Proteolytic Cleavage of Tetanus Toxin Increases Activity

Tetanus toxin is initially synthesized in the form of a single polypeptide chain and then proteolytically "nicked" by the bacteria to produce a two-chain structure joined by a disulfide bond. This two-chain form of the toxin is the form known to be biologically active. Whether such nicking is necessary for activity, as it is for certain other bacterial toxins, has not been demonstrated previously. Single-chain toxin preparations produced by salt extraction from the bacteria are characterized and compared with pure two-chain toxin obtained from extracellular filtrates. The ability of these various toxin preparations to produce paroxysmal activity in mouse spinal cord neurons grown in dissociated cell culture is described. The pure two-chain toxin is demonstrated to have greater activity than the single-chain toxin preparations. Indeed the activity of the single-chain toxin preparations can be explained by the small amounts of residual two-chain toxin present in these extracts. Using a protease from a toxin-minus strain of Clostridium tetani to convert a single-chain toxin preparation to two-chain toxin increases toxin activity. In vivo the single-chain toxin preparation is also less toxic. These findings indicate that proteolytic nicking of tetanus toxin increases activity. The unnicked, single-chain form of tetanus toxin may be a relatively nontoxic protoxin form of the toxin; this is a structure-function relationship similar to that of other bacterial protein toxins.     

Modeling of toxin–antibody interaction and toxin transport toward the endoplasmic reticulum

A model for toxin–antibody interaction and toxin trafficking towards the endoplasmic-reticulum is presented. Antibody and toxin (ricin) initially are delivered outside the cell. The model involves: the pinocytotic (cellular drinking) and receptor-mediated toxin internalization modes from the extracellular into the intracellular domain, its exocytotic excretion from the cytosol back to the extracellular medium, the intact toxin retrograde transport to the endoplasmic reticulum, the anterograde toxin movement outward from the cell across the plasma membrane, the lysosomal toxin degradation, and the toxin clearance (removal from the system) flux. The model consists of a set of coupled PDEs. Using an averaging procedure, the model is reduced to a system of coupled ODEs. Both PDEs and ODEs systems are solved numerically. Numerical results are illustrated by figures and discussed.     

Amino acid sequence of a sea anemone toxin from Parasicyonis actinostoloides

Amino-acid sequence of a toxin from sea anemone, Parasicyonis actinostoloides, is determined. The toxin consists of 31 amino acid residues and is cross-linked with four disulphide bridges. The sequence has some similarity to that of toxin III and no similarity to those of toxin I and toxin II both from sea anemone, Anemonia sulcata, or to that of Anthopleurin A from Anthopleura xanthogrammica.     

利用组织培养技术选育玉米抗小叶斑病突变体

大叶斑病和小叶斑病是玉米最严重的病害,选育抗大、小叶斑病优良自交系及单交种是提高玉米产量的重要措施。Ｇｅｎｇｅｎｂａｃｈ等以玉米Ａ６１９ｃｍｓＴ愈伤组织为材料,筛选出对小叶斑病毒素具有抗性的愈伤组织与再生植株［１,２］,开辟了玉米抗病育种的新途径。...     

Activation of Clostridium botulinum type E toxin purified by two different procedures

Clostridium botulinum type E toxin was purified from culture supernates and from cell extracts by two methods. The specific activity [2 X 10(4) mouse LD50 (mg protein)-1] of the toxin purified from cell extract under slightly acidic conditions was lower than that [3 X 10(5) LD50 (mg protein)-1] of the toxin purified from culture supernate under slightly alkaline conditions. Both toxin preparations were activated by trypsin treatment, but to different extents, the degree of activation of the toxin from cell extract being about 30-fold higher than that of the toxin from culture supernate. The two toxin preparations had the same electrophoretic mobility on SDS-polyacrylamide gels and antigenic specificity as revealed by agar gel double-immunodiffusion tests. The antigenic specificity of the two toxin preparations was unaltered by trypsin treatment. In SDS-polyacrylamide gel electrophoresis, a single band of Mr 144,000 was demonstrated before trypsin treatment and two bands of Mr 100,000 and 55,000 appeared after trypsin treatment. The two toxin preparations were labelled with 125I and chymotryptic peptide maps were obtained before and after trypsin treatment. The two toxin preparations without trypsin treatment demonstrated many differences in their peptide maps, but the preparations after trypsin activation had similar peptide maps. These results indicate that the toxin obtained from culture fluid was a partially activated form, and that its molecular conformation was different from that of the toxin from cell extract. Differences in specific activity and activation ratio by trypsin treatment may be due to differences in the conformation of the toxin molecules.     

The entry of diphtheria toxin into the mammalian cell cytoplasm: evidence for lysosomal involvement

Lysosomotropic amines, such as ammonium chloride, are known to protect cells from the cytotoxic effects of diphtheria toxin. These drugs are believed to inhibit the transport of the toxin from a receptor at the cell exterior into the cytoplasm where a fragment of the toxin arrests protein synthesis. We studied the effects of lysosomotropic agents on the cytotoxic process to better understand how the toxin enters the cytoplasm. The cytotoxic effects of diphtheria toxin were not inhibited by antitoxin when cells were preincubated at 37 degrees C with toxin and ammonium chloride, exposed to antitoxin at 4 degrees C, washed to relieve the ammonium chloride inhibition, and finally warmed to 37 degrees C. The antigenic determinants of the toxin were, therefore, either altered or sheltered. It is likely that the combination of ammonium chloride and a low temperature trapped the toxin in an intracellular vesicle from which the toxin could proceed to the cytoplasm. Because lysosomotropic amines raise the pH within acidic intracellular vesicles, such as lysosomes, they could trap the toxin within such a vesicle if an acidic environment were necessary for the toxin to penetrate into the cytoplasm. We simulated acidic conditions which the toxin might encounter by exposing cells with toxin bound to their surface to acidic medium. We then measured the effects of lysosomotropic amines on the activity of the toxin to see if the acidic environment substituted for the function normally inhibited by the drugs. The drugs no longer protected the cells. This suggests that exposing the toxin to an acidic environment, such as that found within lysosomes, is an important step in the penetration of diphtheria toxin into the cytoplasm.     

Metabolism of trichothecene mycotoxins. I. Microsomal deacetylation of T-2 toxin in animal tissues

In an attempt to elucidate the active form of T-2 toxin, one of trichothecene mycotoxins in vivo, the metabolism in animal tissues was studied in vitro by using gas liquid chromatography. T-2 toxin was selectively hydrolysed by the microsomal esterase at C-4, giving rise to HT-2 toxin as the only metabolite. This esterase activity was found mainly in the microsomes of liver, kidney, and spleen of laboratory animals. Since the enzymatic hydrolysis of T-2 toxin was inhibited by eserine, and diisopropylfluorophosphate, it is concluded that non-specific carboxyesterase [EC 3.1.1.1] of microsomal origin participates in this type of selective hydrolysis of T-2 toxin. The microsomal fraction from rabbit liver was proved to be a convinient material for the preparation of HT-2 toxin from T-2 toxin. From the evidence that the toxicity of HT-2 toxin is comparable to that of T-2 toxin and that the microsomal fraction of whole liver possesses the ability to biotransform the total lethal dose of T-2 toxin into HT-2 within a few minutes, T-2 toxin administered to animals is presumed to exhibit its toxicity partly as HT-2 toxin.     

Binding of the Bacillus sphaericus mosquito larvicidal toxin to cultured insect cells

Using both fluorescent labelled toxin and antibody--secondary antibody techniques, the Bacillus sphaericus toxin was found to bind strongly to susceptible Culex quinquefasciatus cells, but far less strongly to cells of insensitive insects. An insensitive clone of the C. quinquefasciatus cell line was discovered which bound toxin efficiently. The toxin was bound in the cold to sensitive cells and these cells could be rescued from cytotoxicity for ca. 15 min after warming, by which time toxin appeared to be internalized. Binding was saturable. This toxin is apparently internalized by receptor-mediated endocytosis, probably involving a glycoprotein receptor containing N-acetyl-D-glucosamine. Evidence for toxin binding to lipids was not found. Antibody appeared to detect internalized toxin, and high concentrations of sugars inhibited cytotoxicity; these results along with evidence from a recent ultrastructural study suggest that this toxin may form pores in the cell membrane.     

Endocytosis and intracellular transport of the glycolipid-binding ligand Shiga toxin in polarized MDCK cells

The glycolipid-binding cytotoxin produced by Shigella dysenteriae 1, Shiga toxin, binds to MDCK cells (strain 1) only after treatment with short-chain fatty acids like butyric acid or with the tumor promoter 12-O-tetradecanoylphorbol 13-acetate. The induced binding sites were found to be functional with respect to endocytosis and translocation of toxin to the cytosol. Glycolipids that bind Shiga toxin appeared at both the apical and the basolateral surface of polarized MDCK cells grown on filters, and Shiga toxin was found to be endocytosed from both sides of the cells. This was demonstrated by EM of cells incubated with Shiga-HRP and by subcellular fractionation of cells incubated with 125I-labeled Shiga toxin. The data indicated that toxin molecules are endocytosed from coated pits, and that some internalized Shiga toxin is transported to the Golgi apparatus. Fractionation of polarized cells incubated with 125I-Shiga toxin showed that the transport of toxin to the Golgi apparatus was equally efficient from both poles of the cells. After 1-h incubation at 37 degrees C approximately 10% of the internalized toxin was found in the Golgi fractions. The results thus suggest that glycolipids can be efficiently transported to the Golgi apparatus from both sides of polarized MDCK cell monolayers.     

Monoclonal antibody against diphtheria toxin. Effect on toxin binding and entry into cells

A number of monoclonal antibodies against diphtheria toxin were isolated. Some of their properties were determined. Antibody 2 reacts with the region of between 30 and 45 kDa from the NH2 terminus of toxin. Antibody 7 reacts with the COOH-terminal 17-kDa region of toxin. These two antibodies show sharp contrasts in their effects on toxin action in cultured cells. When antibody 2 or 7 and toxin were mixed, incubated at 37 degrees C, and then added to sensitive Vero cells, antibody 7 blocked toxin action, but antibody 2 did not. When antibody 2 or 7 was added to cells to which toxin had been prebound at 4 degrees C, and the cells were then shifted to 37 degrees C, antibody 7 did not block toxin action, but antibody 2 inhibited intoxication. Antibody 7 blocked binding of 125I-toxin to cells and did not block degradation of toxin associated with cells. Antibody 2 did not block binding of 125I-toxin to cells, and was able to bind to cells in the presence of toxin. The results obtained from the effect of antibody 2 on degradation of 125I-toxin associated with cells resemble those seen with amines, which block toxin action but do not inhibit binding of toxin to cells. These facts show that antibody 2 does not block binding of toxin to cell surfaces, but blocks the entry of toxin into the cytosol at a step after binding of toxin to the receptor. Antibodies 14 and 15 react with fragment A of diphtheria toxin, but have no effect on any activity of toxin. The other monoclonal antibodies have effects on toxin binding and entry intermediate between those of 2 and 7.     

The pyrogenic effect of scarlet fever toxin

Scarlet fever toxin was found to liberate leukocytic pyrogen from granulocytesin vitro. In comparative experiments withSalmonella paratyphi B endotoxin and scarlet fever toxin it was tested whether leukocytes from rabbits tolerant to one of these toxins are able to synthetize and liberate endogenous pyrogen. Leukocytes from rabbits tolerant to endotoxin liberated leukoeytic pyrogen following challenge with endotoxin or with scarlet fever toxin. Leukocytes from animals tolerant to scarlet fever toxin liberated leukocytic pyrogen in the presence of endotoxin, but were insensitive to homologous, i.e. scarlet fever toxin. Similarly, leukocytes from cortisone-treated animals did not liberate leukocytic pyrogen if they were incubated with scarlet fever toxin, but liberation of leukocytic pyrogen did take place under challenge with endotoxin. Leukocytes from normal animals incubated in Hanks solution without toxin did not synthetize endogenous pyrogen.     

嗜线虫致病杆菌HB310菌株杀虫蛋白的纯化及活性鉴定

嗜线虫致病杆菌Xenorhabdus nematophila HB310是从河北省土壤中筛选出的一株昆虫病原线虫体内分离纯化获得的共生菌,该菌的发酵液对多种昆虫有较高的杀虫活性。利用85％饱和度的硫酸铵盐析分别获得胞内蛋白提取物和上清液中胞外蛋白提取物,生测结果表明这两种蛋白提取物中都含有胃毒素和血腔毒素。通过制备型非变性凝胶电泳对蛋白提取物进行分离和纯化,得到了3种有杀虫活性的毒素蛋白（毒素Ⅰ、毒素Ⅱ和毒素Ⅲ）,胞内的毒素蛋白与分泌到胞外上清液中的毒素蛋白是同种蛋白。毒素Ⅰ和毒素Ⅱ对棉铃虫初孵幼虫有明显的胃毒活性,但没有血腔毒性;毒素Ⅲ对大蜡螟幼虫有很强的血腔毒性,LD₅₀为0.18 μg/头。SDS-PAGE图谱显示毒素Ⅰ和毒素Ⅱ是由多个多肽组成的复合蛋白,而毒素Ⅲ只分离出一条多肽。毒素Ⅱ在50℃处理10 min,其杀虫活性没有显著变化;70℃处理10 min对毒素Ⅲ杀虫活性没有显著影响。     

Comparison of AP-PCR methods,ribotyping (PCR-ribotyping) and pulsed-field electrophoresis (PFGE) for strains of Clostridium difficile producing toxin B and not producing toxin A

In this study were used AP-PCR, PCR-ribotyping and pulsed-field elecrophoresis (PFGE) for comparative study of toxin A-negative/toxin B-posi-tive Clostridium difficile strains with deletion in toxin A gen. We investigated nine unrelated clinical strains, isolated from different units and different time from patients suffering to antibiotic associated diarrhea (AAD). We found that toxin A-negative/toxin B-positive C. difficile strains isolated in Poland belonging to a single genotype A, are being similar to the Japanese strains.     

The nucleotide exchange factors Grp170 and Sil1 induce cholera toxin release from BiP to enable retrotranslocation

Cholera toxin (CT) intoxicates cells by trafficking from the cell surface to the endoplasmic reticulum (ER), where the catalytic CTA1 subunit hijacks components of the ER-associated degradation (ERAD) machinery to retrotranslocate to the cytosol and induce toxicity. In the ER, CT targets to the ERAD machinery composed of the E3 ubiquitin ligase Hrd1-Sel1L complex, in part via the activity of the Sel1L-binding partner ERdj5. This J protein stimulates BiP''s ATPase activity, allowing BiP to capture the toxin. Presumably, toxin release from BiP must occur before retrotranslocation. Here, using loss-and gain-of-function approaches coupled with binding studies, we demonstrate that the ER-resident nucleotide exchange factors (NEFs) Grp170 and Sil1 induce CT release from BiP in order to promote toxin retrotranslocation. In addition, we find that after NEF-dependent release from BiP, the toxin is transferred to protein disulfide isomerase; this ER redox chaperone is known to unfold CTA1, which allows the toxin to cross the Hrd1-Sel1L complex. Our data thus identify two NEFs that trigger toxin release from BiP to enable successful retrotranslocation and clarify the fate of the toxin after it disengages from BiP.     

Purification and physicochemical properties of a unique Vero cell cytotoxin from Escherichia coli O157:H7

A unique Vero cell cytotoxin has been purified to homogeneity from a strain of Escherichia coli O157:H7, using ultrafiltration with Pellicon membrane cassettes and chromatography with QAE Sephadex A-50. SDS-PAGE showed the molecular weight of the toxin to be 64,000 and the absence of subunits. Based on analytical isoelectric focusing, the toxin had pI of 5.2. This Vero cell toxin was lethal to mice and showed pathological abnormalities of the mouse colonic mucosa when administered intraperitoneally. Vero cell cytotoxicity of this toxin was not neutralizable with rabbit antiserum to Shiga toxin. Based on physicochemical and immunological properties, this toxin is different from the Shiga-like toxin previously found in this organism.     

Entry of diphtheria toxin-protein A chimeras into cells

Fusion proteins consisting of diphtheria toxin and a duplicated Fc-binding domain of protein A were made in vitro after amplification of the DNA template by the polymerase chain reaction. The fusion proteins bound avidly to Vero cells coated with antibodies. A fusion protein containing full-length diphtheria toxin was toxic at lower concentrations than diphtheria toxin alone, apparently due to more efficient binding. The enzymatic part of the fusion protein was translocated across the surface membrane upon exposure to low pH. Like authentic diphtheria toxin, the fusion protein formed cation selective channels at low pH. Excess amounts of unlabeled diphtheria toxin inhibited formation of pronase-protected fragments derived from radiolabeled fusion protein. Furthermore, conditions that down-regulate the diphtheria toxin receptors reduced the sensitivity of the cells to the fusion protein, supporting the notion that authentic diphtheria toxin receptors are required. At temperatures below 18 degrees C the toxicity of the fusion protein was strongly reduced, whereas there was no temperature block for authentic diphtheria toxin. Brefeldin A protected Vero cells against the fusion protein but not against diphtheria toxin. The results indicate that the diphtheria toxin receptor is required for efficient toxin translocation even under conditions where the toxin is bound by an alternate binding moiety, and they suggest that the intracellular routing of the fusion protein is different from that of diphtheria toxin.     

Production and characteristics of monoclonal antibodies to the diphtheria toxin

Monoclonal antibodies to the diphtheria toxin were produced without cross reactivity with the thermolabile toxin (LT) from Escherichia coli; ricin; choleraic toxin; the SeA, SeB, SeE, SeI, and SeG toxins of staphylococcus; the lethal factor of the anthrax toxin; and the protective antigen of the anthrax toxin. A pair of antibodies for the quantitative determination of the diphtheria toxin in the sandwich variation of enzyme-linked immunosorbent assay (ELISA) was chosen. The determination limit of the toxin was 0.7 ng/ml in plate and 1.6 ng/ml in microchip ELISA. The presence of a secretion from the nasopharynx lavage did not decrease the sensitivity of the toxin determination by sandwich ELISA. The immunization of mice with the diphtheria toxin and with a conjugate of the diphtheria toxin with polystyrene microspheres demonstrated that the conjugate immunization resulted in the formation of hybridoma clones which produced antibodies only to the epitopes of the A fragment of the diphtheria toxin. The immunization with the native toxin caused the production of hybridoma clones which predominantly produced antibodies to the epitopes of the B fragment.     

Identification of the syntrophic partners in a coculture coupling anaerobic methanol oxidation to Fe(III) reduction

The repeating sequences of the toxin A gene from toxin A-negative, toxin B-positive (toxin A-, toxin B+) strains of Clostridium difficile which were isolated in geographically separated facilities in Japan and Indonesia were determined. All six strains tested had identical repeating sequences with two deletions (1548 and 273 nucleotides in size) in the toxin A gene. A PCR method was designed to detect the deletions and the deletions were confirmed in all 50 toxin A-, toxin B+ strains examined by this method. Western immunoblot analysis revealed that polyclonal antiserum against native toxin A did not react with the concentrated culture filtrates of the toxin A-, toxin B+ strains. These results may suggest that toxin A-, toxin B+ strains have deletions of the two thirds of the repeating regions of the toxin A gene, which encodes the epitopes fully responsible for the reaction with the polyclonal antiserum.     

Response of Cultured Mammalian Cells to Diphtheria Toxin III. Inhibition of Protein Synthesis Studied at the Subcellular Level

Diphtheria toxin inhibited protein synthesis in intact KB cells. The action of the toxin upon the cell did not result in disaggregation of polyribosomes, or in impairment of their ability to function in protein synthesis. A reduction in single ribosomes and a concomitant increase in polyribosomes did result from the action of toxin. Nascent peptides were not cleaved from polyribosomes by the action of toxin, but treatment of fully intoxicated cells with puromycin resulted in cleavage of these peptides, and caused accelerated polyribosome breakdown. Our data indicated that the toxin must enter the cell to exert its effect. The component or components sensitive to toxin were localized in the 100,000 x g supernatant fraction of cytoplasmic extracts. When extracts from intoxicated cells were treated with nicotinamide, a significant proportion of their capacity to synthesize protein was restored. The specificity of this reaction suggested that nicotinamide adenine dinucleotide is involved in the action of toxin in the intact cell, and that one component inactivated by toxin is soluble transferase II.     

Action of different toxins from the scorpion Androctonus australis on a locust nerve-muscle preparation

The neuromuscular effects of four purified toxins and crude venom from the scorpion Androctonus australis were investigated in the extensor tibiae nerve-muscle preparation of the locust Locusta migratoria. Insect and crustacean toxin and the mammal toxins I and II which have previously been shown to act on fly larvae, isopods, and mice all paralyse locust larvae. The paralytic potencies decrease in the following order: insect toxin → mammal toxin I → crustacean toxin → mammal toxin II.The toxins and crude venom cause repetitive activity of the motor axons. This leads to long spontaneous trains of junction potentials in the case of crude venom and insect toxin. The other toxins chiefly cause short bursts of action and junction potentials following single stimuli.The ‘slow’ excitatory motor axon invariably is affected sooner than the inhibitory or the ‘fast’ excitatory one. The minimal doses of toxins required to affect the ‘slow’ motor axon decrease in an order somewhat different from that established for their paralytic potencies: insect toxin → crustacean toxin → mammal toxin I → mammal toxin II.Crude venom depolarises and destabilises the muscle membrane potential at low doses. At high doses it decreases the membrane resistance, whereas insect toxin leads to an increase.Crude venom and insect toxin enhance the frequency of mejps, whereas mammal toxin I leads to the occurrence of ‘giant’ mejps.The pattern of axonal activities indicates that the various peripheral branches of the motor nerve are the primary target of the toxins.The time course of nerve action potentials is affected by mammal toxin I and crustacean toxin which cause anomalous shapes and prolongations not caused by insect toxin.The results with other animals suggest that only the insect toxin is selective in its activity. The way it affects the axon might be quite different from that previously reported for scorpion venoms or toxins.