Isolation and characterization of prophage mutants of the defective Bacillus subtilis bacteriophage PBSX.

Bacillus subtilis mutants with lesions in PBSX prophage genes have been isolated. One of these appears to be a regulatory mutant and is defective for mitomycin C-induced derepression of PBSX; the others are defective for phage capsid formation. All of the PBSX structural proteins are synthesized during induction of the capsid defective mutants; however, several of these proteins exhibit abnormal serological reactivity with anti-PBSX antiserum. The two head proteins X4 and X7 are not immunoprecipitable in a mutant which fails to assemble phage head structures. In the tail mutant, proteins X5 and X6 are not immunoprecipitable, tails are not assembled, and a possible tail protein precursor remains uncleaved. The noninducible mutant does not synthesize any PBSX structural proteins after exposure to mitomycin C. The mutation is specific for PBSX since ø105 and SPO2 lysogens of the mutant are inducible. All of the known PBSX-specific mutations were shown to be clustered between argC and metC on the host chromosome. In addition, the metC marker was shown to be present in multiple copies in cells induced for PBSX replication. This suggests that the derepressed prophage replicates while still integrated and that replication extends into the adjacent regions of the host chromosome.     

Posttranslational processing of Uukuniemi virus glycoproteins G1 and G2

A total of 26 polypeptides have been resolved by gel electrophoresis of purified phage PBSX, 3 of which belong to the head and the remainder to the tail. After mitomycin C treatment, synthesis of 11 additional proteins which are not found in the assembled phage particle was demonstrated, all but 4 being under the control of the phage repressor. Existence of a prehead and of a precursor of the main capsid protein (molecular weight, 35,000) suggested phage head maturation which is accompanied by cleavage of the precursor (molecular weight, 36,500). The role of induced proteins related and unrelated to PBSX is discussed. Finally, the estimated phage genome mass of 4 X 10(7) daltons exceeded by more than four times its head capacity, which could explain the defectiveness of the phage.     

A new defective phage containing a randomly selected 8 kilobase-pairs fragment of host chromosomal DNA inducible in a strain of Bacillus natto

A new defective phage, designated PBND8, was induced in Bacillus natto strain IAM1207 with bleomycin and mitomycin C. PBND8 particles contained a randomly selected 8 kilobase-pairs (kbp) fragment of the host chromosomal DNA. Electron microscopy showed that PBND8 has a small head with a complex tail structure like PBSX, a defective phage of Bacillus subtilis 168. The PBND8 head, however, is clearly smaller than that of PBSX which contains 13-kbp fragments of the host chromosomal DNA. SDS-polyacrylamide gel electrophoretic analysis revealed that the structural proteins of PBND8 are distinct from those of PBSX and PBSY (PBSZ) of B. subtilis W23. PBND8 exhibited a bacteriocin-like killing activity to the other Bacillus cells.     

Prophage mutation causing heat inducibility of defective Bacillus subtilis bacteriophage PBSX.

A mutant of Bacillus subtilis 168 has been isolated in which the defective phage PBSX was heat inducible, whereas another phage, phi105, was not so induced. A culture of the mutant grown at 30 degrees C, when shifted to 45 degrees C, began to lyse after 45 min; cell viability began to decrease after 10 min. Heat-induced lysis of the mutant was prevented by chloramphenicol. DNA, RNA, protein, and peptidoglycan synthesis were normal at the nonpermissive temperature up to the time of lysis. The site of xhi-1479 mutation causing this phenotype was linked (50%) in phage PBS1-mediated transduction to the host marker metC and to another PBSX marker xtl and was thus thought to map within the PBSX prophage. The order of markers was argC-thiB-metA-xhi-metC. The xhi mutation was thus distinct from another mutation, tsi-23, causing a similar heat inducibility of PBSX (Siegel and Marmur, 1969), which was unlinked to the metC marker. tsi-23 is therefore thought to be a host mutation, and the available evidence for a scattered phage genome being the cause of the defective nature of PBSX is thus less tenable. It was shown that the mutant, besides carrying the xhi mutation, also carried another closely linked mutation, xki-1479, which caused the PBSX produced to have no killing activity on the sensitive strain W23. The xki mutation was separated from xhi by recombination.     

Genetic control of bacterial suicide: regulation of the induction of PBSX in Bacillus subtilis.

PBSX is a phage-like bacteriocin (phibacin) of Bacillus subtilis 168. Bacteria carrying the PBSX genome are induced by DNA-damaging agents to lyse and produce PBSX particles. The particles cannot propagate the PBSX genome. The particles produced by this suicidal response kill strains nonlysogenic for PBSX. A 5.2-kb region which controls the induction of PBSX has been sequenced. The genes identified include the previously identified repressor gene xre and a positive control factor gene, pcf. Pcf is similar to known sigma factors and acts at the late promoter PL, which has been located distal to pcf. The first two genes expressed from the late promoter show homology to genes encoding the subunits of phage terminases.     

Defective pages as an antagonistic factor in closely-related bacilli

The antagonistic effect produced by the detective phage PBSX during cocultivation of the mutant strain B. subtilis 168, in which this phage is heat-inducible, and strain B. subtilis NRS231, which also bears a defective phage, was investigated. As soon as in the first hours of cocultivation under conditions of PBSX induction, the number of viable cells of strain NRS231 decreased by two orders of magnitude. However, the effect was not observed if the temperature of cocultivation was noninducing. The results confirm the supposition that defective phages may play a role in the competition between closely related bacilli.     

DNA packaging by the Bacillus subtilis defective bacteriophage PBSX.

Defective bacteriophage PBSX, a resident of all Bacillus subtilis 168 chromosomes, packages fragments of DNA from all portions of the host chromosome when induced by mitomycin C. In this study, the physical process for DNA packaging of both chromosomal and plasmid DNAs was examined. Discrete 13-kilobase (kb) lengths of DNA were packaged by wild-type phage, and the process was DNase I resistant and probably occurred by a head-filling mechanism. Genetically engineered isogenic host strains having a chloramphenicol resistance determinant integrated as a genetic flag at two different regions of the chromosome were used to monitor the packaging of specific chromosomal regions. No dramatic selectivity for these regions could be documented. If the wild-type strain 168 contains autonomously replicating plasmids, especially pC194, the mitomycin C induces an increase in size of resident plasmid DNA, which is then packaged as 13-kb pieces into phage heads. In strain RB1144, which lacks substantial portions of the PBSX resident phage region, mitomycin C treatment did not affect the structure of resident plasmids. Induction of PBSX started rolling circle replication on plasmids, which then became packaged as 13-kb fragments. This alteration or cannibalization of plasmid replication resulting from mitomycin C treatment requires for its function some DNA within the prophage deletion of strain RB1144.     

Purification and characterization of two phage PBSX-induced lytic enzymes of Bacillus subtilis 168: an N-acetylmuramoyl-L-alanine amidase and an N-acetylmuramidase

After heat-induction of the defective phage PBSX in a xhi-1479 mutant of Bacillus subtilis 168, the culture lysed rapidly even if the lyt-2 mutation was present (which greatly reduces the amount of the bacterial autolysins). Two lytic enzymes, an N-acetylmuramoyl-L-alanine amidase and an endo-N-acetylmuramidase, were purified from the culture supernatant. The amidase was readily distinguished from the bacterial amidase by its low molecular weight. In addition, it was not inhibited by antibody directed against the bacterial enzyme. These results indicate that PBSX does not rely on the bacterial autolysins to accomplish lysis.     

Genetic Mapping of a Defective Bacteriophage on the Chromosome of Bacillus subtilis 168

A genetic marker responsible for the killing activity of PBSX, a defective phage carried by Bacillus subtilis 168, has been located on the bacterial chromosome. Two mutant strains of B. subtilis 168, which produced tailless phage particles upon mitomycin C induction, were shown to carry lesions, designated xtl-1 and xtl-2, which were linked by transformation and PBS1-mediated transduction to metC. The link-age relationship between xtl and adjacent auxotrophic markers was determined by three-factor PBS1 transduction, the suggested order of markers being argO 1 metA metC xtl.     

Characterisation of a repressor gene (xre) and a temperature-sensitive allele from the Bacillus subtilis prophage, PBSX

The defective prophage of Bacillus subtilis 168, PBSX, is a chromosomally based element which encodes a non-infectious phage-like particle with bactericidal activity. PBSX is induced by agents which elicit the SOS response. In a PBSX thermoinducible strain which carries the xhi1479 mutation, PBSX is induced by raising the growth temperature from 37 degrees C to 48 degrees C. A 1.2-kb fragment has been cloned which complements the xhi1479 mutation. The nucleotide sequence of this fragment contains an open reading frame (ORF) which encodes a protein of 113 amino acids (aa). This aa sequence resembles that of other bacteriophage repressors and suggests that the N-terminal region forms a helix-turn-helix motif, typical of the DNA-binding domain of many bacterial regulatory proteins. The ORF is preceded by four 15-bp direct repeats, each of which contains an internal palindromic sequence, and by sequences resembling a SigA-dependent promoter. The nt sequence of an equivalent fragment from the PBSX thermoinducible strain has also been determined. There are three aa differences within the ORF compared to the wild type, one of which lies within the helix-turn-helix segment. This ORF encodes a repressor protein of PBSX.     

Bacteriophage PBSX-induced deletion mutants of Bacillus subtilis 168 constitutive for alkaline phosphatase

Mutants of Bacillus subtilis with deletions extending from the PBSX prophage, and in some cases removing pro(AB) and metC, have been found to be constitutive for vegetatively synthesized alkaline phosphatase. Such deletions were isolated by selecting for heat-resistant derivatives of a strain carrying a xhi-1479 mutation causing heat-inducibility of the defective phage PBSX. These deletions remove the phoS gene, a regulatory gene for alkaline phosphatase; it is concluded that the phoS gene product exerts negative control on alkaline phosphatase synthesis. Deletion mapping, combined with previously published linkage data, indicates a gene order of PBSX-phoS-pro(AB)-metC.     

Temperature-Sensitive Induction of Bacteriophage in Bacillus subtilis 168

In a temperature-sensitive mutant of Bacillus subtilis 168, induction of the defective phage PBSX occurred at 48 C. Cell lysis began after 90 min of growth at 48 C, and cell viability began to decrease after 10 to 30 min. The loss in viability at the nonpermissive temperature was prevented by azide or cyanide. Deoxyribonucleic acid (DNA), ribonucleic acid, and protein synthesis were not inhibited at 48 C. Temperature induction of the temperate phage SPO2 also occurred in this mutant. The temperature-sensitive mutation, designated tsi-23, was linked by transduction to purB6 and pig, the order being purB6 pig tsi-23. Mutation tsi-23 was transformable to wild type by B. subtilis 168 DNA but not by DNA from the closely related strains W23 or S31. DNA from the latter two strains transformed auxotrophic markers of strain 168 at frequencies close to those found with 168 donor DNA. Upon temperature induction, cellular DNA was broken to a size of 22S, characteristic of DNA in PBSX particles. The DNA isolated from temperature-induced PBSX did not give an increased Ade(+)/Met(+) transformant ratio relative to cellular DNA nor contain preferential break points as determined by transformation of four closely linked markers.     

SOS induction in a subpopulation of structural maintenance of chromosome (Smc) mutant cells in Bacillus subtilis

The structural maintenance of chromosome (Smc) protein is highly conserved and involved in chromosome compaction, cohesion, and other DNA-related processes. In Bacillus subtilis, smc null mutations cause defects in DNA supercoiling, chromosome compaction, and chromosome partitioning. We investigated the effects of smc mutations on global gene expression in B. subtilis using DNA microarrays. We found that an smc null mutation caused partial induction of the SOS response, including induction of the defective prophage PBSX. Analysis of SOS and phage gene expression in single cells indicated that approximately 1% of smc mutants have fully induced SOS and PBSX gene expression while the other 99% of cells appear to have little or no expression. We found that induction of PBSX was not responsible for the chromosome partitioning or compaction defects of smc mutants. Similar inductions of the SOS response and PBSX were observed in cells depleted of topoisomerase I, an enzyme that relaxes negatively supercoiled DNA.     

Productive Infection of Bacillus subtilis 168, with Bacteriophage SP-10, Dependent upon Inducing Treatments

Strains of Bacillus that harbor defective phage PBSX were found to be insensitive to SP-10(C), although the phage adsorbed to these insensitive strains. Strains that did not carry the phage were sensitive to SP-10(C). B. subtilis 168 ind(-), which can be tranduced by SP-10(C) but is nonpermissive for the phage, was rendered phage-sensitive after treatment with ultraviolet (UV) light or mitomycin C. After induction with UV light, maximal sensitivity to SP-10(C) was obtained at a multiplicity of infection (MOI) of approximately 14; with mitomycin C induction, an MOI of approximately 1.0 was required. Phage maturation in sensitized cells was followed by plating infected streptomycin-sensitive cells in the presence of streptomycin at various stages during phase development. The latent period was estimated at 60 to 75 min. We suggest that the resistance of B. subtilis 168 to SP-10 is controlled, at least in part, by the presence of a defective prophage.     

Repression of sigK intervening (skin) element gene expression by the CI-like protein SknR and effect of SknR depletion on growth of Bacillus subtilis cells

The Bacillus subtilis phage DNA-like sigK intervening (skin) element (48 kb) is excised from the chromosome by DNA rearrangement, and a composite gene, sigK (spoIIIC and spoIVCB), is created on the chromosome during sporulation. In this study, we first focused on the role of sknR (skin repressor), which has homology with the gene encoding the Xre repressor of defective phage PBSX. The depletion of SknR caused overexpression of the region between yqaF and yqaN (the yqaF-yqaN operon) and a growth defect in B. subtilis. Point mutation analysis and an electrophoretic mobility shift assay (EMSA) suggested that SknR functions as a negative regulator of gene expression in the yqaF-yqaN operon of the skin element through direct interaction with operators of 2-fold symmetry located in the intergenic region between sknR and yqaF. Deletion analysis revealed that the lethal effect of depletion of SknR was related to overexpression of yqaH and yqaM, whose products were previously reported to associate with DnaA and DnaC, respectively. Furthermore, overexpression of either yqaH or yqaM caused cell filamentation and abnormal chromosome segregation, which suggested that overproduction of these proteins inhibits DNA replication. Moreover, overexpression of yqaM inhibited the initiation of replication. Taken together, these data demonstrate that the B. subtilis skin element carries lethal genes, which are induced by the depletion of sknR.     

Characterization of Inducible Bacteriophages in Bacillus licheniformis

Two morphologically distinct and physically separable defective phages have been found in Bacillus licheniformis NRS 243 after induction by mitomycin C. One of them (PBLB) is similar to the defective phage PBSX of B. subtilis, which has a density of 1.373 g/cm(3) in CsCl and a sedimentation coefficient of 160S. PBLB incorporates into its head mainly bacterial deoxyribonucleic acid (DNA) which has a sedimentation coefficient of 22S and a buoyant density in CsCl of 1.706 g/cm(3). The other phage (PBLA) has a morphology similar to the temperate phage phi105 of B. subtilis; the head diameter is about 66 nm, and it possesses a long and noncontractile tail. PBLA has a density of 1.484 g/cm(3) in CsCl and the phage-specific DNA, which is exclusively synthesized after induction by mitomycin C, has a density of 1.701 g/cm(3). PBLA DNA is double-stranded and has a sedimentation coefficient of 36S, corresponding to a molecular weight of 34 x 10(6) to 35 x 10(6) daltons. The phage DNA has one interruption per single strand, giving single-stranded segments with molecular weights of 13 x 10(6) and 4 x 10(6) daltons. Common sequences between the two phage DNA species and with their host DNA have been demonstrated by DNA-DNA hybridization studies. Both phage particles kill sensitive bacteria. However, all attempts thus far to find an indicator strain to support plaque formation have been unsuccessful.     

Prophage induction in thermosensitive DNA mutants of Bacillus subtilis

Summary Incubation of thermosensitive dna mutants of Bacillus subtilis at the non-permissive temperature leads in some instances to induction of defective prophage PBSX and cell lysis. A clear distinction can be made between mutants affected in DNA replication at the growing point (extension mutants) and those unable to initiate new rounds of replication (initiation mutants). The former promote PBSX induction to a variable and mutation-specific extent, whereas the latter do not exhibit any signs of induction. Analysis of mutants carrying two dna mutations suggests that products of some dna genes involved in initiation and in extension are not essential for induction but can substantially amplify its extent. However, mitomycin C treatment of dna mutants which have completed their residual DNA synthesis leads to a PBSX induction essentially identical to that obtained by mitomycin C treatment of the wild-type strain, which precludes an essential role for any of the mutated proteins in this induction process. On the basis of our observations we propose that the induction signal is related to the number of blocked replication forks: the larger that number, the higher the proportion of induced cells within the population.     

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).