Modification of single sodium channels by the insecticide tetramethrin

Effects of DDT and permethrin on neurite growth in cultured neurons of chick embryo brain and Lymnaea stagnalis

The pesticides permethrin and 1,1-bis(4-chlorophenyl)-2,2,2-trichloroethane (DDT), dissolved in either ethanol (EtOH) or dimethylsulphoxide (DMSO), were studied to determine their effect on neurite growth from cultured neurons of Lymnaea stagnalis and embryonic chicks. Both of these toxins decreased the percentage of neurons growing neurites, mean neurite length, and number of neurites/cell in a dose-dependent manner. DMSO increased the toxicity of permethrin and DDT in L. stagnalis neurons. EtOH was not used as a solvent with the embryonic chick cultures. Pre-existing neurites of L. stagnalis neurons exposed to permethrin regressed in a dose- and time-dependent manner. These two toxins may affect neurite outgrowth through interference with intracellular calcium regulation.

Tetrodotoxin Poisoning

Tetrodotoxin (TTX) is one of the most potent and oldest known neurotoxins. The poisoning cases due to ingestion of TTX-containing marine animals, especially for puffer, have frequently occurred in Asia since a long time ago. This chapter describes various topics on TTX poisoning including the tendency of poisoning incidents, typical case report, treatment and prevention, biology distribution, original source, infestation mechanism, detection methods, characteristics of chemistry and pharmacology, and therapeutic application. Furthermore, the protocols for how to make puffer safe to eat and how to prevent puffer products made from toxic puffers have been suggested. Finally, the biological significance and neurophysiological role of TTX have been elucidated and TTX may act as an important drug like anesthetic in future.

Structure–activity relationships for the action of 11 pyrethroid insecticides on rat Nav1.8 sodium channels expressed in Xenopus oocytes

Pyrethroid insecticides bind to voltage-sensitive sodium channels and modify their gating kinetics, thereby disrupting nerve function. This paper describes the action of 11 structurally diverse commercial pyrethroid insecticides on the rat Na v 1.8 sodium channel isoform, the principal carrier of the tetrodotoxin-resistant, pyrethroid-sensitive sodium current of sensory neurons, expressed in Xenopus laevis oocytes. All 11 compounds produced characteristic sodium tail currents following a depolarizing pulse that ranged from rapidly-decaying monoexponential currents (allethrin, cismethrin and permethrin) to persistent biexponential currents (cyfluthrin, cyhalothrin, cypermethrin and deltamethrin). Tail currents for the remaining compounds (bifenthrin, fenpropathrin, fenvalerate and tefluthrin) were monoexponential and decayed with kinetics intermediate between these extremes. Reconstruction of currents carried solely by the pyrethroid-modified subpopulation of channels revealed two types of pyrethroid-modified currents. The first type, found with cismethrin, allethrin, permethrin and tefluthrin, activated relatively rapidly and inactivated partially during a 40-ms depolarization. The second type, found with cypermethrin, cyfluthrin, cyhalothrin, deltamethrin, fenpropathrin and fenvalerate, activated more slowly and did not detectably inactivate during a 40-ms depolarization. Only bifenthrin did not produce modified currents that fit clearly into either of these categories. In all cases, the rate of activation of modified channels was strongly correlated with the rate of tail current decay following repolarization. Modification of Na v 1.8 sodium channels by cyfluthrin, cyhalothrin, cypermethrin and deltamethrin was enhanced 2.3- to 3.4-fold by repetitive stimulation; this effect appeared to result from the accumulation of persistently open channels rather than preferential binding to open channel states. Fenpropathrin was the most effective compound against Na v 1.8 sodium channels from the perspective of either resting or use-dependent modification. When use dependence is taken into account, cypermethrin, deltamethrin and tefluthrin approached the effectiveness of fenpropathrin. The selective expression of Na v 1.8 sodium channels in nociceptive neurons suggests that these channels may be important targets for pyrethroids in the production of paresthesia following dermal exposure.

Mechanisms of pyrethroid neurotoxicity: implications for cumulative risk assessment

The Food Quality Protection Act (FQPA) of 1996 requires the United States Environmental Protection Agency to consider the cumulative effects of exposure to pesticides having a 'common mechanism of toxicity.' This paper reviews the information available on the acute neurotoxicity and mechanisms of toxic action of pyrethroid insecticides in mammals from the perspective of the 'common mechanism' statute of the FQPA. The principal effects of pyrethroids as a class are various signs of excitatory neurotoxicity. Historically, pyrethroids were grouped into two subclasses (Types I and II) based on chemical structure and the production of either the T (tremor) or CS (choreoathetosis with salivation) intoxication syndrome following intravenous or intracerebral administration to rodents. Although this classification system is widely employed, it has several shortcomings for the identification of common toxic effects. In particular, it does not reflect the diversity of intoxication signs found following oral administration of various pyrethroids. Pyrethroids act in vitro on a variety of putative biochemical and physiological target sites, four of which merit consideration as sites of toxic action. Voltage-sensitive sodium channels, the sites of insecticidal action, are also important target sites in mammals. Unlike insects, mammals have multiple sodium channel isoforms that vary in their biophysical and pharmacological properties, including their differential sensitivity to pyrethroids. Pyrethroids also act on some isoforms of voltage-sensitive calcium and chloride channels, and these effects may contribute to the toxicity of some compounds. Effects on peripheral-type benzodiazepine receptors are unlikely to be a principal cause of pyrethroid intoxication but may contribute to or enhance convulsions caused by actions at other target sites. In contrast, other putative target sites that have been identified in vitro do not appear to play a major role in pyrethroid intoxication. The diverse toxic actions and pharmacological effects of pyrethroids suggest that simple additivity models based on combined actions at a single target are not appropriate to assess the risks of cumulative exposure to multiple pyrethroids.

Insecticidal arylalkylbenzhydrolpiperidines: novel inhibitors of voltage-sensitive sodium and calcium channels in mammalian brain

Using preparations derived from whole mouse brain, we have demonstrated that insecticidal arylalkylbenzhydrolpiperidines inhibit the depolarization of synaptoneurosomes as measured by rhodamine 6G fluorescence and block 22Na+ uptake into synaptosomes, when veratridine is used as the activator. These insecticides also have the ability to potently displace the binding of [3H]batrachotoxinin A 20-alpha-benzoate ([3H]BTX-B) to neuronal sodium channels in a concentration-dependent manner. The study compounds can be classified as competitive inhibitors of radioligand binding, since they decrease the affinity of [3H]BTX-B for site 2 without affecting the concentration of sites labelled by this radioligand. Our kinetic analyses revealed that at its IC50, the 4-carbomethoxyaminobenzyl-piperidine analogue reduces the rate of association of [3H]BTX-B with site 2, whereas higher concentrations were required to accelerate dissociation of the [3H]BTX-B:sodium channel complex. These results indicate an ability to interact with both non-activated and persistently activated states of the voltage-sensitive sodium channel, but higher affinity for the former. Such a profile also implies that inhibition of [3H]BTX-B binding to site 2 occurs via an allosteric mechanism. In addition, arylalkylbenzhydrolpiperidines interact with presynaptic voltage-sensitive calcium channels, since we demonstrate that they inhibit increases in [free Ca++] and 45Ca++ uptake when evoked by high KC1 concentration in mouse brain synaptosomal preparations. Such effects generally occur at concentrations that are higher than those required to inhibit sodium channels. Blockade of sodium and calcium channels may therefore contribute to the in vivo neurological effects observed in rodents exposed to these insecticides.

Interaction of tetramethrin and deltamethrin at the single sodium channel in rat hippocampal neurons

Type I and type II pyrethroids are known to modulate the sodium channel to cause persistent openings during depolarization and upon repolarization. Although there are some similarities between the two types of pyrethroids in their actions on sodium channels, the pattern of modification of sodium currents is different between the two types of pyrethroids. In the present study, interactions of the type I pyrethroid tetramethrin and the type II pyrethroid deltamethrin at rat hippocampal neuron sodium channels were investigated using the inside-out single-channel patch clamp technique. Deltamethrin-modified sodium channels opened much longer than tetramethrin-modified sodium channels. When 10 microM tetramethrin was applied to membrane patches that had been exposed to 10 microM deltamethrin, deltamethrin-modified prolonged single sodium currents disappeared and were replaced by shorter openings which were characteristic of tetramethrin-modified channel openings. These single-channel data are compatible with previous whole-cell competition study between type I and type II pyrethroids. These results are interpreted as being due to the displacement of the type II pyrethroid molecule by the type I pyrethroid molecule from the same binding site or to the allosteric interaction of the two pyrethroid molecules at separate sodium channel sites.

Functional analysis of a rat sodium channel carrying a mutation for insect knock-down resistance (kdr) to pyrethroids

Pyrethroid insensitivity in resistant (kdr) insects has been correlated with a leucine to phenylalanine replacement in the S6 transmembrane segment of domain II of the axonal sodium channel alpha(para)-subunit. An alpha-subunit of rat brain type II sodium channel containing this mutation has been expressed and its sensitivity to permethrin compared with that of the wild-type channel. The steady-state activation curve of the mutant was shifted 14 mV in the depolarizing direction. We propose that an equivalent shift of the sodium current activation curve in kdr insects could account for their low sensitivity to permethrin toxicity.

Neuronal ion channels as the target sites of insecticides

Certain types of neuronal ions channels have been demonstrated to be the major target sites of insecticides. The insecticide-channel interactions that have been studied most extensively are pyrethroid actions on the voltage-gated sodium channel and cyclodiene/lindane actions on the GABAA receptor chloride channel complex. With the exception of organophosphate and carbamate insecticides which inhibit acetylcholinesterases, most insecticide commercially developed act on the sodium channel and the GABA system. Pyrethroids show the kinetics of both activation and inactivation gates of sodium channels resulting in prolonged openings of individual channels. This causes membrane depolarization, repetitive discharges and synaptic disturbances leading to hyperexcitatory symptoms of poisoning in animals. Only a very small fraction (approximately 1%) of sodium channel population is required to be modified by pyrethroids to produce severe hyperexcitatory symptoms. This toxicity amplification theory applies to pharmacological and toxicological action of other drugs that go through a threshold phenomenon. Selective toxicity of pyrethroids between invertebrates and mammals can be explained based largely on the responses of sodium channels and partly on metabolic degradation. The pyrethroid-sodium channel interaction is also supported by Na+ uptake and batrachotoxin binding experiments. Cyclodienes and lindane exert a dual action on the GABAA system, the initial transient stimulation being followed by a suppression. The stimulation requires the presence of the gamma 2 subunit. The suppression of the GABA system is also documented by Cl- flux and ligand binding experiments. It appears that the sodium channel and the GABA system merit continuing efforts for development of newer and better insecticides. Nitromethylene heterocycles including imidacloprid act on nicotinic acetylcholine receptors. Insect receptors are more sensitive to these compounds than mammalian receptors. Single-channel analyses of the nicotinic acetylcholine receptor of PC12 cells have shown that imidacloprid increases the activity of subconductance state currents and decreases that of main conductance state currents. This may explain the imidacloprid suppression of acetylcholine responses.

Differential effects of the pyrethroid tetramethrin on tetrodotoxin-sensitive and tetrodotoxin-resistant single sodium channels

The differential effects of the pyrethroid tetramethrin on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) single sodium channel currents in rat dorsal root ganglion (DRG) neurons were investigated using the outside-out configuration of patch-clamp technique. Channel conductances were 10.7 and 6.3 pS for TTX-S and TTX-R sodium channels, respectively, at a room temperature of 24-26 degrees C. The single-channel current of TTX-S sodium channels at the test potential of -30 mV was -1.27 +/- 0.25 pA, and was not changed after exposure to 10 microM tetramethrin (-1.28 +/- 0.23 pA). The open time histogram of TTX-S single-channel currents could be fitted by a single exponential function with a time constant of 1.27 ms. After exposure to 10 microM tetramethrin, the open time histogram could be fitted by the sum of two exponential functions with time constants of 1.36 ms (tau fast) and 5.73 ms (tau slow). The percentage of contribution of each component to the population was 62% for the fast component representing the normal channels and 38% for the slow component representing the tetramethrin modified channels. The amplitude of TTX-R single-channel currents was slightly changed from -0.72 +/- 0.14 to -0.83 +/- 0.07 pA by 10 microM tetramethrin. The open time histogram of TTX-R single-channel currents could be fitted by a single exponential function with a time constant of 1.92 ms. In the presence of 10 microM tetramethrin, the open time histogram could be fitted by the sum of two exponential functions with time constants of 2.07 ms (tau fast) and 9.75 ms (tau slow). The percentage of contribution of each component was 15% for the fast, unmodified component and 85% for the slow, modified component. Differential effects of tetramethrin on the open time distribution of single sodium channel currents explains the differential sensitivity of TTX-S and TTX-R sodium channels.

Interactions of tetramethrin, fenvalerate and DDT at the sodium channel in rat dorsal root ganglion neurons

Type I and type II pyrethroids and dichlorodiphenyltrichloroethane (DDT) are known to modulate the sodium channel to cause the hyperexcitatory symptoms of poisoning in animals. However, since the degrees to which neuronal sodium channel parameters are altered differ, a question is raised as to whether these insecticides bind to the same site in the sodium channel. Competition patch-clamp experiments were performed using rat dorsal root ganglion neurons which are endowed with tetrodotoxin-sensitive and tetrodotoxin-resistant sodium channels. D-trans-Tetramethrin, S,S-fenvalerate and p,p'-DDT caused a slowly rising and slowly falling tail current to be developed in tetrodotoxin-sensitive sodium channels. In tetrodotoxin-resistant sodium channels, these insecticides, particularly tetramethrin and fenvalerate, generated a large and prolonged tail current upon repolarization. The effects of tetramethrin were reversible after washing with drug-free solution, whereas the effects of fenvalerate and DDT were irreversible. When fenvalerate application was followed by tetramethrin application, the characteristic changes in current by fenvalerate disappeared and the characteristic changes by tetramethrin appeared. After washout, the characteristic current pattern of fenvalerate reappeared. These results can be explained by assuming that the tetramethrin molecule displaces the fenvalerate molecule from the same binding site in the sodium channel protein, or that tetramethrin and fenvalerate bind to separate sodium channel sites which interact allosterically with each other. DDT interacted with fenvalerate and tetramethrin in the same manner.

Differential sensitivity of tetrodotoxin-sensitive and tetrodotoxin-resistant sodium channels to the insecticide allethrin in rat dorsal root ganglion neurons

The pyrethroid insecticides are known to modify neuronal sodium channels to cause a prolongation of whole cell current. The sodium channels expressed in the dorsal root ganglion neurons of the rat are of two types, one highly sensitive to tetrodotoxin and the other highly resistant to tetrodotoxin. The pyrethroid allethrin exerted profound effects on tetrodotoxin-resistant sodium channels while causing minimal effects on tetrodotoxin-sensitive sodium channels. Currents derived from tetrodotoxin-resistant sodium channels were greatly prolonged during a step depolarization; the tail currents upon repolarization were also augmented and prolonged. In the tetrodotoxin-sensitive sodium channel currents, these changes caused by allethrin were much smaller or negligible. The activation and inactivation voltages of tetrodotoxin-resistant peak sodium currents were not significantly altered by allethrin. The differential action of allethrin on the two types of sodium channels would be important not only in identifying the target molecular structure but also in interpreting the symptoms of poisoning in mammals.

Sodium and GABA-activated channels as the targets of pyrethroids and cyclodienes

The symptoms of poisoning by the pyrethroid and cyclodiene insecticides are characterized by hyperexcitation and convulsions followed by paralysis. The main target site of the pyrethroids has been identified to be the sodium channels which are kept open for unusually long periods of time, causing a prolonged sodium current to flow which, in turn, leads to hyperexcitation of the nervous system. We have now found large differential sensitivity to the pyrethroids in two types of sodium channels. The dorsal root ganglion neurons of the rat were endowed with two types of sodium channels, one sensitive to the blocking action of tetrodotoxin (TTX) and the other insensitive to TTX. The type I pyrethroid allethrin and the type II pyrethroid deltamethrin were both effective in prolonging the sodium current in the TXX-resistant sodium channel but had only a small effect on the TTX-sensitive sodium channel. These two types of sodium channels also exhibited marked differences in their physiological properties, including the time course of current, the activation voltage, and the steady-state inactivation. In contrast to the pyrethroids, lindane and the cyclodienes endrin, isobenzan, dieldrin and heptachlor-epoxide suppressed the GABA-induced chloride current. The initial transient component of the chloride current was blocked more than the late sustained component. The suppression of the GABA-mediated synaptic inhibition would cause hyperexcitation of the nervous system. The results are compatible with the convulsant action of these insecticides.

Modulation of nerve membrane sodium channel activation by deltamethrin

Deltamethrin is a highly potent pyrethroid insecticide that causes hypersensitivity, choreoathetosis, tremors, and paralysis in mammals. It is known to modify the sodium channel in such a way as to prolong the tail current associated with step repolarization following a depolarizing pulse. Using the axial-wire voltage-clamp technique with the giant axon of the squid Loligo pealei, we have demonstrated that deltamethrin also greatly slows the opening of the sodium channel. This was first observed as a decrease, by as much as 80%, in the peak sodium current flowing during a short, 10 ms depolarization. Current flowing through these slowly opening deltamethrin modified sodium channels was observed during the first depolarizing pulse after deltamethrin exposure and developed with a time constant of 320 ms. This supports the idea that deltamethrin can modify sodium channels when they are in the closed or resting state. Further, evidence of this hypothesis was provided by experiments using 0.1 and 10 microM deltamethrin and measuring the tail current amplitude after depolarizing pulses of varying duration (1-1200 ms). The mean time constant for the increase in tail current amplitude was almost concentration independent; 253 ms at 0.1 microM and 193 ms at 10 microM. We conclude that deltamethrin modifies the activation kinetics of sodium channels in such a way as to slow opening and that this modification occurs predominantly when channels are in the closed or resting state.

Nerve membrane Na+ channels as targets of insecticides

The mechanisms of action of neuroactive insecticides on the nervous system has been studied for many years. It is now well established that severe neurological symptoms of poisoning with pyrethroids and DDT in mammals and insects are the result of modification of Na+ channel activity. Toshio Narahashi discusses the history, approaches and results of the studies leading to this conclusion. Advanced electrophysiological experiments using voltage clamp and patch clamp, together with ligand-binding and ionic flux experiments, have unveiled unique actions of pyrethroids and DDT of keeping the Na+ channel in the open state for an extremely long period, sometimes as long as several seconds. This modification of Na+ channel properties leads to hyperactivity of the nervous system. These insecticides have also been shown to suppress GABA and glutamate receptor-channel complexes and voltage-activated Ca2+ channels, but the toxicological significance of these actions remains to be seen. The results of these studies provide clues for developing newer insecticides with higher selectivity between mammals and insects and for coping with the problem of insecticide resistance.

Block of deltamethrin-modified sodium current in cultured mouse neuroblastoma cells: local anesthetics as potential antidotes

Effects of local anesthetics and anticonvulsants on the pyrethroid-modified sodium current in cultured mouse neuroblastoma cells have been investigated using the suction pipette voltage clamp technique. In the presence of 10 microM of the pyrethroid deltamethrin the sodium current consists of an enhanced peak current during membrane depolarization and a slowly decaying, deltamethrin-induced tail current remaining after repolarization. At the onset of block the local anesthetics tetracaine, lidocaine and QX 314 reduced the deltamethrin-induced tail current more effectively than the peak current. Lidocaine, but not phenytoin, caused a time-dependent block of tail currents evoked by membrane depolarizations lasting 10-1000 ms. Both lidocaine- and phenytoin-induced blocks were independent of the membrane potential during the tail current. The anticonvulsants phenytoin, phenobarbital and valproate blocked the tail and the peak sodium current to the same extent, but diazepam, mephenesin and urethane blocked the peak current more effectively. Vitamin E, which suppresses pyrethroid-induced paresthesia of the skin, had no effect on the voltage-dependent sodium current. It is concluded that indirect effects of anticonvulsants on pyrethroid-induced toxic symptoms predominate, whereas local anesthetics preferentially block the pyrethroid-induced tail current. Therefore, local anesthetics are potentially useful pyrethroid antidotes.

Pyrethroid modifications of the activation and inactivation kinetics of the sodium channels in squid giant axons

The kinetics of sodium channel activation and inactivation were analyzed in the squid giant axons internally treated with various pyrethroids. Pyrethroids increased the steady-state sodium current in squid giant axons by removing the inactivation. The steady-state sodium conductances in control and pyrethroid-treated axons showed the same voltage dependence, indicating that the removal of inactivation by pyrethroids did not lead to an alteration of gating charge transfer. The pyrethroid-modified sodium channels were activated with a biphasic time course involving the movement of at least two gating particles, and both components were voltage-dependent. The slower component was abolished by treatment with either pronase or N-bromoacetamide. The net elementary charges transported in the electric membrane field were reduced in the course of slow activation of the pyrethroid-induced sodium current. It appears that the 'immobilization' of gating charge is related to the slow activation rather than the inactivation of the sodium channel.

Neurotoxicological effects and the mode of action of pyrethroid insecticides

Neuroexcitatory symptoms of acute poisoning of vertebrates by pyrethroids are related to the ability of these insecticides to modify electrical activity in various parts of the nervous system. Repetitive nerve activity, particularly in the sensory nervous system, membrane depolarization, and enhanced neurotransmitter release, eventually followed by block of excitation, result from a prolongation of the sodium current during membrane excitation. This effect is caused by a stereoselective and structure-related interaction with voltage-dependent sodium channels, the primary target site of the pyrethroids. Near-lethal doses of pyrethroids cause sparse axonal damage that is reversed in surviving animals. After prolonged exposure to lower doses of pyrethroids axonal damage is not observed. Occupational exposure to pyrethroids frequently leads to paresthesia and respiratory irritation, which are probably due to repetitive firing of sensory nerve endings. Massive exposure may lead to severe human poisoning symptoms, which are generally treated well by symptomatic and supportive measures.

Kinetic properties of single sodium channels modified by fenvalerate in mouse neuroblastoma cells

(1) The kinetic properties of single sodium channels modified by the pyrethroid fenvalerate have been analyzed by patch clamp techniques using the cultured mouse neuroblastoma cells. (2) Fenvalerate drastically prolonged the open time of single sodium channels from the normal value of 5 ms to several hundred milliseconds during a depolarizing pulse. The channels remained open after termination of a depolarizing pulse for as long as several seconds. (3) The channel lifetime varied with the membrane potential, attained a maximum at -70 mV, and decreased with hyperpolarization and depolarization from -70 mV. (4) Prolonged openings of the modified channels allowed a current-voltage curve for a single channel to be plotted by sweeping a ramp pulse. The single channel conductance had a value of 11 pS and was linear over potentials ranging from 0 to -100 mV. (5) Power density spectral analysis of the open channel current noise indicated a single Lorentzian curve with a cut-off frequency at 90 Hz, indicating that the increase in noise during channel opening resulted from a relatively slow kinetic process. (6) The probability of the channel being modified by fenvalerate was independent of the length of time during which the channel was opened. This observation suggests that channel modification had taken place before the channel opened. This study of the prolonged opening at the single channel level provides a new insight into open channel properties and the kinetics of channel modification.

Modification by pyrethroids and DDT of phosphorylation activities of rat brain sodium channel

The effects of pyrethroids and DDT on the alpha-subunit protein of the rat brain sodium channel were studied by using both native and exogenously added cAMP-dependent protein kinases. For this purpose, the sodium channel was partially purified, using the method of Hartshorne and Catterall [J Biol Chem 259: 1667-1675, 1984], and 32P-phosphorylated using [gamma-32P]ATP and exogenously added catalytic subunit of cAMP-dependent protein kinase. By comparing the phosphorylation patterns of the isolated sodium channel to those of the partially purified or unpurified (i.e. intact synaptosomes) preparations, it was concluded that the alpha-subunit of the voltage-sensitive sodium channel protein is the only phosphorylatable protein present at the 260 kD molecular weight range on the sodium dodecyl sulfate-polyacrylamide gel electrophoretogram. Phosphorylation of the alpha-subunit was induced by depolarization, and this process was inhibited by 10(-6) to 10(-10) M 1R-deltamethrin, but not by 1S-deltamethrin, the latter being an inactive enantiomer of the former. DDT produced a similar effect, but only at a higher concentration range. By using lysed synaptosomal membranes, it was possible to study the direct effects of these compounds on the alpha-subunit, which were similar to those produced by depolarization of intact synaptosomes.

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.

Interaction of insecticides of the pyrethroid family with specific binding sites on the voltage-dependent sodium channel from mammalian brain

Measurement of neurotoxin binding in rat brain membranes and neurotoxin-activated 22Na+ influx in neuroblastoma cells were used to define the site and mechanism of action of pyrethroids and DDT on sodium channels. A highly potent pyrethroid, RU 39568, alone enhanced the binding of [3H]batrachotoxinin A 20-alpha-benzoate up to 30 times. This effect was amplified by the action of neurotoxins such as sea anemone toxins and brevetoxin acting at different sites of the sodium channel protein in brain membranes. The ability of various pyrethroids and DDT to enhance batrachotoxin binding was related to their capacity to activate tetrodotoxin sensitive 22Na+ uptake. These results point to an allosteric mechanism of pyrethroids and DDT action involving preferential binding to active states of sodium channels which have high affinity for neurotoxins, causing persistent activation of sodium channels. Pyrethroids do not block [3H]tetrodotoxin binding, 125I-Anemonia sulcata toxin 2 binding, 125I-Tityus serrulatus toxin gamma binding at neurotoxin receptor sites 1, 3 and 4 respectively. Pyrethroids appear to act at a new neurotoxin receptor site on the sodium channel. The distribution of pyrethroid binding sites in rat brain was determined by quantitative autoradiographic procedures using the property of pyrethroids to reveal binding sites for [3H]batrachotoxinin A 20-alpha-benzoate.

Effect of deltamethrin on transient outward currents in identified snail neurons

1. The effect of a pyrethroid insecticide deltamethrin was investigated on transient outward potassium currents of identified snail (Helix pomatia) neurones LPa1 and RPa3. 2. In 5 x 10(-5)M concentration the deltamethrin decreased the IA amplitude and the slope of I-V curve. The activation variable was shifted left along the voltage axis by 10-20 mV, while the inactivation variable remained unchanged. 3. Time constant of inactivation decreased, and the relaxation of IA described by one exponential. "Modified" ionic channel fraction was not observed. 4. It is suggested that deltamethrin acts on IA channels through a different molecular mechanism to INa channels, since not only the gating machinery but the permeability of the channels were influenced.

Activity of tralomethrin to modify the nerve membrane sodium channel

Deltamethrin is a potent type II pyrethroid insecticide which can modify sodium channel gating kinetics in nerve membranes. The actions of another type II pyrethroid tralomethrin to modify sodium channel kinetics have been ascribed to deltamethrin, to which tralomethrin is known to be converted under certain experimental conditions. The objective of this study was to determine if tralomethrin was intrinsically active in modifying the nerve membrane sodium channel, the major target site of pyrethroids. Experiments were performed using the squid giant axon under voltage-clamp conditions. In axons treated with either pyrethroid, a large sodium tail current was generated upon repolarization from a depolarized level and decayed slowly with a dual exponential time course. The fast time constant for tralomethrin was 165 +/- 110 msec and the slow time constant was 3793 +/- 802 msec. For deltamethrin the time constants were significantly shorter, the fast time constant being 34 +/- 6 msec and the slow time constant being 835 +/- 282 msec. The cumulative dose-response relation of tralomethrin revealed two binding sites with apparent dissociation constants of 0.06 and 5 microM. Deltamethrin appeared to bind to only one site with an apparent dissociation constant of 0.25 microM. It is clear that there are large differences in the gating kinetics of the sodium channels modified by tralomethrin and deltamethrin which are incompatible with the idea that tralomethrin is active only after conversion to deltamethrin. The differences in sodium channel gating kinetics after modification by tralomethrin versus deltamethrin indicate that tralomethrin is intrinsically active in modifying the nerve membrane sodium channels.

Toxins that modulate the sodium channel gating mechanism

A variety of toxins and chemicals has been shown to modulate the gating kinetics of the sodium channel. Studies of batrachotoxin, grayanotoxins and pyrethroids are summarized here as examples. Batrachotoxin and grayanotoxins eliminate the sodium channel inactivation thereby causing a prolonged, steady-state sodium current to flow during a depolarizing step. The sodium channel activation kinetics are not affected markedly. Batrachotoxin appears to bind to a site in the sodium channel to which the inactivation gate normally binds, thus causing an inhibition of sodium inactivation. Single channel recording experiments have shown that the mean open time of individual sodium channels is greatly prolonged by batrachotoxin. It appears that individual sodium channels are modified by batrachotoxin in an all-or-none manner. Pyrethroids which are synthetic derivatives of pyrethrins also modify the kinetics of sodium channels in a very drastic manner. In the presence of type I pyrethroids which lack a cyano group at the alpha position (e.g., allethrin and tetramethrin), a large steady-state sodium current appears during a step depolarization and a large slowly decaying sodium tail current appears upon repolarization. Thus both the activation and inactivation kinetics are slowed. Type II pyrethroids which contain an alpha-cyano group (e.g., deltamethrin, cyphenothrin, and fenvalerate) exert effects on sodium channels qualitatively similar to those of type I pyrethroids. However, the amplitudes of the steady-state sodium current and sodium tail current are smaller and the time constant of tail current decay is much longer. The mean open time of single sodium channels is greatly prolonged by the pyrethroids, and the effect is much more pronounced in type II than in type I pyrethroids. A high degree of stereospecificity has been found among four isomers of tetramethrin, (+)-trans and (+)-cis isomers being highly active and (-)-trans and (-)-cis isomers almost totally inactive. The inactive isomers bind to the sodium channel sites, thus preventing the action of the active isomers. Because of the unique action of pyrethroids in modulating the sodium channels, they are becoming useful tools for channel physiology and pharmacology.

Stabilization of sodium channel states by deltamethrin in mouse neuroblastoma cells

The effect of the pyrethroid insecticide deltamethrin on sodium channels of mouse neuroblastoma cells was investigated using the patch-clamp technique. The study was aimed at determining how the effects of deltamethrin at the whole cell level would be reflected in the modified properties of single sodium channel currents. Whole cell recording showed that deltamethrin prolonged sodium currents in neuroblastoma cells by several orders of magnitude. Single channel recordings showed that a variety of channel states were prolonged by deltamethrin. Not only was the open state prolonged by several orders of magnitude but a closed or inactivated state was also prolonged, leading to less frequent channel openings. A subconducting state and a flickering state were observed in the presence of deltamethrin as well as a state in which channels opened with some delay after the termination of a depolarizing pulse. The results are compatible with the hypothesis that deltamethrin stabilizes a variety of channel states by reducing the transition rates between them. This allows states that are normally very brief to be detected more easily.

Ion permeation and selectivity of squid axon sodium channels modified by tetramethrin

The pyrethroid tetramethrin greatly prolongs the sodium current during step depolarization and the sodium tail current associated with step repolarization of the squid axon membrane. Non-linear current-voltage relationships for the sodium tail current were analyzed to assess the open sodium channel properties which included the permeation of various cations, calcium block and cation selectivity. Tetramethrin had no effect on any of these properties. It was concluded that tetramethrin modifies the sodium channel gating machinery without affecting the pore properties.

Dissociation between circling behaviour and striatal dopamine activity following unilateral deltamethrin administration to rats

The neurotoxic pyrethroid, deltamethrin, induces a severe motor syndrome characterised by tremor and choreoathetosis when injected systemically to rats. The interaction between deltamethrin and the two major dopaminergic pathways - the nigrostriatal and mesolimbic pathways - was investigated in rats. Striatal catecholamines, indoleamines and metabolites were measured by HPLC with electrochemical detection. Unilateral injection of deltamethrin (1.0 microgram) into the ventral tegmental nucleus or substantia nigra induced rapid ipsilateral or contralateral circling respectively but was ineffective at other basal ganglia sites. Both the sham and vehicle injections at either site, resulted in a marked increase above normal in DA turnover in the ipsilateral striatum without inducing circling behaviour. DA turnover was increased to the same extent in the ipsilateral stratum of deltamethrin-treated rats where rapid circling was present. Therefore the neurochemical findings were not consistent with the rotation theories based on striatal DA asymmetry but rather followed alternative mechanisms previously proposed, where circling behaviour can occur by mechanisms not causally related to striatal DA. These findings also indicate that a degree of selectivity exists in the action of deltamethrin, a sodium channel toxin that might be expected to act on all neuronal systems within the SN or VTN or equally at other sites within the basal ganglia associated with circling behaviour.

Voltage-dependent calcium block of normal and tetramethrin-modified single sodium channels

The mechanisms by which external Ca ions block sodium channels were studied by a gigaohm seal patch clamp method using membranes excised from N1E-115 neuroblastoma cells. Tetramethrin was used to prolong the open time of single channels so that the current-voltage relationship could be readily determined over a wide range of membrane potentials. Comparable experiments were performed in the absence of tetramethrin. Increasing external Ca ions from 0.18 to 9.0 mM reduced the single channel conductance without causing flickering. From the dose-response relation the dissociation constant for Ca block at 0 mV was estimated to be 32.4 +/- 1.05 mM. The block was intensified by hyperpolarization. The voltage dependence indicates that Ca ions bind to sodium channels at a site located 37 +/- 2% of the electrical distance from the outside. The current increased with increasing external Na concentrations but showed a saturation; the concentration for half-maximal saturation was estimated to be 185 mM at -50 mV and 204 mM at 0 mV. A model consisting of a one-ion pore with four barriers and three wells can account for the observations that deviate from the independence principle, namely, the saturation of current, block by Ca ions, and rectification in current-voltage relationship. The results suggest that the Ca-induced decrease of the macroscopic sodium current results from a reduced single sodium channel conductance.

Drug-ionic channel interactions: single-channel measurements

Ionic channels of excitable membranes are the basic site where ionic fluxes take place during the generation of action potentials. A variety of natural toxins, chemicals, and therapeutic drugs have been found to modify the gating kinetics of the Na+ channels, thereby altering the excitation pattern. Studies of such chemical modulations of Na+ channel gating provide the basis for understanding the mechanisms underlying the epilepsies and the actions of anticonvulsant drugs. Certain chemicals and toxins have been found to drastically slow the kinetics of the opening and closing of the Na+ channel. For example, batrachotoxin, the grayanotoxins, and the pyrethroids modify a population of the Na+ channels to give rise to an extremely slow opening and closing. Patch clamp techniques developed during the past few years permit measurements of the opening and closing of individual ionic channels. When an isolated membrane patch is depolarized, squared inward currents of about 1 picoampere in amplitude and 2 ms in duration are observed at 10 degrees C. After exposure of the membrane to batrachotoxin, open time is prolonged, single-current amplitude is greatly reduced, and channel opening is observed at large negative potentials, where no opening is expected to occur in normal preparations. In the batrachotoxin-poisoned membrane there are two separate groups of Na+ channels: one exhibiting normal characteristics and the other exhibiting a prolonged opening and reduced amplitude.