The carboxy-terminal C2-like domain of the α-toxin from Clostridium perfringens mediates calcium-dependent membrane recognition

The lethal, cytolytic α-toxin (phospholipase C) of Clostridium perfringens consists of two distinct modules: the larger N-terminal domain catalyses phospholipid hydrolysis, and its activity is potentiated by a smaller C-terminal domain. Calcium ions are essential for the binding of α-toxin to lipid films. Sixteen α-toxin variants with single amino acid substitutions in the C-terminal region were obtained using site-directed mutagenesis and T7 expression technology. Five of these variants showed reduced phospholipase C activity and were considerably less active than native α-toxin under calcium-limiting conditions. Replacement of Thr-272 by Pro diminished phospholipase C activity, severely affected haemolysis and platelet aggregation and perturbed a surface-exposed conformational epitope. The results of sequence comparisons and molecular modelling indicate that the C-terminal region probably belongs to the growing family of C₂β-barrel domains, which are often involved in membrane interactions, and that the functionally important substitutions are clustered at one extremity of the domain. The combined findings suggest that the C-terminal region of α-toxin mediates interactions with membrane phospholipids in a calcium-dependent manner. Mutations to this domain may account for the natural lack of toxicity of the α-toxin homologue, phospholipase C of Clostridium bifermentans .     

Detection of α- and ε-toxigenic Clostridium perfringens Type D in sheep and goats using a DNA amplification technique (PCR)

Clostridium perfringens isolated from sheep and goat with enterotoxaemia at necropsy and from healthy animals at slaughter were typed using specific PCR assays for the detection of the α-, β- and ε-toxin genes. Clostridium perfringens isolated from all 52 animals with pathological signs of enterotoxaemia showed the presence of the α- and ε-toxin genes but were devoid of the β-toxin gene. These strains could therefore be identified as type D, characteristic for clostridial enterotoxaemia of sheep, lambs and goats. In contrast, Cl. perfringens isolated from 11 of 13 healthy animals only contained the α-toxin gene which is typical for type A. Two of the healthy animals contained Cl. perfringens with the α- and ε-toxin genes. However, when several individual Cl. perfringens colonies were analysed from each of these two animals, only a small percentage was found to contain the ε-toxin gene, whereas the majority of the colonies were of type A with the α-toxin gene only. This is in contrast to the findings from the diseased animals which contained practically only type D Cl. perfringens . The β-toxin gene was not found in any Cl. perfringens isolate from goat and sheep. Comparison of the PCR data with results obtained by the classical biological toxin assay using the mouse model showed a good correlation.     

Perturbation of endothelial junction proteins by Staphylococcus aureus α-toxin: inhibition of endothelial gap formation by adrenomedullin

Endothelial hyperpermeability is a hallmark of an inflammatory reaction and contributes to tissue damage in severe infections. Loss of endothelial cell–cell adhesion leads to intercellular gap formation allowing paracellular fluid flux. Although Staphylococcus aureus α-toxin significantly contributed to staphylococci disease, little is known about its mechanism of endothelial hyperpermeability induction. Here, we demonstrate that in a model of isolated perfused rat ileum discontinuation of capillary vascular-endothelial-cadherin (VE-cadherin) was observed after bolus application of S. aureus α-toxin being inhibited by the endogenous peptide adrenomedullin (ADM). In vitro, α-toxin exposure induced loss of immunoreactivity of VE-cadherin and occludin in human cultured umbilical vein endothelial cells. Likewise, ADM blocked α-toxin-related junctional protein disappearance from intercellular sites. Additionally, cyclic AMP elevation was shown to stabilize endothelial barrier function after α-toxin application. Although no RhoA activation was noted after endothelial α-toxin exposure, inhibition of Rho kinase and myosin light chain kinase blocked loss of immunoreactivity of VE-cadherin and occludin as well as intercellular gap formation. In summary, stabilization of endothelial junctional integrity as indicated by interendothelial immunostaining might be an interesting approach to stabilize endothelial barrier function in severe S. aureus infections.Andreas C. Hocke and Bettina Temmesfeld-Wollbrueck have contributed equally to this article.     

Action of staphylococcal α-toxin on membranes: Some recent advances

Summary Recent developments in the area of Staphylococcal -toxin studies are presented which modify the concepts previously held with respect to both biological and physical properties of -toxin. New data concerning the nature of the binding site for -toxin on rabbit erythrocyte membranes and a model to explain the various observed complexes of -toxin and membrane receptor are discussed. Finally, evidence suggesting that Staphylococcal -toxin is a potent demyelinating agent is presented.The work was supported in part by NSF grant PCM 77-19307     

Staphylococcus aureus in chronic and recurrent infections

Ninety-fourStaphylococcus aureus strains isolated from chronic and recurrent skin and respiratory tract infections were investigated for several virulence factor expressions. Production of protein A was noticed in all of the tested strains in amounts from less than 0.1 to more than 2.5 ng per 10⁶ bacterial cells. The percentage of the extracellularly produced protein A was found to lie between 4.5 and 27.8%. Two strains (both from the respiratory tract) produced more than 50 % of protein A in the extracellular form and one strain did not produce any detectable amount of the extracellular protein A; 99 % of the tested strains produced the clumping factor, 96% staphylocoagulase, 79 % staphylokinase and 90 % gelatinolytic activity; 79 % produced α-toxin exclusively or in combination with δ- or β-toxin; 8 % of strains produced β-toxin. There were differences in β-toxin production between strains from the respiratory tract (5 %) and skin infections (25 %). δ-Toxin was produced by 53 % of the strains. In each of the tested strains a complex of virulence factors was detected. The importance of inactivated extracellular products (especially α- and δ-toxin and in the case of skin infections also β-toxin) as components of staphylococcal whole-cell vaccine was suggested. Dedicated to Professor C. John on the occasion of his 75th birthday     

Typing of Clostridium perfringens by in vitro amplification of toxin genes

G. DAUBE, B. CHINA, P. SIMON, K. HVALA AND J. MAINIL. 1994. The strains of Clostridium perfringens are classified according to major toxins produced. Classically, this determination involves the seroneutralization of their lethal effect in mice. However, this method requires specific antisera and a large number of mice. In this work, a new typing method was developed based on the amplification of toxin genes by polymerase chain reaction (PCR). By combination of several pairs of primers, the toxinotype of a Cl. perfringens strain was determined by looking at the pattern of bands on an agarose gel electrophoresis. This mixture contained primers amplifying simultaneously a part of α-toxin, α-toxin, β-toxin and enterotoxin genes. In order to distinguish between toxinotype A and E, the *** l -toxin gene fragment must be amplified in a separate PCR reaction. Moreover, with the primers combination, in most cases, a PCR product corresponding to the α-toxin gene was obtained from direct enrichments of animal intestinal contents.     

Chemical modification ofStaphylococcus aureus α-toxin by diethylpyrocarbonate: Role of histidines in its membrane-damaging properties

Summary Staphylococcus aureus -toxin causes cell damage by forming an amphiphilic hexamer that inserts into the cell membrane and generates a hydrophilic pore. To investigate the role of the three histidine residues of this toxin we modified them with diethylpyrocarbonate, obtaining N-carbethoxy-histidine whose appearance may be followed spectrophotometrically. Despite the statistical nature of random chemical modification, it was possible to establish that modification of any one of the three histidines was enough to impair -toxin activity on red blood cells and platelets. Two out of three histidines were essential for the interaction of the toxin with model membranes such as lipid vesicles and planar bilayers. Loss of lytic activity in both natural and model membranes was due both to defective binding and to defective oligomerization. When -toxin hexamers inserted into lipid vesicles were assayed for chemical modifiability two histidines per monomer were found to be protected from diethylpyrocarbonate modification, whereas only one was protected after delipidation of the oligomer with a detergent. A possible model for the role of each histidine in the monomer is presented.     

The rate assay of alpha-toxin assembly in membrane

Abstract A rapid and easy method to determine the 'rate' of the assembly of α-toxin from Staphylococus aureus in erythrocyte membrane was described. Upon addition of a small amount of α-toxins into erythrocyte suspension, absorbance at 700 nm decreased linearly after a short period of lag time. From the linear portion of the record the rate of the assembly of α-toxin was calculated. An optimum temperature and an optimum pH for the assembly of the toxin on erythrocyte membranes were found to be 25–30°C and pH 5.     

Oligomer formation of staphylococcal α-toxin analyzed by electron microscopy and image processing

Abstract The 12S oligomeric form of Staphylococcus aureus α-toxin has been studied with electron microscopy after incubation of the toxin with membrane preparations or liposomes. The target material originated from human platelet. Different electron microscopic preparation techniques were used including negative staining, freeze-fracture and vitrification in liquid ethane. Analysis of micrographs with image processing methods revealed two groups of ring-like structures corresponding to α-toxin oligomers. One form measured 75 Å in diameter and had a high stain density in the central protein deficient part while the other was larger with a diameter of 100 Å and less stain accumulation in the center. The conditions under which the latter were formed suggest that this corresponds to an inactive loosely-bound form of the toxin. The high stain density in the smaller particle is consistent with the presence of a penetrating pore in this structure.     

Inactivation of Rhizoctonia solani toxin by a putative α-glucosidase from coconut leaves for control of sheath blight disease in rice

Inactivation of a host-specific toxin, RS-toxin, induced by Rhizoctonia solani, the cause of rice sheath blight disease was investigated. A putative -glucosidase identified based on enzyme assay and Western blot analysis was purified from coconut (Cocos nucifera; the only known non-host of R. solani) leaves and tested for its efficacy in degrading RS-toxin. SDS–PAGE analysis showed the appearance of a 97 kDa protein, which appeared in proteins extracted from coconut leaf bits during 48 and 96 h after RS-toxin-treatment and the protein eventually disappeared. A comparison of the u.v. spectra read at 150–300 nm revealed conspicuous disturbances in the absorbance at 24 h of incubation of RS-toxin with the coconut leaf protein extracts as compared to that at 12 h, indicating the possible degradation of RS-toxin by coconut leaf -glucosidase during incubation. Incubation of rice leaf sheath bits with coconut leaf protein extracts significantly reduced electrolyte leakage due to RS-toxin 30 min after the toxin treatment. Simultaneously, there was a significant reduction in sheath blight symptoms when the incubation of rice leaf sheaths with the coconut leaf protein extracts was extended up to 96 or 120 h. This appears to be the first report of purification and characterization of a putative plant -glucosidase.     

Pore Formation by S. aureus α-toxin in Liposomes and Planar Lipid Bilayers: Effects of Nonelectrolytes

Nonelectrolytes such as polyethylene glycols (PEG) and dextrans (i) promote the association of S. aureus α-toxin with liposomes (shown by Coomassie staining) and (ii) enhance the rate and extent of calcein leakage from calcein-loaded liposomes; such leakage is inhibited by H⁺, Zn²⁺ and Ca²⁺ to the same extent as that of nonPEG-treated liposomes. Incubation of liposomes treated with α-toxin in the presence of PEG with the hydrophobic photo-affinity probe 3-(trifluoromethyl)-3-m-[¹²⁵I]iodophenyl)diazirine(¹²⁵I-TID) labels monomeric and—predominantly—hexameric forms of liposome-associated α-toxin; in the absence of PEG little labeling is apparent. At high concentrations of H⁺ and Zn²⁺ but not of Ca²⁺—all of which inhibit calcein leakage—the distribution of label between hexamer and monomer is perturbed in favor of the latter. In α-toxin-treated planar lipid bilayers from which excess toxin has been washed away, PEGs and dextrans strongly promote the appearance of ion-conducting pores. The properties of such pores are similar in most regards to pores induced in the absence of nonelectrolytes; they differ only in being more sensitive to ``closure' by voltage (as are pores induced in cells). In both systems, the stimulation by nonelectrolytes increases with concentration and with molecular mass up to a maximum around 2,000 Da. We conclude (i) that most of the α toxin that becomes associated with liposome or planar lipid bilayers does not form active pores and (ii) that the properties of α-toxin-induced pores in lipid bilayers can be modulated to resemble those in cells. Received: 2 October 1995/Revised: 3 November 1995     

Inhibition of staphylococcal α-toxin. The effect of aromatic polysulphonic acids on the lethal effect of α-toxin in mice

1. Certain aromatic polysulphonic acids, previously tested for inhibition of the haemolytic activity of staphylococcal α-toxin, together with some additional related compounds, were tested as possible inhibitors of α-toxin in mice. 2. Compounds that inhibited the haemolytic activity of α-toxin at concentrations of 0·16mm or less [compounds (I), (II), (IV), (V), (VII) and (VIII)] were found to inhibit the lethal effect of α-toxin. 3. With the exception of compound (VIII), amounts of 1mg. were required to inhibit 4 LD₅₀ of toxin when the test compounds were premixed with α-toxin before injection; comparable inhibition with 0·3mg. of compound (VIII) was achieved without prolonged premixing. 4. Mixtures of α-toxin and compounds (I) and (II) containing an excess of test compound showed markedly diminished inhibitory activities. 5. The `half-molecule' analogues of group 1 [compounds (III) and (XVIII)] were non-inhibitory. 6. Compounds (I)–(V), when administered separately from α-toxin by the same route (intraperitoneal), were active only when injected almost simultaneously with toxin, whereas compounds (VII) and (VIII) were strikingly inhibitory when injected 15min. before or after the toxin. 7. Compound (VIII) failed to inhibit the lethal effect of α-toxin when injected by a different route (intravenous).     

Virulence studies on chromosomal α-toxin and Θ-toxin mutants constructed by allelic exchange provide genetic evidence for the essential role of α-toxin in Clostridium perfringens-mediated gas gangrene

The pathogenesis of clostridial myonecrosis, or gas gangrene, involves the growth of the anaerobic bacterium Clostridium perfringens in the infected tissues and the elaboration of numerous extracellular toxins and enzymes. The precise role of each of these toxins in tissue invasion and necrosis has not been determined. To enable genetic approaches to be used to study C. perfringens pathogenesis we developed an allelic exchange method which involved the transformation of C. perfringens cells with a suicide plasmid carrying a gene insertionally inactivated with an erythromycin-resistance determinant. The frequency with which double reciprocal crossover events were observed was increased to a workable level by increasing the amount of homologous DNA located on either side of the inactivated gene. Allelic exchange was used to isolate mutations in the‘chromosomal pfoA gene, which encodes an oxygen-labile haemolysin known as Θ-toxin or perfringolysin O. and in the chromosomal pic gene, which encodes the α-toxin or phospholipase C. The resultant mutants failed to produce detectable Θ-toxin or α-toxin activity, respectively, and could be complemented by recombinant plasmids that carried the respective wild-type genes. The resultant strains were virulence tested in a mouse myonecrosis model. The results showed that the pic mutants had demonstrably reduced virulence and therefore provided definitive genetic evidence for the essential role of α-toxin in gas gangrene or clostridial myonecrosis.     

Structure–activity relationships in Kluyveromyces lactis γ-toxin,a eukaryal tRNA anticodon nuclease

tRNA anticodon damage inflicted by secreted ribotoxins such as Kluyveromyces lactis γ-toxin and bacterial colicins underlies a rudimentary innate immune system that distinguishes self from nonself species. The intracellular expression of γ-toxin (a 232-amino acid polypeptide) arrests the growth of Saccharomyces cerevisiae by incising a single RNA phosphodiester 3′ of the modified wobble base of tRNA^Glu. Fungal γ-toxin bears no primary structure similarity to any known nuclease and has no plausible homologs in the protein database. To gain insight to γ-toxin''s mechanism, we tested the effects of alanine mutations at 62 basic, acidic, and polar amino acids on ribotoxin activity in vivo. We thereby identified 22 essential residues, including 10 lysines, seven arginines, three glutamates, one cysteine, and one histidine (His209, the only histidine present in γ-toxin). Structure–activity relations were gleaned from the effects of 44 conservative substitutions. Recombinant tag-free γ-toxin, a monomeric protein, incised an oligonucleotide corresponding to the anticodon stem–loop of tRNA^Glu at a single phosphodiester 3′ of the wobble uridine. The anticodon nuclease was metal independent. RNA cleavage was abolished by ribose 2′-H and 2′-F modifications of the wobble uridine. Mutating His209 to alanine, glutamine, or asparagine abolished nuclease activity. We propose that γ-toxin catalyzes an RNase A-like transesterification reaction that relies on His209 and a second nonhistidine side chain as general acid–base catalysts.     

The Level of Expression of α-toxin by Different Strains ofClostridium perfringensis Dependent on Differences in Promoter Structure and Genetic Background

The control of expression of the α-toxin gene (cpaorplc) ofClostridium perfringenshas been studied in three strains shown to have high (NCTC8237), intermediate (strain 13) and low (NCTC8533) phospholipase C activity in the culture supernatant. The phospholipase C activity was shown to be related tocpamRNA levels. Primer extension studies were performed to locate thecpapromoter regions in strains NCTC8237 and 13. Differences in promoter sequences could account for the differences in α-toxin production between strains 13 and NCTC8237. In contrast, the differences in α-toxin production between strains NCTC8237 and NCTC8533 were unlikely to be due to promoter differences because the upstream promoter-containing sequences were identical in these strains. The recombinant plasmid carrying the NCTC8237cpagene was introduced into strains 13 and NCTC8533. The level of production of the α-toxin was 16-fold higher in strain 13, indicating the presence of strain-dependant regulatory systems.     

The role of histidine residues in the alpha toxin of Clostridium perfringens

The α -toxin (phospholipase C) of Clostridium perfringens has been reported to contain catalytically essential zinc ions We report here that histidine residues are essential for the co-ordination of these ion(s). Incubation of alpha toxin with diethylpyrocarbonate, a histidine modifying reagent, did not result in the loss of phospholipase C activity unless the protein was first incubated with EDTA, suggesting that zinc ions normally protect the susceptible histidine residues. When the amino acid sequences of three phospholipase C's were aligned, essential zinc binding histidine residues in the non-toxic B. cereus phospholipase C were found in similar positions in the toxic C. perfringens enzyme and the weakly toxic C. bifermentans phospholipase C.     

Staphylococcus epidermidis Antimicrobial δ-Toxin (Phenol-Soluble Modulin-γ) Cooperates with Host Antimicrobial Peptides to Kill Group A Streptococcus

Antimicrobial peptides play an important role in host defense against pathogens. Recently, phenol-soluble modulins (PSMs) from Staphylococcus epidermidis (S. epidermidis) were shown to interact with lipid membranes, form complexes, and exert antimicrobial activity. Based on the abundance and innocuity of the cutaneous resident S. epidermidis, we hypothesized that their PSMs contribute to host defense. Here we show that S. epidermidis δ-toxin (PSMγ) is normally present in the epidermis and sparsely in the dermis of human skin using immunohistochemistry. Synthetic δ-toxin interacted with neutrophil extracellular traps (NETs) and colocalized with cathelicidin while also inducing NET formation in human neutrophils. In antimicrobial assays against Group A Streptococcus (GAS), δ-toxin cooperated with CRAMP, hBD2, and hBD3. In whole blood, addition of δ-toxin exerted a bacteriostatic effect on GAS, and in NETs, δ-toxin increased their killing capacity against this pathogen. Coimmunoprecipitation and tryptophan spectroscopy demonstrated direct binding of δ-toxin to host antimicrobial peptides LL-37, CRAMP, hBD2, and hBD3. Finally, in a mouse wound model, GAS survival was reduced (along with Mip-2 cytokine levels) when the wounds were pretreated with δ-toxin. Thus, these data suggest that S. epidermidis–derived δ-toxin cooperates with the host-derived antimicrobial peptides in the innate immune system to reduce survival of an important human bacterial pathogen.     

Lambda-Toxin of Clostridium perfringens Activates the Precursor of Epsilon-Toxin by Releasing Its N- and C-Terminal Peptides

The effect of γ-toxin, a thermolysin-like metalloprotease of Clostridium perfringens, on the inactive ε-prototoxin produced by the same organism was examined. When the purified ε-prototoxin was incubated with the purified γ-toxin at 37 C for 2 hr, the 32.5-kDa ε-prototoxin was processed into a 30.5-kDa polypeptide, as determined by SDS-polyacrylamide gel electrophoresis. A mouse lethality test showed that the treatment activated the prototoxin: the 50% lethal doses (LD₅₀) of the prototoxin with and without γ-toxin treatment were 110 and 70,000 ng/kg of body weight, respectively. The lethal activity of the prototoxin activated by γ-toxin was comparable to that with trypsin plus chymotrypsin and higher than that with trypsin alone: LD₅₀ of the prototoxin treated with trypsin and trypsin plus chymotrypsin were 320 and 65 ng/kg of body weight, respectively. The ε-toxin gene was cloned and sequenced. Determination of the N-terminal amino acid sequence of each activated ε-prototoxin revealed that γ-toxin cleaved between the 10th and 11th amino acid residues from the N-terminus of the prototoxin, while trypsin and trypsin plus chymotrypsin cleaved between the 13th and 14th amino acid residues. The molecular weight of each activated ε-prototoxin was also determined by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. The C-terminus deduced from the molecular weight is located at the 23rd or 30th amino acid residue from the C-terminus of the prototoxin, suggesting that removal of not only N-terminal but also C-terminal peptide is responsible for activation of the prototoxin.