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.     

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.     

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.     

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.     

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.     

Effects of dieldrin (HEOD) and some of its metabolites on synaptic transmission in the frog motor end-plate

The effects of HEOD and some of its metabolites on synaptic transmission in the frog motor end-plate were studied by means of intracellular microelectrodes. HEOD itself and the metabolites 9-syn-hydroxy-HEOD and the aldrin-derived dicarboxilic acid had no significant effect on frequency and amplitude of miniature end-plate potentials, nor on end-plate membrane potential. In sharp contrast with this aldrin-transdiol (6,7-trans-dihydroxy-dihydro-aldrin) was very potent in exerting both pre- and postsynaptic actions. This metabolite caused a rapid and marked increase in miniature end-plate potential frequency, together with a decrease in their amplitude. Evidence is presented suggesting that the spontaneous transmitter release is enhanced by two prejunctional mechanisms: partly by a calcium-dependent effect, probably a depolarization of the nerve terminal, and partly by a calcium-independent action. Another typical prejunctional action of aldrin-transdiol is the reduction of the amount of transmitter released in response to high external potassium concentration. Aldrin-transdiol also affected the evoked transmitter release and caused a marked increase in end-plate potential amplitude followed by a decrease, and finally a complete blockade of neuromuscular transmission was observed. This transient increase in transmitter release was shown to be due to a transient increase in quantal content. The subsequent fall in end-plate potential amplitude and the fall in miniature end-plate potential amplitude are probably the result of a reduction of the sensitivity of the postsynaptic membrane to acetylcholine as demonstrated by ionophoretic application of this transmitter. There was no aldrin-transdiol-effect on the end-plate membrane potential. The present results strongly support the hypothesis that HEOD must be converted to aldrin-transdiol before it can exert its neurotoxic action.     

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.     

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.     

Long-term effects of DDT on the behavior and central nervous system activity in Periplaneta americana

The effects of p,p′-DDT and four of its analogs on electrical activity in the central nervous system of the cockroach, Periplaneta americana (L.), were investigated. Cockroaches were injected intraabdominally with an organochlorine compound at LD₅₀ 96-hr doses (except for p,p′-DDE). Extracellular recordings were made from the central nervous system at 1 hr, 24 hr, or 3 weeks postinjection. p,p′-DDT, methoxychlor, and p,p′-DDD induced behavioral changes (tremors, jitters, hyperexcitability) and repetitive firing in the central nervous system prior to 1 hr postinjection. By 24 hr postinjection, most behavioral signs of poisoning had disappeared, though repetitive firing could still be readily elicited in the central nervous system. Cockroaches injected with o,p′-DDT, however, usually required about 48 hr before overt signs of poisoning became apparent. Cockroaches treated with p,p′-DDT or o,p′-DDT behaved normally at 3 weeks postinjection but still displayed a significant occurrence of repetitive firing in the central nervous system. A mechanism is proposed to explain how a cockroach might recover behaviorally from a sublethal dose of an organochlorine compound but still display repetitive firing in its central nervous system. A direct “cause and effect” relationship between repetitive firing in the central nervous system and mortality (and external signs of poisoning) is therefore questioned.     

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.     

Studies on the induction of rat uterine ornithine decarboxylase by DDT analogs. I. Comparison with estradiol-17β activity

The effect of DDT analogs and estradiol-17β on uterine ornithine decarboxylase activity in the immature intact and ovariectomized rat was studied. Pretreatment with various doses of o,p′DDT [1-(o-chlorophenyl)-1-(p-chlorophenyl)-2,2,2-trichloroethane] or estradiol-17β caused a marked increase in the specific activity of ornithine decarboxylase in the 20,000g supernatant fraction of uterine homogenates but not in liver homogenates. Doses as low as 0.5 mg of o,p′DDT or 0.002 μg of estradiol-17β stimulated uterine ornithine decarboxylase activity in the ovariectomized rat. The peaks of activity after treatment with o,p′ DDT and estradiol-17β occurred at 6 and 5 hr, respectively. The level of ornithine decarboxylase activity in untreated groups was consistently lower in ovariectomized rats than in intact immature animals. Treatment with o,p′ DDT (10 mg/100 g body weight) of ovariectomized and intact immature rats demonstrated at 131-fold and an about 20-fold increase in uterine ornithine decarboxylase activity, respectively. Treatment of ovariectomized rats with cycloheximide or actinomycin D effectively blocked the increase in ornithine decarboxylase caused by o,p′ DDT. Similar results were obtained with cycloheximide in the intact immature rat. Animals subjected to both adrenalectomy and ovariectomy demonstrated an increase in ornithine decarboxylase activity when treated with either estradiol-17β or o,p′ DDT. Dose-response curves obtained for estradiol-17β and o,p′ DDT suggest a similar mechanism of action for the two compounds. Graphic analysis of the dose-response curves for estradiol-17β and o,p′ DDT demonstrated an ED₅₀ of 0.038 μg/100 g body weight and 1.8 mg/100 g body weight, respectively. The examination of various DDT analogs in intact and ovariectomized animals showed that o,p′ DDT was the most potent inducer of ornithine decarboxylase. The order of decreasing potency of DDT analogs was o,p′ DDT, o,p′ DDD. p,p′ DDT, p,p′ DDD, and p,p′ DDE.     

In vitro effects of DDT analogs on trout brain Mg2+-ATPases: Inhibition kinetics

A continuous in vitro steady-state assay procedure was used to investigate the dependence of trout brain mitochondrial Mg²⁺-stimulated adenosinetriphosphatase specific activity on temperature and substrate concentration. The inhibition of enzyme activity by DDT was independent of substrate concentration. DDT and several analogs caused increases in the experimental activation energy and frequency factor of the enzyme-catalyzed reaction, which gave rise to a negative temperature coefficient of inhibition. It is suggested that DDT and other highly lipophilic compounds have the potential to allosterically affect membrane-bound enzymes by simply becoming a major lipoid component of the membranes.     

Structure-activity relationships of DDT-type analogs based on in vivo toxicity to the sensory nerves of the cockroach, Periplaneta americana L

Forty-three DDT-type compounds were applied in saline suspension to the crural nerve of Periplaneta americana L. and the threshold concentration (ED₅₀) to produce trains of impulses was determined together with the frequency of appearance of repetitive afterdischarge. These quantitative neurological measures were evaluated in multiple regression analyses of structural parameters including van der Waal's volume, the F and R components of Hammet's σ, and the hydrophobic constant Π. This structure-activity analysis provides an accurate estimation of the intrinsic toxicity of the DDT analogs. The results affirm previous working theories that the bulk of the functional groups within the DDT framework is the primary factor relating to activity. However, conformation is also an important parameter.     

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.     

Effect of pyrethroid insecticides on EEG activity in conscious,immobilized rats

Preseizure and seizure EEG patterns elicited by the pyrethroid insecticides, deltamethrin and cis-permethrin, were compared in immobilized Sprague-Dawley rats. Deltamethrin (1–3 mg/kg, iv) produced a preseizure EEG pattern of high-amplitude, slow, 2- to 5-Hz synchronized cortical waves or spike-wave complexes. cis-Permethrin (20–40 mg/kg, iv) elicited an immediate EEG change characterized by 6- to 12-Hz high-amplitude waves with intermingled high-voltage spikes. DDT (50–70 mg/kg, iv) produced a sustained EEG activation similar to that seen after cis-permethrin, but of higher frequency. All three insecticides produced generalized EEG seizure activity, but this was more prominently associated with poisoning due to deltamethrin. cis-Permethrin and DDT gave rise to EEG seizures only at lethal doses. Electrodes stereotaxically positioned in ventral hippocampus, caudate, putamen, thalamus, septum, red nucleus, and cerebellum detected no preferential activation of any of these subcortical sites in either preconvulsive or convulsive phases of poisoning. These results indicate that both deltamethrin and cis-permethrin can have marked effects on mammalian EEG activity. This does not support the hypothesis of differing sites of action, i.e., peripheral vs. central, for the two types of compound. The more pronounced seizure-inducing action of deltamethrin may instead reflect a greater efficacy of cyanopyrethroids at target sites within the central nervous system.     

DDT and pyrethroids: Receptor binding and mode of action in the house fly

The mode of action of DDT and pyrethroids was investigated in the house fly, Musca domestica L, using drug:receptor binding techniques. Both in vivo and in vitro binding studies demonstrated the existence of membrane receptors which bind specifically to [¹⁴C]DDT and [¹⁴C]cis-permethrin. The receptors show properties to be expected of a critical target site of these insecticides. These include negative temperature correlation with binding, relatively nonsensitivity to DDE, and sensitivity to Ca²⁺. The receptor sites are readily saturated at 45–90 nM [¹⁴C]DDT and have an apparent disassociation constant (K_d) of 12.2 nM. The maximum number of binding sites was estimated to be 17 pmol DDT/mg membrane protein (0.34 pmol/house fly head). Competition studies showed DDT, cis-permethrin, and cypermethrin bind to the same receptor but not at precisely the same site. The addition of Ca²⁺ to the incubation buffer significantly inhibited the binding of both [¹⁴C]DDT and [¹⁴C]cis-permethrin, suggesting the receptor binding is Ca²⁺ sensitive and may have a role in ion conductance.     

Quantitative structure-activity relationships of insecticidal diphenyldichlorocyclopropanes

Neurophysiological activity of a series of aromatic-substituted 1,1-diphenyl-2,2-dichlorocyclopropanes (DCC analogs) in the induction of repetitive discharges in excised central nerve cords of the American cockroach was determined by an extracellular recording technique. Quantitative analysis using physicochemical parameters showed that variations in the activity were parabolically correlated with the van der Waals volume of aromatic substituents. Insecticidal activity of these compounds in the American cockroach under conditions where oxidative metabolic activity was inhibited by piperonyl butoxide was also determined. This was related to the repetitive nerve discharge activity, when transport factors were separated by using a hydrophobicity parameter. The analyses showed that the aromatic substituent effects on the neurophysiological activity as well as the relationship between insecticidal and neurophysiological activities are very close to those observed previously for DDT analogs including DDT, DDD, and prolan derivatives.     

DDT and pyrethroids: Receptor binding in relation to knockdown resistance (kdr) in the house fly

The nature of target site or knockdown resistance (kdr) to DDT and pyrethroids was studied by investigating specific binding of [14_C] DDT and [14_C] cis-permethrin to the previously established membrane receptors from the heads of susceptible (sbo) and resistant (kdr) strains of the house fly, Musca domestica L. In vivo studies showed the heads from sbo flies bound two to three times more DDT than those from kdr flies at all doses tested. Reduced binding was also observed in kdr flies in in vitro [14_C] DDT binding assays. Scatchard analysis indicated that kdr flies have the same affinity but fewer receptors per milligram protein in the CNS than sbo flies. Assays with [14_C] cis-permethrin also showed binding was much reduced in kdr flies in comparison with sbo flies. Based on these results, the nature of the target site insensitivity of kdr flies may relate to their having a reduced number of receptors for the insecticides.     

Actions of formamidines,local anesthetics,octopamine and related compounds upon the electrical activity of neurohaemal organs of the stick insect (Carausius morosus) and sense organs of fly larvae (Musca domestica; Calliphora erythrocephala)

The pesticides, chlordimeform and amitraz, and their metabolites, demethylchlordimeform, N¹-(2,4-dimethylphenyl)-N-methylformamidine, and 2,4-dimethylformanilide, are effective at concentrations as low as 3 μM in raising the firing rate of endogenously active neurosecretory fibres in the isolated neurohaemal organs of Carausius morosus. Molecules such as bunamidine and cetrimide, with cationic detergent properties, produced sporadic bursting which did not elevate the overall firing rate to any great extent. Indeed, bunamidine could induce complete block of action potentials at concentrations as low as 30 μM. The local anesthetics, procaine, lidocaine, and benzocaine, do not induce block of activity at least up to a level of 1 mM. They have no effect at concentrations lower than 100 μM. Between 100 μM and 1 mM lidocaine and benzocaine produce a small increase in firing rate. Procaine produced a pronounced increase in the frequency of firing. The phenolic amines, octopamine, synephrine, and tyramine, markedly increased electrical activity. The catecholamines, dopamine, noradrenaline, and adrenaline, by contrast, only produced a weak excitation. Neither α- nor β-adrenergic blocking agents were effective in antagonizing the electrical activity induced by chlordimeform or phenolic amines until relatively high concentrations of about 1 mM were used. Chlordimeform was able to induce high-frequency bursts from sense organs associated with the epidermis and body-wall musculature in larvae of Musca domestica and Calliphora erythocephala. Octopamine did not induce any similar bursting activity in these sense organs. These results are discussed in relationship to current views on the mode of action of the N-aryl amidines. It is concluded that the excitatory effects of these compounds upon neurohaemal organs and sense organs are more likely to result from a direct action upon voltage sensitive channels of the nerve membranes, rather than by an effect mediated by interactions with octopamine receptors.     

Insecticide cyclic nucleotide interactions: I. Quinoxalinedithiol derivatives: A new group of potent phosphodiesterase inhibitors

The direct effects of tepp, methyl paraoxon, DDT, dieldrin, aldicarb, dimetilan, rotenone, allethrin, and oxythioquinox were surveyed on cockroach brain adenyl cyclase and phosphodiesterase in vitro. The most striking result of this survey was the observation that oxythioquinox is a potent inhibitor of phosphodiesterase. The inhibitory activities of seven different quinoxalinedithiol derivatives were compared with those of methyl-xanthines and SQ 65,442 on phosphodiesterases from cockroach brain, rat brain, and beef heart. Although I₅₀ values of the quinoxaline inhibitors were found to be in the μM range, solubility deficiencies apparently limit their effectiveness with inhibition reaching limiting values of about 70–90% as concentrations are increased. Evaluation of the quinoxaline inhibitors to enhance the accumulation of cyclic AMP in the assay of adenyl cyclase did not demonstrate any significant advantage over the use of aminophylline, a standard inhibitor for this purpose. A new assay for phosphodiesterase, involving separation of substrate from product on aluminum oxide columns, was developed by modification of similar techniques utilized in the assay of adenyl cyclase.