An agonist of CXCR4 induces a rapid recovery from the neurotoxic effects of Vipera ammodytes and Vipera aspis venoms.

People bitten by Alpine vipers are usually treated with antivenom antisera to prevent the noxious consequences caused by the injected venom. However, this treatment suffers from a number of drawbacks and additional therapies are necessary. The venoms of Vipera ammodytes and of Vipera aspis are neurotoxic and cause muscle paralysis by inducing neurodegeneration of motor axon terminals because they contain a presynaptic acting sPLA2 neurotoxin. We have recently found that any type of damage to motor axons is followed by the expression and activation of the intercellular signaling axis consisting of the CXCR4 receptor present on the membrane of the axon stump and of its ligand, the chemokine CXCL12 released by activated terminal Schwann cells. We show here that also V. ammodytes and V. aspis venoms cause the expression of the CXCL12-CXCR4 axis. We also show that a small molecule agonist of CXCR4, dubbed NUCC-390, induces a rapid regeneration of the motor axon terminal with functional recovery of the neuromuscular junction. These findings qualify NUCC-390 as a promising novel therapeutics capable of improving the recovery from the paralysis caused by the snakebite of the two neurotoxic Alpine vipers.

Comparative electrophysiological characterization of ammodytoxin A, a ß-neurotoxin from the nose-horned viper venom, and its enzymatically inactive mutant.

Presynaptic- or ß-neurotoxicity of secreted phospholipases A2 (sPLA2) is a complex process. For full expression of ß-neurotoxicity, the enzymatic activity of the toxin is essential. However, it has been shown that not all toxic effects of a ß-neurotoxin depend on its enzymatic activity, for example, the inhibition of mitochondrial cytochrome c oxidase. The main objective of this study was to verify whether it is possible to observe and study the phospholipase-independent actions of ß-neurotoxins by a standard ex vivo twitch-tension experimental approach. To this end, we compared the effects of a potent snake venom ß-neurotoxin, ammodytoxin A (AtxA), and its enzymatically inactive mutant AtxA(D49S) on muscle contraction of the mouse phrenic nerve-hemidiaphragm preparation. While AtxA significantly affected the amplitude of the indirectly evoked isometric muscle contraction, the resting tension of the neuromuscular (NM) preparation, the amplitude of the end-plate potential (EPP), the EPP half decay time and the resting membrane potential, AtxA(D49S) without enzymatic activity did not. From this, we can conclude that the effects of AtxA independent of enzymatic activity cannot be studied with classical electrophysiological measurements on the isolated NM preparation. Our results also suggest that the inhibition of cytochrome c oxidase activity by AtxA is not involved in the rapid NM blockade by this ß-neurotoxin, but that its pathological consequences are rather long-term. Interestingly, in our experimental setup, AtxA upon direct stimulation reduced the amplitude of muscle contraction and induced contracture of the hemidiaphragm, effects that could be interpreted as myotoxic.

Genetic interactions between a phospholipase A2 and the Rim101 pathway components in S. cerevisiae reveal a role for this pathway in response to changes in membrane composition and shape.

Modulating composition and shape of biological membranes is an emerging mode of regulation of cellular processes. We investigated the global effects that such perturbations have on a model eukaryotic cell. Phospholipases A(2) (PLA(2)s), enzymes that cleave one fatty acid molecule from membrane phospholipids, exert their biological activities through affecting both membrane composition and shape. We have conducted a genome-wide analysis of cellular effects of a PLA(2) in the yeast Saccharomyces cerevisiae as a model system. We demonstrate functional genetic and biochemical interactions between PLA(2) activity and the Rim101 signaling pathway in S. cerevisiae. Our results suggest that the composition and/or the shape of the endosomal membrane affect the Rim101 pathway. We describe a genetically and functionally related network, consisting of components of the Rim101 pathway and the prefoldin, retromer and SWR1 complexes, and predict its functional relation to PLA(2) activity in a model eukaryotic cell. This study provides a list of the players involved in the global response to changes in membrane composition and shape in a model eukaryotic cell, and further studies are needed to understand the precise molecular mechanisms connecting them.

Size of silk fibroin ß-sheet domains affected by Ca2.

In the search for suitable scaffold materials for tissue regeneration, silk fibroin has become one of the most promising candidates due to its biocompatibility and good physical properties. To facilitate bone formation in osteochondral defects, it is often combined with a bone promoting additive. Here we demonstrate using HRTEM analysis how the release of Ca2+ ions from bioactive glass or Ca-salts results in the reduction of ß-sheet domain size that effectively controls a scaffold's properties, such as degradation and mechanical stiffness. We show that these changes already occur in silk fibroin solution prior to scaffold preparation and are caused by a decrease in zeta potential that forces fibroin molecules into tighter packing resulting in higher scaffold crystallinity, smaller ß-sheet domains and higher interconnectivity. The reduction of ß-sheet domains improves the elastic modulus and allows faster degradation despite the higher crystallinity. Ca2+ was also shown to be beneficial to the formation of hydroxy-apatite sheets on the fibroin surface.

Primary structure of ammodytoxin C further reveals the toxic site of ammodytoxin.

The sequence of ammodytoxin C, a presynaptically toxic, basic phospholipase A2 of Vipera ammodytes ammodytes venom was determined. The toxin differs only in two amino acid residues from the most toxic isotoxin ammodytoxin A and is 18-times less lethal. Ammodytoxin B which is 30-times less lethal than ammodytoxin A differs from it only in three amino acid residues. From the three-dimensional model of ammodytoxin A, it can be seen that mutated regions of ammodytoxin B and ammodytoxin C are on the surface, and relatively distant from each other. The observed decrease in toxicity of ammodytoxin C could be a consequence of changed charge in position 128 where a Lys is exchanged for Glu. The resulting change in electrostatic properties of the molecule which influences the orientation of the molecule during the approach to the charged nerve-terminal membrane might be responsible for the observed decrease in toxicity.

Isolation, partial characterization and complete amino acid sequence of the toxic phospholipase A2 from the venom of the common viper, Vipera berus berus.

A basic, toxic phospholipase A2 was purified from the venom of Vipera berus berus (Vbb) by a single purification step, using hydrophobic chromatography. The primary structure of isolated protein was established from peptides generated by Gly-specific papaya proteinase IV, beta-trypsin, CNBr and mild acid hydrolysis. The enzyme consists of a single chain of 122 amino acid residues with 14 Cys in positions characteristic for the phospholipase A2 subgroup IIA. As far as we know, this is the first complete Vipera berus phospholipase A2 amino acid sequence reported.

Stoichiometry and heterogeneity of the pro-region chain in tetrameric human cathepsin C.

The subunit structure and composition of mature human cathepsin C, an oligomeric cysteine proteinase, has been characterised in detail. The heavy chain, light chain and pro-region peptides are shown to be held together solely by non-covalent interactions, and to be present in equimolar ratio, suggesting an important structural role for the residual pro-region chain which is strongly bound to the enzyme. The mass of the light chain, as determined by mass spectrometry, combined with its N-terminal sequence, determines the position of cleavage from the heavy chain. Amino-acid sequencing has led to definition of the 13.5 kDa N-terminal part of the pro-region which remains in the mature enzyme, the C-terminal moiety of 10 kDa being cleaved out and lost from the pro-peptide on activation. The residual pro-region is heterogeneous, a proportion being intact and the remainder being cleaved at alternative positions 58 or 61, yielding two smaller peptides joined by disulphide bond. The proportion of cleaved form was found to vary with tissue and enzyme preparation but did not affect enzyme activity. The molecular masses of the constituent chains after deglycosylation lead to a protein mass of 158 kDa. All four potential glycosylation sites are glycosylated.

Monoclonal antibodies to human stefin B and determination of their epitopes.

Monoclonal antibodies (MAbs) to human stefin B were developed and three of them were characterised. Stefin B was cleaved into four peptides which were later subfragmented to smaller peptides. Only two peptides, of 24 and 30 amino acids, could bind to MAbs. In one instance, two peptides that were not consecutive in the sequence were recognised by the same antibody, proving that the epitope was discontinuous. Location of the epitopes was further narrowed by measuring the binding of MAbs to the complex of stefin B with papain. A sandwich ELISA (enzyme-linked immunosorbent assay), which measures the concentration of free inhibitor, was developed. It confirms that two out of three MAbs bind to different sites of stefin B. On the basis of the crystal structure of complex of stefin B with papain, the surface, accessible to a sphere with a radius of 5 A which simulates the accessibility of variable regions of antibody was determined. From the difference between accessibilities of free stefin B and stefin B in complex, the epitope location was determined more accurately.

Primary and secondary structure of a pore-forming toxin from the sea anemone, Actinia equina L., and its association with lipid vesicles.

The complete amino acid sequence of equinatoxin II, a potent pore-forming toxin with hemolytic, cytotoxic and cardiotoxic activity from the venom of the sea anemone, Actinia equina L., is reported. In addition, circular dicroism was used to estimate the secondary structure of this toxin either in the water-soluble or in the membrane-anchored form. Equinatoxin II when in water was found to contain about 29-33% of alpha-helical structure, 53-58% of beta-strand+beta-turn and 10-16% of random structure. Upon association with phospholipids, in particular with sphingomyelin, a rearrangement of the secondary structure occurs resulting in an increase of the alpha-helix content. An amphiphilic alpha-helical segment is predicted at the N-terminus, which shares structural homology with membrane active peptides like melittin and viral fusion peptides. In analogy to the behaviour of these peptides we propose that at least part of the alpha-helix content increase of equinatoxin II is due to the insertion of its N-terminus into the lipid bilayer. As in the case of melittin, association of 3-4 equinatoxin molecules is necessary to induce membrane permeabilisation.

The complete primary structure of bovine stefin B.

A new stefin B-type low-Mr CPI was isolated from bovine thymus and subjected to structural analysis. The inhibitor consisted of 98 amino acids and its Mr was calculated to be 11,178. The NH2-terminal amino acid residue was blocked. The sequence was determined by automated sequencing of peptides derived by cleavage with cyanogen bromide and fragments of the inhibitor resulting from enzymatic digestion with beta-trypsin and Staphylococcus aureus V-8 proteinase. The NH2-terminal blocking group was established with mass spectrometry. The inhibitor exhibits considerable sequence homology with inhibitors from the stefin family. Furthermore, a highly conserved QVVAG region within the stefin family is for the first time replaced by the QLVAG sequence.

Differences in specificity for the interactions of stefins A, B and D with cysteine proteinases.

Four different stefin-type cysteine proteinase inhibitors have been isolated from porcine thymus and skin. Amino acid sequence determination revealed the presence of stefin A and stefin B type inhibitors and two new inhibitors, designated as porcine stefin D1 and stefin D2. Stefin D1 was identified as PLCPI, an inhibitor recently characterized from porcine polymorphonuclear leukocytes [Lenarcic et al. (1993) FEBS Lett. 336, 289-292]. Stefin A is composed of 101 amino acids and has an Mr of 11 391 while stefin B contains 98 amino acids, has an Mr of 11 174 and is N-terminally blocked. All inhibitors were found to be fast-acting inhibitors of papain, cathepsin L and cathepsin S (Ki = 0.009-0.161 nM). Stefins A and B also bind tightly and rapidly to cathepsin H (Ki = 0.027 and 0.069 nM, respectively), while stefins D1 and D2 have been shown to be very poor inhibitors of cathepsin H (Ki = 102-150 nM). The decreased affinity of these inhibitors toward cathepsin B (Ki = 2-1700 nM) was shown to be mainly due to the low second order association rate constants. The presence of a highly negatively charged N-terminus on stefin D1 constitutes a likely structural determinant of inhibitor specificity.

The primary structure of inhibitor of cysteine proteinases from potato.

The complete amino acid sequence of the cysteine proteinase inhibitor from potato tubers was determined. The inhibitor is a single-chain protein having 180 amino acid residues. Its primary structure was elucidated by automatic degradation of the intact protein and sequence analysis of peptides generated by CNBr, trypsin and glycyl endopeptidase. A search through the protein sequence database showed homology to other plant proteinase inhibitors of different specificities and non-inhibitory proteins of M(r) around 20,000. On the basis of sequence homology, prediction of secondary structure and fold compatibility, based on a 3D-1D score to the three-dimensional profile of Erythrina caffra trypsin inhibitor, we suggest that the potato cysteine proteinase inhibitor belongs to the superfamily of proteins that have the same pattern of three-dimensional structure as soybean trypsin inhibitor. This superfamily would therefore include proteins that inhibit three different classes of proteinases-serine, cysteine and aspartic proteinases.

Expression of fully active ammodytoxin A, a potent presynaptically neurotoxic phospholipase A2, in Escherichia coli.

A cDNA encoding the most presynaptically neurotoxic phospholipase A2, ammodytoxin A, from the venom of the long-nosed viper (Vipera ammodytes ammodytes) has been expressed in Escherichia coli. Ammodytoxin A was produced as a fusion protein with the 81 N-terminal residues of adenylate kinase followed by the tetrapeptide recognition site for factor Xa (IEGR) just preceding the first amino acid residue of the toxin. The fusion protein was expressed under the control of tac promoter without IPTG induction in the form of insoluble inclusion bodies. It was dissolved in guanidine hydrochloride, S-sulfonated and refolded in a reoxidation mixture including a reduced/oxidized glutathione redox couple. Ammodytoxin A was fully activated by limited hydrolysis with trypsin that preferentially cleaves the fusion protein at the factor Xa recognition site and purified by cation-exchange chromatography. The correct N-terminus was confirmed by protein sequencing. Recombinant ammodytoxin A has been proved to be indistinguishable from the native toxin in its enzymatic activity and toxicity.

The amino acid sequence of a novel inhibitor of cathepsin D from potato.

The amino acid sequence of a cathepsin D inhibitor isolated from potato is described. It was determined by analysis of peptides generated by use of the glycine-specific proteinase PPIV. The order of the peptides was established by examination of tryptic peptides derived from the two cyanogen bromide peptides. The inhibitor comprises 187 amino acid residues, and has a calculated Mr of 20,450.

Neuronal receptors for phospholipases A(2 )and beta-neurotoxicity.

Some phospholipases A(2) interrupt neuromuscular communication by blocking the release of neurotransmitter into the synaptic cleft. Despite numerous studies, the molecular mechanism of their action is still largely obscure. In this review the best-characterized receptors for beta-neurotoxins are presented. We propose a model which could be useful in investigating the apparent inconsistency between the observed heterogeneity in the neuronal binding of beta-neurotoxins and the very similar pathomorphological and electrophysiological effects which they produce in the intoxicated tissue. We assume that beta-neurotoxins enter the nerve ending to exert their toxic effect. The model involves different pathways for phospholipase A(2) neurotoxins to reach the site of action inside the neuron, their respective extra- and intracellular neuronal receptors being key features of the pathway. Once in the nerve cell, beta-neurotoxins impair the function of the synaptic vesicles by phospholipid hydrolysis of the inner leaflet of the vesicle bilayer. The proportion of the products of the phospholipid hydrolysis, lysophospholipids and phospholipids in the membrane, has been demonstrated to be very important for the shaping of the membrane, affecting its fusogenic properties. Due to the same final step in the action of beta-neurotoxins, phospholipid hydrolysis, the consequences of their poisoning are practically identical.

Ammodytoxin A acceptor in bovine brain synaptic membranes.

Ammodytoxin A, the presynaptic neurotoxin from Vipera ammodytes ammodytes venom, was found to bind specifically and with high affinity to bovine cortex synaptic membrane preparation. The detected ammodytoxin A high-affinity binding was characterized by equilibrium binding analysis which revealed a single high-affinity binding site with Kd 4.13 nM and Bmax 6.67 pmoles/mg of membrane protein. 125I-ammodytoxin A was covalently cross-linked to its neuronal acceptor using a chemical cross-linking technique. As revealed by subsequent SDS-PAGE analysis and autoradiography, 125I-ammodytoxin A specifically attached to membrane components with apparent mol. wts 53,000-56,000. Besides by the native ammodytoxin A, the binding of radioiodinated ammodytoxin A to the neuronal acceptor was highly attenuated, also by other two iso-neurotoxins from V. a. ammodytes venom, ammodytoxins B and C, and neurotoxin crotoxin B from the venom of the South American rattlesnake (Crotalus durissus terrificus). Vipera berus berus phospholipase A2 was a weaker inhibitor, whereas nontoxic phospholipase A2, ammodytoxin I2 and myotoxic phospholipase A2 homologue, ammodytin L, both from V. a. ammodytes venom as well, were very weak inhibitors. No inhibitory effect on 125I-ammodytoxin A specific binding at all was, however, obtained with alpha-dendrotoxin, beta-bungarotoxin and crotoxin A, respectively. Treatment of synaptic membranes with proteinase K and Staphylococcus aureus V-8 proteinase, a combination of PNGase F and neuroaminidase, heat or acid lowered the 125I-ammodytoxin A specific binding to various extents but never completely abolished it. The ammodytoxin A binding site in bovine synaptic membranes is thus most likely a combination of membrane glycoprotein acceptor and membrane phospholipids. As ammodytoxin A reduced the second negative component of the perineural waveform, measured on mouse triangularis sterni preparation, which is very likely a result of an inhibition of a fraction of the terminal K+ currents, the ammodytoxin A acceptor could well be connected with K+ channels.

Re-examination of crotoxin-membrane interactions.

The interaction of crotoxin with synaptic membranes from Torpedo marmorata has been re-examined, using radioiodinated toxin. In competition experiments, the 'saturable binding' is usually calculated by subtracting the non-saturable binding, determined in the presence of an excess of unlabelled crotoxin, from total binding. Paradoxically, we observed a notable increase of the 'saturable binding' of 125I-crotoxin, defined in this manner in the presence of a high concentration of certain competitors (e.g. crotoxin subunit B, agkistrodotoxin, ammodytoxin and ammodytin I2). This potentiation effect was analysed by competition and cross-linking experiments. The dissociation of the basic crotoxin subunit CB, which differs markedly from crotoxin in its membrane-binding characteristics, was found to be the main reason for the observed phenomenon. 125I-CB could be released from 125I-crotoxin by exchange with a molecule having sufficient affinity towards CA (e.g. CB or agkistrodotoxin) or it could be dissociated from the specific crotoxin membrane-binding site(s) by a competitor molecule. Our results, therefore, suggest a reinterpretation of previous 125I-crotoxin binding studies.

Equinatoxins, pore-forming proteins from the sea anemone Actinia equina, belong to a multigene family.

The multigene family of equinatoxins, pore-forming proteins from sea anemone Actinia equina, has been studied at the protein and gene levels. We report the cDNA sequence of a new, sphingomyelin inhibited equinatoxin, EqtIV. The N-terminal sequences of natural Eqt I and III were also determined, confirming two isoforms of EqtI, differing at position 13. The number of Eqt genes determined by Southern blot hybridization was found to be more than five, indicating that Eqts belong to a multigene family.

Partial primary structure of a fibrinogenase from the venom of the snake Lachesis stenophrys.

The partial primary structure of an Mr 24,000 non-haemorrhagic metalloproteinase isolated from the venom of the snake Lachesis stenophrys has been determined. The native proteinase was resistant to Edman degradation exhibiting the N-terminal blockade. The pyridylethylated or native proteinase was chemically and enzymatically fragmented and the obtained peptides were separated by gel or reversed-phase chromatography, and sequenced. The metalloproteinase from Lachesis stenophrys contains a putative zinc-chelating sequence HELGHNLGMKH, characteristic for the reprolysin family of zinc-metalloproteinases. It contains six cysteine residues in the standard positions for this group of proteins suggesting the same disulfide bonding. Interestingly, it has almost identical sequence as the metalloproteinase from Lachesis muta muta, LHF-II, which is, however, haemorrhagic. The main structural differences between the two molecules were found in their N-terminal parts and in glycosylation. As the substrate-binding regions of both proteinases are practically identical, we suggest that the absence of haemorrhagicity in Lachesis stenophrys enzyme is due to its lower affinity for the matrix proteins and not due to different substrate specificity.

The sensing of membrane microdomains based on pore-forming toxins.

Membrane rafts are transient and unstable membrane microdomains that are enriched in sphingolipids, cholesterol, and specific proteins. They are involved in intracellular trafficking, signal transduction, pathogen entry, and attachment of various ligands. Increasing experimental evidence on the crucial biological roles of membrane rafts under normal and pathological conditions require new techniques for their structural and functional characterization. In particular, fluorescence-labeled cytolytic proteins that interact specifically with molecules enriched in rafts are of increasing interest. Cholera toxin subunit B interacts specifically with raft-residing ganglioside G(M1), and it has long been the lipid probe of choice for membrane rafts. Recently, four new pore-forming toxins have been proposed as selective raft markers: (i) equinatoxin II, a cytolysin from the sea anemone Actinia equina, which specifically recognizes free and membrane-embedded sphingomyelin; (ii) a truncated non-toxic mutant of a cytolytic protein, lysenin, from the earthworm Eisenia foetida, which specifically recognizes sphingomyelin-enriched membrane domains; (iii) a non-toxic derivative of the cholesterol-dependent cytolysin perfringolysin O, from the bacterium Clostridium perfringens, which selectively binds to membrane domains enriched in cholesterol; and (iv) ostreolysin, from the mushroom Pleurotus ostreatus, which does not bind to a single raft-enriched lipid component, but requires a specific combination of two of the most important raft-residing lipids: sphingomyelin and cholesterol. Nontoxic, raft-binding derivatives of cytolytic proteins have already been successfully used to explore both the structure and function of membrane rafts, and of raft-associated molecules. Here, we review these four new derivatives of pore-forming toxins as new putative markers of these membrane microdomains.