Bacillus subtilis as a host for mosquitocidal toxins production

Aedes albopictus transmits several arboviral infections. In the absence of vaccines, control of mosquito populations is the only strategy to prevent vector-borne diseases. As part of the search for novel, biological and environmentally friendly strategies for vector control, the isolation of new bacterial species with mosquitocidal activity represents a promising approach. However, new bacterial isolates may be difficult to grow and genetically manipulate. To overcome these limits, here we set up a system allowing the expression of mosquitocidal bacterial toxins in the well-known genetic background of Bacillus subtilis. As a proof of this concept, the ability of B. subtilis to express individual or combinations of toxins of Bacillus thuringiensis israelensis (Bti) was studied. Different expression systems in which toxin gene expression was driven by IPTG-inducible, auto-inducible or toxin gene-specific promoters were developed. The larvicidal activity of the resulting B. subtilis strains against second-instar Ae. albopictus larvae allowed studying the activity of individual toxins or the synergistic interaction among Cry and Cyt toxins. The expression systems here presented lay the foundation for a better improved system to be used in the future to characterize the larvicidal activity of toxin genes from new environmental isolates.     

Biomineralization of Middle Rare Earth Element Samarium in Yeast and Bacteria Systems

Microorganisms play an important role in the mineralization of heavy metals in different environments. Previous studies have reported the phosphate mineralization of light (Ce) and heavy (Yb) rare earth elements with yeast. However, little is known about differences in the biomineralization process of middle rare earth elements (including Sm, Eu, Gd, Tb and Dy) by yeast and bacteria. We carried out a series of experiments to compare the sorption process of Sm by Saccharomyces cerevisiae (yeast), Pseudomonas fluorescens (gram-negative bacteria) and Bacillus subtilis (gram-positive bacteria) in initial pH 3, 4 and 5 solutions. The concentrations of Sm in exposure solutions decreased as a function of exposure time in all three systems, which revealed the accumulation of Sm by cells. In both yeast and bacteria systems, Sm(III) was mineralized to monazite(Sm) phase particles on cell surfaces at 5 days of exposure after a short-term adsorption process. In these three systems, nano-sized Sm phosphate formed more quickly on cell surfaces with higher pH exposure solutions. The formation of precipitation on bacterial cell surfaces was faster than in yeast. There were no significant differences in the sorption process of Sm between the two bacteria Pseudomonas fluorescens and Bacillus subtilis.     

微生态制剂对海水养殖系统硝化功能建立过程的影响

比较分析投加不同微生态制剂的海水养殖系统硝化功能建立的过程,为实际应用提供依据。利用海水素构建4个海水养殖系统,通过投加硝化细菌、光合细菌、枯草芽胞杆菌3种微生态制剂以及纤维毛球作为生物膜载体,比较分析不同养殖系统硝化功能的建立过程及硝化强度差异。投加硝化细菌+光合细菌和硝化细菌+枯草芽胞杆菌系统硝化功能建立时间分别为108 h和96 h,氨氮初始质量浓度为6 mg/L时,氨氧化强度分别为1.69 mg/(L·d)和1.36 mg/(L·d);添加纤维毛球的生物膜系统与生物絮团系统硝化功能建立时间分别为96 h和120 h,氨氮初始质量浓度为6 mg/L时,氨氧化强度分别为1.36 mg/(L·d)和0.98 mg/(L·d);投加碳源系统和对照系统硝化功能建立时间分别为84 h和96 h,氨氮初始质量浓度为6 mg/L时,氨氧化强度分别为1.18 mg/(L·d)和1.36 mg/(L·d)。硝化细菌+枯草芽胞杆菌系统硝化功能建立时间更短,但系统硝化强度低于硝化细菌+光合细菌系统;生物膜系统硝化强度高于生物絮团系统且硝化功能建立更快;添加碳源能够加快系统硝化功能建立过程,但降低了硝化细菌+枯草芽胞杆菌系统的硝化强度。     

Degradation of Nucleic Acids and their Related Compounds by Microbial Enzymes

Seven strains of microorganisms selected by the previous screening tests were further compared on their ability to produce extracellular enzyme systems capable of degrading RNA into 5′-ribonucleotides. As a result, two strains of Streptomyces were finally concluded to be most preferable. When these two were applied, the rate of 5′-nucleotide production reached up to 70%.

Bacillus subtilis was outstanding in its activity to degrade RNA, but its PDase activity producing 5′-nucleotides from RNA was found to be lower than those of Streptomyces strains. A pathway involving 3′- and 5′-nucleotides as intermediates was proposed for the degradation of RNA by the Bacillus enzyme system. The activity of RNA-degrading enzyme system of Bacillus subtilis contained in the supernatant of culture fluid was found to be lost at 700°C but remained to certain extent at 100°C, a possible mechanism for the phenomenon being discussed. Usability of the Bacillus enzyme system in the practical production of 5′-nucleotides under the condition of high RNA concentration was discussed.     

Expression of luciferase genes from different origins in Bacillus subtilis

Summary A group of vectors for luciferase expression in Bacillus subtilis was constructed. So far, only bacterial luciferases have been expressed in Bacillus, but in this study we wanted also to express genes encoding eukaryotic luciferases to perform direct comparisons of the light levels produced by the two different systems in B. subtilis. The vectors constructed can replicate both in Escherichia coli and B. subtilis, and the luciferase expression is strictly regulated due to the dual plasmid system used. Nearly a 100-fold increase in light production compared to previous results was achieved when genes encoding bacterial luciferase were inserted into the constructs and transformed into B. subtilis. An additional tenfold increase in light production was obtained when luciferase genes from the North American firefly (Photinus pyralis) or a click beetle (Pyrophorus plagiophtalamus) were introduced in a similar fashion into B. subtilis. Measurement of the light emission was performed without disruption of bacterial cells in a real-time manner, which is a common feature when working with all of these constructions. Structures of the shuttle vector constructs and results from light emission measurements are presented.     

A Mechanistic Study of Au(III) Removal from Solution by Bacillus subtilis

Bacteria–Au interactions control the fate of Au in a variety of geologic systems. Although previous studies have determined that non-metabolizing Bacillus subtilis cells can remove Au(III) from solution via cell surface adsorption reactions, and that upon removal Au(III) is rapidly reduced to Au(I) and remains bound to the cell surface, the mechanism of Au(III) removal by B. subtilis is poorly understood. This study provides further constraints on the mechanisms responsible for Au(III) removal by B. subtilis by conducting batch Au(III) removal experiments as a function of pH and Au loading (Au:biomass ratio) using biomass with and without two different types of treatment: (1) a treatment to remove extracellular polymeric substances (EPS) from the biomass, and (2) a treatment to irreversibly block surface sulfhydryl sites from Au binding. The experimental results suggest that Au(III) removal can be attributed primarily to Au complexation with bacterial sulfhydryl sites, but that Au–amino binding is also important under some conditions. Our experiments also suggest that Au–sulfhydryl binding occurs predominantly on EPS molecules produced by B. subtilis, and that Au–amino binding is also important and is located within the bacterial cell envelope. These findings are the first to constrain the location of sulfhydryl-binding sites for B. subtilis biomass, and they are the first to demonstrate the important role played by bacterial EPS in the process of Au adsorption and reduction by bacteria.     

Interactions among the three adaptation systems of Bacillus subtilis chemotaxis as revealed by an in vitro receptor‐kinase assay

The Bacillus subtilis chemotaxis pathway employs three systems for sensory adaptation: the methylation system, the CheC/CheD/CheYp system, and the CheV system. Little is known in general about how these three adaptation systems contribute to chemotaxis in B. subtilis and whether they interact with one another. To further understand these three adaptation systems, we employed a quantitative in vitro receptor‐kinase assay. Using this assay, we were able to determine how CheD and CheV affect receptor‐kinase activity as a function of the receptor modification state. CheD was found to increase receptor‐kinase activity, where the magnitude of the increase depends on the modification state of the receptor. The principal new findings concern CheV. Little was known about this protein before now. Our data suggest that this protein has two roles depending on the modification state of the receptor, one for sensory adaptation when the receptors are modified (methylated) and the other for signal amplification when they are unmodified (unmethylated). In addition, our data suggest that methylation of site 630 tunes the strength of the CheV adaptation system. Collectively, our results provide new insight regarding the integrated function of the three adaptation systems in B. subtilis.     

Allozyme variation within and among populations of onion (Allium cepa L.) from West Africa

Local germplasm of onion (Allium cepa L.) in West Africa is threatened by extinction. Sixteen populations of onion collected in five countries in West Africa were investigated for isozyme polymorphism using four polymorphic enzyme systems (ADH, MDH, 6-PGDH and PGI) among nine enzyme systems assayed. This is the first report on the genetic diversity of local landraces of onion. The inheritance of two dimeric enzyme systems PGI and MDH was demonstrated using F₂ progeny arrays. The PGI system revealed a single locus with three alleles, and the MDH system revealed three loci with four alleles. Four polymorphic systems revealed nine alleles (adh-a1 and a2, mdh-c1 and c2, 6-pgdh-a1 and a2, and pgi-a1, a2 and a3) in the 16 local populations observed. The mean number of alleles per polymorphic locus was 2.25, and 67% of the alleles were present in all populations. Allele 6-pgdh-a2 was present in only two landraces (from Niger and Nigeria); it is considered to be a rare allele (frequency approximately 2%). Among the 16 populations, within-population diversity was greater (90%) than between-population diversity (10%). Genetic distance analyses showed an aggregate of all populations except for two, which originated from Nigeria, an English-speaking country. Received: 24 August 1995 / Accepted: 26 February 2001     

Electrode System for the Determination of Microbial Populations

Determinations of microbial populations were carried out by using a new electrode system composed of two electrodes. Each electrode was constructed from a platinum anode and a silver peroxide cathode. The anode of the reference electrode was covered with cellulose dialysis membrane. The response time of the electrode system was 15 min in culture broth, and current differences between the two electrodes were proportional to populations of microbial cells in cultures of Saccharomyces cerevisiae and Lactobacillus fermentum. Current differences were reproducible; the average relative error was 5%. Furthermore, cell populations of S. cerevisiae in a fermentor could be continuously estimated by using this electrochemical method.     

Efficient constitutive expression of thermostable 4-α-glucanotransferase in Bacillus subtilis using dual promoters

4-α-Glucanotransferases possess strong transglycosylation activity which has been used in various carbohydrate chemistry fields. Due to safety issues of the recombinant enzymes we chose Bacillus subtilis as an expression host to produce a thermostable 4-α-glucanotransferase from Thermus scotoductus (TSαGT). The HpaII promoter in the Gram-positive bacterial vector pUB110 was used first to express TSαGT gene in B. subtilis. However, the activity of TSαGT in B. subtilis was only 4% of that in our previous Escherichia coli system. Two expression systems constructed by sequential alignment of another constitutive promoter for either α-amylase from B. subtilis NA64 or maltogenic amylase from Bacillus licheniformis downstream of the HpaII promoter elevated the TSαGT productivity by 11- and 12-fold, respectively, compared to the single HpaII promoter system. In conclusion, the dual promoter systems in this study were much better than the single promoter system to express the TSαGT gene in B. subtilis.     

Stress responses ofBacillus subtilis to high osmolarity environments: Uptake and synthesis of osmoprotectants

A decrease in the water content of the soil imposes a considerable stress on the voil-living bacteriumBacillus subtilis: water exits from the cells, resulting in decreased turgor and cessation of growth. Under these adverse circumstances,B. subtilis actively modulates the osmolarity of its cytoplasm to maintain turgor within acceptable boundaries. A rapid uptake of potassium ions via turgor-responsive transport systems is the primary stress response to a sudden increase in the external osmolarity. This is followed by the massive accumulation of the so-called compatible solutes, i.e., organic osmolytes that are highly congruous with cellular functions and hence can be accumulated by bacterial cells up to molar concentrations. Initially, the compatible solute proline is accumulated viade novo synthesis, butB. subtilis can also acquire proline from the environment by an osmoregulated transport system, OpuE. The preferred compatible solute ofB. subtilis is the potent osmoprotectant glycine betaine. This trimethylammonium compound can be taken up by the cell through three high-affinity transport systems: the multicomponent ABC transporters OpuA and OpuC, and the single-component transporter OpuD. The OpuC systems also mediates the accumulation of a variety of naturally occurring betaines, each of which can confer a considerable degree of osmotic tolerance. In addition to the uptake of glycine betaine from the environment,B. subtilis can also synthesize this osmoprotectant but it requires exogenously provided choline as its precursor. Two evolutionarily closely related ABC transport systems, OpuB and OpuC, mediate the uptake of choline which is then converted by the GbsA and GbsB enzymes in a two-step oxidation process into glycine betaine. Our data show that the intracellular accumulation of osmoprotectants is of central importance for the cellular defence ofB. subtilis against high osmolarity stress.     

The significances of bacterial colony patterns

Bacteria do many things as organized populations. We have recently learned much about the molecular basis of intercellular communication among prokaryotes. Colonies display bacterial capacities for multicellular coordination which can be useful in nature where bacteria predominantly grow as films, chains, mats and colonies. E. coli colonies are organized into differentiated non-clonal populations and undergo complex morphogenesis. Multicellularity regulates many aspects of bacterial physiology, including DNA rearrangement systems. In some bacterial species, colony development involves swarming (active migration of cell groups). Swarm colony development displays precise geometrical controls and periodic phenomena. Motile E. coli cells in semi-solid media form organized patterns due to chemotactic autoaggregation. On poor media, B. subtilis forms branched colonies using group motility and longrange chemical signalling. The significances of bacterial colony patterns thus reside in a deeper understanding of prokaryotic biology and evolution and in experimental systems for studying self-organization and morphogenesis.     

Optimization of staphylokinase production inBacillus subtilis using inducible and constitutive promoters

Staphylokinase (SAK) was produced inB. subtillis using two different promoter systems,i.e. the P43 andsacB promoters. To maximize SAK expression inB. subtilis, fermentation control strategies for each promoter were examined. SAK, under P43, a vegetative promoter transcribed mainly by σ^B containing RNA polymerase, was overexpressed at low dissolved oxygen (D.O.) levels, suggesting that thesigB operon is somewhat affected by the energy charge of the cells. The expression of SAK at the 10% D.O. level was three times higher than that at the 50% D.O. level. In the case ofsacB, a sucrose-inducible promoter, sucrose feeding was used to control the induction period and induction strength. Since sucrose is hydrolyzed by two sucrose hydrolyzing enzymes in the cell and culture broth, the control strategy was based on replenishing the loss of sucrose in the culture. With continuous feeding of sucrose, WB700 (pSAKBQ), which contains the SAK gene undersacB promoter, yieldedca. 35% more SAK than the batch culture. These results present efficient promoter-dependent control strategies inB. subtilis host system for foreign protein expression.     

CheC and CheD interact to regulate methylation of Bacillus subtilis methyl-accepting chemotaxis proteins

In this study, we have demonstrated that two unique proteins in Bacillus subtilis chemotaxis, CheC and CheD, interact. We have shown this interaction both by using the yeast two-hybrid system and by precipitation of in vitro translated products using glutathione-S-transferase fusions and glutathione agarose beads. We have also shown that CheC inhibits B. subtilis CheR-mediated methylation of B. subtilis methyl-accepting chemotaxis proteins (MCPs) but not of Escherichia coli MCPs. It was previously reported that cheC mutants tend to swim smoothly and do not adapt to addition of attractant; cheD mutants have very poorly methylated MCPs and are very tumbiy, similar to cheA mutants. We hypothesize that CheC exerts its effect on MCP methylation in B. subtilis by controlling the binding of CheD to the MCPs. In absence of CheD, the MCPs are poor substrates for CheR and appear to tie up, rather than activate, CheA. The regulation of CheD by CheC may be part of a unique adaptation system for chemotaxis in B. subtilis, whereby high levels of CheY-P brought about by attractant addition would allow CheC to interact with CheD and consequently leave the MCPs, reducing CheA activity and hence the levels of CheY-P.     

Cell lines, Md108 and Md66, from the hemocytes of Malacosoma disstria (Lepidoptera) display aspects of plasma-free innate non-self activities

The innate non-self response systems of the deciduous tree pest, the forest tent caterpillar, Malacosoma disstria has been documented by us in terms of in vitro and in vivo reactions towards the Gram-positive nonpathogenic bacterium, Bacillus subtilis and Gram-negative pathogenic microbe, Xenorhabdus nematophila and their respective surface antigens, lipopoteichoic acids (LTA) and lipopolysaccharides (LPS). These studies, often conducted in whole and diluted hemolymph, preclude examination of plasma-free cellular (hemocyte) responses. Plasma-free hemocytes as primary cultures are difficult to obtain. The floating cell line Md66 and attached cell line Md108 from M. disstria hemocytes were examined as a model for plasma-free M. disstria hemocyte non-self responses. Herein, it was established that although both lines differed from each other and from the primary hemocyte cultures of M. disstria in growth parameters, cell composition and sizes both cell lines displayed granular cell-like (GL) cells and plasmatocyte-like (PL) cells according to morphological criteria and to some extent antigenic similarities based on labeling with anti-Chrysodeixis includens hemocyte monoclonal antibodies. Hemocyte-specific neuroglian-like protein was detected on cells of both cell lines and in the primary hemocyte cultures albeit with staining patterns differing according to culture and cell types, confluency levels and cell–cell adhesion. Both cell lines bound B. subtilis and X. nematophila, the reaction extent varying with the cell line and its cell types. LPS damaged both cell types in the two cell lines whereas LTA enhanced the adhesion of Md66 GL cells to flask surfaces followed by PL cell adhesion. PL cells of both lines, like the primary cultures, phagocytosed FITC-labeled B. subtilis; only Md108 GL cells phagocytosed B. subtilis. In either case phagocytosis was always less in frequency and intensity than the primary cultures. Proteins released from the cell lines differed in pattern and magnitude but contained bacterial binding proteins that enhanced differential bacterial adhesion to both cell types in both cell lines: the GL cells both cultures, and those of granular cells in primary cultures, were more involved than the primary plasmatocytes and PL cells. Only Md66 cells possessed lysozyme and both cell types of both lines contained phenoloxidase. Neither enzyme type was released during early phase reaction with the bacteria. LPS inhibited phenoloxidase activity. The similarities and differences between the lines and primary cultures make Md66 and Md108 useful for the systematic examination of plasma-free cellular non-self reactions.     

枯草芽孢杆菌刺激小鼠肠上皮细胞分泌的IL-33在活化树突状细胞中发挥重要作用

【目的】枯草芽孢杆菌能有效诱导肠道黏膜免疫应答,但活化黏膜下树突状细胞(DC)的具体机制不完全清楚。【方法】本研究首先用不同浓度枯草芽孢杆菌刺激小鼠肠上皮CMT93细胞,用荧光定量PCR和ELISA检测细胞因子表达水平,然后将枯草芽孢杆菌刺激细胞的培养上清与小鼠骨髓源树突状细胞(BMDC)进行共孵育,用流式细胞术检测BMDC活化标志,最后用RNA干扰技术证明IL-33在活化BMDC中的作用。【结果】枯草芽孢杆菌能显著刺激CMT93细胞分泌IL-6、IL-33和IFN-γ等细胞因子,对刺激IL-33表达呈现剂量依赖性;枯草芽孢杆菌刺激CMT93细胞产生的细胞因子能活化BMDC,在RNA干扰IL-33基因表达和枯草芽孢杆菌刺激后,CMT93细胞培养上清活化BMDC的能力显著降低。【结论】本研究结果表明枯草芽孢杆菌刺激肠上皮细胞产生的IL-33在BMDC活化中具有重要作用。     

A novel component of the division‐site selection system of Bacillus subtilis and a new mode of action for the division inhibitor MinCD

Cell division in bacteria is governed by a complex cytokinetic machinery in which the key player is a tubulin homologue, FtsZ. Most rod‐shaped bacteria divide precisely at mid‐cell between segregated sister chromosomes. Selection of the correct site for cell division is thought to be determined by two negative regulatory systems: the nucleoid occlusion system, which prevents division in the vicinity of the chromosomes, and the Min system, which prevents inappropriate division at the cell poles. In Bacillus subtilis recruitment of the division inhibitor MinCD to cell poles depends on DivIVA, and these proteins were thought to be sufficient for Min function. We have now identified a novel component of the division‐site selection system, MinJ, which bridges DivIVA and MinD. minJ mutants are impaired in division because MinCD activity is no longer restricted to cell poles. Although MinCD was thought to act specifically on FtsZ assembly, analysis of minJ and divIVA mutants showed that their block in division occurs downstream of FtsZ. The results support a model in which the main function of the Min system lies in allowing only a single round of division per cell cycle, and that MinCD acts at multiple levels to prevent inappropriate division.     

Survival of Plasmid-Containing Bacillus subtilis Released into Mushroom Compost

Abstract The survival of a plasmid-containing Bacillus subtilis released into mushroom compost was investigated. The indigenous Bacillus population of mushroom compost exhibited an antibiotic-resistance profile that was distinguished by almost complete absence of chloramphenicol resistance. Bacillus subtilis containing the chloramphenicol-resistance plasmid pC194 was released into mushroom compost microcosms and populations were monitored at different incubation temperatures. The organism colonized both sterile and untreated compost at 37°C, and to a lesser extent at 50°C, but was eliminated after 30 d at 65°C. Although sporulation of the B. subtilis population occurred within compost, the population was maintained for up to 13 weeks at 50°C, largely as vegetative cells. Experiments in which the B. subtilis host strain, without plasmid, was released demonstrated that plasmid carriage had no effect on the ability of the bacterium to colonize and survive in compost. Furthermore, the size and composition of the indigenous bacterial population was unaffected by the presence of the introduced B. subtilis strain. Virtually no loss of plasmid pC194 from the B. subtilis population in compost was observed, and experiments at low growth rates in chemostats confirmed the stability of this host/vector system in the absence of positive selection pressure. Received: 9 July 1997; Accepted: 20 October 1997