Sphingomyelinase ofBacillus Cereusas a Bacterial Hemolysin

The initial surface composition and topography modulate sphingomyelinase-driven sphingomyelin to ceramide conversion in lipid monolayers

Changes of the initial composition and topography of mixed monolayers of Sphingomyelin and Ceramide modulate the degradation of Sphingomyelin by Bacillus cereus Sphingomyelinase. The presence of initial lateral phase boundary due to coexisting condensed and expanded phase domains favors the precatalytic steps of the reaction. The amount and quality of the domain lateral interface, defined by the type of boundary undulation, appears as a modulatory supramolecular code which regulates the catalytic efficiency of the enzyme. The long range domain lattice structuring is determined by the Sphingomyelinase activity.

Bacillus anthracis phospholipases C facilitate macrophage-associated growth and contribute to virulence in a murine model of inhalation anthrax

Several models of anthrax pathogenesis suggest that early in the infectious process Bacillus anthracis endospores germinate and outgrow into vegetative bacilli within phagocytes before being released into the blood. Here, we define the respective contributions of three phospholipases C (PLCs) to the pathogenesis of B. anthracis. Genetic deletions of the PLCs were made in the Sterne 7702 background, resulting in the respective loss of their activities. The PLCs were redundant both in tissue culture and in murine models of anthrax. Deletion of all three PLC genes was required for attenuation of virulence in mice after intratracheal inoculation. This attenuation may be attributed to the inability of the PLC-null strain to grow in association with the macrophage. Complementation of these defects in both models of anthrax was achieved by expression of the PLC genes in trans. The functional redundancy between PLCs in the virulence of B. anthracis implies that their activities are important for anthrax pathogenesis.

Activation of sphingomyelinase from Bacillus cereus by Zn2+ hitherto accepted as a strong inhibitor

Sphingomyelinase (SMase) from Bacillus cereus has been known to be activated by Mg2+, Mn2+, and Co2+, but strongly inhibited by Zn2+. In the present study, we investigated the effects of several kinds of metal ions on the catalytic activity of B. cereus SMase, and found that the activity was inhibited by Zn2+ at its higher concentrations or at higher pH values, but unexpectedly activated at lower Zn2+ concentrations or at lower pH values. This result indicates that SMase possesses at least two different binding sites for Zn2+ and that the Zn2+ binding to the high-affinity site can activate the enzyme, whereas the Zn2+ binding to the low-affinity site can inactivate it. We also found that the binding of substrate to the enzyme was independent of the Zn2+ binding to the high-affinity site, but was competitively inhibited by the Zn2+ binding to the low-affinity site. The binding affinity of the metal ions to the site for activating the enzyme was determined to be in the rank-order of Mg2+ = Co2+ < Mn2+ < Zn2+. It was also demonstrated that these four metal ions competed with each other for the same binding site on the enzyme molecule.

Novel inhibition mechanism of Bacillus cereus sphingomyelinase by beryllium fluoride

Phosphate analogs have been known to inhibit competitively various phosphatases and phospholipase C and D. We found for the first time that only beryllium fluoride (BeF(x)) among the phosphate analogs studied inhibits Bacillus cereus sphingomyelinase (SMase) activity. The active inhibitory species proved to be not BeF(3)(-) but BeF(2) by the measurement of SMase activity and of (19)F NMR spectroscopy in the presence of a fixed concentration of BeCl(2) and different concentrations of NaF, although both the species have been reported for other kinds of enzymes. The result of kinetic experiment also indicated that the BeF(x) binds in the vicinity of the essential binding site for the substrate and that the Mg(2+) binding to SMase is essential for the binding of BeF(x) to the enzyme.

Chromogenic Assay for the Activity of Sphingomyelinase from Bacillus cereus and Its Application to the Enzymatic Hydrolysis of Lysophospholipids

We developed a convenient chromogenic assay method for the activity of sphingomyelinase (SMase) from Bacillus cereus. SMase reaction was quenched by Zn(2+), and the released phosphocholine was converted into a choline by the action of alkaline phosphatase. After that, the choline was converted into a chromogenic dye by the actions of choline oxidase and peroxidase in the presence of EDTA to trap the added Zn(2+) which could interfere with the choline oxidase/peroxidase reactions. Triton X-100 also was added to the reaction mixture, in order to remove turbidity generated from ceramide which had been produced by the SMase reaction. To test a large number of samples in a short period of time, this assay was performed using 96-well microtiter plates. This method proved to be applicable not only to the measurement of the hydrolysis of sphingomyelin but also to those of lysophosphatidylcholine (lysoPC) and lyso platelet-activating factor by B. cereus SMase. Using this method, the kinetic parameters (K(m) and k(cat)) for B. cereus SMase toward various types of substrates were then determined, and the effect of Triton X-100 on the hydrolysis of lysoPC was examined.

His151 and His296 are the acid-base catalytic residues of Bacillus cereus sphingomyelinase in sphingomyelin hydrolysis

Bacillus cereus sphingomyelinase belongs to the Mg(2+)-dependent neutral sphingomyelinase, which hydrolyses sphingomyelin to phosphocholine and ceramide, and acts as an extracellular hemolysin. The triplet residues, His151-Asp195-His296, of the enzyme are highly conserved among bacterial and mammalian Mg(2+)-dependent neutral sphingomyelinases. The triplet residues converge on the active-site pocket of the 3D model of the enzyme. To investigate the function of these residues in the acid-base catalysis, we introduced several mutations for each residue by site-directed mutagenesis. Hemolytic and hydrolytic activities of the enzyme, abolished by the mutations at Asp195 and His296, revealed that these residues are critical for the catalytic function. The effect of the divalent metal cations on the pH dependency of the hydrolytic activities indicates that His296 corresponds to the most acidic ionizable group as a general base. The mutagenesis at His151 was also deleterious; however, the H151A and H151Q mutant enzymes partially retained their activities. The H151A mutation affected the most basic ionizable group, suggesting that His151 may act as a general acid in catalysis. By the structural basis of the 3D model, Asp195 must maintain not only the appropriate spatial arrangement but also pK(a)s of His151 and His296. Taking into consideration all of these, we proposed the acid-base catalytic mechanism of B. cereus sphingomyelinase.

Cooperative, synergistic and antagonistic haemolytic interactions between haemolysin BL, phosphatidylcholine phospholipase C and sphingomyelinase from Bacillus cereus

Haemolysis of erythrocytes from different species (sheep, bovine, swine and human), caused by various combinations of phosphatidylcholine (PC)-preferring phospholipase C (PC-PLC), sphingomyelinase (SMase) and the three-component, pore-forming toxin haemolysin BL (HBL) from Bacillus cereus was analysed. The lytic potency of HBL did not correlate with phospholipid (PL) content, but lysis by the individual or combined enzymes did. SMase alone lysed ruminant erythrocytes, which contain 46-53% sphingomyelin (SM). The cooperative action of PC-PLC and SMase was needed to lyse swine and human erythrocytes (22-31% PC and 28-25% SM). SMase synergistically enhanced haemolysis caused by HBL for all erythrocytes tested, which all contained >25% SM. PC-PLC enhanced HBL haemolysis only in cells containing significant amounts of PC (swine, 22% PC; human, 31% PC). Unexpectedly, PC-PLC inhibited HBL lysis of sheep erythrocytes (<2% PC) and enhanced the discontinuous haemolysis pattern that is characteristic of HBL in sheep blood agar. Inhibition and pattern enhancement was abolished by washing PC-PLC-treated erythrocytes or by adding EDTA, suggesting that enzymic alteration of the membrane is not involved, but that zinc in the active site is required, perhaps to facilitate binding. These observations highlight the potential for cooperative and synergistic interactions among virulence factors in B. cereus infections and dependence of these effects on tissue composition.

Evidence for contribution of tripartite hemolysin BL, phosphatidylcholine-preferring phospholipase C, and collagenase to virulence of Bacillus cereus endophthalmitis

Bacillus cereus causes a highly fulminant endophthalmitis which usually results in blindness. We previously concluded that hemolysin BL (HBL), a tripartite necrotizing pore-forming toxin, is a probable endophthalmitis virulence factor because it is highly toxic to retinal tissue in vitro and in vivo. We also determined that B. cereus produces additional retinal toxins that might contribute to virulence. Here we fractionated crude B. cereus culture supernatant by anion-exchange chromatography and found that in vitro retinal toxicity was also associated with phosphatidylcholine-preferring phospholipase C (PC-PLC). The pure enzyme also caused retinal necrosis in vivo. We showed that phosphatidylinositol-specific PLC and sphingomyelinase were nontoxic and that two hemolysins, cereolysin O and a novel hemolysin designated hemolysin IV, were marginally toxic in vitro. The histopathology of experimental septic endophthalmitis in rabbits mimicked the pathology produced by pure HBL, and both HBL and PC-PLC were detected at toxic concentrations in infected vitreous fluid. Bacterial cells were first seen associated with the posterior margin of the lens and eventually were located throughout the lens cortex. Detection of collagenase in the vitreous humor suggested that infiltration was facilitated by the breakdown of the protective collagen lens capsule by that enzyme. This work supports our conclusion that HBL contributes to B. cereus virulence and implicates PC-PLC and collagenase as additional virulence factors.

Functions of ceramide in coordinating cellular responses to stress

Sphingolipid metabolites participate in key events of signal transduction and cell regulation. In the sphingomyelin cycle, a number of extracellular agents and insults (such as tumor necrosis factor, Fas ligands, and chemotherapeutic agents) cause the activation of sphingomyelinases, which act on membrane sphingomyelin and release ceramide. Multiple experimental approaches suggest an important role for ceramide in regulating such diverse responses as cell cycle arrest, apoptosis, and cell senescence. In vitro, ceramide activates a serine-threonine protein phosphatase, and in cells it regulates protein phosphorylation as well as multiple downstream targets [such as interleukin converting enzyme (ICE)-like proteases, stress-activated protein kinases, and the retinoblastoma gene product] that mediate its distinct cellular effects. This spectrum of inducers of ceramide accumulation and the nature of ceramide-mediated responses suggest that ceramide is a key component of intracellular stress response pathways.

A distant evolutionary relationship between bacterial sphingomyelinase and mammalian DNase I

The three-dimensional structure of bacterial sphingomyelinase (SMase) was predicted using a protein fold recognition method; the search of a library of known structures showed that the SMase sequence is highly compatible with the mammalian DNase I structure, which suggested that SMase adopts a structure similar to that of DNase I. The amino acid sequence alignment based on the prediction revealed that, despite the lack of overall sequence similarity (less than 10% identity), those residues of DNase I that are involved in the hydrolysis of the phosphodiester bond, including two histidine residues (His 134 and His 252) of the active center, are conserved in SMase. In addition, a conserved pentapeptide sequence motif was found, which includes two catalytically critical residues, Asp 251 and His 252. A sequence database search showed that the motif is highly specific to mammalian DNase I and bacterial SMase. The functional roles of SMase residues identified by the sequence comparison were consistent with the results from mutant studies. Two Bacillus cereus SMase mutants (H134A and H252A) were constructed by site-directed mutagenesis. They completely abolished their catalytic activity. A model for the SMase-sphingomyelin complex structure was built to investigate how the SMase specifically recognizes its substrate. The model suggested that a set of residues conserved among bacterial SMases, including Trp 28 and Phe 55, might be important in the substrate recognition. The predicted structural similarity and the conservation of the functionally important residues strongly suggest a distant evolutionary relationship between bacterial SMase and mammalian DNase I. These two phosphodiesterases must have acquired the specificity for different substrates in the course of evolution.

Inhibition of NGF-induced neurite outgrowth of PC12 cells by Bacillus cereus sphingomyelinase, a bacterial hemolysin

Sphingomyelinase of Bacillus cereus, a bacterial hemolysin, reduced nerve growth factor (NGF)-induced neurite outgrowth of PC12 cells in a dose-dependent manner. At 200 mU/ml, sphingomyelinase repressed half the neurite outgrowth of the cells at 250 ng/ml NGF. The c-fos superinduction, one of the early responses induced by NGF, was not influenced by this treatment, suggesting that the repression by sphingomyelinase occurred via a protein kinase C-independent pathway.

The role of acidic amino-acid residues in catalytic and adsorptive sites of Bacillus cereus sphingomyelinase

By the modification of acidic amino-acid residues with Woodward's reagent K (N-ethyl-5-phenylisoxazolium-3'-sulfonate), the activity of sphingomyelinase of Bacillus cereus was decreased by 80-90%. Also, the reduction of Cys residues in the sphingomyelinase molecule by dithiothreitol caused a drastic decrease in enzymatic activity, whereas the sphingomyelinase activity was not affected by treatment with p-chloromercuribenzenesulfonic acid. Actually, no inactivation of sphingomyelinase activity was observed after selective modification of basic amino-acid residues such as Lys, His and Arg, and of the uncharged amino-acid residues Ser and Thr. The treatment of the sphingomyelinase molecule with Woodward's reagent K or dithiothreitol also brought about the inhibition of the specific adsorption of sphingomyelinase toward intact erythrocyte membranes. However, the extent of inhibition in the enzyme adsorption, 20-50%, was less than that observed in the sphingomyelinase activity. These results suggest that acidic amino-acid residues, such as Asp and Glu, in the sphingomyelinase molecule are involved in the catalytic sites and the adsorptive sites. Apparently, the disruption of disulfide linkage in the sphingomyelinase molecule by dithiothreitol destabilized its structure, resulting in a drastic decrease in sphingomyelin-hydrolyzing activity and specific adsorption of sphingomyelinase towards erythrocyte membranes.

Molecular cloning and characterization of the hblA gene encoding the B component of hemolysin BL from Bacillus cereus

Previous evidence suggests that hemolysin BL, which consists of a binding component, B, and two lytic components, L1 and L2, is the enterotoxin responsible for the diarrheal form of gastroenteritis caused by food-borne strains of Bacillus cereus. To prove that hemolysin BL and the enterotoxin are the same requires large amounts of these components free of other B. cereus proteins. For this purpose, we sought to clone the gene encoding the B component and to express it in Escherichia coli. A partial genomic library was constructed and a 29-base, 1,152-fold-degenerate oligonucleotide probe, designed from the N-terminal amino acid sequence of the B component, was used to identify recombinant clones containing the gene. Detection of gene products reactive with a monoclonal antibody specific for the B component and analysis of the nucleotide sequence confirmed that isolated clones, reactive with the oligonucleotide probe, did contain the gene encoding the B component. The protein, expressed in E. coli, apparently from the B. cereus promoter, produces a ring-shaped zone of hemolysis when combined with purified L components from B. cereus, a reaction typical of hemolysin BL. Northern (RNA) blot analysis of B. cereus RNA showed a large (5.1-kb) transcript which hybridized with a 500-bp probe internal to the B-component-coding sequence, suggesting that the hblA gene encoding the B component may be transcribed as part of a polycistronic message, possibly including the structural genes for the two lytic components. Higher levels of expression and disruption of the hblA gene are being pursued to resolve whether hemolysin BL is indeed the enterotoxin.

Sphingomyelinase is part of the 'enterotoxin complex' produced by Bacillus cereus

The three components of the 'enterotoxin complex' have been purified and the sequence of the first 14-15 amino acids of the proteins determined. Limited homology was found in the N-terminal sequence of the three proteins. The molecular mass of the proteins was determined to be 48, 40 and 34 kDa, respectively. Only the 40-kDa protein was toxic to Vero cells, whilst the 34-kDa protein was found to be hemolytic. The sequence of the first 14 N-terminal amino acids of this protein was identical to the sequence of the sphingomyelinase residues 28-41 (the N-terminal after loss of the signal sequence), except for a change from Gln to Glu in position 33 of the sphingomyelinase sequence.