Direct cloning of cDNA inserts from λgt11 phage DNA into a plasmid vector by a novel and simple method

Bacteriophage λgt11 has been used quite extensively for producing cDNA libraries. The cDNA inserts are usually subcloned into a plasmid vector for large scale production and analysis. However, isolating the recombinant DNA of interest from the phage clones can be a tedious task. Since the E. coli strain Y1088 used for λgt11 phage infection carries a pBR322-derived plasmid endogenously, we reasoned that this endogenous plasmid could be used directly for cloning the cDNA phage insert. In this report, we describe a method in which cDNA inserts from λgt11 phage were cloned directly into the pBR322 plasmid vector, by-passing the time-consuming procedures of preparing plasmid DNA as a subcloning vector. This method is likely to be extended to the cloning of DNA inserts derived from other phage λ vectors when bacteria containing endogenous pBR322 are used as host cells.     

Identification of sequences necessary for packaging DNA into lambda phage heads

Several species of DNA molecules are packaged into lambda phage heads if they carry the region around the cohesive end site of lambda phage (cos lambda). The minimal functional sequence around cos lambda needed for packaging was examined by cloning in pBR322. The results showed that the minimal region contained 85 bp around cos lambda; 45 bp of the left arm of lambda phage and 40 bp of the right arm. A 75-bp region located to the right of the minimal region seems to enhance packaging. A 223-bp fragment containing these regions can be used as a portable element for plasmid DNA packaging into lambda phage heads. Plasmid ppBest 322, a derivative of pBR322 carrying this portable packager and both amp and tet genes, was constructed. This plasmid is useful for cloning of large DNA fragments.     

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.     

Lambda phagemids and their transducing properties

Two recombinant lambda DNAs, lambda gt::pMB9 and lambda NM::pBR322, containing, respectively, the pMB9 and pBR322 replicon were constructed and characterized. Both constructs (phagemid DNAs) transfect Escherichia coli cells, producing mature infectious phage progenies. Alternatively, drug-resistant colonies of transductants can be selected upon infection with these phages (phagemid particles) that maintain phagemid DNA in the cell in the form of covalently closed circular plasmids. The efficiency of transduction for nonlysogenic E. coli strains with lambda gt::pMB9 phage producing lambda repressor cIts ranges from 10(-7) to 10(-2) transductant colonies per input phage, depending on the temperature and strain used, while lambda NM::pBR322 phage carrying imm21 transduces with a frequency of up to 1. This means that each lambda NM::pBR322 phagemid particle is capable of establishing itself in the cell as a nonlethal plasmid, permitting formation of a resistant bacterial colony. The maximal level of transduction with lambda gt::pMB9 was obtained when E. coli cells lysogenic for lambda were used. Thus, we believe that the efficiency of transduction is determined by the turn-on of the phage repressor in the transductant. In addition, we have found that all lambda gt::pMB9-containing transductants under certain conditions harbor precisely excised pMB9; excision of pBR322 from lambda NM::pBR322 has not been observed.     

A pSC101-derived plasmid which shows no sequence homology to other commonly used cloning vectors

We have constructed a plasmid cloning vector, pGB2, which is derived from the Escherichia coli plasmid pSC101. The plasmid, which specifies resistance to spectinomycin and streptomycin, contains unique restriction sites for the enzymes HindIII, PstI, SalI, BamHI, SmaI and EcoRI. pGB2 shows no sequence homology, as detected by DNA-DNA hybridization, to several widely used vectors such as pBR322, pUC8 and phage lambda L47.1. Amongst other applications, DNA fragments can be cloned into the plasmid and then radioactive plasmid DNA can be used as a probe to screen recombinant DNA libraries.     

Recombination between bacteriophage T4 and plasmid pBR322 molecules containing cloned T4 DNA

Reciprocal recombination between T4 DNA cloned in plasmid pBR322 and homologous sequences in bacteriophage T4 genomes leads to integration of complete plasmid molecules into phage genomes. Indirect evidence of this integration comes from two kinds of experiments. Packaging of pBR322 DNA into mature phage particles can be detected by a DNA--DNA hybridization assay only when a T4 restriction fragment is cloned in the plasmid. The density of the pBR322 DNA synthesized after phage infection is also consistent with integration of plasmid vector DNA into vegetative phage genomes. Direct evidence of plasmid integration into phage genomes in the region of DNA homology comes from genetic and biochemical analysis of cytosine-containing DNA isolated from mature phage particles. Agarose gel electrophoresis of restriction endonuclease-digested DNA, followed by Southern blot analysis with nick-translated probes, shows that entire plasmid molecules become integrated into phage genomes in the region of T4 DNA homology. In addition, this analysis shows that genomes containing multiple copies of complete plasmid molecules are also formed. Among phage particles containing at least one integrated copy, the average number of integrated plasmid molecules is almost ten. A cloning experiment done with restricted DNA confirms these conclusions and illustrates a method for walking along the T4 genome.     

Lambda plasmidophages and their properties

Plasmidphage lambda NM::pBR322 has been constructed in vitro and characterized. Under normal conditions the hybrid DNA molecule undergoes a lytic cycle of phage development, whereas in the presence of antibiotic lambda DNA replicates in the cell extrachromosomally as a plasmid. Properties of plasmidphage lambda NM::pBR322 have been compared with the earlier constructed lambda gt::pMB9. It has been demonstrated that plasmid pMB9 in vivo can be precisely excised from the lambda gt::pMB9.     

Phasmids. Properties and the use in genetic engineering. I. Construction of the phasmid vector

A phasmid vector molecule designated pMYF11 has been constructed. The vector combines some useful features of plasmid and phage vector molecules. lambda pMYF11 is a hybrid of lambda 47.1 vector and pBR322 plasmid. CI- marker of pMYF11 is replaced with cI+ marker by recombination between the plasmid and prophage 434. The phasmid molecule can be used as a replacement vector for BamHI, HindIII, SalGI endonucleases. The maximum size of fragments to be cloned is 21 kilobase pairs. Positive selection for hybrid molecules is possible because of the Spi phenotype expression after replacement of the central HindIII or BamHI DNA fragment with foreign DNA. A library of Escherichia coli genes is constructed with the help of lambda pMYF11 as a vector molecule. A hybrid phage harboring genes of the proline operon is detected by means of complementation.     

A set of synthetic oligodeoxyribonucleotide primers for DNA sequencing in the plasmid vector pBR322

Seven oligonucleotide primers complementary to the plasmid vector pBR322 at positions adjacent to five of the unique restriction endonuclease cleavage sites (EcoRI, HindIII, BamHI, SalI and PstI) have been chemically synthesized. The polarity of the primers is such that any DNA inserted at one or a combination of two of the above restriction sites may be sequenced by the chain termination method using one of the synthetic DNA primers. One of the primers for sequencing inserts at the PstI site of pBR322 is also complementary to the M13 phage vector designated bla6. This set of universal primers is useful for rapid sequence determination of DNA cloned into pBR322 or M13bla6.     

A new high-capacity cosmid vector and its use

The construction of a cosmid, MUA-3, designed for the convenient cloning of eukaryotic DNA segments up to 48 kb in length is described. The cosmid contains all of the plasmid pBR322 with approx. 400 bases of lambda DNA, including the cohesive end site, inserted at the pBR322 PstI endonuclease recognition site. Methods for using this vector to construct several types of Drosophila melanogaster genomic DNA libraries are given, and libraries made by these methods are characterized. A sheared Drosophila DNA-EcoRI linker library is shown to stably maintain average Drosophila DNA inserts of over 40 kb and up to 48 kb, and the efficiency of producing clones by a partial restriction and ligation method is shown to be over 3 X 10(5) clones/microgram of Drosophila DNA.     

Highly efficient yeast-based in vivo DNA cloning of multiple DNA fragments and the simultaneous construction of yeast/ Escherichia coli shuttle vectors

In vivo recombinational cloning in yeast is a very efficient method. Until now, this method has been limited to experiments with yeast vectors because most animal, insect, and bacterial vectors lack yeast replication origins. We developed a new system to apply yeast-based in vivo cloning to vectors lacking yeast replication origins. Many cloning vectors are derived from the plasmid pBR322 and have a similar backbone that contains the ampicillin resistance gene and pBR322-derived replication origin for Escherichia coli. We constructed a helper plasmid pSUO that allows the in vivo conversion of a pBR322-derived vector to a yeast/E. coli shuttle vector through the use of this backbone sequence. The DNA fragment to be cloned is PCR-amplified with the addition of 40 bp of homology to a pBR322-derived vector. Cotransformation of linearized pSU0, the pBR322-derived vector, and a PCR-amplified DNA fragment, results in the conversion of the pBR322-derived vector into a yeast/E. coli shuttle vector carrying the DNA fragment of interest. Furthermore, this method is applicable to multifragment cloning, which is useful for the creation of fusion genes. Our method provides an alternative to traditional cloning methods.     

Plasmid vector pBR322 and its special-purpose derivatives — a review

The plasmid pBR322 was one of the first EK2 multipurpose cloning vectors to be designed and constructed (ten years ago) for the efficient cloning and selection of recombinant DNA molecules in Escherichia coli. This 4363-bp DNA molecule has been extensively used as a cloning vehicle because of its simplicity and the availability of its nucleotide sequence. The widespread use of pBR322 has prompted numerous studies into its molecular structure and function. These studies revealed two features that detract from the plasmid's effectiveness as a cloning vector: (a) plasmid instability in the absence of selection and, (b) the lack of a direct selection scheme for recombinant DNA molecules. Several vectors based on pBR322 have been constructed to overcome these limitations and to extend the vector's versatility to accomodate special cloning purposes. The objective of this review is to provide a survey of these derivative vectors and to summarize information currently available on pBR322.     

Plasmid vectors for positive galactose-resistance selection of cloned DNA in Escherichia coli

Insertion of a HindIII-EcoRI fragment carrying part of the gal operon from lambda gal+ into pBR322 yields a plasmid (pAA3) which confers strong galactose sensitivity on E. coli strains deleted for the gal operon. Sensitivity to galactose is caused by the expression of kinase and transferase (but not epimerase) genes from a promoter located in the tet gene of pBR322. Insertion of a DNA fragment carrying Tn9 at the HindIII junction blocks gal expression and produces a galactose-resistant phenotype. Hence, galactose resistance can be used to select DNA fragments cloned at the HindIII site. The system was used efficiently for cloning lambda, yeast, and human DNA. The cloned fragments can be screened directly for the presence of promoters by testing for tetracycline resistance. Alternatively, these plasmids can be used as cosmids for cloning large fragments of DNA at a number of sites. Construction of several related vectors is described.     

In vitro packaging into phage T4 particles and specific recircularization of phage lambda DNAs

Concatemeric phage lambda imm434 DNA packaged in vitro into phage T4 particles produced plaques on a selective host. Moreover, lambda DNA containing a pBR322 derivative flanked by the lambda attL and attR sites could be specifically recircularized by excisive lambda recombination to yield the pBR322 derivative. A host deficient in generalized recombination and containing a defective lambda c Its prophage which provided Int and Xis proteins was the recipient for this plasmid derivative carried by T4. Such a T4-lambda hybrid may potentially allow almost one T4 headful of donor DNA (166 kb) to be packaged and recircularized.     

Characterization of a defective phage system for the analysis of bacteriophage T4 DNA replication origins

We have developed a defective phage system for the isolation and analysis of phage T4 replication origins based on the T4-mediated transduction of plasmid pBR322. During the initial infection of a plasmid-containing cell, recombinant plasmids with T4 DNA inserts are converted into fully modified linear DNA concatamers that are packaged into T4 phage particles, to create defective phage (transducing particles). In order to select T4 replication origins from genomic libraries of T4 sequences cloned into the plasmid pBR322, we searched for recombinant plasmids that transduce with an unusually high efficiency, reasoning that this should select for T4 sequences that function as origins on plasmid DNA after phage infection. We also selected for defective phage that can propagate efficiently with the aid of a coinfecting helper phage during subsequent rounds of phage infection. which should select for T4 sequences that can function as origins on the linear DNA present in the defective phage. Several T4 inserts were isolated repeatedly in one or both of these selective procedures, and these were mapped to particular locations on the T4 genome. When plasmids were selected in this way from genomic libraries constructed using different restriction nucleases, they contained overlapping segments of the T4 genome, indicating that the same T4 sequences were selected. The inserts in two of the selected plasmids permit a very high frequency of transduction from circular plasmids: these have been shown to contain a special type of T4 replication origin.     

Physical map of the coliphage 186 chromosome

Summary A physical map of coliphage 186 was established by cloning various restriction fragments of 186 DNA into the plasmid vector pBR322 and determining the genes encoded on each fragment by marker rescue experiments using a range of 186 mutant phage.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

Retrovirus-mediated insertional mutagenesis: phagemid rescue of flanking DNA by selecting plasmid ori

A method for screening recombinant lambda libraries was devised to select phage containing genomic regions containing provirus insertions of retroviruses that carry the kanamycin and G418 resistance factor neo and the origin of replication derived from pBR322 (oripBR). Such recombinants are phagemids, able to replicate as bacteriophages or as plasmids under lambda repressor control. lambda repressor was cloned into a plasmid derived from pSC101 that is compatible with pBR322-derived phagemids. A strain carrying this plasmid may be used to select phagemids derived from a single proviral insertion with 100% efficiency from complex recombinant libraries. Homologous recombination between proviral long terminal repeats was observed at a rate of 10(-4)/plaque-forming unit in recABC+ strains. Despite this frequency, intact phagemids are easily recovered as phage after temperature shift to 42 degrees C. Since oripBR itself is a selectable marker in this system, the method could be applied to recover any sequence carrying the ori sequence from pBR322.