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.     

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.     

Deoxyribonucleic Acid Synthesis in Bacteriophage SPO1-Infected Bacillus subtilis I. Bacteriophage Deoxyribonucleic Acid Synthesis and Fate of Host Deoxyribonucleic Acid in Normal and Polymerase-Deficient Strains

The effect of bacteriophage SPO1 infection of Bacillus subtilis and a deoxyribonucleic acid (DNA) polymerase-deficient (pol⁻) mutant of this microorganism on the synthesis of DNA has been examined. Soon after infection, the incorporation of deoxyribonucleoside triphosphates into acid-insoluble material by cell lysates was greatly reduced. This inhibition of host DNA synthesis was not a result of host chromosome degradation nor did it appear to be due to the induction of thymidine triphosphate nucleotidohydrolase. Examination of the host chromosome for genetic linkage throughout the lytic cycle indicated that no extensive degradation occurred. After the inhibition of host DNA synthesis, a new polymerase activity arose which directed the synthesis of phage DNA. This new activity required deoxyribonucleoside triphosphates as substrates, Mg²⁺ ions, and a sulfhydryl reducing agent, and it was stimulated in the presence of adenosine triphosphate. The phage DNA polymerase, like that of its host, was associated with a fast-sedimenting cell membrane complex. The pol⁻ mutation had no effect on the synthesis of phage DNA or production of mature phage particles.     

Two-stage fermentation with bacteriophage lambda as an expression vector in Escherachia coli

The potential of bacteriophage lambda as an expression vector for a large scale production of cloned-gene proteins was evaluated in batch and continuous bioreactors using a temperature-sensitive mutant in the cl gene, which allows a simple manipulation of temperature as a means to control the phage in the lysogenic or lytic state. A temperature switch from 32 degrees C (or below) to 38 degrees C (or above) forces the phage to go from the lysogenic state to the lytic state. Temperature cycling and a two-reactor system were used for continuous cultures. For the latter the first reactor is maintained in the lysogenic state at a lower temperature to stably maintain the foreign DNA in the host cell, while the second reactor is maintained in the lytic state to force replication of the cloned-gene and overproduction of its products. The results are promising but suggest a greater potential for a mutant which lacks the Q gene which is responsible for host cell lysis and packaging of phage particles.     

Temperate Myxococcus xanthus phage Mx8 encodes a DNA adenine methylase, Mox.

Temperate bacteriophage Mx8 of Myxococcus xanthus encapsidates terminally repetitious DNA, packaged as circular permutations of its 49-kbp genome. During both lytic and lysogenic development, Mx8 expresses a nonessential DNA methylase, Mox, which modifies adenine residues in occurrences of XhoI and PstI recognition sites, CTCGAG and CTGCAG, respectively, on both phage DNA and the host chromosome. The mox gene is necessary for methylase activity in vivo, because an amber mutation in the mox gene abolishes activity. The mox gene is the only phage gene required for methylase activity in vivo, because ectopic expression of mox as part of the M. xanthus mglBA operon results in partial methylation of the host chromosome. The predicted amino acid sequence of Mox is related most closely to that of the methylase involved in the cell cycle control of Caulobacter crescentus. We speculate that Mox acts to protect Mx8 phage DNA against restriction upon infection of a subset of natural M. xanthus hosts. One natural isolate of M. xanthus, the lysogenic source of related phage Mx81, produces a restriction endonuclease with the cleavage specificity of endonuclease BstBI.     

The role of c3 product and anti-immunity in zygotic induction of bacteriophage lambda

Summary A nonlysogenic cell has twenty fold higher (26% versus 1.3%) probability to survive phage infection than entry of the same genome via conjugation (prophage infection). When the entering genome bears a cIII^- mutation, this difference increases to one hundred fold (6% versus 0.06%). A lysogenic im^- cell harbouring a defective prophage able to synthetize anti-immunity (product of gene tof) has ten fold higher probability to survive prophage infection than phage infection (20% versus 2%). Here, cIII^- mutation does not affect the survival. When the cell is simultaneously infected with the phage and prophage, the decision of the phage whether to enter the lytic cycle (in im^- cells) or not (in nonlysogens) is always epistatic to that of the prophage.     

Optimization of bacteriophage λQ −-containing recombinant Escherichia coli fermentation process

Q^m mutant phage 5 is deficient in the synthesis of the proteins involved in cell lysis and 5 DNA packaging. As a result, the replicated Q^m 5 DNA containing a cloned gene is not easily coated by a phage head and remains naked for the ample expression of the cloned gene, and also the host cells do not lyse easily and larger amounts of cloned gene products are produced. In a two-phase operation, the first phase is operated at a low temperature to keep the phage in the lysogenic state for cell growth and cloned gene stability, while the second phase is operated at a high temperature to induce the lytic state for the amplification of the cloned gene and overproduction of its product. This two-phase operation was optimized by determining both the optimal temperatures for the growth and production phases and the optimal switching time between the growth to the production phase. The optimal temperatures for growth and production phases were 33 and 40 °C, respectively. The optimal switching time was 3 h. The recombinant #-galactosidase production using this optimal process was about 20 times higher than in the single-copy lysogenic state.     

Why the Lysogenic State of Phage λ Is So Stable: A Mathematical Modeling Approach

We develop a mathematical model of the phage λ lysis/lysogeny switch, taking into account recent experimental evidence demonstrating enhanced cooperativity between the left and right operator regions. Model parameters are estimated from available experimental data. The model is shown to have a single stable steady state for these estimated parameter values, and this steady state corresponds to the lysogenic state. When the CI degradation rate (γ_cI) is slightly increased from its normal value (γ_cI 0.0 min⁻¹), two additional steady states appear (through a saddle-node bifurcation) in addition to the lysogenic state. One of these new steady states is stable and corresponds to the lytic state. The other steady state is an (unstable) saddle node. The coexistence these two globally stable steady states (the lytic and lysogenic states) is maintained with further increases of γ_cI until γ_cI 0.35 min⁻¹, when the lysogenic steady state and the saddle node collide and vanish (through a reverse saddle node bifurcation) leaving only the lytic state surviving. These results allow us to understand the high degree of stability of the lysogenic state because, normally, it is the only steady state. Further implications of these results for the stability of the phage λ switch are discussed, as well as possible experimental tests of the model.     

Epifluorescence and atomic force microscopy: Two innovative applications for studying phage-host interactions in Lactobacillus helveticus

Bacteriophages attacking lactic acid bacteria (LAB) still represent a crucial problem in industrial dairy fermentations. The consequences of a phage infection against LAB can lead to fermentation delay, alteration of the product quality and, in most severe cases, the product loss. Phage particles enumeration and phage-host interactions are normally evaluated by conventional plaque count assays, but, in many cases, these methods can be unsuccessful. Bacteriophages of Lactobacillus helveticus, a LAB species widely used as dairy starter or probiotic cultures, are often unable to form lysis plaques, thus impairing their enumeration by plate assay. In this study, we used epifluorescence microscopy to enumerate L. helveticus phage particles from phage-infected cultures and Atomic Force Microscopy (AFM) to visualize both phages and bacteria during the different stages of the lytic cycle. Preliminary, we tested the sensitivity of phage counting by epifluorescence microscopy. To this end, phage particles of ΦAQ113, a lytic phage of L. helveticus isolated from a whey starter culture, were stained by SYBR Green I and enumerated by epifluorescence microscopy. Values obtained by the microscopic method were 10 times higher than plate counts, with a lowest sensitivity limit of ≥ 6 log phage/ml. The interaction of phage ΦAQ113 with its host cell L. helveticus Lh1405 was imaged by AFM after 0, 2 and 5 h from phage-host adsorption. The lytic cycle was followed by epifluorescence microscopy counting and the concomitant cell wall changes were visualized by AFM imaging. Our results showed that these two methods can be combined for a reliable phage enumeration and for studying phage and host morphology during infection processes, thus giving a complete overview of phage-host interactions in L. helveticus strains involved in dairy productions.     

Interplay between the temperate phages PY54 and N15, linear plasmid prophages with covalently closed ends

The objective of this study was to determine whether the temperate Yersinia enterocolitica phage PY54 may interact with the related Escherichia coli phage N15 during both the lysogenic and the lytic cycle in the same cell. The PY54 and N15 prophages are linear plasmids which have been shown to be compatible and stably replicating in E. coli and Yersinia. In E. coli, the PY54 prophage does not restrict N15 propagation. In contrast, N15 reduces by use of its cor gene the susceptibility of Yersinia strains to PY54. Doubly lysogenic E. coli strains release PY54 virions, some of which apparently contain the N15 genome. Further experiments with replicative miniplasmid derivatives of PY54, N15, and the related Klebsiella oxytoca phage KO2 demonstrated that the KO2 and N15 plasmid prophages belong to the same incompatibility group.     

Behavior of bacteriophage Mu DNA upon infecton of Escherichia coli cells.

The question whether the ends of bacteriophage Mu DNA are fused to form a ring in host cells is critical to the understanding of the mechanism of integrative recombination between Mu DNA and host DNA. We have examined the fate of ³²P-labeled Mu DNA, after infection of sensitive and immune (lysogenic) cells, by sedimentation in sucrose gradients, ethidium bromide/CsCl density centrifugation and by electrophoresis of parental Mu DNA and its fragments in agarose gels. We find that the parental Mu DNA cannot be detected as covalently closed circles at any stage during the Mu life cycle. An interesting form of Mu DNA can be seen after superinfection of immune cells. This form sediments about twice as fast as the mature phage DNA marker in neutral sucrose gradients but yields linear molecules upon phenol extraction. Upon infection of sensitive cells, most of the parental DNA associates with a large complex, presumably containing the host chromosome. When Mu-sensitive cells are infected with unlabeled Mu particles and Mu DNA examined at different times after infection by fractionation in 0.3% agarose gels and hybridization with ³²P-labeled Mu DNA, Mu sequences are found to appear with the bulk host DNA as the phage lytic cycle progresses. However, no distinct replicative or integrative intermediate of Mu, that behaves differently from linear Mu DNA and is separate from the host DNA, can be detected.     

Quantitative analysis of the lytic cycle of WO phages infecting Wolbachia

WO is a temperate bacteriophage that infects Wolbachia, a maternally inherited endosymbiont of arthropods. WO has lysogenic and lytic cycles, the latter of which is an important process for the spread of WO infection. In this study, we measured the lytic activities of two WO phages, WOCauB2 and WOCauB3, infecting a Wolbachia strain, wCauB. In the lytic cycle of WO, both ends of the prophage are ligated to create a junction sequence called attP in the phage genome. We performed real-time quantitative polymerase chain reaction to measure the amounts of attP sequences produced by WOCauB2 and WOCauB3 in wCauB-infected Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) and wCauB-infected insect cell lines. WOCauB2 produced the phage genome more actively than WOCauB3 in E. kuehniella, whereas WOcauB3 was more active than WOCauB2 in the cell lines, suggesting that the environment of host cells in which Wolbachia is harbored affects the lytic activity of WO phages. The lytic activity was constantly very low: the amounts of attP relative to the prophages were lower than 1?×?10^?3 in all measurements, which was discussed in conjunction with the intracellular life of Wolbachia.     

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.     

Chromosomal integration mechanism of infecting mu virion DNA

DNA transposition is central to the propagation of temperate phage Mu. A long-standing problem in Mu biology has been the mechanism by which the linear genome of an infecting phage, which is linked at both ends to DNA acquired from a previous host, integrates into the new host chromosome. If Mu were to use its well-established cointegrate mechanism for integration (single-strand nicks at Mu ends, joined to a staggered double-strand break in the target), the flanking host sequences would remain linked to Mu; target-primed replication of the linear integrant would subsequently break the chromosome. The absence of evidence for chromosome breaks has led to speculation that infecting Mu might use a cut-and-paste mechanism, whereby Mu DNA is cut away from the flanking sequences prior to integration. In this study we have followed the fate of the flanking DNA during the time course of Mu infection. We have found that these sequences are still attached to Mu upon integration and that they disappear soon after. The data rule out a cut-and-paste mechanism and suggest that infecting Mu integrates to generate simple insertions by a variation of its established cointegrate mechanism in which, instead of a "nick, join, and replicate" pathway, it follows a "nick, join, and process" pathway. The results show similarities with human immunodeficiency virus integration and provide a unifying mechanism for development of Mu along either the lysogenic or lytic pathway.     

A Novel Vibriophage vB＿VcaS＿HC Containing Lysogeny-Related Gene Has Strong Lytic Ability against Pathogenic Bacteria

To avoid the negative effects of antibiotics, using phage to prevent animal disease becomes a promising method in aquaculture. Here, a lytic phage provisionally named v B＿VcaS＿HC that can infect the pathogen(i.e., Vibrio campbellii 18)of prawn was isolated. The phage has an isometric head and a non-contractile tail. During phage infection, the induced host mortality in 5.5 h reached ca. 96%, with a latent period of 1.5 h and a burst size of 172 PFU/cell. It has an 81,566 bp circular dsDNA genome containing 121 open reading frames(ORFs), and ca. 71% of the ORFs are functionally unknown.Comparative genomic and phylogenetic analysis revealed that it is a novel phage belonging to Delepquintavirus,Siphoviridae, Caudovirales. In the phage genome, besides the ordinary genes related to structure assembly and DNA metabolism, there are 10 auxiliary metabolic genes. For the first time, the pyruvate phosphate dikinase(PPDK) gene was found in phages whose product is a key rate-limiting enzyme involving Embden-Meyerhof-Parnas(EMP) reaction.Interestingly, although the phage has a strong bactericidal activity and contains a potential lysogeny related gene, i.e., the recombinase(RecA) gene, we did not find the phage turned into a lysogenic state. Meanwhile, the phage genome does not contain any bacterial virulence gene or antimicrobial resistance gene. This study represents the first comprehensive characterization of a lytic V. campbellii phage and indicates that it is a promising candidate for the treatment of V.campbellii infections.     

Genomic and Gene-Expression Comparisons among Phage-Resistant Type-IV Pilus Mutants of Pseudomonas syringae pathovar phaseolicola

Pseudomonas syringae pv. phaseolicola (Pph) is a significant bacterial pathogen of agricultural crops, and phage Φ6 and other members of the dsRNA virus family Cystoviridae undergo lytic (virulent) infection of Pph, using the type IV pilus as the initial site of cellular attachment. Despite the popularity of Pph/phage Φ6 as a model system in evolutionary biology, Pph resistance to phage Φ6 remains poorly characterized. To investigate differences between phage Φ6 resistant Pph strains, we examined genomic and gene expression variation among three bacterial genotypes that differ in the number of type IV pili expressed per cell: ordinary (wild-type), non-piliated, and super-piliated. Genome sequencing of non-piliated and super-piliated Pph identified few mutations that separate these genotypes from wild type Pph–and none present in genes known to be directly involved in type IV pilus expression. Expression analysis revealed that 81.1% of gene ontology (GO) terms up-regulated in the non-piliated strain were down-regulated in the super-piliated strain. This differential expression is particularly prevalent in genes associated with respiration—specifically genes in the tricarboxylic acid cycle (TCA) cycle, aerobic respiration, and acetyl-CoA metabolism. The expression patterns of the TCA pathway appear to be generally up and down-regulated, in non-piliated and super-piliated Pph respectively. As pilus retraction is mediated by an ATP motor, loss of retraction ability might lead to a lower energy draw on the bacterial cell, leading to a different energy balance than wild type. The lower metabolic rate of the super-piliated strain is potentially a result of its loss of ability to retract.