A plasmid cloning system utilizing replication and packaging functions of the filamentous bacteriophage fd

DNA cloning vectors were developed which utilize the replication origin (ori) of bacteriophage fd for their propagation. These vectors depend on the expression of viral gene 2 that was inserted into phage lambda, which in turn was integrated into the host genome. The constitutive expression of gene 2 in the host cells is sufficient for the propagation of at least 100 pfd plasmids per cell. In addition to the fd ori, the pfd vectors carry various antibiotic-resistance genes and unique restriction sites. Some of these vectors have no homologies to commonly used pBR plasmids or to lambda DNA. The nucleotide sequence of the vectors can be deduced from published sequences. Large DNA inserts can be stably propagated in pfd vectors; these are more stable than similar DNA fragments cloned in intact genomes of filamentous bacteriophage. Inclusion of phage sequences required for efficient phage packaging and infection with a helper phage resulted in formation of phage particles containing single-stranded plasmid genomes. Growth at 42 degrees C without selective pressure results in loss of pfd plasmids.     

Construction and characterization of new coliphage M13 cloning vectors

New single-stranded DNA cloning vectors have been constructed by the insertion of additional DNA fragments into a HaeII restriction site in the bacteriophage M13 duplex replicative form (RF). These inserts into the M13 genome bring a single restriction sites useful for cloning, including PstI, XorII, EcoRI, SstI, XhoI, KpnI, and PvuII. Drug-resistance genes cloned into M13 include the beta-lactamase (bla) gene and the chloramphenicol acetyl transferase (cat) gene. These vectors provide a convenient means of easily obtaining the separated strands of a cloned duplex DNA fragment by cloning the fragment in each of the two possible orientations. Standard cloning techniques commonly applied to double-stranded DNAs can be utilized to insert foreign DNAs into the duplex RF DNAs of these vectors. Cells transformed by chimeric DNAs extrude filamentous phage particles carrying a circular single-stranded copy of the chimeric viral strand. Because M13-infected cells continue to grow and divide, cells can be transformed to yield either plaques or drug-resistant colonies. Specific inserts are readily detected by plaque hybridization techniques using an appropriate probe. Chimeric viral single strands from virus particles in the supernatant of small volumes of infected cultures can be rapidly and sensitively analyzed by agarose gel electrophoresis to determine the size of an insert.     

A phage T4 in vitro packaging system for cloning long DNA molecules.

Recombinant plasmid DNAs containing long DNA inserts that can be propagated in Escherichia coli would be useful in the analysis of complex genomes. We tested a bacteriophage T4 in vitro DNA packaging system that has the capacity to package about 170 kb of DNA into its capsid for cloning long DNA fragments. We first asked whether the T4 in vitro system can package foreign DNA such as concatemerized lambda imm434 DNA and phage P1-pBR322 hybrid DNA. The data suggest that the T4 system can package foreign DNA as efficiently as the mature phage T4 DNA. We then tested the system for its ability to clone foreign DNA fragments using the P1-pBR322 hybrid vectors constructed by Sternberg [Proc. Natl. Acad. Sci. USA 87 (1990) 103-107]. E. coli genomic DNA fragments were ligated with the P1 vectors containing two directly oriented loxP sites, and the ligated DNA was packaged by the T4 in vitro system. The packaged DNA was then transduced into E. coli expressing the phage P1 cyclization recombination protein recombinase to circularize the DNA by recombination between the loxP sites situated at the ends of the transduced DNA molecule. Clones with long DNA inserts were obtained by using this approach, and these were maintained as single-copy plasmids under the control of the P1 plasmid replicon. Clones with up to about 122-kb size inserts were recovered using this approach.     

A family of yeast expression vectors containing the phage f1 intergenic region

The construction and characterization of a family of yeast expression vectors is described. They have the following features: plasmid replication and selection (ApR) in Escherichia coli, packaging of single-stranded (ss) DNA upon infection of E. coli with a filamentous helper phage, replication in Saccharomyces cerevisiae based on the 2 mu plasmid origin of replication (ori), selection in yeast by complementation of LEU2 (pVT-L series, size 6.3 kb) or URA3 gene (pVT-U series, size 6.9 kb) and seven unique restriction sites for cloning within an 'expression cassette' which includes the promoter and 3' sequence of the ADH1 gene. The multiple cloning site as well as the ori and intergenic region of the phage f1 have been cloned in two orientations for convenient gene cloning and ssDNA strand selection. As a result any of these eight vectors can be chosen for cloning, expressing genes in yeast, sequencing and mutagenesis without the need for recloning into specialized vectors.     

A new cloning system for Bacillus subtilis comprising elements of phage, plasmid and transposon vectors

A new cloning system for Bacillus subtilis was devised which makes use of a combination of Tn917-containing phage SP beta derivatives and Tn917-containing Escherichia coli-B. subtilis shuttle plasmids. This system allows the initial cloning of genes in single copy, via 'prophage transformation', with a selection for complementation of mutational defects in B. subtilis hosts and permits subsequent transfer of the cloned material by homologous recombination to low-copy and high-copy vectors that replicate in both B. subtilis and E. coli. Because cloned sequences are adjacent to pB322-derived DNA in the recombinant phages, inserts can also be 'rescued' directly from the phage DNA after digestion with appropriate restriction enzymes, circularization of the fragments by ligation and transformation of an E. coli recipient. Two genomic libraries of B. subtilis chromosomal Sau3A-generated partial-digest fragments in the size ranges of 5-8 kb and 8-10 kb were constructed and screened for the complementation of mutations aroI906, cysA14, dal-1, glyB133, metC3, purA16, purB33, thrA5, trpC2 and recE4. In all cases, specialized transducing phages carrying inserts that complemented the selected markers were recovered. Inserts complementing the dal-1 and trpC2 mutations could be transferred from recombinant phages to Tn917-containing plasmids by homologous recombination without in vitro subcloning. Another insert complementing the purB33 mutation was rescued directly into E. coli from a recombinant phage DNA.     

Lambda Charon vectors (Ch32, 33, 34 and 35) adapted for DNA cloning in recombination-deficient hosts

New phage lambda-based cloning vectors, Charons 32, 33, 34 and 35, have been constructed. These vectors allow cloning of large (19-21 kb) DNA fragments in up to six cloning sites. DNA cloned in these vectors can be propagated on recA- Escherichia coli hosts.     

New derivatives of the Streptomyces temperate phage phi C31 useful for the cloning and functional analysis of Streptomyces DNA

The thiostrepton resistance gene (tsr) of Streptomyces azureus, and a synthetic oligonucleotide adapter sequence, were introduced into the DNA of attP-site-deleted phage phi C31-based cloning vectors. The DNA of two of the new derivatives, KC515 and KC516, contains single sites for the enzymes BamHI, BglII, PstI, PvuII, SstI (two sites close together) and XhoI, available for the insertion of DNA of up to 4 kb. The two vectors also contain a cloned, promoterless viomycin phosphotransferase gene (vph) from Streptomyces vinaceus. When an internal segment of the Streptomyces coelicolor glycerol (gyl) operon was inserted at the appropriate position and in the correct orientation next to vph, it could bring about in vivo recombination leading to fusion of vph of the chromosomally located gyl operon, resulting in glycerol-regulated expression of viomycin resistance. Two other new phi C31 derivatives, KC505 and KC518, are PstI and BamHI replacement vectors, respectively, for 2-8-kb DNA fragments, and allow simple screening for the presence of inserted DNA.     

Phage lambda cDNA cloning vectors for subtractive hybridization, fusion-protein synthesis and Cre-loxP automatic plasmid subcloning

We describe the construction and use of two classes of cDNA cloning vectors. The first class comprises the lambda EXLX(+) and lambda EXLX(-) vectors that can be used for the expression in Escherichia coli of proteins encoded by cDNA inserts. This is achieved by the fusion of cDNA open reading frames to the T7 gene 10 promoter and protein-coding sequences. The second class, the lambda SHLX vectors, allows the generation of large amounts of single-stranded DNA or synthetic cRNA that can be used in subtractive hybridization procedures. Both classes of vectors are designed to allow directional cDNA cloning with non-enzymatic protection of internal restriction sites. In addition, they are designed to facilitate conversion from phage lambda to plasmid clones using a genetic method based on the bacteriophage P1 site-specific recombination system; we refer to this as automatic Cre-loxP plasmid subcloning. The phage lambda arms, lambda LOX, used in the construction of these vectors have unique restriction sites positioned between the two loxP sites. Insertion of a specialized plasmid between these sites will convert it into a phage lambda cDNA cloning vector with automatic plasmid subcloning capability.     

A new filamentous phage cloning vector: fd-tet

We have constructed a hybrid chromosome composed of the genome of wild-type fd (a filamentous, male-specific bacteriophage) and a segment of transposon Tn10 coding for tetracycline resistance but not including the Tn10 insertion sequences. The hybrid phage infects male E. coli, thereby transducing the infected cells to tetracycline resistance. The phage DNA can also be propagated in F- cells after transfection. This new phage, fd-tet, may be used as a cloning vector to produce large quantities of cloned DNA in single-stranded form. Its usefulness has been demonstrated by cloning of a fragment from bacteriophage lambda. Some unexpected sequence alterations have been identified in lambda cloning experiments.     

Vectors for plant transformation and cosmid libraries.

A series of vectors has been constructed for the purpose of introducing cloned DNAs into plant genomes, using Agrobacterium tumefaciens-mediated transformation methods. One of these vectors, pCIT20, is a plasmid that contains a multiple cloning site (MCS), and a marker (Hph) that confers hygromycin resistance to plant cells. The others are all cosmid vectors which allow insertion of up to 46 kb of plant genomic DNA, and which also contain all of the necessary sequences for A. tumefaciens-mediated plant transformation. The cosmid vectors either contain a Hph marker (pCIT30), or a kanamycin-resistance marker (pCIT101-104). Three of the cosmid vectors (pCIT30, pCIT101, and pCIT103) carry bacteriophage T7 and SP6 promoters flanking the cloning Bg/II site, for synthesis of end-specific RNAs. The end-specific RNAs may be used as probes when labeled with radioactive or biotinylated nucleotides, for example, in a chromosome-walking experiment. The other two cosmid vectors (pCIT102 and pCIT104) carry restriction sites flanking the insertion site (XhoI) for convenient release of the insert by restriction digests. These sites, in combination with sites internal to the insert, allow the generation of end fragments for subcloning or labeling probes. These vectors should be valuable for isolation and analysis of plant genes, using transformation, library screening, and chromosome-walking approaches.     

A directed nucleotide-sequencing approach for single-stranded vectors based on recloning intermediates of a progressive DNA synthesis reaction

A simple method for site-directed nucleotide sequencing is presented that uses a novel procedure for generating nested 'deletions' within inserts of single-stranded clones. In this method, single-stranded template, sequencing primer, and the Klenow fragment of Escherichia coli DNA polymerase I are used to initiate progressive DNA synthesis of the entire insert of the clone. By time-dependent sampling and pooling of intermediates from the synthesis reaction a series of nested double-stranded DNA subfragments of the insert can be created. Nested subclones are then produced by S1-endonuclease treatment and oriented subcloning methods. First, smaller quantities of template DNA can be used, equivalent to a fraction of a small DNA sequencing prep. Second, it works with single-stranded M13 phage DNA rather than requiring the preparation of double-stranded replicative form DNA as in ExoIII-based methods. Third, the 'deletions' it generates can span areas of simple nucleotide sequence or secondary structure that often halt digestion in the single-stranded exonuclease-based method. Last, the method is adaptable to a larger variety of insert cloning sites than the ExoIII-based method. The main disadvantage of the method is that, due to the lower efficiency of subcloning larger DNA fragments, subclone inserts larger than 3 kb are generated only infrequently.     

Charons 36 to 40: multi enzyme, high capacity, recombination deficient replacement vectors with polylinkers and polystuffers.

New phage lambda based cloning vectors, Charons 36-40, have been constructed which allow cloning of large (up to 24 kb) DNA fragments with up to sixteen cloning enzymes. Several of these could not be used previously with lambda vectors. Clones produced with these vectors can be propagated under recombination deficient conditions. A novel polystuffer method has been developed that permits vector arms to be purified by simple precipitation and which allows reliable identification of clones that have reincorporated any part of the stuffer. Three of the vectors are available with amber mutations in essential genes.     

Rapid and efficient cosmid cloning

We present a procedure for cosmid cloning that allows rapid and efficient cloning of individual DNA fragments of between 32kb and 45kb. By appropriate treatment of the cloning vector, pJb8, we make left-hand and right-hand vector ends that are incapable of self-ligation but which accept dephosporylated insert DNA fragments. The inserted fragments are generated by partial digestion with MboI or Sau3A and are dephosphorylated to prevent ligation and insertion of non-contiguous fragments. The method eliminates the need to size the insert DNA fragments and prevents formation of clones containing short or multiple inserts. 1 microgram of target Drosophila DNA gives about 5 x 10(5) clones, with an average insert size of 38kb. We also describe a rapid and efficient method for preparing plasmid and cosmid DNA.     

A new host-vector system allowing selection for foreign DNA inserts in bacteriophage lambda gtWES.

An improved vector (lambda gtWES.T5-622) for EcoRI fragments has been derived from EK2 vector lambda gtWES.lambdaB' by replacing the lambda B fragment with two identical 1.1 Md fragments from the pre-early region of bacteriophage T5. The new vector has two advantages which facilitate elimination of parental-type recombinants in an in vitro recombination experiment. Firstly, the 1.1 Md insert is too small to be re-inserted into lambda gtWES in a single copy. Secondly the 1.1 Md T5 fragment carries T5 gene A3 which prevents growth of phage retaining this fragment when the Excherichia coli host carries plasmid ColIb. Thus, essentially all plaques are due to phage with donor DNA inserts and are free of T5 DNA fragments. The size usually given as the theoretical minimum size for insertion into the lambda gt series of vectors is 0.66 Md. We have shown that this size is an underestimate and that the lower limit is about 1.6 Md. A precise estimate is difficult since there is strong selection, among phage having small inserts, for those which have acquired additional genetic material by duplication of the lambda DNA.