Isolation and characterization of specialized lambda transducing bacteriophage carrying the metBJF methionine gene cluster.

Secondary attachment site lysogens of Deltaatt(lambda)Deltappc-argECBH strains of Escherichia coli with lambdacI857 integrated into the bfe gene (88 min) were isolated. Of 20 such lysogens examined, 2 produce lysates with transducing phage containing the metBJF gene cluster (87 min). Reintroduction of the ppc-argECBH chromosome segment (which lies between the bfe and met genes) into these strains virtually abolishes the production of met transducing phage. All of the phage examined have lost essential genes from the left arm of the lambda chromosome. Approximately 85% of the phage appear to have the same genetic composition, containing the metBJF gene cluster, but not the closely linked gene cytR, and having lost phage genes G and J. Analytical CsCl density gradient centrifugation of five representatives of this major class of phage shows four of them to have identical densities (lighter than lambda), while the fifth cannot be resolved from lambda. The four apparently identical phage were isolated from three separate lysates, which suggests the existence of preferred sites for illegitimate recombination on the bacterial and phage chromosomes. Three specialized transducing phage that carry cytR in addition to metB, metJ, and metF have also been studied. Each of these viruses has a different amount of phage deoxyribonucleic acid. Two of them have less deoxyribonucleic acid than lambda, whereas the third has about the same amount. The metB, metF, and cytR genes of the transducing phage have been shown to function in vivo. The phage-borne metB and metF genes are subject to metJ-mediated repression.     

Transduction of Lactose Metabolism in Streptococcus lactis C2

Ultraviolet (UV)-induced phage lysates, from lactose-positive (lac(+)) Streptococcus lactis C2, transduced lactose fermenting ability to lac(-) recipient cells of this organism. Although the phage titer could not be determined due to the absence of an appropriate indicator strain, the number of transductants was proportional to the amount of phage lysate added. Treatment of the lysate with deoxyribonuclease had no effect on this conversion, indicating the observed genetic change was not mediated by free deoxyribonucleic acid. When the lac(+) transductants were isolated and exposed to UV irradiation, lysates with higher transducing ability were obtained. The transducing ability of this lysate was about 100-fold higher than that observed in the original lysates. The lac(+) transductants were unstable since lac(-) segregants occurred at high frequency. The phage lysate from S. lactis C2 also transduced maltose and mannose metabolism to the respective negative recipient cells. The results demonstrate the transduction of carbohydrate markers by a streptococcal phage and establish a genetic transfer system in group N streptococci.     

Concurrent changes in transducing efficiency and content of transforming deoxyribonucleic acid in Bacillus subtilis bacteriophage SP-10

Taylor, Martha J. (Fort Detrick, Frederick, Md.), and Curtis B. Thorne. Concurrent changes in transducing efficiency and content of transforming deoxyribonucleic acid in Bacillus subtilis bacteriophage SP-10. J. Bacteriol. 91:81-88. 1966.-Spores of Bacillus subtilis W-23-S(r) infected with transducing phage SP-10 served as convenient inocula for broth cultures from which transducing phage was harvested. Methods are described for producing highly infected spores. The inoculum level of infected spores in nutrient broth-yeast extract-glucose medium affected the transducing efficiency of SP-10 in lysates of these cultures. Phage in lysates of cultures inoculated with about 10(5) or fewer spores per milliliter transduced 20- to 350-fold more efficiently than did phage in lysates from cultures inoculated with 10(6) to 10(7) spores per milliliter. Transduction frequencies in the order of 10(-5) per plaque-forming unit were obtained routinely, and some infected-spore preparations yielded phage that gave frequencies as high as 10(-4). The combination of inoculum level and incubation time required to produce the best transducing phage had to be determined empirically for each batch of infected spores. Several possible explanations for the difference between lysates having high (HTE) and those having low (LTE) transducing efficiency were ruled out by special experiments. The hypothesis is presented that some cultural condition resulting from a relatively low inoculum of phage-infected spores favors the incorporation by phage particles of bacterial deoxyribonucleic acid (DNA) in the manner required for the production of transducing phage. Support for this hypothesis is a demonstration, through transformation experiments with DNA extracted from HTE and LTE phage particles, that populations of HTE phage particles yielded significantly more (7 to 27 times) transforming activity per microgram of DNA than did populations of LTE phage.     

Specialized transduction of kanamycin resistance in a Providence strain.

Properties of a transducing system with a phage able to transduce a kanamycin-resistance marker of the T compatibility group plasmid R394 at a frequency of 2 times 10(-2)/plaque-forming unit adsorbed are described. The phage was detected in Providence strain P29 transduced to kanamycin resistance by Providence phage PL25 grown on this strain harbouring the R factor. Four P29 transductants, specially selected at the lowest multiplicities of infection of the high frequency transducing (HFT) phage, were defective lysogens. They plated PL25 with an efficiency of I and only one liberated low-titre phage spontaneously or on u.v. induction. The defect in maturation function could be corrected by introduction of a wild PL25 prophage. The transducing phage was serologically frequency was increased by the simultaneous presence of homologous non-transducing phage. Transductants did not transfer the kanamycin-resistance marker by conjugation, and produced kanamycin-sensitive segregants at a moderate rate. These segregants could be transduced to kanamycin resistance by the HFT phage. Irradiation of HFT lysates by u.v. produced an exponential fall in transduction frequency. It was concluded that the defective phage transduced by lysogenization. Kanamycin-resistant transductants could themselves be transduced by streptomycin resistance by PL25 reared on a streptomycin-resistant mutant. Lysogenic transductants produced by the HFT phage did not always liberate HFT phage on u.v. induction. Possible explantations are considered.     

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     

Transducing activity of the temperate SM bacteriophage of Pseudomonas aeruginosa

The temperate bacteriophage SM is not serologically related to the known transducing phages F116, G101, B3 of Pseudomonas aeruginosa. The strains with auxotrophic mutations within the wide ranges of the genetic map of P. aeruginosa strain PAO1 were used for studying the transducing activity of the SM phage. All of the 7 bacterial markers tested are transduced with SM phage grown on a prototrophic donor strain. The frequency of transduction of separate bacterial markers using the wild type SM phage is 2.3 to 4.6 X 10(-8). Linked ilv202+ - met28+ markers are cotransduced with SM phage at a frequency of about 1.5%.     

Mapping and characterization of two mutations to antibiotic supersusceptibility in Pseudomonas aeruginosa

Two mutations associated with antibiotic supersusceptibility in Pseudomonas aeruginosa strain Z61 were transferred separately into strain PAO222, using R68.45-mediated conjugation and phage F116L transduction. One mutation (absA) was 40% contransducible with pro-82 at 26 min on the P. aeruginosa chromosome and was associated with increased susceptibility to beta-lactams, gentamicin and hydrophobic agents. Strains carrying the absA mutation also displayed enhanced uptake of a hydrophobic fluorescent probe, 1-N-phenylnaphthylamine, and were found, by SDS-PAGE, to be altered in the pattern of lipopolysaccharide O-antigen distribution. The other mutation (absB), associated with increased susceptibility to beta-lactams and gentamicin but not to hydrophobic agents, was cotransducible with met-28 and proC at 20 min on the chromosome. The absB mutation caused a structurally undefined alteration in the physical interaction of EDTA and gentamicin with the outer membrane.     

The pilG gene product, required for Pseudomonas aeruginosa pilus production and twitching motility, is homologous to the enteric, single-domain response regulator CheY.

The Pseudomonas aeruginosa pilG gene, encoding a protein which is involved in pilus production, was cloned by phenotypic complementation of a unique, pilus-defective mutant of strain PAO1. This mutant, designated FA2, although resistant to the pilus-specific phage D3112 was sensitive to the pilus-specific phages B3 and F116L. In spite of the unusual phage sensitivity pattern, FA2 lacked the ability to produce functional polar pili (pil) and was incapable of twitching motility (twt). Genetic analysis revealed that the FA2 pil mutation, designated pilG1, mapped near the met-28 marker located at 20 min and was distinct from the previously described pilT mutation. This map location was confirmed by localization of a 6.2-kb EcoRI fragment that complemented FA2 on the SpeI and DpnI physical map of the P. aeruginosa PAO1 chromosome. A 700-bp region encompassing the pilG gene was sequenced, and a 405-bp open reading frame, with characteristic P. aeruginosa codon bias, was identified. The molecular weight of the protein predicted from the amino acid sequence of PilG, which was determined to be 14,717, corresponded very closely to that of a polypeptide with the apparent molecular weight of 15,000 detected after expression of pilG from the T7 promoter in Escherichia coli. Moreover, the predicted amino acid sequence of PilG showed significant homology to that of the enteric CheY protein, a single-domain response regulator. A chromosomal pilG insertion mutant, constructed by allele replacement of the wild-type gene, was not capable of pilus production or twitching motility but displayed normal flagellum-mediated motility. These results, therefore, suggest that PilG may be an important part of the signal transduction system involved in the elaboration of P. aeruginosa pili.     

Bacteriophage P22-mediated specialized transduction in Salmonella typhimurium: high frequency of aberrant prophage excision.

The temperate bacteriophage P22 mediates both generalized and specialized transduction in Salmonella typhimurium. Specialized transduction by phage P22 is different from, and less restricted than, the well characterized specialized transduction by phage lambda, due to differences in the phage DNA packaging mechanisms. Based on the properties of the DNA packaging mechanism of phage P22 a model for the generation of various types of specialized transducing particles is presented that suggests generation of substantial numbers of specialized transducing genomes which are heterogeneous but only some of which have terminally redundant ends. The primary attachment site, ataA, for phage P22 in S. typhimurium is located between the genes proA,B and supQ newD. (The newD gene is a substitute gene for the leuD gene, restoring leucine prototrophy of leuD mutant strains.) The proA,B and supQ newD genes are very closely linked and thus cotransducible by generalized transducing particles. Specialized transducing particles can carry either proA,B or supQ newD but not both simultaneously, and thus cannot give rise to cotransduction of the proA,B and supQ newD genes. This difference is used to calculate the frequency of generalized and specialized transducing particles from the observed cotransduction frequency in phage lysates. By this method, very high frequencies of supQ newD (10(-2)/PFU)- and proA,B (10(-3)/PFU)-specialized transducing particles were detected in lysates produced by induction of lysogenic strains. These transducing particles most of which would have been produced by independent aberrant excision events (which include in situ packaging), were of various types.     

Mini-D3112 bacteriophage transposable elements for genetic analysis of Pseudomonas aeruginosa.

Small bacteriophage D3112 transposable elements deleted for most of the phage-lytic functions while retaining the sites required for transposition and packaging were constructed to facilitate genetic studies in Pseudomonas aeruginosa. These mini-D derivatives were constructed with the terminal 1.85 kilobases (kb) of the phage left end and 1.4 kb of the phage right end and either the Tn5 kanamycin resistance or the pSC101 (pBR322) tetracycline resistance determinant. Thermally induced lysates of strains lysogenic for both a mini-D element and D3112 cts (temperature-sensitive repressor) transduced P. aeruginosa PAO recipients to drug resistance at frequencies of between 10(-4) and 10(-5)/PFU of the helper phage. As for the parent plaque-forming D3112 phage, the mini-D171 element could insert itself into many different sites in the chromosome but the frequency of insertion into particular genes varied widely. Among 1,000 insertions, none resulted in auxotrophy but 10 resulted in pigment production. Insertions were also selected in a cloning plasmid with a transduction scheme. At least eight different insertion sites were found to have been used among 10 individual insertions. Transductants harboring these mini-D elements were immune to infection by D3112, since they contained the D3112 repressor gene in the left 1.85-kb terminal fragment. Chromosomal genes were transduced in a generalized fashion 100 to 1,000 times more frequently by the mini-D-D3112 cts lysates than by the D3112 cts phage alone. Mini-D171-D3112 cts lysates also yielded some transductants that retained the drug resistance marker of the mini-D element and which were unstable for the chromosomal transduced marker. This is consistent with the miniduction properties of Mu whereby transduced genes are flanked by two mini-D elements in the same orientation.     

Structural studies of lambda transducing bacteriophage carrying bacterial deoxyribonucleic acid from the metBJLF region of the Escherichia coli chromosome.

The structures of several lambda dmet and related lambda darg transducing phage were studied by restriction fragment mapping and electron microscopic measurements of homoduplexes and heteroduplexes. A new transducing phage (lambda dmet141), in which metF is the only functional gene of the cluster, was isolated. In contrast, lambda dmet117, which expresses the entire metBJLF cluster, has only 3 kilobases more bacterial deoxyribonucleic acid (DNA) than lambda dmet141. An EcoRI restriction fragment of lambda dmet117, which carries the leftmost 6 kilobases of the bacterial DNA insert, was isolated and shown to contain a functional copy of metB. Small structural differences at the attachment sites of some of the phage were shown to result from different sites of lambda integration in the two parent insertion lysogens.     

Analysis of lambda insertions in the fucose utilization region of Escherichia coli K-12: use of lambda fuc and lambda argA transducing bacteriophages to partially order the fucose utilization genes

Escherichia coli K-12 strains have deletions for the normal lambda integration site were lysogenized with bacteriophage lambda at a site within the L-fucose utilization system (fuc). The frequency of lambda integration at this site is approximately 2 X 10(-8) to 5 X 10(-7). Studies of the lytic properties of these strains indicated very infrequent cell lysis with a relatively low phage burst size. Transductional ability of the phage lysates was found to be normal, comparable to that found in conventional low-frequency transducing lysates. Two major classes of transducing phage were found. One carried the markers argA and fucA (a fucose utilization gene of unknown function previously referred to as fuc-1) and the gene for D-arabinose utilization (dar+). The other carried only fucC, the gene specifying L-fuculose-1-phosphate aldolase. A minor class of phage was found that carried fucA, but not argA or dar+. Upon consideration of the transductional nature of these phage classes, we are proposing that the gene order for the L-fucose utilization system is dar, fucA, (lambda), fucC.     

O-antigen conversion in Pseudomonas aeruginosa PAO1 by bacteriophage D3.

The lysogenization of Pseudomonas aeruginosa PAO by phage D3 results in derivatives which are resistant to superinfection by phage D3c by virtue of the fact that homologous phage cannot adsorb to these cells. The serologically and morphologically unrelated phage E79 showed a markedly decreased adsorption rate to the lysogen PAO(D3). Since both of these phages are lipopolysaccharide specific, these results suggested lysogenic conversion of the phage receptor. The lipopolysaccharide was extracted from strain PAO by the hot phenol-water technique, but this procedure was ineffective with PAO(D3). We developed a technique involving cold trichloroacetic acid extraction, followed by ultracentrifugation, digestion of the high-speed pellet with proteinase K, and ultimate purification on CsCl step gradients. The lipopolysaccharide from the wild type had inactivating activity against D3 and E79, whereas that from PAO(D3) inactivated neither. Chromatographic analysis indicated that the convertant lipopolysaccharide was smooth, and quantitative chemical analyses of the two preparations showed no differences in the level of the major fatty acids, amino compounds, or neutral sugars. On the other hand, sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the side chains had a decreased migration rate through the gel matrix. The application of 1H and 13C nuclear magnetic resonance spectroscopic analysis revealed that the PAO side chain is chemically identical to that of serotype O:2a,d, containing 2,3-(1-acetyl-2-methyl-2-imidazolino-5,4)-2,3-dideoxy-D-mannuronic acid, 2,3-diacetamido-2,3-dideoxy-D-mannuronic acid, and 2-acetamido-2,6-dideoxy-D-galactose (D-fucosamine). The molecular basis of the conversion event was (i) the introduction of an acetyl group into position 4 of the fucosamine residue and a change in the bonding between trisaccharide repeating units from alpha 1 leads to 4 to beta 1 leads to 4.     

Physical and genetical analysis of bacteriophage T4 generalized transduction

This report describes a comparison of the efficiency of transduction of genes in E. coli by the generalized transducing bacteriophages T4GT7 and P1CM. Both phages are capable of transducing many genetic markers in E. coli although the frequency of transduction for particular genes varies over a wide range. The frequency of transduction for most genes depends on which transducing phage is used as well as on the donor and recipient bacterial strains. Analysis of T4GT7 phage lysates by cesium chloride density gradient centrifugation shows that transducing phage particles contain primarily bacterial DNA and carry little, if any, phage DNA. In this regard transducing phages P1CM and T4GT7 are similar; both phages package either bacterial or phage DNA but not both DNAs into the same particle.     

Insertion of bacteriophage SP beta into the citF gene of Bacillus subtilis and specialized transduction of the ilvBC-leu genes.

We isolated a strain of Bacillus subtilis in which the SP beta c2 prophage is inserted into the citF (succinate dehydrogenase) gene. Defective specialized transducing particles for the ilvBC-leu genes were isolated from phage-induced lysates of this lysogen. We isolated a group of phages that differ in the amount of genetic material they carry from this region. Also, we incorporated mutant ilv and leu alleles into the genomes of several transducing phages. Our phage collection enables us to identify the cistron of new ilv and leu mutations by complementation analysis. In this process we discovered a fourth leu cistron, leuD. Characterization of the phages confirmed the published gene order: ilvB-ilvC-leuA-leuC-leuB; leuD lies to the right of leuB.     

Bacteriophage P22-mediated specialized transduction in Salmonella typhimurium: identification of different types of specialized transducing particles.

The temperate bacteriophage P22 mediates both generalized and specialized transduction in Salmonella typhimurium. Specialized transduction by phage P22 is different from, and less restricted than, the well characterized specialized transduction by phage lambda, due to differences in the phage DNA packaging mechanism. Phage lysates produced by induction of lysogenic strains contain very high frequencies of supQ newD- and proA,B-specialized transducing particles (10(-2)/PFU and 10(-3)/PFU, respectively), most of which are produced by independent aberrant excision events of various types. In a model, 12 different modes of transduction mechanisms were characterized by: (i) the structure of the specialized transducing genomes after injection into a new host cell, i.e., linear or circular, and (ii) the requirements for the transduction process, i.e., host recombination functions, phage integration functions, or presence of a prophage. By using different recipient strains and phage helper strains, it was possible to show that most specialized transducing particles (ca. 99%) contain linear genomes that cannot circularize upon injection into a new host cell and that require the presence of an integrated prophage as a site for a recombinational event to give rise to a transductant. Only 0.1% of all specialized transducing particles were shown to transduce by integration, suggesting that transducing genomes containing terminally redundant ends represent only a minor fraction of all transducing particles that are produced. However, it should be pointed out that the frequency (approximately 10(-5)/PFU) of these specialized transducing genomes that can circularize upon injection into a new host cell is as high as or even higher than the frequency of specialized transducing particles of phage lambda. The remaining approximately 1% of all specialized transducing particles can transduce by any one of the other mechanisms described.     

Improved generalized transducing bacteriophage for Caulobacter crescentus.

Caulobacter phage phi Cr30T, a temperature-sensitive derivative of the lytic, generalized transducing phage phi Cr30, was isolated as a double temperature-sensitive recombinant in a cross between phi Cr30ts1 and phi Cr30ts2, phi Cr30T mediated generalized transduction of Caulobacter crescentus at frequencies comparable to those of phi Cr30 and eliminated the requirement for irradiation of transducing lysates to prevent killing of transductants on the plate.     

Isolation and characterization of lambda transducing bacteriophages for the su1+ (supD minus) amber suppressor of Escherichia coli.

Specialized lambda transducing phages for the sul+ (supD-) amber suppressor in Escherichia coli K-12 have been isolated, using a secondary site lambda-cI857 lysogen in which we have shown the prophage to be closely linked to sul+.sul+ transducing particles were detected frequently, at 10-5 per plaque-forming unit, in lysates prepared from the secondary-site lysogens. High-frequency transducing lysates were obtained from several independently isolated sul+ transductants and were analyzed by CsCl equilibrium density gradient centrifugation. The transducing phages are defective; marker rescue analysis indicates that the lambda-N gene is not present. In lambda-cI857DELTANdSul+, a bio-type transducing phage, the genes specifying recombination and excision functions have been replaced by bacterial deoxyribonucleic acid.     

A novel transducing phage

Summary Two newly isolated generalized transducing phages, F126 and F130, are in many respects similar to the previously described phage F116 of P. aeruginosa strain PAO. They also share with F116 the property of not responding to host-specific restriction in strain PAO. However, while the transduction ability of phages F116 and F130 is also inert to PAO-specific restriction, transduction mediated by phage F126 is 8–120 fold reduced in restrictive conditions. In experiments designed to explore the conditions necessary to obtain restriction in F126 transduction it was found that it differed from those previously known to specify host-controlled restriction in P. aeruginosa PAO (Rolfe and Holloway, 1968). These observations suggest that more than one independent restriction system operates in strain PAO.