Bacteriophage lambda derivatives carrying two copies of the cohesive end site

A spontaneously arising tandem duplication derivative of bacteriophage lambda has been isolated, which carries two copies of the site where the cohesive ends are formed (designated cos). Its structure has been determined by electron microscopy of DNA heteroduplexes. These heteroduplexes reveal that the duplication is usually, but not always, carried on the left end of the chromosome. A second duplication phage having two copies of cos, constructed by Feiss &; Campbell (1974), has also been studied by electron microscopy and is found to have a similar property.Unlike most tandem duplication derivatives of phage λ, the mutant studied here is not stable during growth in the absence of generalized recombination, but segregates both the triplication and the parental phage. This verifies that both cos sites are functional. The triplication does not arise as a result of end-to-end aggregation of phage chromosomes or site-specific recombination catalyzed by the chromosome maturation system at cos. It must therefore result from the cutting of mature ι chromosomes from concatemeric replication intermediates. The pattern of cutting observed shows that the λ cohesive ends are not created by a free nuclease acting on unpackaged DNA. The cutting appears to be influenced by the amount of DNA previously packaged into a phage head. A model for λ packaging is presented which explains the results.The duplication phage of Feiss &; Campbell (1974) carries a novel addition containing self-complementary sequences.     

Packaging of coliphage lambda DNA. II. The role of the gene D protein

The gene D protein (pD) of coliphage λ is normally an essential component of the virus capsid. It acts during packaging of concatemeric λ DNA into the phage prohead and is necessary for cutting the concatemers at the cohesive end site (cos). In this report we show that cos cutting and phage production occur without pD in λ deletion mutants whose DNA content is less than 82% that of λ wild type. D-independence appears to result directly from DNA loss rather than from inactivation (or activation) of a phage gene. (1) In cells mixedly infected with undeleted λ and a deletion mutant, particles of the deletion mutant alone are efficiently produced in the absence of pD; and (2) D-independence cannot be attributed to loss of a specific segment of the phage genome. pD-deficient phage resemble pD-containing phage in head size and DNA ends; they differ in their extreme sensitivity to EDTA, greater density, and ability to accept pD.pD appears to act by stabilizing the head against disruption by overfilling with DNA rather than by changing the capacity of the head for DNA. This is shown by the observation that the amount of DNA packaged by a “headful” mechanism, normally in excess of the wild-type chromosome size, is not reduced in the absence of pD. In fact, pD is required for packaging headfuls of DNA. This implies that a mechanism exists for preventing the entry of excess DNA into the head during packaging of concatemers formed by deletion mutants, and we suggest that this is accomplished by binding of cos sites to the head.The above results show that pD is not an essential component of the nuclease that cuts λ concatemers at cos during packaging, and they imply that 82% of a wild-type chromosome length can enter the prohead in the absence of pD. Yet, pD is needed for the formation of cohesive ends after infection with undeleted phage. We propose two models to account for these observations. In the first, cos cutting is assumed to occur early during packaging. The absence of pD leads to release of packaged DNA and the loss of cohesive ends by end-joining. In the second, cos cutting is assumed to occur as a terminal event in packaging. pD promotes cos cutting indirectly through its effect on head stability. We favor the second model because it better explains the asymmetry observed in the packaging of the chromosomes of cos duplication mutants (Emmons, 1974).     

Processive action of terminase during sequential packaging of bacteriophage lambda chromosomes

Bacteriophage lambda chromosomes are packaged in a polarized, sequential fashion from a multimeric DNA substrate. Mature chromosomes are generated when terminase introduces staggered nicks in the cohesive end sites (cos sites) bounding a chromosome. Packaging is polarized, to the initial and terminal cos sites for packaging a chromosome can be defined. To initiate packaging, terminase binds to cos at cosB, and subsequently cuts at cosN. To terminate packaging of a chromosome, a functional cosB is not required at the terminal cos. To explain this finding, it was proposed earlier that terminase scans for the terminal cosN, rather than any subsequent cosB, during packaging. In the work described here we performed helper packaging experiments to see whether processive action of terminase occurs during sequential packaging of lambda chromosomes. The helper packaging experiments involve trilysogens; strains carrying three prophages in tandem. Infection by a hetero-immune helper phage results in packaging of the repressed prophage chromosomes, since the prophage structure is analogous to the normal DNA substrate. Two chromosomes can be packaged from between the three cos sites of the prophages of a trilysogen. Both chromosomes are packaged even when the central cos is cosB-. Our interpretation of these data is that terminase is brought to the central cos by packaging; following cleavage of the central cos, the terminase remains bound to the distal chromosome; and terminase acts to begin packaging of the distal chromosome. The frequency at which terminase reads across the central cos to initiate packaging of the distal chromosome is in the range from 0.3 to 0.5 in our experiments. Reading across cos was found not to be greatly dependent on the state of cosB, indicating that cosB binding is only needed for packaging the first chromosome in a packaging series. A multilysogen was constructed in which the initial cos was cos+ and the distal cos sites were all cosB-. The initial and downstream chromosomes were found to be packaged. This result indicates that terminase that is brought to the central cos by packaging is not only able to initiate packaging of a downstream chromosome, but can also scan and terminate packaging of the downstream chromosome. A model is presented in which processive action of terminase is the basis for sequential packaging of lambda chromosomes.     

Packaging of coliphage lambda DNA. I. The role of the cohesive end site and the gene A protein

The cohesive ends of the DNA of bacteriophage λ particles are normally formed by the action of a nuclease on the cohesive end sites (cos) of concatemeric λ DNA (reviewed by Hohn et al., 1977). The nuclease also cuts the cos site of an integrated prophage, and DNA located to the right is preferentially packaged into phage particles. This process occurs with approximately the same efficiency and rate in a single lysogen as in a tandem polylysogen. Thus, the rate of cos cutting does not increase when the number of cos sites per molecule increases, an hypothesis that has been proposed to explain why cohesive ends are not formed in circular monomers of λ DNA. We propose instead that the interaction of Ter with cos is influenced by the configuration of the DNA outside of cos during packaging, and that this configuration is different for circular monomers than for other forms of λ DNA. A model that gives rise to such a difference is described.We also found that missense mutations in the λ A gene changed the efficiency of packaging of phage relative to host DNA. This was not the case for missense mutations in several phage genes required for capsid formation. Thus, the product of gene A plays a role in determining packaging specificity, as expected if it is or is part of the nuclease that cuts λ DNA at cos.     

On maturation of the bacteriophage lambda chromosome

Summary Repressed lambda chromosomes that possess a duplication of the cohesive end site (cos site) are matured during lytic growth of 80. This result is in contrast to repressed non-duplication lambda chromosomes that are not matured by 80. DNA molecules matured by 80 are unreplicated and lack the duplication: both cos sites are cleaved. These results indicate that in normal lambda development, mature, unit-length chromosomes are generated from a multichromosomal length of lambda DNA by cleavage of two cos sites.     

Genetic Variation of Lactobacillus delbrueckii subsp. lactis Bacteriophages Isolated from Cheese Processing Plants in Finland

The genomes of four Lactobacillus delbrueckii subsp. lactis bacteriophages were characterized by restriction endonuclease mapping, Southern hybridization, and heteroduplex analysis. The phages were isolated from different cheese processing plants in Finland between 1950 and 1972. All four phages had a small isometric head and a long noncontractile tail. Two different types of genome (double-stranded DNA) organization existed among the different phages, the pac type and the cos type, corresponding to alternative types of phage DNA packaging. Three phages belonged to the pac type, and a fourth was a cos-type phage. The pac-type phages were genetically closely related. In the genomes of the pac-type phages, three putative insertion/deletions (0.7 to 0.8 kb, 1.0 kb, and 1.5 kb) and one other region (0.9 kb) containing clustered base substitutions were discovered and localized. At the phenotype level, three main differences were observed among the pac-type phages. These concerned two minor structural proteins and the efficiency of phage DNA packaging. The genomes of the pac-type phages showed only weak homology with that of the cos-type phage. Phage-related DNA, probably a defective prophage, was located in the chromosome of the host strain sensitive to the cos-type phage. This DNA exhibited homology under stringent conditions to the pac-type phages.     

Isolation of Plaque-Forming, Galactose-Transducing Strains of Phage Lambda

Plaque-forming, galactose-transducing lambda strains have been isolated from lysogens in which bacterial genes have been removed from between the galactose operon and the prophage by deletion mutation.—A second class has been isolated starting with a lysogenic strain which carries a deletion of the genes to the right of the galactose operon and part of the prophage. This strain was lysogenized with a second lambda phage to yield a lysogen from which galactose-transducing, plaque-forming phages were obtained. These plaque-forming phages were found to be genetically unstable, due to a duplication of part of the lambda chromosome. The genetic instability of these partial diploid strains is due to homologous genetic recombindation between the two identical copies of the phage DNA comprising the duplication. The galactose operon and the duplication of phage DNA carried by these strains is located between the phage lambda P and Q genes.     

Bacteriophage Resistance Plasmid pTR2030 Inhibits Lytic Infection of r1t Temperate Bacteriophage but Not Induction of r1t Prophage in Streptococcus cremoris R1

The effects of pTR2030 on the replication of four small isometric bacteriophages were examined in Streptococcus cremoris R1. Three lytic phages (652, 720, and 751), which were isolated independently over a 29-year period, were unable to form plaques on a pTR2030 transconjugant of S. cremoris R1. The fourth phage evaluated, phage r₁t, was a temperate phage induced from S. cremoris R1 by treatment with mitomycin C. A prophage-cured derivative of S. cremoris R1, designated R1Cs, was isolated and served as a lytic indicator for phage r₁t. Strain R1Cs and a derivative of this strain that was relysogenized with r₁t, designated R1Cs(r₁t), were used as conjugal recipients for transfer of the phage resistance plasmid pTR2030. pTR2030 transconjugants of strains R1Cs and R1Cs(r₁t) were evaluated for sensitivity to r₁t phage and induction of r₁t prophage, respectively. The temperate phage r₁t adsorbed eficiently but did not form plaques on the prophage-cured, pTR2030 transconjugant strain T-R1Cs. However, in the r₁t lysogen [T-R1Cs(r₁t)], pTR2030 did not inhibit prophage induction with mitomycin C, cell lysis, or production of infective r₁t phage particles. The data demonstrated that pTR2030-induced resistance inhibited lytic infection by r₁t phage from without but did not retard lytic development after prophage induction within the cell. It was suggested that pTR2030-encoded phage resistance to small isometric phages may, therefore, act at the cell surface or membrane to prevent phage DNA passage into the host cell or inhibit early events required for lytic replication of externally infecting phage.     

An improved helper phage system for efficient isolation of specific antibody molecules in phage display

Phage display technology has been applied in many fields of biological and medical sciences to study molecular interactions and especially in the generation of monoclonal antibodies of human origin. However, extremely low display level of antibody molecules on the surface of phage is an intrinsic problem of a phagemid-based display system resulting in low success rate of isolating specific binding molecules. We show here that display of single-chain antibody fragment (scFv) generated with pIGT3 phagemid can be increased dramatically by using a genetically modified Ex-phage. Ex-phage has a mutant pIII gene that produces a functional wild-type pIII in suppressing Escherichia coli strains but does not make any pIII in non-suppressing E.coli strains. Packaging phagemids encoding antibody-pIII fusion in F⁺ non-suppressing E.coli strains with Ex-phage enhanced the display level of antibody fragments on the surfaces of recombinant phage particles resulting in an increase of antigen-binding reactivity >100-fold compared to packaging with M13KO7 helper phage. Thus, the Ex-phage and pIGT3 phagemid vector provides a system for the efficient enrichment of specific binding antibodies from a phage display library and, thereby, increases the chance of obtaining more diverse antibodies specific for target antigens.     

Repair mechanisms involved in prophage reactivation and UV reactivation of UV-irradiated phage lambda

Survival of UV-irradiated phage λ is increased when the host is lysogenic for a homologous heteroimmune prophage such as λimm434 (prophage reactivation). Survival can also be increased by UV-irradiating slightly the non-lysogenic host (UV reactivation).Experiments on prophage reactivation were aimed at evaluating, in this recombination process, the respective roles of phage and bacterial genes as well as that of the extent of homology between phage and prophage.To test whether UV reactivation was dependent upon recombination between the UV-damaged phage and cellular DNAs, lysogenic host cells were employed. Such hosts had thus as much DNA homologous to the infecting phage as can be attained. Therefore, if recombination between phage and host DNAs was involved in this repair process, it could clearly be evidenced.By using unexposed or UV-exposed host cells of the same type, prophage reactivation and UV reactivation could be compared in the same genetic background.The following results were obtained: (1) Prophage reactivation is strongly decreased in a host carrying recA mutations but quite unaffected by mutation lex-I known to prevent UV reactivation; (2) In the absence of the recA⁺ function, the red⁺ but not the int⁺ function can substitute for recA⁺ to produce prophage reactivation, although less efficiently; (3) Prophage reactivation is dependent upon the number of prophages in the cell and upon their degree of homology to the infecting phage. The presence in a recA host of two prophages either in cis (on the chromosome) or in trans (on the chromosome and on an episome) increases the efficiency of prophage reactivation; (4) Upon prophage reactivation there is a high rate of recombination between phage and prophage but no phage mutagenesis; (5) The rate of recombination between phage and prophage decreases if the host has been UV-irradiated whereas the overall efficiency of repair is increased. Under these conditions UV reactivation of the phage occurs as in a non-lysogen, as attested by the high rate of mutagenesis of the restored phage.These results demonstrate that UV reactivation is certainty not dependent upon recombination between two pre-existing DNA duplexes. The hypothesis is offered that UV reactivation involves a repair mechanism different from excision and recombination repair processes.     

DNA-DNA Homology Between Lactic Streptococci and Their Temperate and Lytic Phages

Temperate phages were induced from Streptococcus cremoris R₁, BK₅, and 134. DNA from the three induced phages was shown to be homologous with prophage DNA in the bacterial chromosomes of their lysogenic hosts by the Southern blot hybridization technique. ³²P-labeled DNA from 11 lytic phages which had been isolated on cheese starters was similarly hybridized with DNA from 36 strains of lactic streptococci. No significant homology was detected between the phage and bacterial DNA. Phages and lactic streptococci used included phages isolated in a recently opened cheese plant and all the starter strains used in the plant since it commenced operation. The three temperate phages were compared by DNA-DNA hybridizations with 25 lytic phages isolated on cheese starters. Little or no homology was found between DNA from the temperate and lytic phages. In contrast, temperate phages showed a partial relationship with one another. Temperate phage DNA also showed partial homology with DNA from a number of strains of lactic streptococci, many of which have been shown to be lysogenic. This suggests that many temperate phages in lactic streptococci may be related to one another and therefore may be homoimmune with one another. These findings indicate that the release of temperate phages from starter cells currently in use is unlikely to be the predominant source of lytic phages in cheese plants.     

Commitment to Lysogeny Is Preceded by a Prolonged Period of Sensitivity to the Late Lytic Regulator Q in Bacteriophage λ

A key event in development is the irreversible commitment to a particular cell fate, which may be concurrent with or delayed with respect to the initial cell fate decision. In this work, we use the paradigmatic bacteriophage λ lysis-lysogeny decision circuit to study the timing of commitment. The lysis-lysogeny decision is made based on the expression trajectory of CII. The chosen developmental strategy is manifested by repression of the pR and pL promoters by CI (lysogeny) or by antitermination of late gene expression by Q (lysis). We found that expression of Q in trans from a plasmid at the time of infection resulted in a uniform lytic decision. Furthermore, expression of Q up to 50 min after infection results in lysis of the majority of cells which initially chose lysogenic development. In contrast, expression of Q in cells containing a single chromosomal prophage had no effect on cell growth, indicating commitment to lysogeny. Notably, if the prophage was present in 10 plasmid-borne copies, Q expression resulted in lytic development, suggesting that the cellular phage chromosome number is the critical determinant of the timing of lysogenic commitment. Based on our results, we conclude that (i) the lysogenic decision made by the CI-Cro switch soon after infection can be overruled by ectopic Q expression at least for a time equivalent to one phage life cycle, (ii) the presence of multiple λ chromosomes is a prerequisite for a successful Q-mediated switch from lysogenic to lytic development, and (iii) phage chromosomes within the same cell can reach different decisions.     

Investigation of the Relationship between Lysogeny and Lysis of Lactococcus lactis in Cheese Using Prophage-Targeted PCR

The ability of lactococcal strains to lyse (and release intracellular enzymes) during cheese manufacture can be a very desirable trait and has been associated with improvement in flavor and acceleration of cheese ripening. Using a laboratory-scale cheese manufacturing assay, the autolytic behavior of 31 strains of Lactococcus lactis was assessed. In general, marked variation was observed between strains with a 20-fold difference between the best and worst lysing strains based on the release of the intracellular enzyme lactate dehydrogenase. In a parallel experiment, the genomes of these strains were examined for the presence of prophage integrase (int) sequences by using conserved primer sequences from known lysogenic phage. Results demonstrated that the lytic behavior of lactococcal starter strains significantly correlates with the presence of prophage sequences. These results highlight not only the contribution of prophage to starter cell lysis but also the potential of PCR as a useful initial screen to assess strains for this important industrial trait.     

Prophage lambda at unusual chromosomal locations: III. The components of the secondary attachment sites

The integration of phage λ occurs by a reciprocal genetic exchange, promoted by the product of phage int gene, at specific sites on the phage and bacterial genomes (att's). Lysogenic bacteria thus contain two att's which bracket the inserted prophage. Genetically, the phage, bacterial and prophage att's differ from each other, indicating that each site has specific elements which segregate during recombination.In hosts that lack the bacterial att, phage integration occurs at about 0.5% the normal frequency. It results from Int-promoted recombination between the phage att and any one of many secondary sites in the bacterial genome. To analyze these sites, we measured Int-promoted recombination at the secondary prophage att's. We found that they differed from the normal prophage att's and from the phage att. The secondary sites, therefore, do not appear to carry any of the specific elements of the phage or bacterial att's.The transducing phage isolated from secondary site lysogens integrate at two loci. In the absence of helper, they insert via homology with the bacterial DNA. Co-infection with helper results in their integration at the normal bacterial att.     

Carriage of λ Latent Virus Is Costly for Its Bacterial Host due to Frequent Reactivation in Monoxenic Mouse Intestine

Temperate phages, the bacterial viruses able to enter in a dormant prophage state in bacterial genomes, are present in the majority of bacterial strains for which the genome sequence is available. Although these prophages are generally considered to increase their hosts’ fitness by bringing beneficial genes, studies demonstrating such effects in ecologically relevant environments are relatively limited to few bacterial species. Here, we investigated the impact of prophage carriage in the gastrointestinal tract of monoxenic mice. Combined with mathematical modelling, these experimental results provided a quantitative estimation of key parameters governing phage-bacteria interactions within this model ecosystem. We used wild-type and mutant strains of the best known host/phage pair, Escherichia coli and phage λ. Unexpectedly, λ prophage caused a significant fitness cost for its carrier, due to an induction rate 50-fold higher than in vitro, with 1 to 2% of the prophage being induced. However, when prophage carriers were in competition with isogenic phage susceptible bacteria, the prophage indirectly benefited its carrier by killing competitors: infection of susceptible bacteria led to phage lytic development in about 80% of cases. The remaining infected bacteria were lysogenized, resulting overall in the rapid lysogenization of the susceptible lineage. Moreover, our setup enabled to demonstrate that rare events of phage gene capture by homologous recombination occurred in the intestine of monoxenic mice. To our knowledge, this study constitutes the first quantitative characterization of temperate phage-bacteria interactions in a simplified gut environment. The high prophage induction rate detected reveals DNA damage-mediated SOS response in monoxenic mouse intestine. We propose that the mammalian gut, the most densely populated bacterial ecosystem on earth, might foster bacterial evolution through high temperate phage activity.     

Targeted Curing of All Lysogenic Bacteriophage from Streptococcus pyogenes Using a Novel Counter-selection Technique

Streptococcus pyogenes is a human commensal and a bacterial pathogen responsible for a wide variety of human diseases differing in symptoms, severity, and tissue tropism. The completed genome sequences of >37 strains of S. pyogenes, representing diverse disease-causing serotypes, have been published. The greatest genetic variation among these strains is attributed to numerous integrated prophage and prophage-like elements, encoding several virulence factors. A comparison of isogenic strains, differing in prophage content, would reveal the effects of these elements on streptococcal pathogenesis. However, curing strains of prophage is often difficult and sometimes unattainable. We have applied a novel counter-selection approach to identify rare S. pyogenes mutants spontaneously cured of select prophage. To accomplish this, we first inserted a two-gene cassette containing a gene for kanamycin resistance (Kan^R) and the rpsL wild-type gene, responsible for dominant streptomycin sensitivity (Sm^S), into a targeted prophage on the chromosome of a streptomycin resistant (Sm^R) mutant of S. pyogenes strain SF370. We then applied antibiotic counter-selection for the re-establishment of the Kan^S/Sm^R phenotype to select for isolates cured of targeted prophage. This methodology allowed for the precise selection of spontaneous phage loss and restoration of the natural phage attB attachment sites for all four prophage-like elements in this S. pyogenes chromosome. Overall, 15 mutants were constructed that encompassed every permutation of phage knockout as well as a mutant strain, named CEM1ΔΦ, completely cured of all bacteriophage elements (a ~10% loss of the genome); the only reported S. pyogenes strain free of prophage-like elements. We compared CEM1ΔΦ to the WT strain by analyzing differences in secreted DNase activity, as well as lytic and lysogenic potential. These mutant strains should allow for the direct examination of bacteriophage relationships within S. pyogenes and further elucidate how the presence of prophage may affect overall streptococcal survival, pathogenicity, and evolution.     

Coupling with Packaging Explains Apparent Nonreciprocality of Chi-Stimulated Recombination of Bacteriophage Lambda by Reca and Recbc Functions

Chi (χ, 5'-GCTGGTGG) is a recombinator in RecA- and RecBC-mediated recombination in Escherichia coli. In vegetative recombination between two bacteriophage lambda strains, one with and the other without Chi (a⁺χ⁺b^- x a^-χ^ob⁺), the χ-containing recombinant (a^-χ⁺b ^-) is less abundant than the non-χ-containing recombinant (a⁺χ^ob⁺). Previously this was taken was evidence for nonreciprocality of χ-stimulated exchange. This inequality, however, is now seen to result from an event at cos (λ's packaging origin) that both activates Chi and initiates DNA packaging. An event at rightward cos leads to activation of leftward χ on the same chromosome for an exchange to its left. From the resulting circulating dimer (—cos-a⁺-χ^o-b ⁺-cos-a ^--χ⁺-b-—), the cos that activated χ is more likely to be used for rightward packaging initiation than is the cos from the other parent. Consistent with this coupling model is "biased packaging" in λ carrying two cos sites per monomer genome. When their maturation is dependent on dimerization by χ-stimulated exchange, the phage particles result more often from packaging from the cos that activates χ than from packaging from the other cos. Since Chi activation and packaging can be uncoupled, we infer that some early and reversible step in packaging activates χ. A strong candidate for this step is a double-strand break at cos that provides an oriented entry site for a recombinase.     

Phage-transposon interaction: the cip locus of prophage D3112 responsible for the inhibition of integration and transposition of related phage B39 of Pseudomonas aeruginosa

Bacterial cells lysogenic for D3112, a transposable Pseudomonas aeruginosa phage restrict the growth of a related heteroimmune B39 phage. The lysogens are divided into two different types PAO(D3112). In the lysogens of the type I the efficiency of B39 growth only decreases slightly, the lysogens of the type II restricting completely the growth of this phage (e.o.p. is less than 10(-7). As shown by the results of Southern hybridization experiments, lysogens of the type I are monolysogens, while those of the type II are double or polylysogens. Restriction of B39 in PAO(D3112) is caused by expression of a locus in the D3112 genome. The locus has been termed as cip (control of interaction of phages). The cip locus was mapped at the interval 1.3-2.45 kb of the D3112 physical map using different deletion derivatives of D3112. Expression of cip only takes place in the prophage state and not during the phage lytic development. When expressed, cip affects the early steps in the growth of B39 lowering the level of integration and transposition processes; the effect is not dependent on the way of initiation of the lytic cycle (through prophage induction or infection).     

ppGpp-Dependent Negative Control of DNA Replication of Shiga Toxin-Converting Bacteriophages in Escherichia coli

The pathogenicity of enterohemorrhagic Escherichia coli (EHEC) strains depends on the production of Shiga toxins that are encoded on lambdoid prophages. Effective production of these toxins requires prophage induction and subsequent phage replication. Previous reports indicated that lytic development of Shiga toxin-converting bacteriophages is inhibited in amino acid-starved bacteria. However, those studies demonstrated that inhibition of both phage-derived plasmid replication and production of progeny virions occurred during the stringent as well as the relaxed response to amino acid starvation, i.e., in the presence as well as the absence of high levels of ppGpp, an alarmone of the stringent response. Therefore, we asked whether ppGpp influences DNA replication and lytic development of Shiga toxin-converting bacteriophages. Lytic development of 5 such bacteriophages was tested in an E. coli wild-type strain and an isogenic mutant that does not produce ppGpp (ppGpp⁰). In the absence of ppGpp, production of progeny phages was significantly (in the range of an order of magnitude) more efficient than in wild-type cells. Such effects were observed in infected bacteria as well as after prophage induction. All tested bacteriophages formed considerably larger plaques on lawns formed by ppGpp⁰ bacteria than on those formed by wild-type E. coli. The efficiency of synthesis of phage DNA and relative amount of lambdoid plasmid DNA were increased in cells devoid of ppGpp relative to bacteria containing a basal level of this nucleotide. We conclude that ppGpp negatively influences the lytic development of Shiga toxin-converting bacteriophages and that phage DNA replication efficiency is limited by the stringent control alarmone.     

Yet another way that phage λ manipulates its Escherichia coli host: λrexB is involved in the lysogenic–lytic switch

The life cycle of phage λ has been studied extensively. Of particular interest has been the process leading to the decision of the phage to switch from lysogenic to lytic cycle. The principal participant in this process is the λcI repressor, which is cleaved under conditions of DNA damage. Cleaved λcI no longer acts as a repressor, allowing phage λ to switch from its lysogenic to lytic cycle. The well‐known mechanism responsible for λcI cleavage is the SOS response. We have recently reported that the Escherichia coli toxin‐antitoxin mazEF pathway inhibits the SOS response; in fact, the SOS response is permitted only in E. coli strains deficient in the expression of the mazEF pathway. Moreover, in strains lysogenic for prophage λ, the SOS response is enabled by the presence of λrexB. λRexB had previously been found to inhibit the degradation of the antitoxin MazE, thereby preventing the toxic action of MazF. Thus, phage λ rexB gene not only safeguards the prophage state by preventing death of its E. coli host but is also indirectly involved in the lysogenic–lytic switch.