Maltose uptake and its regulation in Bacillus subtilis

Extracts prepared from cultures of Bacillus subtilis, grown on maltose as the sole carbon source, lacked maltose phosphotransferase system activity. There was, however, evidence for a maltose phosphorylase activity, and such extracts also possessed both glucokinase and glucose phosphotransferase system activities. Maltose was accumulated by whole cells of B. subtilis by an energy-dependent mechanism. This uptake was sensitive to the effects of uncouplers, suggesting a role for the proton-motive force in maltose transport. Accumulation of maltose was inhibited in the presence of glucose, and there was no accumulation of maltose by a strain carrying the ptsI6 null-mutation. A strain carrying the temperature-sensitive ptsI1 mutation accumulated maltose normally at 37 degrees C but, in contrast to the wild-type, was devoid of maltose transport activity at 47 degrees C. The results indicate a role for the phosphotransferase system in the regulation of maltose transport activity in this organism.     

A pleitropic mutation affecting purine metabolism in Bacillus subtilis

A pleiotropic mutation (cpm) which is localized in the vicinity of the spoOA gene is described in Bacillus subtilis. The mutation inhibits spore formation, rendering bacteria auxotrophic for adenine and tyrosine, enhances sensitivity to antibiotics, decreases cell motility, inhibits the ability to grow on pentoses and to maintain bacteriophage multiplication, induces severalfold the activities of alkaline proteinase and alpha-amylase. At the same time, the cpm mutant starts to excrete inosine into the growth medium. This excretion most probably is explained by a 50-fold increase in the activity of inosine monophosphate: 5'-nucleotidase and a 10-fold decrease in the activity of purine nucleoside phosphorylase. The inosine production and Ade- phenotype of the cpm mutant is not accompanied by the change in the activity of succinyl adenosine monophosphate synthetase. The nature of the mutation is discussed.     

Determination of turgor pressure in Bacillus subtilis: a possible role for K+ in turgor regulation

The effects of hypersaline treatment (osmotic upshock) on cell water relations were examined in the Gram-positive bacterium Bacillus subtilis using particle size analysis. Application of the Boyle-van't Hoff relationship (cell volume versus reciprocal of external osmolality) permitted direct determination of turgor pressure, which was approximately 0.75 osmol kg-1 (1.9 MPa) in exponentially growing bacteria in a defined medium. The abolition of turgor pressure immediately after upshock and the subsequent recovery of turgor were investigated. Recovery of turgor was K+ dependent. Calculation of turgor by an alternative method involving spectrophotometric analysis of shrinkage gave somewhat lower estimates of turgor pressure.     

A possible role for L24 of Bacillus subtilis in nucleoid organization and segregation

The condensation of DNA in bacterial nucleoids during cell cycle is a complex and dynamic process. Proteins displaying the physico-chemical properties of histones are known to contribute to this process. During a search for B. subtilis nucleoid associated proteins, HBsu and L24 were identified as the most abundant proteins in nucleoid containing fractions. Purified L24 binds and condenses DNA in vitro. In this paper we describe immunofluorescence studies that demonstrated that L24 is located at the poles of the nucleoids in exponentially growing cells. In contrast, the protein is dispersed in the cytoplasm during stationary phase. Moreover, overexpression of the rplX gene encoding L24 disrupts nucleoid segregation and positioning.     

Gene-enzyme relationships of the purine biosynthetic pathway in Bacillus subtilis

Summary The gene-enzyme relationship has been established for most of the steps of the purine de novo biosynthetic pathway in Bacillus subtilis. The synthesis of inosine monophosphate (IMP) involves ten steps, and the branching from IMP to AMP and to guanosine monophoshate (GMP) synthesis both require two steps. To avoid confusion in the nomenclature of the pur genes we have adopted the Escherichia coli system for B. subtilis. The two genes specifying the enzymes catalysing the conversion of IMP to succinyl-AMP (purA), and the conversion of IMP to xanthosine monophosphate (guaB), occur as single units whilst the other purine genes are clustered at 55 degrees on the B. subtilis linkage map. Based on transformation and transduction studies, and on complementation studies using B. subtilis pur genes cloned in plasmids, the arrangement of some of the clustered genes has been determined relative to outside markers. The following gene order has been established: pbuG-purB-purF-purM-purH-purD-tre. Three other genes were also found to be located in the cluster, guaA, purL and purE/C. However, we were not able to find their exact location. When the purF, purM, purD and purB genes of B. subtilis are present in plasmids they are capable of directing the synthesis in E. coli of phosphoribosylpyrophosphate amidotransferase (purF), aminoimidazole ribonucleotide synthetase (purM), glycinamide ribonucleotide synthetase (purD) and adenylosuccinate lyase (purB), respectively.     

Autostimulation of dihydrostreptomycin uptake in Bacillus subtilis

In Bacillus subtilis it was shown that the membrane potential (delta psi) has to reach a threshold value of -180 to -190 mV for efficient uptake of dihydrostreptomycin to occur. The magnitude of delta psi is raised above this threshold, and dihydrostreptomycin uptake greatly enhanced, not only by dihydrostreptomycin itself (autostimulation) and by other miscoding aminoglycoside antibiotics, but also by puromycin, bacitracin and N,N'-dicyclohexylcarbodiimide. Stimulation of uptake by dihydrostreptomycin or puromycin was dependent on a specific interference with ongoing protein synthesis. Thus, chloramphenicol prevented the stimulating effect of puromycin by lowering the magnitude of delta psi. Although normally severely antagonizing streptomycin accumulation, K+, as well as spermidine and putrescine, which are known to stabilize ribosomes, consequently enhanced autostimulation of dihydrostreptomycin uptake in a K+-retention mutant with impaired protein synthesis. It is suggested that miscoding aminoglycosides and puromycin both enhance dihydrostreptomycin uptake by increasing delta psi due to ion fluxes, which are themselves caused by a dramatic stimulation of intracellular proteolysis of faulty proteins.     

枯草芽孢杆菌嘌呤合成途径的修饰对腺苷积累的影响

【目的】研究嘌呤操纵子中purF、purM、purN、purH和purD基因的共同过表达对枯草芽孢杆菌发酵生产腺苷的影响。【方法】利用温敏质粒pKS1,以单交换的形式增加了purF基因在基因组上的拷贝数,同时将强启动子P43插入嘌呤操纵子中,使嘌呤合成途径中purF基因及其下游purM、purN、purH和purD基因的表达水平得到加强,通过实时定量PCR(Realtime Quantitative PCR,RT-qPCR)测定相关基因(purF、purM、purN、purH和purD)的转录水平;通过酶活性检测分析关键酶基因扩增对PRPP转酰胺酶活性的影响;通过发酵实验考察出发菌株与工程菌株的生长、耗糖和腺苷积累情况。【结果】实时定量PCR结果表明,purF、purM、purN、purH和purD基因的表达水平均有不同程度的提高,嘌呤合成途径中关键酶PRPP转酰胺酶的活性是出发菌株的2.4倍。摇瓶发酵实验发现工程菌腺苷产量较出发菌提高17.5%,糖苷转化率增加26.1%。5 L罐发酵实验表明,虽然工程菌的菌体生长受到一定的影响,但在相同发酵周期内腺苷产量比出发菌提高了9.7%。【结论】嘌呤操纵子中purF、purM、purN、purH和purD基因转录水平的增强能够提高腺苷的产量,为通过代谢工程技术改造腺苷生产菌提供了理论依据和研究思路。     

Protein conformational change and nucleotide binding involved in regulation of sigmaF in Bacillus subtilis.

We have studied the ability of three mutant forms of SpoIIAA, containing amino acid substitutions at the site of phosphorylation (serine 58), to interact with SpoIIAB. Native gel analysis revealed that SpoIIAAS58A could form a complex with SpoIIAB in the presence of ADP and more strongly in the presence of ATP. SpoIIAAS58N did not form a complex with SpoIIAB in the presence of ADP but displayed some interaction with SpoIIAB in the presence of ATP. SpoIIAAS58D was unable to form a complex with SpoIIAB in the presence of either ADP or ATP. Corresponding differences were found in the behavior of the three mutant proteins when studied by gel permeation with high-performance liquid chromatography and limited proteolysis. SpoIIAAS58A behaved like the wild-type SpoIIAA, SpoIIAAS58D like SpoIIAA-P, and SpoIIAAS58N in a way that was intermediate between the behaviors of SpoIIAA and SpoIIAA-P. Limited proteolysis was also used to show that on binding of ADP or ATP SpoIIAB undergoes a shift in conformation. The affinity of SpoIIAB for ADP and ATP was determined by limited proteolysis in the presence of a wide range of nucleotide concentrations. The results indicated that SpoIIAB has approximately equal affinity for ADP and for ATP.     

Studies of the regulation of purine nucleotide catabolism.

Ehrlich ascites tumor cells containing radioactive ATP were incubated in vitro with a range of concentrations of 2-deoxyglucose in order to produce different rates of ATP catabolism. Concentrations of all radioactive products of ATP catabolism were measured, and apparent rates of adenylate deaminase and inosinate dehydrogenase and of adenylate and inosinate dephosphorylation were calculated. It was concluded that these processes were reggulated primarily by the rate of formation of substrate, and to a lesser extent in some cases, by substrate concentration. No evidence was obtained for regulation of these processes by the concentration of ATP. The deoxyglucose-induced catabolism of radioactive GTP was also studied. When ATP catabolism was induced by incubation with 2,4-dinitrophenol, time courses of accumulation of purine nucleoside monophosphates and rates of alternative pathways of their metabolism were quite different than when deoxyglucose was used.     

Ferri-bacillibactin uptake and hydrolysis in Bacillus subtilis

Upon iron limitation, Bacillus subtilis secretes the catecholic trilactone (2,3-dihydroxybenzoate-glycine-threonine)3 siderophore bacillibactin (BB) for ferric iron scavenging. Here, we show that ferri-BB uptake is mediated by the FeuABC transporter and that YuiI, a novel trilactone hydrolase, catalyses ferri-BB hydrolysis leading to cytosolic iron release. Among several Fur-regulated ABC transport mutants, only DeltafeuABC exhibited impaired growth during iron starvation. Quantification of intra- and extracellular (ferri)-BB in iron-depleted DeltafeuABC cultures revealed a fourfold increase of the extracellular siderophore concentration, confirming a blocked ferri-BB uptake in the absence of FeuABC. Ferri-BB was found to bind selectively to the periplasmic binding protein FeuA (Kd = 57 +/- 1 nM), proving high-affinity transport of the iron-charged siderophore. During iron starvation, a DeltayuiI mutant displayed impaired growth and strong intracellular (30-fold) and extracellular (6.5-fold) (ferri)-BB accumulation. Kinetic studies in vitro revealed that YuiI hydrolyses both BB and ferri-BB. While BB hydrolysis led to strong accumulation of the tri- and dimeric reaction intermediates, ferri-BB hydrolysis yielded exclusively the monomeric reaction product and occurred with a 25-fold higher catalytic efficiency than BB single hydrolysis. Thus, ferri-BB was the preferred substrate of the YuiI esterase whose gene locus was designated besA.