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Scorpions toxins
Abstract
Scorpions use a cocktail of toxins to immobilize their prey. Their venoms constitute a complex mixure of polypeptides exhibiting different pharmacological activities. These polypeptides are small (between 30 and 70 amino acids long), basic and highly reticulated (3 or 4 disulfide bridges). They bind with very high affinities to specific targets, which are different ionic channels of excitable cells. Thus, they constitute usefull tools for the neurobiologist. 1)The a long << chain toxins >> (60-70 amino acids residues cross-linked by 3 disulfide-bridges) affect exclusively voltage-dependent Na; channels of excitable cells from mammals and insects; 2) The << short chain toxins >> (30-40 amino acids residues cross-linked by 3 or 4 disulfide-bridges) block several types of K+ channels in different cells. At the structural level, scorpion toxins show a dense core of secondary elements, 2 1/2 turns of an alpha-helix, and a short segment of anti-parallel beta-sheet, already found in all known structures of scorpion toxins, irrespective of their size. sequence and function. From cDNA libraries, full-lengh cDNAs encoding precursors of these toxins have been isolated and could be used in heterologous expression systems, in order to produce recombinant toxins. They will provide a template for the design of new biopesticide agents, able to mimic the interactive surface of the toxins.
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Recombinant nuclear polyhedrosis viruses (NPVs) expressing insect-selective toxins, hormones, or enzymes could enhance their insecticidal properties. We have constructed a recombinant, polyhedrin-positive Autographa californica NPV (AcNPV) that is orally infectious and expresses an insect-selective toxin (AaIT), isolated from the scorpion Androctonus australis, under the control of the p10 promoter. Bioassays with the recombinant baculovirus on 2nd instar larvae of Heliothis virescens demonstrated a significant decrease in the time to kill (LT50 88.0 hours) compared to wild-type AcNPV (LT50 125 hours). Production of AaIT was confirmed by western blot analysis of larval hemolymph from infected H. virescens, and bioassays with larvae of Sarcophaga falculata.
Two insect selective toxins were purified by gel-permeation and ion-exchange chromatographies from the venom of the scorpion, Leiurus quinquestriatus quinquestriatus, and their chemical and pharmacological properties were studied. The first toxin (LqqIT1) induces a fast excitatory contraction paralysis of fly larvae and is about 40 times more toxic than the crude venom. It is a polypeptide composed of 71 amino acids, including 8 half-cystines and devoid of methionine and tryptophan, with an estimated molecular weight of 8189 and a pI value of 8.5. The second toxin (LqqIT2) induces a slow depressant, flaccid paralysis of fly larvae. It is composed of 72 amino acids, including 8 half-cystines, is devoid of proline methionine and histidine, and has an estimated molecular weight of 7990 and a pI value of 8.3. The contrasting symptomatology of these toxins is interpreted in terms of their effects on an isolated axonal preparation of the cockroach in current and voltage clamp conditions. LqqIT1 (0.5-4 microM) induced repetitive firing of the axon which was attributable to two changes in the sodium conductance, a small increase in the peak conductance and a slowing of its turning off. LqqIT2 (1-8 microM) caused a blockage of the evoked action potentials, attributable to both a strong depolarization of the axonal membrane and a progressive suppression of the sodium current. Neither toxin affected potassium conductance. The two toxins differ mainly in their opposite effects on the activatable sodium permeability. In binding assays to a preparation of insect synaptosomal membrane vesicles, the two toxins were shown to competitively displace the radioiodinated excitatory insect toxin derived from the venom of the scorpion, Androctonus australis [( 125I]AaIT), which strongly resembles, in its chemistry and action, the LqqIT1 toxin. The present two toxins have demonstrated a strong affinity closely resembling the AaIT, with KD values of 0.4, 1.9, and 1.0 nM for LqqIT1, LqqIT2, and AaIT, respectively. These data suggest the possibility that the excitatory and depressant insect toxins share a common binding site associated with sodium channels in insect neuronal membranes.
Charybdotoxin (CTX) is a peptide of known structure that inhibits Shaker K+ channels by a pore-blocking mechanism. Point mutagenesis of all 30 solvent-exposed residues identified the part of the CTX molecular surface making contact with the receptor in the K+ channel. All close-contact residues are clustered in a well-defined interaction surface; the shape of this surface implies that the outer opening of the Shaker channel conduction pore abruptly widens to a 25 x 35 A plateau. A mutagenic scan of the S5-S6 linker sequence of the Shaker K+ channel identified those channel residues influencing CTX binding affinity. The Shaker residues making the strongest contribution to toxin binding are located close to the pore-lining sequence, and more distant residues on both sides of this region influence CTX binding weakly, probably by an electrostatic mechanism. Complementary mutagenesis of both CTX and Shaker suggests that Shaker-F425 contacts a specific area near T8 and T9 on the CTX molecular surface. This contact point constrains Shaker-F425 to be located at a 20 A radial distance from the pore axis and 10-15 A above the "floor" of the CTX receptor.
The paper describes isolation of neurotoxins of the polypeptide nature (from snake, bee, and scorpion venoms), establishment of their primary and spatial structures, chemical modification of native toxins as well as their total synthesis. It includes data on native and modified toxins used in the study of corresponding receptors.
The venom of the scorpion Androctonus mauretanicus mauretanicus contains a toxin, P05, which is structurally and functionally similar to scorpion leiurotoxin I (87% sequence identity), a blocker of the apamin-sensitive Ca2+-activated K+ channels. It is a 31-residue polypeptide cross-linked by three disulfide bridges. A C-terminal carboxyl-amidated analog of P05 (sP05-NH2) was chemically synthesized by the solid-phase technique and fully characterized. Toxicity assays in vivo established that sP05-NH2, like native P05, is a potent and lethal neurotoxic agent in mice (LD50 of 20 ng per mouse). Pharmacological assays in vitro however showed that, unlike P05 which has a binding affinity of 2 x 10(-11) M, sP05-NH2 apparently binds irreversibly to the apamin receptor. Iodination at the C-terminal His gave diiodo-sP05-NH2, which had a binding affinity similar to that of native P05. The disulfide bridge pairings were chemically determined for sP05-NH2 and thereby deduced for P05 and leiurotoxin 1: linkages were between Cys3 and Cys21, Cys8 and Cys26, and Cys12 and Cys28. Molecular dynamics refinement of P05 also using data from leiurotoxin I suggests that P05 is mainly composed of a double-stranded, antiparallel beta-sheet (from Leu18 to Val29) linked to an alpha-helix (from Arg6 to Gly16) by two disulfides (Cys8-Cys26 and Cys12-Cys28) and to an extended fragment (from Thr1 to Leu5) by the third disulfide (Cys3-Cys21). In agreement with the model, circular dichroism analysis of sP05-NH2 showed that the toxin structure is highly rigid. A common Arg-Arg-Cys-Gln sequence was identified in the helical region of both P05 and apamin. Two Arg-substituted analogs of sP05-NH2 ([Lys6Lys7] sP05-NH2 and [Leu6,Leu7] sP05-NH2) were synthesized and tested for bioactivity. The results indicate that, as for apamin, Arg residues of the motif are required in the binding and expression of the leiurotoxin I/apamin-like biological properties of P05.
The alpha neurotoxin LqhαIT is toxic to both insects and mammals but exhibits a bioactivity ratio favoring insects (insect/mammal 2). With the objective of increasing this ratio by genetic manipulation of the amino acid sequence, a cDNA clone encoding LqhαIT was used to produce recombinant variants of the toxin in a high efficiency bacterial expression system. The unmodified recombinant toxin, isolated from inclusion bodies and renatured in vitro, exhibited chemical and biological properties indistinguishable from those of the authentic native toxin. Alteration of the toxin by site-directed mutagenesis led to a substantial reduction in anti-mammalian toxicity (mouse LD50 reduced 6.4-fold) but only a slight reduction (×1.5) in the insect ED50 value for paralysis. The reduction in anti-mammalian toxicity was correlated with a 2-fold reduction of its potency for slowing of sodium channel inactivation in mammalian neurons, while no change in mutant toxin binding affinity to insect neuronal receptors was registered. These results demonstrate for the first time expression of a recombinant sodium channel neurotoxin in Escherichia coli and the use of site-directed mutagenesis to improve phylogenetic selectivity. This recombinant approach provides a promising strategy for optimizing the selective toxicity of peptide neurotoxins.
Using column chromatography, a protein, selectively toxic to isopods (Crustacea) has been isolated and purified from the venom of the scorpion Androctonus australis. The final product is about 250 times more toxic than the crude venom. It is a low molecular weight (70 amino acids) basic protein, devoid of methionine, histidine, and phenylalanine, rich in arginine and supposed to contain five disulfide bridges.The amino acid composition of this toxin is compared to those specifically active to mammals as well as to insects derived from the same venom, and the significance of such selectivity in action is discussed.
Abstract The effects of neonatal gonadectomy of male, and testosterone propionate treatment of female rat pups on levels of monoamines and metabolites in the cerebral cortex were assessed using high-performance liquid chromatography with electrochemical detection. In Experiment 1, pups were killed at 0, 4, 10 and 21 days of age and the anterior and posterior portions of cortex in each hemisphere were removed. At 21 days of age the levels of dopamine in anterior cortex were higher in males and testosterone propionate-treated females than in females and gonadectomized males. However, dopaminergic activity developed earlier in females than in males and the gonadal hormone manipulations shifted the pattern of development to that of the other sex. In Experiment 2, the effects of these same gonadal hormone manipulations on the uptake, metabolism and storage capacity of catecholamine neurons in the cingulate, agranular insular, parietal and occipital cortex were estimated at 4 and 10 days of age by considering the difference between measured catecholamines in animals pretreated with vehicle or 2.5 mg/kg reserpine and then given 100 mg/kg L-DOPA. Again, the data indicated earlier development of catecholamine neurons in females, especially in the agranular insular cortex. Dopamine was found to account for group differences; for when dopamine levels alone were considered it was found that, at 4 days of age, females had the highest levels in every area with the exception of the occipital cortex where gonadectomized males had equally high levels. These data suggest a mechanism that might account for sex differences in the development of specific cortical regions.
A cDNA encoding the main Tityus serrulatus beta-neurotoxin was isolated from a venom gland cDNA library by using an oligonucleotide probe. The amino acid sequence deduced from the cDNA nucleotide sequence indicated that the toxin is the processed product of a precursor containing: (i) a signal peptide of 20 residues; (ii) the amino acid sequence of the mature toxin; and (iii) an extra Gly-Lys-Lys tail at the C-terminal end before the termination codon. Thus, in addition to the removal of the signal peptide by a signal peptidase, the generation of the mature toxin requires both a post-translational cleavage by a carboxypeptidase specific for basic residues and the action of an alpha-amidating enzyme. These results also show that the biosynthetic pathway for beta-toxins of 'New World' scorpion venoms is similar to that already described for alpha-toxins of 'Old World' scorpion venoms.
The scorpion Androctonus australis has a peptide (AaIT) which selectively targets the insect sodium channel. This mode of action is similar to that of many widely used chemical insecticides. When Bombyx mori larvae were infected with a recombinant baculovirus carrying a synthetic AaIT gene, the expressed protein was secreted into the hemolymph and caused symptoms consistent with sodium channel blocking, including tremors and feeding cessation at 40 hr p.i. followed by paralysis and death by 60 hr p.i. Larvae infected with control virus died by 96 hr p.i. These results indicate that foreign genes can be used in recombinant baculoviruses to reduce insect feeding damage and increase the rate of insect kill.
Sequence-specific nuclear magnetic resonance assignments for the polypeptide backbone and for most of the amino acid side-chain protons, as well as the general folding of AaH IT, are described. AaH IT is a neurotoxin purified from the venom of the scorpion Androctonus australis Hector and is specifically active on the insect nervous system. The secondary structure and the hydrogen-bonding patterns in the regular secondary structure elements are deduced from nuclear Overhauser effects and the sequence locations of the slowly exchanging amide protons. The backbone folding is determined by distance geometry calculations with the DISMAN program. The regular secondary structure includes two and a half turns of alpha-helix running from residues 21 to 30 and a three-stranded antiparallel beta-sheet including peptides 3-5, 34-38, and 41-46. Two tight turns are present, one connecting the end of the alpha-helix to an external strand of the beta-sheet, i.e., turn 31-34, and another connecting this same strand to the central one, i.e., turn 38-41. These structure elements are very similar to the secondary structure reported in single crystals for either variant 3 from the scorpion Centruroides sculpturatus Ewing (CsE V3) or toxin II from the scorpion A. australis Hector (AaH II). The differences in the specificity of these related proteins, which are able to discriminate between mammalian and insect voltage-dependent sodium channels of excitable tissues, are most probably brought about by the position of the C-terminal peptide with regard to a hydrophobic surface common to all scorpion toxins examined thus far. This surface is made of an aromatic cluster that is surrounded by long hydrophobic side-chain residues, as well as the loops protruding out of it. Thus, the interaction of a given scorpion toxin with its receptor might well be governed by the presence of this solvent-exposed hydrophobic surface, whereas adjacent areas modulate the specificity of the interaction.
Many venom toxins interfere with ion channel function. Toxins, as specific, high affinity ligands, have played an important part in purifying and characterizing many ion channel proteins. Our knowledge of potassium ion channel structure is meager because until recently, no specific potassium channel toxins were known, or identified as such. This review summarizes the sudden explosion of research on potassium channel toxins that has occurred in recent years. Toxins are discussed in terms of their structure, physiological and pharmacological properties, and the characterization of toxin binding sites on different subtypes of potassium ion channels.
A new toxin, Lqh alpha IT, which caused a unique mode of paralysis of blowfly larvae, was purified from the venom of the scorpion Leiurus quinquestriatus hebraeus, and its structural and pharmacological properties were compared to those of three other groups of neurotoxins found in Buthinae scorpion venoms. Like the excitatory and depressant insect-selective neurotoxins, Lqh alpha IT was highly toxic to insects, but it differed from these toxins in two important characteristics: (a) Lqh alpha IT lacked strict selectivity for insects; it was highly toxic to crustaceans and had a measurable but low toxicity to mice. (b) It did not displace an excitatory insect toxin, 125I-AaIT, from its binding sites in the insect neuronal membrane; this indicates that the binding sites for Lqh alpha IT are different from those shared by the excitatory and depressant toxins. However, in its primary structure and its effect on excitable tissues, Lqh alpha IT strongly resembled the well-characterized alpha scorpion toxins, which affect mammals. The amino acid sequence was identical with alpha toxin sequences in 55%-75% of positions. This degree of similarity is comparable to that seen among the alpha toxins themselves. Voltage- and current-clamp studies showed that Lqh alpha IT caused an extreme prolongation of the action potential in both cockroach giant axon and rat skeletal muscle preparations as a result of the slowing and incomplete inactivation of the sodium currents. These observations indicate that Lqh alpha IT is an alpha toxin which acts on insect sodium channels.(ABSTRACT TRUNCATED AT 250 WORDS)
Some beta-toxins from the South American scorpion Tityus serrulatus (e.g. Ts VII) are highly toxic both for mouse and fly larva. Radioiodinated Ts VII and the insect toxin from the North African scorpion Androctonus australis Hector (AaH IT) bind to the same site on a house fly head synaptosomal fraction. These results reinforce the hypothesis about the existence of a correlated series of scorpion toxins as previously defined by amino acid compositions and sequences, and immunological and circular dichroism studies, in suggesting that Ts VII constitutes a link which may fill the pharmacological gap existing between beta-toxins and insect toxins such as AaH IT.
Photoreactive and radioiodinated derivatives of several scorpion toxins acting on insect Na+ channels were prepared without loss of their pharmacological activities. Photoaffinity experiments were carried out on a synaptosomal fraction from the nerve cord of the cockroach Periplaneta americana: with all toxin derivatives, a single specifically labeled band was obtained with a molecular weight of 188,000 +/- 12,000 (n = 17). These results indicate for the first time the molecular weight of the scorpion toxin receptor from the insect nervous system which is probably associated with voltage sensitive Na+ channels. One of these toxins, toxin VII from Tityus serrulatus venom, has been previously shown to be active both in mammals and in insects, in rat brain synaptosomes this toxin labeled a Mr = 31,000 +/- 4,000 band in contrast, to observations in the insect preparation.
Orthorhombic crystals (space group P212121, a = 45.94 A, b = 40.68 A, c = 29.93 A) of the potent scorpion alpha-toxin II from Androctonus australis Hector were grown using sterile techniques. The structure was solved by a combination of heavy-atom and model phasing. Subsequently, it was refined at 1.8 A resolution by a fast-Fourier restrained least-squares procedure. The crystallographic R factor is 0.152 for data with 7.0 A greater than d greater than 1.8 A and F greater than 2.5 sigma (F) and 0.177 when all data are considered. Eighty-nine solvent molecules have been incorporated into the model. The dense core formed by the alpha-helical and antiparallel beta-sheet moieties and three of the four disulfide bridges is similar in variant 3, a toxin purified from the North American scorpion Centruroides sculpturatus, and in toxin II. However, the two molecules differ markedly in the orientation of loops protruding from the core. Toxin II seems to contain several highly ordered solvent molecules. Eight of them occupy a cavity consisting of the C-terminal region and a loop found only in scorpion alpha-toxins. The highly reactive and pharmacologically important Lys-58 is found at one of the extremes of this cavity, where it establishes a series of hydrogen bonds with protein and solvent atoms. The reactivities of the five lysine residues of toxin II are highly correlated with the formation of hydrogen bonds, hydrophobic interactions, and salt links.
We have explored the possibility of improving baculovirus pesticides by incorporating an insect-specific neurotoxin gene into a baculovirus genome. A 112-bp gene (BeIt) encoding insectotoxin-1 of the scorpion Buthus eupeus was synthesized and cloned in Escherichia coli. For expression, BeIt was transferred to the DNA genome of Autographa californica nuclear polyhedrosis virus (AcMNPV). Three different recombinant AcMNPVs, carrying BeIt under the control of the strong AcMNPV polyhedrin promoter, were constructed and expression of BeIt was monitored upon infection of Spodoptera frugiperda (Sf) cells. Toxin expression was low using a recombinant virus in which BeIt was inserted 6 nucleotides (nt) downstream from the intact polyhedrin mRNA leader. More expression was observed when a signal-peptide was attached in-frame to the N terminus of BeIt. The highest level of expression was observed with a fusion gene comprised of the 58 N-terminal codons of polyhedrin fused to BeIt; however, the level of expression was ten- to twenty-fold below that for polyhedrin. Polyhedrin promoter-directed transcripts of all three recombinants accumulated to levels similar to those of wild-type polyhedrin transcripts, indicating that the limitation to expression of unfused BeIt was not at the level of transcription but rather at the posttranscriptional level including translation or protein stability. Paralytic activity of the toxin products was not detected.
A large scale procedure for purification of the toxins in the venom of the North African scorpion Androctonus australis has been developed. This procedure optimizes the sequence of the steps, leading to better yields of toxins and shortening of the time. It is possible to use 10-15 g batches of venom and also prevent cross-contamination of the toxins. High pressure liquid chromatography has been used to separate AaH I and I', two isotoxins which differ by one amino acid residue in position 17: valine or isoleucine. The procedure allows the characterization of a new toxin active in mice, AaH IV, which represents 0.6 and 2.5% of the venom weight and toxicity, respectively. This new component has been characterized as an alpha toxin made up of 61 amino acid residues and having a neutral isoelectric point.
The toxicity of the insect toxin from the venom of the scorpion Androctonus australis Hector has been studied in six species of insects, three species of crustaceans (two terrestrial and one aquatic) and in mice. Paralysing and lethal effects were observed not only in insects but also on the three crustacean species. For insects the LD50 varies from 2 to 1310 ng per 100 mg of insect, according to the species. On crustaceans doses up to 3-9 micrograms per 100 mg of animal induced a paralysing or lethal effect. In mice injections of 0.05 and 1 mg of the toxin intracerebroventricularly and s.c. resulted in no apparent symptoms of intoxication. These results demonstrate that the insect toxin of Androctonus australis Hector has no toxicity for the mouse, but also that it is not absolutely specific for insects.
The positions of the disulfide bridges in toxin II of Androctonus australis Hector were investigated using proteolytic enzymes. The resulting peptides were separated by column and paper chromatography and high-voltage electrophoresis. Determination of the amino acid compositions of the cystine-containing peptides or their oxidized derivatives and, when necessary, dansyl Edman degradation allowed to locate the disulfide bonds in the toxin. The four disulfide bridges were found to link the half-cystine residues number 12 and 63, 16 and 36, 22 and 46, 26 and 48. These positions are probably the same in all scorpion neurotoxins.
Die Reinigung eines für Insekten toxischen Proteins aus dem Gift des Skorpions Androctonus australis Hector ist mittels Rezyklieren von Sephadex G50-Filtration und Chromatographie en DEAE-Sephadex A50 und Amberlit CG-50 durchgeführt worden. Das Endprodukt wurde 267 Mal gereinigt im Vergleich zu dem rohen Gift. Die Gift ausbeute war 95 %. Die Reinheit des Insekttoxins wurde durch Aminosäureanalyse, sequentiale N-End-Degradation, C-End-Aminosäure-Bestimmung und Zonen Elektrophorese geschätzt. Sein Molekulargewicht ist 7498. Das Insekttoxin unterscheidet sich von den für Säugetiere giftigen Toxinen, die in demselben Gift enthalten sind. Die Sequenz der ersten 15 Aminosäurereste aus den N-Enden der beiden Toxinarten wird verglichen. Die physiologische Bedeutung dieser neurotoxischen Proteine wird besprochen.
The purification of eleven neurotoxins from the venom of three scorpions (Androctonus australis Hector, Buthus occitanus tunetanus and Leiurus quinquestriatus quinquestriatus) has been performed by Sephadex G-50 filtration (with and without recycling) and equilibrium chromatography on Amberlite CG-50, CM-Sephadex C-50 and DEAE-Sephadex A-50. All the chromatographic steps were carried out in ammonium acetate buffers. Purity of the neurotoxins was assessed by amino acid analysis and zone electrophoresis. All have a molecular weight of about 7000 daltons and do not contain methionine. As shown by amino acid composition and chain length scorpion neurotoxins show a high degree of homology.
The three-dimensional crystal structure of variant-3 toxin from the scorpion Centruroides sculpturatus Ewing has been determined at 3 A resolution. Phases were obtained by use of K2PtCl4 and K2IrCl6 derivatives. The most prominent secondary structural features are two and a half turns of alpha-helix and a three-strand stretch of antiparallel beta-sheet, which runs parallel to the alpha-helix. The helix is connected to the middle strand of the beta-sheet by two disulfide bridges; a third disulfide bridge is located nearby. Several loops extend out of this dense core of secondary structure. The largest loop is joined to the COOH terminus of the molecule by the fourth disulfide bridge. The overall shape of the molecule resembles a right-hand fist: the alpha-helix runs along the knuckles of the fist; the beta-sheet lies along the second and third joints of the fingers; the thumb is defined by two short loops that are composed of residues 16-21 and residues 41-46; the wrist corresponds to the COOH-terminal stretch of residues 52-65 and a loop composed of residues 5-14; and the second joint of the little finger is near the NH2 terminus of the molecule. The alpha-carbon backbone displays a large flat surface that lies along the second joints of the fingers and the heel of the hand in the fist model. Several of the conserved residues in the scorpion neurotoxins are clustered on this surface, which may play a role in interactions of scorpion toxins with sodium channels of excitable membranes.
The action of the neurotoxin in Buthinae scorpion venoms (Androctonus, Buthus or Leiurus genera) has been extensively studied. These proteins induce a prolongation of the action potential of nerves and muscles by slowing down inactivation of the sodium channel. Their affinity for their receptor site depends on membrane potential. In the present report we describe a toxin from a Centrurinae scorpion, Centruroides suffusus, which binds rat brain synaptosomes at a receptor site distinct from the Buthinae scorpion site independently of voltage. We name Androctonus-like toxins, alpha-scorpion toxins (alpha-ScTX), and Centruroides-like toxins, beta-scorpion toxins (beta-ScTX). We further report that beta-ScTX induces repetitive firing in frog myelinated nerve fibres by producing an abnormal sodium permeability. The beta-toxin binds specifically to rat brain synaptosomes (Kd = 3 nM) and induces an inhibition of the uptake and a stimulation of the release of GABA at concentrations which are in good agreement with the Kd value. These effects are blocked by tetrodotoxin. The binding site of beta -ScTX is distinct from those of other neurotoxins acting on the sodium channel like tetrodotoxin, alpha-ScTX and veratridine. The alpha-ScTX/beta-ScTX binding site capacities decreases as development of rat brain synaptosomes progresses ; at day 7 after birth, it is 1.1. and at day 39, 0.3.
The binding of toxin II from the scorpion Centruroides suffusus suffusus (CssII) to electroplaque membranes from Electrophorus electricus was studied with the use of a radiolabeled derivative of the toxin ([125I]CssII). Specific binding of the latter to the membranes required the protonation of a group, either in the membrane or in the toxin itself, with an apparent pKa value of 7.5 and also the presence of a certain minimum concentration of ions, though there was no requirement for a specific ion. At 20 degrees C and pH 6 the second-order rate constant for formation of the [125I]CssII-membrane complex was about 5 X 10(6) M-1 s-1, while the first-order constant for its dissociation was about 2 X 10(-3) s-1. Under equilibrium conditions specific binding of [125I]CssII was a simple saturable function of [125I]CssII concentration, characterized by a dissociation constant of 0.4-0.7 nM and a maximum capacity of 0.9-2.4 pmol of toxin/mg of membrane protein. The latter value was the same as the number of membrane sites that could specifically bind a radiolabeled derivative of tetrodotoxin. Unlabeled CssII displaced bound [125I]CssII with an apparent dissociation constant of about 1 nM. None of 19 other neurotoxins or local anaesthetics known to interact with Na+ channels in excitable cells affected [125I]CssII binding, but it was completely inhibited by toxin gamma from the scorpion Tityus serrulatus serrulatus. These findings suggest that the Na+ channel possesses a distinct class of binding sites to which these two scorpion toxins bind with high affinities. On the other hand, no CssII receptor was detected in crab axonal membranes, indicating that it is not a characteristic feature of all Na+ channels.
Scorpion venom toxins were systematically classified according to amino acid composition, insertion/deletion events and sequence. The significance of each comparison method and its outcome is discussed in relation to known immunological and structural properties. A general classification of the toxins is proposed that accounts for both the immunological groupings and the differences in mode of action.
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The architecture of the pore-region of a voltage-gated K+ channel, Kv1.3, was probed using four high affinity scorpion toxins as molecular calipers. We established the structural relatedness of these toxins by solving the structures of kaliotoxin and margatoxin and comparing them with the published structure of charybdotoxin; a homology model of noxiustoxin was then developed. Complementary mutagenesis of Kv1.3 and these toxins, combined with electrostatic compliance and thermodynamic mutant cycle analyses, allowed us to identify multiple toxin-channel interactions. Our analyses reveal the existence of a shallow vestibule at the external entrance to the pore. This vestibule is approximately 28-32 A wide at its outer margin, approximately 28-34 A wide at its base, and approximately 4-8 A deep. The pore is 9-14 A wide at its external entrance and tapers to a width of 4-5 A at a depth of approximately 5-7 A from the vestibule. This structural information should directly aid in developing topological models of the pores of related ion channels and facilitate therapeutic drug design.
The Androctonus australis scorpion venom contains alpha-toxins for which the complementary DNAs have been cloned [Bougis et al. (1989) J. Biol. Chem. 264, 19259-19265], targeting with high affinity the voltage-sensitive sodium channel. From a genomic library made of this species of scorpion, we have cloned and characterized the gene encoding the toxin AaH I'. The gene transcriptional unit is 793 base pairs long, and the gene has a single intron of 425 base pairs located near the end of the signal peptide of the toxin precursor. The transcription initiation site was determined by primer extension and corresponded to the nucleotide sequence AACAA. Upstream, a promoter region has been identified with positive acting sequence elements at consensus positions, such as a CCAAT box and a TATA box. In addition, putative elements for binding the transcriptional factors MAT-alpha 2, Pit-1, and IEF1 are also present. Analysis of DNA curvature by computer modeling revealed a strong bending centered around the transcription initiation site of the gene. The bending angle (61 degrees) estimated experimentally using polyacrylamide gel electrophoresis correlates well with the value predicted by computer modeling (66 degrees). Other minor deflections of the helix axis cooperate for an overall curvature of nearly 90 degrees, which is significantly stronger than similar structures already reported in eukaryotic cells. It is worth noting that the grooves relative to the CCAAT box and the TATA box lie along the inside of the DNA curve. This observation is in agreement with the previously reported correlation between DNA bending and promoter function.
We describe the secondary structure and the overall fold of toxin III from the venom of the scorpion Leiurus quinquestriatus quinquestriatus determined using two-dimensional-1H-NMR spectroscopy. This protein, which contains 64 amino acids and 4 disulfide bridges, belongs to the long-chain toxin category and is highly toxic to both mammals and insects. The overall fold was determined on the basis of 1208 inter-proton-distance restraints derived from NOE measurements and 90 psi, phi dihedral-angle restraints derived from NOE connectivities and 3JNH-alphaH coupling constants using the HABAS program. This fold, which mainly consists of an alpha-helix packed against a small antiparallel three-stranded beta-sheet, and of several turns and loops, is similar to that of other long-chain scorpion toxins. Aromatic and non-polar residues form several patches on the surface of the protein which alternate with patches of charged and polar residues. Such a topology should be important in the interactions of toxin III with sodium channels in membranes. Two weakly constrained loops introduce some flexibility to the structure which could be related to the activity of this toxin. The central core of toxin III is compared with the cysteine-stabilized alpha beta motif (an alpha-helix connected to a beta-sheet through two disulfide bridges) found in insect defensins and plant thionins. Defensins and thionins are small proteins (approximately 40--50 amino acid residues) containing three or four disulfide bridges, respectively. This comparison confirms that the cysteine-stabilized alpha beta motif is a common core to a number of small proteins from different origins and having different activities.
We have constructed a cDNA library from venom glands of the scorpion Buthus occitanus tunetanus and cloned a DNA sequence that encodes an alpha-toxin. This clone was efficiently expressed in Escherichia coli as a fusion protein with two Ig-binding (Z) domains of protein A from Staphylococcus aureus. After CNBr treatment of the fusion protein and HPLC purification, we obtained approximately 1 mg recombinant apha-toxin/l bacterial culture. The toxin, called Bot XIV, displays no toxicity towards mammals but is active towards insects as shown by its paralytic activity against Blatella germanica cockroach and by electrophysiological studies on Periplaneta americana cockroaches. The Bot XIV protein fused to two Z domains is highly immunogenic in mice and induces production of antisera that specifically recognize and neutralize highly toxic components that had been injected into mice. This fusion protein could be very useful for development of potent protective antisera against scorpion venoms.
In voltage-dependent K+ channels, each of the four identical subunits contributes one pore loop to the central ion selectivity unit at the interface between the subunits. The pore loop is also the target for scorpion venom peptide inhibitors. These inhibitors bind at the pore entryway between the four subunits and can assume any one of four orientations. The orientations become distinguishable only if the binding site symmetry is disrupted. We have used mutagenesis and site-directed chemical modification to alter pore loop amino acids in either one or four subunits. The effects of these alterations on inhibitor affinity define the eccentricity of amino acids in the pore entryway and imply a different secondary structure for the amino and carboxyl ends of the pore loop.
A single intron of 87 bp, close to the region encoding the C-terminal part of the signal peptide, was found in the gene of the 'short' scorpion toxin kaliotoxin 2 of Androctonus australis acting on various types of K+ channels. Its A+T content was particularly high (up to 86%). By walking and ligation-mediated PCR, the promoter sequences of the kaliotoxin 2 gene of Androctonus australis were studied. The transcription unit of the gene is 390 bp long. Consensus sequences were identified. The genes of 'short' scorpion toxins active on K+ channels are organized similarly to those of the 'long' scorpion toxins active on Na+ channels and not like those of structurally related insect defensins, which are intronless.