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

Biological and genomic analysis of a PBSX-like defective phage induced from Bacillus pumilus AB94180

Defective prophages, which are found in the genomes of many bacteria, are unable to complete a viral replication cycle and propagate in their hosts as healthy prophages. They package random DNA fragments derived from various sites of the host chromosome instead of their own genomes. In this study, we characterized a defective phage, PBP180, which was induced from Bacillus pumilus AB94180 by treatment with mitomycin C. Electron microscopy showed that the PBP180 particle has a head with a hexagonal outline of ~40 nm in diameter and a long tail. The DNA packaged in the PBP180 head consists of 8-kb DNA fragments from random portions of the host chromosome. The head and tail proteins of the PBP180 particle consist of four major proteins of approximately 49, 33, 16 and 14 kDa. The protein profile of PBP180 is different from that of PBSX, a well-known defective phage induced from Bacillus subtilis 168. A killing activity test against two susceptible strains each of B. subtilis and B. pumilus showed that the defective particles of PBP180 killed three strains other than its own host, B. pumilus AB94180, differing from the host-killing ranges of the defective phages PBSX, PBSZ (induced from B. subtilis W23), and PBSX4 (induced from B. pumilus AB94044). The genome of the PBP180 prophage, which is integrated in the B. pumilus AB94180 chromosome, is 28,205 bp in length, with 40 predicted open reading frames (ORFs). Further genomic comparison of prophages PBP180, PBSX, PBSZ and other PBSX-like prophage elements in B. pumilus strains revealed that their overall architectures are similar, but significant low homology exists in ORF29-ORF38, which presumably encode tail fiber proteins involved in recognition and killing of susceptible strains.

Genomic organization and molecular analysis of the inducible prophage EJ-1, a mosaic myovirus from an atypical pneumococcus

We report the complete genomic sequence of EJ-1, an inducible prophage isolated from an atypical Streptococcus pneumoniae strain that belongs to the Myoviridae morphology family. The phage and bacterial recombinational sites (attachment sites) have been also determined. The genome of the EJ-1 prophage (42935 bp) is organized in 73 open reading frames (ORFs) and in at least five major clusters. Bioinformatic and N-terminal amino acid sequence analyses enabled the assignment of possible functions to 52 ORFs. The predicted proteins coded for the EJ-1 genome revealed similarities in the lysogeny, DNA replication, regulation, packaging, and head morphogenesis protein clusters with those from several siphoviruses infecting lactic acid bacteria. However, the proteins encoded by genes orf53 to orf64, corresponding to putative tail proteins of the virion, were very similar to those of the defective Bacillus subtilis myovirus PBSX with the notable exception of the gene product of orf56 (the tape measure tail protein) that was similar to proteins from phages infecting Gram-negative bacteria. The first description of the genome of a myovirus infecting a low G + C content Gram-positive bacterium, a member of a group embracing important human pathogens and industrial relevant species, will contribute to expand our current knowledge on phage biology and evolution.

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.

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.

Characterization of PBSX, a defective prophage of Bacillus subtilis

PBSX, a defective Bacillus subtilis prophage, maps to the metA-metC region of the chromosome. DNA (33 kilobases) from this region of the chromosome was cloned and analyzed by insertional mutagenesis with the integrating plasmid pWD3. This plasmid had a promoterless alpha-amylase gene (amyL) that provided information on the direction and level of transcription at the site of integration. Transcription under the control of the PBSX repressor proceeded in the direction metA to metC over a distance of at least 18 kilobases. Electrophoretic analysis of proteins produced by different integrant strains upon PBSX induction and by fragments subcloned in Escherichia coli allowed the identification of early and late regions of the prophage. A set of contiguous fragments directing mutagenic integration suggested that the minimum size of an operon that encodes phage structural proteins is 19 kilobases. The adaptation of PBSX transcriptional and replicational functions to a chromosomally based, thermoinducible expression system is discussed.

Integrable alpha-amylase plasmid for generating random transcriptional fusions in Bacillus subtilis

An integrable plasmid, pOK4, which replicated independently in Escherichia coli was constructed for generating transcriptional fusions in vivo in Bacillus DNA. It did not replicate independently in Bacillus subtilis, but it could be made to integrate into the chromosome of B. subtilis if sequences homologous to chromosomal sequences were inserted into it. It had a selectable marker for chloramphenicol resistance and carried unique sites for EcoRI and SmaI just to the 5' side of a promoterless alpha-amylase gene from Bacillus licheniformis. When B. subtilis DNA fragments were ligated into one of these sites and the ligation mixture was used to transform an alpha-amylase-negative B. subtilis strain, chloramphenicol-resistant transformants could be isolated conveniently. Many of these were alpha-amylase positive, owing to the fusion of the plasmid amylase gene to chromosomal operons. In principle, because integration need not be mutagenic, it is possible to obtain fusions to any chromosomal operon. The site of each integration can be mapped, and the flanking sequences can be cloned into E. coli. The alpha-amylase gene can be used to detect regulated genes. We used it as an indicator to detect operons which are DNA-damage-inducible (din), and we identified insertions in both SP beta and PBSX prophages.

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.

Characterization of proteins induced by mitomycin C treatment of Bacillus subtilis

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.

Isolation of an autonomously replicating DNA fragment from the region of defective bacteriophage PBSX of Bacillus subtilis

We have isolated a 5.4-kilobase fragment of Bacillus subtilis DNA that confers the ability to replicate upon a nonreplicative plasmid. The B. subtilis 168 EcoRI fragment was ligated into the chimeric plasmid pCs540, which contains a chloramphenicol resistance determinant from the Staphylococcus aureus plasmid pC194 and an HpaII fragment from the Escherichia coli plasmid, pSC101. A recE B. subtilis derivative, strain BD224, is capable of maintaining this DNA as an autonomously replicating plasmid. In rec+ recipients, chloramphenicol-resistant transformants do not contain free plasmid. The plasmid is integrated as demonstrated by alterations in the pattern of chromosomal restriction enzyme fragments to which the plasmid hybridizes. The site of plasmid integration was mapped by PBS1-mediated transduction to the metC-PBSX region. A strain was a deletion in the region of defective bacteriophage PBSX differs in the hybridization profile obtained by probing EcoRI digests with this cloned fragment. This same deletion mutant, though proficient in normal recombinational pathways, permits autonomous replication of the plasmid apparently owing to the lack of an homologous chromosomal region with which to recombine. We believe that, like E. coli. B. subtilis contains at least one DNA fragment capable of autonomous replication when liberated from its normally integrated chromosomal site and that this cloned DNA fragment comes from the region of defective bacteriophage PBSX.

Mutagenesis during transformation of Bacillus subtilis. II. An increase in chemically-induced mutations during competency

During the development of competency in Bacillus subtilis there was an increased sensitivity to methyl methanesulfonate (MMS) treatments. The frequency of reverse mutation also increased among the MMS-revertible markers by a factor of 100 as compared to vegetative cultures. The frequency of 2-aminopurine(AP)-induced mutagenesis was the same in competent and noncompetent cultures. Studies with DNA-polymerase-deficient mutants showed a direct involvement of DNA polymerase I in promoting MMS and transformation-induced mutagenesis in competent cells.

Chromosomal loci of genes controlling site-specific restriction endonucleases of Bacillus subtilis

We constructed transformation of B. subtilis 168 which acquired genes for site-specific restriction endonucleases. These endonucleases originated from various strains of B. subtilis and were classified into five groups based on the specificity of the sequences recognized by the enzymes. We examined the loci of genes for site-specific restriction endonucleases belonging to different groups: hsrE determined Endo. R. Bsu1231 (I), hsrB Endo.R.Bsu1247(I), hsrR Endo.R.BsuR and hsrC Endo.R.Bsu-1247(II). One gene, hsrE, was located between sacA and purA by transduction crosses with phage PBS1, and another gene, hsrB, between hsrE and purA. Genes hsrR and hsrC had been suggested to be allelic or closely linked by previous studies with transformation. We located hsrR and hsrC between purB and tre. Our previous observation and this study show that B. subtilis 168 has at least three independent loci on the chromosome for four genes for site-specific restriction endonucleases in addition to the locus for the original restriction activity (Bsu168-specific restriction) of strain 168.

Properties of Bacillus subtilis 168 derivatives freed of their natural prophages

An isogenic set of Bacillus subtilis 168 strains which are non-inducible for prophage PBSX and are cured of prophage SP beta has been constructed. By utilizing these strains, prophage SP beta has been shown to control the inducible DNA modification system which exists in this bacterium. However, neither the PBSX nor the SP beta prophages alter the ability of the bacterium to undergo genetic recombination, to repair damaged DNA or to sporulate. Prophageless B. subtilis would be a useful host for the phi 3T cloning vector, because of the absence of vector--prophage interactions.

The occurrence and taxonomic value of PBS X-like defective phages in the genus Bacillus

72 strains of 24 Bacillus species were induced with mitomycin C. The lysates were examined for the presence of defective phages resembling PBS X in morphology. All strains tested of B. amyloliquefaciens. B, licheniformis, B. pumilus and B. subtilis contained such phages. Five morphological types of defective, PBS X-like phage could be distinguished, differing in their tail lengths and in the number of cross-striations on the tail. The quaternary structure of the tail, the molecular weight of the main tail protein and the antigenic properties of the phages were identical. The killing ranges of the defective phages have been determined and their possible use in taxonomy discussed.

Isolation of a Bacillus subtilis 168 derivative sensitive to defective bacteriophage PBSX

A derivative of Bacillus subtilis strain 168 sensitive to defective bacteriophages PBSX and PBSZ has been isolated. This particular strain, RUB824, carries the genetic information for defective bacteriophage PBSX.

Fragmentation of Bacillus bacteriophage phi105 DNA by complementary single-stranded DNA in the cohesive ends of the molecule

The structure of DNA from the temperate Bacillus subtilis phage phi105 was examined by using the restriction endonuclease EcoRI and by sedimentation analysis. The DNA contains six EcoRI cleavage sites. Although eight DNA fragments were identified in the EcoRI digests, the largest of these was shown to consist of the two fragments that carry the cohesive ends of the phage DNA. In neutral gradients, the majority of whole phi105 DNA sedimented as nicked circles and the remainder as oligomers. No unit-length linear structures were detected. The associated cohesive ends could be sealed by DNA ligase from Escherichia coli and could be cleaved by S1 nuclease. On the basis of these results and previously reported studies, it appears that, as isolated from phage particles, phi105 DNA is a circular molecule that is formed from the linear structure by the association of complementary single-stranded DNA.

DNA repair in Bacillus subtilis. II. Activation of the inducible system in competent bacteria

Competent B. subtilis are more UV sensitive than the non-competent population of the culture. This increased sensitivity is lose in mutants unable to induce the 'SOS system' (recA1,, recG13), in mutants defective in the induction of prophage PBSX (xin), and in late stage competent cells. Moreover, bacteriophage phi 105 produced from transfected cells are less restricted on strain YB880 than bacteriophage produced from infected cells. Therefore, competent cells (those capable of being transfected) have a DNA modification system, whereas the average log phase cell does not. These data support the hypothesis that the development of competence is correlated with the activation of derepression of the "SOS" system in B. subtilis.

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.

Association of the recombination-deficient phenotype of Bacillus subtilis recC strains with the presence of an SPO2 prophage

The recombination-defective phenotype associated with the recC genetic locus in Bacillus subtilis is not due to a chromosomal mutation at this site but rather to the presence of an integrated SPO2 prophage.

Bacteriophages of Bacillus subtilis

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Bacteriophage-specific protein synthesis during induction of the defective Bacillus subtilis bacteriophage PBSX

Particles of PBSX, a defective, noninfectious phage which is inducible from strains of Bacillus subtilis 168, contain at least seven structural proteins resolvable by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Five of these proteins are associated with the phage tail and two with the phage head. An eighth protein, which also may be coded for by the PBSX prophage, has been identified in cells derepressed for PBSX replication.