and may be a useful tool for investigating representation of cloned sequences in cosmid libraries. Our library was prepared in the vector c2RB (Bates and Swift, 1983), but the method is applicable to any cosmid cloning system in which the inserted DNA can be separated from the vector by restriction enzyme digestion. A cosmid library containing five human genome equivalents can be rapidly screened using three to four Southern hybridization filters. This results in substantial labor saving, particularly when screening genomes of high complexity with many different probes. Another advantage of the system is that it allows for the long-term storage of the cosmids so that they can be screened whenever necessary. As a consequence, cosmid screening can be made a routine laboratory procedure.     

Overabundance of rare-cutting restriction endonuclease sites in the human genome.

A human chromosome 3-specific cosmid library was constructed from a somatic cell hybrid containing human chromosome 3 as its only human component. This library was screened to identify 230 human recombinants which contained an average insert size of 37 kilobases. DNA prepared from 54 of these cosmids, representing 2000 kilobases of human DNA, was then tested for restriction endonuclease sites for EcoRI, HindIII, KpnI, XhoI, and DraI, as well as those of the rare-cutting restriction endonucleases NotI, SfiI, NruI, MluI, SacII, and BssHII. Sites for the latter enzymes were much more abundant than would be expected from theoretical calculations, reflecting non-random clustering of these sites. This has important implications for the use of these enzymes in the construction of physical maps of chromosomes. Some individual cosmids contained large numbers of rare sites, offering an alternative means of physically mapping chromosomes based upon identifying clusters of rare restriction sites. These clusters appear to be spaced an average of 1000 kb apart.     

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.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide excision repair gene FRCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

Isolation and regional localisation of DNA sequences from a human chromosome 11-specific cosmid library

Summary A cosmid library has been prepared in the lorist-B vector from a mouse/human somatic cell hybrid containing region 11q23-11pter as the only human component. This chromosome region is stably maintained in the hybrid as a result of translocation onto one copy of mouse chromosome 13. Individual cosmids containing human DNA were isolated by their ability to hybridise with total human DNA, digested with either HindIII or EcoRI, and 33 individual unique sequences were identified. These fragments were then isolated and subcloned into the bluescribe plasmid vector. Regional localisation of these unique sequences was achieved using a panel of somatic cell hybrids containing different overlapping deletions of chromosome 11. The majority of the 33 mapped sequences derived from the long arm of chromosome 11. Two clones were located within the 11p13–p14 region, which is associated with a predisposition to Wilms' tumour. These probes supplement those already mapped to this chromosome and will assist in the generation of a detailed chromosome 11 linkage map.     

The generation of ordered sets of cosmid DNA clones from human chromosome region 11p.

We describe progress in a continuing project aimed at the generation of an overlapping cosmid DNA clone map of the short arm of human chromosome 11. The automated procedures used to prepare DNA samples and the computerized data collection and recording systems are described. We also demonstrate the use of the clones as reagents for the rapid isolation of genomic DNAs containing smaller probed regions. We have isolated approximately 4700 human cosmid DNA clones from mouse/human hybrid cell lines that contain predominantly human chromosomal region 11p. Of the DNA in the cell lines, 60% is derived from this chromosomal region, and the remaining 40% is derived from regions of chromosomes 3, 19, and 20. A total of 4159 clones have been fingerprinted to identify potential overlaps, and we have developed 535 sets ("contigs"). Using random modeling, it is estimated that 65% of 11p must be contained in the analyzed cosmids. The database of clones has been used to identify single or overlapping clones from noncosmid DNA probes. Examples are presented. It is proposed that cosmid reference filters be distributed to requesting laboratories.     

A highly polymorphic locus on chromosome 16q revealed by a probe from a chromosome-specific cosmid library

Summary A cosmid library was constructed from genomic DNA of a human-mouse somatic cell hybrid containing an 11q–16q translocation chromosome as the only human DNA. Cosmids with human inserts were prehybridized with total human DNA and were screened to find probes that revealed highly polymorphic loci. From one such cosmid, CF33-79, a single-copy subclone was isolated which revealed an insertion/deletion polymorphism with at least 11 alleles and a PIC of 0.77. Using a somatic cell hybrid mapping panel, the subclone was mapped to chromosome 16. By in situ hybridization with the entire cosmid used as a probe, chromosomal localization was shown at 16q2224.     

Eucaryotic chromosome transfer: production of a murine-specific cosmid library from a neor-linked fragment of murine chromosome 17.

We recently developed a procedure for the molecular analysis of specific mammalian chromosomal fragments. This procedure allows for the transfer of contiguous chromosomal fragments, varying in size from a fraction to several centimorgans in length, from the donor cell of one species into a recipient cell of a different species. Specifically, we inserted a neor gene, encoded by a recombinant retrovirus, into the murine major histocompatibility complex (MHC). Metaphase chromosome transfers with this neor-tagged chromosome into recipient hamster, primate, and canine fibroblasts produced a panel of primary neor transferents, each containing a portion of, or all of, the murine MHC. A cosmid library was made from one such transferent, CHMD(D)B1. Cosmid clones were divided, using species-specific repeat probes, into those containing murine (donor) DNA sequences and those containing sequences derived from the recipient cell. The murine-specific cosmids were clustered into overlapping DNA segments by restriction enzyme digest analysis of the cosmid DNAs coupled with Southern blot analysis with, as probes, murine-specific repeat sequences and nick-translated murine genomic DNA. These cosmid clusters were analyzed for their position within or outside of the MHC, using recombinant mouse strains, and for the presence within them of known murine MHC genes.     

Four restriction fragment length polymorphisms revealed by probes from a single cosmid map to human chromosome 12q

Summary Human gene mapping would be greatly facilitated if marker loci with sufficient polymorphism information content were generally available. As a source of such markers, we have used cosmids from a human genomic library. We have used a rapid method for screening random cosmids to identify those homologous to genomic regions especially rich in restriction fragment length polymophisms (Litt and White 1985). This method allows whole cosmids to be used as probes against Southern transfers of genomic DNA; regions of cosmid probes homologous to repeated genomic sequences are rendered unable to anneal with Southern transfers by prerendered of the probes with a vast excess of non-radioactive genomic DNA. From one cosmid (C1-11) identified by this procedure, we have isolated four single-copy probes, each of which identifies a polymorphic locus. Despite the existence of some linkage disequilibrium in this system, the polymorthism information content was computed as 0.73. Using a somatic cell hybrid mapping panel, we have mapped probes from cosmid 1–11 to human chromosome 12q. Additionally, in situ hybridization of the whole cosmid to metaphase spreads allowed more precise assignment of the locus to the region 12cenq13. The locus revealed by probes from cosmid 1–11 has been designated D12S6.     

A rapid method to identify cosmids containing rare restriction sites.

A procedure for identifying specific cosmid clones containing recognition sites for "rare cutting" restriction enzymes has been developed. Cosmid clones containing human inserts were selected by hybridisation to human repetitive DNA. An oligonucleotide corresponding to the NotI recognition site, eight bases long, was labelled and used to probe DNA samples from one hundred cosmids. By optimising the difference in melting characteristics between eight-base perfect match and six-base match/two base mismatch hybrids, we were able to detect the cosmids containing either NotI (8 bp match) or XmaIII/EagI (6 bp match) sites. The generation of a map for rare cutter sites along a human chromosome, or a chromosome region, should be simplified using this approach, which will enable the identification of a set of "milestones" at intervals of several hundred kilobases (kb) along the DNA sequence.     

Mapping of 50 cosmid clones isolated from a flow-sorted human X chromosome library by fluorescence in situ hybridization.

Fifty cosmids have been mapped to metaphase chromosomes by fluorescence in situ hybridization under conditions that suppress signals from repetitive DNA sequences. The cosmid clones were isolated from a flow-sorted human X chromosome library. Thirty-eight of the clones were localized to chromosome X and 12 to autosomes such as chromosomes 3, 7, 8, 14, and 17. Although most of the cosmids mapped to the X chromosome appeared to be scattered along both the short and long arms, 10 cosmids were localized to the centromeric region of the chromosome. Southern blot analysis revealed that only two of these clones hybridized to probe pXBR-1, which detects the DXZ1 locus. In addition, 4 out of 5 cosmids mapped on chromosome 8 also localized on the centromeric region. While localization of X-specific cosmids will facilitate the physical mapping of the human X chromosome, cosmids mapped to the centromeric regions of chromosomes X and 8 should be especially useful for studying the structure and organization of these regions.