Involvement of both sodium influx and potassium efflux in ciguatoxin-induced nodal swelling of frog myelinated axons

Ciguatoxins, mainly produced by benthic dinoflagellate Gambierdiscus species, are responsible for a complex human poisoning known as ciguatera. Previous pharmacological studies revealed that these toxins activate voltage-gated Na+ channels. In frog nodes of Ranvier, ciguatoxins induce spontaneous and repetitive action potentials (APs) and increase axonal volume that may explain alterations of nerve functioning in intoxicated humans. The present study aimed determining the ionic mechanisms involved in Pacific ciguatoxin-1B (P-CTX-1B)-induced membrane hyperexcitability and subsequent volume increase in frog nodes of Ranvier, using electrophysiology and confocal microscopy. The results reveal that P-CTX-1B action is not dependent on external Cl- ions since it was not affected by substituting Cl- by methylsulfate ions. In contrast, substitution of external Na+ by Li+ ions suppressed spontaneous APs and prevented nodal swelling. This suggests that P-CTX-1B-modified Na+ channels are not selective to Li+ ions and/or are blocked by these ions, and that Na+ influx through Na+ channels opened during spontaneous APs is required for axonal swelling. The fact that the K+ channel blocker tetraethylammonium modified, but did not suppress, spontaneous APs and greatly reduced nodal swelling induced by P-CTX-1B indicates that K+ efflux might also be involved. This is supported by the fact that P-CTX-1B, when tested in the presence of both tetraethylammonium and the K+ ionophore valinomycin, produced the characteristic nodal swelling. It is concluded that, during the action of P-CTX-1B, water movements responsible for axonal swelling depend on both Na+ influx and K+ efflux. These results pave the way for further studies regarding ciguatera treatment.

Complex I inhibition in the visual pathway induces disorganization of the node of Ranvier

Mitochondrial defects can have significant consequences on many aspects of neuronal physiology. In particular, deficiencies in the first enzyme complex of the mitochondrial respiratory chain (complex I) are considered to be involved in a number of human neurodegenerative diseases. The current work highlights a tight correlation between the inhibition of complex I and the state of axonal myelination of the optic nerve. Exposing the visual pathway of rats to rotenone, a complex I inhibitor, resulted in disorganization of the node of Ranvier. The structure and function of the node depend on specific cell adhesion molecules, among others, CASPR (contactin associated protein) and contactin. CASPR and contactin are both on the axonal surfaces and need to be associated to be able to anchor their myelin counterpart. Here we show that inhibition of mitochondrial complex I by rotenone in rats induces reactive oxygen species, disrupts the interaction of CASPR and contactin couple, and thus damages the organization and function of the node of Ranvier. Demyelination of the optic nerve occurs as a consequence which is accompanied by a loss of vision. The physiological impairment could be reversed by introducing an alternative NADH dehydrogenase to the mitochondria of the visual system. The restoration of the nodal structure was specifically correlated with visual recovery in the treated animal.

Dexamethasone effects on Na(v)1.6 in tooth pulp, dental nerves, and alveolar osteoclasts of adult rats

Dexamethasone causes extensive physiologic reactions including the reduction of inflammation and pain. Here, we asked whether it also affected dental or periodontal cells or dental innervation by altering voltage-gated sodium channel Na(v)1.6 immunoreactivity (IR) or neural synaptophysin. Daily dexamethasone (0.2 mg/kg) given for 1 week to rats caused 12-fold increased intensity of Na(v)1.6-IR in dendritic pulpal cells of normal molars and incisors compared with vehicle treatment. These cells also co-localized monocyte (ED-1) or dendritic cell (CD11b/Ox42) markers, and their location in molars expanded during dexamethasone treatment to include deeper pulp. Furthermore, dexamethasone caused a 10-fold decrease in the number of Na(v)1.6-immunoreactive multinucleate osteoclasts along the alveolar bone of molar root sockets. No changes occurred for neural Na(v)1.6 at axonal nodes of Ranvier, even though IR for calcitonin gene-related peptide was greatly decreased, as expected, and neural synaptophysin-IR was decreased 59% by dexamethasone. At 4 days after tooth injury, pulpal vasodilation and increased Na(v)1.6-immunoreactive pulp cells were similar for all groups. Thus, dexamethasone changes dental pulp cell and alveolar osteoclast Na(v)1.6-IR in normal teeth, but different mechanisms occur after tooth injury when tissue reactions were similar for dexamethasone- and vehicle-treated rats. Steroid-induced alterations of dental pain and inflammation coincide with altered exocytic capability in dental nerve fibers as shown by synaptophysin-IR and with altered pulp cell Na(v)1.6-IR and osteoclast number, but not with any changes in Na(v)1.6-IR for nodes of Ranvier in myelinated dental axons.

Physiological Roles of Neurite Outgrowth Inhibitors in Myelinated Axons of the Central Nervous System - Implications for the Therapeutic Neutralization of Neurite Outgrowth Inhibitors

It has long been recognized that the central nervous system (CNS) exhibits only limited capacity for axonal regeneration following injury. It has been proposed that myelin-associated inhibitory molecules are responsible for the nonpermissive nature of the CNS environment to axonal regeneration. Experimental strategies to enhance regeneration by neutralizing these inhibitory molecules are rapidly advancing toward clinical application. It is therefore important that the physiological distribution and functions of these supposed inhibitory molecules should be understood. In this review, we examine the distribution of these inhibitors of neurite outgrowth in relation to the longitudinal polarization of the myelinated axon into the node of Ranvier and associated domains and explore their potential domain specific physiological functions. Potential implications for the therapeutic strategy of neutralizing these inhibitory molecules to promote neural repair are discussed.

Oxaliplatin, an anticancer agent that affects both Na+ and K+ channels in frog peripheral myelinated axons

The use of oxaliplatin, a relatively new chemotherapeutic agent, is somewhat limited since it produces a specific peripheral neuropathy regarding other neurotoxic anticancer platinum analogues. In order to investigate the mechanism of such a peripheral neuropathy, the effects of 1-100 micromol/l oxaliplatin were assessed on the nodal ionic currents of single frog myelinated axons as a model of peripheral excitable membranes. Oxaliplatin decreased both Na(+) and K(+) currents in a dose-dependent manner and within 5-10 min, without producing any marked changes in the current kinetics. It was about three to eight times more effective in reducing the Na(+) than the K(+) current. In addition, it shifted the voltage-dependence of both Na(+) and K(+) conductances towards negative membrane potentials. A negative shift in the steady-state inactivation-voltage curve of the peak Na(+) current was also observed in the presence of oxaliplatin. These effects were not reversed by washing the myelinated axons with an oxaliplatin-free solution for at least 30 min. It is concluded that oxaliplatin modifies the voltage-dependent ionic channels mainly by altering the external surface membrane potential. The knowledge of such a mechanism may help to counteract the neurotoxic action of this anticancer agent.

[Postcatelectrotonic potentials and trace changes in the nerve fiber excitability]

When cathode subthreshold impulse was turned off, excitable membranes of isolated nerve fibres and nervous trunk show postelectrotonic depolarisation (PED), that is a slow recovery of membrane potential to the resting level. PED of the single nodes of Ranvier and nervous trunk is registered not only in normal conditions, but also after complete block of sodium channels. The size and duration of nervous trunk PED under subthreshold depolarising current increase along with duration of applied depolarisation: when cathode current 1 ms in duration was used, they were 0.093 +/- +/- 0.004 mV and 7.123 +/- 0.576 ms, respectively; when current was 5 ms in duration, they were 0.189 +/- 0.005 mV and 23.212 +/- 1.186 ms, whereas a 10-ms depolarisation yields values of 0.220 +/- 0.011 mV and 68.721 +/- 3.389 ms. Application of the train of catelectrotonic impulses leads to PED built-up. As PED is found not only in normal conditions but also after complete block of sodium channels, it is reasonable to suggest that the most probable reason for PED is an outward potassium current.

Ionic mechanisms involved in the nodal swelling of myelinated axons caused by marine toxins

This review describes the ionic mechanisms involved in the nodal swelling of frog myelinated axons caused by specific marine neurotoxins (ciguatoxins, brevetoxins, Conus consors toxin and equinatoxin-II), analysed using confocal laser scanning microscopy. We have focussed on toxins that either target neuronal voltage-dependent Na+ channels, or that form cation-selective pores and indirectly affect the functioning of the Na(+)-Ca(++)exchanger.

Tolperisone--a novel modulator of ionic currents in myelinated axons

The actions of tolperisone on single intact Ranvier nodes of the toad Xenopus were investigated by means of the Hodgkin-Huxley formalism. Adding tolperisone to the bathing medium (100 micromol/l) caused the following fully reversible effects: 1. The sodium permeability P'Na was decreased by about 50% in a nearly potential-independent manner while the so-called sodium inactivation curve was shifted in the negative direction by about 3 mV. 2. The remaining parameters of the sodium system, i.e. m, taum and tauh, did not change. 3. The potassium permeability P'K decreased at strong depolarizing potentials (V > 60 mV); hence the permeability constant P(K) decreased by about 8%. However, weak depolarizations (V < 60 mV) caused P'K to increase by about 7%. 4. The potassium activation curve was shifted in the positive direction by about 9 mV and the exponent of n, b, was reduced from about 3.5 to about 1.5. Concentration-response relations for reduction of the sodium permeability constant PNa and of the potassium permeability constant P(K) yielded apparent dissociation constants of about 0.06 mmol/l and 0.32 mmol/l, respectively. The increase of P'K at V = 40 mV, however, was largely concentration-independent. Our findings show that, in contrast to the prevailing view, tolperisone cannot be said to have a so-called lidocaine-like activity, because its effect on potassium permeability in the threshold region is fundamentally different from that of other known local anaesthetics. We infer that this effect, in combination with the decrease in sodium permeability, is responsible for the tendency of tolperisone to reduce excitability and hence for the antispastic action of tolperisone documented by clinical observations.

Effects of silperisone on the excitation process in Ranvier nodes

The effect of silperisone on single intact Ranvier nodes of the toad Xenopus was investigated by adding it to the bathing medium. At 100 micromol/l the following fully reversible effects were observed: 1. The spike amplitude decreased in a frequency-dependent manner. 2. Both the sodium activation and the inactivation curves as well as the potential dependence of taum were slightly shifted in the negative direction, while tauh did not change. 3. The sodium permeability constant PNa decreased by 50%. 4. The potassium currents acquired a phasic time course previously described for certain psoralens. They reached a relative maximum and then approached a lower steady state value, kappa(infinity) with a time constant of about 5 ms. Concentration-related responses of PNa, PK and of k(infinity), yielded: 5. The apparent dissociation constant of block of PNa was 110 micromol/l. 6. PK proved not to be changed by silperisone in the concentration range tested, while the variable kappa(infinity) yielded a relation similar to that of PNa except that the apparent dissociation constant was 24 micromol/l. The phasic course of the potassium currents in the presence of silperisone may be due to an open channel blockade. In view of the similarities between the actions of silperisone and 5-methoxypsoralen, it is entirely conceivable that silperisone has potential for an antispastic drug, e.g., in demyelinating diseases like multiple sclerosis.

Gallamine triethiodide selectively blocks voltage-gated potassium channels in Ranvier nodes

The effects of gallamine on ionic currents in single intact Ranvier nodes of the toad Xenopus were investigated. The following fully reversible effects were observed: 1. With a test concentration of 1 mmol/l the current-voltage relation of steady-state potassium currents, IK ss exhibited a complete block of IK ss up to about V = 110 mV; with stronger depolarisations the block was incomplete. The peak sodium currents, in contrast, were not affected. 2. At the same test concentration the potassium permeability constant PK was reduced by 92% from its normal value, while the sodium permeability constant PNa decreased by only 8%. 3. Concentration-response relations of the block of PK yielded an apparent dissociation constant of 30 micromol/l and a steepness parameter of unity. Patch-clamp experiments on cloned Kv1.1, Kv1.2, Kv1.3 and Kv3.1 channels yielded apparent dissociation constants of 86, 19, >>100 and 121 micromol/l, respectively. Our findings show that gallamine is particularly well suited for separating potassium and sodium currents in axonal current ensembles. They also strongly suggest that potassium currents in Ranvier nodes of Xenopus are mainly carried by an ensemble of Kv1.1 and 1.2 channels.

Effects of three alkoxypsoralens on voltage gated ion channels in Ranvier nodes

The effects of the phototoxic K+- channel blockers 8-methoxypsoralen (8-MOP) and 5-methoxypsoralen (5-MOP) on Ranvier nodes were compared to those of 5,8-diethoxypsoralen (5,8-EOP) by means of the Hodgkin-Huxley formalism. When these test substances were added individually to the bathing solution (8-MOP: 100 micromol/l; 5-MOP: 50 micromol/l; 5,8-EOP: 10 micromol/l) the following completely reversible effects were observed: 1. 8-MOP, caused a nearly potential-independent decrease of the sodium permeability, P'Na, by ca. 17%. 5-MOP and 5,8-EOP merely decreased the maximal value of P'Na, by ca. 12 and 8% respectively, whereas with weak depolarisations P'Na was unchanged. 2. In the tested potential range the potassium permeability, P'K, was caused to decrease by ca. 9% by 8-MOP, ca. 21% by 5-MOP and ca. 19% by 5,8-EOP. 3. The potassium currents acquired a phasic time course previously described for 8-MOP and 5-MOP. They reached a relative maximum and approached a lower steady-state value, kinfinity, with a time constant tauk at V = 120 mV of about 16 ms (8-MOP), 20 ms (5-MOP) and 94 ms (5,8-EOP). To obtain dose-response relations the drug-induced effects on peak P'K and on the steady state value, kinfinity, were measured. The corresponding apparent dissociation constants (in micromol/l) were 66.6 and 80.1 (for 8-MOP), 87.6 and 25.8 (for 5-MOP), and 13.5 and 6.5 (for 5,8-EOP). In view of the similarity of the actions of 5-MOP and 5,8-EOP as well as the fact that 5,8-EOP is not phototoxic, in future 5,8-EOP may well prove to be a particularly suitable K+-channel blocker for the symptomatic therapy of multiple sclerosis and other demyelinating diseases.

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 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 x 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-(beta-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.

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 microM 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.

Structural and electrophysiological effects of local anesthetics and of low temperature on myelinated nerves: implication of the lipid chains in nerve excitability

X-ray scattering and electrophysiological experiments performed on toad sciatic nerves as a function of the exposure to either low temperature or tetracaine yielded the following results: (i) the main structural effect is to thicken the individual membranes, thus to stiffen the acyl chains and increase the repeat distance of the one-dimensional lattice, phenomena that are typical of lipid-containing systems with disordered chains; (ii) the electrophysiological effect is to decrease the amplitude and velocity of the compound action potential; (iii) the structural and physiological effects of the two agents are practically identical. Since the structural and the electrophysiological parameters have different origins in the nerves (the structure regards the myelin sheath, the electrical signals originate at the nodes of Ranvier) it is inferred that tetracaine and low temperature exert similar effects on the membranes of both the myelin sheath and the nodes of Ranvier. Also, since local anesthetics act by inhibiting the Na+ channels, these observations suggest that the acyl chain conformation modulates the channel function and thus the generation of action potential.

The wheat proteins puroindoline-a and alpha1-purothionin induce nodal swelling in myelinated axons

The effects of two basic cysteine-rich lipid-binding proteins isolated from wheat seedlings, puroindoline-a and alpha1-purothionin, were studied on single frog myelinated axons stained with the fluorescent dye FM1-43 using confocal laser scanning microscopy. During exposure to either puroindoline-a or alpha1-purothionin (10 and 100 microM) a marked swelling of nodes of Ranvier was observed, provided NaCl was present in the external solution. It is suggested that these proteins increase the internal osmolality by forming pores in the axonal membrane and induce water influx to compensate for such an increase. Moreover, in the presence of alpha1-purothionin (100 microM), the intensity of the axonal staining with FM1-43 was increased. It is the first time, to our knowledge, that basic proteins containing domains of a cysteine-rich repeated motif are reported to produce swelling and water movements across neuronal cell membranes.

Alkoxypsoralens, novel nonpeptide blockers of Shaker-type K+ channels: synthesis and photoreactivity

A series of psoralens and structurally related 5,7-disubstituted coumarins was synthesized and investigated for their K+ channel blocking activity as well as for their phototoxicity to Artemia salina and their ability to generate singlet oxygen and to photomodify DNA. After screening the compounds on Ranvier nodes of the toad Xenopus laevis, the affinities of the most promising compounds, which proved to be psoralens bearing alkoxy substituents in the 5-position or alkoxymethyl substituents in the neighboring 4- or 4'-position, to a number of homomeric K+ channels were characterized. All compounds exhibited the highest affinity to Kv1.2. 5,8-Diethoxypsoralen (10d) was found to be an equally potent inhibitor of Kv1.2 and Kv1.3, while lacking the phototoxicity normally inherent in psoralens. The reported compounds represent a novel series of nonpeptide blockers of Shaker-type K+ channels that could be further developed into selective inhibitors of Kv1.2 or Kv1. 3.

Gambiertoxin (CTX-4B), purified from wild Gambierdiscus toxicus dinoflagellates, induces Na(+)-dependent swelling of single frog myelinated axons and motor nerve terminals in situ

The effects of gambiertoxin (CTX-4B), purified from the dinoflagellate Gambierdiscus toxicus, were assessed on the morphology of both frog myelinated axons and motor nerve terminals, using confocal laser scanning microscopy. During the action of the toxin (24 and 30 nM), a marked swelling of nodes of Ranvier and motor nerve terminals was observed. The CTX-4B-induced swelling could be prevented by blocking voltage-dependent Na+ channels with tetrodotoxin, and could be partly reversed by an external hyperosmotic solution containing 100 mM D-mannitol. The results suggest that CTX-4B, by modifying voltage-dependent Na+ channels, increases internal Na+ concentration of axons and nerve terminals and consequently induces water influx to compensate such an increase. It is suggested that stimulated transmitter release by CTX-4B, as well as by hyperosmotic dmannitol, contribute also to the swelling of the terminals through an increase in their surface area.

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 effect of inhibitors of sodium permeability (novocaine and tetrodotoxin) on the trace depolarization of myelinated nerve fibers]

Partial block of the sodium permeability by local anesthetics does not induce significant aftereffect of depolarisation in intact Ranvier nodes of the frog isolated myelinated nerve fibres. The sodium current seems to take no part in generation of the depolarisation aftereffect.

Na(+)-activated K+ channels localized in the nodal region of myelinated axons of Xenopus

1. A potassium channel activated by internal Na+ ions (K+Na channel) was identified in peripheral myelinated axons of Xenopus laevis using the cell-attached and excised configurations of the patch clamp technique. 2. The single-channel conductance for the main open state was 88 pS with [K+]o = 105 mM and pS with [K+]o = 2.5 mM ([K+]i = 105 mM). The channel was selectively permeable to K+ over Na+ ions. A characteristic feature of the K+Na channel was the frequent occurrence of subconductance states. 3. The open probability of the channel was strongly dependent on the concentration of Na+ ions at the inner side of the membrane. The half-maximal activating Na+ concentration and the Hill coefficient were 33 mM and 2.9, respectively. The open probability of the channel showed only weak potential dependence. 4. The K+Na channel was relatively insensitive to external tetraethylammonium (TEA+) in comparison with voltage-dependent axonal K+ channels; the half-maximal inhibitory concentration (IC50) was 21.3 mM (at -90 mV). In contrast, the channel was blocked by low concentrations of external Ba2+ and Cs+ ions, with IC50 values of 0.7 and 1.1 mM, respectively (at -90 mV). The block by Ba2+ and Cs+ was more pronounced at negative than at positive membrane potentials. 5. A comparison of the number of K+Na channels in nodal and paranodal patches from the same axon revealed that the channel density was about 10-fold higher at the node of Ranvier than at the paranode. Moreover, a correlation between the number of K+Na channels and voltage-dependent Na+ channels in the same patches was found, suggesting co-localization of both channel types. 6. As weakly potential-dependent ('leakage') channels, axonal K+Na channels may be involved in setting the resting potential of vertebrate axons. Simulations of Na+ ion diffusion suggest two possible mechanisms of activation of K+Na channels: the local increase of Na+ concentration in a cluster of Na+ channels during a single action potential or the accumulation in the intracellular axonal compartment during a train of action potentials.

Mode of action of psoralens, benzofurans, acridinons, and coumarins on the ionic currents in intact myelinated nerve fibres and its significance in demyelinating diseases

The actions of psoralens, benzofurans, acridinons and coumarins on the ionic currents in intact myelinated nerve fibres were investigated. All 6 substances blocked the potassium currents in a time-dependent manner, producing so-called K+ transients. Only 5-methoxypsoralen is a largely selective blocker of predominantly the axolemmal potassium channels, which is the characteristic required by our previously proposed working hypothesis for the mechanism of potassium-channel blockers in demyelinating diseases, in particular multiple sclerosis. If the observed K+ transients were to arise by blocking of the potassium channels of the Schwann cell, that is, by the periaxonal accumulation of K+ and a resulting collapse of the electromotive driving force for potassium-ions, according to a modified version of our previous hypothesis the other substances tested could also have a beneficial effect on the impaired impulse conduction in demyelinated axons. In this case a large number of new potential drugs would be available for the symptomatic therapy of MS.

Characteristics of Na+ current in Schwann cells cultured from frog sciatic nerve

Characteristics of voltage-dependent currents in cultured frog Schwann cells were investigated by the whole-cell clamp technique. An inward current was detectable at a membrane potential level more positive than -50 mV and reached a maximum value at about -10 mV, while no rectifying channel was present. The inward current was carried by Na+ ions, because the extrapolated reversal potential of the current agreed with the calculated ENa, and the current was sensitive to tetrodotoxin. The membrane potential for half-maximal inactivation was -82 mV. The inactivation curve indicated that more than 90% of the Na+ channels were inactivated at the resting membrane potential, suggesting that the cultured frog Schwann cells could not generate an action potential under physiological conditions. The time constant for the inactivation at a maximum current was 5.3 ms (-10 mV, 13 degrees C). The electrophysiological characteristics of the Na+ current in the cultured frog Schwann cells were compared with those in other tissues. This Na+ current was quantitatively different from that observed in the amphibian node of Ranvier but was similar to that in the mammalian Schwann or glial cells, especially in the more hyperpolarized half-maximal inactivation potential and in the slower inactivation time course.

Different effects of 4-aminopyridine on regenerated cutaneous and muscular rat sciatic nerve branches

Developing and regenerated myelinated rat dorsal and ventral root fibers respond differently to the fast potassium channel blocking agent 4-aminopyridine (4-AP). To pursue this issue further, we made unilateral sciatic nerve crushes in adult rats. Sural (SN) and lateral gastrocnemius (LGN) nerve branches were collected 4-6 months later, for physiological and morphological examination. Regenerated and control nerves in Ringers solution showed generally similar compound action potential (CAP) waveforms, but CAPs of regenerated SNs and LGNs in 4-AP were markedly different. While regenerated SNs showed a prominent late CAP negativity with a "rippled" appearance and markedly compromised recovery properties, the CAP and recovery properties of regenerated LGNs were minimally changed. Light and electron microscopic examination of SN and LGN fibers failed to reveal any features obviously related to the observed physiological differences. We conclude, that the effect of 4-AP on regenerated cutaneous afferents differs from its action on regenerated muscular afferents and efferents. This physiological diversity lacks obvious structural correlates.

Fast K channels are more sensitive to riluzole than slow K channels in myelinated nerve fibre

The effects of 1-500 microM riluzole, a novel psychotropic agent, were studied on the nodal K current of isolated nerve fibres of the frog. When added to the external solution, the substance rapidly and reversibly inhibited slow, fast 1 and fast 2 K components of the tail K current. The concentrations of riluzole inducing half maximum reduction of slow, fast 1 and fast 2 K conductances were 413 microM, 24 microM and 21 microM respectively. It is concluded that the substance is about 20 times more effective in blocking fast than slow K channels.

Induction of motor neuron sprouting in vivo by ciliary neurotrophic factor and basic fibroblast growth factor

Ciliary neurotrophic factor (CNTF) and basic fibroblast growth factor (bFGF) were tested for effects on sprouting by motor neurons innervating the adult mouse gluteus muscle. Factors were delivered by subcutaneous injection directly over the surface of the superior gluteus muscle once daily for 7 d and then end plates and axons were visualized by combined silver and cholinesterase staining. CNTF (500 ng daily) induced sprouting both from end plates and from the subset of nodes of Ranvier that are closest to the end plate. The effect of CNTF was potentiated twofold by coadministration of bFGF at doses of 2-20 ng daily, whereas treatment with bFGF alone failed to induce sprouting from either end plates or nodes of Ranvier. The sprouting stimulus delivered by the factors showed limited penetrance into the muscle and restricted lateral spread from the injection site.

Comparative analysis of the effects of synthetic derivatives of batrachotoxin on sodium currents in frog node of Ranvier

1. In voltage-clamp experiments on frog myelinated nerve fibers, the effects of nine synthetic derivatives of batrachotoxin (BTX) obtained from 7,8-dihydrobatrachotoxinin A (DBTX-A) on Na+ currents (INa) have been investigated. 2. Both of 20 alpha-esters of DBTX-A with 2,4,5-trimethylpyrrol-3-carboxylic acid (DBTX-P) and benzoic acid (DBTX) at a 10(-5) M concentration caused modification of INa qualitatively similar to that induced by BTX. 3. The quaternary derivative of DBTX (QDBTX) produced such changes in INa only at a 5.10(-4) M concentration, apparently due to its much lower lipid solubility. 4. Replacement of a -CH2- by a -C = O. group in the homomorpholine ring near the tertiary nitrogen atom abolished the DBTX activity, strongly suggesting the necessity of tertiary nitrogen protonation for the toxin interaction with the channel receptor. 5. Transfer of an 11-hydroxygroup from the alpha- to the beta-position in the DBTX molecule did not decrease its activity in spite of the fact that in the beta-position this group is sterically very hindered. The activity of 11 beta-DBTX is at variance with the prediction of Codding's (1983) "oxygen triad" hypothesis. 6. DBTX-A and compounds obtained from DBTX by oxidation of the 11 alpha-hydroxygroup (K-DBTX), acetylation (Ac-DBTX), or reduction of the hemiketal moiety (H2DBTX) even at a concentration as high as 10(-3) M were able to modify only a very small fraction of the Na channels. However, a clear-cut reversible blocking action on both normal and modified Na channels was observed. 7. These results led us to conclude that BTX modifies the Na channels only in the charged form and hemiketal and 20 alpha-ester moieties provide adequate disposition of toxin on the receptor surface. The inability of H2DBTX, DBTX-A, and K-DBTX and Ac-DBTX to modify most of the Na channels can be explained by a low "probability of correct disposition" of these ligands on the receptor surface.

Riluzole specifically blocks inactivated Na channels in myelinated nerve fibre

The effects of 0.15-250 microM 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 100 microM, 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 microM 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.

Increased numbers of sodium channels form along demyelinated axons

Sodium channels, which are largely localized to the nodes of Ranvier in myelinated axons, appear to form new distributions along demyelinated axons. In this study a sensitive radioimmunoassay (RIA) was used to examine the changes in the total number of sodium channels that occur in nerves experimentally demyelinated in vivo with doxorubicin (adriamycin). The results clearly illustrate the development of an increased number of sodium channels during demyelination, suggesting that this process is associated with the formation of new sodium channels.

[The effect of N-bromoacetamide on the components of sodium channel inactivation in the membrane of Ranvier's node]

In voltage clamp experiments on the frog Ranvier node, the specific protein reagent, N-bromacetamide, significantly decelerates the sodium inactivation kinetics and makes it incomplete. After treatment with N-bromacetamide, both fast and slow inactivation time constants are increased and the proportion of inactivation components is changed favouring the slowly inactivating one in the wide range of membrane potentials. The results are consistent with a single channel population following the 3-state model of inactivation.

Use-dependent block with tetrodotoxin and saxitoxin at frog Ranvier nodes. II. Extrinsic influence of cations

Use-dependent declines of Na+ currents in myelinated frog nerve fibres were measured during a train of depolarizing pulses in solutions containing tetrodotoxin (TTX) or saxitoxin (STX). The following effects of external monovalent (Na+), divalent (Ca2+, Mg2+) and trivalent (La3+) cations on use dependence were found: Increasing the Ca2+ concentration from 2 to 8 mM shifts its voltage dependence by 20 mV whereas no significant use-dependent decline occurred at 0.2 mM Ca2+. Doubling the external Na+ concentration in 0.2 mM Ca2+ solutions did not initiate phasic block. External Mg2+ ions induced a smaller, and La3+ ions a larger, use dependence. The time constants of the current decline were 4-fold greater in 1.08 mM La3+. The static block of Na+ currents by La3+ could be directly demonstrated by the relief of block during a train of pulses. The results are qualitatively explained by a toxin binding site at the Na+ channel whose affinity for TTX or STX depends on 1) the gating conformation of the channel, probably the inactivation and ii) the occupancy of a blocking site by di- or trivalent external cations.

Use-dependent block with tetrodotoxin and saxitoxin at frog Ranvier nodes. I. Intrinsic channel and toxin parameters

The use-dependent phasic blockage of sodium channels by tetrodotoxin (TTX) and saxitoxin (STX) was examined in frog nodes of Ranvier using trains of depolarizing pulses. The decline of the peak Na+ current from its initial value (I0) before the train to a stationary value (I infinity) after the train was more pronounced at more negative holding potentials. The relationship between I infinity/I0 and holding potential was fitted by a sigmoid function which yielded values for the steepness of the voltage dependencies of around -15 mV for TTX and -8 mV for STX. Similar values were obtained at toxin concentrations of 4 and 8 nM. The higher voltage sensitivity of STX versus TTX is interpreted in terms of the higher charge and the faster binding kinetics of STX. These differences also explain the frequency dependence of the decline of Na+ currents with STX (between 0.5 and 2 Hz) and the frequency independence with TTX. Variation of the pulse amplitude in a train of conditioning pulses revealed that the magnitude of the use-dependent actions of STX parallels the steady-state Na+ inactivation curve h infinity. Inhibition of inactivation, by pre-treatment with chloramine-T, did not, however, abolish the use dependence. Instead, it introduced a change in the time constants of the decline of the Na+ currents and the magnitude became independent of the holding potential.

Voltage-dependent action of valproate on potassium channels in frog node of Ranvier

The influence of the anti-epileptic drug, valproate, on K conductance (gK) was investigated in voltage-clamped Ranvier nodes of Xenopus laevis. A double pulse method was used in order to eliminate the effect of accumulation of potassium ions in the perinodal space, thus enabling the determination of the 'true' magnitude of gK. Valproate (2.4 mM) had a voltage-dependent action on the magnitude of gK. With small step depolarizations more negative than about -50 mV, valproate increased gK (20 ms after the step) to approximately 12% of the maximal gK, an increase which disappeared due to a relatively rapid (less than 200 ms) inactivation process. However, with step depolarizations more positive than about -50 mV, valproate markedly reduced gK (20 ms after the step) at greater depolarizations, with a maximum of about 40% of the maximal gK. Moreover, at these voltages gK was inactivated completely (less than or equal to 10 s), whereas under control conditions the inactivation was only partial. Both the temporary increase and the steady state decrease of gK could contribute to an anti-epileptic effect by increasing the action potential threshold and by preventing excessive depolarizations of the nerve during epileptic seizures, respectively.

Inhibition of voltage-dependent Na+ and K+ currents by forskolin in nodes of Ranvier

The effect of forskolin on voltage-activated Na+ and K+ currents in nodes of Ranvier from the toad, Bufo marinus, has been examined using the vaseline-gap voltage-clamp technique. Peak Na+ currents (INa) were reduced by 35% and the rate of decline of Na+ current during continuous depolarization was accelerated following treatment with 450 microM forskolin. However, the voltage-dependence of steady-state inactivation as well as the rate of recovery from fast inactivation remained unchanged. Upon repetitive depolarization at 1-10 Hz, a further inhibition of INa (approximately 60%) was observed. This use-dependent or phasic inhibition recovers slowly at -80 mV (tau approximately 13 s) and had a voltage-dependence like that of activation of the Na conductance. Near maximal steady-state phasic inhibition occurred with depolarizing pulse durations of only 4 ms, consistent with a direct involvement of the open Na+ channel in the blocking process. Inhibition of the delayed K+ current (IK) was characterized by a concentration-dependent reduction in steady-state current amplitude (IC50 approximately 80 microM) and a concentration-independent acceleration of current inactivation. A similar inhibition of IK was obtained with 1,9-dideoxyforskolin, a homolog which does not activate adenylate cyclase (AC). The results suggest that the inhibition IK and perhaps INa follows directly from drug binding and is not a consequence of AC activation.

Membrane currents in lizard motor nerve terminals and nodes of Ranvier

Presynaptic membrane currents were recorded by external electrodes and nodal membrane currents were obtained by the voltage clamp technique in motor nerve endings and nodes of Ranvier of the lizard Anolis carolinensis. Although of compact shape, lizard motor endings display relatively long terminal branches; they exhibit, in agreement with previous findings in mouse and frog motor terminals, Na, Ca and K conductances, the latter consisting of a voltage- and a Ca-dependent type. Lizard nodes of Ranvier, like those of the frog, but unlike those of the mouse, exhibit a K conductance. These observations provide an explanation for the differences and similarities in presynaptic wave form configuration between the lizard and the other two species.

A model for the fast 4-aminopyridine effects on amphibian myelinated nerve fibres. A study based on voltage-clamp experiments

The effect of 4-aminopyridine (4-AP) on the potassium currents in the node of Ranvier in myelinated nerve fibres was investigated with the voltage-clamp technique. The potential and time dependence of the currents in solutions with a high potassium concentration (114.5 mM) were studied. The block of the tail current was found to be less than that of the corresponding current during a potential step. Also, the time-course of the tail current was modified. In order to explain these findings, kinetic models of the 4-AP action were constructed and analysed numerically. A simple four-state model, in which 4-AP interacts only with open channels and where the binding is diphasically potential dependent, was found to account for the effects.

[Functional restructuring of the bush-like receptor during the suppression of anaerobic glycolysis]

The bush-like receptors of frog's bladder have been investigated simultaneously by vital microscopic, and spectrophotometric studies and registration of biopotentials. It is demonstrated that electrogenic function of receptors is suppressed by monoiodacetate and anoxia more rapidly than without monoiodacetate. At the same time reducing of methylene blue into receptors is accelerated. This demonstrates a damage of power metabolism of sensory terminals. It is suggested that the changes result from blockade of anaerobic glycolysis being an alternative way for power maintenance of receptor function under anoxia.

The action of pyrethroids on sodium channels in myelinated nerve fibres and spinal ganglion cells of the frog

The interaction of pyrethroids with the voltage-dependent sodium channel was studied in voltage-clamped nodes of Ranvier and isolated spinal ganglion neurons of the clawed frog, Xenopus laevis. In the node, pyrethroids prolonged the sodium tail current associated with a step repolarization of the membrane. It was found that the amplitude of the slow, pyrethroid-induced, sodium tail current (PIT) first increased and then decreased as a function of the duration of membrane depolarization (to -5 mV). This decrease of the PIT amplitude was absent when depolarizations to the sodium equilibrium potential (+40 mV) were used. Measurements of changes in sodium reversal potential indicated that sodium ion depletion in the perinodal space is largely responsible for the inactivation of the pyrethroid-modified sodium current. Inactivation is not completely abolished by pyrethroid treatment since the probability of channel opening, measured in membrane patches excised from spinal ganglion cells, decreased slowly during prolonged depolarization. Analysis of unitary currents indicated that both activation and inactivation are retarded by pyrethroids. The arrival of sodium channels in the pyrethroid-modified open state followed a time course that was slower than both activation and inactivation of unmodified sodium channels. Our findings indicate that sodium channels are modified when in the closed resting state and that both opening and closing kinetics are delayed by pyrethroids.

[Effect of niflumic acid on the components of inactivation of the sodium channels of the Ranvier node membrane]

In voltage clamp experiments on the frog Ranvier node, niflumic acid did not alter fast or slow inactivation time courses in the wide range of membrane potentials but reduced the amplitude of the fast phase of inactivation. Fast and slow currents, corresponding respectively to fast and slow phases of inactivation, reversed at the same voltage, revealed different activation- and inactivation-voltage dependences both in intact fibre and after application of niflumic acid. The latter induced a shift of the steady-state inactivation curves for both components of inactivation towards more negative potentials without changing their steepness. The validity of suggestion of the existence of two populations of sodium channels in nerve membrane, is discussed.

Rapid and slow gating of veratridine-modified sodium channels in frog myelinated nerve

The properties of voltage-dependent Na channels modified by veratridine (VTD) were studied in voltage-clamped nodes of Ranvier of the frog Rana pipiens. Two modes of gating of VTD-modified channels are described. The first, occurring on a time scale of milliseconds, is shown to be the transition of channels between a modified resting state and a modified open state. There are important qualitative and quantitative differences of this gating process in nerve compared with that in muscle (Leibowitz et al., 1986). A second gating process occurring on a time scale of seconds, was originally described as a modified activation process (Ulbricht, 1969). This process is further analyzed here, and a model is presented in which the slow process represents the gating of VTD-modified channels between open and inactivated states. An expanded model is a step in the direction of unifying the known rapid and slow physiologic processes of Na channels modified by VTD and related alkaloid neurotoxins.

Mechanism of action of a structural analog of alphaxalone on myelinated nerve fibre

The action of alphadolone acetate (0.05-5 mM), a steroid anaesthetic and structural analog of alphaxalone, was investigated on frog myelinated axons under voltage-clamp conditions. When applied externally, alphadolone acetate reduced K and Na currents, with apparent dissociation constants of 0.70 and 1.74 mM, respectively, and without noticeable modification in their time course. In addition, Na conductance-voltage and steady-state inactivation-voltage curves were shifted towards negative voltages. This effect was more pronounced on the steady-state inactivation-voltage relationship. These results suggest that alphadolone acetate blocked K channels indifferently in their resting or open state, and Na channels preferentially in their inactivated state. Alphaxalone has been shown to preferentially block open K and inactivated Na channels (Benoit et al., 1988, Br. J. Pharmacol. 94, 635). Thus, a structural change of a steroid molecule can lead to differences in its mechanism of action. This supports the hypothesis of direct interactions between steroid molecules and target membrane proteins with resulting anaesthetic activity.

Interactions between molecules of a steroid anaesthetic (alphaxalone) and ionic channels of nodal membrane in voltage-clamped myelinated nerve fibre

1. The effects of the anaesthetic alphaxalone (0.05 to 1 mM) on the node of Ranvier of isolated myelinated nerve fibres of the frog were studied under voltage-clamp conditions. 2. When added to the solution bathing voltage-clamped nodes, alphaxalone modified neither linear leakage nor capacitative currents but rapidly and reversibly blocked K and Na currents. The blocking effects of the anaesthetic on both types of current were not dependent on the frequency of stimulation of the nerve fibres between 0.7 and 10 Hz. 3. The kinetics of the Na current were not modified by alphaxalone but, in the presence of the drug, the K current showed an apparent fast inactivation. 4. Alphaxalone rapidly and reversibly shifted towards negative voltages both the steady-state K conductance-voltage and the peak Na steady-state inactivation-voltage relationships, without noticeable modification of their shape. In contrast, the anaesthetic reversibly decreased the slope of the peak Na conductance-voltage curve. 5. The reduction of the K current induced by alphaxalone was voltage-dependent with an apparent dissociation constant first decreasing from about 0.25 to 0.08 mM between -20 mV and +20 mV and then remaining constant above +20 mV. In contrast, the apparent dissociation constant for the Na current was almost constant with increasing voltages and equalled about 0.30 mM. Hill coefficient values for both K and Na currents were noticeably less than one. 6. It is concluded that, at higher concentrations than those attainable in the brain or in the plasma during surgical anaesthesia in man, alphaxalone has a 'local anaesthetic-like' action on the peripheral nervous system in that it specifically and differentially interacts with K and Na channel gating systems: it is suggested that the anaesthetic would preferentially modify open K and inactivated Na channels.

The effect of metacaine on the slow variation of peak sodium currents in potential clamped Ranvier nodes following changes in holding potential

The effect of changes in the holding potential on peak sodium currents in isolated myelinated nerve fibres (peak INa) was investigated with the conventional sodium inactivation being kept at h infinity = 1. In Ringer solution no stationary values of peak INa could be obtained over the potential range tested. Near the normal resting potential, ER, peak INa changed with time clearly even after 10 min. Therefore, the individual values of peak INa as normalized by peak INa at ER and corrected for the unevitable run-down of peak INa could not serve as measure for stationary values of any membrane parameter. Under metacaine (1 mmol/l) peak INa changed comparably faster and proved to be less potential dependent as compared to peak INa of the untreated fibre. The effects observed are not necessarily governed by a specific process located inside the nodal membrane.