Specialized transduction of the ilvD-thyB-ilvA region mediated by Bacillus subtilis bacteriophage SP beta

Specialized transducing SP beta particles were found that carried the Bacillus subtilis genes lying to the left of the prophage attachment site. Three classes of transducing particles were differentiated, depending upon whether they carried ilvA only, thyB and ilvA, or ilvD, thyB, and ilvA. Lysates prepared by the induction of strains that carried both a transducing phage and a plaque-forming phage contained the two particles in a ratio of about 1:3,000. When the transducing particles were used to transduce a phage-sensitive auxotrophic strain to prototrophy, some of the transductants carried only the transducing phage genomes which, by themselves, were defective. One putative nondefective transducing phage (for ilvA only) is also described. SP beta can mediate specialized transduction even in the absence of the major (recE) bacterial recombination system.     

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.     

Formation of specifically transducing lambda dg-particles. II. Relationship between the transduction rate, the qualitative composition of the transductants, and the dose of the inducing agent

The formation of specifically transducing lambda dg-particles in E.coli strain W3110 (lambda) due to the effect of different doses of UV irradiation was studied. A sharp increase in both the absolute number of transductants and the relative transduction frequency was found to occur as the dose of UV irradiation increased. On achieving definite doses this relationship became almost direct. At higher doses similarity was observed in the kinetics of a decrease in the absolute number of transductants and in active phage titers. As the dose increased further, a sharp increase in the percentage of heterogenoue transductants occurred. The conclusion that the formation of specifically transducing lambda dg-particles is due to the effect of the inducing factor on the DNA of lysogenic cells has been made.     

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.     

Studies on the Mechanism of Transduction by Bacteriophage ?_entitystart_#947_entit II. Formation of Transducing Elements

The formation of the transducing elements (TE) of bacteriophage ϕγ, analyzed in lysogens of the thermo-inducible derivative ϕγhyI, has been found to parallel the formation of plaque-forming particles with a frequency of 2 x 10^-2 TE/PFU, but is more sensitive to temperature and to UV. Deletion of one of the prophage termini (attR) prevents normal excision and formation of plaque-forming particles, but does not affect the formation of transducing elements, which arise at a rate of nearly 10^-1 TE per induced bacterium. Transducing elements would be formed by in situ encapsulation of a hybrid segment from a specific point in the induced prophage, possibly the presumed packaging initiation site of the normal phage genome, before excision of the latter has occurred. Analysis of the mechanism of transduction to partly heterologous lysogens has revealed the participation of a co-infecting genome arranged in a linear fashion and has given evidence for a permutation in the sequence of transducing and nontransducing genomes. The data are consistent with a mechanism of encapsidation distinct from the Ter system even for hybrids inheriting part of the ϕ80 genome, but endowed with the property to form transducing elements like those of ϕγ. Upon infection, transducing elements are formed after one cycle of lytic development with the same characteristics as those resulting from induction, but with a frequency 50 to 100 times lower. This process is dependent on the efficiency of Int promoted recombination. Superinfection experiments performed under conditions preventing Int promoted recombination reveal that any superinfecting ϕγ can promote the formation of transducing particles, depending on the presence within the host prophage of a site from which transducing genome packaging initiates.     

A novel assay for illegitimate recombination in Escherichia coli: Stimulation of λbio transducing phage formation by ultra-violet light and its independence from RecA function

We developed a novel assay system for illegitimate recombination, in which the frequency of the formation of λ Spi⁻ phages formed during prophage induction was measured with an E. coli P2 lysogen as the indicator bacteria. Since almost all of the λ Spi⁻ phages thus detected contain attR, they have essentially the same structures as λbio transducing phages, indicating that this assay system enables us to detect specialized transducing phages that produce heterogenote transductants, thus ignoring the occurrences of docL and docR particles which carry only one cohesive end. The following results on the formation of specialized transducing phages have been obtained by this assay system to date. (1) Irradiation with UV light greatly enhanced the formation of λ Spi⁻ phages. (2) Treatments with other DNA-damaging agents also enhanced the formation of λ Spi⁻ phages. (3) Illegitimate recombination during prophage induction does not require the RecA function, indicating that enhancement of λ Spi⁻ phage formation is not controlled by the SOS regulatory system. (4) Preliminary results suggested that DNA gyrase is involved in the formation of λ Spi⁻ phage during prophage induction. Since the above results were consistent with most of the previous observations on the illegitimate recombination in other systems, the Spi⁻ assay system can provide important clues to the mechanism of illegitimate recombination.     

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     

The origin of DNA in transducing particles in P22-mutants with increased transduction-frequencies (HT-mutants)

Summary The physical properties of the transducing DNA of HT-phage mutants are described. It could be shown that the increased frequency of transducing particles is not due to replication of such structures formed at a normal rate, but rather to an increased rate of their formation. Further it turned out that density and the sedimentation coefficient of transducing DNA of HT-mutants is comparable to transducing DNA of wild type phages. It could be confirmed that there is also a contribution of about 10% newly synthesized DNA to the bacterial fragment. Therefore it is concluded that the mechanism which leads to transducing particles in HT-mutants is the same as in wild type phages.     

The origin of the DNA in transducing particles of bacteriophage Mu

Summary The origin of DNA in transducing particles of bacteriophage Mu was investigated by density labelling techniques. Unlabelled plaque-forming and leu⁺-transducing particles were of about the same density. Preinfection labelling of DNA with 5-bromodeoxyuridine increased the density of the transducing particles, but not that of the infective ones. Postinfection labelling increased the density of the infective particles twice as much as that of the transducing particles. We conclude that half of the transducing DNA is synthesized before infection and half is synthesized after infection, similar to the results obtained with Plkc transducing phages (Ikeda and Tomizawa, 1965).     

Suppression of gamma ray-induced illegitimate recombination in Escherichia coli by the DNA-binding protein H-NS

To study the mechanism of gamma-ray-induced illegitimate recombination, we examined the formation of lambdabio transducing phage in Escherichia coli after gamma-ray irradiation. We show that gamma-ray irradiation enhances the formation of lambdabio transducing phage during prophage induction. Moreover, an hns mutation synergistically enhanced the incidence of lambda-ray-induced illegitimate recombination. Next we determined the sequences at the recombination junctions of the lambdabio transducing phages induced by gamma-ray irradiation. Most of the recombination sites coincided with known hotspots. Among them, hotspot I accounted for 67% and 77% of gamma-ray-induced lambdabio transducing phages in the wild type and the hns mutant, respectively. Therefore, the recombination sites appear to occur mostly at hotspot I or at other hotspots, but rarely at non-hotspot sites. These results suggest that types of DNA damage other than the double-strand breaks induced at random sites are mainly responsible for the introduction of the site-specific or region-specific DNA double strand breaks that lead to recombination at the hotspots. The results also showed that the recombination events took place between DNA sequences possessing short stretches of homology. H-NS protein, which binds to curved DNA, suppresses illegitimate recombination in the presence and absence of gamma-ray irradiation. Models for gamma-ray-induced illegitimate recombination are discussed.     

Gal transduction by phage lambda: on the origin and nature of LFT transducing genomes

Summary There are at least two classes of transducing particles made on the induction of normal lysogens: the first is capable of transducing by the insertion of the whole transducing genome into the host chromosome, so its genome must be capable of circularizing; the second transduces less well by insertion—perhaps not at all; if it does not transduce by insertion then its genome need not be linear.The formation of a transducing genome can be accomplished in three steps: (a) breaking the lysogenic bacterial chromosomes in two places, (b) joining the fragment ends together to form a circular structure, (c) opening the circle (by ter) to form a linear genome. If the resultant structure meets the requirements for packaging, it may be formed into a transducing phage, like a bougus .Any meaningful rearrangement of these steps in which step (b) is omitted or delayed leads to the formation of genomes, which are (1) unable to transduce by insertion (because both of its mature ends are unexposed) and (2) are on the average smaller than genomes which are capable of transducing by insertion (so the resultant transducing phage is less dense). Consequence (2) has been confirmed.We assume that the red function of catalyzes the joining of broken DNA molecules to each other. So red is responsible for rehealing the product of (a) back into a lysogenic chromosome and for catalyzing step (b), the healing of fragment ends into a circular structure. The much elevated level of stable transductants on induction of red ^– lysogens hereby is explained.Supported by grant E-2862 of the U.S.P.H.S. to Dr. Allan Campell.     

Bacterial DNA synthesized under phage control in a DNA-defective Salmonella-mutant and packaged into a special fraction of transducing particles of phage P22.

Summary Lysates of P22 contain a small fraction of transducing particles with bacterial DNA replicated semiconservatively after the time of infection. It was demonstrated that the presence and relative amount of this class of transducing particles was unchanged, if infection of Salmonella occured under a condition nonpermissive for bacterial DNA replication. Analysis of particles with DNA fragments derived from different regions of the Salmonella chromosome indicated that the replication of the bacterial DNA carried by these transducing particles was not initiated specifically at the normal origin for bacterial chromosome replication.Abbreviations i.p. transducing particles - moi multiplicity of infection - i.p. intectious particles     

Transduction of plasmid determinants in Staphylococcus aureus and Escherichia coli.

Buoyant density analysis of transducing lysates derived from Staphylococcus aureus and Escherichia coli indicated that phage particles bearing plasmid determinants contain a quantity of DNA equivalent to that found in the lytic particles. Transducing particles that bear plasmid determinants smaller than viral DNA must therefore contain a quantity of DNA in excess of a single plasmid genome. In the E. coli P1vir system, a dependence upon host-mediated recombination for the transduction of small plasmids, but not for large R factors or chromosomal genes, was observed. However, no evidence for the involvement of such functions in the transduction of S. aureus plasmids was obtained. Although the origin of the additional DNA in plasmid transducing particles has not been identified, circumstantial evidence has been presented in the staphylococcal system indicating that transducing particles carrying a small tetracycline plasmid are not formed by the wrapping of multiple copies of this plasmid DNA.     

Isolation of specialized transducing bacteriophages carrying the structural genes of the hexuronate system in Escherichia coli K-12: exu region.

In Escherichia coli HfrH 58, isolated by Shimada et al., a heat-inducible phage has been integrated in a secondary attachment site. We have characterized tha nature of the lambda integration. The exuR regulatory gene is inactivated by prophage integration. Genetic and biochemical analysis indicated a gene order: uxaA-uxaC-exuT-(exuR')-lambdaNRAJ (exuR'). By induction of HfrH 58, one class of deletions extending into the exu region was obtained. Analysis of these deletions confirms the exu region topography and the regulatory mechanism of the hexuronate system previously described. It has been possible to regenerate a functional exuR gene by prophage exision. Various lambda transducing particles plaque-forming and defective transducing phages carrying the left part or the right part of the exu region, have been derived from the secondary site lysogen HfrH 58. A phage carrying the entire exuR region was constructed by a cross between these two types of phage. The construction and characterization of these exu transducing phages are presented.     

Transduction of multi-copy plasmid pBR322 by bacteriophage Mu

Summary The temperate bacteriophage Mu transduces the 4363 bp multi-copy plasmid pBR322 at frequencies similar to those of chromosomal markers. Plasmid transducing particles contain DNA molecules of Mu DNA length. Plasmid DNA is transduced as a head-to-tail oligomer that becomes circularized in the recipient cell. The rec system of the donor strain participates in oligomer formation and the rec system of the recipient strain is required for oligomer circularization. Possible mechanisms that may explain the origin of plasmid transducing particles are discussed.     

A method of estimating the effectiveness of ionizing radiation and magnetic fields for phage induction in lysogenic bacterial culture

Either the difference delta N of the content of free phage particles in the experiment and the control or K ratio of these values can be used to estimate the effectiveness of ionizing radiation or other agents inducing phage formation in a lysogenic bacterium culture. The estimation technique the results of which are nearly independent of the fluctuations in the number of phage particles in the control, the inductor dose being invariable, is the most adequate one. The induction of phage in E. coli K12 (lambda) culture by X-rays and magnetic field is an example illustrating that the K ratio, which can be called "the induction coefficient", is in a good agreement with the requirement mentioned above. A possible nature of the phenomenon observed is discussed.     

Transduction of plasmid DNA in Streptomyces spp. and related genera by bacteriophage FP43.

A segment (hft) of bacteriophage FP43 DNA cloned into plasmid pIJ702 mediated high-frequency transduction of the resulting plasmid (pRHB101) by FP43 in Streptomyces griseofuscus. The transducing particles contained linear concatemers of plasmid DNA. Lysates of FP43 prepared on S. griseofuscus containing pRHB101 also transduced many other Streptomyces species, including several that restrict plaque formation by FP43 and at least two that produce restriction endonucleases that cut pRHB101 DNA. Transduction efficiencies in different species were influenced by the addition of anti-FP43 antiserum to the transduction plates, the temperature for cell growth before transduction, the multiplicity of infection, and the host on which the transducing lysate was prepared. FP43 lysates prepared on S. griseofuscus(pRHB101) also transduced species of Streptoverticillium, Chainia, and Saccharopolyspora.     

The molecular structure of the transducing particles of Salmonella phage P22. II. Density gradient analysis of DNA

Summary CsCl density gradient analysis showed that the DNA of plaque forming particles ofSalmonella phageP22 is lighter than the host DNA. The DNA of transducing phages exhibits an intermediate density, but close to host DNA. BU labelling of DNA synthesized in the cells after phage infection resulted in a density increase of transducing DNA of about 0.004 gxcm^-3, whereas infectious DNA increased by about 0.045 gxcm^-3. Shearing of isolated DNA molecules from unlabelledP22 lysates demonstrated that transducing DNA consists of two pieces of DNA of different density: 90% stem from the bacterial host whereas 10% are phage DNA and therefore responsible for the BU lable in transducing phages.     

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.     

Transductional selection of cloned bacteriophage phi 105 and SP02 deoxyribonucleic acids in Bacillus subtilis.

The Bacillus subtilis temperate bacteriophages phi 105 and SP02 are incapable of transduction of the small, multicopy drug resistance plasmids pUB110 and pCM194. Cloning endonuclease-generated fragments of phi 105 or SP02 DNA into each of the plasmids renders the chimeric derivatives susceptible to transduction specifically by the phage whose deoxyribonucleic acid is present in the chimera. The majority of phage deoxyribonucleic acid fragments identified that render plasmids transducible by phi 105 or SP02 appear to be internal fragments, not fragments containing the cohesive ends. However, the highest overall transduction frequency was observed in SP02-mediated transduction of a derivative of pUB110 containing a 1.6-megadalton EcoRI fragment that likely contains the SP02 cohesive ends (plasmid pPL1010). The transducing activity present in a phi 105 transducing lysate had a buoyant density slightly greater than infectious particles, whereas the majority of transducing particles in an SP02(pPL1010) transducing lysate had a buoyant density slightly less than infectious particles. Although no detectable change in plasmid structure resulted from transduction by phi 105 or SP02, deoxyribonucleic acid isolated from a purified SP02(pPL1010) transducing lysate contained no detectable monomeric pPL1010, but did contain a form of pPL1010 of higher molecular weight than the monomer.