Unusual neurotoxic envenomations by Vipera aspis aspis snakes in France.

Vipera aspis aspis (V.a.a.) is the most dangerous poisonous snake in South-Eastern France. The clinical symptoms observed after V.a.a. envenomations involve mostly local signs (pain, edema) associated in the more severe cases with systemic symptoms (gastro-intestinal and cardiovascular manifestations). Since 1992, several unusual cases of moderate and severe 'neurotoxic' envenomations by V.a.a. snakes have been reported in a very localized area in South-Eastern France. Most of the human patients mainly suffered neurological signs owing to cephalic muscle paralysis. Drowsiness and dyspnea were observed for the most severe cases. Envenomed animals suffered respiratory distress and paralysis. The local signs were never as severe as observed after envenomations by vipers in other French regions. Human patients with moderate or severe clinical features received two intravenous injections of Viperfav antivenom, the first dose inducing the decrease of the neurological signs and the second reducing significantly the edema. Neurotoxic components immunologically cross-reacting with toxins from V. ammodytes ammodytes venom from Eastern Europe were detected in the blood of all patients suffering neurological symptoms after a V.a.a. bite. The protective efficacy of various antivenoms was evaluated in mice. The existence of geographical variations in the composition of V.a.a. venom emphasizes on the use of polyvalent antivenom in the treatment of viper envenomations in France.

Thermal stability of acetylcholinesterase from Bungarus fasciatus venom as investigated by capillary electrophoresis.

Previous studies on the conformation of the monomeric acetylcholinesterase (AChE) from the krait (Bungarus fasciatus) venom showed that the protein possesses a large permanent dipole moment. These studies predicted that thermal irreversible denaturation must occur via partially unfolded states. The thermal stability of Bungarus AChE was determined using capillary electrophoresis (CE) with optimized conditions. Runs performed at convenient temperature scanning rates provided evidence for an irreversible denaturation process according to the Lumry and Eyring model. The mid-transition temperature, T(m), and the effective enthalpy change, DeltaH(m) were determined at different pH. The temperature dependence of the free energy, DeltaG, of Bungarus AChE unfolding was drawn using values of T(m), DeltaH(m) and DeltaC(p) determined by CE. The thermodynamic parameters for the thermal denaturation of the monomeric snake enzyme were compared with those of different dimeric and tetrameric ChEs. It was shown that the changes in the ratio of DeltaH(cal/)DeltaH(vH) and DeltaC(p) reflect the oligomerization state of these proteins. All these results indicate that wild-type monomeric Bungarus AChE is a stable enzyme under standard conditions. However, designed mutants of this enzyme capable of degrading organophosphates have to be engineered to enhance their thermostability.

Absorption and elimination of viper venom after antivenom administration.

The mechanisms by which antivenom neutralizes the venom are still poorly understood. In the present work, we studied the effects of antivenom, constituted with either F(ab')2 or Fab, on the processes of absorption and elimination of Vipera aspis venom in experimentally envenomed rabbits. We first concluded from this study that during the few hours after intramuscular injection, the venom rapidly disappeared from the site of injection but did not immediately reach the vascular system, suggesting that it is partly absorbed via the lymphatic circulation. Concerning the elimination process of the venom in the presence of antivenom, we observed that the elimination of F(ab')2/venom complexes is slower than that of free venom in the absence of antivenom but faster than that of free F(ab')2, suggesting that F(ab')2/venom complexes are eliminated by phagocytosis. The Fab/venom complexes, on the other hand, are eliminated more slowly than free Fab. These complexes are not eliminated through the renal route in agreement with their high molecular weight. In addition, we observed that the treatment of envenomed rabbits with antivenom made of Fab, but not F(ab')2, is responsible for an oliguria that could be responsible for clinical problems.

Convulxin, a potent platelet-aggregating protein from Crotalus durissus terrificus venom, specifically binds to platelets.

Convulxin, a very potent aggregating protein from rattlesnake venom, was purified by a new procedure and its heterodimeric structure alpha 3 beta 3 was confirmed. The polypeptide N-terminal sequences of convulxin subunits were determined by Edman degradation. They are very similar and appear homologous to botrocetin from Bothrops jararaca venom and to rattlesnake lectin from Crotalus atrox venom, both being classified among the C-type lectin family. The binding of 125I-labelled convulxin to blood platelets has also been analysed under equilibrium conditions. These studies indicated that convulxin binds to platelets with a high affinity (Kd = 30 pM) on a small number of binding sites (1000 binding sites per cell). The high-affinity binding of convulxin appears specific to platelets, since it is not observed on other cell types such as neutrophils and erythrocytes. Also, the high-affinity binding of convulxin to membranes platelet is not inhibited by alpha-thrombin, fibrinogen, collagen, laminin binding inhibitor, RGDS peptide, adenosine diphosphate, platelet-activating factor-acether, serotonin or epinephrine. This, together with the recent observation that platelet activation by convulxin is partially mediated by phospholipase C and involves other mechanisms as well, indicates that convulxin may interact with a specific platelet acceptor (receptor) protein which has yet to be characterized.

Stimulation of early eosinophil progenitors by a heat stable alveolar macrophage product from ovalbumin-sensitized and non-sensitized guinea pigs.

BACKGROUND: Alveolar macrophages (AM) may participate in brochopulmonary hyper-reactivity by secreting cytokines that recruit mature eosinophils, or induce eosinophil production from recruited circulating progenitors. OBJECTIVE: To define whether AM products can contribute to lung eosinophil production in immunized guinea pigs (GP), by analysing the effect of AM culture supernatants (AM-SN) on in vitro eosinophilopoiesis. METHODS: Liquid and semi-solid bone marrow (BM) cultures were seeded with SN from 95% pure AM exposed to LPS. RESULTS: AM-SN increased very significantly the long-term viability, cell proliferation and eosinophil production in liquid culture and supported formation of eosinophil-bearing mixed colonies, by acting on progenitors depleted of mature eosinophils. The effect on eosinophil production was not duplicated by natural or recombinant sources of GM-CSF (which nevertheless supported GM colony formation by GP BM), not by rhIL-8 (which was active on GP cells) and was not due to residual LPS. FPLC separation of active AM SN yielded a peak of apparent m.w. 43 kDa, active on both liquid and semi-solid cultures. The active moiety was heat- and trypsin-resistant. Neutralizing monoclonal antibodies to hGM-CSF, mGM-CSF, hIL-3 and mIL-3 failed to deplete the activity in AM-SN. Ovalbumin immunization induced its production by AM even without LPS challenge. CONCLUSIONS: The lack of T lymphocytes among factor-producing AM, the properties of the active material, the inability of GM-CSF to reproduce these effects, and the failure of MoAbs to GM-CSF and to IL-3 to neutralize the activity indicate it is not due to the major eosinopoietic factors GM-CSF, IL-3 or IL-5.

The carboxy-terminal C2-like domain of the alpha-toxin from Clostridium perfringens mediates calcium-dependent membrane recognition.

The lethal, cytolytic alpha-toxin (phospholipase C) of Clostridium perfringens consists of two distinct modules: the larger N-terminal domain catalyses phospholipid hydrolysis, and its activity is potentiated by a smaller C-terminal domain. Calcium ions are essential for the binding of alpha-toxin to lipid films. Sixteen alpha-toxin variants with single amino acid substitutions in the C-terminal region were obtained using site-directed mutagenesis and T7 expression technology. Five of these variants showed reduced phospholipase C activity and were considerably less active than native alpha-toxin under calcium-limiting conditions. Replacement of Thr-272 by Pro diminished phospholipase C activity, severely affected haemolysis and platelet aggregation and perturbed a surface-exposed conformational epitope. The results of sequence comparisons and molecular modelling indicate that the C-terminal region probably belongs to the growing family of C2 beta-barrel domains, which are often involved in membrane interactions, and that the functionally important substitutions are clustered at one extremity of the domain. The combined findings suggest that the C-terminal region of alpha-toxin mediates interactions with membrane phospholipids in a calcium-dependent manner. Mutations to this domain may account for the natural lack of toxicity of the alpha-toxin homologue, phospholipase C of Clostridium bifermentans.

Acetylcholinesterase from Bungarus venom: a monomeric species.

The venom of Bungarus fasciatus, an Elapidae snake, contains a high level of AChE activity. Partial peptide sequences show that it is closely homologous to other AChEs. Bungarus venom AChE is a non-amphiphilic monomeric species, a molecular form of AChE which has not been previously found in significant levels in other tissues. The composition of carbohydrates suggests the presence of N-glycans of the 'complex' and 'hybrid' types. Ion exchange chromatography, isoelectric focusing and electrophoresis in non-denaturing and denaturing conditions reveal a complex microheterogeneity of this enzyme, which is partly related to its glycosylation.

Molecular structure and mechanism of action of the crotoxin inhibitor from Crotalus durissus terrificus serum.

An antivenom protein has been identified in the blood of the snake Crotalus durissus terrificus and proved to act by specifically neutralizing crotoxin, the main lethal component of rattlesnake venoms. The aim of this study was to purify the crotoxin inhibitor from Crotalus serum (CICS), and to analyze its mechanism of action. CICS has been purified from blood serum of the Crotalus snake by gel filtration on Sephadex G-200, ion-exchange chromatography on DEAE-Sephacel, and FPLC gel filtration on a Superose 12 column. It is an oligomeric glycoprotein of 130 kDa, made by the non-covalent association of 23-25-kDa subunits. Two different subunit peptides were identified by SDS/PAGE, however, their N-terminal sequences are identical. They are characterized by the absence of methionine residues and a high content of acidic, hydrophobic and cysteine residues. The neutralizing effect of purified CICS towards the neurotoxic effects of crotoxin has been demonstrated in vivo by lethality assays. CICS binds to the phospholipase subunit CB of crotoxin, but not to the acidic chaperon subunit CA; it efficiently inhibits the phospholipase activity of crotoxin and its isolated CB subunit and evokes the dissociation of the crotoxin complex. The molecular mechanism of the interaction between CICS and crotoxin seems to be very similar to that of crotoxin with its acceptor. It is, therefore, tempting to suggest that CICS acts physiologically as a false crotoxin acceptor that would retain the toxin in the vascular system, thus preventing its action on the neuromuscular system.

Antipeptide antibodies directed to the C-terminal part of ammodytoxin A react with the PLA2 subunit of crotoxin and neutralize its pharmacological activity.

Crotoxin and ammodytoxin A are snake venom neurotoxic phospholipases A2. Polyclonal antibodies against three synthetic peptides selected from the C-terminal part of the primary structure of ammodytoxin A were tested by ELISA for their interaction with crotoxin and its subunits, CA and CB. All three antipeptide antibodies reacted specifically with corresponding parts of ammodytoxin A and CB, either native or reduced. Conversely, polyclonal antibodies produced against ammodytoxin A and CB reacted strongly with all three peptides, suggesting that they constitute at least a part of natural epitopes in both proteins. All antipeptide antibodies reacted also with the corresponding peptides derived from CB by cyanogen bromide cleavage. The biological activity of the immune complexes was tested. No significant change in the enzymatic activity of CB, ammodytoxin A or crotoxin was observed with any of the three antipeptide antibodies. These antibodies were, however, able to protect mice against the lethal potency of CB and to prolong survival time of mice injected with crotoxin. These antipeptide antibodies were assayed in vitro for their protective effect against the action of CB or crotoxin on synaptosomes from Torpedo marmorata electric organ. They partly inhibited the acetylcholine release induced by both proteins. These results indicate that the C-terminal part of CB is likely to be involved in the pharmacological action of crotoxin.

Comparison of crotoxin isoforms reveals that stability of the complex plays a major role in its pharmacological action.

Crotoxin from the venom of the South American rattlesnake Crotalus durissus terrificus is a potent neurotoxin consisting of a weakly toxic phospholipase-A2 subunit (CB) and a non-enzymic, non-toxic subunit (CA). Crotoxin complex (CACB) dissociates upon interaction with membranes: CB binds while CA does not. Moreover, CA enhances the toxicity of CB by preventing its non-specific adsorption. Several crotoxin isoforms have been identified. Multiple variants of each subunit give different crotoxin complexes that can be subdivided into two classes: those of high toxicity and low enzymic activity and those of moderate toxicity and a high phospholipase-A2 activity. In this study, we demonstrate that the more-toxic isoforms block neuromuscular transmission of chick biventer cervicis preparations more efficiently than weakly toxic isoforms. The less-toxic crotoxin complexes have the same Km and Vmax as CB alone. In contrast, the more-toxic isoforms are enzymically less active than CB. These differences correlate with the stability of the complexes: less-toxic isoforms are less stable (Kd = 25 nM) and dissociate rapidly (half-life about 1 min), whereas the more-toxic isoforms are more stable (Kd = 4.5 nM) and dissociate more slowly (half-life 10-20 min). The rate of interaction of crotoxin complexes with vesicles of negatively charged phospholipids paralleled the rate of dissociation of the complexes in the absence of vesicles. The differences of pharmacological and biochemical properties of crotoxin isoforms indicate that the stability of crotoxin complexes plays a major role in the synergistic action of crotoxin subunits: a stronger association between the two crotoxin subunits would account for their slower dissociation rate, a weaker enzymic activity, a slower interaction with phosphatidylglycerol vesicles, a faster blockade of neuromuscular transmission and a higher lethal potency.

Snake-venom phospholipase A2 neurotoxins. Potentiation of a single-chain neurotoxin by the chaperon subunit of a two-component neurotoxin.

The venoms from Crotalinae and Viperinae snakes contain only two kinds of phospholipase A2 neurotoxins (beta-neurotoxins): single-chain beta-neurotoxins, such as agkistrodotoxin and ammodytoxin-A, and dimeric beta-neurotoxins, which, in the case of the best studied ones, crotoxin-like toxins, consist of the non-covalent association of a phospholipase A2 (CB) and a non-enzymatic chaperon (CA). Possible evolutionary relationships of these beta-neurotoxins have been investigated by analyzing whether CA could behave as a chaperon toward agkistrodotoxin and ammodytoxin, as it does in the crotoxin complex. CA increased the lethal potency of agkistrodotoxin and modified its pharmacological effect on Torpedo synaptosomes. Sedimentation experiments proved that CA can form an heterocomplex with agkistrodotoxin. Agkistrodotoxin prevented the binding to CA of an anti-CA mAb which recognizes an epitope at the zone of interaction between crotoxin subunits, suggesting the association of CA and agkistrodotoxin implicated the same zone. A 10-fold molar excess of CA over ammodytoxin modified the effect of ammodytoxin on acetylcholine release but did not increase the lethal potency of ammodytoxin. Sedimentation experiments showed CA and ammodytoxin can form an heterocomplex which is less stable than CA.agkistrodotoxin. Ammodytoxin A did not compete with the anti-CA mAb. These observations are in good agreement with the sequence similarities between CB and agkistrodotoxin (80%) and ammodytoxin A (60%).

Immunochemical analysis of a snake venom phospholipase A2 neurotoxin, crotoxin, with monoclonal antibodies.

Crotoxin is the major neurotoxic component of the venom of the South American rattlesnake, Crotalus durissus terrificus. The crotoxin molecule is composed of two subunits: a basic and weakly toxic phospholipase A2 (PLA2) called component-B (CB), and an acidic, nonenzymatic and nontoxic subunit called component-A (CA). Crotoxin exists as a mixture of several isoforms (or variants) resulting from the association of several subunit isoforms. We prepared monoclonal antibodies (MAbs) against each isolated subunit. Six anti-CA MAbs and eight anti-CB MAbs were tested for their cross-reactivities with each subunit and with other toxic and nontoxic PLA2s. Four of the six anti-CA MAbs cross-reacted with CB, whereas only one of the eight anti-CB MAbs cross-reacted with CA. Two anti-CB MAbs were found to cross-react with agkistrodotoxin, a single chain neurotoxic PLA2 purified from the venom of Agkistrodon blomhoffii brevicaudus. We determined the dissociation constants of each MAb for CA and CB isoforms and their capacities to neutralize the lethality and to inhibit the catalytic activity of crotoxin. We defined three epitopic regions on CA and four on CB, and used a schematic representation of the two subunits to characterize these epitopic regions with respect to: (1) the "toxic" and the "catalytic" sites of CB, and (2) the zone of interaction between the two subunits. We propose three-dimensional structures of the crotoxin subunits in which we localize amino acid residues that might be involved in the epitopic regions described here.

Multiplicity of acidic subunit isoforms of crotoxin, the phospholipase A2 neurotoxin from Crotalus durissus terrificus venom, results from posttranslational modifications.

Crotoxin, the major toxin of the venom of the South American rattlesnake, Crotalus durissus terrificus, is made of two subunits: component B, a basic and weakly toxic phospholipase A2, and component A, an acidic and nontoxic protein that enhances the lethal potency of component B. Crotoxin is a mixture of isoforms that results from the association of several isoforms of its two subunits. In the present investigation, we have purified four component A isoforms that, when associated with the same purified component B isoform, produced different crotoxin isoforms, all having the same specific enzymatic activity and the same lethal potency. We further determined by Edman degradation the polypeptide sequences of these four component A isoforms. They are made of three disulfide-linked polypeptide chains (alpha, beta, and gamma) that correspond to three different regions of a phospholipase A2 precursor. We observed that the polypeptide sequences of the various component A isoforms all agree with the sequence of an unique precursor. The differences between the isoforms result first by differences in the length of the various chains alpha and beta, indicating that component A isoforms are generated from the proteolytic cleavage of the component A precursor at very close sites, possibly by the combined actions of endopeptidases and exopeptidases, and second by the possible cyclization of the alpha-NH2 of the N-terminal glutamine residue of chains beta and gamma. These observations indicate that the component A isoforms are the consequence of different posttranslational events occurring on an unique precursor, rather than the expression of different genes.

Binding of divalent and trivalent cations with crotoxin and with its phospholipase and its non-catalytic subunits: effects on enzymatic activity and on the interaction of phospholipase component with phospholipids.

We have studied the interaction of divalent and trivalent with a potent phospholipase A(2) neurotoxin, crotoxin, from Crotalus durissus terrificus venom. The pharmacological action of crotoxin requires dissociation of its catalytic subunit (component B) and of its non-enzymatic chaperone subunit (component A), then the binding of the phospholipase subunit to target sites on cellular membranes and finally phospholipid hydrolysis. In this report, we show that the phospholipase A(2) activity of crotoxin and of component B required Ca2+ and that other divalent cations (Sr2+, Cd2+ and Ba2+) and trivalent lanthanide ions are inhibitors. The lowest phospholipase A(2) activity was observed in the presence of Ba2+, which proved to be a competitive inhibitor of Ca2+. The binding of divalent cations and trivalent lanthanide ions to crotoxin and to its subunits has been examined by equilibrium dialysis and by spectrofluorimetric methods. We found that crotoxin binds two divalent cations per mole with different affinities; the site presenting the highest affinity (K(d) in the mM range) in involved in the activation (or inhibition) of the phospholipase A(2) activity and must therefore be located on component B, the other site (K(d) higher than 10 mM) is probably localized on component A and does not play any role in the catalytic activity of crotoxin. We also observed that crotoxin component B binds to vesicular and micellar phospholipids, even in the absence of divalent cations. The affinity of this interaction either does not change or else increases by an order of magnitude in the presence of divalent cations.

Binding of crotoxin, a presynaptic phospholipase A2 neurotoxin, to negatively charged phospholipid vesicles.

Crotoxin, isolated from the venom of Crotalus durissus terrificus, is a potent neurotoxin consisting of a basic and weakly toxic phospholipase A2 subunit (component B) and an acidic nonenzymatic subunit (component A). The nontoxic component A enhances the toxicity of the phospholipase subunit by preventing its nonspecific adsorption. The binding of crotoxin and of its subunits to small unilamellar phospholipid vesicles was examined under experimental conditions that prevented any phospholipid hydrolysis. Isolated component B rapidly bound with a low affinity (Kapp in the millimolar range) to zwitterionic phospholipid vesicles and with a high affinity (Kapp of less than 1 microM) to negatively charged phospholipid vesicles. On the other hand, the crotoxin complex did not interact with zwitterionic phospholipid vesicles but dissociated in the presence of negatively charged phospholipid vesicles; the noncatalytic component A was released into solution, whereas component B remained tightly bound to lipid vesicles, with apparent affinity constants from 100 to less than 1 microM, according to the chemical composition of the phospholipids. On binding, crotoxin or its component B caused the leakage of a dye entrapped in vesicles of negatively charged but not of zwitterionic phospholipids. The selective binding of crotoxin suggests that negatively charged phospholipids may constitute a component of the acceptor site of crotoxin on the presynaptic plasma membrane.

Crotoxin, half-century of investigations on a phospholipase A2 neurotoxin.

Crotoxin, the major toxic component of the South American rattlesnake, Crotalus durissus terrificus, is a neurotoxic phospholipase A2 which exerts its pathophysiological action by blocking the neuromuscular transmission. Crotoxin acts primarily by altering the acetylcholine release from the nerves terminals through a mechanism which has not yet been elucidated. It also acts on postsynaptic membranes by stabilizing the acetylcholine receptor in an inactive conformation very similar to the desensitized state. Crotoxin is made of two dissimilar subunits: a basic and weakly toxic phospholipase A2 component-B, and an acidic and non toxic component-A which does not possess any enzymatic activity. Binding experiments showed that crotoxin subunits dissociate when crotoxin interacts with biological membranes: Component-B binds, whereas component-A appears free in solution. The phospholipase A2 subunit binds in a non saturable, non specific manner, on any kind of biological membranes, whereas in the presence of component-A it interacts only with a limited number of high affinity binding sites present on synaptic membranes but not on erythrocyte membranes. Although the target site (acceptor) of crotoxin has not yet been formally identified, binding experiments carried out with small unilamellar phospholipid vesicles of different compositions indicate that some negatively charged phospholipids like mono and diphosphoinositide phosphates might be an important component of crotoxin acceptor site. Crotoxin is in fact a mixture of several isoforms which have very similar but not identical polypeptide sequences. An individual Crotalus durissus terrificus snake is able to synthesize several crotoxin isoforms which may result of the expression of several isogenes and/or of post-translational events. When compared in quantitative manner, the crotoxin isoforms slightly but significantly differ in their enzymatic and pharmacological properties. Finally, immunochemical investigations carried out with polyclonal antibodies prepared against both crotoxin subunits, showed that non precipitating anti-component-B- antibodies (Fab) inhibit the phospholipase A2 activity of crotoxin and neutralize its lethal potency, suggesting that the catalytic and toxic sites of crotoxin are closely related.

Crotoxin, half-century of investigations on a phospholipase A2 neurotoxin.

Crotoxin, the major toxic component of the South American rattlesnake, Crotalus durissus terrificus, is a neurotoxic phospholipase A2 which exerts its pathophysiological action by blocking the neuromuscular transmission. Crotoxin acts primarily by altering the acetylcholine release from the nerves terminals through a mechanism which has not yet been elucidated. It also acts on postsynaptic membranes by stabilizing the acetylcholine receptor in an inactive conformation very similar to the desensitized state. Crotoxin is made of two dissimilar subunits: a basic and weakly toxic phospholipase A2 component-B, and an acidic and non toxic component-A which does not possess any enzymatic activity. Binding experiments showed that crotoxin subunits dissociate when crotoxin interacts with biological membranes: Component-B binds, whereas component-A appears free in solution. The phospholipase A2 subunit binds in a non saturable, non specific manner, on any kind of biological membranes, whereas in the presence of component-A it interacts only with a limited number of high affinity binding sites present on synaptic membranes but not on erythrocyte membranes. Although the target site (acceptor) of crotoxin has not yet been formally identified, binding experiments carried out with small unilamellar phospholipid vesicles of different compositions indicate that some negatively charged phospholipids like mono and diphosphoinositide phosphates might be an important component of crotoxin acceptor site. Crotoxin is in fact a mixture of several isoforms which have very similar but not identical polypeptide sequences. An individual Crotalus durissus terrificus snake is able to synthesize several crotoxin isoforms which may result of the expression of several isogenes and/or of post-translational events. When compared in quantitative manner, the crotoxin isoforms slightly but significantly differ in their enzymatic and pharmacological properties. Finally, immunochemical investigations carried out with polyclonal antibodies prepared against both crotoxin subunits, showed that non precipitating anti-component-B- antibodies (Fab) inhibit the phospholipase A2 activity of crotoxin and neutralize its lethal potency, suggesting that the catalytic and toxic sites of crotoxin are closely related.

The interaction between the presynaptic phospholipase neurotoxins beta-bungarotoxin and crotoxin and mixed detergent-phosphatidylcholine micelles. A comparison with non-neurotoxic snake venom phospholipases A2.

Certain phospholipase A2 enzymes (E.C.3.1.1.4) selectively inhibit neurotransmitter release from cholinergic nerve terminals. Both specific acceptor proteins and the physical state of nerve terminal phospholipids have been implicated in studies of the mechanism of phospholipase neurotoxin action. Here we have examined the effects of charge on a micellar phospholipid substrate by comparing the enzyme activity and binding of two neurotoxic phospholipases (beta-bungarotoxin and crotoxin) with other non-neurotoxic phospholipases. This has been achieved by altering either the phospholipid or the ionic charge of the detergent in the mixed phospholipid micelle. The neurotoxic phospholipases were only active on negatively charged micelles, whereas the non-neurotoxic enzymes were equally active in hydrolyzing neutral micelles. This distinction was also reflected in binding studies; the non-neurotoxic phospholipases bound to both types of substrate, whereas beta-bungarotoxin and crotoxin selectively bound to negatively charged micellar structures. These experiments suggest that, in addition to the existence of any specific acceptor proteins, neurotoxin binding is also governed by the charge on the lipid phase of the nerve terminal membrane.