Transitory recombination between plasmid pHV33 and phage M13

Plasmid pHV33 and phage M13 which have no homology exceeding 13 bp, combine in Escherichia coli cells. The chimeric genome is encapsidated in phage proteins and injected into a recipient cell, where it decombines to regenerate the two parental genomes. We call this combination-decombination process 'transitory recombination'.     

The use of filamentous phage M13 in protein engineering

M13B1 vector based on the filamentous phage M13 has been constructed. M13B1 phage carries the gene of resistance to ampicillin and contains the unique site of recognition for BamHI restriction endonuclease in gene VIII coding for the major coat protein. BamHI restriction site has been inserted into the gene of the major coat protein by means of oligonucleotide directed mutagenesis. The synthetic DNA fragment coding for the model peptides has been inserted through BamHI site into the M13B1 DNA. The possibility of inserting foreign peptides into the N-terminus at maintaining the viability of hybrid phages has been shown. The differences in specificity of the recombinant phage maturation have been determined by analysing the amino acid sequence of B-protein.     

Genes involved in transitory recombination between phage M13 and plasmid pHV33.

Plasmid pHV33 and phage M13 combine in Escherichia coli cells to form a chimera, which decombines to regenerate two parental genomes. Combination can occur via two genetic pathways, one defined by the recBC genes, the other by recA, recF and possibly recL genes. Decombination can also occur via two pathways, one defined again by the recBC genes, the other by a gene not identified, but active only in the absence of the recL gene product.     

A simple system of cloning in phage M13 and DNA sequencing with terminators

A compilation of techniques for DNA cloning in filamentous phage M13 based vectors for a novice in cloning is presented. It does not require either specialized microbiological facilities, or any specific knowledge in Escherichia coli genetics. The cloning strategy uses only blunt-end ligation into a vector that has been prepared once for several hundred experiments. The first part describes the isolation, preparation and checking of a blunt-ended M13 vector (with M13 mp series vectors as an example), and also the isolation of clonable fragments, transformation of competent cells and preliminary analysis of recombinants. The second part describes procedures and equipment, which enable to sequence recombinant M13 clones by the chain termination procedure of Sanger et al. It includes simplified procedures for the preparation of sequencing gels, and the rules of interpretation of the sequencing ladders. Reference material is added, which includes trouble-shooting guide, E. coli K12 strain list and polylinker sequences for use of mp-series vectors as well as a fully documented cloning and sequencing experiment.     

A method for unidirectional deletion mutagenesis with application to nucleotide sequencing and preparation of gene fusions

A method is described for the preparation of deletions that extend in one direction from a fixed point. The method is based on the ability of deoxynucleoside [1-thio]triphosphates to be incorporated into DNA by DNA polymerase I, Klenow fragment, and the fact that alpha-thiophosphate-containing phosphodiester bonds are resistant to hydrolysis by the 3'-to-5' exonucleolytic activity of phage T4 DNA polymerase. Therefore, linear duplex DNA molecules blocked at one 3'-terminus with a thiophosphate were prepared and then degraded from the other end with the exonuclease. Digestion for different lengths of time followed by treatment with nuclease S1 and ligation allowed the preparation and recovery of a nested set of deletion mutants. Importantly, it was observed that a significant fraction of deletion mutants of recombinant M13 phages carrying the target gene in the same orientation as 'lacZ alpha' yielded phage that produced lacZ alpha-complementing activity. Nucleotide (nt) sequencing showed that these phages carried in-frame fusions between the target gene and 'lacZ alpha'. The deletion mutagenesis procedure is applied to the nt sequencing of a gnd gene from a natural isolate of Escherichia coli.     

Improved M13 phage cloning vectors and host strains: nucleotide sequences of the M13mp18 and pUC19 vectors

Three kinds of improvements have been introduced into the M13-based cloning systems. (1) New Escherichia coli host strains have been constructed for the E. coli bacteriophage M13 and the high-copy-number pUC-plasmid cloning vectors. Mutations introduced into these strains improve cloning of unmodified DNA and of repetitive sequences. A new suppressorless strain facilitates the cloning of selected recombinants. (2) The complete nucleotide sequences of the M13mp and pUC vectors have been compiled from a number of sources, including the sequencing of selected segments. The M13mp18 sequence is revised to include the G-to-T substitution in its gene II at position 6 125 bp (in M13) or 6967 bp in M13mp18. (3) M13 clones suitable for sequencing have been obtained by a new method of generating unidirectional progressive deletions from the polycloning site using exonucleases HI and VII.     

A short primer for sequencing DNA cloned in the single-stranded phage vector M13mp2.

In this paper we describe the synthesis and cloning of a short segment of DNA complementary to the region immediately adjacent to the EcoRI insertion site in the single-stranded bacteriophage vector M13mp2. This segment is useful as a "universal" primer for DNA sequencing by the dideoxynucleotide chain termination method; the template can be any DNA species cloned in M13mp2 or its derivatives. The primer has been cloned into the tetracycline resistance gene of plasmid pBR322 as one strand of a 26 bp EcoRI/BamHI fragment. This fragment may be readily prepared from an EcoRI + BamHI restriction digest of the parent plasmid (designated pSP14) by a simple size fractionation.     

A simple and rapid method to isolate purer M13 phage by isoelectric precipitation

M13 virus (phage) has been extensively used in phage display technology and nanomaterial templating. Our research aimed to use M13 phage to template sulfur nanoparticles for making lithium ion batteries. Traditional methods for harvesting M13 phage from Escherichia coli employ polyethylene glycol (PEG)-based precipitation, and the yield is usually measured by plaque counting. With this method, PEG residue is present in the M13 phage pellet and is difficult to eliminate. To resolve this issue, a method based on isoelectric precipitation was introduced and tested. The isoelectric method resulted in the production of purer phage with a higher yield, compared to the traditional PEG-based method. There is no significant variation in infectivity of the phage prepared using isoelectric precipitation, and the dynamic light scattering data indirectly prove that the phage structure is not damaged by pH adjustment. To maximize phage production, a dry-weight yield curve of M13 phage for various culture times was produced. The yield curve is proportional to the growth curve of E. coli. On a 200-mL culture scale, 0.2 g L^?1 M13 phage (dry-weight) was produced by the isoelectric precipitation method.     

Construction of a large phage display antibody library by in vitro package and in vivo recombination

Capacity and diversity are extremely important to the quality of various phage display libraries. In this work, λ phage-based in vitro package was applied to construct a filamentous phage display antibody library so as to enlarge its capacity and introduce more sequence diversity in the final library. In vivo recombination via Cre recombinase/lox sites was also exploited to create V_H/V_L combination diversity based on multivalent package of λ phage packaging extracts on phagemid DNA concatemers. The library constructed with 10 μg concatenated phagemid DNA and ten vials of λ phage packaging extracts was calculated to contain 1.40×10¹⁰ independent clones. Higher capacity can be easily achieved when more materials are consumed. This strategy is somewhat more efficient than prior methods.     

Long-chain adducts of trans-4-hydroxy-2-nonenal to DNA bases cause recombination, base substitutions and frameshift mutations in M13 phage

Oxidative stress enhances lipid peroxidation (LPO) implicated in the promotion and progression of carcinogenesis. One of the major LPO products is trans-4-hydroxy-2-nonenal (HNE), which was shown to react with guanosine and under peroxidizing conditions also with adenosine. We show here that all four DNA bases are targets for HNE, although displaying different reactivity: dG > dC > dA approximately equal to dT. HPLC and mass spectrometry analyses of HNE reactions with deoxynucleosides showed in each case the formation of several products, with mass peaks corresponding to HNE-dN adducts at a 1:1 and also 2:1 and 3:1 ratios. In the dA, dC and dG reactions, mass peaks corresponding to heptyl-substituted etheno-adducts were also detected, indicating HNE oxidation to its epoxide by air oxygen. In DNA pretreated with HNE, DNA synthesis by T7 DNA polymerase was stopped in a sequence-dependent manner at G > or = C > A and T sites. HNE increased the mutation rates in the lac Z gene of M13 phage transfected into wild type Escherichia coli. The most frequent event was the recombination between lacZ gene sequences in M13 and the E. coli F' factor DNA. Base substitutions and frameshifts were also observed in approximately similar numbers. Over 50% of base substitutions were the C-->T transitions, followed by the G-->C and A-->C transversions. In the E. coli recA strain recombination was not observed, although one mutational G-->T hot-spot appeared within the DNA fragment undergoing recombination in the wild type E. coli. We conclude that long chain HNE adducts to DNA bases arrest DNA synthesis and cause recombination, base substitutions and frameshift mutations in ssDNA.     

In vivo recombination as a tool to generate molecular diversity in phage antibody libraries

The creation of diversity in populations of polypeptides has become an important tool in the derivation of polypeptides with useful characteristics. This requires efficient methods to create diversity coupled with methods to select polypeptides with desired properties. In this review we describe the use of in vivo recombination as a powerful way to generate diversity. The novel principles for the recombination process and several applications of this process for the creation of phage antibody libraries are described. The advantage and disadvantages are discussed and possible future exploitation presented.     

In vivo recombination as a tool to generate molecular diversity in phage antibody libraries

The creation of diversity in populations of polypeptides has become an important tool in the derivation of polypeptides with useful characteristics. This requires efficient methods to create diversity coupled with methods to select polypeptides with desired properties. In this review we describe the use of in vivo recombination as a powerful way to generate diversity. The novel principles for the recombination process and several applications of this process for the creation of phage antibody libraries are described. The advantage and disadvantages are discussed and possible future exploitation presented.     

The complete nucleotide sequence of an infectious clone of cauliflower mosaic virus by M13mp7 shotgun sequencing.

We have determined the complete primary structure (8031 base pairs) of an infectious clone of cauliflower mosaic virus strain CM1841. The sequence was obtained using the strategy of cloning shotgun restriction fragments in the sequencing vector M13mp7. Comparison of the CM1841 sequence with that published for another caMV strain (Strasbourg) reveals 4.4% changes, mostly nucleotide substitutions with a few small insertions and deletions. The six open reading frames in the sequence of the Strasbourg isolate are also present in CM1841.     

Genomic fingerprinting of microorganisms: its use as a hybridization probe of phage M13 DNA

Hypervariable nucleotide sequences detected by hybridization with the phage M13 DNA probe were found in the chromosomal DNAs of certain pathogenic microbial species. DNA fingerprinting, based on hybridization of M13-probe with hypervariable chromosomal DNA sequences, opens new approaches to epidemiological analysis, epidemiological prognosis, taxonomy, and other theoretical and applied fields of bacteriology.