A selective λ phage cloning vector with automatic excision of the insert in a plasmid

A bacteriophage λ cloning vehicle has been constructed for the generation of cDNA libraries. The vector has the following properties. (1) It has a unique BamHI site engineered into the λ gam gene. Segments of DNA can be cloned into this site and clones with an insert can be selected by their ability to grow on an Escherichia coli host lysogenic for phage P2 (Spi⁻ phenotype). (2) When the recombinant phage infects a Cre-producing E. coli strain, a site-specific recombination event results in the excision of a plasmid replicon with the cloned insert. (3) Single-stranded DNAs can be recovered by growing helper M13 phages on bacteria harboring such plasmids. The vector, λMGU2, has been used to construct a nematode (Caenorhabditis elegans) cDNA library.     

Molecular Analysis of λbio Transducing Phage Produced by Oxolinic Acid-Induced Illegitimate Recombination in Vivo

To study the mechanism of DNA gyrase-mediated illegitimate recombination in Escherichia coli, we examined the formation of λ Spi(-) phage during prophage induction. The frequency of Spi(-) phage was two to three orders of magnitude higher in the presence of oxolinic acid, an inhibitor of DNA gyrase A subunit, than in the absence of the drug, while it was very low in nalA(r) bacteria with the drug. RecA function is not required for the formation of these phages, indicating that this enhancement is not caused by the expression of SOS-controlled genes. Analyses of att region and recombination junctions of Spi(-) phages revealed that they have essentially the same structures as λbio transducing phages but are classified into two groups with respect to recombination sites. In the majority class of the transducing phages, there were not more than 3-bp homologies bewteen the parental E. coli bio and λ recombination sites. In the minority class of the transducing phages, on the other hand, 9-10-bp homologies were found between the parental recombination sites. These results suggested that oxolinic acid-induced illegitimate recombination takes place by two variants of a DNA gyrase-dependent mechanism.     

Campylobacter group II phage CP21 is the prototype of a new subgroup revealing a distinct modular genome organization and host specificity

Background

The application of phages is a promising tool to reduce the number of Campylobacter along the food chain. Besides the efficacy against a broad range of strains, phages have to be safe in terms of their genomes. Thus far, no genes with pathogenic potential (e.g., genes encoding virulence factors) have been detected in Campylobacter phages. However, preliminary studies suggested that the genomes of group II phages may be diverse and prone to genomic rearrangements.

Results

We determined and analysed the genomic sequence (182,761 bp) of group II phage CP21 that is closely related to the already characterized group II phages CP220 and CPt10. The genomes of these phages are comprised of four modules separated by very similar repeat regions, some of which harbouring open reading frames (ORFs). Though, the arrangement of the modules and the location of some ORFs on the genomes are different in CP21 and in CP220/CPt10. In this work, a PCR system was established to study the modular genome organization of other group II phages demonstrating that they belong to different subgroups of the CP220-like virus genus, the prototypes of which are CP21 and CP220. The subgroups revealed different restriction patterns and, interestingly enough, also distinct host specificities, tail fiber proteins and tRNA genes. We additionally analysed the genome of group II phage vB_CcoM-IBB_35 (IBB_35) for which to date only five individual contigs could be determined. We show that the contigs represent modules linked by long repeat regions enclosing some yet not identified ORFs (e.g., for a head completion protein). The data suggest that IBB_35 is a member of the CP220 subgroup.

Conclusion

Campylobacter group II phages are diverse regarding their genome organization. Since all hitherto characterized group II phages contain numerous genes for transposases and homing endonucleases as well as similar repeat regions, it cannot be excluded that these phages are genetically unstable. To answer this question, further experiments and sequencing of more group II phages should be performed.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1837-1) contains supplementary material, which is available to authorized users.     

The maturation of coliphage lambda DNA in the absence of its packaging

In vivo, λ DNA cannot be cleaved at cos (matured) if proheads are not present; in vitro, however, cos cleavage readily takes place in the absence of proheads. In order to investigate this paradox, we have constructed plasmids that synthesize λ terminase in vivo upon induction. The plasmids also contain cos at the normal position, about 190 bp upstream of λ gene Nul. One of the plasmids, pFM3, produces levels of terminase comparable to those found after phage induction. If cells carrying pFM3 are thermoinduced, almost 100% of the intracellular plasmid DNA has a double-strand interruption at or near cos.

Since the only λ genes that pFM3 carries are Nul, A, W and B, this in vivo cleavage is occurring in the absence of proheads. Previous failure to observe 2 maturation with phages carrying prohead mutations may be due to exonucleolytic degradation of the unprotected DNA ends, a different DNA topology or compartmentalization, or terminase inhibition in the absence of prohead by the product of another λ gene that maps to the right of gene B.     

Molecular cloning of cDNA for human prostatic acid phosphatase

A human liver cDNA library in λgt11 was screened with polyclonal antiserum to human acid phosphatase isoenzyme 2a/4. About eleven positive clones have been obtained. Two clones, λ Hap21 and λ Hap22 were further characterized: clone λHap21 contained a 0.8-kb cDNA insert and clone λHap22 a 1.8–2.0-kb insert. XbaI digestion of λHap22 generated two fragments of 1.0 and 0.9 kb. BglII digestion resulted in a 1.2-kb fragment and several smaller fragments of undetermined size. Clone 1 Hap22 contained all the genes carried by λ gt11(lac 5cI857nin 5Sam 100) and the 2-kb insert. An Escherichia coli(λHap22) lysogen was generated, and its acid phosphatase activity was approximately ten-fold higher than that in the control nonlysogenic lysate. Western-blot analysis of total proteins present in this E. coli(λHap22) lysate revealed that the non-induced λHap22 prophage directed the synthesis of an approx. 175-kDa protein. This protein was recognized by antibody to the human acid phosphatase isoenzyme 2a/4 and anti-β-galactosidase and was produced only upon induction with IPTG. These results indicated that AHap22 carried a major portion of the gene coding for the human acid phosphatase isoenzyme 2a and/or 4 and this protein fragment of acid phosphatase was sufficient to manifest enzymatic activity.     

The production of generalized transducing phage by bacteriophage lambda

Generalized tranduction has for about 30 years been a major tool in the genetic manipulation of bacterial chromosomes. However, throughout that time little progress has been made in understanding how generalized transducing particles are produced. The experiments presented in this paper use phage λ to assess some of the factors that affect that process. The results of those experiments indicate: (1) the production of generalized transducing particles by bacteriophage λ is inhibited by the phage λ exonuclease (Exo). Also inhibited by λ Exo is the production of λdocR particles, a class of particles whose packaging is initiated in bacterial DNA and terminated at the normal phage packaging site, cos. In contrast, the production of λdocL particles, a class of particles whose packaging is initiated at cos and terminated in bacterial DNA, is unaffected by λ Exo; (2) λ-generalized transducing particles are not detected in induced lysis-defective (S⁻) λ lysogens until about 60–90 min after prophage induction. Since wild-type λ would normally lyse cells by 60 min, the production of λ-generalized transducing particles depends on the phage being lysis-defective; (3) if transducing lysates are prepared by phage infection then the frequency of generalized transduction for different bacterial markers varies over a 10–20-fold range. In contrast, if transducing lysates are prepared by the induction of a λ lysogen containing an excision-defective prophage, then the variation in transduction frequency is much greater, and markers adjacent to, and on both sides of, the prophage are transduced with much higher frequencies than are other markers ; (4) if the prophage is replication-defective then the increased transduction of prophage-proximal markers is eliminated; (5) measurements of total DNA in induced lysogens indicate that part of the increase in transduction frequency following prophage induction can be accounted for by an increase in the amount of prophage-proximal bacterial DNA in the cell. Measurements of DNA in transducing particles indicate that the rest of the increase is probably due to the preferential packaging of the prophage-proximal bacterial DNA.

These results are most easily interpreted in terms of a model for the initiation of bacterial DNA packaging by λ, in which the proteins involved (Ter) do not recognize any particular sequence in bacterial DNA but rather     

DNA Packaging Specificity of Bacteriophage N15 with an Excursion into the Genetics of a Cohesive End Mismatch

During DNA replication by the λ-like bacteriophages, immature concatemeric DNA is produced by rolling circle replication. The concatemers are processed into mature chromosomes with cohesive ends, and packaged into prohead shells, during virion assembly. Cohesive ends are generated by the viral enzyme terminase, which introduces staggered nicks at cos, an approx. 200 bp-long sequence containing subsites cosQ, cosN and cosB. Interactions of cos subsites of immature concatemeric DNA with terminase orchestrate DNA processing and packaging. To initiate DNA packaging, terminase interacts with cosB and nicks cosN. The cohesive ends of N15 DNA differ from those of λ at 2/12 positions. Genetic experiments show that phages with chromosomes containing mismatched cohesive ends are functional. In at least some infections, the cohesive end mismatch persists through cyclization and replication, so that progeny phages of both allelic types are produced in the infected cell. N15 possesses an asymmetric packaging specificity: N15 DNA is not packaged by phages λ or 21, but surprisingly, N15-specific terminase packages λ DNA. Implications for genetic interactions among λ-like bacteriophages are discussed.     

A new macrocyclic tetraamine, 2,4-dinitrophenylcyclen (= 1-(2,4-dinitrophenyl)-1,4,7,10-tetraazacyclododecane):synthesis, cation reporter properties, and recognition of 1-methylthymine by its zinc(II) complex

A new functional macrocyclic ligand, 2,4-dinitrophenylcyclen (= 1-(2,4-dinitrophenyl)-1,4,7,10-tetraazacyclododecane), has been synthesized and isolated as its trihydrochloric acid salt (L·3HCl). The protonation constants (log K_n) for three secondary nitrogens of L were determined by potentiometric pH titration to be 10.10, 7.33 and <2 with I = 0.10 (NaNO₃) at 25°C. The 2,4-dinitrophenylaniline chromophore was proven to be a good reporter signaling proton- and metal-binding events in the macrocyclic cavity. The UV absorption band (λ_max 370 nm, 8200) of the 2,4-dinitrophenylaniline moiety at pH ≥ 9 becomes quenched as pH is lowered (to pH 3.1, where the major species is L·2H⁺), due to the strong protonation effect extended to the aniline moiety within the macrocyclic cavity. This is in sharp contrast to the pH-independent UV absorption (λ_max 390 nm, 14 000) of a reference compound, N,N-diethyl-2,4-dinitroaniline. The UV absorption band of L is shifted to lower wavelengths with Zn²⁺ (λ_max 320 nm), Cd²⁺ (λ_max 316 nm) and Pb²⁺ (λ_max 317 nm), while it almost disappears with Cu²⁺ and Ni²⁺. The 1:1 Zn²⁺ and Cu²⁺ complexes with L were isolated and characterized. The Zn²⁺ complex recognizes 1-methylthymine anion (MT⁻) in aqueous solution at physiological pH to yield a stable ternary complex ZnL-MT⁻. The X-ray crystal structure of ZnL-MT⁻ showed that Zn²⁺ is four-coordinate with three secondary nitrogens of L and the deprotonated imide anion that is cofacial to the 2,4-dinitrophenyl ring.     

Susceptibility of Different Coliphage Genomes to Host-controlled Variation

Twenty-eight coliphages were studied for their susceptibility to four systems of host control variation in Escherichia coli. Both temperate and virulent phages were studied, including phages with ribonucleic acid, double- and single-stranded deoxyribonucleic acid (DNA) and glucosylated DNA. The systems examined were E. coli C-K, K-B, B-K, and K-K(P1). The C-K, K-B, and B-K systems affected temperate phages and nonlysogenizing mutants derived from temperate phages. In general, these systems did not restrict virulent phages. Phage 21e, a variant of phage 21, lost the ability to undergo restriction in the C-K and B-K systems, but retained susceptibility to the K-B and K-K(P1) systems. This suggests that the genetic site(s) on the phage, as well as in the host, determines susceptibility to host-controlled variation. Both temperate and dependent virulent phages were susceptible to the host control system resulting from the presence of prophage P1. The autonomous and small virulents were not susceptible. In a given system, the various susceptible phages differed widely in their efficiency of plating on the restricting host. If the few infections that occur arise in rare special cells, then different populations of special cells are available to different phage species. For most phage types, when a susceptible phage infected a nonrestricting host, the progeny showed the specificity appropriate to that host. Behavior of T3 was exceptional, however. When T3 obtained from E. coli K infected E. coli C or B, some of the progeny phages retained K host specificity, whereas others acquired the specificity of the new host.     

Recognition of Adenosine Residues by the Active Site of Poly(A)-specific Ribonuclease

Poly(A)-specific ribonuclease (PARN) is a mammalian 3′-exoribonuclease that degrades poly(A) with high specificity. To reveal mechanisms by which poly(A) is recognized by the active site of PARN, we have performed a kinetic analysis using a large repertoire of trinucleotide substrates. Our analysis demonstrated that PARN harbors specificity for adenosine recognition in its active site and that the nucleotides surrounding the scissile bond are critical for adenosine recognition. We propose that two binding pockets, which interact with the nucleotides surrounding the scissile bond, play a pivotal role in providing specificity for the recognition of adenosine residues by the active site of PARN. In addition, we show that PARN, besides poly(A), also quite efficiently degrades poly(U), ∼10-fold less efficiently than poly(A). The poly(U)-degrading property of PARN could be of biological significance as oligo(U) tails recently have been proposed to play a role in RNA stabilization and destabilization.     

Genetic control of the UV-induced SOS mutator effect in single- and double-stranded DNA phages

The SOS hypothesis postulated that the mutator effect on undameged DNA that generates phage-untargeted mutagenesis (UTM) results directly from the mechanism of targeted mutagenesis. RecA protein, which stimulates the cleavage of both the LexA repressor and UmuD protein, and the UmuDC gene products are required for UV-induced targeted mutagenesis. The use of phage λ for analyzing UV-induced mutagenesis has permitted a distinction to be made between the mechanisms of targeted and untargeted mutagenesis, in that the two processes differ with respect to their genetic requirements for recA⁺ and umuDC⁺ genes. In this paper, we show thet (i) proficiency for excision repair is required for UTM in double-stranded DNA phage but not in single-stranded DNA phage; (ii) the umuC function, which is not required for UTM of the double-stranded DNA phage λ, is necessary for untargeted mutagenesis of the single-stranded DNA phages M13 and φX174; (iii) for both single-stranded and double-stranded DNA phage, UV irradiation of the host increases the level of recA730-induced UTM. Our results are also consistent with the interpretation that the expression of untargeted mutagenesis in phage λ and in M13 depends on the polymerase and to a lesser extent on the exonuclease 5′ → 3′, activities of Po1I. These results suggest that the involvement of the RecA and UmuDC proteins may be related to more than the presence of base damage in the DNA substrate.     

The isolation and characterization of two Stenotrophomonas maltophilia bacteriophages capable of cross-taxonomic order infectivity

Background

A rapid worldwide increase in the number of human infections caused by the extremely antibiotic resistant bacterium Stenotrophomonas maltophilia is prompting alarm. One potential treatment solution to the current antibiotic resistance dilemma is “phage therapy”, the clinical application of bacteriophages to selectively kill bacteria.

Results

Towards that end, phages DLP1 and DLP2 (vB_SmaS-DLP_1 and vB_SmaS-DLP_2, respectively) were isolated against S. maltophilia strain D1585. Host range analysis for each phage was conducted using 27 clinical S. maltophilia isolates and 11 Pseudomonas aeruginosa strains. Both phages exhibit unusually broad host ranges capable of infecting bacteria across taxonomic orders. Transmission electron microscopy of the phage DLP1 and DLP2 morphology reveals that they belong to the Siphoviridae family of bacteriophages. Restriction fragment length polymorphism analysis and complete genome sequencing and analysis indicates that phages DLP1 and DLP2 are closely related but different phages, sharing 96.7 % identity over 97.2 % of their genomes. These two phages are also related to P. aeruginosa phages vB_Pae-Kakheti_25 (PA25), PA73, and vB_PaeS_SCH_Ab26 (Ab26) and more distantly related to Burkholderia cepacia complex phage KL1, which together make up a taxonomic sub-family. Phages DLP1 and DLP2 exhibited significant differences in host ranges and growth kinetics.

Conclusions

The isolation and characterization of phages able to infect two completely different species of bacteria is an exciting discovery, as phages typically can only infect related bacterial species, and rarely infect bacteria across taxonomic families, let alone across taxonomic orders.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1848-y) contains supplementary material, which is available to authorized users.     

Nucleotide sequences at the phi X gene A protein cleavage site in replicative form I DNAs of bacteriophages U3, G14, and alpha 3

Gene A protein, a bacteriophage phi X174-encoded endonuclease involved in phi X replicative form (RF) DNA replication, nicks not only phi X RFI DNA but also RFI DNAs of several other spherical single-stranded DNA bacteriophages. The position of the phi X gene A protein nick and the nucleotide sequence surrounding this site in RF DNAs of the bacteriophages U3, G14, and alpha 3 were determined. Comparison of the nucleotide sequences which surround the nick site of the gene A protein in RF DNAs of phi X174, G4, St-1, U3, G14, and alpha 3 revealed that a strongly conserved 30-nucleotide stretch occurred in RF DNAs of all six phages. However, perfect DNA sequence homology around this site was only 10 nucleotides, the decamer sequence CAACTTGATA. The present results support the hypothesis that, for nicking of double-stranded supercoiled DNA by the phi X gene A protein, the presence of the recognition sequence CAACTTGATA and a specific gene A protein binding sequence upstream from the recognition sequence are required. The sequence data obtained so far from phages U3, G14, St-1, and alpha 3 have been compared with the nucleotide sequences and amino acid sequences of both phi X and G4. According to this comparison, the evolutionary relationship between phages G4, U3, and G14 is very close, which also holds for phages alpha 3 and St-1. However, the two groups are only distantly related, both to each other and to phi X.     

The Cleavage of Nucleic Acids in Reversed Micelles Using Site Specific Endonucleases

Plasmid and λ DNA molecules of between 2.2 and 48.5 kb pairs can be solubilised in n-hexane containing the surfactant sodium dioctyl sulfosuccinate (AOT) and aqueous buffers. Linear λ phage DNA fragments (2.2-23.1 kb pairs) and intact λ bio 1 DNA (48.5 kb pairs) are efficiently cleaved by Bam HI and Em RI in systems containing 100 mM AOT. Under these conditions, λ bio 1 DNA undergoes regioselective restriction by Hind III at only one site but is completely cleaved when the surfactant concentration is lowered to 50 mM. Covalent closed circular plasmid DNA (pUC8, 2.73 kb pairs) is only partially linearised by Eco RI and Bam HI in reversed micelles; Hae II cleavage affords both complete and partial restriction fragments. The results suggest that the tertiary structures adopted by substrate DNA in reversed micelles influence the availability of restriction sites.     

粘质沙雷菌裂解性噬菌体ФSM9-3Y的分离和鉴定

目的从医院污水中分离粘质沙雷菌噬菌体,并分析其生物学特性,为进一步研究针对耐药性粘质沙雷菌的噬菌体制剂提供依据。方法采用双层琼脂平板法分离纯化针对粘质沙雷菌的裂解性噬菌体,观察噬菌体对宿主菌的裂解特异性,通过负染法电镜观察噬菌体的形态结构,提取噬菌体核酸进行酶切电泳,测定噬菌体的最佳感染复数和一步生长曲线,SDS-PAGE电泳初步分析噬菌体的结构蛋白和非结构蛋白。结果从医院污水分离出7株可裂解粘质沙雷菌的噬菌体,对其中一株噬菌体(命名为ФSM9-3Y)的生物学特征进行了初步研究。电镜显示噬菌体呈蝌蚪状,头部为20面体立体对称、直径约70 nm;尾部长约50 nm。ФSM9-3Y的最佳感染复数为1。一步生长曲线表明;ФSM9-3Y的潜伏期约30 min,暴发时间70 min,暴发量为629 PFU/cell。凝胶电泳显示噬菌体基因组为双链DNA、大小约54 kb。SDS-PAGE呈现至少包括13种蛋白,相对分子质量范围在25～130 kD,其中主要蛋白的相对分子质量约为48 kD。结论此次分离的噬菌体ФSM9-3Y为裂解性噬菌体,根据形态和结构特征,粘质沙雷菌噬菌体ФSM9-3Y属于有尾病毒目,肌尾噬菌体科。     

Tumor specific phage particles promote tumor regression in a mouse melanoma model

Within cancer research, phage display libraries have been widely used for the identification of tumor targeting peptides and antibodies. Additionally, phages are known to be highly immunogenic; therefore we evaluated the immunotherapeutic potential of tumor specific phages to treat established solid tumors in a mouse model of melanoma. We developed two tumor specific phages, one derived from a peptide phage display library and one Fab expressing phage with known specificity, for the treatment of mice bearing palpable B16-F10 or B16/A2K^b tumors. Therapy in B16-F10 tumor bearing mice with tumor specific phages was superior to treatment with non-tumor specific phages and lead to delayed tumor growth and increased survival. In B16/A2K^b tumor bearing mice, therapy with tumor specific phages resulted in complete tumor regression and long-term survival in 50% of the mice. Histological analysis of tumors undergoing treatment with tumor specific phages revealed that phage administration induced a massive infiltration of polymorphonuclear neutrophils. Furthermore, phages induced secretion of IL-12 (p70) and IFN-γ as measured in mouse splenocyte culture supernatants. These results demonstrate a novel, immunotherapeutic cancer treatment showing that tumor specific phages can promote regression of established tumors by recruitment of inflammatory cells and induction of Th1 cytokines.     

Transposition and targeting of the prokaryotic mobile element IS30 in zebrafish

We provide evidence that a prokaryotic insertion sequence (IS) element is active in a vertebrate system. The transposase of Escherichia coli element IS30 catalyzes both excision and integration in extrachromosomal DNA in zebrafish embryos. The transposase has a pronounced target preference, which is shown to be modified by fusing the enzyme to unrelated DNA binding proteins. Joining the transposase to the cI repressor of phage λ causes transposition primarily into the vicinity of the λ operator in E. coli, and linking to the DNA binding domain of Gli1 also directs the recombination activity of transposase near to the Gli1 binding site in zebrafish. Our results demonstrate the possibility of fusion transposases to acquire novel target specificity in both prokaryotes and eukaryotes.     

Cytotoxin-converting phages, φCTX and PS21, are R pyocin-related phages

Abstract φCTX is a temperate phage of Pseudomonas aeruginosa harbouring the ctx gene that encodes cytotoxin (CTX). We identified φCTX as an R pyocin-related phage, by serological and molecular analysis, based on the findings that the infectivity of the phage was inhibited with the antisera directed R pyocins and R pyocin-related phages and that the φCTX genome showed DNA homology to the genome of PS17 (a representative of the R pyocin-related phages) as well as to the pyocin R2 genes. Another new CTX-converting, R pyocin-related phage named PS21 was isolated from a CTX-producing strain of P. aeruginosa , suggesting the distribution of the ctx gene by certain members of R pyocin-related phage family.