Evelyne Benoit

Riluzole specifically blocks inactivated Na channels in myelinated nerve fibre

The effects of 0.15–250 μM riluzole, a novel psychotropic agent with anticonvulsant properties, were studied on voltage-clamped nodes of Ranvier of isolated nerve fibres of the frog. When added to the external solution, the drug rapidly and reversibly inhibited both K and Na currents with an apparent dissociation constant of 0.09 mM. The riluzole-induced decrease of these currents was not “use-dependent”. At concentrations up to 100μM, the drug had no noticeable effect on the time course of Na current inactivation nor on the shape and the position along voltage axis of the Na conductance/voltage relationship. On the other hand, it induced substantial shifts towards negative voltages of the steady-state Na inactivation/voltage curve. From these results, according to the modulated-receptor model, an apparent dissociation constant of 0.29 μM could be calculated for riluzole-induced blockage of inactivated Na channels. The recovery from Na current inactivation was also affected by the drug. It is concluded that riluzole is a highly specific blocker of inactivated Na channels, which is more than 300 times more effective on these channels than on K or resting Na channels.

Structural determinants in phycotoxins and AChBP conferring high affinity binding and nicotinic AChR antagonism

Spirolide and gymnodimine macrocyclic imine phycotoxins belong to an emerging class of chemical agents associated with marine algal blooms and shellfish toxicity. Analysis of 13-desmethyl spirolide C and gymnodimine A by binding and voltage-clamp recordings on muscle-type α12βγδ and neuronal α3β2 and α4β2 nicotinic acetylcholine receptors reveals subnanomolar affinities, potent antagonism, and limited subtype selectivity. Their binding to acetylcholine-binding proteins (AChBP), as soluble receptor surrogates, exhibits picomolar affinities governed by diffusion-limited association and slow dissociation, accounting for apparent irreversibility. Crystal structures of the phycotoxins bound to Aplysia-AChBP (≈2.4Å) show toxins neatly imbedded within the nest of ar-omatic side chains contributed by loops C and F on opposing faces of the subunit interface, and which in physiological conditions accommodates acetylcholine. The structures also point to three major features: (i) the sequence-conserved loop C envelops the bound toxins to maximize surface complementarity; (ii) hydrogen bonding of the protonated imine nitrogen in the toxins with the carbonyl oxygen of loop C Trp147 tethers the toxin core centered within the pocket; and (iii) the spirolide bis-spiroacetal or gymnodimine tetrahydrofuran and their common cyclohexene-butyrolactone further anchor the toxins in apical and membrane directions, along the subunit interface. In contrast, the se-quence-variable loop F only sparingly contributes contact points to preserve the broad receptor subtype recognition unique to phycotoxins compared with other nicotinic antagonists. These data offer unique means for detecting spiroimine toxins in shellfish and identify distinctive ligands, functional determinants and binding regions for the design of new drugs able to target several receptor subtypes with high affinity.

Brevenal inhibits Pacific ciguatoxin-1B-induced neurosecretion from bovine chromaffin cells

Ciguatoxins and brevetoxins are neurotoxic cyclic polyether compounds produced by dinoflagellates, which are responsible for ciguatera and neurotoxic shellfish poisoning (NSP) respectively. Recently, brevenal, a natural compound was found to specifically inhibit brevetoxin action and to have a beneficial effect in NSP. Considering that brevetoxin and ciguatoxin specifically activate voltage-sensitive Na+ channels through the same binding site, brevenal has therefore a good potential for the treatment of ciguatera. Pacific ciguatoxin-1B (P-CTX-1B) activates voltage-sensitive Na+ channels and promotes an increase in neurotransmitter release believed to underpin the symptoms associated with ciguatera. However, the mechanism through which slow Na+ influx promotes neurosecretion is not fully understood. In the present study, we used chromaffin cells as a model to reconstitute the sequence of events culminating in ciguatoxin-evoked neurosecretion. We show that P-CTX-1B induces a tetrodotoxin-sensitive rise in intracellular Na+, closely followed by an increase in cytosolic Ca2+ responsible for promoting SNARE-dependent catecholamine secretion. Our results reveal that brevenal and β-naphtoyl-brevetoxin prevent P-CTX-1B secretagogue activity without affecting nicotine or barium-induced catecholamine secretion. Brevenal is therefore a potent inhibitor of ciguatoxin-induced neurotoxic effect and a potential treatment for ciguatera.

Nodal swelling produced by ciguatoxin-induced selective activation of sodium channels in myelinated nerve fibers

Ciguatoxin-1b, the major toxin involved in ciguatera fish poisoning, and D-mannitol were examined on frog nodes of Ranvier using confocal laser scanning microscopy and conventional current- and voltage-clamp techniques. During the action of 10 nM ciguatoxin-1b, an increase in nodal volume was observed as determined by digital image processing and three-dimensional reconstruction of axons. The increase was prevented by blocking Na+ channels with tetrodotoxin. Ciguatoxin-1b (10 nM) induced high frequency action potential discharges up to 70-100 Hz. Analysis of Na+ current revealed that the toxin modified a current fraction which was activated at resting membrane potential and failed to inactivate. Increasing the osmolality of the external solution by about 50% with D-mannitol restored the nodal volume to its control value and suppressed spontaneous action potentials. In addition, D-mannitol affected unmodified and ciguatoxin-1b-treated Na+ currents in a similar manner causing a reduction of maximum conductance, negative shifts of current reversal potential and modification of the voltage-dependence of current activation and inactivation. In conclusion, ciguatoxin-1b induced a tetrodotoxin-sensitive swelling of nodes of Ranvier and selectively affected the Na+ current of myelinated axons. It is proposed that ciguatoxin-1b, by modifying Na+ current, increased intracellular Na+ concentration which caused water influx and nodal swelling. This may explain some of the reported symptoms of ciguatera fish poisoning. D-mannitol, an agent used for ciguatera treatment, was found to reverse the effects of ciguatoxin-1b by reducing Na+ entry and increasing the efflux of water through its osmotic action. It is the first time that osmotic changes produced by the selective activation of ionic channels, i.e. Na+ channels, are reported.

The marine phycotoxin gymnodimine targets muscular and neuronal nicotinic acetylcholine receptor subtypes with high affinity

Gymnodimines (GYMs) are phycotoxins exhibiting unusual structural features including a spirocyclic imine ring system and a trisubstituted tetrahydrofuran embedded within a 16‐membered macrocycle. The toxic potential and the mechanism of action of GYM‐A, highly purified from contaminated clams, have been assessed. GYM‐A in isolated mouse phrenic hemidiaphragm preparations produced a concentration‐ and time‐dependent block of twitch responses evoked by nerve stimulation, without affecting directly elicited muscle twitches, suggesting that it may block the muscle nicotinic acetylcholine (ACh) receptor (nAChR). This was confirmed by the blockade of miniature endplate potentials and the recording of subthreshold endplate potentials in GYM‐A paralyzed frog and mouse isolated neuromuscular preparations. Patch‐clamp recordings in Xenopus skeletal myocytes revealed that nicotinic currents evoked by constant iontophoretical ACh pulses were blocked by GYM‐A in a reversible manner. GYM‐A also blocked, in a voltage‐independent manner, homomeric human α7 nAChR expressed in Xenopus oocytes. Competition‐binding assays confirmed that GYM‐A is a powerful ligand interacting with muscle‐type nAChR, heteropentameric α3β2, α4β2, and chimeric α7‐5HT3 neuronal nAChRs. Our data show for the first time that GYM‐A broadly targets nAChRs with high affinity explaining the basis of its neurotoxicity, and also pave the way for designing specific tests for accurate GYM‐A detection in shellfish samples.

Total Synthesis of Pinnatoxins A and G and Revision of the Mode of Action of Pinnatoxin A

Pinnatoxins belong to an emerging class of potent marine toxins of the cyclic imine group. Detailed studies of their biological effects have been impeded by unavailability of the complex natural product from natural sources. This work describes the development of a robust, scalable synthetic sequence relying on a convergent strategy that delivered a sufficient amount of the toxin for detailed biological studies and its commercialization for use by other research groups and regulatory agencies. A central transformation in the synthesis is the highly diastereoselective Ireland-Claisen rearrangement of a complex α,α-disubstituted allylic ester based on a unique mode for stereoselective enolization through a chirality match between the substrate and the lithium amide base. With synthetic pinnatoxin A, a detailed study has been performed that provides conclusive evidence for its mode of action as a potent inhibitor of nicotinic acetylcholine receptors selective for the human neuronal α7 subtype. The comprehensive electrophysiological, biochemical, and computational studies support the view that the spiroimine subunit of pinnatoxins is critical for blocking nicotinic acetylcholine receptor subtypes, as evidenced by analyzing the effect of a synthetic analogue of pinnatoxin A containing an open form of the imine ring. Our studies have paved the way for the production of certified standards to be used for mass-spectrometric determination of these toxins in marine matrices and for the development of tests to detect these toxins in contaminated shellfish.

Neurotoxins targetting receptor site 5 of voltage-dependent sodium channels increase the nodal volume of myelinated axons

The effects of a C57 type ciguatoxin (CTX‐3C) and two types of brevetoxins (PbTx‐1 and PbTx‐3), known to bind to receptor site 5 of the neuronal voltage‐dependent Na+ channel‐protein, were studied on the morphology of living frog myelinated axons using confocal laser scanning microscopy. During the action of CTX‐3C, PbTx‐1, and PbTx‐3 (10–50 nM), a marked swelling of nodes of Ranvier was observed without apparent modification of internodal parts of axons. In all cases, toxin‐induced nodal swelling attained a steady‐state within 75–100 min that was well maintained during an additional 90–115 min. The nodal swelling was reversed by an external hyperosmotic solution containing 100 mM D‐mannitol and could be completely prevented by blocking voltage‐dependent Na+ channels with 1 μM tetrodotoxin. It is suggested that CTX‐3C, PbTx‐1, and PbTx‐3 by activating Na+ channels cause a continuous Na+ entry into axons, increasing internal Na+ concentration. Such an increase directly or indirectly disturbs the osmotic equilibrium between intra‐ and extra‐axonal media, resulting in an influx of water, which is responsible for the long‐lasting nodal swelling. Similar results were previously reported with two C60 type ciguatoxins (CTX‐1B and CTX‐4B). Thus, it is concluded that the four types of toxins targetting receptor site 5 of neuronal voltage‐dependent Na+ channels, not only enhance nerve membrane excitability but also, on a long‐term basis, cause a marked increase in the axonal volume. J. Neurosci. Res. 55:666–673, 1999. 

A new conotoxin isolated from Conus consors venom acting selectively on axons and motor nerve terminals through a Na+‐dependent mechanism

A novel conotoxin was isolated and characterized from the venom of the fish‐hunting marine snail Conus consors. The peptide was identified by screening chromatography fractions of the crude venom that produced a marked contraction and extension of the caudal and dorsal fins in fish, and noticeable spontaneous contractions of isolated frog neuromuscular preparations. The peptide, named CcTX, had 30 amino acids and the following scaffold: X11CCX7CX2CXCX3C. At the frog neuromuscular junction, CcTx at nanomolar concentrations selectively increased nerve terminal excitability so that a single nerve stimulation triggered trains of repetitive or spontaneous synaptic potentials and action potentials. In contrast, CcTx had no noticeable effect on muscle excitability even at concentrations 100 × higher than those that affected motor nerve terminals, as revealed by direct muscle stimulation. In addition, CcTx increased miniature endplate potential (MEPP) frequency in a Ca2+‐free medium supplemented with ethylene glycol‐bis‐(β‐aminoethyl ether)‐N,N,N′,N′‐tetraacetic acid (EGTA). Blockade of voltage‐dependent sodium channels with tetrodotoxin (TTX) either prevented or suppressed the increase of MEPP frequency induced by the toxin. CcTx also produced a TTX‐sensitive depolarization of the nodal membrane in single myelinated axons giving rise, in some cases, to repetitive and/or spontaneous action potential discharges. In addition, CcTx increased the nodal volume of myelinated axons, as determined using confocal laser scanning microscopy. This increase was reversed by external hyperosmolar solutions and was prevented by pretreatment of axons with TTX. It is suggested that CcTx, by specifically activating neuronal voltage‐gated sodium channels at the resting membrane potential, produced Na+ entry into nerve terminals and axons without directly affecting skeletal muscle fibres. CcTx belongs to a novel family of conotoxins that targets neuronal voltage‐gated sodium channels.

Hyperosmolar D-mannitol reverses the increased membrane excitability and the nodal swelling caused by Caribbean ciguatoxin-1 in single frog myelinated axons

The effects of hyperosmolar D-mannitol were studied on single frog myelinated nerve fibres previously poisoned with Caribbean ciguatoxin-1 (C-CTX-1), a new toxin isolated from the pelagic fish Caranx latus inhabiting the Caribbean region. In current-clamped myelinated axons, C-CTX-1 (50-120 nM) caused spontaneous and repetitive action potential discharges after a short delay. In addition, the toxin produced a marked swelling of nodes of Ranvier of myelinated axons that reached a steady state within about 90 min, as revealed by using confocal laser scanning microscopy. The increased excitability and the nodal swelling caused by C-CTX-1 were prevented or reversed by an external hyperosmotic solution containing 100 mM D-mannitol. Moreover, the C-CTX-1-induced nodal swelling was completely prevented by the blockade of voltage-sensitive sodium channels by tetrodotoxin (TTX). It is suggested that C-CTX-1, by increasing nerve membrane excitability, enhances Na(+) entry into nodes of Ranvier through TTX-sensitive sodium channels, which directly or indirectly disturb the osmotic equilibrium between intra- and extra-axonal media resulting in an influx of water that was responsible for the long-lasting nodal swelling. The fact, that hyperosmolar D-mannitol either reversed or prevented the neurocellular actions of C-CTX-1, is of particular interest since it provides the rational basis for its use to treat the neurological symptoms of ciguatera fish poisoning in the Caribbean area.

A novel µ-conopeptide, CnIIIC, exerts potent and preferential inhibition of NaV1.2/1.4 channels and blocks neuronal nicotinic acetylcholine receptors.

The µ‐conopeptide family is defined by its ability to block voltage‐gated sodium channels (VGSCs), a property that can be used for the development of myorelaxants and analgesics. We characterized the pharmacology of a new µ‐conopeptide (µ‐CnIIIC) on a range of preparations and molecular targets to assess its potential as a myorelaxant.