The BceRS two-component regulatory system induces expression of the bacitracin transporter,BceAB, in Bacillus subtilis

BceA and bceB encode a nucleotide-binding domain (NBD) and membrane-spanning domain (MSD) subunit, respectively, of an ATP-binding cassette (ABC) transporter in Bacillus subtilis. Disruption of these genes resulted in hypersensitivity to bacitracin, a peptide antibiotic that is non-ribosomally synthesized in some strains of Bacillus. Northern hybridization analyses showed that expression of the bceAB operon is induced by bacitracin present in the growth medium. The bceRS genes encoding a two-component regulatory system are located immediately upstream of bceAB. Deletion analyses of the bceAB promoter together with DNase I footprinting experiments revealed that a sensor kinase, BceS, responds to extracellular bacitracin either directly or indirectly and transmits a signal to a cognate response regulator, BceR. The regulator binds directly to the upstream region of the bceAB promoter and upregulates the expression of bceAB genes. The bcrC gene product is additionally involved in bacitracin resistance. The expression of bcrC is dependent on the ECF sigma factors, sigmaM and sigmaX, but not on the BceRS two-component system. In view of these results, possible roles of BceA, BceB and BcrC in bacitracin resistance of B. subtilis 168 are discussed.     

Partial nucleotide limitation induces phosphodiesterase I and 5'-nucleotidase in Bacillus subtilis.

Changes in the specific activity of enzymes involved in the degradation of RNA and nucleotides were measured in Bacillus subtilis under conditions of guanine deprivation, which initiates sporulation, and uracil deprivation, which does not initiate sporulation. Whereas the specific activities of most of the enzymes studied increased by less than a factor of 3, those of 5'-mononucleotide-producing phosphodiesterase and 5'-nucleotidase increased at least eightfold under both deprivation conditions.     

Acrylonitrile induces autolysis Bacillus subtilis

Acrylonitrile (AN) is an industrial chemical used in the manufacture of plastics and other polymers. AN has been reported to be an acute toxin and is a known carcinogen in rodents. When AN was mixed with suspensions of Bacillus subtilis, the bacteria began autolysis. It was determined that AN is partially converted to cyanide, a strong protonophore in B. subtilis. Autolytic enzymes in B. subtilis become active when the protonmotive force is dissipated. The amount of cyanide produced from AN, however, was not enough to promote autolysis in exponential B. subtilis. This is the first report showing that AN may induce autolytic reactions in bacteria. It is suggested the autolysis of B. subtilis may be useful in the environmental monitoring of AN. In addition, the metabolism of AN by bacilli may be useful in bioremediation.     

Mechanism of expression of the overlapping genes of Bacillus subtilis aspartokinase II

The mechanism of expression of the overlapping genes that encode the alpha and beta subunits of aspartokinase II of Bacillus subtilis was studied by specific mutagenesis of the cloned coding sequence. Escherichia coli or B. subtilis VB31 (aspartokinase II-deficient), transformed with plasmids carrying either a deletion of the translation start site and about one-half of the coding region for the larger alpha subunit or a frameshift mutation early in the alpha subunit coding region, produced the smaller beta subunit in the absence of alpha subunit synthesis, indicating that beta subunit is not derived from alpha subunit and that its synthesis does not depend on the alpha subunit translation initiation site. The beta subunit translation start site was identified by oligonucleotide-directed mutagenesis of the putative translation start codon. Modification of the nucleotide sequence encoding methionine residue 247 of the alpha subunit from ATG to either TTA or AAT (but not GTG) abolished beta subunit synthesis but had no effect on the production of alpha subunit. This observation is consistent with peptide chain initiation by N-formylmethionine, which specifically requires an ATG or GTG sequence, and indicates that translation of the beta subunit starts at a site corresponding to Met247 of the alpha subunit. Initial studies on the function of the aspartokinase II subunits, using E. coli as a heterologous host, showed that beta subunit was not essential for the expression of the catalytic function of aspartokinase, measured in vitro and in vivo, nor for its allosteric regulation by L-lysine. Whether the beta subunit has a function specific to B. subtilis needs to be explored in a homologous expression system.     

Vegetative expression of the delta-endotoxin genes of Bacillus thuringiensis subsp. kurstaki in Bacillus subtilis.

Bacillus thuringiensis subsp. kurstaki total DNA was digested with BglII and cloned into the BamHI site of plasmid pUC9 in Escherichia coli. A recombinant plasmid, pHBHE, expressed a protein of 135,000 daltons that was toxic to caterpillars. A HincII-SmaI double digest of pHBHE was then ligated to BglII-cut plasmid pBD64 and introduced into Bacillus subtilis by transformation. The transformants were identified by colony hybridization and confirmed by Southern blot hybridization. A 135,000-dalton protein which bound to an antibody specific for the crystal protein of B. thuringiensis was detected from the B. subtilis clones containing the toxin gene insert in either orientation. A toxin gene insert cloned into a PvuII site distal from the two drug resistance genes of the pBD64 vector also expressed a 135,000-dalton protein. These results suggest that the toxin gene is transcribed from its own promoter. Western blotting of proteins expressed at various stages of growth revealed that the crystal protein expression in B. subtilis begins early in the vegetative phase, while in B. thuringiensis it is concomitant with the onset of sporulation. The cloned genes when transferred to a nonsporulating strain of B. subtilis also expressed a 135,000-dalton protein. These results suggest that toxin gene expression in B. subtilis is independent of sporulation. Another toxin gene encoding a 130,000- to 135,000-dalton protein was cloned in E. coli from a library of B. thuringiensis genes established in lambda 1059. This gene was then subcloned in B. subtilis. The cell extracts from both clones were toxic to caterpillars. Electron microscope studies revealed the presence of an irregular crystal inclusion in E. coli and a well-formed bipyramidal crystal in B. subtilis clones similar to the crystals found in B. thuringiensis.     

Cloning and expression of the Arthrobacter globiformis fcb genes in Bacillus subtilis]

The fcb genes of Arthrobacter globiformis KZT1 coding for the dehalogenase (4-chlorobenzoate-4-hydroxylase) activity have been cloned. The characteristics of fcb genes expression have been studied. The recombinant strains of Bacillus subtilis 6JM15 (pCBS 311) and 6JM15 (pCBS1) have shown the decreased level of substrate dehalogenation as compared with the one in the parent strain KZT1 and the recombinant strains of Escherichia coli and Pseudomonas putida.     

Heterologous expression of Bacillus intermedius gene of glutamyl endopeptidase in Bacillus subtilis strains defective in regulatory proteins

Expression of the gene of glutamyl endopeptidase from Bacillus intermedius (gseBi) cloned on the plasmid pV has been studied in Bacillus subtilis recombinant strains with mutations of the regulatory proteins involved in sporogenesis and spore germination. It has been established that inactivation of the regulatory protein Spo0A involved in sporulation initiation resulted in a decrease in the expression of the gseBi gene by 65% on average. A mutation in the gene of the sensor histidine kinase kinA had no effect on the biosynthesis of the enzyme. Inactivation of Ger proteins regulating bacterial spore germination resulted in a 1.5-5-fold decrease in glutamyl endopeptidase activity. It has been concluded that expression of the B. intermedius glutamyl endopeptidase gene from plasmid pV in recombinant cells of B. subtilis is under impaired control by the regulatory system of Spo0F/Spo0A phosphorelay, which participates in sporulation initiation. The regulatory Ger proteins responsible for spore germination also affect expression of the gene of this enzyme.     

Terminal oxidases are essential to bypass the requirement for ResD for full Pho induction in Bacillus subtilis

The Bacillus subtilis Pho signal transduction network, which regulates the cellular response to phosphate starvation, integrates the activity of three signal transduction systems to regulate the level of the Pho response. This signal transduction network includes a positive feedback loop between the PhoP/PhoR and ResD/ResE two-component systems. Within this network, ResD is responsible for 80% of the Pho response. To date, the role of ResD in the generation of the Pho response has not been understood. Expression of two terminal oxidases requires ResD function, and expression of at least one terminal oxidase is needed for the wild-type Pho response. Previously, our investigators have shown that strains bearing mutations in resD are impaired for growth and acquire secondary mutations which compensate for the loss of the a-type terminal oxidases by allowing production of cytochrome bd. We report here that the expression of cytochrome bd in a DeltaresDE background is sufficient to compensate for the loss of ResD for full Pho induction. A ctaA mutant strain, deficient in the production of heme A, has the same Pho induction phenotype as a DeltaresDE strain. This demonstrates that the production of a-type terminal oxidases is the basis for the role of ResD in Pho induction. Terminal oxidases affect the redox state of the quinone pool. Reduced quinones inhibit PhoR autophosphorylation in vitro, consistent with a requirement for terminal oxidases for full Pho induction in vivo.     

Molecular characterization of regulatory elements controlling expression of the Bacillus subtilis recA+ gene.

Expression of the Bacillus subtilis recA gene is induced following DNA damage as well as during the development of the competent state. DNA damage-induction of the recA gene occurs by a RecA-dependent mechanism, whereas competence-induction occurs by a RecA-independent mechanism. To examine the molecular mechanisms that control the expression of the recA gene, a deletion analysis of the recA promoter region was performed. A regulatory region that is required for repression of recA expression was identified upstream of the recA promoter. Deletion of this regulatory region derepressed expression and abolished damage-induction of the recA promoter. Within this region are sequences similar to the consensus sequence that has been identified within DNA damage-inducible promoter regions of other B subtilis genes. Another regulatory region was identified that is required for the RecA-independent, competence-specific induction of the recA gene. Deletion of these sequences significantly reduced competence-induction of the recA promoter.     

Prochymosin expression in Bacillus subtilis

Prochymosin (PC) sequence was cloned in Bacillus subtilis using two kinds of plasmid constructions. In plasmid pSM316 the cDNA was inserted to obtain the intracellular expression of the enzyme. The enzyme turned out to be expressed in an insoluble form which could be converted to native enzyme under proper denaturing and refolding conditions. The levels of intracellular expression of PC were further enhanced by modifying the 5' region of the gene in a way that a two-cistron expression system was created. For the PC secretion, the cDNA was fused to the subtilisin leader sequence and expressed under the control of the B. subtilis neutral protease promoter. A properly folded PC was secreted by the cells, although to low levels.     

Regulated expression of heterologous genes inBacillus subtilis using the Tn10 encodedtet regulatory elements

Summary TheEscherichia coli-derivedtet regulatory elements from Tn10 have been used to construct vectors allowing the regulated, inducible, high-level expression of foreign genes inBacillus subtilis. While the wild-typetet promoters are inactive inB. subtilis, a synthetic mutanttet sequence with improved promoter consensus sequences and upstream poly A blocks shows activity inB. subtilis. The expression of an indicatorcat gene is inducible by sublethal amounts of tetracycline, indicating that the Tet repressor protein and thetet operator sequences are functional. However, the inducibility and maximal expression are not sufficient in this construct. To improve these properties atet operator sequence was placed between the —35 and —10 boxes of theB. subtilis-derived very strongxyl promoter. In the presence of atetR gene this construct is about 100-fold inducible and has high promoter strength, but some basal expression. This is avoided by placing a secondtet operator downstream resulting in no detectable basal expression at the expense of reduced inducibility. Using the system with a singletet operator inducible expression of glucose dehydrogenase fromB. megaterium was obtained at a very high level, and inducible expression of human single-chain urokinase-like plasminogen activator was achieved at the same level as inE. coli. Unlike inE. coli, the product was not degraded up to 4 h after induction inB. subtilis. These results demonstrate that the regulated expression vector described here should be very useful for production of foreign gene products fromB. subtilis cultures.     

Heterospecific expression of the Bacillus subtilis cell shape determination genes mreBCD in Escherichia coli

The divIVB operon of Bacillus subtilis includes the cell shape-associated mre genes, including the membrane-associated proteins MreC and MreD. TnphoA mutagenesis was utilized to analyze a topological model for MreC. MreC has a short cytoplasmic amino terminus, a single membrane-spanning domain, and a large carboxy terminal domain which lies externally to the outer leaflet of the cell membrane. Expression of the B. subtilis MreB protein, or the Mre C and D proteins, results in a morphological conversion of the Escherichia coli host cells from a rod to a roughly spherical cell, morphologically similar to mre-negative mutants of E. coli. Immunolocalization of the MreC protein in B. subtilis revealed that this protein is found at the midcell division site of the bacterial cells, consistent with the postulated role of the Mre proteins in the regulation of septum-specific peptidoglycan synthesis.