Sporulation of bacterial species in the presence of metabisulphite

The effect of metabisulphite on the sporulating ability of Bacillus subtilis E52 and B. cereus W18 was studied. Whereas metabisulphite concentrations of 500 and 600 micrograms ml-1 prevented sporulation of B. subtilis and B. cereus, respectively, lower concentrations caused reductions in their percentage sporulations. Glucose dehydrogenase (GDH) and alkaline phosphatase (ALP) activities of both sporulating bacteria were not detected at the stated metabisulphite concentrations. A relationship between the percentage sporulation of the bacteria and the activity of the enzymes in the presence of metabisulphite was exhibited. ALP activity may serve as an index of the effectiveness of the antisporulating activity of metabisulphite. Both enzymes are likely to be among the few targets for the antisporulating activity of metabisulphite.     

Transglutaminase in sporulating cells of Bacillus subtilis

We screened various Bacillus species producing transglutaminase (TGase), measured as labeled putrescine incorporated into N,N-dimethylcasein. As a result, we detected TGase activity in sporulating cells of B. subtilis, B. cereus, B. alvei and B. aneurinolyticus, and found TGase activity related to sporulation. TGase activity of Bacillus subtilis was detected in lysozyme-treated sporulating cells during late sporulation, but not in cells without lysozyme treatment or the supernatant of the culture broth. TGase was found to be localized on spores. TGase was preliminarily purified by gel filtration chromatography for characterization. Its activity was eluted in the fractions indicating a molecular weight of approximately 23 kDa. TGase could cross-link and polymerize a certain protein. The enzyme was strongly suggested to form epsilon-(gamma-glutamyl)lysine bonds, which were detected in the spore coat proteins of B. subtilis. The activity was Ca(2+)-independent like the TGases derived from Streptoverticillium or some plants. It is suggested that TGase is expressed during sporulation and plays a role in the assembly of the spore coat proteins of the genus Bacillus.     

Sigma 29-like protein is a common sporulation-specific element in bacteria of the genus Bacillus.

A monoclonal antibody specific for an antigenic determinant on the Bacillus subtilis sporulation-induced sigma factor sigma 29 reacted with proteins similar in size to sigma 29 in extracts of sporulating Bacillus licheniformis, Bacillus amyloliquifaciens, Bacillus cereus, Bacillus natto, and Bacillus pumilus but not in extracts prepared from vegetatively growing cultures of these bacteria. These results indicate that RNA polymerase modifications, initially described for B. subtilis, are likely to be common among sporulating Bacillus spp. and that at least some of the specific modifications that are observed in sporulating B. subtilis are conserved among members of this genus.     

EtfA catalyses the formation of dipicolinic acid in Clostridium perfringens

Dipicolinic acid (DPA) is a major component of bacterial endospores, comprising 5–15% of the spore dry weight, and is important for spore stability and resistance properties. The biosynthetic precursor to DPA, dihydro-dipicolinic acid (DHDPA), is produced by DHDPA synthase within the lysine biosynthesis pathway. In Bacillus subtilis , and most other bacilli and clostridia, DHDPA is oxidized to DPA by the products of the spoVF operon. Analysis of the genomes of the clostridia in Cluster I, including the pathogens Clostridium perfringens , Clostridium botulinum and Clostridium tetani , has shown that no spoVF orthologues exist in these organisms. DPA synthase was purified from extracts of sporulating C. perfringens cells. Peptide sequencing identified an electron transfer flavoprotein, EtfA, in this purified protein fraction. A C. perfringens strain with etfA inactivated is blocked in late stage sporulation and produces ≤ 11% of wild-type DPA levels. C. perfringens EtfA was expressed in and purified from Escherichia coli , and this protein catalysed DPA formation in vitro . The sequential production of DHDPA and DPA in C. perfringens appears to be catalysed by DHDPA synthase followed by EtfA. Genome sequence data and the taxonomy of spore-forming species suggest that this may be the ancestral mechanism for DPA synthesis.     

Two active forms of valyl-tRNA synthetase from Bacillus subtilis: alteration related to the early stages of sporulation

Two enzymatically active forms, E-I and E-II, of valyl-tRNA synthetase [EC 6.1.1.9] from cells at various stages in the life cycle of Bacillus subtilis 168 LTT, germinated cells, vegetative cells (t-0.5), sporulating cells (t0, t1, t3, and t4), forespores and mature spores, were analyzed by hydroxyapatite column chromatography. The E-II activity was detected in the main fraction of valyl-tRNA synthetase during the life cycle of B. subtilis 168 LTT. The high activity of E-II at t0 decreased rapidly in the stationary and sporulating phases. On the other hand, the E-I activity increased in the early sporulating stage and was about twofold higher at t3 than at t0. After t3, this activity also decreased rapidly and was not detected in forespores and mature spores. The relative amount of E-I at t0 was 3.4% of the total valyl-tRNA synthetase activity eluted from the hydroxyapatite column, 12.9% at t1 and 29.2% at t3, but it was less than 10% at t4 and in germinated cells. The alteration in E-I and E-II activities was also observed in cells of B. subtilis NIG 1121 (spo+), W23 and 168W, but not in any asporogenous mutant strain studied. These results show that the alteration in the valyl-tRNA synthetase activity appears only during the early stages of sporulation and is closely related to the sporulation of B. subtilis.     

The bactericidal action of beta-lactam antibiotics on an autolysin-deficient strain of Bacillus subtilis

An autolysin-deficient mutant of Bacillus subtilis was completely tolerant to 5 h incubation with 50-100 micrograms cycloserine ml-1 whereas the wild-type was rapidly lysed and killed by 12 micrograms ml-1. Lysis also did not occur when low concentrations of beta-lactams were added to exponentially growing cultures of the mutant, but over 90% of the bacteria were killed within 90-120 min. Protein, lipid and peptidoglycan synthesis as well as growth were inhibited after about 60 min. At this time, but not earlier, small amounts of these three cell components appeared in culture supernatants. Earlier, at about 20-30 min, the intracellular pools of amino acids started to decline rapidly and there was a temporary apparent increase in the rate of lipid synthesis. Neither of the latter phenomena occurred with cycloserine, with which protein and lipid synthesis declined only slowly and the rate of peptidoglycan synthesis was 80% inhibited within 30 min. Only occasional cells with damaged walls were seen 30-90 min after addition of either beta-lactams or cycloserine to the cultures. It thus seems unlikely that wall hydrolysis or penetration by residual autolysins in the mutant are responsible for mass cell death caused by the beta-lactams.     

Antibacterial spectrum of lisosubtilin G10X

Data on the antibacterial spectrum of lysosubtilin G10X, a preparation of lytic enzymes from Bacillus subtilis SK-52 are presented. Lysosubtilin was active against grampositive and gramnegative pathogenic bacteria. When it was used as a substrate of live lyophilized microbial cells the highest lysis levels were observed in B. brevis, B. cereus, B. pumilis, B. subtilis and S. faecalis. Preincubation of the substrate in acid media mainly increased the levels of the lysis by enzyme preparation. Sometimes the increase was very high (B. sphaericus, B. subtilis 720, E. coli K12 and MRE-600). Such a preincubation provided cell lysis in some strains not liable to the effect of lysosubtilin (B. cereus 1312, C. renale, M. luteus, S. aureus KP, 800, 805 and 126001, S. pyogenes 291). An increase in the lysosubtilin concentration in the reaction mixture in the majority of the cases did not provide favourable results. However, some strains resistant to the preparation at a concentration of 1000 units/ml were lysed with its 10 times higher doses. An increase in the lysis level was also achieved with increasing the time of the incubation with the enzyme preparation. Proceeding from the preparation antibacterial spectrum it is possible to recommend it for treatment of diseases in agricultural animals. Its use in veterinary was a success.     

Inhibition of microbial growth by ajoene, a sulfur-containing compound derived from garlic.

Ajoene, a garlic-derived sulfur-containing compound that prevents platelet aggregation, exhibited broad-spectrum antimicrobial activity. Growth of gram-positive bacteria, such as Bacillus cereus, Bacillus subtilis, Mycobacterium smegmatis, and Streptomyces griseus, was inhibited at 5 micrograms of ajoene per ml. Staphylococcus aureus and Lactobacillus plantarum also were inhibited below 20 micrograms of ajoene per ml. For gram-negative bacteria, such as Escherichia coli, Klebsiella pneumoniae, and Xanthomonas maltophilia, MICs were between 100 and 160 micrograms/ml. Ajoene also inhibited yeast growth at concentrations below 20 micrograms/ml. The microbicidal effect of ajoene on growing cells was observed at slightly higher concentrations than the corresponding MICs. B. cereus and Saccharomyces cerevisiae were killed at 30 micrograms of ajoene per ml after 24 h of cultivation when cultivation was started at 10(5) cells per ml. However, the minimal microbicidal concentrations for resting cells were at 10 to 100 times higher concentrations than the corresponding MICs. The disulfide bond in ajoene appears to be necessary for the antimicrobial activity of ajoene, since reduction by cysteine, which reacts with disulfide bonds, abolished its antimicrobial activity.     

Biochemical studies of bacterial sporulation and germination. XII. A sulfonic acid as a major sulfur compound of Bacillus subtilis spores

A sulfonic acid found to be a major constituent of spores of Bacillus subtilis was provisionally identified as 3-l-sulfolactic acid. This compound was completely absent from vegetative cells during growth, but large amounts accumulated in sporulating cells just before the development of refractile spores. Essentially all of the accumulated sulfolactic acid was eventually incorporated into the nature spore, where it may represent more than 5% of the dry weight of the spore. Germination resulted in the rapid and complete release into the medium of unaltered sulfolactic acid. This compound was not found in spores of Bacillus megaterium, B. cereus, or B. thuringiensis.     

Cloning of the genes for penicillinase, penP and penI, of Bacillus licheniformis in some vector plasmids and their expression in Escherichia coli, Bacillus subtilis, and Bacillus licheniformis.

By using plasmid pMB9, penicillinase genes (penP and penI) from both the wild-type and constitutive strains of Bacillus licheniformis 9945A were cloned in EScherichia coli. When a low-copy-number plasmid was used, both wild-type and constitutive penicillinase genes could be transferred into Bacillus subtilis. However, when a high-copy-number plasmid was used, only the genes of the wild type could be transferred. These recombinant plasmids in B. subtilis could all be transferred by the protoplast transformation procedure into B. licheniformis. Transformants of E. coli were resistant to ampicillin (20 micrograms/ml) in spite of the low penicillinase activities (7 U/mg of cells). However, transformants of B. subtilis and B. licheniformis were sensitive to ampicillin (20 micrograms/ml) even in high penicillinase activities (more than 10,000 U/mg of cells). The secretion of penicillinase was rarely observed in E. coli. In contrast, penicillinases secreted from transformants of B. subtilis and B. licheniformis were around 30 and 60% of the total activities, respectively. We took advantage of the plasmids to permit the construction of hetero- and mero-polyploid structures in host cells, and we discuss a regulatory mechanism of penicillinase synthesis in B. licheniformis.     

Functional modifications of the translational system in Bacillus subtilis during sporulation.

Extracts of sporulating cells were found to be defective in vitro translation of phage SP01 ribonucleic acid (RNA) and vegetative Bacillus subtilis RNA. The activity of washed ribosomes from sporulating cells was very similar to that of washed ribosomes from vegetative cells in translating polyuridylic acid, SP01 RNA, and vegetative RNA. The S-150 fraction from either vegetative or sporulating cells grown in Difco sporulation medium contained an apparent inhibitor of protein synthesis. The crude initiation factor fraction from ribosomes of sporulating cells was defective in promoting the initiation factor-dependent translation of SP01 RNA. The crude initiation factor preparations from sporulating cells were as active as the corresponding preparations from vegetative cells in promoting the initiation factor-dependent translation of either phage Qbeta or phage T4 RNA by washed Escherichia coli ribosomes. The crude initiation factors from sporulating cells were perhaps more active than those from vegetative cells in promoting the initiation factor-dependent synthesis of phage T4 lysozyme by E. coli ribosomes. The crude initiation factor preparations from either vegetative or stationary-phase cells of an asporogenous mutant showed similar ability to promote the in vitro translation of SP01 RNA.     

蜡样芽孢杆菌ATCC14579核黄素操纵子的克隆及在枯草芽孢杆菌中的表达

利用BLAST从B．cereus ATCC14579的基因组中找到一段与枯草芽孢杆茵核黄素操纵子具有较高相似性的4．6kb大小的基因组DNA片段,该片段中含有完整的核黄素操纵子。该操纵子结构基因的编码产物的氨基酸序列与枯草芽孢杆菌核黄素操纵子相应结构基因的编码产物的氨基酸序列具有99％的同源性。该片段被克隆到大肠杆茵一枯草芽孢杆茵穿梭载体pHP13M中。表达分析的结果表明B．cereus ATCC14579核黄素操纵子可在大肠杆茵和枯草芽孢杆菌中表达。利用PCR方法用来自枯草杆菌的sac B基因的启动子替换B．cereus ATCC14579核黄素操纵子原有的启动子使其更好表达。替换启动子后的核黄素操纵子在本文使用的发酵条件下有较好的表达,核黄素产量从39．5mg／L增加到61．7mg/L.     

Molecular cloning of a tetracycline-resistance determinant from Bacillus subtilis chromosomal DNA and its expression in Escherichia coli and B. subtilis

Bacillus subtilis GSY908 DNA fragments (5.1 and 4.4 kilobase pairs (kb)) containing a tetracycline-resistance determinant were cloned in Escherichia coli using a shuttle plasmid vector pLS353. Restriction endonucelase analysis showed that the 4.4 kb fragment is a spontaneous deletion derivative of the 5.1 kb fragment. E. coli tetracycline-resistance transformants carrying pLS353 with the 5.1 kb fragment (named pTBS1) and that with 4.4 kb fragment (pTBS1.1) could grow at tetracycline concentrations up to 80 and 50 micrograms per ml, respectively. B. subtilis MI112 and RM125 were transformed by pTBS1, resulting in isolation of transformants of MI112 maintaining pTBS1 and RM125 maintaining either pTBS1 or pTBS1.1. Maximum tetracycline concentrations permitting growth of plasmidless MI112 and MI112 with pTBS1 were 4 and 10 micrograms per ml, respectively, while those of plasmidless RM125, RM125 with pTBS1 and RM125 with pTBS1.1 were 7, 50 and 80 micrograms per ml, respectively. It was interesting to note that the tetracycline-resistance level in E. coli conferred by the 5.1 kb fragment is higher than that conferred by the 4.4 kb fragment, but in B. subtilis the 4.4 kb fragment, in contrast, confers a higher level of tetracycline resistance. The level of tetracycline resistance in B. subtilis conferred by the cloned determinant clearly depends on the host strain. The tetracycline resistance conferred by the cloned determinant was associated with decreased accumulation of the drug into the cells. However, it was constitutive in E. coli, but inducible in B. subtilis. The cloned tetracycline-resistance determinant was detected specifically on the chromosome of B. subtilis Marburg 168 derivatives.     

Stability and synthesis of the penicillin-binding proteins during sporulation

The penicillin-binding proteins (PBPs) of Bacillus subtilis were examined after incubation of vegetative and sporulating cultures with chloramphenicol, an inhibitor of protein synthesis. The results indicate that the sporulation-specific increases in vegetative PBPs 2B and 3 and the appearance of two new PBPs, 4* and 5*, depend on concurrent protein synthesis, which is most likely to be de novo synthesis of the PBPs rather than synthesis of an activator or processing enzyme. It was also learned that in vivo the PBPs differ in their individual stabilities, which helps to explain some of the quantitative changes that occur in the PBP profile during sporulation. All the membrane-bound PBPs, except possibly PBP 1, were found to be stable in the presence of crude extracts of sporulating cells that contained proteolytic activity.     

The program of protein synthesis during sporulation in Bacillus subtilis

The program of protein synthesis was examined during sporulation in Bacillus subtilis as an index of the control of gene expression. At various stages of growth and spore formation, cells of B. subtilis were pulse-labeled with ³⁵S-methionine. Protein was extracted from the radioactively labeled bacteria and then subjected to high resolution one-dimensional and two-dimensional slab gel electrophoresis. We report that sporulating cells restricted or “turned off” the synthesis of certain polypeptides characteristic of the vegetative phase of growth. In certain cases, this “turn off” was prevented in a mutant (SpoOa-5NA) blocked at the first stage of spore formation. Sporulating bacteria also elaborated new polypeptide species that could not be detected in vegetatively growing cells or in cells of the asporogenous mutant SpoOa-5NA in sporulation medium. The synthesis of these sporulation-specific proteins was “turned on” in a temporally defined sequence throughout the period of spore formation. Spore coat protein, for example, was first synthesized at 4 hr after the onset of sporulation, the time at which refractile prespores appeared. Certain sporulation-specific polypeptides including the coat protein were among the most actively produced polypeptides in sporulating cells.     

Cytological and biochemical characterization of the FtsA cell division protein of Bacillus subtilis

The actin-like protein FtsA is present in many eubacteria, and genetic experiments have shown that it plays an important, sometimes essential, role in cell division. Here, we show that Bacillus subtilis FtsA is targeted to division sites in both vegetative and sporulating cells. As in other organisms FtsA is probably recruited immediately after FtsZ. In sporulating cells of B. subtilis FtsZ is recruited to potential division sites at both poles of the cell, but asymmetric division occurs at only one pole. We have now found that FtsA is recruited to only one cell pole, suggesting that it may play an important role in the generation of asymmetry in this system. FtsA is present in much higher quantities in B. subtilis than in Escherichia coli, with approximately one molecule of FtsA for five of FtsZ. This means that there is sufficient FtsA to form a complete circumferential ring at the division site. Therefore, FtsA may have a direct structural role in cell division. We have purified FtsA and shown that it behaves as a dimer and that it has both ATP-binding and ATP-hydrolysis activities. This suggests that ATP hydrolysis by FtsA is required, together with GTP hydrolysis by FtsZ, for cell division in B. subtilis (and possibly in most eubacteria).     

Phosphatases modulate the bistable sporulation gene expression pattern in Bacillus subtilis

Summary Spore formation in the Gram-positive bacterium Bacillus subtilis is a last resort adaptive response to starvation. To initiate sporulation, the key regulator in this process, Spo0A, needs to be activated by the so-called phosphorelay. Within a sporulating culture of B. subtilis, some cells initiate this developmental program, while other cells do not. Therefore, initiation of sporulation appears to be a regulatory process with a bistable outcome. Using a single cell analytical approach, we show that the autostimulatory loop of spo0A is responsible for generating a bistable response resulting in phenotypic variation within the sporulating culture. It is demonstrated that the main function of RapA, a phosphorelay phosphatase, is to maintain the bistable sporulation gene expression. As rapA expression is quorum regulated, it follows that quorum sensing influences sporulation bistability. Deletion of spo0E, a phosphatase directly acting on Spo0A approximately P, resulted in abolishment of the bistable expression pattern. Artificial induction of a heterologous Rap phosphatase restored heterogeneity in a rapA or spo0E mutant. These results demonstrate that with external phosphatases, B. subtilis can use the phosphorelay as a tuner to modulate the bistable outcome of the sporulating culture. This shows that B. subtilis employs multiple pathways to maintain the bistable nature of a sporulating culture, stressing the physiological importance of this phenomenon.     

Spore coat protein synthesis in cell-free systems from sporulating cells of Bacillus subtilis.

Cell-free systems for protein synthesis were prepared from Bacillus subtilis 168 cells at several stages of sporulation. Immunological methods were used to determine whether spore coat protein could be synthesized in the cell-free systems prepared from sporulating cells. Spore coat protein synthesis first occurred in extracts from stage t2 cells. The proportion of spore coat protein to total proteins synthesized in the cell-free systems was 2.4 and 3.9% at stages t2 and t4, respectively. The sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis patterns of immunoprecipitates from the cell-free systems showed the complete synthesis of an apparent spore coat protein precursor (molecular weight, 25,000). A polypeptide of this weight was previously identified in studies in vivo (L.E. Munoz, Y. Sadaie, and R.H. Doi, J. Biol. Chem., in press). The synthesis in vitro of polysome-associated nascent spore coat polypeptides with varying molecular weights up to 23,000 was also detected. These results indicate that the spore coat protein may be synthesized as a precursor protein. The removal of proteases in the crude extracts by treatment with hemoglobin-Sepharose affinity techniques may be preventing the conversion of the large 25,000-dalton precursor to the 12,500-dalton mature spore coat protein.     

Cloning and expression of the Clostridium thermosulfurogenes glucose isomerase gene in Escherichia coli and Bacillus subtilis

The gene that encodes thermostable glucose isomerase in Clostridium thermosulfurogenes was cloned by complementation of glucose isomerase activity in a xylA mutant of Escherichia coli. A new assay method for thermostable glucose isomerase activity on agar plates, using a top agar mixture containing fructose, glucose oxidase, peroxidase, and benzidine, was developed. One positive clone, carrying plasmid pCGI38, was isolated from a cosmid library of C. thermosulfurogenes DNA. The plasmid was further subcloned into a Bacillus cloning vector, pTB523, to generate shuttle plasmid pMLG1, which is able to replicate in both E. coli and Bacillus subtilis. Expression of the thermostable glucose isomerase gene in both species was constitutive, whereas synthesis of the enzyme in C. thermosulfurogenes was inducible by D-xylose. B. subtilis and E. coli produced higher levels of thermostable glucose isomerase (1.54 and 0.46 U/mg of protein, respectively) than did C. thermosulfurogenes (0.29 U/mg of protein). The glucose isomerases synthesized in E. coli and B. subtilis were purified to homogeneity and displayed properties (subunit Mr, 50,000; tetrameric molecular structure; thermostability; metal ion requirement; and apparent temperature and pH optima) identical to those of the native enzyme purified from C. thermosulfurogenes. Simple heat treatment of crude extracts from E. coli and B. subtilis cells carrying the recombinant plasmid at 85 degrees C for 15 min generated 80% pure glucose isomerase. The maximum conversion yield of glucose (35%, wt/wt) to fructose with the thermostable glucose isomerase (10.8 U/g of dry substrate) was 52% at pH 7.0 and 70 degrees C.     

Cloning and expression of the Clostridium thermosulfurogenes glucose isomerase gene in Escherichia coli and Bacillus subtilis.

The gene that encodes thermostable glucose isomerase in Clostridium thermosulfurogenes was cloned by complementation of glucose isomerase activity in a xylA mutant of Escherichia coli. A new assay method for thermostable glucose isomerase activity on agar plates, using a top agar mixture containing fructose, glucose oxidase, peroxidase, and benzidine, was developed. One positive clone, carrying plasmid pCGI38, was isolated from a cosmid library of C. thermosulfurogenes DNA. The plasmid was further subcloned into a Bacillus cloning vector, pTB523, to generate shuttle plasmid pMLG1, which is able to replicate in both E. coli and Bacillus subtilis. Expression of the thermostable glucose isomerase gene in both species was constitutive, whereas synthesis of the enzyme in C. thermosulfurogenes was inducible by D-xylose. B. subtilis and E. coli produced higher levels of thermostable glucose isomerase (1.54 and 0.46 U/mg of protein, respectively) than did C. thermosulfurogenes (0.29 U/mg of protein). The glucose isomerases synthesized in E. coli and B. subtilis were purified to homogeneity and displayed properties (subunit Mr, 50,000; tetrameric molecular structure; thermostability; metal ion requirement; and apparent temperature and pH optima) identical to those of the native enzyme purified from C. thermosulfurogenes. Simple heat treatment of crude extracts from E. coli and B. subtilis cells carrying the recombinant plasmid at 85 degrees C for 15 min generated 80% pure glucose isomerase. The maximum conversion yield of glucose (35%, wt/wt) to fructose with the thermostable glucose isomerase (10.8 U/g of dry substrate) was 52% at pH 7.0 and 70 degrees C.