Mode of action of sulfenylated carbamates: Rapid conversion of N,N′-thiodicarbamates to parent carbamate measured by neurophysiological bioassay

Four N,N′-thiodicarbamate derivatives of carbofuran induced uncoupled convulsions with similar latencies following topical application to the cuticle of tethered S_NAIDM house flies, despite considerable differences in their lipophilic properties. There was a small but statistically significant delay in the latency to response to the derivatives compared to carbofuran, but when perfused directly on the exposed thoracic ganglia to assess intrinsic activity, carbofuran acted up to 4.4 times faster than the derivative. It is suggested that the NS bond of the derivatives is cleaved soon after application to the house fly cuticle and carbofuran is released from each derivative in sufficient quantities to accumulate toxic concentrations in the central nervous system at similar rates.     

Structure and insecticidal activity of picrotoxinin analogs

Picrotoxinin, a convulsant in mammals, was nontoxic when topically applied on whole house flies. When synergized with piperonyl butoxide, the topical LD₅₀ of picrotoxinin on house flies was 6.50 μg/g or 260 times less toxic on house flies than the synergized insecticide, carbofuran, a carbamate cholinesterase inhibitor.When perfused on the isolated thoracic ganglion of house fly, picrotoxinin was less potent in producing convulsions than carbofuran; however, when assayed on the desheathed thoracic ganglion, picrotoxin was more potent than carbofuran. This suggested a substantial barrier to picrotoxinin preventing diffusion into the house fly central nervous system.Of several picrotoxinin analogs synthesized the 2-iodo,4-isopropyl, 6-methylenebromidecyclohexane-γ-lactone was the most potent convulsant.     

Decreased nerve sensitivity and decreased cuticular penetration as mechanisms of resistance to pyrethroids in a (1R)-trans-permethrin-selected strain of the house fly

A fenthion-resistant strain of the house fly (Musca domestica L.) was selected with bioresmethrin resulting in ca. 90-fold resistance to the selecting agent. This strain was subsequently selected with (1R)-trans-permethrin producing ca. 140-fold resistance to this latter insecticide. The permethrin-resistant (147-R) strain was highly cross-resistant to several other pyrethroids and demonstrated resistance to knockdown by these insecticides as well as by DDT. The sensitivity of the central nervous system to four pyrethroids was investigated. The 147-R strain was 2.6-fold less sensitive to (1R)-trans-ethanoresmethrin than the susceptible (NAIDM-S) strain, and >43-fold and >67-fold less sensitive to (1R,S)-cis, trans-tetramethrin and (1R)-trans-permethrin, respectively. It also displayed decreased penetration of (1R,S)-trans-[¹⁴C]permethrin when compared to the NAIDM-S strain. Lower nerve sensitivity and decreased cuticular penetration are potential mechanisms of resistance to pyrethroids in house flies in the United States.     

The mechanism of resistance to lindane and hexadeuterated lindane in the Third Yumenoshima strain of house fly

The factors which cause lindane resistance in the Third Yumenoshima strain, a strain of house flies highly resistant to insecticides, were studied using hexadeuterated lindane. Hexadeuterated lindane has the same physicochemical properties as lindane, but the former is much less biodegradable than the latter. The LD₅₀ ratio of lindane to hexadeuterated lindane in this strain, deuterium isotope effect on LD₅₀ values, was larger than that in S_NAIDM, a susceptible (nonresistant) strain. The penetration rates of labeled and nonlabeled lindane through the insect cuticle were about the same for both strains. Thus, penetration rate does not cause resistance. The metabolic degradation of lindane in the resistant strain in vivo occurred much faster than in the susceptible strain. This was also the case for lindane degradation processes in vitro such as microsomal oxidation and glutathione conjugation. In both strains, significant isotope effects were observed in the degradation rates in vitro of labeled and nonlabeled lindane. Therefore, principal biodegradation and detoxication pathways should include reactions which cleave the CH bonds. When the much less biodegradable d₆ counterpart of lindane was applied to both strains, the susceptible strain became much more highly intoxicated than the other within 20 to 30 min. This indicates that a combination of both greater degradability and probably lower sensitivity at the action site are the main factors underlying resistance in the Third Yumenoshima strain.     

Action of avermectin B1a on the leg muscles and the nervous system of the American cockroach

The action of avermectin was studied in the leg muscle and the central nervous system of the American cockroach, Periplanata americana L. Avermectin at a low concentration (10^?7M) causes a failure of the leg muscles to respond to external stimuli within 30 min without affecting the magnitude of contraction. Avermectin was found to stimulate Cl^? uptake by the leg muscles within 4 min at 10^?7M. The threshold concentration to cause such stimulation was on the order of 10^?8M. This stimulatory action could be antagonized by picrotoxinin (10^?4M) and to a lesser extent by bicuculline methiodide (10^?4M). The phenomenon is observable under both Na⁺-free and K⁺-free conditions. It was concluded that the action of avermectin is to open the chloride channel on the plasma membrane. This action of avermectin does not seem to be mediated through GABA, GABA receptors, diazepine receptors, or picrotoxinin receptor in this insect species, and therefore suggests that avermectin directly attacks the chloride channel proper both in the central nervous and the neuromuscular systems.     

Behavioural and electrophysiological investigation of 1-(7-ethoxygeranyl)-2-methylbenzimidazole on the house fly Musca domestica

The insecticidal properties of 1-(7-ethoxygeranyl)-2-methylbenzimidazole (EGMB) were investigated on larval and adult house flies. Unsynergised EGMB gave topical LD₅₀ values of 0.53 μg per female fly on NAIDM strain house flies. When flies were pretreated with 5.2 μg piperonyl butoxide, susceptibility was increased (LD₅₀ 0.12 μg per female fly). House fly larvae were less susceptible to EGMB (LD₅₀ 2.2 μg). Poisoning with EGMB resulted in a rapid reduction in locomotor activity of both larval and adult house flies. This reduction in locomotion was progressive and led to complete paralysis. Various parameters of larval nervous system function were investigated in larvae during these early phases of poisoning. As early as 15 min after dosing larvae with LD₉₅ doses of EGMB, sensory nerves were less responsive. Over a somewhat longer time (2–4 h), neurally evoked contractures were adversely affected by EGMB. In some cases, this effect appeared to be due to reduced postsynaptic potential amplitude; in other instances, it appeared to be due to an effect independent of neuromuscular transmission. The close temporal correlation between behavioural and electrophysiological observations suggests that the nervous and muscular systems are important sites of action of EGMB.     

Pyrethroid insecticides: Potent,stereospecific enhancers of mouse brain sodium channel activation

Deltamethrin and NRDC 157, pyrethroid insecticides that produce different poisoning syndromes in mammals, enhanced veratridine-dependent, sodium channel-mediated ²²Na⁺ uptake in mouse brain synaptosomes. Concentrations producing half-maximal enhancement were 2.5 × 10^?8M (deltamethrin) and 2.2 × 10^?7M (NRDC 157). This effect was stereospecific: The nontoxic 1S enantiomers had no significant effect on veratridine-dependent activation. At high deltamethrin concentrations, enhancement was maximal at 5 × 10^?5?1 × 10^?4M veratridine. Pyrethroid enhancement was completely blocked by 5 × 10^?6M tetrodotoxin, and neither pyrethroid affected ²²Na⁺ uptake in the absence of veratridine at concentrations up to 1 × 10^?5M. The relative potencies of deltamethrin and NRDC 157 in the synaptosomal sodium channel assay agree well with their relative acute toxicities to mice when administered by intracerebral injection. These findings demonstrate that pyrethroids exemplifying both characteristic poisoning syndromes are potent, stereospecific modifiers of sodium channel function in mammalian brain.     

Toxicokinetics of carbofuran in house fly, Musca domestica L

The kinetics of accumulation and elimination of lethal doses of [¹⁴C]carbofuran in the hemolymph of the house fly suggest a one-compartment open model. Carbofuran in the hemolymph appeared to be in equilibrium with that in the tissues very soon after treatment.Following topical application of carbofuran, the rate of onset of symptoms of poisoning was correlated with the amount of carbofuran in the hemolymph, and the onset of convulsions only occurred after the concentration of carbofuran in the hemolymph reached μM levels. This value correlated well with neurobioassays of known concentrations of carbofuran perfused in saline onto the isolated thoracic ganglion.Following topical doses, carbofuran concentration in the hemolymph reached a peak within an hour and then gradually declined. At an LD₆₀ dose, the initial decline in carbofuran concentration in the hemolymph over time was significantly slower than the decline after an LD₁₀ dose, suggesting saturation kinetics.Hemolymph was collected from house flies for up to 3 hr following topical application of toxic amounts of carbofuran. Thereafter, hemolymph volume decreased and blood samples could not be collected. Curiously, hemolymph samples could be collected for 5 hr from house flies that were injected with toxic doses of carbofuran.     

Toxicity of spinosad to susceptible and resistant strains of house flies,Musca domestica

The toxicity of spinosad, a new insecticide derived from the bacterium Saccharopolyspora spinosa, was evaluated against susceptible and resistant strains of house fly (Musca domestica L.). Spinosad was highly toxic to house flies based on 72-h LD₅₀ values and the symptoms of poisoning were consistent with a neurotoxic mechanism of action. Spinosad was relatively slow acting, with the maximum toxicity noted at 72 h. Piperonyl butoxide and S,S,S,-tribu-tylphosphorotrithioate synergized the toxicity of spinosad by 3·0- and 1·8-fold, respectively, while diethyl maleate had no significant effect. These results suggest that there is a small degree of monooxygenase-mediated spinosad detoxification in house flies, while hydrolases may be only minimally important and glutathione transferases may have no role. There were no substantial levels of cross-resistance detected, except in the LPR strain where a low 4·3-fold cross-resistance was observed. The cyclodiene-resistant OCR strain was 2·7-fold more sensitive to spinosad than the susceptible strain (CS). These results suggest that cross-resistance may not be a limiting factor for the use of spinosad against house flies. © 1998 Society of Chemical Industry     

In vivo measurement of house fly temperature,flight muscle potentials,heartbeat and locomotion during insecticide poisoning

The average heartbeat rate of female adult Musca domestica was near 250 beats/min in vivo at 23°C. However, standard deviation values ranged from ±35 to ±60 depending on the individual house fly. Heartbeat rates in tethered house flies fluctuated between cessation to over 300 beats/min. The heartbeat rate was temperature dependent with a Q₁₀ of 2.3. Either a bite by the Lynx spider, Peucetia vividans (Hentz), or severing the abdomen from the thorax caused the heartbeat to become extremely steady at near 300 beats/min which gradually decreased over several minutes.Application of lethal doses of Monitor or Lindane to the house fly caused thoracic temperature to increase by at most 3°C in conjunction with increased convulsive activity and increased average heartbeat rate. In late stages of poisoning, the heartbeat was relatively uniform indicating a disruption in cardioregulatory nervous activity. Response of the house fly to carbofuran or its N-thiomethyl analog was similar to that of Monitor and Lindane except in late stages of poisoning where the heartbeat continued to exhibit large variations in average rate.     

The action of insecticides on neurosecretory neurons in the stick insect, Carausius morosus

The action of insecticides on the spontaneous electrical activity of neurohemal tissue in the stick insect, Carausius morosus, has been studied using extracellular electrodes. The pyrethroid, permethrin, causes a massive increase in the frequency of the spontaneously generated action potentials at concentrations between 5 × 10^?5 and 5 × 10^?8M. Concentrations as low as 5 × 10^?11M are still effective in producing bursting activity.DDT, at concentrations between 5 × 10^?5M and 5 × 10^?6M, produces an overall increase in activity although the bursting activity is less violent than that shown with permethrin. DDT, 5 × 10^?7M, is ineffective at altering the resting pattern.Carbaryl and coroxon cause a transitory increase in electrical activity at 1 × 10^?4M, but are ineffective at 1 × 10^?5M.It is concluded that insecticides could have a direct effect upon the neurohormonal balance in insects.     

Metabolism of O,S-dimethyl propionyl- and hexanoylphosphoramidothioate in the house fly and white mouse

The metabolism of O,S-dimethyl propionyl- and hexanoylphosphoramidothioate was investigated in the white mouse and house flies. Compared to the hexanoylphosphoramidothioate, the propionyl analog is approximately 35-fold more toxic to house flies and is 10-fold less toxic to mice. On a percentage basis, substantially larger amounts of methamidophos were detected in house flies treated topically with the propionylphosphoramidothioate than in flies treated with the hexanoyl derivative. The reverse was evident in the case of the mouse where much larger amounts of methamidophos were formed after oral treatment with the hexanoylphosphoramidothioate. Minor amounts of other metabolic products also were detected, including an unknown from the hexanoylphosphoramidothioate. Metabolism of the S-methyl moiety to carbon dioxide appeared to be a major pathway for metabolic degradation of both compounds in both the white mouse and house fly. The difference in toxicity of the two acylphosphoramidothioates to the mouse and house fly is attributed to difference in the amounts of methamidophos formed in the animals.     

Indoxacarb resistance in the house fly, Musca domestica

Indoxacarb (DPX-MP062) is a recently introduced oxadiazine insecticide with activity against a wide range of pests, including house flies. It is metabolically decarbomethoxylated to DCJW. Selection of field collected house flies with indoxacarb produced a New York indoxacarb-resistant (NYINDR) strain with >118-fold resistance after three generations. Resistance in NYINDR could be partially overcome with the P450 inhibitor piperonyl butoxide (PBO), but the synergists diethyl maleate and S,S,S-tributyl phosphorothioate did not alter expression of the resistance, suggesting P450 monooxygenases, but not esterases or glutathione S-transferases are involved in the indoxacarb resistance. Conversely, the NYINDR strain showed only 3.2-fold resistance to DCJW, and this resistance could be suppressed with PBO. Only limited levels of cross-resistance were detected to pyrethroid, organophosphate, carbamate or chlorinated hydrocarbon insecticides in NYINDR. Indoxacarb resistance in the NYINDR strain was inherited primarily as a completely recessive trait. Analysis of the phenotypes vs. mortality data revealed that the major factor for indoxacarb resistance is located on autosome 4 with a minor factor on autosome 3. It appears these genes have not previously been associated with insecticide resistance.     

Genetic studies on glutathione-dependent reactions in resistant strains of the house fly,Musca domestica L

Genetic studies of glutathione-dependent reactions were conducted with a diazinon-resistant house fly strain in which resistance is controlled primarily by genes on chromsome II. The resistant strain was crossed with a susceptible strain which had mutant markers on chromosomes II, III, and V, and the F₁ was backcrossed to the susceptible strain. Glutathione transferase activities of the resultant eight phenotypes were measured using 3,4-dichloronitrobenzene, methyl iodide, and γ-benzene hexachloride as substrates. High levels of all these activities are controlled by gene(s) on chromosome II. Further analysis was made by introducing diazinon resistance into a susceptible strain via genetic crossing-over. Intermediate activity levels for 3,4-dichloronitrobenzene and methyl iodide conjugations were introduced along with intermediate levels of resistance. Assays of individual flies of the synthesized strain revealed they were heterogeneous for glutathione-dependent activities, consisting of individuals with low, intermediate, and high transferase activity. Based on these results, high levels of the glutathione-dependent enzymes are not a major biochemical mechanism responsible for diazinon resistance. It was also demonstrated that glutathione S-aryltransferase and S-alkyltransferase in the house fly, as measured with 3,4-dichloronitrobenzene and methyl iodide, are inseparable genetically and may, therefore, be the same enzyme.     

Diversity and frequencies of genetic mutations involved in insecticide resistance in field populations of the house fly (Musca domestica L.) from China

Insecticides have been extensively used for house fly control in China, with dichlorvos and deltamethrin being widely used. Knowledge about the current status of insecticide resistance and the underlying genetic changes is crucial for developing effective fly control strategies. The susceptibility to dichlorvos and deltamethrin, and the frequencies of genetic mutations involved in insecticide resistance were studied in five field populations of the house fly collected across China. Bioassay results show that flies exhibit 14- to 28-fold resistance to dichlorvos and 41- to 94-fold resistance to deltamethrin, indicating that dichlorvos and deltamethrin resistance are common in house fly populations in China. Molecular analysis reveals that flies from the five various locations carry resistance alleles at multiple loci and have diverse allelic types, different relative frequencies and combinations of each allele. Four non-synonymous single nucleotide polymorphisms (SNPs) (i.e. V260L, G342A/V, F407Y) in acetylcholinesterase (Ace) and two mutations (W251L/S) in a carboxylesterase (MdαE7) were commonly present in the field house flies. The L1014H rather than L1014F mutation in the voltage sensitive sodium channel gene (Vssc) was widely distributed in Chinese house flies. CYP6D1v1, which confers pyrethroid resistance, was found in all the five tested populations in China, although its frequency in house fly from Shandong province was very low. Our results suggest that resistance monitoring and management of house flies should be customized for a given location.     

Frequencies and evolution of organophosphate insensitive acetylcholinesterase alleles in laboratory and field populations of the house fly, Musca domestica L.

Resistance to organophosphate (OP) and/or carbamate insecticides can be due to mutations in the acetylcholinesterase gene (Ace). Genotypes of house fly, Musca domestica L., Ace were determined in twelve laboratory maintained strains (originally from North America, Europe and Asia) and two field collected populations from New York and Florida. There were 15 Ace alleles found and 11 of the alleles coded for a susceptible form of the enzyme (i.e., V260, A316, G342 and F407). Three of the four resistance alleles were previously described, while one is new. Phylogenetic analysis of the alleles suggests multiple origins of the F407Y mutation and multiple origins of the G342A mutation that confer OP resistance. Genotyping of field collected house flies from New York and Florida populations revealed the presence of only one resistance allele, Acev10 (containing the non-synonymous mutations for A342 and Y407). All other alleles detected from the field-collected flies coded for a susceptible AChE. Thus, we were able to categorize individual flies as having homozygous susceptible (Ace^S/Ace^S), homozygous insensitive (Ace^I/Ace^I or Acev10/Acev10) or heterozygous AChE. The frequencies of Ace^S and Ace^I were not different between the NY2002 and FL2002 populations. Both populations were out of Castle-Hardy-Weinberg equilibrium, having an excess of Ace^S/Ace^I individuals and very few Ace^S/Ace^S individuals. Comparison of Ace, Vssc and CYP6D1 genotypes indicates individual house flies commonly have resistance alleles at multiple loci. Comparison of genotype data with bioassays, as well as the use of genotype data in resistance studies is discussed.     

Studies on the chiral isomers of fonofos and fonofos oxon: III. In vivo metabolism

The metabolism of the chiral isomers of ³⁵S-labeled fonofos was examined in the house fly and white mouse. Metabolism of the chiral isomers of fonofos oxon also was investigated in the mouse. Little difference in either the rate of penetration or pattern of metabolism was observed between house flies treated with the (R)_P and (S)_P enantiomers of fonofos. At the higher dosage of 8 mg/kg the less toxic (S)_P enantiomer was degraded in mice and eliminated in significantly larger amounts than (R)_P-fonofos. However, at the sublethal dosage of 4 mg/kg little difference in degradation and total elimination was observed between the two isomers although the excretion rate appeared to be faster initially with the less toxic enantiomer. Overall, metabolism and excretion of the chiral isomers of both fonofos and fonofos oxon took place more rapidly and to a greater extent with the less toxic enantiomer.     

Glutathione S-transferase in the house fly: Biochemical and genetic changes associated with induction and insecticide resistance

Kinetic parameters were measured for glutathione S-transferase, an enzyme important in metabolic resistance to insecticides, in one susceptible and two insecticide-resistant strains of the house fly (Musca domestica L.), and in untreated and chemically induced flies. Both resistant strains differed from the susceptible strain in apparent K_m values for the enzyme, while only one differed in apparent V_max. Two of the strains were inducible with phenobarbital; the third with 3-methylcholanthrene. Kinetic analysis indicated enzyme induction was associated with changes in K_m rather than V_max, and genetic experiments showed that most variation relating to K_m and V_max was controlled by chromosome II. Based on these results, both metabolic resistance and induction of enzyme activity were associated primarily with the production of different forms of glutathione S-transferase rather than more of the enzyme present in susceptible flies.     

In vitro inhibition of acetylcholinesterase by O,O-dimethyl S-aryl phosphorothioates

In vitro inhibition of house cricket head, house fly head, and bovine erythrocyte acetylcholinesterase by O,O-dimethyl S-aryl phosphorothioates was studied by Main's kinetic treatment. The potency of the compounds as reflected by the bimolecular reaction constants (k_i) indicated that house fly head acetylcholinesterase was the most sensitive to the inhibition followed by house cricket head and bovine erythrocyte acetylcholinesterase. There are no linear relationships between the phosphorylation rate constants and the total binding energies for the inhibition of three enzymes by this series of compounds, suggesting that the initial binding and the phosphorylation rate are not related. The structure and activity relationships were analyzed by multiple regression analyses with the use of Hammett's sigma, alkaline hydrolysis rates of the compounds, and p_i constants. The hydrophobic bonding of the compound on the enzyme surface as reflected by the p_i constant played a significant role in the determination of the potency of the inhibition of house cricket head and house fly head acetylcholinesterase by those compounds. However, the alkaline hydrolysis rates of the compounds, or the Hammett's sigma values seems to play a more important role in the determination of the inhibition of bovine erythrocyte acetylcholinesterase. Moderate insecticidal activity toward house crickets, house flies, and mosquito larvae were found.     

Genetic and biochemical mechanisms limiting fipronil toxicity in the LPR strain of house fly,Musca domestica

Fipronil is a new insecticide which exerts its toxic action by interacting with the insect GABA-gated chloride channel. Previous studies have shown that cyclodiene-resistant insects have low to moderate levels of cross-resistance to fipronil, while other resistant strains are usually susceptible. In contrast, we recently found a strain (LPR) of house fly (Musca domestica L) with 15-fold cross-resistance to fipronil that was not associated with cyclodiene resistance. Fipronil cross-resistance in LPR was inherited as an intermediately dominant, autosomal, multigenic trait. [¹⁴C]Fipronil was observed to penetrate into LPR flies more slowly than into susceptible flies. S,S,S-tributylphosphorotrithioate and diethyl maleate pretreatment did not reduce the level of fipronil cross-resistance, while piperonyl butoxide resulted in a slight decrease. These results indicate that decreased penetration and monooxygenase-mediated detoxification may be mechanisms contributing to fipronil cross-resistance in the LPR strain. © 1999 Society of Chemical Industry