Action of pyrethroids on a nerve-muscle preparation of the clawed frog,Xenopus laevis

The effects of a range of pyrethroids on end-plate potentials and muscle action potentials were studied in the pectoralis nerve-muscle preparation of the clawed frog, Xenopus laevis. The noncyano pyrethroids allethrin, cismethrin, bioresmethrin, and IR-cisphenothrin caused moderate presynaptic repetitive activity only, resulting in the occurrence of multiple end-plate potentials (epps). Trains of repetitive muscle action potentials without presynaptic repetitive activity were observed after the α-ethynyl pyrethroid S-5655 and after the α-cyano pyrethroids cypermethrin, deltamethrin, FCR 1272, and FCR 2769. An intermediate group of pyrethroids consisting of the non-cyano compounds 1R-permethrin, des-cyano-deltamethrin, NAK 1901 and NAK 1963, and the α-cyano pyrethroids cyphenothrin and fenvalerate caused both types of effect. The insecticidally inactive S-enantiomers of permethrin had no effect on the nerve-muscle preparation. Trains of repetitive action potentials in pyrethroid-treated muscle fibers were followed by a depolarizing afterpotential which in general decayed more rapidly for the non-cyano pyrethroids than for the α-cyano pyrethroids. The rate of decay of the depolarizing afterpotential decreased gradually as the temperature was lowered, whereas the pre- and postsynaptic repetitive activity remained largely unaffected over a large temperature range. It is concluded that in muscle membrane like in nerve membrane the pyrethroid-induced repetitive activity is due to a prolongation of the sodium current and that a clear distinction between non-cyano pyrethroids on the one hand and α-cyano compounds on the other cannot be made on the basis of the present results.     

Structure-related effects of pyrethroid insecticides on the lateral-line sense organ and on peripheral nerves of the clawed frog, Xenopus laevis

The effects of seven different pyrethroid insecticides on the lateral-line sense organ and on peripheral nerves of the clawed frog, Xenopus laevis, were investigated by means of electrophysiological methods. The results show that two classes of pyrethroid can be clearly distinguished. (i) Pyrethroids without an α-cyano group (permethrin, cismethrin, and bioresmethrin). These noncyano pyrethroids induce short trains of nerve impulses in the lateral-line sense organ. In peripheral nerve branches they induce a depolarizing afterpotential and repetitive firing. These effects are very similar to those previously reported for allethrin. (ii) Pyrethroids with an α-cyano-3-phenoxybenzyl alcohol (cypermethrin, fenpropathrin, deltamethrin, and fenvalerate). In the lateral-line sense organ these α-cyano pyrethroids induce very long trains of nerve impulses which may last for seconds and may contain hundreds or even thousands of impulses. The α-cyano compounds do not cause repetitive activity in peripheral nerves. Instead they induce a quickly reversible, stimulus frequency-dependent suppression of the action potential. Since the chemical structure of cypermethrin differs from that of permethrin only in the α-cyano group and because all four α-cyano compounds act in a very similar way, it is concluded that the α-cyano substituent is responsible for the large differences in neurotoxic effects. In the lateral-line sense organ the duration of nerve impulse trains induced by the noncyano as well as the α-cyano pyrethroids increases dramatically when the temperature is lowered. Further, in sensory fibers the effects of both classes of pyrethroid on the nerve action potential are more pronounced compared to their effects on motor fibers. It is argued that the different neurotoxic effects reported here originate from a common mechanism of action of pyrethroids, which is a prolongation of the transient increase of sodium permeability of the nerve membrane associated with excitation.It is concluded that the sodium channel in the nerve membrane is the major target site of noncyano and α-cyano pyrethroids.     

Neuropharmacological studies of an insecticidal trihaloimidazole derivative in the crayfish neuromuscular preparation

A trihaloimidazole derivative (S-377; 1-(4-chlorobutoxymethyl)-2,4,5-trichloroimidazole) caused giant excitatory junctional potentials by a single electrical stimulus to the excitatory nerves. Repetitive discharges were simultaneously induced in the nerve fibres. S-377 also caused repetitive firing in the inhibitory nerve fibres. Permethrin showed quite similar actions on both the junction and nerve fibres. It was supposed that S-377 inhibited the inactivating system of the sodium channel, like pyrethroids. However, S-377 reduced the number of spikes of the permethrin-induced repetitive discharges on the excitatory nerve fibres. These observations suggest that binding sites of S-377 on sodium channels are different from those of pyrethroids.     

The importance of nerve terminal depolarization in pyrethroid poisoning of insects

The effects of several pyrethroids and DDT were examined on neuromuscular preparations from larvae of Musca domestica, Culex quinquefasciatus, Anopheles stephensi, and Trichoplusia ni, in order to determine the importance of the type I effect (repetitive firing) and the type II effect (increased miniature excitatory postsynaptic potential (mepsp) rate, indicating nerve terminal depolarization) in the poisoning process. α-Cyano pyrethroids were very potent in increasing mepsp rate, and although DDT and non-α-cyano compounds were more potent at inducing repetitive firing, all these compounds increased mepsp rate at higher concentrations. A variety of evidence showed that the mepsp rate-increasing activity could be an important factor in toxicity: among all of the compounds, there was a positive correlation between toxicity and mepsp rate-increasing activity; mepsp rate-increasing activity had a negative temperature dependence; nerves of kdr larvae in vitro were resistant to the mepsp rate-increasing activity, commensurate with resistance level; and finally, increased mepsp rate and neuromuscular block were observed in poisoned insects, associated with paralysis. Among type I compounds, repetitive firing activity was correlated negatively with toxicity, but positively with knockdown activity.     

Recent studies on the effects of DDT and pyrethroid insecticides on nervous activity in cockroaches

A summary is given of the results of three sets of electrophysiological experiments on the American cockroach (Periplaneta americana). The effects of DDT and S-bioallethrin [bioallethrin (S)-cyclopentenyl isomer] on single giant axons were studied using the voltage-clamp technique. Whereas both molecules induced long tails of inward (sodium ion) current, the voltage and time-dependency of these tails differed. With DDT, the tail was proportional to the activation of the peak current and decreased with the duration of the pulse, suggesting that the molecules were bound to open sodium channels and delayed their closing. With S-bioallethrin, the voltage dependency of the tail was different from that of the peak current, and the tail current increased exponentially with the duration of the depolarisation, suggesting that the pyrethroid insecticide modified resting (or silent) sodium channels into slowly activating channels. Modified action potentials, mimicking those produced by the two molecules, were computed on the basis of these results. Deltamethrin, one of the most potent pyrethroid insecticides, was applied topically on a leg mechanoreceptor and was found to have little effect on the local ‘receptor potential’ but to inhibit action potential production. The effects of topical applications of deltamethrin on the dorsal part of the abdomen, on nervous activity in the abdominal connectives, were studied under different experimental conditions. The results suggest that the insecticide molecules diffused rapidly through the cuticle, were concentrated in the haemolymph, and eventually reached the central nervous system, where they inhibited nerve activity.     

Carbofuran triggers flight motor output in pyrethroid-blocked reflex pathways of the house fly

The initiation of flight from loss of tarsal contact (flight reflex responses) and the tergotrochanteral muscle (TTM) responses evoked by brain stimulation were analyzed during carbofuran, permethrin, deltamethrin, and DDT poisoning in the house fly. Blockage of the flight reflex by LD₅₀ doses of permethrin or deltamethrin was rapid, but the effects of DDT on the flight reflex took hours to develop. In addition, carbofuran treatment induced spontaneous flight in blocked preparations by an action in the central nervous system. This result suggests that pyrethroid blockage of the flight reflex was due to an action on sensory nerves, since the central flight program and its associated efferent systems were functionally intact. The relevance of this finding in terms of pyrethroid knockdown is discussed. The TTM response was unaffected by permethrin or deltamethrin both early and late in the poisoning process, possibly because the evoked TTM response does not involve peripheral sensory nerves, which seem to be important sites of pyrethroid action early in poisoning. Carbofuran induced repetitive firing and blockage of the TTM response within 1 hr, but normal responses were observed late in poisoning, which is consistent with the reversibility of carbamate inhibition of acetylcholinesterase. DDT caused no change in the evoked TTM response until bursts were recorded about 15 hr after treatment; this was another example of a slowly developing DDT effect. The protracted development of various DDT actions was concordant with a hypothesis of reduced efficacy at a proposed target site, viz., the sodium channels of nerve membranes.     

Depolarization of motor nerve terminals by pyrethroids in susceptible and kdr-resistant house flies

When applied at concentrations of one nM or higher to a house fly larval neuromuscular preparation, deltamethrin (DM) and fenvalerate (FV) greatly increased miniature excitatory postsynaptic potential (mepsp) rate and blocked neuromuscular transmission. The DM-induced mepsp discharge was abolished by tetrodotoxin (TTX), removal of Ca²⁺ from the saline, or by application of hyperpolarizing stimuli to the nerve, indicating that it was due to depolarization of the presynaptic terminals. Also, in the presence of TTX, K⁺ depolarization increased mepsp rate at the same external K⁺ concentration before and after DM treatment, confirming that DM released transmitter by depolarizing the nerve terminals rather than by altering the voltage dependence of transmitter release. The potassium channel blocker tetraethylammonium (TEA) increased mepsp rate somewhat, while aconitine (20 μM), which keeps sodium channels open, increased mepsp rate consistently. Pretreatment of nerves with a subthreshold dose of TEA greatly increased the mepsp rate-increasing activity of DM and aconitine, while a subthreshold level of aconitine did not synergize DM. These observations suggest that DM, like aconitine, depolarized nerves by modifying the sodium channels. Knockdown resistant (kdr) larvae were resistant to the depolarizing action of DM and aconitine but not to that of TEA, indicating that the kdr gene produced a modified sodium channel which was less sensitive to the action of pyrethroids and aconitine. During sustained transmitter release by DM, evoked release gradually declined, resulting in a condition called early block in which spontaneous release was high and release could be evoked by electrotonic depolarization of the nerve terminals, but not by a nerve action potential. Early block was probably due to conduction block in the nerve terminals. Early block eventually gave way to late block, characterized by the decline of spontaneous release to subnormal levels and complete failure of evoked release. After late block, the calcium ionophore X-537A could not release transmitter, suggesting that late block was due to depletion of available transmitter. DM did not have a direct effect upon extrasynaptic muscle membrane. However, after late block, muscles were left insensitive to the putative transmitters glutamate and aspartate when these were bath or iontophoretically applied. A low rate of mepsps persisted after late block, indicating that the muscles were still sensitive to the natural transmitters.     

Deltamethrin: A neurophysiological study of the sites of action

Recent experiments on the mode of action of pyrethroids have indicated that those pyrethroids containing an α-cyano phenoxybenzyl group may act on GABA-mediated chloride channels. The crayfish stretch receptor neuron provides a useful preparation for examining the effects of pyrethroids on these channels and on sodium channels. The lowest concentration of deltamethrin to have an effect on sodium channels was 10⁻¹² M, but the response of the preparation to GABA appeared to be unaffected by concentrations of deltamethrin up to 10⁻⁷ M. Although 10⁻⁶ M deltamethrin had a slight effect on the GABA response of the dactyl abductor muscle, it appears that the majority of the effects of cyano pyrethroids in invertebrates could be accounted for solely by their action on sodium channels.     

State-dependent modification of voltage-gated sodium channels by pyrethroids

Pyrethroids disrupt nerve function by altering the rapid kinetic transitions between conducting and nonconducting states of voltage-gated sodium channels that underlie the generation of nerve action potentials. Recent studies of pyrethroid action on cloned insect and mammalian sodium channel isoforms expressed in Xenopus laevis oocytes show that in some cases pyrethroid modification is either absolutely dependent on or significantly enhanced by repeated channel activation. These use-dependent effects have been interpreted as evidence of preferential binding of at least some pyrethroids to the open, rather than resting, state of the sodium channel. This paper reviews the evidence for state-dependent modification of insect and mammalian sodium channels expressed in oocytes by pyrethroids and considers the implications of state-dependent effects for understanding the molecular mechanism of pyrethroid action and the development and testing of models of the pyrethroid receptor.     

Symptomatic and neurophysiological activities of new synthetic non-ester pyrethroids,ethofenprox, MTI-800, and related compounds

Ethofenprox (MTI-500), MTI-800, and related compounds, which have a m-phenoxybenzyl moiety but lack ester bonding, were compared with DDT-type compounds and pyrethroid insecticides for their lethal and convulsive activities toward American cockroaches. The most potent among them ranked between phenothrin and cyphenothrin. Neurophysiological effects were also examined by extra- and intracellular recording and voltage clamp techniques. Some derivatives induced repetitive discharges in the excised central nerve cord of the American cockroach. The after-potential recorded intracellularly from the crayfish giant axon was markedly increased by some compounds. Voltage clamp experiments with the crayfish giant axon showed that ethofenprox decreased the peak sodium current and induced a large residual current during a step depolarization. It also induced a large and prolonged tail current after a step repolarization of the membrane. The effects of the test compounds on the action potential and the sodium current were similar to those of DDT-type compounds and the pyrethroids such as allethrin and phenothrin. A shift of sodium channel population from normal to modified was thought to result in modifications of the sodium current which, in turn, cause the increase in after-potential and the induction of repetitive discharges.     

Molecular neurobiology: Implications for insecticide action and resistance

Recent advances in molecular neurobiology have provided an unprecedented insight into the structure and function of the three principal target sites for neurotoxic insecticides: acetylcholinesterase, the 4-aminobutyric acid (GABA) receptor–chloride ionophore complex, and the voltage-sensitive sodium channel. This paper reviews some of these advances and their current or potential application to problems in insecticide resistance. It particularly emphasizes studies of the molecular biology of voltage-dependent sodium channels in the context of resistance to DDT and pyrethroids resulting from reduced neuronal sensitivity.     

The crayfish stretch receptor organ: A useful model system for investigating the effects of neuroactive substances: II. A pharmacological investigation of pyrethroid mode of action

The crayfish stretch receptor neuron is very sensitive to disruption by pyrethroids. Experiments were therefore carried out on this preparation to investigate whether all observed symptoms of pyrethroid poisoning could be explained in terms of a single action of pyrethroids on the gating mechanism of sodium channels. Other possible mechanisms of pyrethroid action, including effects on potassium channels, inhibitory synapses, and inhibition of calcium ATPases, were also investigated. An effect on sodium channels was clearly demonstrated, but the contribution of other mechanisms was less clear. It appears that the action on the sodium channel could be responsible for the majority, if not all, of the observed effects of pyrethroids on sensory cells.     

Temperature dependence of allethrin-induced repetitive discharges in nerves

The action of allethrin in inducing repetitive discharges by a single stimulus has been studied with squid giant axons at various temperatures. Repetitive discharges are evoked in the allethrin-poisoned axon at optimal temperatures ranging from 20 to 28°C. A single action potential is produced below and above this temperature range. The negative (depolarizing) after-potential is increased markedly by allethrin, and it exceeds the threshold membrane potential for excitation only at the optimal temperatures, thereby accounting for the temperature dependence of repetitive responsiveness.     

Insecticidal and neuroexciting actions of DDT analogs

The neuroexciting activity of DDT and its analogs to produce repetitive responses on the nerve cord of Periplaneta americana was determined using the extracellular electrode method. The convulsive activity on P. americana and the insecticidal effect on Callosobruchus chinensis were also examined. It was found that the convulsive and insecticidal activities increase almost proportionally with increase in the neuroexciting activity within a set of p,p′-substituted DDT analogs. The intimate connections among these biological effects suggest that symptoms such as convulsion and death caused by DDT analogs are closely related with their neuroexcitory effect and there is a common mode of action in spite of differences in insect species.     

Comparative effects of DDT,allethrin, dieldrin and aldrin-transdiol on sense organs of Xenopus laevis

The effects of DDT, allethrin, dieldrin and aldrin-transdiol were studied in two different sense organs of Xenopus laevis; the lateral-line organ and the cutaneous touch receptors. DDT and allethrin produced pronounced repetitive firing in both preparations. Dieldrin and aldrin-transdiol, on the other hand, failed to induce any sign of repetitive activity. Aldrin-transdiol, however, caused a marked increase in the rate of spontaneous firing of the lateral-line organ, later followed by a blockade. The repetitive activity in the cutaneous touch receptors, whether induced by DDT or allethrin, was not distinguishable from repetitive firing of the afferent nerve fibers and showed no marked dependence on temperature. This contrasts sharply with the know negative temperature coefficient of the DDT- or allethrin-induced repetitive activity in the lateral-line organ.     

Neurotoxic implications of the agonistic action of CS-syndrome pyrethroids on the N-type Ca(v)2.2 calcium channel

BACKGROUND: Cismethrin (T-syndrome) and deltamethrin (CS-syndrome) pyrethroids have been previously shown to increase membrane depolarization and calcium influx, but only deltamethrin increased Ca(2+)-dependent neurotransmitter release from rat brain synaptosomes. Deltamethrin's action was blocked by omega-conotoxin GVIA, delineating a separate action at N-type Ca(v)2.2 channels that is consistent with the in vivo release of neurotransmitter. It is hypothesized that other CS-syndrome pyrethroids will elicit similar actions at presynaptic nerve terminals.RESULTS: Nine additional pyrethroids were similarly examined, and these data were used in a cluster analysis. CS-syndrome pyrethroids that possessed alpha-cyano groups, cypermethrin, deltamethrin and esfenvalerate, all caused Ca(2+) influx and neurotransmitter release and clustered with two other alpha-cyano pyrethroids, cyfluthrin and cyhalothrin, that shared these same actions. T-syndrome pyrethroids, bioallethrin, cismethrin and fenpropathrin, did not share these actions and clustered with two non-alpha-cyano pyrethroids, tefluthin and bifenthrin, which likewise did not elicit these actions. Deltamethrin reduced peak current of heterologously expressed wild-type Ca(v)2.2, increased peak current of T422E Ca(v)2.2 and was 20-fold more potent on T422E Ca(v)2.2 than on wild-type channels, indicating that the permanently phosphorylated form of Ca(v)2.2 is the preferred target.CONCLUSIONS: Ca(v)2.2 is directly modified by deltamethrin, but the resulting perturbation is dependent upon its phosphorylation state. The present findings may provide a partial explanation for the different toxic syndromes produced by these structurally distinct pyrethroids.     

Actions of pyrethroid insecticides on insect axonal sodium channels

The actions of pyrethroid insecticides were tested on isolated giant axons of the cockroach Periplaneta americana, using oil-gap, single-fibre recording techniques. Current-clamp and voltage-clamp experiments were used to determine the actions of pyrethroids on axonal membrane potentials and ionic currents. Treatment with deltamethrin at micromolar concentrations caused gradual depolarisation of the axon accompanied by a reduction in amplitude of the action potential. This depolarisation was enhanced by an increase in stimulation frequency. Other synthetic pyrethroids: 3,4,5,6-tetrahydrophthalimidomethyl (1RS)-cis-3-[(RS)-2,2-dimethylcyclopropyl]-2,2-dimethylcyclopropanecarboxylate, biopermethrin and its (1S)-enantiomer, (1R)-tetramethrin, S-bioallethrin, bioresmethrin and its (1S)-enantiomer, cismethrin, and 5-benzyl-3-furylmethyl (E)-(1R)-cis-2,2-dimethyl-3-(2-oxothiolan-3-ylidenemethyl)cyclopropanecarboxylate (RU-15525, ‘Kadethrin’) were investigated. The (1S)-enantiomers were inactive, but all the other pyrethroids tested, apart from deltamethrin, induced prolonged negative (depolarising) after-potentials. All the treatments with the active pyrethroids resulted in the appearance of a voltage and time-dependent ‘maintained’ sodium conductance. The duration of this ‘slow’ conductance varied considerably depending on the pyrethroid under test. Clearly, the effectiveness of pyrethroids on whole insects is not determined only by the degree to which they directly modify the properties of sodium channels. Nevertheless, voltage-clamp experiments on isolated axons readily permit direct comparison of the actions of different pyrethroids on the sodium channels of insect neurones.     

Pyrethroid resistance in a strain of Spodoptera littoralis is correlated with decreased sensitivity of the CNS in vitro

The effects of permethrin and cypermethrin on the isolated abdominal nerve cord of insecticide-resistant [R] and -susceptible [S] strains of Spodoptera littoralis larvae have been studied. Above ca. 19°C, permethrin at 10^?7M caused a prolonged spike train to follow electrical stimulation of the nerve cord. The time of onset of this repetitive firing was significantly greater for the [R] strain. Moreover, cypermethrin, to which this strain shows negligible resistance, did not cause such repetitive discharges. Thus, resistance to permethrin but not to cypermethrin appears to be based on a qualitative difference between the pyrethroids. Nerve blockage by the two pyrethroids was also investigated, with particular reference to temperature. Once again, differences were apparent: when considered relative to untreated controls, permethrin caused quicker nerve blockage as temperature was reduced whereas the blocking action of cypermethrin was not affected by temperature. However, the times taken to cause nerve blockage by permethrin in [R] and [S] larvae were not significantly different, making it unlikely that nerve blockage plays a major role in this resistance. Two methods were employed to reduce the resistance factor in vitro. The synergist dodecyl imidazole failed to significantly reduce the time taken for permethrin to cause either repetitive firing or nerve blockage. However, reducing the calcium concentration in the saline did significantly reduce the latency of repetitive firing caused by permethrin in [R] larvae, thus increasing the nerve sensitivity to approximately the same level as normal calcium, [S] insects.     

Selection of Anopheles stephensi with DDT and dieldrin and cross-resistance spectrum to pyrethroids and fipronil

The field strain of Anopheles stephensi, the main malaria vector in south of Iran, was colonized in laboratory and selected with DDT and dieldrin in two separate lines for 3 generations to a level of 19.5- and 14-fold for DDT and dieldrin resistance, respectively. Synergist tests with chlorofenethol (DMC) and piperonyl butoxide (PBO) on the selected strains indicated that dehydrochlorination and oxidative detoxification might be the underlying mechanisms involved in the resistance to dieldrin and DDT in selected strains. DDT selection decreased susceptibility to DDT and pyrethroids including lambdacyhalothrin, permethrin deltamethrin and cyfluthrin. The result also showed that selection with dieldrin caused negative and positive cross-resistance to pyrethroid and fipronil, respectively. Based on these results, it can be concluded that besides metabolic resistance mechanisms, other factors such as mutation in γ aminobutyric acid (GABA) and voltage-gated sodium channels (Kdr) might be involved.     

Effects of the pyrethroids bioallethrin,deltamethrin and RU-15525 on the electrical activity of a cuticular mechanoreceptor of the cockroach Periplaneta americana

A study has been made of the effects of bioallethrin, RU-15525 [5-benzyl-3-furylmethyl (1R)-cis-2,2-dimethyl-3-(tetrahydro-2-oxo-3-thienylidenemethyl)-cyclopropanecarboxylate, ‘Kadethrin’], and deltamethrin on the electrical activity, measured in vivo, of a cuticular mechanoreceptor of Periplaneta americana. The modifications induced by these pyrethroids on the membrane excitability can be classified into two groups: Type I effects (bioallethrin) are characterised by a substantial increase in the number of action potentials triggered at the initiation site by a given mechanical stimulation, by an electrical activity persisting after mechanical stimulus has been stopped (repetitive activity), and possibly, by an inhibition of excitability of the cell membrane. Type II effects (RU-15525 and deltamethrin), are characterised by an inhibition of the excitability of the initiation site. In the case of RU-15525, there was a transient spontaneous electrical activity. Both types of effects have been linked to an action on the sodium channel, particularly at the initiation site. The preparation studied, which possessed no synapses, was shown to be more sensitive to deltamethrin (which is also the most insecticidal of the three pyrethroids) than to either allethrin or RU-15525. These results suggest that it is unnecessary to envisage a main target (sodium channel) that is different for the two types of pyrethroid.