Cloning of the Bacillus subtilis recE+ gene and functional expression of recE+ in B. subtilis.

By use of the Bacillus subtilis bacteriophage cloning vehicle phi 105J23, B. subtilis chromosomal MboI fragments have been cloned that alleviate the pleiotropic effects of the recE4 mutation. The recombinant bacteriophages phi 105Rec phi 1 (3.85-kilobase insert) and phi 105Rec phi 4 (3.3-kilobase insert) both conferred on the recE4 strain YB1015 resistance to ethylmethane sulfonate, methylmethane sulfonate, mitomycin C, and UV irradiation comparable with the resistance observed in recE+ strains. While strain YB1015 (recE4) and its derivatives lysogenized with bacteriophage phi 105J23 were not transformed to prototrophy by B. subtilis chromosomal DNA, strain YB1015 lysogenized with either phi 105Rec phi 1 or phi 105Rec phi 4 was susceptible to transformation with homologous B. subtilis chromosomal DNA. The heteroimmune prophages phi 105 and SPO2 were essentially uninducible in strain YB1015. Significantly, both recombinant prophages phi 105Rec phi 1 and phi 105Rec phi 4 were fully inducible and allowed the spontaneous and mitomycin C-dependent induction of a coresident SPO2 prophage in a recE4 host. The presence of the recombinant prophages also restored the ability of din genes to be induced in strains carrying the recE4 mutation. Finally, both recombinant bacteriophages elaborated a mitomycin C-inducible, 45-kilodalton protein that was immunoreactive with Escherichia coli recA+ gene product antibodies. Collectively, these data demonstrate that the recE+ gene has been cloned and that this gene elaborates the 45-kilodalton protein that is involved in SOB induction and homologous recombination.     

Unrelatedness of Temperate Bacillus subtilis Bacteriophages SPO2 and φ105

SPO2 and phi105 are temperate Bacillus subtilis bacteriophages which have been suggested to belong to a cluster of related bacteriophages. In the present work, we show that SPO2 does not complement any of the 11 essential genes known in phi105 and that the phages do not recombine. Deoxyribonucleic acid (DNA)-DNA hybridization shows less than 10% homology between SPO2 and phi105 DNA. DNA synthesis in phi105 shows a greater dependence on host functions than does SPO2 DNA synthesis. Growth of phi105 but not of SPO2 is inhibited by the uracil analogue 6-(p-hydroxyphenylazo)-uracil. Infection of a DNA polymerase-deficient strain of B. subtilis with SPO2 leads to an increase in DNA polymerase activity in crude extracts, whereas no such increase is found after infection of this strain with phi105. It is concluded that SPO2 and phi105 are unrelated bacteriophages.     

Cloning of the Bacillus subtilis spoIIA and spoV A loci in phage phi 105DI:1t

A 6.95 kb HindIII-generated DNA fragment from Bacillus subtilis 168 was inserted into the DNA of phage phi 105DI:1t. The recombinant phage (phi 105DS1) contained DNA of 33.8 kb as compared with 35.2 kb for phi 105DI:1t and 39.2 kb for the wild-type phage. In the presence of helper phage, phi 105DS1 complemented both spoIIA and spoV A mutations in B. subtilis.     

Nucleotide sequence of the immunity region of Bacillus subtilis bacteriophage phi 105: identification of the repressor gene and its mRNA and protein products

A gene involved in the regulation of lysogeny in the temperate Bacillus subtilis phage phi 105 has been identified and isolated. A plasmid, pDC4, was constructed that contains a 740-bp HindIII-PvuII fragment that is derived from the phi 105 immunity region and is capable of rendering B. subtilis immune to infection by phi 105. Three different hybrid plasmids that contain the 740-bp fragment, pAG101 [Cully and Garro, J. Virol. 34 (1980) 789-791], pDC1 and pDC2, were found to synthesize a common 18-kDal polypeptide in B. subtilis minicells and Escherichia coli maxicells. The nucleotide (nt) sequence of this region revealed three open reading frames (ORFs) that predict proteins with Mrs of 16521, 7332, and 5516. In vivo synthesized phi 105 prophage RNA was mapped by primer extension and shown to be transcribed from the DNA strand coding for the Mr 16521 protein. The 5' end of the phi 105 lysogen RNA was mapped to a region that contains conserved sequences for RNA polymerase recognition.     

Mechanism of Transfection with Deoxyribonucleic Acid from the Temperate Bacillus Bacteriophage φ105

Bacteriophage phi105 is a temperate phage for the transformable Bacillus subtilis 168. The infectivity of deoxyribonucleic acid (DNA) extracted from mature phi105 phage particles, from bacteria lysogenic for phi105 (prophage DNA), and from induced lysogenic bacteria (vegetative DNA) was examined in the B. subtilis transformation system. About one infectious center was formed per 10(8) mature DNA molecules added to competent cells, but single markers could be rescued from mature DNA by a superinfecting phage at a 10(3)- to 10(4)-fold higher frequency. Single markers in mature DNA were inactivated at an exponential rate after uptake by a competent cell. Prophage and vegetative DNA gave about one infectious center per 10(3) molecules added to competent cells. Infectious prophage DNA entered competent cells as a single molecule; it gave a majority of lytic responses. Single markers in sheared prophage DNA were inactivated at the same rate as markers in mature DNA. Prophage DNA was dependent on the bacterial rec-1 function for its infectivity, whereas vegetative DNA was not. The mechanism of transfection of B. subtilis with viral DNA is discussed, and a model for transfection with phi105 DNA is proposed.     

Construction of improved bacteriophage phi 105 vectors for cloning by transfection in Bacillus subtilis

A series of improved phage vectors have been constructed, based on Bacillus subtilis bacteriophage phi 105, which can be used to clone genes in B. subtilis by direct transfection of protoplasts. The new vectors, designated phi 105J23, phi 105J24, phi 105J27 and phi 105J28, show frequencies of plaque formation that are equal to those of wild-type phi 105. This represents at least a 10-fold improvement over phi 105J9, the vector used in previous cloning experiments. Two of the new vectors phi 105J27 and phi 105J28 incorporate a mutation, cts-52, that renders the prophage temperature inducible. This has made it possible to devise a rapid small-scale procedure for screening progeny phage for the presence of inserted DNA. The usefulness of the new vectors is illustrated in the accompanying paper by cloning more than 20 B. subtilis sporulation genes.     

Expression of superinfection immunity to bacteriophage phi 105 by Bacillus subtilis cells carrying a plasmic chimera of pUB110 and EcoRI fragment F of phi 105 DNA.

A 2.1-megadalton, EcoRI-generated fragment of Bacillus subtilis phage phi 105 DNA was cloned into plasmid pUB110. The hybrid plasmid produces a biologically active product which renders B. subtilis immune to infection by phi 105.     

Evidence for circular permutation of the prophage genome of Bacillus subtilis bacteriophage phi 105.

Analysis of DNA extracted from Bacillus subtilis lysogenic for bacteriophage phi 105 was performed by restriction endonuclease digestion and Southern hybridization using mature phi 105 DNA as a probe. The data revealed that the phi 105 prophage is circularly permuted. Digests using the enzymes EcoRI, SmaI, PstI, and HindIII localized the bacteriophage attachment site (att) to a region 63.4 to 65.7% from the left end of the mature bacteriophage genome. The phi 105 att site-containing SmaI C, PstI J, and HindIII L fragments were not present in digests of phi 105 prophage DNA. phi 105-homologous "junction" fragments were visualized by probing digests of prophage DNA with the purified PstI J fragment isolated from the mature bacteriophage genome. The excision of the phi 105 prophage was detected by observing the appearance of the mature PstI J fragment and the concomitant disappearance of a junction fragment during the course of prophage induction.     

Use of the thermoinducible temperate phage Phi 105cts139 for cloning in Bacillus subtilis

The gene for alpha-amylase from Bacillus amyloliquefaciens having a foreign promoter providing gene expression in logarithmic growth phase and the cat gene of plasmid pC194 (AC fragment) were inserted into thermoinducible prophage phi 105 cts139. Possibility of amylolytic activity enhancement was studied after thermoinduction. When AC fragment and random PstI restricts of phage DNA were ligated and used to transform Bacillus subtilis 1A289 (phi 105 cts139) the Amy+ CmR transformants were obtained having the different levels of increased amylolytic activity (maximum--26 fold). Numerous phages without insert found in induced lysates suggest that insertions were unstable and (or) the clones were double lysogens for hybrid and original type phages. Stable insertion of AC fragment replacing the PstI-H-fragment of phage DNA revealed that all Amy+ CmR transformants were double lysogens. Inducibility depended on the insertion orientation.     

枯草芽孢杆菌噬菌体载体的构建

以φ0105DI：It为原始株构建的重组噬菌体φ105S35和φ10 5S36具有自主侵染能力和溶源化特征。其基因组内插入的lkb片段上的cat,基因赋予二者所在宿主以氯霉素抗性,在两株噬菌体中插入位点相同,即原φ105DI ：It的smal酶切片段D、E之间,但插入片段在二者中的定向相反。与cat基因同时引入的单一BamHI和Xbal位点提供了外源DNA的插入位置。重组噬菌体DNA可高效转染枯草芽孢杆菌原生质体。因此φ105S35和币φ105S36可作为枯草芽孢杆随系统的载体而被利用。     

Behavior of a temperate bacteriophage in differentiating cells of Bacillus subtilis.

During the first 6 hr of sporulation, infection of Bacillus subtilis by by phi105 wild type or the clear-plaque mutant phi105 c30 was nonproductive, but phage DNA was trapped inside developing spores. After infection with either wild-type or mutant phage at early times of sporulation (T1-T3), phage DNA entered the developing spores in a heat-stable form, which may represent integration of the phage DNA into the host chromosome. Phage DNA in carrier spores produced by infection at later times (T4-T6) was much more heat sensitive. Spore preparations containing either phi105 wild type or phi105 c30 carrier spores gave rise to a spontaneous burst of phage during outgrowth, although the fraction of carried wild-type phage that chose lysis over lysogeny at germination has not been determined. Heat induction of the thermoinducible lysogen 3610 (phi105 cts23) was also abortive during sporulation. Furthermore, induction neither prevented eventual spore formation nor resulted in the conversion of prophage DNA to the carrier state; during outgrowth, the previously induced lysogenic spores remained stable lysogens. However, if the sporulating lysogenic cells were plated immediately after induction, they did not form colonies at high efficiency, as though transfer to fresh medium allowed sufficient phage expression to kill the host.     

Heat Induction of Prophage φ 105 in Bacillus subtilis: Bacteriophage-Induced Bidirectional Replication of the Bacterial Chromosome

A mutant of Bacillus subtilis, dna-1, which cannot initiate new rounds of DNA replication (obtained from N. Sueoka) was lysogenized with wild-type phi 105 and with the heat-inducible mutant phi 105 cts23. Bacteria were incubated at the permissive temperature in the presence of chloramphenicol and then shifted to the nonpermissive temperature where induction of phi 105 cts23 occurs. DNA made after the shift was labeled with a density label, and the distribution of bacterial and phage markers in replicated and unreplicated DNA was determined. Similar experiments were performed with nonlysogenic dna-1 infected with phage phi 105 cts23 after the temperature shift. The results show that after induction of phi 105 cts23 prophage, bacterial markers on either side of the prophage replicate at an increased rate compared to more distant markers. No selective stimulation of bacterial DNA synthesis was observed on infection or after shifting bacteria lysogenic for noninducible phage to the higher temperature. Attempts to suppress the initiation mutation dna-1 by phage phi 105 were unsuccessful.     

Effect of lysogeny on transfection and transfection enhancement in Bacillus subtilis.

Strains of Bacillus subtilis 168 lysogenic for bacteriophage phi105 transfer with deoxyribonucleic acid (DNA) isolated from bacteriophage SPO2 at a higher efficiency than non-lysogenic strains. This enhancement of transfection was not the result of recombination between bacteriophages SPO2 and phi105. Superinfection marker rescue increased transfection with DNA from bacteriophage phi105 occurred simultaneously with the addition of the transfecting DNA. Again, this enhancement of transfection was not the result of recombination but rather a protection of the transfecting DNA by the superinfecting bacteriophage. The ability of the superinfecting bacteriophage to protect the transfecting DNA from inactivation was maximal when the bacteria were just becoming competent. Bacteriophage phi1 cannot replicate after the transfection of competent bacteria lacking a functional DNA replication system, whereas bacteriophage phi1 was able to replicate after infection of competent bacteria grown under comparable conditions. These observations support the hypothesis that GAPase and an inducible repair system play an important role in the development of competence.     

Construction and characterization of recombinant phage phi 105 d(Cmrmet) for cloning in Bacillus subtilis

A 1.6 kb fragment of DNA of plasmid pBD64, obtained after partial digestion with HpaII, carrying a chloramphenicol-resistance determinant and a single site for the enzyme Bg/II, was inserted into the genome of defective phage phi 105 d/ys. Two types of phage were subsequently isolated and both transduced cells of Bacillus subtilis to chloramphenicol resistance. One type contained 26 kb and the other 32 kb of DNA. Bacillus subtilis chromosomal DNA fragments generated by cleavage with Bg/II were ligated into the unique Bg/II site within the smaller phage genome. A specialized transducing phage was isolated which carried the metC gene on a 6 kb Bg/II fragment. This phage, denoted phi 105 d(Cmrmet), transduced B. subtilis strain MB79 pheA12 metC3 to Met+ and to chloramphenicol resistance, and the metC3 mutation was complemented in transductants.     

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.     

Interaction of the Bacillus subtilis phage phi 105 repressor DNA: a genetic analysis.

The Bacillus subtilis phage phi 105 repressor specifically recognizes a 14-bp operator sequence which does not exhibit 2-fold rotational symmetry. To facilitate a genetic analysis of this sequence-dependent DNA binding a B. subtilis strain was constructed in which mutations affecting the phi 105 repressor-operator interaction cause a selectable phenotype, chloramphenicol resistance. After in vivo mutagenesis, we isolated and mapped 22 different mutations in the repressor coding sequence, 15 of which are missense substitutions. These are exclusively located in the N-terminal part (positions 1-43) of the 144 residue long polypeptide. Two nonsense mutants, at positions 70 and 89, respectively, still show partial repressor activity. These data suggest that the phi 105 repressor consists of at least two independently folding structural domains, of which the N-terminal is involved in operator binding. Twelve missense mutations are clustered in a region extending from Gln-18 to Arg-37, which we propose to be the DNA-binding alpha-helix--beta-turn--alpha-helix motif, common to all lambda Cro-like repressors. The second ('recognition') helix shows significant homology with the corresponding sequence in Tn3 resolvase, and there is also a striking similarity between the phi 105 operator and the consensus sequence for a Tn3 res half-site. Based on these observations, and on the previously isolated phi 105 0c mutants, we tentatively assign some specific contacts between base pairs from the first half of a phi 105 operator site and amino acids from the repressor's 'recognition helix'.     

Restriction endonuclease mapping of bacteriophage phi105 and closely related temperate Bacillus subtilis bacteriophages rho10 and rho14.

Cleavage maps of the three similar Bacillus subtilis temperate bacteriophages, phi105, rho10, and rho14, were constructed by partial digestion analysis utilizing the restriction endonuclease EcoRI. Comparison of the topography of these maps indicates that all phage DNAs posses cohesive ends and a number of EcoRI restriction sites; the fragments are conserved, and the estimated base substitution/nucleotide divergence between these phages is 0.03 to 0.07 based on conserved fragments or between 0.03 and 0.11 based on conserved cleavage sites. These lines of evidence indicate that phi105, rho10, and rho14 are closely related. Double-enzyme digestion analysis reveals that rho14 DNA has unique SalGI and BglII restriction sites and phi105 DNA has a unique SalGI restriction site, making these phages possible cloning vectors for B. subtilis.     

Revised restriction maps of Bacillus subtilis bacteriophage phi 105 DNA.

Physical mapping of Bacillus subtilis temperate phage phi 105 DNA was carried out by using restriction endonucleases EcoRI, SmaI, and KpnI, and a new revised EcoRI cleavage map is presented. In addition, the EcoRI cleavage maps of six specialized transducing phages carrying sporulation genes of B. subtilis were revised.     

Bacteriophage Interference in Bacillus subtilis 168

Strains of Bacillus subtilis lysogenic for temperate bacteriophage SPO2 inhibit the development of bacteriophage phi1. After infection by bacteriophage phi1, DNA and RNA synthesis in the lysogenic host terminates, culminating in cell death. Bacteriophage SPO2 also prevents the production of bacteriophage phi105. Mechanisms for these two types of bacteriophage interference are discussed.