Toxicology and metabolism of some synthetic pyrethroids in larvae of susceptible and resistant strains of the cattle tick boophilus microplus (Can.)

Larvae of the Malchi and DDT-R pyrethroid-resistant strains of ticks, compared with larvae of the Yeerongpilly (susceptible) strain, exhibited knock-down resistance equally to (1 RS)-cis- and (1 RS)-trans-permethrin but little resistance to either (1 RS)-cis- or (1 RS)-trans-cypermethrin. Kill resistance was higher in Malchi than in DDT-R ticks and more pronounced against the permethrin isomers. The cis-isomers were more potent overall than the trans-isomers. Cypermethrin isomers penetrated more slowly than permethrin isomers, especially into Malchi larvae. Metabolic detoxication, mainly esteratic, was fastest in Malchi larvae, trans-isomers consistently being attacked faster than cis-isomers. The greatei resistance of Malchi ticks is therefore probably due to a combination of these two differences. Dual mechanisms of the toxic action of pyrethroids are discussed.     

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.     

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.     

Separation and characterization of the pyrethroid-hydrolyzing esterases of the cattle tick, Boophilus microplus

The principal esterases present in homogenates of cattle tick larvae have been separated by gel filtration and preparative isoelectric focusing. Substrate specificities have been determined using trans-permethrin, trans-cypermethrin, p-nitrophenyl butyrate, and the pyrethroid analog, p-nitrophenyl-(1R,S)-3-(2,2-dichlorovinyl)-2,2-dimethylcyclopropanecarboxylate (t-NPDC). One of the esterases, with pI = 4.6, and molecular weight ～67,000, hydrolyzed the α-cyano-substituted pyrethroid, trans-cypermethrin, but not permethrin. The major esterase activity was found in the pI 5.6–5.8 region, and corresponded to a molecular weight of ～89,000. Small differences in substrate specificity and differences in the banding pattern after isoelectric focusing were detected between esterases of ticks of a pyrethroid-resistant strain (Malchi) and a pyrethroid-susceptible strain (Yeerongpilly). Rate constants were determined for the inhibition of the different esterases by the organophosphate coroxon and by naphthyl N-propylcarbamate, using p-nitrophenyl butyrate and t-NPDC as substrates.     

Pesticide interactions: Effects of organophosphorus pesticides on the metabolism,toxicity, and persistence of selected pyrethroid insecticides

The organophosphorus pesticides profenofos, sulprofos, O-ethyl O-(4-nitrophenyl) phenylphosphonothioate (EPN), and S,S,S,-tributyl phosphorotrithioate (DEF) administered intraperitoneally to mice at 0.5 to 5 mg/kg strongly inhibit the liver microsomal esterase(s) hydrolyzing trans-permethrin. Profenofos, EPN, and DEF at 25 mg/kg increase the intraperitoneal toxicity of fenvalerate > 25-fold and of malathion > 100-fold. Topically applied profenofos, sulprofos, and DEF significantly synergize the toxicity of cis-cypermethrin to cabbage looper larvae and house fly adults but these phosphorus compounds are much less effective in synergizing the toxicity of trans-permethrin. The magnitude of synergism appears to depend on the species, organophosphorus compound, and pyrethroid involved. Profenofos, sulprofos, and EPN do not significantly alter the persistence of trans-permethrin on bean foliage.     

Synthetic pyrethroids: Toxicity and synergism on dietary exposure of Tribolium castaneum (Herbst) larvae

The potency of six dietary pyrethroids, as toxicants and inhibitors of weight gain in first- and fourth-instar Tribolium castaneum (Herbst) larvae, decreased in the order of cis-cypermethrin and deltamethrin > trans-cypermethrin and cis-permethrin > fenvalerate and trans-permethrin. Dosages that reduced larval weight also delayed pupation and emergence, probably due to their antifeeding activity. Three oxidase inhibitors (piperonyl butoxide, O, O-diethyl O-phenyl phosphorothioate, and O-isobutyl O-prop-2-ynyl phenylphosphonate), at a dietary concentration of 100 mg kg^?1, had little or no effect on the toxicity of trans-permethrin, but strongly synergised the toxicity of cis-cypermethrin by about 3-, 3- and 10-fold, respectively. Piperonyl butoxide also synergised the toxicity of cis-permethrin, trans-cypermethrin and deltamethrin, but not that of fenvalerate. On the other hand, an esterase inhibitor, profenofos, did not enhance the potency of any of the α-cyano-3-phenoxybenzyl pyrethroids. Oxidases appear to be more important than esterases in pyrethroid detoxification by T. castaneum larvae.     

Properties of a fluorescent analog of the pyrethroids

The ester of pyrene-1-methanol with cis-2,2-dimethyl-3(2,2-dichlorovinyl) cyclopropane carboxylic acid (cis-permethrin acid) is introduced as a fluorescent analog of the pyrethroids. Relative intensities of the vibronic bands in the fluorescence emission spectrum of the ester in lipid bilayers are consistent with a location for the pyrene group in the glycerol backbone region of the bilayer. It is suggested that pyrethroids adopt a “horseshoe” conformation in the bilayer with the ester group at the lipid-water interface. Fluorescence data are interpreted in terms of one binding site per four lipids. In the (Ca²⁺Mg²⁺)-ATPase system prepared from muscle sarcoplasmic reticulum, the ester binds both to sites in the lipid and on the ATPase. There are a large number of sites for the ester on the ATPase. For the ATPase reconstituted with the short chain lipid dimyristoleoylphosphatidylcholine, the ester causes an increase in activity comparable to that caused by the pyrethroids.     

Selective inhibition of separate esterases in rat and mouse liver microsomes hydrolyzing malathion,trans-permethrin,and cis-permethrin

Separate esterase activities of rat and mouse liver microsomes hydrolyzing malathion, trans-permethrin, and cis-permethrin were differentiated on the basis of their sensitivities to inhibition by paraoxon and α-naphthyl N-propylcarbamate (NPC). In rat liver microsomes, the malathionhydrolyzing activity was more sensitive to both inhibitors and showed a different time course of NPC inhibition than the activities hydrolyzing the permethrin isomers. Paraoxon completely inhibited trans-permethrin hydrolysis, but only partially inhibited that of cis-permethrin. The paraoxonsensitive trans- and cis-permethrin-hydrolyzing activities were not differentially inhibited, but separate inhibition curves were obtained for the inhibition of trans- and cis-permethrin hydrolysis by NPC. The mouse liver esterase activity hydrolyzing trans-permethrin showed a similar paraoxon sensitivity to that of rat liver, but that the paraoxon-sensitive portion of the cis-permethrinhydrolyzing activity was 5.5-fold less sensitive to paraoxon than the corresponding rat liver activity and was clearly differentiated from the mouse liver trans-permethrin-hydrolyzing activity. The mouse liver malathion-hydrolyzing activity was 100-fold less sensitive to paraoxon and 14-fold less sensitive to NPC than the corresponding rat liver activity. Rat and mouse liver esterase activities hydrolyzed trans- and cis-permethrin at similar rates under standard assay conditions, but mouse liver esterases were 10-fold less active in hydrolyzing malathion. The higher specific activity of rat liver malathion-hydrolyzing esterases resulted from the greater apparent affinity and maximum velocity for malathion hydrolysis. These results demonstrate that the hydrolysis of malathion, trans-permethrin, and cis-permethrin by rat and mouse liver microsomal preparations involves several esterases with differing substrate specificities and inhibitor sensitivities.     

Hydrolysis of permethrin by pyrethroid esterases from resistant and susceptible strains of Amblyseius fallacis (Acari: Phytoseiidae)

Pyrethroid-hydrolyzing activity in whole body homogenates of three insecticide-resistant and one susceptible strain of the predator mite, Amblyseius fallacis Garman has been examined in vitro. The highest esterase activity was found in the synthetic pyrethroid-resistant GH-1 strain body homogenate. All three pyrethroid-resistant strains had esterases that hydrolyzed trans-permethrin two times faster than cis-permethrin but isomer specificity was not observed in the susceptible strain. The pyrethroid esterases of the GH-1 strain were very sensitive to inhibition by dichlorovos, S,S,S-tributhylphosphorotrithioate, and 3-octylthio-1,1,1-trifluoro-2-propanone. Carbaryl and tetraethylpyrophosphate exhibited moderate inhibition in the GH-1 strain. Eserine sulfate and piperonyl butoxide only inhibited permethrin hydrolysis at higher concentrations. Fifteen esterase bands were resolved from body homogenates by gradient gel electrophoresis in the GH-1 strain, and were identified as carboxylesterases. The major pyrethroid-hydrolyzing activity was located in E5–E12 bands from GH-1 and composite susceptible strain esterases. Six esterase bands exhibiting low pyrethroid-hydroloyzing activity were also obtained from the two spotted spider mite, Tetranychus urticae (Koch).     

Metabolism of permethrin isomers in American cockroach adults,house fly adults,and cabbage looper larvae

Forty-two insect metabolites of [1RS,trans]-and [1RS,cis]-permethrin are tentatively identified in studies with Periplaneta americana adults, Musca domestica adults, and Trichoplusia ni larvae involving administration of ¹⁴C preparations labeled in either the alcohol or acid moieties. The less-insecticidal trans isomer is generally metabolized more rapidly than the more-insecticidal cis isomer, particularly in cabbage looper larvae, and metabolites retaining the ester linkage appear in larger amount with cis-permethrin. Although the dichlorovinyl group effectively blocks oxidation in the acid side chain, the permethrin isomers are metabolized by hydrolysis and hydroxylation at the geminal-dimethyl group (either trans- or cis-methyl substituent) and the phenoxybenzyl group (predominantly at the 4′-position in all species but also at the 6-position in house flies). The alcoholic and phenolic metabolites are excreted as glucosides, and the carboxylic acids are excreted as glucosides and amino conjugates (glycine, glutamic acid, glutamine, and serine) with considerable species variation in the preferred conjugating moiety.     

Penetration and metabolism of topically applied permethrin and cypermethrin in pyrethroid-tolerant Wiseana cervinata larvae

The penetration, excretion, and metabolism of topically applied [¹⁴C]permethrin and [¹⁴C]cypermethrin have been examined in larvae of the porina moth Wiseana cervinata to determine the factors which affect body levels of unchanged pyrethroids. Metabolism was by hydrolysis and to a lesser extent oxidation and the primary metabolites were quickly conjugated to water-soluble products. Little excretion occurred and body levels of unchanged pyrethroids were dependent on the interaction of penetration and metabolism. cis-Cypermethrin was more resistant to metabolism than trans-cypermethrin and cis- and trans-permethrin. trans-Permethrin most readily penetrated into larvae. The body levels of unchanged permethrin were enhanced by pretreatment of larvae with the metabolic inhibitors carbaryl or piperonyl butoxide. Tolerance of the pasture pest porina to the synthetic pyrethroids is discussed in relation to these findings.     

Interaction of pyrethroids with mammalian spinal neurons

The effects of intravenous administration of non-cyano (cis-permethrin) and cyano-substituted (deltamethrin) pyrethroids were studied on spontaneous and evoked ventral root activity in rat spinal cord and on spontaneous firing of ventral horn interneurons in the cat. Both pyrethroids had dramatic facilitatory effects on spontaneous firing rates of ventral roots and spinal interneurons and increased the amplitude of mono- and polysynaptically mediated ventral root responses to dorsal root stimulation. Spontaneous and evoked afferent sensory activity was slightly enhanced by cis-permethrin, but not by deltamethrin. In the cat diazepam (0.5 mg/kg, iv) was equally effective in antagonizing the facilitation of interneuronal firing resulting from either deltamethrin or cis-permethrin. These effects of pyrethroids on spinal neurons may underly the production of tremor and choreoathetosis-salivation toxicity symptoms in mammals.     

Carboxylesterases from Boophilus microplus hydrolyze trans-permethrin

An esterase which hydrolyzes the ester bond of trans-permethrin has been partially purified from homogenates of larvae of the cattle tick. The final (gel filtration) step showed two distinct peaks of p-nitrophenylbutyrate-hydrolyzing activity. The trans-permethrin-hydrolyzing activity of the lower-molecular-weight enzyme cochromatographed with the p-nitrophenylbutyrate-hydrolyzing activity of that enzyme. Little trans-permethrin hydrolysis was observed in the high-molecular-weight peak. The yield of the low-molecular-weight enzyme increased on extraction of the homogenates with Triton X-100. Inhibition studies using the low-molecular-weight enzyme and trans-permethrin as substrate indicated that hydrolysis was due largely to a carboxylesterase (EC 3.1.1.1).     

Pyrethroid resistance and esterase activity in three strains of the cotton bollworm, Helicoverpa armigera (Hübner)

Microplate assay technique for estimation of esterase activity in a single insect was used in combination with dose mortality bioassays to detect pyrethroid resistance in three strains of Helicoverpa armigera and to study the frequency of pyrethroid resistant individuals within the population of the same strain at two larval stages, third and fifth instar. The third and fifth instar larvae of the field strains i.e., Nagpur strain and Delhi strain that displayed high degree of resistance towards deltamethrin, had higher esterase activity compared to a susceptible laboratory strain. The frequency distribution of individuals with elevated esterase activity above 1.00 absorbance unit was correlated with the resistance level of the strains. The frequency of resistant individuals in the third instar larvae of Nagpur strain and Delhi strain were 29% and 23%, respectively compared to 4% in the susceptible strain. The resistant individuals in the resistant strains have markedly increased in the fifth instar larvae with a frequency distribution of 63% and 90% in Delhi strain and Nagpur strain, respectively, while only 14% of individuals was found to have elevated esterase activity in the susceptible strain. The results demonstrated the role of esterase in pyrethroid resistance in H. armigera. Microplate assay proved to be a rapid and reliable biochemical technique for monitoring of pyrethroid resistance in H. armigera.     

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.     

Nerve insensitivity resistance to cypermethrin in larvae of the tobacco budworm Heliothis virescens from USA cotton field populations

Spontaneous neuronal activity was recorded from the peripheral nerves of third-instar larvae of strains of Heliothis virescens (F.) obtained directly from cotton fields in the USA. Following a control period the preparations were exposed to increasing concentrations of cis-cypermethrin in a cumulative dose-response assay. A positive response was defined as an increase of at least five-fold in the rate of neuronal activity over that seen during the control period. Up to 35 individuals of each strain were assayed and the responses used to construct a phenotypic profile categorising the individuals from nerve-susceptible to highly nerve-insensitive. An EC₅₀ for the action of cis-cypermethrin was also obtained. There was a positive, significant correlation between non-synergisable resistance to cypermethrin and nerve insensitivity as defined in the neurophysiological assay. It was shown that nerve insensitivity to cypermethrin increased throughout the cotton-growing season.     

Esterases and resistance to synthetic pyrethroids in the Egyptian cotton leafworm

Esterases hydrolyzing α-naphthyl acetate (α-NA), β-naphthyl acetate (β-NA), and p-nitrophenyl acetate (p-NPA) were investigated colorimetrically in larval homogenates of synthetic pyrethroid susceptible (S) and resistant (R) strains of Spodoptera littoralis (Boised). The hydrolytic activity towards the three substrates in cybolt, decamethrin, and fenvalerate R strains were from 3 to 6.5 times as high as in the S strain. The increase in esterase activity was closely associated with the development of resistance in the R strains. DEF (S,S,S-tributyl phosphorotrithioate) proved to be an inhibitor for all esterases, with a particularly potent action on p-NPA-hydrolyzing enzymes. The inhibitory action was more pronounced in R strains than in the S strain. Pretreatment with DEF increased the toxicity of pyrethroid compounds in the R strains more than in the S strain and hence decreased the levels of resistance in these strains. This is evidence that the esterases contribute to the resistance against synthetic pyrethroids in S. littoralis larvae.     

Pyrethroid synergism and prevention of emergence inTribolium castaneum andMusca domestica vicina by the insect growth regulator RO 13-5223

Ethyl [2-(4-phenoxyphenoxy)ethyl] carbamate (RO 13-5223) at a dietary concentration of 100 mg kg^-1 synergized the toxicity of thetrans- andcis-isomers of permethrin and cypermethrin in inhibiting the growth (measured as gain in larval weight) ofTribolium castaneum andMusca domestica vicina. With both species the synergism factor forcis-cypermethrin with 100 mg kg^-1 synergist was 1.5- to twofold for RO 13-5223 and about fourfold for piperonyl butoxide. Synergism was more pronounced with first instar than with fourth instarT. castaneum larvae. Methoprene was not a pyrethroid synergist withT. castaneum larvae, so the synergistic effect of RO 13-5223 appears to depend on its structural features and not its insect-growth-regulator activity. Joint application of RO 13-5223 and pyrethroids resulted in a dual effect on bothT. castaneum andM. domestica: increased inhibition of larval growth due to pyrethroid synergism, and progeny suppression — expressed by larval and pupal mortality — due to RO 13-5223 juvenilizing activity.     

Developmental changes in trans-permethrin and α-naphthyl acetate ester hydrolysis during the last larval instar of Pseudoplusia includens

The hydrolysis of trans-permethrin and α-naphthyl acatate by midgut, fat body, and cuticle homogenates from Pseudoplusia includens (Walker) was monitored during the development of the last instar. The midgut homogenates appeared to have two pH optima (7.6 and 8.6) for the hydrolysis of trans-permethrin, the fat body homogenates had one optimum (7.4–7.8), and the cuticle homogenates had a major optimum at 6.6. Hydrolysis of both substrates peaked during the late feeding stages for midgut and cuticle homogenates, although relative changes were not the same. Hydrolysis of trans-permethrin peaked during the late feeding stage in fat body homogenates, while hydrolysis of α-naphthyl acetate continually increased through the prepupal stage. Thus, the hydrolysis of α-naphthyl acetate is not necessarily associated with the hydrolysis of trans-permethrin. The LD₅₀ values for trans-permethrin on the different stages appeared to reflect the influence of hydrolysis.