M13 Clones Research Articles

Effects of the Magnetic Orientation of M13 Bacteriophage on Phage Display Selection.

Although phage display selection using a library of M13 bacteriophage has become a powerful tool for finding peptides binding to target materials, a remaining concern of this method is the interference by the M13 main body, which is a huge filament >103 times larger than the displayed peptide, and therefore would nonspecifically adhere to the target or sterically inhibit the binding of the displayed peptide. Meanwhile, filamentous phages are known to be orientable by a magnetic field. If M13 filaments are magnetically oriented during the selection, their angular arrangement toward the target surface would be changed, being expected to control the interference by the M13 main body. Here we report that the magnetic orientation of M13 filaments vertical to the target surface significantly affects the selection. When the target surface was affinitive to the M13 main body, this orientation notably suppressed the nonspecific adhesion. Furthermore, when the target surface was less affinitive to the M13 main body and intrinsically free from the nonspecific adhesion, this orientation drastically changed the population of M13 clones obtained through selection. Our method of using no chemicals but only a physical stimulus, is simple, clean, and expected to expand the scope of phage display selection.

Preparation of Double-Stranded (Replicative Form) Bacteriophage M13 DNA.

The double-stranded, closed-circular, replicative form (RF) of M13 DNA is present in high copy numbers in infected cells, and its physical characteristics are essentially identical to those of closed-circular plasmid DNAs. Any of the methods commonly used to purify plasmid DNA can therefore be used to isolate M13 RF DNA. This protocol describes the isolation of M13 RF DNA by alkaline lysis from small volumes (1-2 mL) of infected bacterial cultures. The yield of DNA (1-4 mg, depending on the size of the M13 clone) is more than enough for most purposes in molecular cloning. However, should more DNA be needed, the procedure can easily be scaled up.

Volume 1, Number 1

Volume 1, Number 1

Protective immunity induced by phage displayed mitochondrial related peptides of Schistosoma japonicum

New antigens and strategies are necessary for vaccine development against schistosomiasis japonica. Using a pool of 43 high titred anti-SWA sera from individuals residing in an Schistosoma japonicum endemic area of China, we have cloned a S. japonicum gene by cDNA library screening. The recombinant Sj338 protein has 44–46% identity to a mitochondrial precursor receptor protein of humans and rats. Immunization of mice with the recombinant Sj338 conferred 27–32% ( p < 0.01) reduction in worm burdens following cercarial challenge. In an effort to identify protective epitopes in Sj338 and increase the level of protection, we screened a random 12-mer peptide library constructed in M13 using a polyspecific anti-Sj338 rabbit serum. After five rounds of biopanning, we identified 30 reactive clones consisting of 11 distinct peptide sequences. These clones shared limited primary sequence homology with the recombinant Sj338 protein. Anti-sera raised against these phage clones recognized recombinant Sj338 and SWAP by Western blot. In murine vaccination experiments using whole recombinant phage without adjuvant, four of these clones demonstrated worm reductions of 11.6–25.1% ( p = ns − 0.05) compared to M13 vaccinated animals. Animals vaccinated with all four of these phage demonstrated 34.2% ( p < 0.01) worm reduction compared to controls vaccinated with M13 clone. These data suggest that mimotope peptides are potential vaccine candidates for S. japonicum.

Preparation of Double-stranded (Replicative Form) Bacteriophage M13 DNA

The double-stranded, closed-circular, replicative form (RF) of M13 DNA is present in high copy numbers in infected cells, and its physical characteristics are essentially identical to those of closed-circular plasmid DNAs. Any of the methods commonly used to purify plasmid DNA can therefore be used to isolate M13 RF DNA. This protocol describes the isolation of M13 RF DNA by alkaline lysis from small volumes (1-2 mL) of infected bacterial cultures. The yield of DNA (1-4 mg, depending on the size of the M13 clone) is more than enough for most purposes in molecular cloning. However, should more DNA be needed, the procedure can easily be scaled up.

Identification of a genomic island present in the majority of pathogenic isolates of Pseudomonas aeruginosa.

Pseudomonas aeruginosa, a ubiquitous gram-negative bacterium, is capable of colonizing a wide range of environmental niches and can also cause serious infections in humans. In order to understand the genetic makeup of pathogenic P. aeruginosa strains, a method of differential hybridization of arrayed libraries of cloned DNA fragments was developed. An M13 library of DNA from strain X24509, isolated from a patient with a urinary tract infection, was screened using a DNA probe from P. aeruginosa strain PAO1. The genome of PAO1 has been recently sequenced and can be used as a reference for comparisons of genetic organization in different strains. M13 clones that did not react with a DNA probe from PAO1 carried X24509-specific inserts. When a similar array hybridization analysis with DNA probes from different strains was used, a set of M13 clones which carried sequences present in the majority of human P. aeruginosa isolates from a wide range of clinical sources was identified. The inserts of these clones were used to identify cosmids encompassing a contiguous 48.9-kb region of the X24509 chromosome called PAGI-1 (for "P. aeruginosa genomic island 1"). PAGI-1 is incorporated in the X24509 chromosome at a locus that shows a deletion of a 6,729-bp region present in strain PAO1. Survey of the incidence of PAGI-1 revealed that this island is present in 85% of the strains from clinical sources. Approximately half of the PAGI-1-carrying strains show the same deletion as X24509, while the remaining strains contain both the PAGI-1 sequences and the 6,729-bp PAO1 segment. Sequence analysis of PAGI-1 revealed that it contains 51 predicted open reading frames. Several of these genes encoded products with predictable function based on their sequence similarities to known genes, including insertion sequences, determinants of regulatory proteins, a number of dehydrogenase gene homologs, and two for proteins of implicated in detoxification of reactive oxygen species. It is very likely that PAGI-1 was acquired by a large number of P. aeruginosa isolates through horizontal gene transfer. The selection for its maintenance may be the consequence of expression of any one of the genes of unknown function or the genes which allow P. aeruginosa to survive under the conditions that generate reactive oxygen species. Alternatively, one or both of the transcriptional regulators encoded in PAGI-1 may control the expression of genes in the P. aeruginosa chromosome, which provides a selective advantage for strains that have acquired this genomic island.

M13 sequencing.

The sequencing of DNA has undergone rapid improvement since the introduction of the chain-termination DNA sequencing method (1) and the construction of convenient single-stranded DNA cloning vectors, such as the bacteriophage M13 cloning vectors and their derivatives (2,3). The chain-termination method involves the synthesis of a DNA strand by a DNA polymerase in vitro using a single-stranded DNA template. Synthesis is initiated at only one site where an oligonucleotide primer anneals to the template. The synthesis reaction is terminated by the incorporation of a nucleotide analog that will not support continued DNA elongation. The chain-terminating nucleotide analogs are the 2′, 3′-dideoxynucleotide 5′-triphosphates (ddNTPs), which lack the 3′-OH group necessary for DNA chain elongation. When proper mixtures of deoxynucleotide triphosphates (dNTPs) and one of the four ddNTPs are used, enzymecatalyzed polymerization will be terminated in a fraction of the population of chains at each site where the ddNTP is incorporated. Four separate reactions, each with a different ddNTP, give complete sequence information.

M13 cloning of mung bean nuclease digested PCR fragments as a means of gap closure within A/T-rich, genome sequencing projects.

Obtaining the complete DNA sequence of a genome is often not straightforward. After standard shotgun sequencing strategies have been employed there are often gaps remaining and these can be the most intractable regions, frequently containing repeat sequences, "uncloneable" sequences and/or regions of potential secondary structure or differential base composition. In genomes with a high A/T content, such as Plasmodium falciparum and Dictyostelium discoideum, solving these gaps is a particularly difficult problem as the sequences concerned are "fragile" and easily denatured, commonly uncloneable and have a paucity of good oligonucleotide priming sites. Reported here is a simple, yet reliable method for determining the sequence of A/T-rich gap-spanning PCR products. This method relies on the slippage of the specificity of mung bean nuclease so that it digests A/T-rich double-stranded DNA into a set of deletion fragments that can then be cloned into M13, sequenced and the original sequence assembled therefrom.

S1 Analysis of Messenger RNA Using Single‐Stranded DNA Probes

This method takes advantage of the ability of oligonucleotides to be efficiently labeled to a high specific activity at the 5' end through the use of kinase. The oligonucleotide is hybridized to a specific single-stranded template containing the complementary sequence to the oligonucleotide, and this hybrid is extended through the use of the Klenow fragment of E. coli DNA polymerase I. The mixture is cut with a restriction enzyme to give the probe a defined 3' end, and the probe is isolated on an alkaline agarose gel. Before using this protocol it is first helpful to have an M13 clone. If this is unavailable, a double-stranded plasmid clone of the region to be studied may be used, as described in an alternate protocol. Another alternate protocol describes the use of long oligonucleotides as probes for S1 analysis (useful for rapid and easy quantitation of the level of mRNA produced from a characterized promoter). For the mapping of the 5' end of an RNA species, hybridization of the probe to RNA is then carried out. S1 nuclease is added to digest all of the unhybridized portion of the probe. Electrophoresis of the hybrid on a denaturing polyacrylamide gel allows a determination of the length of the remaining DNA fragment. This length equals the distance between the 5' end of the probe to the 5' end of the RNA, defining the transcriptional start site to the nucleotide. By performing the hybridization reaction in vast probe excess, quantitation of the relative amounts of RNA can be estimated between samples.

The Tum Protein of Coliphage 186 Is an Antirepressor

The tum gene of coliphage 186, encoded on a LexA controlled operon, is essential for UV induction of a 186 prophage. Primer extension analysis is used to confirm that Tum is the sole phage function required for prophage induction and that it acts against the maintenance repressor, CI, to relieve repression of the lytic promoters, pR and pB, and thereby bring about lytic development. In vitro experiments with purified proteins demonstrate that Tum prevents CI binding to its operator sites. Tum does not compete with CI for binding sites on DNA, and unlike RecA mediated induction of lambda prophage, the action of Tum on CI is reversible. Mechanisms by which Tum may act against CI are discussed.

Genome organization of Xestia c-nigrum granulovirus.

In order to characterize the genome organization of Xestia c-nigrum granulovirus (XcGV), mapping of putative XcGV genes was performed by construction of lambda and M13 phage libraries followed by Southern blot and nucleotide sequencing analyses. Mapping of the lambda (32 clones covering the entire XcGV genome) and M13 (133 clones made by random cloning) phage library clones was carried out by hybridization of the labeled lambda phage clone DNAs to 1) Southern blotted XcGV genomic DNA fragments cleaved with EcoRI, BamHI, or HindIII, and 2) dot blotted M13 clone DNAs. All 133 M13 clone DNAs were sequenced, and coding possibilities were investigated by computer-assisted homology search; in total, about 43 kb of the genome was sequenced. Amino acid sequence homology searches of 67 M13 clones suggested that these GV DNAs coded for previously characterized genes identified in nucleopolyhedroviruses (NPVs) and GVs. These 67 M13 clones were classified into 25 gene homolog groups (including 29 putative genes) based on their homologies to NPV and GV genes. The remaining M13 clones, except one that encoded a putative metalloproteinase, did not possess deduced amino acid sequences with significant homology to proteins in gene databases. Complete nucleotide sequences of the putative XcGV DNA polymerase and Ac144 homolog genes confirmed the reliability of our speculation of putative genes based on the M13 clones sequencing analysis. In a comparison of relative locations of putative XcGV genes with locations of their homologs in NPVs, most XcGV genes were mapped close to the corresponding locations in NPV genomes. These results suggested that XcGV, compared to NPVs, had relatively conserved gene arrangements, although about 22 kb of 43 kb of DNA sequenced randomly in the XcGV genome consisted of sequences/genes non-homologous to those of previously characterized NPVs.

Comparison of Sample Sequences of the Salmonella typhiGenome to the Sequence of the Complete Escherichia coliK-12 Genome

Raw sequence data representing the majority of a bacterial genome can be obtained at a tiny fraction of the cost of a completed sequence. To demonstrate the utility of such a resource, 870 single-stranded M13 clones were sequenced from a shotgun library of the Salmonella typhi Ty2 genome. The sequence reads averaged over 400 bases and sampled the genome with an average spacing of once every 5,000 bases. A total of 339,243 bases of unique sequence was generated (approximately 7% representation). The sample of 870 sequences was compared to the complete Escherichia coli K-12 genome and to the rest of the GenBank database, which can also be considered a collection of sampled sequences. Despite the incomplete S. typhidata set, interesting categories could easily be discerned. Sixteen percent of the sequences determined from S. typhi had close homologs among known Salmonella sequences (P < 1e−40 in BlastX or BlastN), reflecting the proportion of these genomes that have been sequenced previously; 277 sequences (32%) had no apparent orthologs in the complete E. coli K-12 genome (P > 1e−20), of which 155 sequences (18%) had no close similarities to any sequence in the database (P> 1e−5). Eight of the 277 sequences had similarities to genes in other strains of E. coli or plasmids, and six sequences showed evidence of novel phage lysogens or sequence remnants of phage integrations, including a member of the lambda family (P < 1e−15). Twenty-three sample sequences had a significantly closer similarity a sequence in the database from organisms other than the E. coli/Salmonella clade (which includes Shigella andCitrobacter). These sequences are new candidate lateral transfer events to the S. typhi lineage or deletions on the E. coli K-12 lineage. Eleven putative junctions of insertion/deletion events greater than 100 bp were observed in the sample, indicating that well over 150 such events may distinguishS. typhi from E. coli K-12. The need for automatic methods to more effectively exploit sample sequences is discussed.

Specificity of mutagenesis by 4-aminobiphenyl: mutations at G residues in bacteriophage M13 DNA and G--&gt;C transversions at a unique dG(8-ABP) lesion in single-stranded DNA

Mutagenesis by the human bladder carcinogen 4-aminobiphenyl (ABP) was studied in single-stranded DNA from a bacteriophage M13 cloning vector. In comparison to ABP lesions in double-stranded DNA, lesions in single-stranded DNA were approximately 70-fold more mutagenic and 50-fold more genotoxic. Sequencing analysis of ABP-induced mutations in the lacZ gene revealed exclusively base-pair substitutions, with over 80% of the mutations occurring at G sites; the G at position 6310 accounted for 25% of the observed mutations. Among the sequence changes at G sites, G-->T transversions predominated, followed by G-->C transversions and G-->A transitions. In order to further elucidate the mutagenic mechanism of ABP, an oligonucleotide containing the major DNA adduct, N-(deoxyguanosin-8-yl)-4-aminobiphenyl (dG(8-ABP)), was situated within the PstI site of a single-stranded M13 genome. After in vivo replication of the adduct containing ABP-modified and control (unadducted) genomes, the mutational frequency and mutational specificity of the dG(8-ABP) lesion were determined. The targeted mutational efficiency was approximately 0.01%, and the primary mutation observed was the G-->C transversion. Thus dG(8-ABP), albeit weakly mutagenic at the PstI site, can contribute to the mutational spectrum of ABP lesions.

Sequence analysis of the Bacillus subtilis chromosome region between the serA and kdg loci cloned in a yeast artificial chromosome.

The standard strategies of genome sequencing based on lambda-vector or cosmid libraries are only partially applicable to AT-rich Gram-positive bacteria because of the problem of instability of their chromosomal DNA in heterologous hosts like Escherichia coli. One complete collection of ordered clones known for such bacteria is that of Bacillus subtilis, established by using yeast artificial chromosomes (YACs). This paper reports the results of the direct use of one of the YAC clones from the above collection for the sequencing of the region cloned in it. The strategy applied consisted of the following: (i) construction of M13 banks of the partially purified YAC DNA and sequencing of 800 M13 clones chosen at random; (ii) directed selection of M13 clones to sequence by using marginal contig fragments as hybridization probes; (iii) direct sequencing of joining PCR fragments obtained by combinations of primers corresponding to the ends of representative contigs. The complete 104,109 bp insert sequence of this YAC clone was thus established. The strategy used allowed us to avoid resequencing the two largest, previously sequenced, contigs (13,695 and 20,303 bp) of the YAC insert. We propose that the strategy used can be applied to the sequencing of the whole bacterial genome without intermediate cloning, as well as for larger inserts of eukaryotic origin cloned in YACs. Sequencing of the insert of the YAC clone 15-6B allowed us to establish the contiguous sequence of 127 kb from spollA to kdg. The organization of the newly determined region is presented. Of the 138 ORFs identified in the spollA-kdg region, 57 have no clear putative function from their homology to proteins in the databases.

Cloning, restriction endonuclease mapping and partial sequence analysis of the genome of human herpesvirus 7 strain JI.

Human herpesvirus 7 (HHV-7) is a recently isolated herpesvirus that has been shown to be related to human cytomegalovirus and human herpesvirus 6 and to be a member of the betaherpesvirus subgroup. Here we report the cloning, restriction endonuclease mapping and partial sequence analysis of HHV-7 strain JI DNA. Virus particles were obtained from the supernatant of infected SupT1 cells, the DNA isolated by proteinase K treatment-phenol extraction, and full-length viral DNA was purified and isolated on a pulsed-field gel. Aliquots of this highly purified material were treated in the following ways: (i) sonicated and end-repaired to create short randomly sheared fragments for cloning into M13mp 18-Smal vector DNA; (ii) cut with EcoRI for cloning into EcoRI-cut lambda ZAPII or lambda DASHII vectors; (iii) cut with BamHI for cloning into BamHI-cut lambda ZAP-Express or lambda DASHII vectors. Partial nucleotide sequencing of the M13 clones followed by detection of open reading frames and their translation allowed the identification of homologues through FASTA searches of the database. Relevant M13 clones were used as probes to isolate corresponding lambda phage clones, which could tentatively be mapped to the genome on the basis of presumed genetic collinearity between HHV-7 and HHV-6. Genomic "walking' between EcoRI and BamHI lambda genomic libraries enabled overlapping neighbouring clones to be identified and mapped. Each of these clones was analysed to map BamHI, EcoRI, Sa/l, Smal and Xhol restriction endonuclease sites to provide complete endonuclease maps for the entire genome.

The identification of polymorphicmicrosatellite loci in the horse and their use in thoroughbred parentage testing

Six new horse microsatellite loci were identified by sequencing M13 clones containing horse genomic inserts which gave positive signals when probed with a CA/GT repeat probe. Oligonucleotide primer pairs were synthesized for these loci and for two previously described horse microsatellites, HTG4 and HTG6. Polymerase chain reaction assays were then carried out on a panel of 20 different unrelated Thoroughbred horse DNAs. DNAs from eight cases of double covering which could not be solved by conventional blood typing were also examined. Several of the loci amplified were found to be polymorphic and, using a limited subset of primers, a clear exclusion could be established for one of the stallions in five of the cases. DNA typing is therefore a useful adjunct to blood typing in the horse and indeed, in the future will probably replace it.

The ADP-Ribosyltransferases (gpAlt) of Bacteriophages T2, T4, and T6: Sequencing of the Genes and Comparison of Their Products

The Alt gene product is a component of the T4 phage head. Upon infection of the host cell, approximately 40 copies of the Alt protein enter the cell together with the viral DNA molecule. The Alt protein then ADP-ribosylates one of the two α-subunits of host RNA polymerase. A restriction fragment harboring the ADP-ribosyltransferase gene of bacteriophage T4 was cloned into the plasmid vector pBluescript, the nucleotide sequence was determined, and the reading frame was identified. Two M13 clone libraries, established with DNA isolated from bacteriophages T2 and T6, then were screened for the corresponding genes The nucleotide sequences of the three alt genes and the deduced amino acid sequences were compared. Secondary structure predictions and NAD-binding studies resulted in the location of the substrate-binding site in the NH2-terminal regions of the enzymes.

Stem-loop IV of 5S rRNA lies close to the peptidyltransferase center.

A DNA fragment containing the Escherichia coli 5S rDNA sequence linked to a T7 promoter was prepared by PCR from an M13 clone carrying the 5S-complementary sequence. The DNA was transcribed with T7 polymerase using a mixture of [alpha-32P]UTP and 4-thio-UTP, yielding a transcript in which approximately 18% of the uridine residues were randomly replaced by thiouridine. This modified 5S RNA could be reconstituted efficiently into 50S ribosomal subunits or 70S functional complexes. The reconstituted particles were irradiated at wavelengths above 300 nm, and the crosslinked ribosomal components were identified. A crosslink in high yield was reproducibly observed between the modified 5S RNA and 23S RNA, involving residue U-89 of the 5S RNA (at the loop end of helix IV) linked to nucleotide 2477 of the 23S RNA in the loop end of helix 89, immediately adjacent to the peptidyltransferase "ring." On the basis of this result, and in combination with earlier immunoelectron microscopic data, we propose a model for the orientation of the 5S RNA in the 50S subunit.

Polycos vectors: a system for packaging filamentous phage and phagemid vectors using lambda phage packaging extracts

A new class of hybrid vectors, ‘polycos’ vectors, incorporate a phage λ cos site and filamentous phage origin to allow high-efficiency cloning via in vitro λ packaging extracts. The head-filling mechanism of cos site recognition by λ packaging proteins permits concatemers of several of these small cos-containing vectors to be packaged per phage particle. Excision of vector monomers after infection is accomplished via a λZAP-like M13 excision process. This system has the advantage of adapting high-efficiency λ packaging extracts to M13 and phagemid cloning vectors.

The DNA Sequence of Adenovirus Type 40

The 34,214 bp DNA sequence of adenovirus type 40 strain Dugan was determined directly from random fragments of virion DNA cloned into a bacteriophage M13 cloning vector. The gene layout is similar to that of other human adenoviruses, and in addition contains two potential protein-coding regions that are conserved, but have not been recognized previously, in other adenovirus genomes. One is oriented rightward, contained within the intron in the protein-coding region for the L4 33K gene, and would encode a protein sharing N-terminal sequence with 33K. The other is a leftward oriented exon located between the E3 and L5 IV (fibre) regions which would specify the N terminus of a novel protein. The region encoding the C terminus of this protein is not apparent from sequence data.