An improved pulsed-field polyacrylamide gel electrophoresis system for physical selection of linking clones: isolation of SfiI linking clones from a chromosome 21-specific library

We had previously developed an efficient procedure for selective cloning of rare-cutter linking fragments that is based on physical separation of linking clone DNAs by pulsed-field polyacrylamide gel electrophoresis (PF-PAGE). An advantage of the physical selection procedure over the conventional cloning-based ones utilizing the insertion of selection marker or vector sequences into the rare-cutter sites is that it can be readily applied to the selection of linking fragments for rare-cutters, generating ambiguous cohesive end sequences such as SfiI (GGCCNNNN/NGGCC). In the present work, the physical separation procedure was improved by introducing a discontinuous buffer system into PF-PAGE, and its feasibility was exemplified by the selective isolation of SfiI linking clones from a human chromosome 21-specific library. This simple and efficient procedure will provide a useful tool for genome analysis.     

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.     

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.     

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.     

Use of the polymerase chain reaction for the differential cross screening of libraries cloned into phage-lambda-based vectors

We describe a simple and rapid method that can be used to identify sequences present in any two DNA libraries (either genomic or cDNA), provided only that the libraries are in different vectors with different cloning sites. This procedure makes use of the polymerase chain reaction (PCR) to amplify the inserts of one library. The product of the PCR reaction is then used to screen a second library to identify sequences which are common to both. We illustrate the use of this method for the systematic isolation of human X-chromosome-linked genomic clones that harbor sequences expressed in human chorioretinal tissue.     

The isolation of structural genes from libraries of eucaryotic DNA

We present a procedure for eucaryotic structural gene isolation which involves the construction and screening of cloned libraries of genomic DNA. Large random DNA fragments are joined to phage lambda vectors by using synthetic DNA linkers. The recombinant molecules are packaged into viable phage particles in vitro and amplified to establish a permanent library. We isolated structural genes together with their associated sequences from three libraries constructed from Drosophila, silkmoth and rabbit genomic DNA. In particular, we obtained a large number of phage recombinants bearing the chorion gene sequence from the silkmoth library and several independent clones of β-globin genes from the rabbit library. Restriction mapping and hybridization studies reveal the presence of closely linked β-globin genes.     

The mapping of chromosomes in Saccharomyces cerevisiae. I. A cosmid vector designed to establish, by cloning into cdc-mutants, numerous start loci for chromosome walking in the yeast genome

A series of vectors for cosmid cloning in yeast has been derived from cosmid pHC79. Vectors pMT4 through pMT6 contain two tandemly arranged cohesive end sites (cos) from the genome of bacteriophage lambda. Their design allows the rapid and simple preparation of cosmid arms by linearizing a vector at the unique PvuII-restriction site located between the two cos-sequences and then cutting the linearized molecule at one of its unique cloning sites for BamHI, ClaI, PvuI, SalI or ScaI. Cosmids generated with arms from the most advanced vector, pMT6, carry the origin of replication (ori) and the ApR gene from pBR322 and the TRP1/ARS1 and URA1 genes from Saccharomyces cerevisiae. A yeast genomic DNA library was established by packaging in vitro, into bacteriophage lambda preheads, of partially restricted yeast DNA fragments ligated to cosmid arms of vector pMT6. About 80% of the clones thus obtained comprise inserts of contiguous genomic DNA over 30 kb in length. Unique DNA probes for the yeast genes CDC10, CDC39, HIS4, LEU2, and PGK1 have successfully been applied when testing for completeness of this library by isolating a series of overlapping cosmid clones that carry the respective genes. The library will thus be useful for the selection of cosmid clones which carry CDC genes from yeast by complementing first, with the vectorial yeast gene URA1, the pyrimidine auxotrophy of most cdc-strains and then, with the respective CDC wild-type genes, of the temperature-sensitive mutant alleles. Most CDC clones thus obtained will provide unique DNA probes which serve as randomly distributed start sequences within the yeast genome for overlap hybridization screening in chromosome mapping studies.     

Isolation of a functional human interleukin 2 gene from a cosmid library by recombination in vivo

A method has been developed that allows the isolation of genomic clones from a cosmid library by homologous recombination in vivo. This method was used to isolate a human genomic interleukin 2 (IL2) gene. The genomic cosmid library was packaged in vivo into lambda phage particles. A recombination-proficient host strain carrying IL2 cDNA sequences in a non-homologous plasmid vector was infected by the packaged cosmid library. After in vivo packaging and reinfection, recombinants carrying the antibiotic resistance genes of both vectors were selected. From a recombinant cosmid clone the chromosomal IL2 gene was restored. After DNA mediated gene transfer into mouse Ltk- cells human IL2 was expressed constitutively.     

HpaII library indicates ‘methylation-free islands’ in wheat and barley

Summary A library of wheat genomic DNA HpaII tiny fragments (HTF), sized below 500 bp, has been constructed. Of the clones in the library 80% belong to the single/low-copy category, while 12% of the clones are nuclear repetitive sequences and 8% originate from the chloroplast and mitochondrial DNA. This result shows a substantial enrichment in the single/low-copy sequences of the wheat genome, which contains at least 80% repetitive sequences. Twenty-nine random single/lowcopy clones were analysed further for wheat chromosome location, cross-hybridisation to barley DNA and their association with rare-cutting, C-methylation-sensitive restriction sites. The results show that the HTF clones are associated more frequently than expected with NotI, MluI, NruI and PstI sites in wheat and barley genomic DNA. The 12% repetitive fraction of the clones contain both moderately and highly repetitive sequences, but no tandemly repeated sequences. The level of enrichment for single/low-copy sequences indicates that libraries of this type are a valuable source of probes for RFLP mapping. In addition, the close association of the HTF clones with rare-cutting restriction enzyme sites ensures that HTF clones will have a useful role in the construction of long-range physical maps in wheat.     

Use of short oligonucleotides to screen cosmid libraries for clones containing G/C-rich sequences

We have developed a method to identify clones containing recognition sequences for enzymes that cut mammalian genomes infrequently by direct screening of genomic libraries. The degenerate oligonucleotide NNGCGGCCGCNN, in which the internal 8 bases correspond to the recognition sequence of Not I, was used to screen a cosmid library, and it led to a greater than 10-fold enrichment in the number of clones containing Not I sites. This technique permits the efficient identification of sufficient clones from a chromosome-specific library to allow the construction of a complete pulsed-field map of that chromosome and to assist in finding genes in genomic DNA.     

Characterization of the gene for human plasminogen, a key proenzyme in the fibrinolytic system

The organization and structure of the gene coding for plasminogen has been determined by a combination of in vitro amplification of leukocyte DNA from normal individuals and isolation of unique clones from three different human genomic libraries. These clones were characterized by restriction mapping, Southern blotting, and DNA sequencing. The gene for human plasminogen spanned about 52.5 kilobases of DNA and consisted of 19 exons separated by 18 introns. DNA sequence analysis revealed that the five kringle structures in plasminogen were coded by two exons. The nucleotides in the introns at the intron-exon boundaries were GT-AG analogous to those found in other eukaryotic genes. Three polyadenylation sites for plasminogen mRNA were also identified. When the amino acid sequences deduced from the genomic DNA and cDNAs of plasminogen were compared with that of the plasma protein determined by amino acid sequence analysis, an apparent amino acid polymorphism was observed in several positions of the polypeptide chain. Nucleotide sequence analysis of the amplified genomic DNAs and genomic clones also revealed that the plasminogen gene was very closely related to several other proteins, including apolipoprotein(a). This protein may have evolved via duplication and exon shuffling of the plasminogen gene. The presence of another plasminogen-related gene(s) in the human genomic library was also observed.     

Plasmid and bacteriophage vectors for excision of intact inserts

Plasmid (pPolyIII) and bacteriophage lambda (EMBL301) vectors are described in which sites for the rare-cutting enzymes SfiI and NotI (8-bp, recognition sequences) flank the polylinker cloning region. Intact DNA inserts for introduction into cultured cells or into the early embryo are readily excised from the vectors. General-purpose miniplasmid cloning vectors pPolyI and pPolyII are also described, and the utility of the bacteriophage lambda vector is demonstrated in the construction of a bovine genomic library.     

A binary vector for transferring genomic libraries to plants.

The transformation of mutant plants with a complete recombinant library derived from wild-type DNA followed by assay of transformed plants for complementation of the mutant phenotype is a promising method for the isolation of plant genes. The small genome of Arabidopsis thaliana is a good candidate for attempting this so-called shotgun transformation. We present the properties of an A. thaliana genomic library cloned in a binary vector, pC22. This vector, designed to introduce genomic libraries into plants, contains the oriV of the Ri plasmid pRiHR1 by which it replicates perfectly stably in Agrobacterium. Upon transfer of the library from E. coli to A. tumefaciens large differences in transfer efficiencies of individual recombinant clones were observed. There is a direct relation between transfer efficiency and stability of the recombinant clones both in E. coli and A. tumefaciens. The stability is independent of the insert size, but seems to be related to the nature of the insert DNA. The feasibility of shotgun transformation and problems of statistical sampling are discussed.     

Isolation of clones on chromosome 7 that contain recognition sites for rare-cutting enzymes by oligonucleotide hybridization

Five G/C-containing oligonucleotides that include the recognition sequences of rare-cutting restriction enzymes have been used to isolate almost 100 different genomic segments from chromosome 7 that contain recognition sites for those enzymes. Hybridization and washing at 27 degrees C allow the use of 8-bp radiolabeled oligonucleotides to detect specific G/C-containing sequences in less than 1 ng of cloned DNA. This method was used to isolate 9 positive clones from 138 previously isolated single-copy probes from a flow-sorted chromosome 7 library. The specificity of the method was confirmed by showing that clones that gave positive hybridization signals also contained the corresponding restriction site. The oligonucleotides were also used to analyze approximately 12,000 kb of genomic sequence from a newly constructed chromosome 7 cosmid library that yielded 88 positive cosmids from 350 analyzed. The average distances between binding sites ranged from 200 to 690 kb and was independent of the number of CpG residues present in the oligonucleotide. Confirmation that clones containing restriction sites for these rare-cutting enzymes are located near genes was obtained by hybridization to RNA and cross-species DNA blots.     

An F factor based cloning system for large DNA fragments.

An effective technique using an Escherichia coli plasmid system was developed to clone fragments of exogenous DNA of as large as 100 kilobase pairs. The characteristic features of this technique are the use of a low copy number (one to two) mini-F based plasmid vector and the introduction of artificial lambda cosR ends into the termini of DNA sources and then of the cosL ends into those of linearized vector molecules. This terminal modification greatly facilitated the formation of active large recombinant molecules, which was rarely achieved when the modification was omitted. The efficiency with which large recombinant clones can be generated is high enough to allow construction of a comprehensive library of higher organisms. All analyses of the plasmids recovered have revealed that the inserts were faithful replicas of the human DNAs used as sources.     

High efficiency vectors for cosmid microcloning and genomic analysis

We describe the construction and use of cosmid vectors designed for microcloning, gene isolation and genomic mapping starting from submicrogram amounts of eukaryotic DNA. These vectors contain (1) multiple cos sites to allow for simple and efficient cloning using non size-selected DNA; (2) bacteriophage T3 and T7 promoter sequences flanking the cloning site to allow for the synthesis of end-specific probes for chromosome walking; (3) a selectable gene for immediate gene transfer of cosmid DNA into mammalian cells; (4) recognition sequences for specific oligodeoxyribonucleotides to allow rapid restriction mapping; (5) unique NotI, SacII or SfiI sites flanking the cloning site to allow for removal of the cloned DNA insert from the vector. These cosmid vectors allow the construction of high quality genomic libraries in situations where the quantity of purified DNA is extremely limited, such as when using DNA prepared from purified mammalian chromosomes isolated by fluorescence-activated cell sorting.     

Use of repetitive DNA probes as physical mapping strategy in Caenorhabditis elegans.

A method for linking genomic sequences cloned in yeast artificial chromosomes (YACs) has been tested using Caenorhabditis elegans as a model system. Yeast clones carrying YACs with repeated sequences were selected from a C. elegans genomic library, total DNA was digested with restriction enzymes, transferred to nylon membranes and probed with a variety of repetitive DNA probes. YAC clones that overlap share common bands with one or more repetitive DNA probes. In 159 YAC clones tested with one restriction enzyme and six probes 28 overlapping clones were detected. The advantages and limitations of this method for construction of YAC physical maps is discussed.     

Positive selection vectors for high-fidelity PCR cloning

The power of PCR cloning of a target DNA fragment is limited by polymerase-induced mutations. While high-fidelity PCR products can be achieved by reducing the number of PCR cycles, the cloning of the very small amount of DNA thus amplified should give only a few recombinant clones (carrying an insert), which would be very difficult to screen from thousands of background false-positive clones generated by all the currently available vectors, including the positive selection vectors. False-positive clones are mostly generated by the recircularization of linearized vectors that have lost some bases at their ends due to digestion with contaminating exonuclease activities present in restriction enzymes, ligases, polymerases, and other reagents. To overcome this problem, two positive selection vectors, pRGR1Ap and pREM5Tc, have been developed, based on the principles of reporter gene reconstruction and regulatory element modulation, respectively. A PCR primer carrying a vector-specific sequence at its 5' end is used in PCR. When the resultant PCR products are ligated to the specific vector, an antibiotic resistance gene is expressed, thus donating positive selection capability to the harboring cells in a specific selection medium. These vectors cloned PCR fragments generated from less than a femtomole quantity of Escherichia coli genomic DNA after only three cycles of PCR amplification, thus greatly reducing the number of recombinant clones containing polymerase-induced mutations.     

Clones from an 840-kb fragment containing the 5' region of the DMD locus enriched by pulsed field gel electrophoresis

Detailed analysis of a large region of genomic DNA is facilitated by generating overlapping clones covering the entire region. These clones are usually obtained by bidirectional "walking" using either bacteriophage lambda or cosmid cloning vectors. This is a slow procedure when starting from a single start site. Multiple start sites are an advantage, and here we describe a method of generating clones from an extensive region of the Duchenne muscular dystrophy locus by preparative pulsed field gel electrophoresis using the chromosome of interest isolated in a cell hybrid. We have generated 12 clones mapping to an 840-kb SfiI fragment of DNA from the Xp2.1 region of the X chromosome, where the DMD gene has been localized. Further localization of these clones to the four subregions of the 840-kb fragment indicates that the clones are distributed throughout the fragment. The feasibility of using this approach to generate probes close to other loci is discussed.     

Construction of a bacterial artificial chromosome library, determination of genome size, and characterization of an Hsp70 gene family in Phytophthora nicotianae

The oomycete plant pathogen Phytophthora nicotianae causes diseases on a wide range of plant species. To facilitate isolation and functional characterization of pathogenicity genes, we have constructed a large-insert bacterial artificial chromosome (BAC) library using nuclear DNA from P. nicotianae H1111. The library contains 10,752 clones with an average insert size of 90 kb and is free of mitochondrial DNA. The quality of the library was verified by hybridization with 37 genes, all of which resulted in the identification of multiple positive clones. The library is estimated to be 10.6 haploid genome equivalents based on hybridization of 23 single-copy genes and the genome size of P. nicotianae was estimated to be 95.5 Mb. Hybridization with a nuclear repetitive DNA probe revealed that 4.4% of clones in the library contained 28S rDNA. Hybridization of total genomic DNA to the library indicated that at least 39% of the BAC library contains repetitive DNA sequences. A BAC pooling strategy was developed for efficient library screening. The library was used to identify and characterize BAC clones containing an Hsp70 gene family whose four members were identified to be clustered within approximately 18 kb in the P. nicotianae genome based on the physical mapping of eight BACs spanning a genomic region of approximately 186 kb. The BAC library created provides an invaluable resource for the isolation of P. nicotianae genes and for comparative genomics studies.