Mechanism of Haemophilus influenzae transfection by single and double prophage deoxyribonucleic acid.

Whole phages HP1 and HP3, vegetative-phage deoxyribonucleic acid (DNA), and single and tandem double prophage DNA were exposed to ultraviolet radiation and then assayed on a wild-type (DNA repair-proficient) Haemophilus influenzae Rd strain and on a repair-deficient uvr-1 strain. Host cell reactivation (DNA repair) was observed for whole-phage and vegetative-phage DNA but not for single and double prophage DNA. Competent (phage-resistant) Haemophilus parainfluenzae cells were normally transfected with H. influenzae-grown phage DNA and with tandem double prophage DNA but not at all with single prophage DNA. CaCl2-treated H. influenzae suspensions could be transfected with vegetative phage DNA and with double prophage DNA but not with single prophage DNA. These observations support the hypothesis that transfection with single prophage DNA occurs through prophage DNA single-strand insertion into the recipient chromosome (at the bacterial att site) followed by DNA replication and then prophage induction.     

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).     

Ant-mediated inactivation of Salmonella phage L-specified repression at OR of prophage L.

Summary Ant product of phage P22 inactivates repression of prophage L at the right-hand operator o_R and allows for transactivation of prophage gene 12. The transactivation efficiency observed with a series of phage and prophage recombinants, using single superinfection of a lysogenic bacterium, is about the same as that recently observed at o_L of prophage L. This finding is in contrast to the failure to demonstrate derepression at o_R of prophage L in an experimental system employing double superinfection (Prell, 1978a). The reasons for the differing results are discussed and it is shown that derepression by the ant product in trans at o_R of the prophage is not modified to any significant degree by the immunity specificity (L or P22) of the prophage or of the superinfecting phage.     

Prophage induction and inactivation by UV light.

Analysis of the induction curves for UV light-irradiated Haemophilus influenzae lysogens and the distribution of pyrimidine dimers in a repair-deficient lysogen suggests that one dimer per prophage-size segment of the host bacterial chromosome is necessary as a preinduction event. The close correlations obtained prompted a renewed consideration of the possibility that direct prophage induction occurs when one dimer is stabilized within the prophage genome. The host excision-repair system apparently functions to reduce the probability of "stabilizing" within the prophage those dimers that are necessary for induction and inactivation. The presence of the inducible defective prophage in strain Rd depresses the inducibility of prophage HP1c1.     

Prophage induction by DNA topoisomerase II poisons and reactive-oxygen species: role of DNA breaks.

Various compounds were evaluated for their ability to induce prophage lambda in the Escherichia coli WP2s(lambda) microscreen assay. The inability of a DNA gyrase subunit B inhibitor (novobiocin) to induce prophage indicated that inhibition of the gyrase's ATPase was insufficient to elicit the SOS response. In contrast, poisons of DNA gyrase subunit A (nalidixic acid and oxolinic acid) were the most potent inducers of prophage among the agents examined here. This suggested that inhibition of the ligation function of subunit A, which also has a DNA nicking activity, likely resulted in DNA breaks that were available (as single-stranded DNA) to act as strong SOS-inducing signals, leading to prophage induction. Agents that both intercalated and produced reactive-oxygen species (the mammalian DNA topoisomerase II poisons, adriamycin, ellipticine, and m-AMSA) were the next most potent inducers of prophage. Agents that produced reactive-oxygen species only (hydrogen peroxide and paraquat) were less potent than adriamycin and ellipticine but more potent than m-AMSA. Agents that intercalated but did not generate reactive-oxygen species (actinomycin D) or that did neither (teniposide) were unable to induce prophage, suggesting that intercalation alone may be insufficient to induce prophage. These results illustrate the variety of mechanisms (and the relative effectiveness of these mechanisms) by which agents can induce prophage. Nonetheless, these agents may induce prophage by producing essentially the same type of DNA damage, i.e., DNA strand breaks. The potent genotoxicity of the DNA gyrase subunit A poisons illustrates the genotoxic consequences of perturbing an important DNA-protein complex such as that formed by DNA and DNA topoisomerase.     

Heat sensitivity of Haemophilus influenzae containing defective prophage.

Strains of Haemophilus influenzae that carry a defective prophage are more sensitive to heat than is a strain that does not, even in the presence of a rec-1 mutation, which normally renders prophage noninducible. The prophage of HP1c1, a nondefective phage, does not affect the heat sensitivity.     

Diversity of prophage DNA regions of Streptococcus agalactiae clonal lineages from adults and neonates with invasive infectious disease

The phylogenetic position and prophage DNA content of the genomes of 142 S. agalactiae (group-B streptococcus, GBS) isolates responsible for bacteremia and meningitis in adults and neonates were studied and compared. The distribution of the invasive isolates between the various serotypes, sequence types (STs) and clonal complexes (CCs) differed significantly between adult and neonatal isolates. Use of the neighbor-net algorithm with the PHI test revealed evidence for recombination in the population studied (PHI, P = 2.01 × 10(-6)), and the recombination-mutation ratio (R/M) was 6:7. Nevertheless, the estimated R/M ratio differed between CCs. Analysis of the prophage DNA regions of the genomes of the isolates assigned 90% of the isolates to five major prophage DNA groups: A to E. The mean number of prophage DNA fragments amplified per isolate varied from 2.6 for the isolates of prophage DNA group E to 4.0 for the isolates of prophage DNA group C. The isolates from adults and neonates with invasive diseases were distributed differently between the various prophage DNA groups (P < 0.00001). Group C prophage DNA fragments were found in 52% of adult invasive isolates, whereas 74% of neonatal invasive isolates had prophage DNA fragments of groups A and B. Differences in prophage DNA content were also found between serotypes, STs and CCs (P < 0.00001). All the ST-1 and CC1 isolates, mostly of serotype V, belonged to the prophage DNA group C, whereas 84% of the ST-17 and CC17 isolates, all of serotype III, belonged to prophage DNA groups A and B. These data indicate that the transduction mechanisms, i.e., gene transfer from one bacterium to another by a bacteriophage, underlying genetic recombination in S. agalactiae species, are specific to each intraspecies lineage and population of strains responsible for invasive diseases in adults and neonates.     

Inactivation of prophage in ultraviolet-irradiated Escherichia coli: dependence on recA gene activity.

The fate of the prophage part of the lysogenic chromosome was followed in the course of post-ultraviolet incubation. For this purpose, lambda cI857 ind prophage, which can be induced by heat but not by ultraviolet light, was used. The prophage, intially more resistant than its repair-proficient host cell, was rapidly inactivated. This inactivation was not caused by the impaired capacity of irradiated cells to support growth of the phage. Over the entire dose range tested, little, if any, sensitivity difference between the host and the prophage was found at the end of cell division delay. Rapid inactivation of the prophage was also observed in uvr cells after small doses of ultraviolet light. The same small doses did not cause inactivation in lysogens carrying a mutation in the gene recA. This suggests that the functional gene recA is required for inactivation of the prophage part of the lysogenic chromosome.     

Early events in the replication of Mu prophage DNA.

To determine whether the early replication of Mu prophage DNA proceeds beyond the termini of the prophage into hose DNA, the amounts of both Mu DNA and the prophage-adjacent host DNA sequences were measured using a DNA-DNA annealing assay after induction of the Mu vegetative cycle. Whereas Mu-specific DNA synthesis began 6 to 8 min after induction, no amplification of the adjacent DNA sequences was observed. These data suggest that early Mu-induced DNA synthesis is constrained within the boundaries of the Mu prophage. Since prophage Mu DNA does not undergo a prophage lambda-like excision from its original site after induction (E. Ljungquist and A. I. Bukhari, Proc. Natl. Acad. Sci. U.S.A. 74:3143--3147, 1977), we propose the existence of a control mechanism which excludes prophage-adjacent sequences from the initial mu prophage replication. The frequencies of the Mu prophage-adjacent DNA sequences, relative to other Escherichia coli genes, were not observed to change after the onset of Mu-specific DNA replication. This suggests that these regions remain associated with the host chromosome and continue to be replicated by the chromosomal replication fork. Therefore, we conclude that both the Mu prophage and adjacent host sequences are maintained in the host chromosome, rather than on an extrachromosomal form containing Mu and host DNA.     

Preferred secondary attachment site of prophage phi80 on Escherichia coli K-12 chromosome]

The integration frequency of phage att80 immlambdac1857 into the chromosome of a mutant strain H47 Escherichia coli K-12 deleted for the normal prophage insertion site is found to be about 20-fold decreased as compared with its integration into the wild type strain. The most of the resulting lysogens contain the prophage at the secondary attachment site of the mutant bacterial chromosome which is preferentially utilized for prophage insertion. This attachment site (att80-II) is located close to his-genes on the chromosome of H47 strain. Prophage curing procedure of such abnormal lysogens results in the appearance of rare auxotrophic heat-resistant survivors with the His- phenotype. In some cases the prophage insertion can induce an inversion of a neighbouring genetic region. Such lysogens contain the purC gene near prophage located at the att80-II site, and after curing they segregate the heat-resistant His- and Pur- colonies.     

Physical study of prophage excision and curing of lambda prophage from lysogenic Escherichia coli

A sex factor, F′450(λ), which can be isolated as a covalent circle of DNA, has been examined by alkaline sucrose gradient centrifugation of lysates of induced cells in order to study λ prophage excision. Thermal derepression of the prophage results in loss of F′450(λ) covalent circles, which is mediated by systems involved in excision and initiation of replication. When protocols known to result in prophage curing are used, the F′450(λ) is converted to an F′450 and a λ covalent circle; in normal excision leading to phage development, F′450 covalent circles are not found. We have shown that: (1) excision usually occurs later than initiation of DNA replication of the prophage so that the excised prophage is usually already replicated or in the act of replication; (2) the DNA growing points of the prophage leave the prophage and enter the bacterial DNA; (3) the int and xis genes are involved in the earliest detectable stage of the excision process, i.e. breakage of the DNA at the attachment region; (4) the xis gene product is involved in a weak non-specific nuclease activity in addition to its highly specific activity in excision; and (5) the excision system fails to attack a single attachment site.     

Efficiency of induction of prophage lambda mutants as a function of recA alleles.

Mutants of the cI gene of prophage lambda have been defined phenotypically in a recA+ host as noninducible (Ind-), inducible (Ind+), or induction sensitive (Inds). We showed that a phage lambda cI+ carrying operator mutations v2 and v3 displays an Inds phenotype, as does lambda cI inds-1. We characterized a fourth induction phenotype called induction resistant (Indr). Using these four prophage types, we tested the influence of bacterial recA mutations on prophage induction. Indr prophages were fully induced in recA441 bacteria whose RecA441 protein is activated constitutively. Indr prophages were not induced in a mutant overproducing RecA+ protein, confirming that RecA+ protein must be activated to promote prophage induction. Inds prophages were induced in recA142 and recA453-441 lysogens, previously described as deficient in prophage induction.     

Lambda excision revisited: testing a model for synapsis of prophage ends

Excision of lambda prophage was reexamined to test a model for prophage end synapsis. The model proposes that, during in situ prophage replication, following induction, the diverging replication forks are held together. Consequently, prophage DNA is spooled through the replication machinery, drawing the prophage ends together and facilitating synapsis. The model predicts that excision will be slowed if in situ lambda replication is inhibited, and the predicted low rate of excision of a nonreplicating prophage was observed after thermoinduction. However, excision was rapid if additional Int protein was supplied or if the temperature was reduced after induction, showing that (i) Int is partially thermosensitive for excision at 42 degrees C and (ii) in situ replication is not required for rapid excision, a finding that is inconsistent with the model.     

ArgR and PepA, accessory proteins for XerCD-mediated resolution of ColE1 dimers, are also required for stable maintenance of the P1 prophage

Dimers of low copy number plasmids must be resolved to monomers to prevent interference with active partition. For the P1 prophage this is achieved by the Cre site-specific recombinase acting at lox. Multimerisation of multicopy plasmids threatens stability via copy number depression, and multimers of ColE1 are resolved by XerCD-mediated recombination at cer. Xer-cer is constrained to multimer resolution by accessory proteins ArgR and PepA. Recently, it has been shown that ArgR and PepA influence Cre-mediated recombination at a cer-lox hybrid site in vitro, defining the structure of the synaptic complex. We show here that both ArgR and PepA are required for stable maintenance of the P1 prophage. It is extremely difficult to establish P1 in a strain lacking PepA and the prophage was lost rapidly once selection was removed. ArgR plays a less crucial role although its absence significantly increased prophage loss. The effect of the accessory proteins is seen only at physiological concentrations of Cre; when the recombinase is expressed from a multicopy plasmid, the prophage is unstable even in the presence of ArgR and PepA. We propose that ArgR and PepA are involved in Cre-lox recombination in vivo, probably by constraining the system to resolution of prophage dimers.     

Replication in situ and DNA encapsulation following induction of an excision-defective lysogen of Salmonella bacteriophage P22.

The induction of an excision-defective bacteriophage P22 lysogen results in the production of particles which carry a DNA molecule of normal length within a normal capsid, but which are nonetheless defective. The DNA content of these particles was characterized physically by a restriction enzyme analysis, and genetically by two marker rescue techniques. The particles carry DNA corresponding to one side of the prophage map as well as additional DNA, apparently derived from the host chromosome to one side of the prophage insertion site. Normally, mature P22 DNA molecules are derived from a concatemer by sequential cleavage of adjacent headful lengths, beginning at a genetically unique site, the encapsulation origin (Tye et al., 1974). The defective particles appear to contain DNA matured by the same sequential mechanisms, operating on the integrated prophage and neighboring bacterial chromosome, rather than on the normal concatemeric substrate. Both the initiation and directional specificities of normal maturation are maintained during the maturation of defective particle DNA. Sequential cleavage begins within the prophage at the encapsulation origin, a site near gene 3, and proceeds into the host chromosome on the proC side of the prophage. The initiation specificity of DNA encapsulation seems to reside in the morphogenetic machinery, rather than in the mechanism of DNA replication. Replication of an induced excision-defective prophage takes place in situ on the host chromosome, apparently without disruption of the linear integrity of the prophage. Further, the entire prophage, as well as adjacent bacterial DNA, is replicated, even though only a portion of this DNA is destined to be encapsulated.     

DNA Sequence Heterogeneity of Campylobacter jejuni CJIE4 Prophages and Expression of Prophage Genes

Campylobacter jejuni carry temperate bacteriophages that can affect the biology or virulence of the host bacterium. Known effects include genomic rearrangements and resistance to DNA transformation. C. jejuni prophage CJIE1 shows sequence variability and variability in the content of morons. Homologs of the CJIE1 prophage enhance both adherence and invasion to cells in culture and increase the expression of a specific subset of bacterial genes. Other C. jejuni temperate phages have so far not been well characterized. In this study we describe investigations into the DNA sequence variability and protein expression in a second prophage, CJIE4. CJIE4 sequences were obtained de novo from DNA sequencing of five C. jejuni isolates, as well as from whole genome sequences submitted to GenBank by other research groups. These CJIE4 DNA sequences were heterogenous, with several different insertions/deletions (indels) in different parts of the prophage genome. Two variants of a 3–4 kb region inserted within CJIE4 had different gene content that distinguished two major conserved CJIE4 prophage families. Additional indels were detected throughout the prophage. Detection of proteins in the five isolates characterized in our laboratory in isobaric Tags for Relative and Absolute Quantitation (iTRAQ) experiments indicated that prophage proteins within each of the two large indel variants were expressed during growth of the bacteria on Mueller Hinton agar plates. These proteins included the extracellular DNase associated with resistance to DNA transformation and prophage repressor proteins. Other proteins associated with known or suspected roles in prophage biology were also expressed from CJIE4, including capsid protein, the phage integrase, and MazF, a type II toxin-antitoxin system protein. Together with the results previously obtained for the CJIE1 prophage these results demonstrate that sequence variability and expression of moron genes are both general properties of temperate bacteriophages in C. jejuni.     

Small chromosomal integration site of classical CTX prophage in Mozambique <Emphasis Type="Italic">Vibrio cholerae</Emphasis> O1 biotype El Tor strain

An unusual strain of Vibrio cholerae O1 biotype El Tor harbouring multiple tandem copies of classical CTX prophage caused a cholera epidemic in Mozambique in 2004. However, the location of the classical CTX prophage in the genome of the Mozambique strain was unknown. In this study, pulsed field gel electrophoresis (PFGE) of the whole genome along with Southern hybridization experiments indicated that the classical CTX prophage present in the Mozambique strain is located in the small chromosome. To determine the CTX prophage integration site in the small chromosome of Mozambique strain, the 5'and 3' junctions of the prophage and small chromosome were PCR amplified, cloned and sequenced. Sequence analysis indicated that the prophage was integrated in the conserved dif site of the replication terminus region of the Mozambique strain. While using an O1 El Tor isolate VC44 as a control strain, which carries tandem copies of CTX prophage in its small chromosome like the Mozambique strain, it was unexpectedly detected that the strain VC44 also possesses classical cholera toxin B gene allele. Since the strain VC44 was isolated in India in the year 1992, it appears that the Mozambique strain has probably originated from a VC44-like strain.     

The modifying effect of glycerine and cysteamine on prophage lambda induction in E. coli cells under gamma irradiation

In studying the modifying influence of glycerol and cysteamine of gamma radiation induction of lambda prophage it was shown that dose curves for lambda prophage induced upon irradiation in normal conditions and in the presence of glycerol are those with a maximum. In the presence of cysteamine, the prophage induction is inhibited significantly.     

Prophage lambda induces terminal recombination in Escherichia coli by inhibiting chromosome dimer resolution. An orientation-dependent cis-effect lending support to bipolarization of the terminus

A prophage lambda inserted by homologous recombination near dif, the chromosome dimer resolution site of Escherichia coli, is excised at a frequency that depends on its orientation with respect to dif. In wild-type cells, terminal hyper- (TH) recombination is prophage specific and undetectable by a test involving deletion of chromosomal segments between repeats identical to those used for prophage insertion. TH recombination is, however, detected in both excision and deletion assays when Deltadif, xerC, or ftsK mutations inhibit dimer resolution: lack of specialized resolution apparently results in recombinogenic lesions near dif. We also observed that the presence near dif of the prophage, in the orientation causing TH recombination, inhibits dif resolution activity. By its recombinogenic effect, this inhibition explains the enhanced prophage excision in wild-type cells. The primary effect of the prophage is probably an alteration of the dimer resolution regional control, which requires that dif is flanked by suitably oriented (polarized) stretches of DNA. Our model postulates that the prophage inserted near dif in the deleterious orientation disturbs chromosome polarization on the side of the site where it is integrated, because lambda DNA, like the chromosome, is polarized by sequence elements. Candidate sequences are oligomers that display skewed distributions on each oriC-dif chromosome arm and on lambda DNA.