The action of allethrin on the peripheral nervous system of the frog

A study was made of the neurotoxic effects of the pyrethroid insecticide allethrin on the peripheral nervous system of the frog by means of electrophysiological techniques. The principal action of allethrin is to induce repetitive activity, not only in sensory nerve fibres and in sense organs, but also in the distal part of the motor fibres, leading to pronounced repetition in the motor end-plate. Measured by the number of repetitive nerve impulses allethrin shows a marked negative temperature coefficient of activity in the lateral-line sense organ and in the motor nerve terminal.     

Two classes of pyrethroid action in the cockroach

Pyrethroids are divided into two classes (Types I and II) based on their effects on the cercal sensory nerves recorded in vivo and in vitro and on the symptomology they produce in dosed cockroaches, Periplaneta americana. Type I compounds include pyrethrins, S-bioallethrin, [1R,cis]resmethrin, kadethrin, the 1R,trans and 1R,cis isomers of tetramethrin, phenothrin, and permethrin, and an oxime O-phenoxybenzyl ether. Electrophysiological recordings from dosed individuals reveal trains of cercal sensory spikes and sometimes also spike trains from the cercal motor nerves and in the CNS. Low concentrations of these pyrethroids act in vitro to induce repetitive firing in a cercal sensory nerve following a single electrical stimulus. This in vitro measurement, standardized for evaluating structure-activity relationships, shows that only 1R, insecticidal isomers are highly effective neurotoxins. The most potent compounds on the isolated nerve are [1R,trans]- and [1R,cis]tetramethrin, each active at 3 × 10^?13M. The poisoning symptoms of Type I compounds are restlessness, incoordination, hyperactivity, prostration, and paralysis. Type II compounds include [1R,cis,αS]- and [1R,trans,αS]cypermethrin, deltamethrin, and [S,S]fenvalerate. These α-cyanophenoxybenzyl pyrethroids do not induce repetitive firing in the cercal sensory nerves either in vivo or in vitro; moreover, they cause different symptoms, including a pronounced convulsive phase. Two other pyrethroids with an α-cyano substituent, i.e., fenpropathrin and an oxime O-α-cyanophenoxybenzyl ether, are classified as Type I based on their action on a cercal sensory nerve but the symptoms with these compounds resemble Type II. The two classes of pyrethroid action evident with the cockroach are discussed relative to their neurophysiological effects and symptomology in other organisms.     

Characterization of 11 commercial pyrethroids on the functional attributes of rat brain synaptosomes

The action of 11 commercial pyrethroids on Ca²⁺ influx and glutamate release was assessed using high-throughput functional assays with rat brain synaptosomes to better understand the mechanistic nature of pyrethroid-induced neurotoxicity and aid in the reassessment of pyrethroids in vivo. Concentration-dependent response curves for each of the non-cyano and α-cyano containing pyrethroids were determined and the data used in a cluster analysis. The previously characterized α-cyano pyrethroids that induce the CS-syndrome (cypermethrin, deltamethrin, and esfenvalerate) increased Ca²⁺ influx and glutamate release, and clustered with two other α-cyano pyrethroids (β-cyfluthrin and λ-cyhalothrin) that shared these same actions. Previously characterized T-syndrome pyrethroids (bioallethrin, cismethrin, and fenpropathrin) did not share these actions and clustered with two other non-cyano pyrethroids (tefluthrin and bifenthrin) that likewise did not elicit these actions. Our current findings indicate that pyrethroids that have an α-cyano group (with the exception of fenpropathrin) were more potent enhancers of Ca²⁺ influx and glutamate release under depolarizing conditions than pyrethroids that did not possess this functional group. The collective data set does not support the hypothesis that pyrethroids, as a class, act in a similar fashion at presynaptic nerve terminals.     

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.     

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.     

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.     

Evidence for different mechanisms of action of the three pyrethroids,deltamethrin, cypermethrin,and fenvalerate,on the excitation threshold of myelinated nerve

The effects of three α-cyano pyrethroids (deltamethrin, fenvalerate, and cypermethrin) on the electrophysiological function of single myelinated nerve fibers from Rana esculenta were investigated. The time course of pyrethroid-induced changes on the threshold interval, V_s − V_m (V_s: threshold voltage; V_m: membrane potential), as well as stationary membrane parameters determining this interval was measured on the same nerve preparation (membrane potential V_m, stationary transition voltage V_Tr, stationary sodium conductance). The results suggest that the mechanisms of changing the threshold interval are different for the three pyrethroids. Deltamethrin and cypermethrin increase this interval until inexcitability, deltamethrin by increasing the stationary sodium conductance and cypermethrin by blocking the sodium conductance. Fenvalerate, however, insignificantly affects the threshold interval because both V_m and V_s are shifted parallel by about the same amount in the same direction (depolarization). These qualitatively different effects of chemically related substances differentiate the pyrethroids from other classes of substances which are effective on the nerve function and suggests that the molecular mechanisms underlying the pyrethroid effects might have a unique quality.     

Effects of pyrethroids on neuronal excitability of adult honeybees Apis mellifera

Pyrethroids act on the nervous system as a primary target organ and exert their neurotoxic effects primarily by altering the conductance of sodium channel, leading to hyperexcitation. However, few studies investigated the effects of pyrethroids on neuronal excitability of honeybee brain neurons. In this study, a whole-cell patch-clamp technique was used to record current threshold, the minimum current to induce an action potential, and peak sodium current in the dissociated honeybee brain neurons treated with bifenthrin, deltamethrin and fluvalinate in vitro & in vivo. The study showed that these pyrethroids greatly suppressed the neuronal excitability as revealed by increasing current injected and inhibited the peak sodium current in honeybees. The three pyrethroids also inhibited steady-state inactivation in addition to reduction of sodium peak current.     

Kinetics of sodium channel modification as the basis for the variation in the nerve membrane effects of pyrethroids and DDT analogs

The effects of a wide range of pyrethroids and DDT analogs on the membrane potential and membrane sodium currents were studied in crayfish giant axons. Compounds differed greatly in their ability to produce depolarizing afterpotentials, repetitive firing, and membrane depolarization. The differences observed at the membrane potential level could be explained by differences in the kinetics with which the insecticides interact with the nerve membrane sodium channel. The compounds containing a cyano group at the α position retain sodium channels in a modified open state persistently, depolarize the membrane, and block the action potential without causing repetitive firing. The pyrethroids without an α-cyano group and DDT analogs retain sodium channels in a modified open state only transiently, cause large depolarizing afterpotentials, and evoke repetitive firing with minimal effect on the resting potential. The effects of the phenoxybenzyl pyrethroids were found to be intermediate between these two extremes suggesting that a continuous variation exists in kinetics with which pyrethroids and DDT analogs modify sodium channels. It was not necessary to assume a second site of action to account for the variability observed. The implications of these results to the construction of quantitative structure-activity relationships is discussed.     

Pyrethroid toxicology in the frog

Adult Rana pipiens pipiens (Shreber) are highly sensitive to insecticidal α-cyano-3-phenoxybenzyl esters administered subcutaneously, i.e., LD₅₀ 0.13–0.35 mg/kg for deltamethrin and the most potent isomer of each of cis-cypermethrin, fenpropathrin, and fenvalerate and 0.65 mg/kg for (1R,αS)-trans-cypermethrin. Pyrethroids lacking the α-cyano substituent [pyrethrins, S-bioallethrin, kadethrin, and the Cis- and trans-isomers of (1R)-tetramethrin, (1RS)-resmethrin, (1R)-phenothrin, and (1R)-permethrin] vary greatly in their toxicity (LD₅₀ 0.14 to > 60 mg/kg) and the trans isomers are much less toxic than the corresponding cis isomers. The trans/cis specificity is due in large part to relative detoxification rates based on synergism studies with the resmethrin and permèthrin isomers and liver pyrethroid esterase assays with the permethrin and cypermethrin isomers. Poisoning by the noncyano compounds involves hyperactivity and tremors whereas by the cyanophenoxybenzyl esters involves tonic seizures and choreoathetosis, i.e., types I and II syndromes, respectively. Picrotoxinin, t-butylbicyclophosphate, and five other small cage compounds give a third type of syndrome with clonic seizures. Diazepam and its 2′-fluoro-4-methyl-4,5-dihydro analog (RO 5-3636) are more effective than 23 other compounds tested in protecting against deltamethrin toxicity. Diazepam is most effective in alleviating the Type II syndrome, intermediate with the type I syndrome, and is not active with picrotoxinin.     

Binary mixtures of pyrethroids produce differential effects on Ca influx and glutamate release at isolated presynaptic nerve terminals from rat brain

Isolated rat brain synaptosomes were used to evaluate the action of pyrethroid mixtures on Ca²⁺ influx and subsequent glutamate release under depolarizing conditions. In equipotent binary mixtures at their respective and/or estimated EC₅₀s with deltamethrin always as one of the two components, cismethrin, λ-cyhalothrin, cypermethrin, esfenvalerate and permethrin were additive and S-bioallethrin, fenpropathrin and tefluthrin were less-than-additive on Ca²⁺ influx. In binary mixtures with deltamethrin always as one of the two components, esfenvalerate, permethrin and tefluthrin were additive and λ-cyhalothrin was less-than-additive on glutamate release. Binary mixture of S-bioallethrin and cismethrin was additive for both Ca²⁺ influx and glutamate release. Only a subset of pyrethroids (S-bioallethrin, cismethrin, cypermethrin, and fenpropathrin) in binary mixtures with deltamethrin caused a more-than-additive effect on glutamate release. These binary mixtures were, however, only additive (cismethrin and cypermethrin) or less-than-additive (S-bioallethrin and fenpropathrin) on Ca²⁺ influx. Therefore, increased glutamate release evoked by this subset of pyrethroids in binary mixture with deltamethrin is not entirely occurring by Ca²⁺-dependent mechanisms via their action at voltage-sensitive calcium channels. These results suggest that pyrethroids do not share a common mode of toxicity at presynaptic nerve terminals from rat brain and appear to affect multiple target sites, including voltage-sensitive calcium, chloride and sodium channels.     

Cytochrome P450 monooxygenase-mediated permethrin resistance confers limited and larval specific cross-resistance in the southern house mosquito, Culex pipiens quinquefasciatus

The cytochrome P450-dependent monooxygenases (P450s) are an important enzymatic system that metabolizes xenobiotics (e.g., pesticides), as well as endogenous compounds (e.g., hormones). P450-mediated metabolism can result in detoxification of insecticides such as pyrethroids, or can be involved in the bioactivation and detoxification of insecticides such as organophosphates. We isolated (from the JPAL strain) a permethrin resistant strain (ISOP450) of Culex pipiens quinquefasciatus, having 1300-fold permethrin resistance using standard backcrossing procedures. ISOP450 is highly related to the susceptible lab strain (SLAB) and the high resistance to permethrin is due solely to P450-mediated detoxification. This is the first time in mosquitoes that P450 monooxygenase involvement in pyrethroid resistance has been isolated and studied without the confounding effects of kdr. Resistance in ISOP450 is incompletely dominant (D = +0.3), autosomally linked, and monofactorally inherited. It is expressed in the larvae, but not in adults. Cross-resistance to pyrethroids lacking a 3-phenoxybenzyl moiety (tetramethrin, fenfluthrin, bioallethrin, and bifenthrin) ranged from 1.5- to 12-fold. ISOP450 had only limited (6.6- and 11-fold) cross-resistance to 3-phenoxybenzyl pyrethroids with an α-cyano group (cypermethrin and deltamethrin, respectively). Examination of cross-resistance patterns to organophosphate insecticides in ISOP450 showed an 8-fold resistance to fenitrothion, while low, but significant, levels of negative cross-resistance were found for malathion (RR = 0.84), temephos (RR = 0.73), and methyl-parathion (RR = 0.55). The importance and uniqueness of this P450 mechanism in insecticide resistance is discussed.     

Neural and behavioral correlates of pyrethroid and DDT-type poisoning in the house fly, Musca domestica L

Intact house flies were observed during poisoning caused by several pyrethroid and DDT-type insecticides. The two insecticide classes could be generally distinguished from each other based on differences in symptoms and several physiological correlates. Both insecticide types caused motor unit repetitive backfiring, but the temporal development and stability of repetitiveness were distinctly different between the two classes. Repetitive backfiring always disappeared at low temperatures, but DDT-type backfiring disappeared at lower temperatures than the pyrethroids. trans-Tetramethrin caused a threshold increase in flight motor nerve endings which did not occur in DDT or trans-Barthrin poisoning. Pyrethroids caused “uncoupling” of the flight motor pattern, while DDT-types did not. trans-Barthrin, a methylenedioxyphenyl pyrethroid, was unique in causing both symptoms and physiological aberrations which more closely resembled those of the DDT-types than the pyrethroids.     

A pharmacological study of pyrethroid neurotoxicity in mice

Permethrin (cis-, trans-, and technical grade [tech.]) and deltamethrin, representatives of the non-cyano- and cyano-containing classes of synthetic pyrethroids, produced neurotoxic symptoms when administered to mice. ED₅₀ values for this effect were compared following intracerebroventricular (icv) or peripheral (iv) injection. Both permethrin and deltamethrin showed large increases in potency following icv administration, suggesting a mainly central site of action for both classes of pyrethroid. Pretreatment of mice with drugs affecting central noradrenergic, cholinergic, or serotonergic transmission was demonstrated to potentiate the toxic response to iv injections of tech.-permethrin, while some symptoms of toxicity could be partially alleviated by ip pretreatment with diazepam, aminooxyacetic acid, or cycloheximide.     

Antifeeding effect of cypermethrin and permethrin at sub-lethal levels against Pieris brassicae larvae

An antifeeding (feeding deterrent) response by first- and fifth-instar larvae of Pieris brassicae was shown to be significant at sub-lethal levels of cypermethrin and permethrin, using leaf-discs treated with the pyrethroids by dipping. Permethrin was slightly more effective than cypermethrin both as an insecticide and as an antifeedant against fifth-instar larvae, but the reverse order of effectiveness was observed, with a marked difference in mortality, against newly-hatched larvae. When 1-day-old fifth-instar larvae were continuously given leaf discs treated with a solution of the pyrethroid (1 mg litre^?1), up to the time of pupation, both cypermethrin and permethrin induced a significant extension of the larval period, with a reduction in the maximum larval and pupal weights, as well as a reduction in the total leaf-area consumed. However, at higher levels of both pyrethroids, lowering the temperature induced some irritancy, as indicated by regurgitation and frequent uncoordinated wriggling movements of the fifth-instar larvae. The advantages of cypermethrin as a protectant and as an antifeedant over permethrin are discussed.     

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.     

Pyrethroid toxicology: Mouse intracerebral structure-toxicity relationships

Mouse intracerebral (ic) toxicity studies with 29 pyrethroids confirm earlier mouse intraperitoneal (ip) and rat oral and intravenous findings in three respects: α-cyano-3-phenoxybenzyl esters produce choreoathetosis, convulsions, and salivation, whereas compounds lacking the α-cyano group yield tremors and convulsions; high stereospecificity is involved in inducing both poisoning syndromes; large toxicity differences for (1R,trans) vs (1R,cis) resmethrin and permethrin do not extend to ethanomethrin and the cyanophenoxybenzyl esters. The ic investigations further establish that: profuse salivation is not unique for pyrethroids with the α-cyano group; the inactivity of (1R,trans) resmethrin in the brain is not due to detoxification; pyrethroids acting most rapidly in the brain are those with the highest knockdown activity for insects; the cyanophenoxybenzyl esters, in comparison with the non-cyano pyrethroids, have a high ic toxicity relative to their synergized ip toxicity indicating the importance of the brain in the Type II poisoning syndrome.     

Two different types of inhibitory effects of pyrethroids on nerve Ca- and Ca + Mg-ATPase activity in the squid, Loligo pealei

The biochemical process by which various pyrethroid insecticides affect membrane-bound ATPase activities of the squid nervous system was examined. Of the five ATP-hydrolyzing systems tested, only Ca²⁺-stimulated ATPase activities are seen to be clearly affected by pyrethroids. It was found that the “natural type” pyrethroids (e.g., pyrethrin and allethrin) primarily inhibit Ca-ATPase activity whereas the “highly modified type” pyrethroids (e.g., cypermethrin and decamethrin) mainly inhibit Ca + Mg-ATPase. permethrin, which is considered to possess structural similarities to both the natural type and the highly modified type pyrethroids, was found to have an intermediate property in terms of its inhibitory potency to both Ca- and Ca + Mg-ATPase activities. The level of inhibition of Ca²⁺-stimulated ATPase activities was generally high in the retinal axons and optic lobe synaptosomes but lowest in the axoplasmic preparations.     

Pharmacokinetics of pyrethroids in twospotted spider mites

The penetration and degradation of six pyrethroids were examined in the twospotted spider mite, Tetranychus urticae Koch, and the results were related to their toxicity as measured by inhibition of respiration using the Warburg technique and mortality using the slide-dip bioassay. FMC-54800 [1,1′-biphenyl-3ylmethyl cis-3-(2-chloro-3,3,3-trifluoro-1-propenyl)-2,2-dimethylcyclopropanecarboxylate] was the most toxic pyrethroid to the mites based on both respiration and mortality studies. It and flucythrinate had the highest pharmacokinetic efficiency as determined by delivery and maintenance of internal levels of parent compounds. Permethrin, fenvalerate, and fluvalinate were intermediate in pharmacokinetic efficiency, whereas cypermethrin was significantly lower. The highest intrinsic activity, as estimated by the percentage inhibition of respiration per microgram of internal parent, was possessed by cypermethrin and FMC-54800. Fenvalerate and fluvalinate had intermediate levels, while permethrin and flucythrinate had significantly lower capacities to inhibit respiration. The combination of relatively high pharmacokinetic efficiency and intrinsic activity of FMC-54800 appeared to be responsible for its high toxicity. In addition to these findings, differences in the kinetics for cis and trans isomers were observed for permethrin but not cypermethrin. This study has yielded evidence that acaricidal activity of pyrethroids can be enhanced by optimizing the structure for increased pharmacokinetic efficiency and increased intrinsic activity.     

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.