Orthorhombic crystals and three-dimensional structure of the potent toxin II from the scorpion Androctonus australis Hector

Solution structure of gamma 1-H and gamma 1-P thionins from barley and wheat endosperm determined by 1H-NMR: a structural motif common to toxic arthropod proteins

The complete assignment of the proton NMR spectra of the homologous gamma 1-hordothionin and gamma 1-purothionin (47 amino acids, 4 disulfide bridges) from barley and wheat, respectively, has been performed by two-dimensional sequence-specific methods. A total of 299 proton-proton distance constraints for gamma 1-H and 285 for gamma 1-P derived from NOESY spectra have been used to calculate the three-dimensional solution structures. Initial structures have been generated by distance geometry methods and further refined by dynamical simulated annealing calculations. Both proteins show identical secondary and tertiary structure with a well-defined triple-stranded antiparallel beta-sheet (residues 1-6, 31-34, and 39-47), an alpha-helix (residues 16-28), and the corresponding connecting loops. Three disulfide bridges are located in the hydrophobic core holding together the alpha-helix and the beta-sheet and forming a cysteine-stabilized alpha-helical (CSH) motif. Moreover, a clustering of positive charges is observed on the face of the beta-sheet opposite to the helix. The three-dimensional structures of the gamma-thionins differ remarkably from plant alpha- and beta-thionins and crambin. However, they show a higher structural analogy with scorpion toxins and insect defensins which also present the CSH motif.

Antibodies cross-reactive with the scorpion-toxin II from Androctonus australis Hector elicited in mice by a synthetic peptide

With the aim of developing active protection against the noxious effects provoked in humans by scorpion stings, the possibility of eliciting toxin reactive antibodies by immunization with a short peptide was assessed in mice. The amino acid sequence of residues 50 to 59 of Androctonus australis Hector toxin II was chosen, on the basis of previous results indicating that rabbit anti-(50-59) antibodies neutralize the biological effects of the parent toxin. The peptide was prepared by solid-phase synthesis procedures and used in different forms (free, linearly polymerized, coupled to KLH, coupled to a low-molecular weight B-lymphocyte activator) in order to immunize groups of non-congenic NMRI or congenic C57BL/6 mice. The reactivities of each serum with the peptide and with the toxin were assessed in ELISA. Strong reactivities with both the peptide (mean titer over 1:52,600) and the toxin (mean titer 1:800) were observed in all mice from the group that received the KLH-coupled peptide. However, mouse immune sera failed either to recognize the toxin in a liquid-phase radioimmunoassay or to neutralize the lethal effects of the toxin. The requirements, in terms of affinity and recognition of native conformation, for anti-peptide antibodies to display neutralizing properties are discussed.

Development of recombinant viral insecticides by expression of an insect-specific toxin and insect-specific enzyme in nuclear polyhedrosis viruses

As supplements to classical chemical insecticides, two approaches to develop recombinant baculovirus insecticides are described. In one approach an insect-specific toxin is expressed leading to a dramatic reduction in time to death. In the second approach an insect juvenile hormone esterase is expressed which leads to a reduction in feeding. Modifications of the wildtype esterase led to viruses which reduced the time to death as effectively as did the toxin-expressing virus. In both cases existing recombinant viruses are viewed as leads, and approaches to further improvement in the engineered viruses are suggested. Many of these approaches are based on analogy with the development of classical synthetic insecticides. Using these viruses as examples, the potential utility and limitations of recombinant viruses and other biological insecticides are discussed.

Solution conformation of human neuropeptide Y by 1H nuclear magnetic resonance and restrained molecular dynamics

The solution structure of human neuropeptide Y has been solved by conventional two-dimensional NMR techniques followed by distance-geometry and molecular-dynamics methods. The conformation obtained is composed of two short contiguous alpha-helices comprising residues 15-26 and 28-35, linked by a hinge inducing a 100 degree angle. The first helix (15-26) is connected to a polyproline stretch (residues 1-10) by a tight hairpin (residues 11-14). The helices and the polyproline stretch are packed together by hydrophobic interactions. This structure is related to that of the homologous avian pancreatic polypeptide and bovine pancreatic polypeptide. The C- and N-terminii, known to be involved in the biological activity for respectively the receptor binding and activation, are close together in space. The side chains of residues Arg33, Arg35 and Tyr36 on the one hand, and Tyr1 and Pro2 on the other, form a continuous solvent-exposed surface of 4.9 mm2 which is supposed to interact with the receptor for neuropeptide Y.

Amino acid sequence and immunological characterization with monoclonal antibodies of two toxins from the venom of the scorpion Centruroides noxius Hoffmann

Two toxins, which we propose to call toxins 2 and 3, were purified to homogeneity from the venom of the scorpion Centruroides noxius Hoffmann. The full primary structures of both peptides (66 amino acid residues each) was determined. Sequence comparison indicates that the two new toxins display 79% identity and present a high similarity to previously characterized Centruroides toxins, the most similar toxins being Centruroides suffusus toxin 2 and Centruroides limpidus tecomanus toxin 1. Six monoclonal antibodies (mAb) directed against purified fraction II-9.2 (which contains toxins 2 and 3) were isolated in order to carry out the immunochemical characterization of these toxins. mAb BCF2, BCF3, BCF7 and BCF9 reacted only with toxin 2, whereas BCF1 and BCF8 reacted with both toxins 2 and 3 with the same affinity. Simultaneous binding of mAb pairs to the toxin and cross-reactivity of the venoms of different scorpions with the mAb were examined. The results of these experiments showed that the mAb define four different epitopes (A-D). Epitope A (BCF8) is topographically unrelated to epitopes B (BCF2 and BCF7), C (BCF3) and D (BCF9) but the latter three appear to be more closely related or in close proximity to each other. Epitope A was found in all Centruroides venoms tested as well as on four different purified toxins of C. noxius, and thus seems to correspond to a highly conserved structure. Based on the cross-reactivity of their venoms with the mAb, Centruroides species could be classified in the following order: Centruroides elegans, Centruroides suffusus suffusus = Centruroides infamatus infamatus, Centruroides limpidus tecomanus, Centruroides limpidus limpidus, and Centruroides limpidus acatlanensis, according to increasing immunochemical relatedness of their toxins to those of Centruroides noxius. All six mAb inhibited the binding of toxin 2 to rat brain synaptosomal membranes, but only mAb BCF2, which belongs to the IgG2a subclass, displayed a clear neutralizing activity in vivo.

Refined structure of charybdotoxin: common motifs in scorpion toxins and insect defensins

Conflicting three-dimensional structures of charybdotoxin (Chtx), a blocker of K+ channels, have been previously reported. A high-resolution model depicting the tertiary structure of Chtx has been obtained by DIANA and X-PLOR calculations from new proton nuclear magnetic resonance (NMR) data. The protein possesses a small triple-stranded antiparallel beta sheet linked to a short helix by two disulfides and to an extended fragment by one disulfide, respectively. This motif also exists in all known structures of scorpion toxins, irrespective of their size, sequence, and function. Strikingly, antibacterial insect defensins also adopt this folding pattern.

Crystal structure of defensin HNP-3, an amphiphilic dimer: mechanisms of membrane permeabilization

Defensins (molecular weight 3500 to 4000) act in the mammalian immune response by permeabilizing the plasma membranes of a broad spectrum of target organisms, including bacteria, fungi, and enveloped viruses. The high-resolution crystal structure of defensin HNP-3 (1.9 angstrom resolution, R factor 0.19) reveals a dimeric beta sheet that has an architecture very different from other lytic peptides. The dimeric assembly suggests mechanisms by which defensins might bind to and permeabilize the lipid bilayer.

Three-dimensional structure of natural charybdotoxin in aqueous solution by 1H-NMR. Charybdotoxin possesses a structural motif found in other scorpion toxins

A 600-MHz proton NMR study of natural charybdotoxin, a toxin acting on K+ channels, is reported. The unambiguous sequential assignment of all the protons of the toxin was achieved. The analysis of NOEs and of backbone coupling constants showed the existence of an alpha-helix (residues 10-19) and of an antiparallel beta-sheet in the 26-35 part. Three-dimensional structures were generated by distance geometry, using a set of 114 interresidual calibrated constraints (63 sequential, 47 medium and long range, 4 hydrogen bonds) and 29 phi angles. These structures show that charybdotoxin is composed of a beta-sheet linked to an alpha-helix by two disulphide bridges and to an extended fragment by the third disulphide bridge. Comparison with the other known structures of long and short scorpion toxins shows that this structural motif is common to all these proteins.

Two-dimensional 1H nuclear magnetic resonance study of AaH IT, an anti-insect toxin from the scorpion Androctonus australis Hector. Sequential resonance assignments and folding of the polypeptide chain

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.

Characterization of cationic binding sites of neurotoxins from venom of the scorpion (Centruroides sculpturatus Ewing) using lanthanides as binding probes

Binding sites for cations were probed in the structures of protein neurotoxins from Centruroides sculpturatus by enhancement of terbium(III) fluorescence, detected by emission at 552 nm, when aromatic side-chains of the toxins were activated at 286 nm. Gadolinium, Gd(III), was used as a cation binding probe by observing its effects on nuclear magnetic resonance (NMR) spectra. Toxins CsE-v2 and v3, when bound to Tb(III), enhance luminescence of Tb(III) 20-fold whereas CsE-v1 enhances Tb(III) luminescence about 15-fold. Toxins CsE-I and V have no effect on the luminescence of Tb(III) implying that these latter two toxins have structures incompatible with efficient energy transfer from activated aromatic side-chains. Enhancement of fluorescence is pH dependent and is competitively inhibited by alkaline earth divalent cations and by other lanthanide(III) ions. Neodymium, Nd(III), with an ionic radius of 0.995 A is the most efficient of the lanthanide ions and the divalent cations in displacement of Tb(III) from the toxins. Relaxation enhancements of aromatic CH resonances by Gd(III) are apparent with tyrosines 4, 42, 38, 14-40 peak and tryptophan 47. Results from pH vs fluorescence studies suggest that carboxyl groups are involved in binding of Tb(III). Association constants (Ka) of the Tb(III)-CsE-v2 and v3 complexes are respectively 2.5 x 10(3) and 2.4 x 10(3) M-1 determined by fluorescence enhancement and 2.4 x 10(3) and 2.3 x 10(3) M-1 by equilibrium dialysis. Similarly Ka values for toxins CsE I and V are respectively 1.9 x 10(3) and 1.8 x 10(3) M-1 determined by equilibrium dialysis. Experimental evidence suggests that at least two Tb(III)s are bound per toxin molecule. The results from these studies are discussed in relation to the tertiary structure of toxin CsE-v3.

Structure and structure-function relationships of sea anemone proteins that interact with the sodium channel

Sea anemones produce a series of toxic polypeptides and proteins with molecular weights in the range 3000-5000 that act by binding to specific receptor sites on the voltage-gated sodium channel of excitable tissue. This article reviews our current knowledge of the molecular basis for activity of these molecules, with particular emphasis on recent results on their receptor binding properties, the role of individual residues in activity and receptor binding, and their three-dimensional structures as determined by nuclear magnetic resonance spectroscopy. A region of these molecules that constitutes at least part of the receptor binding domain is proposed.

The complete amino acid sequence of toxin TsTX-VI isolated from the venom of the scorpion Tityus serrulatus

The complete sequence of the toxin TsTX-VI from the venom of the scorpion Tityus serrulatus Lutz and Mello is presented. The sequence has been determined by automated Edman analysis of the reduced and carboxymethylated protein as well as of the resulting peptides, obtained from S. aureus protease and tryptic digestions. TsTX-VI is composed of 62 residues and has a calculated molecular weight of 6717. Homology studies with other scorpion toxins show that TsTX-VI is more similar to the Old World than to the North American scorpion toxins. The hydropathic index indicates that TsTX-VI is more hydrophobic than Ts-gamma. Toxicity studies carried out in mice demonstrate that i.v. injection of TsTX-VI is unable to evoke the usual symptoms induced by the typical neurotoxins of this venom, but only a generalized allergic reaction. These properties are important in clarifying the relationship between primary structure and biological function of scorpion toxins.

Neurotoxins active on insects: amino acid sequences, chemical modifications, and secondary structure estimation by circular dichroism of toxins from the scorpion Androctonus australis Hector

Two scorpion neurotoxins active only on insects, the insect toxins AaH IT1 and AaH IT2, were purified from the venom of scorpions Androctonus australis Hector collected in Tozeur (Tunisia) and characterized. AaH IT2 was sequenced and found to differ in four amino acid positions from AaH IT, the single previously sequenced insect toxin [Darbon, H., Zlotkin, E., Kopeyan, C., Van Rietschoten, J., & Rochat, H. (1982) Int. J. Pept. Protein Res. 20, 320-330] which possessed an equal potential for paralyzing fly larvae. The basic amino acid residues of AaH IT1, which differs from AaH IT by one amino acid residue, were selectively chemically modified. Six derivatives were characterized. Their toxicity toward fly larvae and cockroach was determined, and their affinity for the AaH IT1 synaptosomal receptor from cockroach nerve cord was measured. Modification of His-30, Lys-34, and Arg-60 showed no significant effect on biological activity. However, the modification of Lys-28 or Lys-51 demonstrated that these two amino acids are important for toxicity. Furthermore, simultaneous modifications of both Lys-28 and Lys-51 led to a cumulative decrease in biological activity. AaH IT1 and AaH IT2 show similar CD spectra. The secondary structures content of AaH IT2 was estimated from circular dichroism data. Results showed that this class of toxin should possess an additional alpha-helical region and a beta-sheet strand, not found in toxins active on mammals. Attempts to localize these secondary structural features in the amino acid sequence of AaH IT2 indicated that these two regions would be located within the last 20 C-terminal amino acid residues. From these studies on secondary structures, it is possible to consider that toxins active on insects are more structurally constrained than those active on mammals; a decreased molecular flexibility may be, at least partially, responsible for the observed specificity of these toxins for the insect sodium channel. Furthermore, the two alpha-helices found in insect toxins enclosed the two conserved Lys-28 and Lys-51 and might thus be implicated in the toxic site of insect toxins.

Conformational flexibility of a scorpion toxin active on mammals and insects: a circular dichroism study

Three scorpion toxins have been analyzed by circular dichroism in water and in 2,2,2-trifluoroethanol (TFE) solutions. These toxins were chosen because they are representative of three kinds of pharmacological activities: (1) toxin AaH IT2, an antiinsect toxin purified from the venom of Androctonus australis Hector, which is able to bind to insect nervous system preparation, (2) toxin Css II, from the venom of Centruroides suffusus suffusus, which is a beta-type antimammal toxin capable of binding to mammal nervous system preparation, and (3) the toxin Ts VII from the venom of Tityus serrulatus, which is able to bind to both types of nervous systems. In order to minimize bias, CD data were analyzed by a predictive algorithm to assess secondary structure content. Among the three molecules, Ts VII presented the most unordered secondary structure in water, but it gained in ordered forms when solubilized in TFE. These results indicated that the Ts VII backbone is the most flexible, which might result in a more pronounced tendency for this toxin molecule to undergo conformational changes. This is consistent with the fact that it competes with both antiinsect and beta-type antimammal toxins for the binding to the sodium channel.

Structure-activity relationships of scorpion alpha-neurotoxins: contribution of arginine residues

The role of arginine residues in the structure-activity relationships of alpha-scorpion neurotoxins was studied. Toxins I and II from Androctonus australis Hector (north African scorpion), containing respectively 2 and 3 arginines, were modified by phenylglyoxal or p-hydroxyphenylglyoxal. Modified derivatives were purified by reverse-phase HPLC and/or ion exchange HPLC. Subsequent bioassays showed that toxin I (AaH I) derivatives with single modifications on Arg 2 and Arg 60 had low activity (25 and 14% of residual activity, assessed in receptor binding experiments). Doubly modified (Arg 2, Arg 60) AaH I had 7% residual activity while further derivatization of the alpha-amino group led to an almost inactive derivative. These results agree with the involvement of arginines 2 and 60, as well as the alpha-amino group, of AaH I in the toxin/receptor interaction, probably via electrostatic interactions. Consistent with the role of N-terminal residues, the selective removal of the N-terminal dipeptide Val-Arg of toxin III from the same scorpion resulted in low activity (7% residual activity). The arginine residue in position 56 of toxin II was important for bioactivity since the derivative modified by phenylglyoxal on Arg 56 exhibited low residual activity (20%). Arg 62 and Arg 18, on the other hand, can be modified without any great effect on the pharmacological activity of AaH II. These results furnish a more precise picture of those residues involved in the "toxic region", which appears to be composed of residues belonging to the conserved hydrophobic surface and to the C-terminal and N-terminal sequences.

Localization of the receptor site for alpha-scorpion toxins by antibody mapping: implications for sodium channel topology

Site-directed and monoclonal antibodies recognizing different extracellular regions of the RII sodium channel alpha subunit have been used to determine the sequences that comprise the receptor for alpha-scorpion toxins by evaluating the effect of antibody on voltage-dependent binding of radio-labeled toxin isolated from Leiurus quinquestriatus to both reconstituted rat brain sodium channel and rat brain synaptosomes. Of six antibodies tested, two recognizing amino acid residues 355-371 and 382-400 located on an extracellular loop between transmembrane segments S5 and S6 of domain I and one recognizing residues 1686-1703 of a similar loop of domain IV inhibit binding by 30-55%. Inhibition is concentration-(EC50 = 0.4-2 microM) and time- (t1/2 = 40-80 min) dependent. Five different monoclonal antibodies recognizing the same extracellular loop in domain I inhibit binding completely with similar EC50 values as observed for site-directed antibodies. Kinetic studies of the antibody effect are consistent with a slowly reversible competition for the toxin receptor site. Our results suggest that the extracellular loops between segments S5 and S6 of domains I and IV comprise at least part of the alpha-scorpion toxin receptor site and support the membrane topology models in which domains I and IV are adjacent in the tertiary structure of the channel protein and six transmembrane sequences are contained in each of the four homologous domains.

Three-dimensional model of the insect-directed scorpion toxin from Androctonus australis Hector and its implication for the evolution of scorpion toxins in general

The three-dimensional structure of the insect-directed toxin from the scorpion Androctonus australis Hector has been modelled using computer graphics and energy-minimization techniques. The model-building procedure was based on the known high resolution structures of two scorpion toxins of different types: toxin II from A. australis Hector, an alpha-toxin, and variant 3 from Centruroides sculpturatus Ewing that belongs to the beta-toxin structural group. Although the insect-directed toxin has one atypical disulfide bridge, the general structural features of the scorpion toxin family, including the presence of a "conserved-hydrophobic" surface, seem to be well-conserved. However, the orientation and length of some loops and regions thought to be important for toxicity are different for alpha-toxins, beta-toxins, and the insect-directed toxin. Thus, the binding of a scorpion toxin to its site on the Na+ channel seems to be based on (1) the presence of a surface containing a series of conserved and/or hydrophobic residues, more or less common to all these molecules, and (2) an adjacent area that modulates the specificity of the interaction.

Structure/activity relationships of scorpion alpha-toxins. Multiple residues contribute to the interaction with receptors

Chemical modifications of tyrosine and tryptophan residues of scorpion alpha-neurotoxins II and III from Androctonus australis Hector were performed as well as modification of the two arginines and the alpha-amino group of toxin I. The pharmacological potencies of each derivative were assessed in vivo by LD50 measurement and in vitro by competition experiments with 125I-toxin for synaptosomal receptors. Arginine residues in positions 2 and 60 and the alpha-amino group of Androctonus toxin I were derivatized by p-hydroxyphenylglyoxal; the corresponding modified toxins exhibit low pharmacological potencies. Tryptophan 38 of toxin II and tryptophan 45 of toxin III were modified by nitrophenylsulfenyl chloride, leading respectively to a poorly and a fully active derivative. The tetranitromethane modification of tyrosine residues in positions 60, 5 and 14 of toxin III induced respectively 60%, 40% and 30% of loss of biological activity. Circular dichroic analysis indicated that for every derivative, except the nitrophenylsulfenyl derivative of Trp-45 of AaH III, the conformation of the toxin was not altered by derivatization. Conformational integrity was also confirmed by full activity of the derivatives in radioimmunoassays. Taken together, the results suggest that aromatic residues belonging to the conserved hydrophobic surface, to the C-terminal and to the loop region 37-44 are involved in the molecular mechanisms by which scorpion alpha-toxins act. Charged residues in the N-terminal and C-terminal also contribute to the high efficacy of the binding process. It appears that all important residues are clustered on one face of the toxin, suggesting a multipoint interaction with the proteins of the sodium channel.

Oxidative folding of cystine-rich peptides vs regioselective cysteine pairing strategies

The methodology of regioselective cysteine pairings in synthetic multiple-cystine peptides has progressed in the past years to an efficiency that allows for at least three specific inter- and intrachain disulfide bridgings. Conformational studies on various multiple-cystine peptides like hormones, protease inhibitors, and toxins revealed that these bioactive peptides, generated by posttranslational processing of precursor proteins, are folded into miniprotein-like compact globular structures of remarkable stability. This strongly suggests protein domain or subdomain properties of these families of peptides, and thus sufficient sequence-encoded information for correct oxidative refolding under appropriate experimental conditions. From intensive research on the mechanisms and pathways of oxidative refolding of proteins in vivo and in vitro, the efficient methods have emerged for simulating nature in the regeneration of native folds not only for intact proteins, but also for protein domains and subdomains. In fact, the results obtained in the oxidative folding of excised protein fragments and of relatively low mass products of posttranslational processings show that this procedure is indeed a simple way of preparing peptides with several disulfide bonds, if optimization of reaction conditions is performed in terms of redox buffer, temperature, and additives capable of disrupting aggregates and of stabilizing nascent secondary structures. Moreover, with increased knowledge about stable, small natural cystine frameworks, their use instead of artificial templates should facilitate engineering of synthetic miniproteins with specific conformation and tailored functions.