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

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.

Specialized transduction of the ilvD-thyB-ilvA region mediated by Bacillus subtilis bacteriophage SP beta

Specialized transducing SP beta particles were found that carried the Bacillus subtilis genes lying to the left of the prophage attachment site. Three classes of transducing particles were differentiated, depending upon whether they carried ilvA only, thyB and ilvA, or ilvD, thyB, and ilvA. Lysates prepared by the induction of strains that carried both a transducing phage and a plaque-forming phage contained the two particles in a ratio of about 1:3,000. When the transducing particles were used to transduce a phage-sensitive auxotrophic strain to prototrophy, some of the transductants carried only the transducing phage genomes which, by themselves, were defective. One putative nondefective transducing phage (for ilvA only) is also described. SP beta can mediate specialized transduction even in the absence of the major (recE) bacterial recombination system.

Genetic structure and internal rearrangements of stable merodiploids from Bacillus subtilis strains carrying the trpE26 mutation

Transformation and transduction to tryptophan independence of strains of Bacillus subtilis carrying the "trpE26" chromosomal aberrations (a translocation and an inversion) with a "normal" 168 type strain as donor induce a tandem duplication of the thrA-ilvA region of the chromosome. The clones possessing this unstable duplication segregate besides the Trp- some stable Trp+ cells which retain only part of the duplication (the trpE-ilvA region) in nontandem configuration. Such clones may also be produced directly during the crosses. The genetic map of these clones (designated as class I stable merodiploids) was constructed: they possess the translocation and the inversion of the trpE26 parental strain. Another type of stable Trp+ clones (class II) also appears, although more rarely, in similar crosses. Studies on their genetic structure revealed that they are haploid for the trpE-ilvA region and carry a nontandem duplication of the thrA-trpE region. In these clones the cysB-tre region has the orientation of the 168 type strain. The duplications in both classes are stable, that of class I being more stable than that of class II where loss of one copy of the thrA-trpE region leads to about 1% haploid cells. Detailed genetic studies on heterozygous clones from both classes have shown exchange of alleles between copies of the nontandem duplications. Models are proposed for the formation of each class of merodiploids and for recombination events taking place in them. These models imply recombination at sequences of intrachromosomal homology and (or) introduction of heterologous junctions ("novel joints") by transformation or transduction.

Attachment of the chromosomal terminus of Bacillus subtilis to a fast-sedimenting particle

After gently lysed protoplasts of exponential phase cells of Bacillus subtilis were treated with restriction endonuclease BamHI, 99% of the DNA did not sediment with the plasma membrane. This DNA was fractionated on sucrose gradients into (i) a fast-sedimenting fraction highly enriched for genes from the origin and terminus (purA and ilvA), (ii) a 50 to 100S component also enriched for purA and ilvA, and (iii) the bulk of the DNA. The fast-sedimenting fraction was dissociated by Sarkosyl; this fraction contained a substantial amount of protein and is probably a membrane subparticle. The S value of the 50 to 100S component was not greatly affected by Sarkosyl treatment, but these particles were unable to penetrate an agarose gel during electrophoresis and were retained by nitrocellulose filters. The terminus DNA in the fast-sedimenting fraction and the 50 to 100S component contained a large restriction fragment (1.5 x 10(7) to 2.0 x 10(7) daltons) encoding ilvA, thyB, and ilvD. The bulk of the SP beta prophage and metB, which lie to the right and left, respectively, of the ilvA-ilvD cluster, were not part of the complex. citK, which lies to the right of SP beta, appeared to be present in the fast-sedimenting complexes. The neighboring genes kauA and gltA were not part of the fast-sedimenting complexes. The presence of terminus DNA in the fast-sedimenting components was also demonstrated by a radiochemical method.

Glutamine synthetase subunit mixing and regulation in Bacillus subtilis partial diploids

A specialized transducing phage, SP beta c2 dglnA2, of Bacillus subtilis was used to construct partial diploids with various glutamine auxotrophs. The overproduction of manganese-stimulated glutamine synthetase no longer occurred in the diploids. The kinetics of heat inactivation of the enzyme extracted from two diploids suggests that there was subunit mixing.

Defective specialized SP beta transducing bacteriophages of Bacillus subtilis that carry the sup-3 or sup-44 gene

We isolated defective specialized transducing phages of SP beta that carry one of the extracistronic suppressors, sup-3 or sup-44. Lysates containing these phages can be used in a simple spot test to determine whether an auxotrophic mutation can be suppressed. The sup-3 and sup-44 mutations are distinct, in that their suppression patterns differ for the markers hisA1, metC3, and thr-5; and they are not alleles.

Integration of the bacteriophage phi 3T-coded thymidylate synthetase gene into the Bacillus subtilis chromosome

Transformation of Bacillus subtilis 168 Thy- auxotrophs with phi 3T deoxyribonucleic acid (DNA) to thymine independence was found to involve site-specific recombination of phi 3T DNA sequences with their homologous counterparts in the bacterial chromosome. During the transformation, the phage phi 3T-encoded thymidylate synthetase gene, thyP3, was shown to integrate at two genetically distinct sites in the B. Subtilis 168 chromosome. The first site was identified to be in the bacterial thymidylate synthetase gene, thyA. The second site was in a prophage (SPB) known to be carried in the host genome. The frequency of the integration of the thyP3 gene at each of the two loci and some of the parameters affecting this frequency were studied. The common origin of the thyP3 and thyA genes and their molecular evolution are also reported.

Distribution of bacteriophage phi 3T homologous deoxyribonucleic acid sequences in Bacillus subtilis 168, related bacteriophages, and other Bacillus species

The Bacillus subtilis 168 chromosome was found to share extensive homology with the genome of bacteriophage phi 3T. At least three different regions of the bacterial genome hydridized to ribonucleic acid complementary to phi 3T deoxyribonucleic acid (DNA). The thymidylate synthetase gene, thyA, of B. subtilis and the sequences adjacent to it were shown to be homologous to the region in the phi 3T DNA containing the phage-encoded thymidylate synthetase gene, thyP3. SP beta, a temperate bacteriophage known to be integrated into the B. subtilis 168 chromosome, was demonstrated to be closely related to phi 3T. Other regions of the bacterial genome were also found to hybridize to the phi 3T probe. The nature and location of these sequences in the bacterial and phage chromosomes were not identified. It was shown however, that they were not homologous to either the thyP3 gene or the DNA surrounding the thyP3 gene. The chromosomes of other Bacillus species were also screened for the presence of phi 3T homologous sequences, and the thyP3 gene was localized in the linear genomes of phages phi 3T and rho 11 by heteroduplex mapping. It is suggested that the presence of sequences of phage origin in the B. subtilis 168 chromosome might contribute to the restructuring and evolution of the viral and bacterial DNAs.

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.

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

The restriction fragment patterns of two mutants forms of the temperate Bacillus subtilis bacteriophage SP beta have been examined. The DNA of a heat-inducible mutant, SP beta c2, which has a molecular size of 128 kilobases (kb), yields the same restriction pattern as the wild type SP beta c+ DNA. The DNA of a clear-plaque mutant, SP beta c1, has a molecular size of 117 kb, and is deleted for an 11 kb region of phage DNA. Neither SP beta c1 nor SP beta c2 DNA is cleaved by the endonuclease HaeIII.

Restriction and modification in Bacillus subtilis: gene coding for a BsuR-specific modification methyltransferase in the temperate bacteriophage phi 3T

The resistance of Phi3T DNA to degradation by the restriction enzyme BsuR or its isoschizomer HaeIII is due to obligatory modification of such DNA. Biochemical and genetical experiments indicate that Phi3T codes for a methyltransferase, which methylates Phi3T DNA itself or heterologous DNA at target sites 5'-GG(*)CC.

A genetic engineering manifesto for the genus Bacillus

The genus Bacillus is widely studied in industry and academia because of the secretion of enzymes and antibiotics. Genetic manipulation is available in several species and genetic engineering capabilities are presently developed or under construction. Bacteriophage cloning vehicles are available which facilitate isolation and selection of individual genes and plasmid cloning vehicles are available for amplification of genes and gene products. The application of these techniques to industrially important genes is just beginning in Bacillus and continued genetic engineering in this genus promises to enhance production of numerous products in the near future.

Restriction and modification in Bacillus subtilis: identification of a gene in the temperate phage SP beta coding for a BsuR specific modification methyltransferase

A gene coding for a modifying DNA-methyltransferase which methylates the central C in the BsuR recognition sequence 5'GGCC was identified in the genome of the temperature Bacillus subtilis phage SP beta. This gene is expressed only after induction of the prophage by either mitomycin C or UV. The presence of active methyltransferase in induced cells leads to modification of BsuR recognition sites in SP beta DNA as well as in heterologous DNA.

Specific labeling of the Bacillus subtilis chromosome terminus

The deoxyribonucleic acid labeled by a procedure described previously for labeling the chromosomal terminus of B. subtilis 168 was substantially enriched for sequences homologous to bacteriophages SP beta and phi 3T, which integrate in the terminal region.

Genetics of the alpha-ketoglutarate dehydrogenase complex of Bacillus subtilis

The enzymatic defects in a number of Bacillus subtilis mutants of the alpha-ketoglutarate dehydrogenase complex lacking activity have been investigated. Mutants in the citK locus, as well as a series of deletions of unknown length covering the citK locus, are deficient in E1 of the complex, alpha-ketoglutarate dehydrogenase, but have normal activities of E2, dehydrolipoyl transsuccinylase, and E3, lipoamide dehydrogenase. The citK mutants and the citL22 mutant show in vitro complementation of alpha-ketoglutarate dehydrogenase complex activity. The citL22 mutant is severely deficient in lipoamide dehydrogenase activity, and, as a result, lacks activity for both the alpha-ketoglutarate and the pyruvate dehydrogenase complexes. Thus, the E3 components of both complexes are identical. The citL22 mutation maps between ura and metC on the chromosome.

Macromolecular synthesis in chromosome initiation mutants of Bacillus subtilis

Inactivation of the dna B or dna D gene product in Bacillus subtilis stimulates RNA and protein synthesis. Strains containing ts dna B and D mutations have been constructed by introducing the mutations by transformation into a thymine requiring strain which does not lyse during thymine starvation. The consequences of inactivation of these gene products have been assessed by comparing RNA and protein synthesis during thymine starvation at the restrictive temperature with the recipient strain. In the ts+ strain, there is a doubling in rate of RNA synthesis during thymine starvation. In the ts dna B and D mutations at the restrictive temperature the rate of RNA synthesis increases four fold. By preincubating the mutants in the absence of thymine for one generation at the permissive temperature the two fold increase in rate of RNA synthesis associated with inactivation of the initiation complex can be demonstrated under conditions where the ts+ strain shows a decrease in rate of RNA synthesis. The rate of protein synthesis observed largely reflects the rate of RNA synthesis in all strains. Completion of the chromosome at the restrictive temperature has no significant effect on the rate of RNA synthesis. It is suggested that inactivation of the initiation complex after chromosome initiation could play an important role in control of RNA synthesis in relation to the cell cycle.

Selective plasmid transduction in Bacillus pumilus

The inducible temperate bacteriophage phi75 and a clear-plaque-forming variant, phi75C1, mediated transduction of a 4.4 X 10(6)-dalton multicopy Bacillus pumilus plasmid, pPL10, at frequencies of 10(-5) to 10(-6) transductants per plaque-forming unit. phi75- and phi75C1-mediated transduction of several chromosome markers tested did not occur at a detectable frequency. phi75-mediated plasmid transducing activity resides in particles that are similar to infectious particles in sedimentation velocity and buoyant density.