Purification of a RecA protein analogue from Bacillus subtilis

We have identified in Bacillus subtilis an analogue of the Escherichia coli RecA protein. Its activities suggest that it has a corresponding role in general genetic recombination and in regulation of SOS (DNA repair) functions. The B. subtilis protein (B. subtilis Rec) has a Mr of 42,000 and cross-reacts with antisera raised against E. coli RecA protein. Its level is significantly reduced in the recombination-deficient recE4 mutant. B. subtilis Rec is induced 10- to 20-fold in rec+ strains following treatment with mitomycin C, whereas it is not induced in the recombination-deficient mutants recE4, recE45, and recA1. We have purified B. subtilis Rec about 2000-fold to near homogeneity and we describe its activities. It catalyzes DNA-dependent hydrolysis of dATP at a rate comparable to that of E. coli RecA protein. However, B. subtilis Rec has a negligible ATPase activity, although ATP effectively inhibits dATP hydrolysis. In the presence of dATP, B. subtilis Rec catalyzes DNA strand transfer, assayed by the conversion of phi X174 linear duplex DNA and homologous circular single-stranded DNA to replicative form II (circular double-stranded DNA with a discontinuity in one strand). ATP does not support strand transfer by this protein. B. subtilis Rec catalyzes proteolytic cleavage of E. coli LexA repressor in a reaction that requires single-stranded DNA and nucleoside triphosphate. This result suggests that an SOS regulatory system like the E. coli system is present in B. subtilis. The B. subtilis enzyme does not promote any detectable cleavage of the E. coli bacteriophage lambda repressor.     

Bacillus subtilis CheD is a chemoreceptor modification enzyme required for chemotaxis

The chemotaxis machinery of Bacillus subtilis is similar to that of the well characterized system of Escherichia coli. However, B. subtilis contains several chemotaxis genes not found in the E. coli genome, such as cheC and cheD, indicating that the B. subtilis chemotactic system is more complex. In B. subtilis, CheD is required for chemotaxis; the cheD mutant displays a tumbly phenotype, has abnormally methylated chemoreceptors, and responds poorly to most chemical stimuli. Homologs of B. subtilis CheD have been found in chemotaxis-like operons of a large number of bacteria and archaea, suggesting that CheD plays an important role in chemotactic sensory transduction for many organisms. However, the molecular function of CheD has remained unknown. In this study, we show that CheD catalyzes amide hydrolysis of specific glutaminyl side chains of the B. subtilis chemoreceptor McpA. In addition, we present evidence that CheD deamidates other B. subtilis chemoreceptors including McpB and McpC. Previously, deamidation of B. subtilis receptors was thought to be catalyzed by the CheB methylesterase, as is the case for E. coli receptors. Because cheD mutant cells do not respond to most chemoattractants, we conclude that deamidation by CheD is required for B. subtilis chemoreceptors to effectively transduce signals to the CheA kinase.     

Nucleotide sequence and characterization of a Bacillus subtilis gene encoding a flagellar switch protein.

The nucleotide sequence of the Bacillus subtilis fliM gene has been determined. This gene encodes a 38-kDa protein that is homologous to the FliM flagellar switch proteins of Escherichia coli and Salmonella typhimurium. Expression of this gene in Che+ cells of E. coli and B. subtilis interferes with normal chemotaxis. The nature of the chemotaxis defect is dependent upon the host used. In B. subtilis, overproduction of FliM generates mostly nonmotile cells. Those cells that are motile switch less frequently. Expression of B. subtilis FliM in E. coli also generates nonmotile cells. However, those cells that are motile have a tumble bias. The B. subtilis fliM gene cannot complement an E. coli fliM mutant. A frameshift mutation was constructed in the fliM gene, and the mutation was transferred onto the B. subtilis chromosome. The mutant has a Fla- phenotype. This phenotype is consistent with the hypothesis that the FliM protein encodes a component of the flagellar switch in B. subtilis. Additional characterization of the fliM mutant suggests that the hag and mot loci are not expressed. These loci are regulated by the SigD form of RNA polymerase. We also did not observe any methyl-accepting chemotaxis proteins in an in vivo methylation experiment. The expression of these proteins is also dependent upon SigD. It is possible that a functional basal body-hook complex may be required for the expression of SigD-regulated chemotaxis and motility genes.     

Characterization of a chimeric proU operon in a subtilin-producing mutant of Bacillus subtilis 168.

The ability to respond to osmotic stress by osmoregulation is common to virtually all living cells. Gram-negative bacteria such as Escherichia coli and Salmonella typhimurium can achieve osmotolerance by import of osmoprotectants such as proline and glycine betaine by an import system encoded in an operon called proU with genes for proteins ProV, ProW, and ProX. In this report, we describe the discovery of a proU-type locus in the gram-positive bacterium Bacillus subtilis. It contains four open reading frames (ProV, ProW, ProX, and ProZ) with homology to the gram-negative ProU proteins, with the B. subtilis ProV, ProW, and ProX proteins having sequence homologies of 35, 29, and 17%, respectively, to the E. coli proteins. The B. subtilis ProZ protein is similar to the ProW protein but is smaller and, accordingly, may fulfill a novel role in osmoprotection. The B. subtilis proU locus was discovered while exploring the chromosomal sequence upstream from the spa operon in B. subtilis LH45, which is a subtilin-producing mutant of B. subtilis 168. B. subtilis LH45 had been previously constructed by transformation of strain 168 with linear DNA from B. subtilis ATCC 6633 (W. Liu and J. N. Hansen, J. Bacteriol. 173:7387-7390, 1991). Hybridization experiments showed that LH45 resulted from recombination in a region of homology in the proV gene, so that the proU locus in LH45 is a chimera between strains 168 and 6633. Despite being a chimera, this proU locus was fully functional in its ability to confer osmotolerance when glycine betaine was available in the medium. Conversely, a mutant (LH45 deltaproU) in which most of the proU locus had been deleted grew poorly at high osmolarity in the presence of glycine betaine. We conclude that the proU-like locus in B. subtilis LH45 is a gram-positive counterpart of the proU locus in gram-negative bacteria and probably evolved prior to the evolutionary split of prokaryotes into gram-positive and gram-negative forms.     

Conversion of Bacillus subtilis 168 to a subtilin producer by competence transformation.

Subtilin is a ribosomally synthesized peptide antibiotic produced by Bacillus subtilis ATCC 6633. B. subtilis 168 was converted to a subtilin producer by competence transformation with chromosomal DNA from B. subtilis ATCC 6633. A chloramphenicol acetyltransferase gene was inserted next to the subtilin structural gene as a selectable marker. The genes that conferred subtilin production were derived from a 40-kb region of the B. subtilis ATCC 6633 chromosome that had flanking homologies to the B. subtilis 168 chromosome. The subtilin produced by the mutant was identical to natural subtilin in its biological activity, chromatographic behavior, amino acid composition, and N-terminal amino acid sequence.     

Assay and characterization of a strong promoter element from B. subtilis

A new strong promoter fragment isolated from Bacillus subtilis was identified and characterized. Using the heat stable beta-galactosidase as reporter, the promoter fragment exhibited high expression strength both in Escherichia coli and B. subtilis. The typical prokaryotic promoter conservation regions were found in the promoter fragment and the putative promoter was identified as the control element of yxiE gene via sequencing assay and predication of promoter. To further verify and characterize the cloned strong promoter, the putative promoter was sub-cloned and the beta-Gal directed by the promoters was high-level expressed both in E. coli and B. subtilis. By means of the isolated promoter, an efficient expression system was developed in B. subtilis and the benefit and usefulness was demonstrated through expression of three heterologous and homogenous proteins. Thus, we identified a newly strong promoter of B. subtilis and provided a robust expression system for genetic engineering of B. subtilis.     

Plasmid transfer in bacilli by a self-transmissible plasmid p19 from a Bacillus subtilis soil strain

The cryptic 95-kb plasmid p19 of the Bacillus subtilis 19 soil strain promotes the transfer of a small kanamycin resistance plasmid pUB110. To facilitate direct selection for p19 transfer, a plasmid derivative carrying the chloramphenicol resistance gene was constructed. The frequency of transfer of the large plasmid between cells of B. subtilis 19 approached 100% but was more than two orders of magnitude lower when the strain B. subtilis 168 was a recipient. However, when the restriction-deficient strain B. subtilis 168 was a recipient, the transfer efficiency was almost completely recovered. The effectiveness of pUB110 mobilization was virtually not altered in all these cases. pC194 was not mobilized by p19. The kinetics of p19 conjugative transfer is also presented.     

Bacillus subtilis generates a major specific deletion in pAM beta 1

pAM beta 1, a 26.5-kilobase plasmid originally isolated from Streptococcus faecalis, was conjugally transferred from Streptococcus lactis to Bacillus subtilis. No conjugal transfer of pAM beta 1 from B. subtilis to S. lactis was observed. In addition, pAM beta 1 which had been reintroduced in S. lactis after cycling through B. subtilis had lost its conjugal transferability to Streptococcus cremoris, although under the same conditions noncycled pAM beta 1 was transferred at high efficiency. Restriction and Southern blot analyses showed that pAM beta 1 had suffered one major, specific 10.6-kilobase deletion and several minor but also specific deletions in B. subtilis. Comparing the major deletion derivative, delta pAM beta 1, with B. subtilis strains which have been reported to contain pAM beta 1 showed that these strains also contained delta pAM beta 1. Hybridization experiments showed that the deleted fragment was not transposed to the B. subtilis chromosome. Based on the size of the minor deletion derivatives from pAM beta 1, it is suggested that these use a different origin of replication in B. subtilis.     

Bacillus subtilis generates a major specific deletion in pAM beta 1.

pAM beta 1, a 26.5-kilobase plasmid originally isolated from Streptococcus faecalis, was conjugally transferred from Streptococcus lactis to Bacillus subtilis. No conjugal transfer of pAM beta 1 from B. subtilis to S. lactis was observed. In addition, pAM beta 1 which had been reintroduced in S. lactis after cycling through B. subtilis had lost its conjugal transferability to Streptococcus cremoris, although under the same conditions noncycled pAM beta 1 was transferred at high efficiency. Restriction and Southern blot analyses showed that pAM beta 1 had suffered one major, specific 10.6-kilobase deletion and several minor but also specific deletions in B. subtilis. Comparing the major deletion derivative, delta pAM beta 1, with B. subtilis strains which have been reported to contain pAM beta 1 showed that these strains also contained delta pAM beta 1. Hybridization experiments showed that the deleted fragment was not transposed to the B. subtilis chromosome. Based on the size of the minor deletion derivatives from pAM beta 1, it is suggested that these use a different origin of replication in B. subtilis.     

Bacillus subtilis contains a cyclodextrin-binding protein which is part of a putative ABC-transporter

Bacillus subtilis is able to grow on alpha-, beta- and gamma-cyclodextrins as a carbon source via a yet unknown metabolizing system. Sequence analysis of the B. subtilis genome reveals that the putative yvfK-yvfO operon seems to be involved in cyclodextrin utilization, containing the open reading frame yvfK, now termed cycB. The amino acid sequence derived from the DNA sequence bears high similarities to solute-binding proteins from B. subtilis, as well as to cymE from Klebsiella oxytoca and malE from Escherichia coli, both encoding solute-binding proteins able to interact with cyclodextrins. A [His](6)-tagged variant of CycB from B. subtilis was constructed, overproduced in E. coli and purified. The modified protein has been used to study its substrate specificity by surface plasmon resonance and fluorescence spectroscopy. From these data, CycB can be classified as a cyclodextrin-binding protein which interacts with all three natural cyclodextrins: alpha, beta and gamma, thereby showing the highest affinity to gamma-cyclodextrin.     

Bacillus subtilis chemotaxis: a deviation from the Escherichia coli paradigm

In Escherichia coli, chemotactic sensory transduction is believed to involve phosphoryl transfer for excitation, and changes in receptor methylation for adaptation. In Bacillus subtilis, changes in degree of receptor methylation do not bring about adaptation. Novel methylation reactions are believed to be involved in excitation in B. subtilis. The main chemotaxis proteins of E. coli--CheA, CheB, CheR, CheW and CheY--are present in B. subtilis but play somewhat different roles in the two organisms. Several unique chemotaxis proteins are also present in B. subtilis. Some of the properties of B. subtilis chemotaxis are also seen in Halobacterium halobium, suggesting that there may be a similar underlying mechanism that predates the evolutionary separation of the bacteria from the archaea and eucarya.     

A polypurine sequence that acts as a 5' mRNA stabilizer in Bacillus subtilis.

A segment of early RNA from Bacillus subtilis bacteriophage SP82 was shown to function as a 5' stabilizer in B. subtilis. Several heterologous RNA sequences were stabilized by the presence of the SP82 sequence at the 5' end, and expression of downstream coding sequences was increased severalfold. The SP82 RNA segment encodes a B. subtilis RNase III cleavage site, but cleavage by B. subtilis RNase III was not required for stabilization. The sequence that specifies 5' stabilizer function was localized to a polypurine sequence that resembles a ribosome binding site. The ability of the SP82 sequence to stabilize downstream RNA was dependent on its position relative to the 5' end of the RNA. These results demonstrate the existence of a new type of 5' stabilizer in B. subtilis and indicate that attack at the 5' end is a principal mechanism for initiation of mRNA decay in B. subtilis.     

Hsp70 is a new target of Sgt1--an interaction modulated by S100A6

Here, two temperature sensitive promoters, P2 and P7, isolated from Bacillus subtilis, were characterized. The production of beta-galactosidase driven by these promoters was much higher at 45 degrees C than that at 37 degrees C both in Escherichia coli and B. subtilis and that the P2 promoter showed higher expression strength in B. subtilis at 45 degrees C. Thereby, an efficient temperature-inducible expression system was constructed by using P2 promoter in B. subtilis. Thus, we isolated and characterized a newly temperature inducible promoter and exploited it as a potential expression element in B. subtilis.     

Molecular cloning in Bacillus subtilis of a Bacillus licheniformis gene encoding a thermostable alpha amylase

A resident-plasmid cloning system developed for Bacillus subtilis has been used to isolate recombinant plasmids carrying DNA from Bacillus licheniformis which confer alpha-amylase activity on alpha-amylase-negative mutants of B. subtilis. These plasmids contain a 3550-bp insert at the EcoRI site of the plasmid pBD64. Subcloning various lengths of the B. licheniformis DNA has localised the gene to a 2550-bp BclI fragment. We present evidence that the cloned fragment codes for a B. licheniformis heat-stable alpha-amylase with a temperature optimum of 93 degrees C. The foreign gene is expressed efficiently in B. subtilis and is stably maintained.     

Nucleotide sequence of a cellulase gene of Bacillus subtilis

The nucleotide sequence of an endolytic cellulase gene of Bacillus subtilis was determined and compared with the NH2-terminal amino acid sequence of the purified enzyme. The mature protein appeared to be extended by a signal sequence of 36 amino acids. The putative AUG initiation codon was preceded by a sigma 43-type promoter of B. subtilis and an AAGGAGG sequence, typical of procaryotic ribosomal binding sites. Partial homology of amino acid sequences was found between B. subtilis cellulase and an alkalophilic Bacillus cellulase.     

Analysis of the function of a putative 2,3-diphosphoglyceric acid-dependent phosphoglycerate mutase from Bacillus subtilis

A Bacillus subtilis gene termed yhfR encodes the only B. subtilis protein with significant sequence similarity to 2, 3-diphosphoglycerate-dependent phosphoglycerate mutases (dPGM). This gene is expressed at a low level during growth and sporulation, but deletion of yhfR had no effect on growth, sporulation, or spore germination and outgrowth. YhfR was expressed in and partially purified from Escherichia coli but had little if any PGM activity and gave no detectable PGM activity in B. subtilis. These data indicate that B. subtilis does not require YhfR and most likely does not require a dPGM.     

Expression of thymidylate synthetase activity in Bacillus subtilis upon integration of a cloned gene from Escherichia coli

The gene from Escherichia coli encoding thymidylate synthetase was cloned in the plasmid pBR322. The resulting chimeric plasmid, pER2, was effective in transforming both E. coli and Bacillus subtilis to thymine prototrophy. Uncloned linear E. coli chromosomal DNA was unable to transform thymine-requiring strains of B. subtilis to thymine independence. Linearization of the chimeric plasmid, pER2, with restriction enzymes markedly diminished its ability to transform B. subtilis auxotrophs. The Thy+ transformants derived from the transformation of B. subtilis with pER2 DNA did not contain detectable extrachromosomal DNA as demonstrated by Southern hybridization patterns and centrifugation in CsCl gradients of DNA isolated from B. subtilis colonies transformed with the chimeric plasmid. We conclude that the DNA from the chimeric plasmid was integrated into the chromosome of B. subtilis, demonstrating that extensive homology is not required for the integration of foreign DNA. This is the first reported case of a gene from a Gram-negative bacterium functioning in a Gram-positive organism.     

The ISBsu2 mobile element is present in a plasmid of a soil strain and in the chromosomes of several other strains of Bacillus subtilis

Chromosomes of several Bacillus subtilis strains were shown to contain homologs of the ISBsu2 mobile genetic element, which was earlier revealed in a cryptic plasmid of a soil strain of B. subtilis.