Molecular basis for the exploitation of spore formation as survival mechanism by virulent phage phi29

Phage phi29 is a virulent phage of Bacillus subtilis with no known lysogenic cycle. Indeed, lysis occurs rapidly following infection of vegetative cells. Here, we show that phi29 possesses a powerful strategy that enables it to adapt its infection strategy to the physiological conditions of the infected host to optimize its survival and proliferation. Thus, the lytic cycle is suppressed when the infected cell has initiated the process of sporulation and the infecting phage genome is directed into the highly resistant spore to remain dormant until germination of the spore. We have also identified two host-encoded factors that are key players in this adaptive infection strategy. We present evidence that chromosome segregation protein Spo0J is involved in spore entrapment of the infected phi29 genome. In addition, we demonstrate that Spo0A, the master regulator for initiation of sporulation, suppresses phi29 development by repressing the main early phi29 promoters via different and novel mechanisms and also by preventing activation of the single late phi29 promoter.     

Molecular Phylogeny of φ29-Like Phages and Their Evolutionary Relatedness to Other Protein-Primed Replicating Phages and Other Phages Hosted by Gram-Positive Bacteria

The φ29-like phage genus of Podoviridae family contains phages B103, BS32, GA-1, M2, Nf, φ15, φ29, and PZA that all infect Bacillus subtilis. They have very similar morphology and their genomes consist of linear double-stranded DNA of approximately 20 kb. The nucleotide sequences of individual genomes or their parts determined thus far show that these phages evolved from a common ancestor. A terminal protein (TP) that is covalently bound to the DNA 5′-end primes DNA replication of these phages. The same mechanism of DNA replication is used by the Cp-1 related phages (also members of the Podoviridae family) and by the phage PRD1 (member of the Tectoviridae family). Based on the complete or partial genomic sequence data of these phages it was possible to analyze the evolutionary relationship within the φ29-like phage genus as well as to other protein-primed replicating phages. Noncoding regions containing origins of replication were used in the analysis, as well as amino acid sequences of DNA polymerases, and with the φ29-like phages also amino acid sequences of the terminal proteins and of the gene 17 protein product, an accessory component of bacteriophage DNA replicating machinery. Included in the analysis are also results of a comparison of these phage DNAs with the prophages present in the Bacillus subtilis genome. Based on this complex analysis we define and describe in more detail the evolutionary branches of φ29-like phages, one branch consisting of phages BS32, φ15, φ29, and PZA, the second branch composed of phages B103, M2, and Nf, and the third branch having phage GA-1 as its sole member. In addition, amino acid sequences of holins, proteins involved in phage lysis were used to extend the evolutionary study to other phages infecting Gram-positive bacteria. The analysis based on the amino acid sequences of holins showed several weak points in present bacteriophage classification. Received: 14 April 1998 / Accepted: 31 July 1998     

Isolation and characterization of a novel Enterococcus faecalis bacteriophage φEF24C as a therapeutic candidate

Vancomycin-resistant Enterococcus faecalis (VRE) has become a significant threat in nosocomial settings. Bacteriophage (phage) therapy is frequently proposed as a potential alternative therapy for infections caused by this bacterium. To search for candidate therapeutic phages against Enterococcus faecalis infections, 30 Enterococcus faecalis phages were isolated from the environment. One of these, virulent phage φEF24C, which has a broad host range, was selected for analysis. The plaque-forming ability of φEF24C was virtually unaffected by differences in the clinical host strains. Furthermore, the phage had a shorter latent period and a larger burst size than ordinary tailed phages, indicating that φEF24C has effective lytic activity against many Enterococcus faecalis strains, including VRE. Morphological and genomic analyses revealed that φEF24C is a large myovirus (classified as family Myoviridae morphotype A1) with a linear double-stranded DNA genome of c . 143 kbp. Analyses of the N-terminal amino acid sequences of the virion proteins, together with the morphology and the genome size, speculated that φEF24C is closely related to other myoviruses of Gram-positive bacteria that have been used experimentally or practically for therapy or prophylaxis. Considering these results, φEF24C may be a potential candidate therapeutic phage against Enterococcus faecalis infections.     

DNA polymerase template switching at specific sites on the φ29 genome causes the in vivo accumulation of subgenomic φ29 DNA molecules

The accumulation of subgenomic phage φ29 DNA molecules with specific sizes was observed after prolonged infection times with delayed lysis phage mutants. Whereas the majority of the molecules had a size of 4 kb, additional DNA species were observed with sizes of 8.2, 6.5, 2.3, 2 and 1 kb. Most of the molecules were shown to originate from the right end of the linear Bacillus subtilis phage φ29 genome. The nature of the 4, 2.3, 2 and 1 kb molecules was studied. The 2 kb molecules were shown to be single-stranded self-complementary strands forming hairpin structures. The other molecules consisted of palindromic linear double-stranded DNA molecules. Most probably, the subgenomic DNA molecules were formed when the moving phage replication fork from the right origin encountered a block that induces the DNA polymerase to switch template. Once formed, the subgenomic molecules are then amplified in vivo . Determination of the centres of symmetry of the 4 and 1 kb molecules revealed that both contained the almost 16 bp perfect dyad symmetry element (DSE): 5'-TGTTtCAC-GTGgAACA-3' being a likely candidate for a protein binding site. Database analysis showed that this sequence occurs four times in the φ29 genome. In addition, the almost identical sequence 5'-TgGTTTCAC-GTGGAAtCA-3' was found once. These five DSEs are all located in the right half of the φ29 genome, and the same sequences are also present in the linear DNA of related B. subtilis phages. Most interestingly, this sequence is also found in the spoOJ gene of the B. subtilis chromosome. Recently, it has been shown that the SpoOJ protein is associated in vivo with the same DSE. As the same subgenomic φ29 DNA molecules accumulate after infection of B. subtilis spoOJ deletion strains, it is likely that, in addition to and/or independently of SpoOJ, other protein(s) bind to DSE.     

Nucleotide sequence of Bacillus phage Nf terminal protein gene.

The nucleotide sequence of Bacillus phage Nf gene E has been determined. Gene E codes for phage terminal protein which is the primer necessary for the initiation of DNA replication. The deduced amino acid sequence of Nf terminal protein is approximately 66% homologous with the terminal proteins of Bacillus phages PZA and luminal diameter 29, and shows similar hydropathy and secondary structure predictions. A serine which has been identified as the residue which covalently links the protein to the 5' end of the genome in luminal diameter 29, is conserved in all three phages. The hydropathic and secondary structural environment of this serine is similar in these phage terminal proteins and also similar to the linking serine of adenovirus terminal protein.     

Prevalence and distribution of bacteriophage φAa DNA in strains of Actinobacillus actinomycetemcomitans

Abstract φAa is a bacteriophage that was originally isolated by induction of a lysogenic strain of the oral bacterium Actinobacillus actinomycetemcomitans . Since the discovery of phage φAa , additional phages infecting several other strains of A. actinomycetemcomitans have been identified. To determine the prevalence of φAa or φAa -related temperate phages in this species, a φAa -specific DNA probe was prepared to screen for homologous sequences among 42 strains of A. actinomycetemcomitans . Fourteen (33%) of the 42 strains examined contained DNA sequences that hybridized with the phage φAa probe. A bacteriophage designated φAa ₃₃₃₈₄ was isolated by induction from one of the strains (ATCC 33384) that contained a sequence that hybridized with the φAa probe. The φAa probe hybridized with the DNA extracted from bacteriophage φAa ₃₃₃₈₄. The distribution of the phage φAa sequence among A. actinomycetemcomitans serotypes was 5/13 (38%) of the serotype a strains, 0/16 (0%) of the serotype b strains, and 9/13 (69%) of the serotype c strains. The results of this investigation suggest that the target sequence prepared from the phage φAa genome is fairly common in the A. actinomycetemcomitans chromosome, and that the sequence is distributed among the A. actinomycetemcomitans serotypes in a seemingly nonrandom manner.     

Cytotoxin-converting phages, φCTX and PS21, are R pyocin-related phages

Abstract φCTX is a temperate phage of Pseudomonas aeruginosa harbouring the ctx gene that encodes cytotoxin (CTX). We identified φCTX as an R pyocin-related phage, by serological and molecular analysis, based on the findings that the infectivity of the phage was inhibited with the antisera directed R pyocins and R pyocin-related phages and that the φCTX genome showed DNA homology to the genome of PS17 (a representative of the R pyocin-related phages) as well as to the pyocin R2 genes. Another new CTX-converting, R pyocin-related phage named PS21 was isolated from a CTX-producing strain of P. aeruginosa , suggesting the distribution of the ctx gene by certain members of R pyocin-related phage family.     

Phenogenetic Characterization of a Group of Giant φKZ-like Bacteriophages of Pseudomonas aeruginosa

A comparative study was made of a group ofPseudomonas aeruginosa virulent giant DNA bacteriophages similar to phage KZ in several genetic and phenotypic properties (particle size, particle morphology, genome size, appearance of negative colonies, high productivity, broad spectrum of lytic activity, ability to overcome the suppressing effect of plasmids, absence of several DNA restriction sites, capability of general transduction, pseudolysogeny). We have recently sequenced the phage KZ genome (288 334 bp) [J. Mol. Biol., 2002, vol. 317, pp. 1–19]. By DNA homology, the phages were assigned to three species (represented by phages KZ, Lin68, and EL, respectively) and two new genera (KZ and EL). Restriction enzyme analysis revealed the mosaic genome structure in four phages of the KZ species (KZ, Lin21, NN, and PTB80) and two phages of the EL species (EL and RU). Comparisons with respect to phage particle size, number of structural proteins, and the N-terminal sequences of the major capsid protein confirmed the phylogenetic relatedness of the phages belonging to the KZ genus. The origin and evolution of the KZ-like phages are discussed. Analysis of protein sequences encoded by the phage KZ genome made it possible to assume wide migration of the KZ-like phages (wandering phages) among various prokaryotes and possibly eukaryotes. Since the phage KZ genome codes for potentially toxic proteins, caution must be exercised in the employment of large bacteriophages in phage therapy.     

Isolation and characterization of lytic phages fromBacterioides ruminicola ssbrevis

Two bacteriophages (Brb01 and Brb02), lytic toBacteroides ruminicola ssbrevis AR20, were isolated from sewage water. Both phages possessed polyhedral heads and long noncontractile tails, and were classified as Siphoviridae of morphotype B1. Bacteria resistant to phages Brb01 and Brb02 arose following lysis of broth cultures. Survivors of Brb01 infection were capsulated but remained susceptible to Brb02 infection. Survivors of Brb02 infection were noncapsulated and were resistant to attack by both Brb01 and Brb02. Neither phage lysogenized the host. Both phages contained double-stranded DNA, and their restriction endonuclease digestion patterns indicated that the phage genomes were circularly permuted and terminally redundant. Phage Brb01 genome was examined in greater detail and confirmed to be circularly permuted, of size 33 kb, with a terminal redundancy of 2 kb, or 6% of the length of the genome. Circularly permuted genomes in phages of rumen bacteria do not appear to have been reported previously.At present, there is considerable interest in the genetic manipulation of rumen bacteria. The characterization of the phages described herein provides the basic information required for their use in the construction of vectors for the transfer of genetic material.     

Localization of prophages of serological group B and F on restriction fragments defined in the restriction map of Staphylococcus aureus NCTC 8325

Abstract Several Staphylococcus aureus strains were lysogenized by the phages of serological group B (phages φ53, φ85) as well as by some of serological group F (phages φ77, φ84) and macrorestriction fragment patterns of genomic DNA were estimated in the lysogenized, non-lysogenic and delysogenized (cured of prophages) strains. It was shown that the integration of phage DNA into chromosome of S. aureus leads to specific changes in restriction fragment pattern in all the lysogenized strains. These changes correlate well with the Sma I restriction map of S. aureus NCTC 8325 since they concern the restriction fragments defined in this map. Phages φ53 and φ85 integrate into Sma I fragment B. On the other hand, phages φ77 and φ84 integrate into Smal fragment E of the S. aureus restriction map. The prophages of strain NCTC 8511 have their integration sites, as follows: the phage designated by us φM integrates in fragment A, whereas the integration site for phage φJ lies in fragment E. Phage φM was estimated to be genetically related to phages of serological group A and phage φJ to those of serological group F. Evidence was given that lysogenization of S. aureus strains by at least four prophages does not cast any doubt upon the estimation of their genetic relatedness based on their similarity in restriction pattern.     

Blood kinetics of four intraperitoneally administered therapeutic candidate bacteriophages in healthy and neutropenic mice

Due to multiple-drug resistant bacteria, phage therapy is being revisited. Although most animal experiments focus on therapeutic efficacy, the blood clearance kinetics of phages have not been well described. For further development of an efficient therapeutic strategy, information on phage blood kinetics is important. In this study, time-course concentration changes in peripheral blood of healthy and neutropenic mice were measured using four therapeutic phages (φMR11, KPP10, φEF24C, and KEP10). The results showed a two- to three-day rapid phage clearance, which fits a two-compartment model.     

Effect of ultraviolet radiation on the Bacillus subtilis phages SPO2, SPP1 and phi 29 and their DNAs

A comparative study of the effects of ultraviolet radiation on three Bacillus subtilis phages is presented. Phages phi 29, SPP1 and SPO2c12 or their DNAs were irradiated by UVC (254 nm) and quantum yields for inactivation were calculated. For each phage, the purified DNA was found to be more sensitive than the intact virus when assayed in a uvr+ host. The data imply that this is because transfecting DNA is repaired less efficiently than DNA of the intact phage; rather than because of differences in sensitivity to lesion production. Even though phi 29 has the smallest target size of the three phages, phi 29 and its DNA are the most sensitive. Phages SPO2 and SPP1 code for gene products which complement the repair system of the host. The transfecting DNA of phage SPP1 is extremely sensitive to UV damage when assayed in a uvr-host. This is attributed to the fact that in transfection SPP1 DNA must undergo recombination for productive infection to occur. The recombination process strongly interferes with the repair of damaged DNA.     

Genetic analysis of spo0A and spo0C mutants of Bacillus subtilis with a phi 105 prophage merodiploid system.

An 8.0-kilobase chromosomal fragment of Bacillus subtilis which contained an intact spo0A gene was recloned onto temperate phage phi 105 from the rho 11dspo0A+-1 transducing phage. A specialized transducing phage, phi 105-dspo0A+-1, was constructed and used to transduce the spo0A12 mutant strain 1S9. A Spo+ transductant which was a single lysogen of the phi 105dspo0A+-1 transducing phage was isolated. From competent cells of this Spo+ transductant was isolated a Spo- (Spo0A) strain which was immune to phi 105. It was used to prepare a lysate of the phi 105dspo0A12 phage. Transduction of the spo0C9V recE4 strain with the phi 105dspo0A12 and phi 105dspo0A+-1 phages was carried out. The phi 105dspo0A+-1 phage gave rise to a large number of heat-resistant cells, but the phi 105dspo0A12 phage formed no heat-resistant cells. These results indicate that the spo0A12 and spo0C9V mutant genes do not complement each other in the ability to sporulate and that the spo0C9V mutation is located within the spo0A gene. Although the spo0C9V strain was completely asporogenous, the spo0C9V/spo0C9V diploid strain produced heat-resistant cells at a frequency of ca. 10(-3) in the sporulation medium. This result indicates that two copies of the spo0C9V mutant gene partially restore the ability of these cells to sporulate.     

The adsorption of Pseudomonas aeruginosa bacteriophage φKMV is dependent on expression regulation of type IV pili genes

Pseudomonas aeruginosa bacteriophage φKMV requires type IV pili for infection, as observed from the phenotypic characterization and phage adsorption assays on a phage infection-resistant host strain mutant. A cosmid clone library of the host ( P. aeruginosa PAO1) genomic DNA was generated and used to select for a clone that was able to restore φKMV infection in the resistant mutant. This complementing cosmid also re-established type IV pili-dependent twitching motility. The correlation between bacteriophage φKMV infectivity and type IV pili, along with its associated twitching motility, was confirmed by the resistance of a P. aeruginosa PAO1Δ pilA mutant to the phage. Subcloning of the complementing cosmid and further phage infection analysis and motility assays suggests that a common regulatory mechanism and/or interaction between the ponA and pilMNOPQ gene products are essential for bacteriophage φKMV infectivity.