Characterization of interspecific plasmid transfer mediated by Bacillus subtilis temperate bacteriophage SP02.

Plasmid pPL1010 is a 7.0-kilobase derivative of plasmid pUB110 that harbors the cohesive end site of the bacteriophage SP02 genome. Plasmid pPL1017 is a 6.8-kilobase derivative of plasmid pC194 that contains the immunity region of bacteriophage phi 105 and the cohesive end site of bacteriophage SP02. These plasmids are transducible by bacteriophage SP02 at a frequency of 10(-2) transductants per PFU among mutant derivatives of Bacillus subtilis 168 and have been transferred to other strains of B. subtilis and B. amyloliquefaciens by means of bacteriophage SP02-mediated transduction, with frequencies ranging from 10(-5) to 10(-7) transductants per PFU. The introduced plasmids were stably maintained in nearly all new hosts in the absence of selective pressure. An exception was found in B. subtilis DSM704, which also harbored three cryptic plasmids. Plasmids pPL1010 and pPL1017 were incompatible with a 7.9-kilobase replicon native to strain DSM704. Furthermore, plasmid pPL1017 was processed by strain DSM704 into a approximately 5.3-kilobase replicon that was compatible with the resident plasmid content of strain DSM704. The use of bacteriophage SP02-mediated plasmid transduction has allowed the identification of Bacillus strains that are susceptible to bacteriophage SP02-mediated genetic transfer but cannot support bacteriophage SP02 lytic infection.     

Insertion of bacteriophage SP beta into the citF gene of Bacillus subtilis and specialized transduction of the ilvBC-leu genes.

We isolated a strain of Bacillus subtilis in which the SP beta c2 prophage is inserted into the citF (succinate dehydrogenase) gene. Defective specialized transducing particles for the ilvBC-leu genes were isolated from phage-induced lysates of this lysogen. We isolated a group of phages that differ in the amount of genetic material they carry from this region. Also, we incorporated mutant ilv and leu alleles into the genomes of several transducing phages. Our phage collection enables us to identify the cistron of new ilv and leu mutations by complementation analysis. In this process we discovered a fourth leu cistron, leuD. Characterization of the phages confirmed the published gene order: ilvB-ilvC-leuA-leuC-leuB; leuD lies to the right of leuB.     

The role of temperate bacteriophage SP beta in prophage-mediated interference in Bacillus subtilis.

Virulent bacteriophage phi 1 grows on a variety of Bacillus subtilis strains, mutants of this virus which abortively infect the transformable bacillus. B. subtilis 168, while retaining the ability to productively infect related bacteria have been found. In the present study, we demonstrate that the inability of one such variant, phi 1m, to develop normally in strain 168 is mediated by cryptic prophage SP beta. The latter is a temperate bacteriophage which is carried by B. subtilis 168 and most strains derived from this bacterium. Phi 1 m infection of SP beta lysogens begins with apparently normal adsorption, penetration, and inititaion of virus-directed syntheses. At about the 20th min of the latent period, however, there is an abrupt cessation of nucleic acid synthesis and cellular respiration, accompanied by a change in cell permeability. This course of events can be altered to a permissive infection by mutation in the mpi gene of SP beta, by mutation in the spoOA gene of the host, or by growing SP beta lysogens at high temperature. In addition, we found a second class of phi 1 mutants which abortively infect B. subtilis 168 derivatives even in the absence of the SP beta prophage.     

Predominance of bacteriophage SP82 over bacteriophage SP01 in mixed infections of Bacillus subtilis

In mixed infections with Bacillus subtilis phages SP82 and SP01, the SP82 genotype is predominant among the progeny. This predominance is determined by a specific region of the genome, the pos region, which apparently is located near genes 29 to 32 (by the SP01 numbering system). Recombination between SP82 and SP01 yields phage which have both the SP82 pos region and an SP01 mutation. This mutation then behaves in mixed infection as if it were part of an SP82 genome.     

Control of lysogeny and immunity of Bacillus subtilis temperate bacteriophage SP beta by its d gene.

The d gene from the Bacillus subtilis temperate bacteriophage SP beta was isolated. When introduced into an SP beta-sensitive strain of B. subtilis, the cloned d gene directed the synthesis of a 22-kilodalton protein and conferred on the host immunity to SP beta phage. A frameshift mutation, designated d2, was introduced into the cloned d gene, and it was subsequently crossed back into the SP beta phage genome. The resulting SP beta phage grew lytically and formed clear plaques on sensitive bacteria. Although the cloned d gene confers immunity to the host, we could not detect complementation of the d gene by mixed infection with SP beta d2 and various SP beta c mutants. The nucleotide sequence of the 1,033-base-pair PstI-to-EcoRI fragment containing the d gene was determined; it includes an open reading frame that could potentially encode a protein of 227 amino acids. The gene was mapped within the PstI H fragment on the phage genome, which positions the d gene about 25 kilobases from the right end of the phage genome. It is transcribed from right to left.     

Bacillus subtilis bacteriophages SP beta c1 is a deletion mutant of SP beta

Summary The restriction fragment patterns of two mutant forms of the temperate Bacillus subtilis bacteriophage SP have been examined. The DNA of a heat-inducible mutant, SPc2, which has a molecular size of 128 kilobases (kb), yields the same restriction pattern as the wild type SPc⁺ DNA. The DNA of a clear-plaque mutant, SPc1, has a molecular size of 117 kb, and is deleted for an 11 kb region of phage DNA. Neither SPc1 nor SPc2 DNA is cleaved by the endonuclease HaeIII.     

DNA gyrase inhibitors block development of Bacillus subtilis bacteriophage SP01

SP01 development was inhibited by nalidixic acid and novobiocin in the sensitive host Bacillus subtilis 168M. Inhibition by novobiocin was prevented by a Novr mutation in the cellular DNA gyrase gene. Nalidixic acid inhibition persisted in hosts carrying a Nalr gyrase, but could be overcome by phage mutation. We conclude that SP01 requires for its development subunit B of the host DNA gyrase, but replaces or modifies subunit A.     

Trans-translation mediated by Bacillus subtilis tmRNA

Trans-translation, in which a ribosome switches between translation of an mRNA and a tmRNA, produces a chimera polypeptide of an N-terminal truncated polypeptide and a C-terminal tag-peptide encoded by tmRNA. One of the tmRNA binding proteins, a ribosomal protein S1, has not been found in a group of Gram-positive bacteria. In this study, the trans-translation reaction with tmRNA from Bacillus subtilis belonging to this group was examined. When a truncated gene lacking a termination codon was expressed in B. subtilis, a 15-amino acid tag-peptide derived from tmRNA was identified in the C-termini of the trans-translation products. An identical tag-peptide was also found at the C-termini of the products from a truncated gene, when it was coexpressed with B. subtilis tmRNA in Escherichia coli. B. subtilis tmRNA was functional, although much less efficiently, in the in vitro poly(U)-dependent tag-peptide synthesis system of E. coli. A comparison of two bacterial tmRNAs suggests that the rule for determining the tag-initiation point on tmRNA may be the same in Gram-positive and Gram-negative bacteria.     

Interaction between bacteriophage PBS1 and clay minerals and transduction of Bacillus subtilis by clay-phage complexes

Bacteriophage PBS1 of Bacillus subtilis was rapidly adsorbed on montmorillonite (M) and kaolinite (K), and adsorption was maximal after 30 min on both clays. There was no correlation between adsorption and the cation exchange capacity of the clays. Studies with sodium metaphosphate (a polyanion that interacts with positively charged sites on clay) indicated that positively charged sites on K were primarily responsible for the adsorption of the phage, whereas other mechanisms appeared to be involved in adsorption of the phage on M. X-ray diffraction and electron microscopic analyses showed that the phage partially intercalated M. Survival of the phage was increased by adsorption on the clays, and adsorbed phage maintained its ability to transduce bacterial cells for at least 30 days (the longest time studied) after the preparation of the clay–phage complexes. Electron microscopic observations indicated that transduction by the clay–phage complexes was primarily the result of the phage detaching from the clays in the presence of host cells.     

Plasmid transduction by Bacillus anthracis bacteriophage CP54

Possibility of plasmid transduction in Bacillus anthracis vaccine strains Sterne and STI-1 by bacteriophage CP54ant having an increased ability of adsorbtion and a shortened period of latent development in Bacillus anthracis cells has been isolated. The main parameters of plasmid transduction by the bacteriophage have been established for the plasmid pTG141 (TcR). They include the effect of multiplicity of infection, the level of UV-inactivation of bacteriophage, the presence of antiphage serum in the incubation medium. Plasmid transduction by the mutant phage CP54ant was found to be more efficient as compared with the one by the parent phage. The isolated transductants served as donors of the transduced plasmid for Bacillus anthracis and Bacillus thuringiensis strains.     

Peptide syntheses mediated by Bacillus subtilis protease

Summary Bacillus subtilis protease (Amano protease N) was examined as a catalyst for peptide bond formationvia both the kinetically and thermodynamically controlled approaches. In general, the latter approach proved to be superior to the former, and a series of dipeptide syntheses and several segment condensations were achieved in good to high yields using the immobilized enzyme on Celite in acetonitrile with low water content.     

Specialized transduction of Pseudomonas aeruginosa PAO by bacteriophage D3.

D3, a temperate bacteriophage of Pseudomonas aeruginosa PAO, was found to specifically transduce the alleles met-49 and met-117. Induction of established lysogens with UV light was necessary for the production of transducing lysates. Transduced cells were immune to superinfection by phage D3 and could give rise to high-frequency transducing lysates. Cotransduction of these two alleles could not be demonstrated. met-117 was mapped to 26 min on the PAO genetic map. Complementation studies using the generalized transducing phage F116L indicated that met-49 is an allele of met-9011 which maps at 55 min. The integrated D3 prophage was shown to be coinherited with met-117 and with met-49.     

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.     

Bacillus subtilis bacteriophage SPbeta: localization of the prophage attachment site, and specialized transduction.

The attachment site for the prophage of SPbeta lies between ilvA and kauA on the chromosome of Bacillus subtilis strain 168. Specialized transduction of citK and kauA can be carried out by certain lysates of SPbeta.     

Plasmid DNA transduction in Bacillus subtilis

Transduction of Bacillus subtilis pUB110 plasmid by AR9 phage is described. Some aspects of this process are studied. Plasmid transduction depended on multiplicity of infection similar to cases of chromosomal markers transduction, though optimal multiplicity of infection was achieved using low number of phage particles. No cotransduction of plasmid and chromosomal markers was demonstrated. The transduction frequencies of plasmid and chromosomal markers increased after UV irradiation of phage suspensions within the range of definite doses.