Amino acid sequence of neurotoxin I from Centruroides sculpturatus Ewing

The further characterization of toxin I from venom of the scorpion Centruroides sculpturatus Ewing (region, Southwestern United States) is reported. Toxin I is a single polypeptide chain of 64 amino acid residues crosslinked by four disulfide bridges. The complete amino acid sequence of toxin I was deduced from the sequence of its tryptic peptides and overlaps provided by its chymotryptic peptides. Toxin I has an amino terminal lysyl residue and a carboxyl terminal threonyl residue.The amino acid sequences of toxin I and neurotoxic variants 1, 2, and 3, likewise isolated from C. sculpturatus venom, differ at 26 positions.The sequences of toxin I from C. sculpturatus and toxins I and II from the North African scorpion, Androctonus australis Hector, are also compared.     

Plant pathotoxins from Alternaria citri: The minor ACRL toxins

Five host-specific pathotoxins, ACRL toxins II, III, III′, IV and IV′, were isolated from the culture broth of Alternaria citri, the fungus causing brown spot disease of rough lemon. These toxins are related structurally to the major ACRL toxin, toxin I, and to its derivative compound A. Chemical and spectral studies indicated that the ACRL minor toxins were a group of analogous compounds of different chain lengths all of which have a α-pyrone group, in contrast to the dihydro-α-pyrone group in toxin I. Toxin II showed a very low biological activity (ED₅₀ greater than 10 μg/ml) whereas the other minor toxins had slightly higher activities ranging from 1 to 10 μg/ml. The dihydropyrone group in ACRL toxin I was correlated with high biological activity (ED₅₀ = 18–30 ng/ml).     

The Toxins of Helminthosporium maydis (Race T) : A Colorimetric Determination of the Toxins, Their Appearance in Culture and in Infected Plants

Host-specific toxins produced by Helminthosporium maydis, race T, are measured quantitatively by a chemical assay procedure involving reaction of the toxins with a sulfuric acidacetic anhydride reagent and measurement of the absorbance of the product at 330 nm. The assay was shown to measure total toxin concentrations after only limited fractionation of the culture medium. Using the assay it was possible to show that the highest amount of toxin per gram of fungus mycelium occurs early in the growth cycle of H. maydis. Toxins I, II, and V are the predominant toxins at these early times both in culture and in infected corn and wheat varieties. Some chromatographic and spectral properties of toxin V, a previously unreported toxin, are described. Since toxin V appears in culture prior to toxins I, II, III and IV, a precursor-product relationship can be suggested.     

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.     

Common features of the NAD-binding and catalytic site of ADP-ribosylating toxins

Computer analysis of the three-dimensional structure of ADP-ribosylating toxins showed that in all toxins the NAD-binding site is located in a cavity. This cavity consists of 16 contiguous amino acids that form an a-helix bent over β-strand. The tertiary folding of this structure is strictly conserved despite the differences in the amino acid sequence. Catalysis is supported by two spatially conserved amino acids, each flanking the NAD-binding site. These are: a glutamic acid that is conserved in all toxins, and a nucleophillc residue, which is a histidine in the diphtheria toxin and Pseudomonas exotoxin A, and an arginine in the cholera toxin, the Escherichia coli heat-labile enterotoxins, the pertussis toxin and the mosquitocidal toxin of Bacillus sphaericus. The latter group of toxins presents an additional histidine that appears important for catalysis. This structure suggests a general mechanism of ADP-ribosylation evolved to work on different target proteins.     

Isolation and Biological Activities of Four Selective Toxins from Helminthosporium carbonum

A new and simpler purification procedure was developed for host selective toxins from Helminthosporium carbonum race 1. Four analogs or forms of toxin with the same selectivity as the fungus were isolated from culture fluids; two forms (HC toxins III and IV) have not been reported by other workers. Crystals of the major form of toxin (HC toxin I) were recovered in high yields (>80 milligrams per liter of culture fluid) without the use of high performance or preparative thin layer liquid chromatography. ED₅₀ values, based on inhibition of root growth of susceptible seedlings, for HC toxins I, II, III, and IV were 0.2, 0.4, 2.0, and 20 micrograms per milliliter, respectively. The specific activity of crystalline HC toxin I matched the most active preparation reported previously; the preparation of HC toxin II was more active than that reported previously. Resistant seedlings tolerated 100-fold higher concentrations of each form of toxin than did susceptible seedlings. Hydrolysis of the epoxide group of HC toxin I to a diol destroyed toxicity to susceptible and resistant seedlings. The data suggest that the same mechanisms are affected in resistant and susceptible plants.     

New weak toxins from the cobra venom

A protein with M 7485 Da containing five disulfide bonds was isolated from the venom of cobra Naja oxiana using various types of liquid chromatography. The complete amino acid sequence of the protein was determined by protein chemistry methods, which permitted us to assign it to the group of weak toxins. This is the first weak toxin isolated from the venom of N. oxiana. In a similar way, two new toxins with M 7628 and 7559 Da, which fall into the range of weak toxin masses, were isolated from the venom of the cobra N. kaouthia. The characterization of these proteins using Edman degradation and MALDI mass spectrometry has shown that one of these proteins is a novel weak toxin, and the other is the known weak toxin WTX with an oxidized methionine residue in position 9. Such a modification was detected in weak toxins for the first time. A study of the biological activity of the toxin from N. oxiana showed that, like other weak toxins, it can be bound by α7 and muscle-type nicotinic acetylcholine receptors.     

Isolation and Partial Characterization of Four Host-specific Toxins of Helminthosporium maydis (Race T)

Helminthosporium maydis, race T, produces four host-specific toxins in culture. These have been designated toxins I, II, III, and IV. A method for isolation and purification of the four toxins is presented, and the criteria of purity of preparations of toxins I, II, and III are given. Toxins I and II are chemically similar and yield the same molecular ion when subjected to mass spectrometry, while toxin III appears to be a glycoside of a compound related to toxins I and II. Toxins I, II, and III can be biologically derived from ¹⁴C-mevalonic acid or ¹⁴C-acetate, permitting preparation of ¹⁴C-labeled toxins. Some chemical, spectral, and chromatographic properties of toxins I, II, and III are presented, and these data are discussed relative to the possible structure of the three compounds. In addition, four host-specific toxins have been isolated from corn infected with H. maydis (race T). These toxins are recovered in the same fractions as toxins I, II, III, and IV using the isolation procedure described here. Three of the toxins isolated from infected corn cannot be distinguished from toxins I, II, and III on the basis of infrared spectra or chromatographic mobility.     

Primary Structure of a Short Toxin from the Venom of a Vietnamese Scorpion (Buthus sp.)

The complete amino acid sequence of an important toxin (toxin 14) from the venom of a Vietnamese scorpion (Buthus occitanus sp.) has been determined, which includes 35 amino acid residues and three disulfide bridges (molecular weight, 3843 Da). The comparison of the sequence with known sequences of short scorpion toxins led to the conclusion that toxin 14 belongs to a novel group of toxins affecting the excitability of myelinated nerves.     

Inactivation of the Pore-Forming Toxin Sticholysin I by Peroxynitrite: Protection by Cys Groups Incorporated in the Toxin

Sea anemones synthesize a variety of toxic peptides and proteins of biological interest. The Caribbean Sea anemone Stichodactyla helianthus, produces two pore-forming toxins, Sticholysin I (St I) and Stichloysin II (St II), with the ability to form oligomeric pores in cell and lipid bilayers characteristically lacking cysteine in their amino acid sequences. Recently, two mutants of a recombinant variant of Sticholysin I (rSt I) have been obtained with a Cys residue in functionally relevant regions for the pore-forming activity of the toxin: r St I F15C (in the amino terminal sequence) and r St I R52C (in the binding site). Aiming at characterizing the effects of oxidants in toxins devoid (r St I) or containing –SH moieties (r St I F15C and r St I R52C), we measured their hemolytic activity and pore forming capacity prior and after their incubation with peroxynitrite (ONOO^?). At low ONOO^?/Toxin ratios, nearly 0.8 Trp groups are modified by each added peroxynitrite molecule, and the toxin activity is reduced in ca. 20 %. On the other hand, in –SH bearing mutants only 0.5 Trp groups are modified by each peroxynitrite molecule and the toxin activity is only reduced in 10 %. The results indicated that Cys is the initial target of the oxidative damage and that Trp residues in Cys-containing toxins were less damaged than those in r St I. This relative protection of Trp groups correlates with a smaller loss of hemolytic activity and permeabilization ability in liposomes and emphasizes the relevance of Trp groups in the pore forming capacity of the toxins.     

Glucosylation and Other Biotransformations of T-2 Toxin by Yeasts of the Trichomonascus Clade

Trichothecenes are sesquiterpenoid toxins produced by Fusarium species. Since these mycotoxins are very stable, there is interest in microbial transformations that can remove toxins from contaminated grain or cereal products. Twenty-three yeast species assigned to the Trichomonascus clade (Saccharomycotina, Ascomycota), including four Trichomonascus species and 19 anamorphic species presently classified in Blastobotrys, were tested for their ability to convert the trichothecene T-2 toxin to less-toxic products. These species gave three types of biotransformations: acetylation to 3-acetyl T-2 toxin, glycosylation to T-2 toxin 3-glucoside, and removal of the isovaleryl group to form neosolaniol. Some species gave more than one type of biotransformation. Three Blastobotrys species converted T-2 toxin into T-2 toxin 3-glucoside, a compound that has been identified as a masked mycotoxin in Fusarium-infected grain. This is the first report of a microbial whole-cell method for producing trichothecene glycosides, and the potential large-scale availability of T-2 toxin 3-glucoside will facilitate toxicity testing and development of methods for detection of this compound in agricultural and other products.     

Display of Biologically Functional Insecticidal Toxin on the Surface of λ Phage

The successful use of Bacillus thuringiensis insecticidal toxins to control agricultural pests could be undermined by the evolution of insect resistance. Under selection pressure in the laboratory, a number of insects have gained resistance to the toxins, and several cases of resistance in the diamondback moth have been reported from the field. The use of protein engineering to develop novel toxins active against resistant insects could offer a solution to this problem. The display of proteins on the surface of phages has been shown to be a powerful technology to search for proteins with new characteristics from combinatorial libraries. However, this potential of phage display to develop Cry toxins with new binding properties and new target specificities has hitherto not been realized because of the failure of displayed Cry toxins to bind their natural receptors. In this work we describe the construction of a display system in which the Cry1Ac toxin is fused to the amino terminus of the capsid protein D of bacteriophage lambda. The resultant phage was viable and infectious, and the displayed toxin interacted successfully with its natural receptor.     

The Species-Specific Acquisition and Diversification of a K1-like Family of Killer Toxins in Budding Yeasts of the Saccharomycotina

Killer toxins are extracellular antifungal proteins that are produced by a wide variety of fungi, including Saccharomyces yeasts. Although many Saccharomyces killer toxins have been previously identified, their evolutionary origins remain uncertain given that many of these genes have been mobilized by double-stranded RNA (dsRNA) viruses. A survey of yeasts from the Saccharomyces genus has identified a novel killer toxin with a unique spectrum of activity produced by Saccharomyces paradoxus. The expression of this killer toxin is associated with the presence of a dsRNA totivirus and a satellite dsRNA. Genetic sequencing of the satellite dsRNA confirmed that it encodes a killer toxin with homology to the canonical ionophoric K1 toxin from Saccharomyces cerevisiae and has been named K1-like (K1L). Genomic homologs of K1L were identified in six non-Saccharomyces yeast species of the Saccharomycotina subphylum, predominantly in subtelomeric regions of the genome. When ectopically expressed in S. cerevisiae from cloned cDNAs, both K1L and its homologs can inhibit the growth of competing yeast species, confirming the discovery of a family of biologically active K1-like killer toxins. The sporadic distribution of these genes supports their acquisition by horizontal gene transfer followed by diversification. The phylogenetic relationship between K1L and its genomic homologs suggests a common ancestry and gene flow via dsRNAs and DNAs across taxonomic divisions. This appears to enable the acquisition of a diverse arsenal of killer toxins by different yeast species for potential use in niche competition.     

Aggregation of Bacillus thuringiensis Cry1A Toxins upon Binding to Target Insect Larval Midgut Vesicles

During sporulation, Bacillus thuringiensis produces crystalline inclusions comprised of a mixture of δ-endotoxins. Following ingestion by insect larvae, these inclusion proteins are solubilized, and the protoxins are converted to toxins. These bind specifically to receptors on the surfaces of midgut apical cells and are then incorporated into the membrane to form ion channels. The steps required for toxin insertion into the membrane and possible oligomerization to form a channel have been examined. When bound to vesicles from the midguts of Manduca sexta larvae, the Cry1Ac toxin was largely resistant to digestion with protease K. Only about 60 amino acids were removed from the Cry1Ac amino terminus, which included primarily helix α1. Following incubation of the Cry1Ab or Cry1Ac toxins with vesicles, the preparations were solubilized by relatively mild conditions, and the toxin antigens were analyzed by immunoblotting. In both cases, most of the toxin formed a large, antigenic aggregate of ca. 200 kDa. These toxin aggregates did not include the toxin receptor aminopeptidase N, but interactions with other vesicle components were not excluded. No oligomerization occurred when inactive toxins with mutations in amphipathic helices (α5) and known to insert into the membrane were tested. Active toxins with other mutations in this helix did form oligomers. There was one exception; a very active helix α5 mutant toxin bound very well to membranes, but no oligomers were detected. Toxins with mutations in the loop connecting helices α2 and α3, which affected the irreversible binding to vesicles, also did not oligomerize. There was a greater extent of oligomerization of the Cry1Ac toxin with vesicles from the Heliothis virescens midgut than with those from the M. sexta midgut, which correlated with observed differences in toxicity. Tight binding of virtually the entire toxin molecule to the membrane and the subsequent oligomerization are both important steps in toxicity.     

Amino acid sequence of toxin VII,A β-toxin from the venom of the scorpton Tityus serrulatus

The sequence of the 61 amino acids of toxin VII, a β-toxin from the venom of the South American scorpion Tityus serrulatus, has been determined by automatic sequencing of the reduced and S-[¹⁴C] car?ymethylated protein and of tryptic peptides obtained before or after citraconylation of this protein. This toxin, the most active β-toxin from this venom, is the first Tityus toxin to be fully sequenced. The results clearly show that toxin VII belongs to the structural group of scorpion toxins originating from Central and North America.     

Enzymatic transformation of PSP toxins in the littleneck clam (Protothacastaminea)

Stemming from investigations into the relationship between toxins produced by Gonyaulax sp. and accumulated in shellfish, we wish to report enzymatic transformations of the PSP toxins to decarbamoyl derivatives in the littleneck clam (Protothaca staminea). No toxin transformations were observed in either mussels (Mytilus edulis) or in butter clams (Saxidomus giganteus). In addition, littleneck clam samples from the natural environment contained predominantly the decarbamoyl derivatives, while other shellfish species collected from the same vicinity contained the previously reported PSP toxins.     

Permeation and metabolism of Alternaria mycotoxins with perylene quinone structure in cultured Caco-2 cells

The absorption of four Alternaria toxins with perylene quinone structures, i.e. altertoxin (ATX) I and II, alteichin (ALTCH) and stemphyltoxin (STTX) III, has been determined in the Caco-2 cell Transwell system, which represents a widely accepted in vitro model for human intestinal absorption and metabolism. The cells were incubated with the four mycotoxins on the apical side, and the concentration of the toxins in the incubation media of both chambers and in the cell lysate were determined by liquid chromatography coupled with diode array detection and mass spectrometry (LC-DAD-MS) analysis. ATX I and ALTCH were not metabolised in Caco-2 cells, but ATX II and STTX III were partly biotransformed by reductive de-epoxidation to the metabolites ATX I and ALTCH, respectively. Based on the apparent permeability coefficients (P_app), the following ranking order for the permeation into the basolateral compartment was obtained: ATX I > ALTCH >> ATX II > STTX III. Total recovery of the four toxins decreased in the same order. It is assumed that the losses of STTX III, ATX II and ALTCH in Caco-2 cells are caused by covalent binding to cell components due to the epoxide group and/or the α,β-unsaturated carbonyl group present in these toxins. We conclude from this study that ATX I and ALTCH are well absorbed from the intestinal lumen into the portal blood in vivo. For ATX II and STTX III, intestinal absorption of the parent toxins is very low, but these toxins are partly metabolised to ATX I and ALTCH, respectively, in the intestinal epithelium and absorbed as such.     

The Mechanisms Underlying α-Amanitin Resistance in Drosophila melanogaster: A Microarray Analysis

The rapid evolution of toxin resistance in animals has important consequences for the ecology of species and our economy. Pesticide resistance in insects has been a subject of intensive study; however, very little is known about how Drosophila species became resistant to natural toxins with ecological relevance, such as α-amanitin that is produced in deadly poisonous mushrooms. Here we performed a microarray study to elucidate the genes, chromosomal loci, molecular functions, biological processes, and cellular components that contribute to the α-amanitin resistance phenotype in Drosophila melanogaster. We suggest that toxin entry blockage through the cuticle, phase I and II detoxification, sequestration in lipid particles, and proteolytic cleavage of α-amanitin contribute in concert to this quantitative trait. We speculate that the resistance to mushroom toxins in D. melanogaster and perhaps in mycophagous Drosophila species has evolved as cross-resistance to pesticides, other xenobiotic substances, or environmental stress factors.