Coevolution of bacteria and their viruses

Coevolution between bacteria and bacteriophages can be characterized as an infinitive constant evolutionary battle (phage-host arm race), which starts during phage adsorption and penetration into host cell, continues during phage replication inside the cells, and remains preserved also during prophage lysogeny. Bacteriophage may exist inside the bacterial cells in four forms with different evolutionary strategies: as a replicating virus during the lytic cycle, in an unstable carrier state termed pseudolysogeny, as a prophage with complete genome during the lysogeny, or as a defective cryptic prophage. Some defensive mechanisms of bacteria and virus countermeasures are characterized, and some evolutionary questions concerning phage–host relationship are discussed.     

Bacteriophage Resistance Plasmid pTR2030 Inhibits Lytic Infection of r(1)t Temperate Bacteriophage but Not Induction of r(1)t 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 r(1)t, 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 r(1)t. Strain R1Cs and a derivative of this strain that was relysogenized with r(1)t, designated R1Cs(r(1)t), were used as conjugal recipients for transfer of the phage resistance plasmid pTR2030. pTR2030 transconjugants of strains R1Cs and R1Cs(r(1)t) were evaluated for sensitivity to r(1)t phage and induction of r(1)t prophage, respectively. The temperate phage r(1)t adsorbed eficiently but did not form plaques on the prophage-cured, pTR2030 transconjugant strain T-R1Cs. However, in the r(1)t lysogen [T-R1Cs(r(1)t)], pTR2030 did not inhibit prophage induction with mitomycin C, cell lysis, or production of infective r(1)t phage particles. The data demonstrated that pTR2030-induced resistance inhibited lytic infection by r(1)t 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.     

Recruitment of host ATP-dependent proteases by bacteriophage lambda

Upon infection of a bacterial cell, the temperate bacteriophage lambda executes a regulated temporal program with two possible outcomes: (1) Cell lysis and virion production or (2) establishment of a dormant state, lysogeny, in which the phage genome (prophage) is integrated into the host chromosome. The prophage is replicated passively as part of the host chromosome until it is induced to resume the lytic cycle. In this review, we summarize the evidence that implicates every known ATP-dependent protease in the regulation of specific steps in the phage life cycle. The proteolysis of specific regulatory proteins appears to fine-tune phage gene expression. The bacteriophage utilizes multiple proteases to irreversibly inactivate specific regulators resulting in a temporally regulated program of gene expression. Evolutionary forces may have favored the utilization of overlapping protease specificities for differential proteolysis of phage regulators according to different phage life styles.     

Genome analysis of the obligately lytic bacteriophage 4268 of Lactococcus lactis provides insight into its adaptable nature

Analysis of the complete nucleotide sequence of the lactococcal phage 4268, which is lytic for the cheese starter Lactococcus lactis DPC4268, is presented. Phage 4268 has a linear genome of 36,596 bp, which is modularly organised and encompasses 49 open reading frames. Putative functions were assigned to approximately 45% of the predicted products of these open reading frames based on sequence similarity with known proteins, N-terminal sequence analysis and identification of conserved domains. Significantly, a segment of the genome has homology to the recently sequenced lysogenic module in lactococcal phage phi31 that contains a lytic switch but no phage integrase or attachment site. This suggests that it is derived from a prophage. A phage 4268-encoded and a host-encoded methylase were found to be highly similar, having only two nucleotide mismatches, suggesting that the phage acquired the methylase gene to protect it from a host endonuclease. Comparative genomic analysis revealed significant homology between phage 4268 and the lactococcal phage BK5-T. The comparative analysis also supported the classification of phage 4268 and other BK5-T-related phage as separate from the proposed P335 species of lactococcal phage.     

An extrachromosomal prophage naturally associated with Bacillus thuringiensis serovar israelensis

Bacillus thuringiensis serovar israelensis , an entomopathogen for mosquito larvae, was demonstrated to be lysogenized by temperate phage SU-11 whose genome was located extrachromosomally in the cell. The prophage SU-11 was cured at high frequency from the parental strain by continuous sub-culture at high temperature, but the ability to produce δ-endotoxin remained in the prophage cured strain. Moreover, phage induction was found to occur after mating of serovar israelensis with its prophage cured strain, as well as with B. thuringiensis serovar thuringiensis , B. cereus and B. subtilis .     

Genome-Based Identification of Active Prophage Regions by Next Generation Sequencing in Bacillus licheniformis DSM13

Prophages are viruses, which have integrated their genomes into the genome of a bacterial host. The status of the prophage genome can vary from fully intact with the potential to form infective particles to a remnant state where only a few phage genes persist. Prophages have impact on the properties of their host and are therefore of great interest for genomic research and strain design. Here we present a genome- and next generation sequencing (NGS)-based approach for identification and activity evaluation of prophage regions. Seven prophage or prophage-like regions were identified in the genome of Bacillus licheniformis DSM13. Six of these regions show similarity to members of the Siphoviridae phage family. The remaining region encodes the B. licheniformis orthologue of the PBSX prophage from Bacillus subtilis. Analysis of isolated phage particles (induced by mitomycin C) from the wild-type strain and prophage deletion mutant strains revealed activity of the prophage regions BLi_Pp2 (PBSX-like), BLi_Pp3 and BLi_Pp6. In contrast to BLi_Pp2 and BLi_Pp3, neither phage DNA nor phage particles of BLi_Pp6 could be visualized. However, the ability of prophage BLi_Pp6 to generate particles could be confirmed by sequencing of particle-protected DNA mapping to prophage locus BLi_Pp6. The introduced NGS-based approach allows the investigation of prophage regions and their ability to form particles. Our results show that this approach increases the sensitivity of prophage activity analysis and can complement more conventional approaches such as transmission electron microscopy (TEM).     

'Ca. Liberibacter asiaticus' carries an excision plasmid prophage and a chromosomally integrated prophage that becomes lytic in plant infections

Huanglongbing (HLB), also known as citrus greening, is a lethal disease of citrus caused by several species of 'Candidatus Liberibacter', a psyllid-transmitted, phloem-limited, alpha proteobacteria. 'Ca. Liberibacter asiaticus' is widespread in Florida citrus. The recently published 'Ca. L. asiaticus' psy62 genome, derived from a psyllid, revealed a prophage-like region of DNA in the genome, but phage have not been associated with 'Ca. L. asiaticus' to date. In the present study, shotgun sequencing and a fosmid DNA library of curated 'Ca. L. asiaticus' UF506, originally derived from citrus symptomatic for HLB, revealed two largely homologous, circular phage genomes, SC1 and SC2. SC2 encoded putative adhesin and peroxidase genes that had not previously been identified in 'Ca. L. asiaticus' and which may be involved in lysogenic conversion. SC2 also appeared to lack lytic cycle genes and replicated as a prophage excision plasmid, in addition to being found integrated in tandem with SC1 in the UF506 chromosome. By contrast, SC1 carried suspected lytic cycle genes and was found in nonintegrated, lytic cycle forms only in planta. Phage particles associated with 'Ca. L. asiaticus' were found in the phloem of infected periwinkles by transmission electron microscopy. In psyllids, both SC1 and SC2 were found only as prophage.     

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.     

Evolution of a Lytic Bacteriophage via DNA Acquisition from the Lactococcus lactis Chromosome

We discovered a phage-host interaction in which the lytic phage ul36, in response to pressure exerted by an abortive phage resistance mechanism, acquired a large DNA fragment from the chromosome of Lactococcus lactis NCK203 to form a new phage, ul37. Phage ul37 was characterized at morphological, phenotypic, and genotypic levels and was found to be a member of the P335 species. Although it exhibits a high level of DNA homology with ul36, phage ul37 is resistant to the abortive mechanism and has a longer tail, a different base plate, and apparently a different origin of replication. The chromosomal DNA implicated in the formation of new phage ul37 was disrupted by site-specific integration in NCK203. This strategy prevented the appearance of ul37 during subsequent infections with ul36.     

Chaperone-assisted excisive recombination, a solitary role for DnaJ (Hsp40) chaperone in lysogeny escape

Temperate bacteriophage lytic development is intrinsically related to the stress response in particular at the DNA replication and virion maturation steps. Alternatively, temperate phages become lysogenic and integrate their genome into the host chromosome. Under stressful conditions, the prophage resumes a lytic development program, and the phage DNA is excised before being replicated. The KplE1 defective prophage of Escherichia coli K12 constitutes a model system because it is fully competent for integrative as well as excisive recombination and presents an atypical recombination module, which is conserved in various phage genomes. In this work, we identified the host-encoded stress-responsive molecular chaperone DnaJ (Hsp40) as an active participant in KplE1 prophage excision. We first show that the recombination directionality factor TorI of KplE1 specifically interacts with DnaJ. In addition, we found that DnaJ dramatically enhances both TorI binding to its DNA target and excisive recombination in vitro. Remarkably, such stimulatory effect by DnaJ was performed independently of its DnaK chaperone partner and did not require a functional DnaJ J-domain. Taken together, our results underline a novel and unsuspected functional interaction between the generic host stress-regulated chaperone and temperate bacteriophage lysogenic development.     

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.     

Role of the ø11 Phage Genome in Competence of Staphylococcus aureus

Both phage ?11 and 83A, when present as prophage or when used as helper phage, induce competence for transfection and transformation to the same level in Staphylococcus aureus, strain 8325-4. Cells lysogenized with certain temperature-sensitive (ts) mutants of phage ?11 show competence at the nonpermissive temperature (41 C) without production of infectious phages. Phage ?11ts allele 31 can neither as a prophage nor as a helper phage develop competence under nonpermissive conditions. This mutant appears, therefore, to be mutated in the region of the phage genome controlling competence. The competence level for both transfection and transformation is increased by superinfecting strain 8325-4 (?11) or 8325-4 (83A) at high multiplicities with phage ?11 with some of its mutants or with phage 83A. This superinfection enhancement appears to require protein synthesis but not deoxyribonucleic acid synthesis as judged from studies with inhibitors of macromolecular synthesis. Besides the phage particle, no extracellular or cell-bound factors so far detected can induce competence. The phage-induced product conferring competence is rapidly synthesized by strain 8325-4 (ts?11(31)) after shift to permissive conditions, but requires deoxyribonucleic acid and protein synthesis to be expressed. Recombination between the sus mutants of phage ?11 of Kretschmer and Egan and ts?11(31) indicate that competence is controlled by an early gene in the lytic cycle which may be expressed also in lysogenic cells. The phage product inducing competence appears to have a half-life of 10 to 15 min in the conditional lethal mutant at shift to nonpermissive temperature. Ultraviolet inactivation of phage ?11 infectivity occurs more rapidly than inactivation of competence induction. In fact, the number of transformants is increased at low doses of irradiation. Competence induction is, however, decreased at high does of ultraviolet irradiation.     

Isolation, characterization and mapping of the N15 phasmid insertion mutations]

Prophage of N15 temperate bacteriophage is stably maintained in Escherichia coli lysogens as a 46.33 kb linear plasmid. Using different transposons we obtained 18 insertion mutants of the N15 plasmid prophage. They were analysed for plaque formation ability, stability of the plasmid state and lysogenic conversion. Restriction mapping of the insertions allowed us to localize on the map the regions necessary for lytic growth and to map the lysogenic conversion gene. A recombinant phage encoding two antibiotic resistance genes was obtained. The phage contains an additional 4.77 kb DNA fragment (over 10% of the N15 genome).     

Contribution of mobile genetic elements to Desulfovibrio vulgaris genome plasticity

The genome of Desulfovibrio vulgaris strain DePue, a sulfate-reducing Deltaproteobacterium isolated from heavy metal-impacted lake sediment, was completely sequenced and compared with the type strain D. vulgaris Hildenborough. The two genomes share a high degree of relatedness and synteny, but harbour distinct prophage and signatures of past phage encounters. In addition to a highly variable phage contribution, the genome of strain DePue contains a cluster of open-reading frames not found in strain Hildenborough coding for the production and export of a capsule exopolysaccharide, possibly of relevance to heavy metal resistance. Comparative whole-genome microarray analysis on four additional D. vulgaris strains established greater interstrain variation within regions associated with phage insertion and exopolysaccharide biosynthesis.     

The antirepressor needed for induction of linear plasmid-prophage N15 belongs to the SOS regulon

The physiological conditions and molecular interactions that control phage production have been studied in only a few families of temperate phages. We investigated the mechanisms that regulate activation of lytic development in lysogens of coliphage N15, a prophage that is not integrated into the host chromosome but exists as a linear plasmid with covalently closed ends. We identified the N15 antirepressor gene, antC, and showed that its product binds to and acts against the main phage repressor, CB. LexA binds to and represses the promoter of antC. Mitomycin C-stimulated N15 induction required RecA-dependent autocleavage of LexA and expression of AntC protein. Thus, a cellular repressor whose activity is regulated by DNA damage controls N15 prophage induction.     

Lysis to Kill: Evaluation of the Lytic Abilities,and Genomics of Nine Bacteriophages Infective for Gordonia spp. and Their Potential Use in Activated Sludge Foam Biocontrol

Nine bacteriophages (phages) infective for members of the genus Gordonia were isolated from wastewater and other natural water environments using standard enrichment techniques. The majority were broad host range phages targeting more than one Gordonia species. When their genomes were sequenced, they all emerged as double stranded DNA Siphoviridae phages, ranging from 17,562 to 103,424 bp in size, and containing between 27 and 127 genes, many of which were detailed for the first time. Many of these phage genomes diverged from the expected modular genome architecture of other characterized Siphoviridae phages and contained unusual lysis gene arrangements. Whole genome sequencing also revealed that infection with lytic phages does not appear to prevent spontaneous prophage induction in Gordonia malaquae lysogen strain BEN700. TEM sample preparation techniques were developed to view both attachment and replication stages of phage infection.     

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).