Potentiation and cellular phenotypes of the insecticidal Toxin complexes of Photorhabdus bacteria

The toxin complex (tc) genes of bacteria comprise a large and growing family whose mode of action remains obscure. In the insect pathogen Photorhabdus, tc genes encode high molecular weight insecticidal toxins with oral activity against caterpillar pests. One protein, TcdA, has recently been expressed in transgenic plants and shown to confer insect resistance. These toxins therefore represent alternatives to toxins from Bacillus thuringiensis (Bt) for deployment in transgenic crops. Levels of TcdA expression in transgenic plants were, however, low and the full toxicity associated with the native toxin was not reconstituted. Here we show that increased activity of the toxin TcdA1 requires potentiation by either of two pairs of gene products, TcdB1 and TccC1 or TcdB2 and TccC3. Moreover, these same pairs of proteins can also cross-potentiate a second toxin, TcaA1B1. To elucidate the likely functional domains present in these large proteins, we expressed fragments of each 'toxin' or 'potentiator' gene within mammalian cells. Several domains produced abnormal cellular morphologies leading to cell death, while others showed specific phenotypes such as nuclear translocation. Our results prove that the Tc toxins are complex proteins with multiple functional domains. They also show that both toxin genes and their potentiator pairs will need to be expressed to reconstitute full activity in insect-resistant transgenic plants. Moreover, they suggest that the same potentiator pair will be able to cross-potentiate more than one toxin in a single plant.     

Purification and Properties of Clostridium botulinum Type F Toxin

Clostridium botulinum type F toxin of proteolytic Langeland strain was purified. Toxin in whole cultures was precipitated with (NH₄)₂SO₄. Extract of the precipitate was successively chromatographed on diethylaminoethyl-cellulose at pH 6.0, O-(carboxymethyl) cellulose at pH 4.9, Sephadex G-200 at pH 8.1, quaternary aminoethyl-Sephadex at pH 4.9, and finally diethylaminoethyl-cellulose at pH 8.1. The procedure recovered 14% of the toxin assayed in the starting culture. The toxin was homogeneous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, double gel diffusion serology, and isoelectric focusing. Purified toxin had a molecular weight of 150,000 by gel filtration and 155,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Specific toxicity was 9.6 × 10⁶ mean lethal doses per absorbancy (278 nm) unit. Sub-units of 105,000 and 56,000 molecular weight are found when purified toxin is treated with a disulfide reducing agent and electrophoresed on sodium dodecyl sulfate-polyacrylamide gels. Reciprocal cross neutralizations were demonstrated when purified type F and E toxins were reacted with antitoxins which were obtained with immunizing toxoids prepared with purified toxins.     

Protease activation of the entomocidal protoxin of Bacillus thuringiensis subsp. kurstaki

Two isolates of Bacillus thuringiensis subsp. kurstaki were examined which produced different levels of intracellular proteases. Although the crystals from both strains had comparable toxicity, one of the strains, LB1, had a strong polypeptide band at 68,000 molecular weight in the protein from the crystal; in the other, HD251, no such band was evident. When the intracellular proteases in both strains were measured, strain HD251 produced less than 10% of the proteolytic activity found in LB1. These proteases were primarily neutral metalloproteases, although low levels of other proteases were detected. In LB1, the synthesis of protease increased as the cells began to sporulate; however, in HD251, protease activity appeared much later in the sporulation cycle. The protease activity in strain LB1 was very high when the cells were making crystal toxin, whereas in HD251 reduced proteolytic activity was present during crystal toxin synthesis. The insecticidal toxin (molecular weight, 68,000) from both strains could be prepared by cleaving the protoxin (molecular weight, 135,000) with trypsin, followed by ion-exchange chromatography. The procedure described gave quantitative recovery of toxic activity, and approximately half of the total protein was recovered. Calculations show that these results correspond to stoichiometric conversion of protoxin to insecticidal toxin. The toxicities of whole crystals, soluble crystal protein, and purified toxin from both strains were comparable.     

Protease activation of the entomocidal protoxin of Bacillus thuringiensis subsp. kurstaki.

Two isolates of Bacillus thuringiensis subsp. kurstaki were examined which produced different levels of intracellular proteases. Although the crystals from both strains had comparable toxicity, one of the strains, LB1, had a strong polypeptide band at 68,000 molecular weight in the protein from the crystal; in the other, HD251, no such band was evident. When the intracellular proteases in both strains were measured, strain HD251 produced less than 10% of the proteolytic activity found in LB1. These proteases were primarily neutral metalloproteases, although low levels of other proteases were detected. In LB1, the synthesis of protease increased as the cells began to sporulate; however, in HD251, protease activity appeared much later in the sporulation cycle. The protease activity in strain LB1 was very high when the cells were making crystal toxin, whereas in HD251 reduced proteolytic activity was present during crystal toxin synthesis. The insecticidal toxin (molecular weight, 68,000) from both strains could be prepared by cleaving the protoxin (molecular weight, 135,000) with trypsin, followed by ion-exchange chromatography. The procedure described gave quantitative recovery of toxic activity, and approximately half of the total protein was recovered. Calculations show that these results correspond to stoichiometric conversion of protoxin to insecticidal toxin. The toxicities of whole crystals, soluble crystal protein, and purified toxin from both strains were comparable.     

Ultracentrifugal Analysis of Staphylococcal Alpha Toxin

Ultracentrifugal examination of staphylococcal alpha toxin at different stages of purification showed the presence of a major component having a sedimentation coefficient of 2.8S, present to the extent of more than 90% of the sample, and identifiable with active toxin. Several minor components having S(20,w) values of 11.5S, 8.5S, and 2.0S were detected. The 11.5S component presumably is identical with a toxin aggregate studied earlier and designated 12S; the 8.5S component appears to be delta toxin. A sedimentation equilibrium study of more highly purified material gave 32,700 as the best estimate of molecular weight of alpha toxin. Lowering the pH of the partially purified alpha toxin from 10.2 to 5.3 resulted in a small increase in S(20,w) of the 11.5S component and in the disappearance of the 8.5S component, whereas the S(20,w), molecular weight, and hemolytic activity of the toxin remained constant. Exposure of toxin to pH 3.5 irreversibly reduced the S(20,w) to 2.0S, the molecular weight to about 16,000, and caused irreversible inactivation. Raising the pH of acid-inactivated toxin and adding sodium dodecyl sulfate to 1% increased the S(20,w) to near its normal value (2.7S) but did not restore activity.     

Molecular Construction of Clostridium botulinum Progenitor Toxin

Molecular dissociation of purified type F progenitor toxin with an S20,W of 10.3 and a molecular weight of 235,000 into two components, toxic and atoxic, was demonstrated by ultracentrifugation, gel filtration, and diethylaminoethyl-Sephadex chromatography at pH 7.5. The ultracentrifugal analysis indicated that type F progenitor toxin dissociates into components of the same molecular size of 5.9S. The toxic component contained a toxicity of 2.5 times 10-8 50% lethal doses per mg of N. Much higher stability of progenitor toxin than that of derivative toxin, particularly at pH below 5, suggests that only progenitor toxin can act as an oral toxin.     

Targeted Silencing of Anthrax Toxin Receptors Protects against Anthrax Toxins

Anthrax spores can be aerosolized and dispersed as a bioweapon. Current postexposure treatments are inadequate at later stages of infection, when high levels of anthrax toxins are present. Anthrax toxins enter cells via two identified anthrax toxin receptors: tumor endothelial marker 8 (TEM8) and capillary morphogenesis protein 2 (CMG2). We hypothesized that host cells would be protected from anthrax toxins if anthrax toxin receptor expression was effectively silenced using RNA interference (RNAi) technology. Thus, anthrax toxin receptors in mouse and human macrophages were silenced using targeted siRNAs or blocked with specific antibody prior to challenge with anthrax lethal toxin. Viability assays were used to assess protection in macrophages treated with specific siRNA or antibody as compared with untreated cells. Silencing CMG2 using targeted siRNAs provided almost complete protection against anthrax lethal toxin-induced cytotoxicity and death in murine and human macrophages. The same results were obtained by prebinding cells with specific antibody prior to treatment with anthrax lethal toxin. In addition, TEM8-targeted siRNAs also offered significant protection against lethal toxin in human macrophage-like cells. Furthermore, silencing CMG2, TEM8, or both receptors in combination was also protective against MEK2 cleavage by lethal toxin or adenylyl cyclase activity by edema toxin in human kidney cells. Thus, anthrax toxin receptor-targeted RNAi has the potential to be developed as a life-saving, postexposure therapy against anthrax.     

Influence of a Ceratocystis ulmi Toxin on Water Relations of Elm (Ulmus americana)

Water-soluble glycopeptides isolated from cultures of Ceratocystis ulmi have been reported to be toxins involved in Dutch elm disease. The influence of the glycopeptides on the water relations of Ulmus americana seedlings was tested by placing cut stems in glycopeptide preparations. After 4 hours in 200 micrograms per milliliter toxin the stem conductance of the seedlings was reduced by 79% and the leaf water potential was reduced by 3 bars to that at which the seedlings wilted, the stomata closed, and transpiration decreased. Decrease in stem conductance as the mode of action of the toxin was further confirmed by forcing toxin through the stem and petiole of elm and measuring the effects on stem conductance. High molecular weight dextrans were found to mimic the action of toxin on stem and petiole conductance, and their ability to do so was found to be correlated with their molecular weight. As low as 4 micrograms of toxin or dextrans were found to measurably decrease the stem and petiole conductance of elms. Disruption of the water-conducting system of elms and other plants by small quantities of high molecular weight compounds may be a factor in diseases with wilting symptoms.     

Production of Escherichia coli Heat-labile Enterotoxin in Fermenter Dialysis Culture

Production of Escherichia coli heat-labile enterotoxin was investigated with one porcine and one human strain in three different media under different cultivation conditions. Cultivation in aerated fermenters at pH 7·0 yielded 10–20 times more enterotoxin/ml of culture fluid than cultivation in shake flasks. A trypton-yeast extract medium was optimal in fermenter cultures. Comparatively good yields of enterotoxin in fermenters were also obtained in a glucose-salts medium. Continuous feeding of glucose and salts during fermenter cultivation resulted in a lower production of enterotoxin/mg of bacterial cells. Since this decrease in specific yield could be reversed by using dialysis culture, it was concluded that inhibition of toxin formation was due to the accumulation of extracellular low molecular weight metabolites. The highest yield of enterotoxin in dialysis culture was 80 ED₅₀ ml⁻¹ (rabbit jejunal loop test) which is at least eight times more toxin than in ordinary fermenter culture and 80 times more toxin than in shake flask cultures.     

Tetanus Toxin and Antigenic Derivatives I. Purification of the Biologically Active Monomer

A procedure for the isolation of pure tetanus toxin in a lethal monomeric form was developed based on the extraction of whole cells and chromatographic techniques. A crude extract of toxin was obtained by hypertonic extraction of cells from a 72-hr culture of Clostridium tetani Massachusetts strain. The extract was precipitated with ammonium sulfate and further purified by sequential use of ion-exchange chromatography and gel filtration. The degree of purification obtained by the fractionation procedures was monitored by polyacrylamide gel electrophoresis. The pure toxin has an average specific activity of 150 x 10(6) mouse MLD per mg of N and 3,000 Lf per mg of N. Immunological purity was demonstrated by a single line on both immunoelectrophoresis and agar double diffusion. One band was obtained on polyacrylamide electrophoresis, as was a single symmetrical peak in the ultracentrifuge and on Sephadex G-100 chromatography. The pure protein has an absorbancy ratio (280/260 mmu) of 2.1 in phosphate buffer (pH 7.5).     

In vitro Reaction of Sunflower (Helianthus annuus L.) to the Toxin(s) Produced by Alternaria alternata, the Casual Agent of Brown Leaf Spot

A bioassay system was developed for studying the in vitro reaction of sunflower ( Helianthus annuus L. cv. 'Nanus') against the toxin produced by the virulent pathotype IMI 366417 (1) of the pathogenic fungus Alternaria alternata. Cotyledons from 2-week-old seedlings were cultured on a MS (Murashige and Skoog) medium supplemented with 0.3 μM NAA (α-napthylacetic acid) and 1.3 μM BA (6-benzyladenine). Exponentially growing calli were transferred to selective media containing toxin solutions at various concentrations. The fresh weight of the cultured calli was reduced as the toxin concentration increased, although the viability of the cells, expressed as callus dehydrogenase activity, increased. Selection for toxinresistant genotypes was attempted at 30% toxin concentration, which causes a 90% reduction in callus growth. After one month in culture, 18% of the calli demonstrated resistance to the toxin. However, no plants could be regenerated from those calli after transfer onto a MS medium supplemented with 5.4 μM NAA and 4.4 μM BA. The effect of the toxin purification method on toxin yield and biological activity, as well as its possible mode of cellular action are discussed. The results of these experiments may contribute to a better understanding of the disease mechanism and help establish an efficient selection method of resistant sunflower genotypes.     

Structure of tetanus toxin. II. Toxin binding to ganglioside.

The interaction between tetanus toxin and ganglioside containing 2 N-acetylneuraminic acid residues linked in sequence to one another has been investigated using a new method involving radioactively labeled ganglioside and tetanus toxin adsorbed to Sephadex matrix. Binding between the two components was demonstrated, and it was calculated that in the nanomolar concentration range, tetanus toxin becomes half-saturated at about 5 X 10(-8) M concentration of ganglioside. Removal of the ceramide portion from the ganglioside resulted in the complete loss of binding activity, whereas removal of the terminal N-acetylneuraminic acid residue from the intact ganglioside had no effect. Among the fragments derived from tetanus toxin (Helting, T. B., and Zwisler, O. (1977) J. Biol. Chem. 252, 187-193), only the heavy chain polypeptide exhibited a binding activity of the same order of magnitude as that observed for the native toxin. The light chain polypeptide showed no interaction with ganglioside and among the fragments derived from the toxin by digestion with papain, only Fragment C, at a high protein concentration, displayed marginal binding activity. Using monovalent antibodies directed against specific regions of the tetanus toxin molecule, it was demonstrated that antibodies directed against Fragment C uniquely interfere with the binding process. Anti-light chain serum was ineffective, as well as antitetanus toxoid serum previously absorbed with Fragment C. It is concluded that the binding site for ganglioside is located on the heavy chain portion of tetanus toxin, possibly in or near the region comprised by Fragment C.     

Homogeneity and Molecular Weight of Toxin of Clostridium botulinum Type B

Gerwing et al. described the isolation and purification from culture filtrates of the toxin of Clostridium botulinum type B and characterized it as a homogeneous protein of less than 10,000 molecular weight. Analysis by various methods of samples of this toxin obtained from Gerwing et al., and preparations produced by their methods in our laboratories, furnished convincing evidence that neither her preparation nor ours was homogeneous. The molecular weight of the toxic component isolated from either of the preparations was 100,000 or greater and resembled, in a number of respects, the alpha component isolated by us from the crystalline toxin of C. botulinum type A.     

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.     

Chemical Constitution of the Host-Specific Toxin of Helminthosporium carbonum

The host-specific toxin of Helminthosporium carbonum Ullstrup has a molecular formula approximating C(32)H(50)N(6)O(10). The compound has been crystallized and a crystalline hydrochloride derivative has been produced. The molecular weight, as determined by chromatography on Sephadex G-10, is slightly less than 700. The toxin appears to be a cyclic peptide, since, although it does not react with ninhydrin or dinitrofluorobenzene, it yields, on hydrolysis, compounds which react to these reagents. It is unstable in dilute acids, yielding ninhydrin-reacting products. Complete acid hydrolysis yields alanine, proline, and three other ninhydrin-reacting components. The infrared spectrum of the toxin reveals an ester band in addition to amide absorption. Its ultraviolet spectrum reveals the presence of unsaturation in the molecule. The toxin is relatively unstable and loses its specific toxicity. This loss of activity appears to be associated with loss of nitrogen and with decreased solubility in water.     

Isolation and Some Properties of the Enzyme That Transforms Eremofortin C to PR Toxin

PR toxin and eremofortin C are secondary metabolites of Penicillium roqueforti. The chemical structures of these two compounds are closely related to each other and differ only by an aldehyde and an alcohol group at the C-12 position. In an effort to better understand the biosynthesis of PR toxin, we discovered the enzyme of P. roqueforti that is responsible for the transformation of eremofortin C to PR toxin. The maximum activity of the enzyme in the culture medium was found to occur on day 13, which corresponded to the maximal production of PR toxin in the medium. The enzyme was isolated and purified from the culture medium and the mycelium of the fungus, respectively, through a procedure involving ammonium sulfate fractionation and DEAE-cellulose chromatography. The specific activity increased 20- and 8-fold, respectively, and the yield was 33.3 and 21.6%, respectively, for the enzyme from the medium and mycelium. The optimal pH for the enzyme reaction was ca. pH 5.6. The enzyme reaction was temperature dependent. The rates followed a linear time course when it catalyzed the transformation at 30°C and decayed with time when reacted at higher temperatures. At 100°C, the enzyme activity was completely lost. The K_m and V_max of the enzyme as determined at 30°C were 0.02 mM and 4.0 μmol/min per mg, respectively. The molecular weight of the enzyme was estimated by gel filtration on a high-pressure liquid chromatography I-250 protein column to be ca. 40,000.     

Identification of GTP-Binding Proteins by ADP-Ribosylation in the Presence of Cholera Toxin, Pertussis Toxin and Botulinum Toxin D in Plasma Membrane Isolated from Eggs and Embryos of Sea Urchin

In plasma membrane fraction isolated from eggs and embryos of sea urchin, ³²P-labeled proteins were found on the fluorographs of SDS-polyacrylamide gel electrophoresis, performed after an exposure of the fraction to [adenylate-³²P] nicotinamide adenine dinucleotide in the presence of cholera toxin, pertussis toxin or botulinum toxin D. The molecular weights of proteins, thus ADP-ribosylated in the presence of cholera toxin and pertussis toxin are 45 and 39 K, which correspond to Gs and Gi or Go, respectively. Protein with the molecular weight of 24 K, labeled in the presence of botulinum toxin D, corresponds to small molecular weight G-protein. The labeling intensity of 45 K protein, probably proportional to its amount, became high at the blastula stage. The labeling intensity of 39 K protein was hardly altered up to the blastula stage. The labeling intensity of 24 K protein increased after fertilization and further increase occurred at the blastula stage. At the gastrula stage, the labeling intensities of these proteins became somewhat lower than at the blastula stage. Transmembrane signaling system, in which these G-proteins are involved, is probably altered in its function during early development.     

Activity of Diphtheria Toxin II. Early Events in the Intoxication of HeLa Cells

The initial steps in the interaction of diphtheria toxin with HeLa cells were studied. It was demonstrated that lethal doses of toxin are rapidly adsorbed to the cell. The kinetics of uptake, as measured by lethality, indicated that a single toxin molecule is able to cause cell death. Studies on the effect of pH on intoxication showed that adsorption of toxin occurred over a wide pH range but was partially inhibited at high pH values. Experiments to determine the influence of the ionic environment on intoxication indicated that adsorption of toxin did not take place in the absence of salts and was partially inhibited in the presence of a polyanion. The evidence indicates that the initial binding of toxin to the cell is electrostatic in nature, involving positively charged surface groups. Attempts to demonstrate specific receptors for the attachment of toxin to cells were unsuccessful, suggesting that toxin adsorption may be a nonspecific process. The effect of energy inhibitors on intoxication was examined. Sodium fluoride, an inhibitor of glycolysis, almost completely prevented intoxication in HeLa cells, whereas inhibitors of respiration and oxidative phosphorylation had no effect. Sodium fluoride did not prevent adsorption of toxin but appeared to inhibit a later step in the intoxication process, perhaps the transport of toxin to subsurface or intracellular levels.     

Filipin-dependent Inhibition of Cholera Toxin: Evidence for Toxin Internalization and Activation through Caveolae-like Domains

The mechanism by which cholera toxin (CT) is internalized from the plasma membrane before its intracellular reduction and subsequent activation of adenylyl cyclase is not well understood. Ganglioside G_M1, the receptor for CT, is predominantly clustered in detergent-insoluble glycolipid rafts and in caveolae, noncoated, cholesterol-rich invaginations on the plasma membrane. In this study, we used filipin, a sterol-binding agent that disrupts caveolae and caveolae-like structures, to explore their role in the internalization and activation of CT in CaCo-2 human intestinal epithelial cells. When toxin internalization was quantified, only 33% of surface-bound toxin was internalized by filipin-treated cells within 1 h compared with 79% in untreated cells. However, CT activation as determined by its reduction to form the A₁ peptide and CT activity as measured by cyclic AMP accumulation were inhibited in filipin-treated cells. Another sterol-binding agent, 2-hydroxy-β-cyclodextrin, gave comparable results. The cationic amphiphilic drug chlorpromazine, an inhibitor of clathrin-dependent, receptor-mediated endocytosis, however, affected neither CT internalization, activation, nor activity in contrast to its inhibitory effects on diphtheria toxin cytotoxicity. As filipin did not inhibit the latter, the two drugs appeared to distinguish between caveolae- and coated pit–mediated processes. In addition to its effects in CaCo-2 cells that express low levels of caveolin, filipin also inhibited CT activity in human epidermoid carcinoma A431 and Jurkat T lymphoma cells that are, respectively, rich in or lack caveolin. Thus, filipin inhibition correlated more closely with alterations in the biochemical characteristics of CT-bound membranes due to the interactions of filipin with cholesterol rather than with the expressed levels of caveolin and caveolar structure. Our results indicated that the internalization and activation of CT was dependent on and mediated through cholesterol- and glycolipid-rich microdomains at the plasma membrane rather than through a specific morphological structure and that these glycolipid microdomains have the necessary components required to mediate endocytosis.     

Structure of tetanus toxin. Demonstration and separation of a specific enzyme converting intracellular tetanus toxin to the extracellular form.

Protease activity has been demonstrated in culture supernatants of Clostridium tetani at various stages of fermentation. Gel chromatography of the concentrated filtrates revealed the presence of three enzymatically active fractions eluting at separate positions off the column. The smallest protease was found to "nick" the single chain intracellular tetanus toxin, producing the extracellular, two-chain structure of the molecule. As little as 3 ng of active protease were sufficient to cleave 50 microgram of intracellular tetanus toxin, suggesting that this enzyme is responsible for the observed structural change of the toxin molecule during its release into the culture medium. By comparison, the second protease, eluting at an intermediate position, exhibited only marginal activity towards intracellular toxin. The third, largest, enzyme was not active under the conditions of the assay. However, the latter protease effectively hydrolyzed low molecular weight histidyl peptides, and it is concluded that this enzyme is similar to the one described by Miller, P.A. Gray, C.T., and Eaton, M.D. (1960) J. Bacteriol. 79, 95-102. The properties of the partially purified enzymes, including their differential behavior towards a number of protease inhibitors, are reported.