Restriction enzyme analysis of Bacillus subtilis bacteriophage phi 105 DNA

The recognition sites on phi 105 DNA for the restriction endonucleases EcoRI, Bg/II, SmaI, KpnI, SstI, SalI, XhoI, NcoI, PstI, HindIII, ClaI, EcoRV and MluI have been mapped. The sites for EcoRI are shown to be different from those published earlier. The DNA from phi 105 contains no recognition sites for the endonucleases BamHI and XbaI.     

Correlated genetic and EcoRI cleavage map of Bacillus subtilis bacteriophage phi105 DNA.

The seven previously identified EcoRI cleavage fragments of phi 105 DNA were ordered with respect to their sites of origin on the phage genome by marker rescue. One fragment, H, did not carry any determinants essential for replication. This fragment was totally missing in a deletion mutant which exhibited a lysogenization-defective phenotype. There is a nonessential region on the phi 105 genome which begins in fragment B, spans fragment H, and ends in fragment F. The size of the nonessential region, as estimated by alterations observed in the fragmentation patterns of deletion mutant DNAs, is approximately 2.7 X 10(6) daltons. Two new EcoRI cleavage fragments with molecular weights of approximately 0.2 X 10(6) were detected by autoradiography of 32P-labeled DNA. These small fragments were not located on the cleavage map.     

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.     

Detection of mutagen-induced lesions in isolated DNA by marker rescue of Bacillus subtilis phage phi 105

A new mutagenesis assay is described which detects the induction of forward mutations in isolated DNA. The assay utilizes replicative from DNA of the temperate Bacillus subtilis phage φ105 and tests the ability of chemicals to induce lesions which inactivate phage genes involved in lysogen formation. There is a cluster of such genes tightly linked to the φ105 genetic marker Jsus11 which restricts the host range of the phage to cells capable of suppressing sus mutations. In the actual assay chemically treated DNA, from wild-type J⁺ phage, is added to competent cells which are infected with φ105Jsus11. Wild-type phage, capable of producing plaques on cells which are nonpermissive for φ105Jsus11, are produced by recombination between the added chemically-treated DNA and infecting φ105Jsus11 DNA. If the added DNA also carried mutagenic lesions in any of the genes controlling lysogeny, clear plaque mutants are produced which are readily distinguishable from the turbid plaquing wild-type phage. This report demonstrates the capacity of this marker rescue-based assay to detect as mutagens the following DNA-reactive chemicals: hydroxylamine (HA); N-methyl-N′-nitro-N-nitrosoguanidine (MNNG); chloroacetaldehyde (CAA); propylene oxide (PO) and N-acetyl-N-acetoxy-2-amino-fluorene (AAAF). The effect of using a host cell, defective for excision repair, on the sensitivity with which the assay detected the mutagenic activities of CAA, PO and AAAF also was examined.The new mutagenesis assay offers 2 advantages over several other previously described transformation-based assays: (1) in contrast to assays based on the induction of ribosome-associated drug resistances, the new assay can detect frameshift as well as base-substitution-type mutagens and (2) the mutants generated can be detected at high plating densities. The assay thus may be useful for general mutagen screening especially with highly bactericidal compounds which are not readily tested in other microbial assays.     

A novel DNA polymerase induced by Bacillus subtilis phage phi 29.

A novel DNA polymerase induced by Bacillus subtilis bacteriophage phi 29 has been identified. This polymerase can be separated from host DNA polymerase, by fractionation of extracts prepared from phage infected cells, using phosphocellulose chromatography. The isolated polymerase prefers poly(dA)oligo(dT) as template. The DNA polymerase isolated from the cells infected with a gene 2 temperature sensitive mutant (ts2) showed greater heat-lability than that induced by wild type phi 29. The ts2 DNA polymerase was also thermolabile for its activity in the formation of a covalent complex between phi 29 terminal protein and dAMP, the initiation step of phi 29 DNA replication. These findings indicate that gene 2 is the structural gene for a phi 29 DNA polymerase required for the complex formation step of DNA initiation.     

Deletion mutants of temperate Bacillus subtilis bacteriophage phi105.

Summary Six deletion mutants of temperate Bacillus subtilis phage 105 have been isolated on the basis of their increased resistance to chelating agents. The size and position of the deletions was determined by electronmicroscopy of DNA heteroduplexes. All deletions are located in a region about 55–70% from one end of the DNA molecule, in the right half of the known genetic map of the phage. The segment 55–65% does not contain any genes essential for lytic growth or lysogenization. A gene(s) for immunity is located in a segment 65–70% from the left end.By electronmicroscopy of partially denatured 105 DNA two A-T rich regions have been localized in the right half of the molecule. One of these regions falls within the non-essential 55–65% DNA segment.     

X-ray scattering of the non-isometric Bacillus subtilis phage phi29.

The non-isometric virus φ29 and its empty capsid have enough elements of symmetry so that their size and approximate shape can be determined by low-angle X-ray scattering. The scattering curve of the virus can be simulated by a cylinder of 390 Å diameter and 460 Å height. The protein coat has a thickness of about 30 Å. The DNA is packed tightly and regularly in the phage head.     

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.     

Upper limit for DNA packaging by Bacillus subtilis bacteriophage phi 105: isolation of phage deletion mutants by induction of oversized prophages

Summary We have determined the upper size limit for DNA packaging in Bacillus subtilis bacteriophage 105 by examining the plaque-forming and transducing capabilities of lysates made from strains containing prophages of various sizes. The upper size limit for efficient packaging of the phage genome appears to be about 40.2 kb, which is about 1 kb larger than the wild-type genome. This places an upper limit of about 5 kb on the size of insertions that can be accommodated in 105 transfection cloning vectors, such as 105J27. Induction of prophages that exceed the upper limit, followed by selection for plaque formation or transduction, provides a powerful means of isolating phage deletion mutants. A comparison of the location of each deletion with the resultant phenotype has enabled us to identify non-essential regions of the phage genome, and regions that are required for tail biosynthesis and for host cell lysis.     

Intracellular effects of phage phi W-14 DNA on transformation of Bacillus subtilis

Summary Uptake of transforming DNA by competent Bacillus subtilis cells in the presence of phage W-14 DNA (in which half the thymine residues are replaced by -putrescinyl-thymine) is accompanied by a decrease in the amount of trichloracetic acid-precipitable label of the former retained by recipient cells during subsequent incubation. Fractionation of lysates of cells incubated for 0.5 min at 37°C after DNA uptake at 30°C in the presence of low concentrations of W-14 DNA (0.1 g/ml) demonstrated the presence of single-stranded transforming DNA molecules, typical for DNA taken up by B. subtilis. The intracellular effect of W-14 DNA was enhanced by an increase in its concentration (to 0.5–1 g/ml), or by increasing the temperature of uptake (to 37°C). With either of these treatments transforming DNA taken up was found in the form of a broad asymmetric band, indicative of degradation, and partially located at the density characteristic for single-stranded molecules. Fractionation of lysates of cells treated (0.1 g/ml) or untreated with W-14 DNA, and incubated for 20 min at 37°C after DNA uptake, showed disappearance of the single-stranded band. Donor DNA label was then found exclusively in the recipient DNA band, its amount being lower in samples treated with W-14 DNA. The influence of a high concentration of W-14 DNA on retention of transforming DNA label was correlated with its effect on transformation. On exposure to low concentrations of phage DNA, such a correlation was observed only after longer periods of incubation, due to slower intracellular degradation of homologous DNA taken up. The results are consistent with the proposal that W-14 DNA-induced reduction in efficiency of transformation is due to intracellular stimulation of transforming DNA degradation, leading to a decrease in the number of donor molecules available for recombination with the recipient chromosome.     

Location of the Bacillus subtilis temperate bacteriophage phi 105 attP attachment site.

Chromosomal DNAs of lysogens of phi 105 and phi 105 DI:1t were digested with restriction enzymes EcoRI and HpaI and were probed with nick-translated mature phi 105 DNA. Altered bacteriophage-specific bands in the lysogens were detected, indicating that the phage integrates into the host chromosome at a single site, probably via a Campbell-type circular intermediate. The phage attachment site is centrally located in the phage genome and lies between the phage immunity region and the nonessential deletable region of phi 105.