The relationship of esterases to organophosphorus insecticide tolerance in mosquitofish

The levels of peripheral acetylcholinesterase and carboxylesterases and their organophosphate sensitivities were studied in two populations of mosquitofish (Gambusia affinis). One population, highly resistant to organochlorine insecticides, demonstrated a low tolerance to parathion and methyl parathion. The organochlorine resistant fish possessed higher levels of both peripheral acetylcholinesterase and carboxylesterases. The sensitivities of these esterases to organophosphate inhibition were the same in both populations. The esterases were more sensitive to paraoxon than to methyl paraoxon. Carboxylesterases were far more sensitive to organophosphate inhibition than was acetylcholinesterase. Carboxylesterases, by their higher affinity for the organophosphates, may serve to protect acetylcholinesterase from inhibition.     

Biochemical characteristics of insecticide resistance in the fall armyworm, Spodoptera frugiperda (J.E. Smith)

A strain of the fall armyworm, Spodoptera frugiperda (J.E. Smith), collected from corn in Citra, Florida, showed high resistance to carbaryl (562-fold) and methyl parathion (354-fold). Biochemical studies revealed that various detoxification enzyme activities were higher in the field strain than in the susceptible strain. In larval midguts, activities of microsomal oxidases (epoxidases, hydroxylase, sulfoxidase, N-demethylase, and O-demethylase) and hydrolases (general esterase, carboxylesterase, β-glucosidase) were 1.2- to 1.9-fold higher in the field strain than in the susceptible strain. In larval fat bodies, various activities of microsomal oxidases (epoxidases, hydroxylase, N-demethylase, O-demethylases, and S-demethylase), glutathione S-transferases (CDNB, DCNB, and p-nitrophenyl acetate conjugation), hydrolases (general esterase, carboxylesterase, β-glucosidase, and carboxylamidase) and reductases (juglone reductase and cytochrome c reductase) were 1.3- to 7.7-fold higher in the field strain than in the susceptible strain. Cytochrome P450 level was 2.5-fold higher in the field strain than in the susceptible strain. In adult abdomens, their detoxification enzyme activities were generally lower than those in larval midguts or fat bodies; this is especially true when microsomal oxidases are considered. However, activities of microsomal oxidases (S-demethylase), hydrolases (general esterase and permethrin esterase) and reductases (juglone reductase and cytochrome c reductase) were 1.5- to 3.0-fold higher in the field strain than in the susceptible strain. Levels of cytochrome P450 and cytochrome b₅ were 2.1 and 1.9-fold higher, respectively, in the field strain than in the susceptible strain. In addition, acetylcholinesterase from the field strain was 2- to 85-fold less sensitive than that from the susceptible strain to inhibition by carbamates (carbaryl, propoxur, carbofuran, bendiocarb, thiodicarb) and organophosphates (methyl paraoxon, paraoxon, dichlorvos), insensitivity being highest toward carbaryl. Kinetics studies showed that the apparent K_m value for acetylcholinesterase from the field strain was 56% of that from the susceptible strain. The results indicated that the insecticide resistance observed in the field strain was due to multiple resistance mechanisms, including increased detoxification of these insecticides by microsomal oxidases, glutathione S-transferases, hydrolases and reductases, and target site insensitivity such as insensitive acetylcholinesterase. Resistance appeared to be correlated better with detoxification enzyme activities in larval fat bodies than in larval midguts, suggesting that the larval fat body is an ideal tissue source for comparing detoxification capability between insecticide-susceptible and -resistant insects.     

Juvenile hormone analogs: Toxicity and cross-resistance in the housefly

The toxicity of several juvenile hormone analogs (JHAs) to susceptible and insecticide-resistant housefly (Musca domestica L.) strains was determined by an assay procedure in which larvae were exposed to residues of JHAs in glass vials. All JHAs tested were toxic and the most active compound, isopropyl 11-methoxy-3, 7, 11-trimethylododeca-2, 4-dienoate, was 100 times as toxic to the susceptible Orlando Regular strain as methyl parathion and 600 times as toxic as DDT.A 5- to 30-fold tolerance to the different JHAs was present in an insecticide resistant strain in which resistance is associated with a high level of NADPH-dependent microsomal oxidase activity controlled by a gene(s) on chromosome II. Cross-resistance was less marked in a strain with a chromosome V high oxidase gene and absent in strains with other resistance mechanisms.The data indicate that cross-resistance to JHAs in insects may occur in certain strains with high levels of oxidative detoxifying activity. Even so, the most active JHA was far more toxic to both susceptible and resistant strains than methyl parathion or DDT.     

Insensitive acetylcholinesterase,high glutathione-S-transferase,and hydrolytic activity as resistance factors in a tetrachlorvinphos-resistant strain of house fly

The gene producing insensitive acetylcholinesterase in a tetrachlorvinphos-resistant strain of house fly was introduced into the genome of a susceptible strain. The resistance to a number of organophosphorus insecticides, which was high in the original strain (234- and more than 800-fold for paraoxon and tetrachlorvinphos, respectively), was much lower in the resulting strain, ranging from 53-fold for paraoxon to 3.9-fold for tetrachlorvinphos. Synergists further decreased these factors. The reduction in sensitivity of the acetylcholinesterase in vitro was about 20-fold for both inhibitors. The Michaelis parameters for hydrolysis of acetylcholine and acetylthiocholine of the mutant and normal acetylcholinesterase showed only minor differences. An increased rate of metabolism of the insecticides was found in the original strain. In vitro, glutathione-dependent detoxication was from 9- to 120-fold that of a susceptible strain, depending on the insecticide and the conditions used. The enzyme de-alkylated parathion and methylparaoxon, but there was no de-arylation of parathion, although it is important in other strains. In vitro, paraoxon and methylparaoxon were also hydrolysed, and this is not so in the susceptible strain. The high resistance present in the original strain seems to be due to joint action of at least three mechanisms.     

in vitro metabolism of azinphosmethyl in susceptible and resistant houseflies

The in vitro metabolism of [¹⁴C-methoxy] or [³²P]azinphosmethyl by subcellular fractions of abdomens from a resistant and a susceptible strain of houseflies was studied. The degradative activity in both strains was associated with the microsomal and soluble fractions and required NADPH and glutathione, respectively. The resistant strain possessed higher activity for both the mixed-function oxidases and the glutathione transferase than the susceptible strain, and both systems appear to be important in the resistance mechanism. The mixed-function oxidases were involved in the oxidative desulfuration as well as the dearylation of azinphosmethyl. A glutathione transferase located in the soluble fraction catalyzed the formation of desmethyl azinphosmethyl and methyl glutathione. This enzyme also demethylated azinphosmethyl oxygen analog. Although the soluble fraction exhibited both glutathione S-alkyltransferase and S-aryltransferase activity against noninsecticidal substrates, no evidence of the transfer of the benzazimide moiety from azinphosmethyl to glutathione was obtained. Sephadex G-100 chromatography of the soluble enzymes revealed a common eluting fraction responsible for both types of transferase activity.     

橘小实蝇对甲氨基阿维菌素苯甲酸盐的抗性机制及对其他药剂的交互抗性

入侵害虫橘小实蝇严重为害蔬菜、花卉、水果等经济作物,目前在田间常使用杀虫剂进行防治。为探索甲氨基阿维菌素苯甲酸盐(甲维盐)防控橘小实蝇的抗性风险,采用药膜法测定了橘小实蝇抗甲维盐种群(EB)对8种杀虫剂的交互抗性水平,并测定了橘小实蝇EB种群、金华田间种群(JH)和敏感种群(S)的解毒酶活性。历经33代筛选,橘小实蝇EB种群对甲维盐产生了43.4倍的中等水平抗性,对阿维菌素存在中等水平交互抗性,对吡虫啉、辛硫磷、马拉硫磷存在低水平交互抗性,对噻虫胺、高效氯氟氰菊酯、多杀霉素和虫螨腈未表现出交互抗性。胡椒基丁醚(PBO)、磷酸三苯酯(TPP)和顺丁烯二酸二乙酯(DEM)均可显著提高甲维盐对橘小实蝇EB种群、JH种群和S种群的室内毒力。橘小实蝇EB种群细胞色素P450(3.9倍)和b₅含量(3.3倍)、O-脱甲基酶活性(4.2倍)、谷胱甘肽S-转移酶活性(2.7倍)、羧酸酯酶活性(3.2倍)显著高于S种群。多功能氧化酶、谷胱甘肽S-转移酶、羧酸酯酶活性显著增强可能是橘小实蝇对甲维盐产生高水平抗性的重要机制。     

The toxicological significance of paraoxon deethylation

The in vivo formation of deethylation and hydrolytic products of paraoxon degradation after parathion or paraoxon administration was nearly equal in control male rats, and the relative abundance of metabolites was not appreciably altered by pretreatment of rats with enzymeinducing agents. However, pretreatment with inducers dramatically increased the oxidative paraoxon O-deethylase of male rat liver while having little effect on hydrolytic enzymes. Prior to induction, the hepatic O-deethylase activity was greatly inferior to the various hydrolytic enzymes, but nearly equal levels of both enzyme systems were found after induction. These results indicate that a large portion of the hepatic hydrolases detected in vitro is not active in vivo. It also appears that the majority of the induced hepatic deethylase was not involved in vivo at the dosage levels employed. The in vivo metabolism of monoethyl paraoxon was also demonstrated. The predominant metabolite of ethyl-[1-¹⁴C]monoethyl paraoxon is ¹⁴CO₂, while phenyl-[1-¹⁴C]monoethyl paraoxon yielded 4-nitro[1-¹⁴C]phenol. Paraoxon deethylation was also shown to be an important detoxication mechanism in female rats and male mice and must be considered in interpreting the toxicological properties of parathion and paraoxon.     

Effect of liver enzyme induction on paraoxon metabolism in the rat

Orally administered [1-¹⁴C]ethyl paraoxon, O,O-diethyl-O-p-nitrophenyl phosphate, is readily absorbed from the gastrointestinal tract of male albino rats. Radioactivity is essentially eliminated in 72 hr by excretion into urine and feces and by expiration as ¹⁴CO₂. Compounds with radioactivity in the urine are tentatively identified as diethyl phosphoric acid, desethyl paraoxon, ethanol, metabolites conjugated with amino acids, and paraoxon; the first compound is the predominant radioactive metabolite. Intraperitoneally injected phenobarbital, DDT, dieldrin, and endrin are inducers of microsomal enzymes that degrade paraoxon. The aryl phosphate-cleaving activity in vitro is not dependent on the addition of NADPH. O-Dealkylation of paraoxon is catalyzed by microsomal enzymes that require NADPH and oxygen and are inhibited by carbon monoxide. Microsomal enzymes from rats pretreated with enzyme inducers give an increased rate of O-dealkylation of paraoxon. Reduced glutathione has little or no effect on paraoxon degradation by either microsomal or soluble enzymes. Actinomycin D inhibits O-dealkylation of paraoxon in vivo, as indicated by reduction of ¹⁴CO₂ formation, and in vitro, as indicated by decreased activity of microsomal O-dealkylase. The role of microsomal mixed-function oxidases and NADPH-dependent O-dealkylase in the metabolism of organophosphorus insecticides is discussed.     

Glutathione-dependent degradation of parathion and its significance for resistance in the housefly

Glutathione-dependent degradation of parathion was studied in six strains of houseflies to find out whether it might be important as a cause of resistance. When supernatant fractions of high-speed centrifuged homogenates were fortified with glutathione and incubated with parathion, water-soluble products were formed. The rate of parathion detoxication was highest in a malathion-resistant strain (c. 4 μg parathion degraded per abdomen per hour), lowest in a susceptible strain, and intermediate in some other organophosphate-resistant strains. In one of the latter strains, E₁, the gene for glutathione-dependent degradation is located on the second chromosome, closely linked with gene cm⁺. This is the same chromosome on which gene a for low ali-esterase activity and hydrolytic detoxication of paraoxon is located. It is not likely that the gene for glutathione-dependent degradation is identical with gene a, since it is also present in strain Nie which lacks gene a, and, therefore, the presence of a separate gene which is called gene g is postulated.     

Metabolism and absorption of methyl parathion by tobacco budworms resistant or susceptible to organophosphorus insecticides

Factors involved in insecticide resistance were evaluated by using ¹⁴C-labeled methyl parathion and aldrin to compare rates of absorption and metabolism by Heliothis virescens (F.) larvae that were resistant (R) and susceptible (S) to methyl parathion. Tests with third-stage R and S larvae suggested that the rate of insecticide absorption from the cuticular surface was not a major resistance factor. Further evidence for this assumption was demonstrated by the resistance of R larvae to injected and orally administered doses of methyl parathion. Smaller amounts of unmetabolized methyl parathion and aldrin were recovered from S larvae, an indication that differences in metabolism were probably related to the resistance.     

棉铃虫对甲氧虫酰肼抗性机理的初步研究

在室内通过抗性汰选和敏感性反汰选,获得了对甲氧虫酰肼抗性指数相差为72.61倍的棉铃虫Helicoverpa amigera(Hübner)抗性种群和敏感种群。通过增效试验和离体酶活性测定表明:棉铃虫对甲氧虫酰肼产生的抗药性主要与其多功能氧化酶(MFO)、全酯酶和谷胱甘肽-S-转移酶(GSTs)活性的提高有关。     

Induction of detoxification enzymes by triazine herbicides in the fall armyworm, Spodoptera frugiperda (J.E. Smith)

The inductive effect of six triazine herbicides on a variety of detoxification enzymes was investigated in fall armyworm (Spodoptera frugiperda) larvae maintained on an artificial diet. Dietary atrazine induced nine microsomal oxidase activities ranging from 1.3- to 21.6-fold, 12 glutathione S-transferase activities ranging from 1.3- to 4.2-fold, four hydrolase activities ranging from 1.3- to 2.9-fold, and two reductase activities ranging from 1.5- to 5.1-fold, depending on the enzyme assayed and tissue source (midgut vs. fat body) used. Simazine, cyanazine, ametryn, tebutryn, and terbuthylazine also induced these detoxification enzymes. The induction of microsomal oxidase (aldrin epoxidase) ranged from 1.2- to 11-fold, glutathione S-transferase (CDNB) ranged from 1.3- to 4-fold, and general esterase ranged from 1.4- to 4.1-fold, depending on the tissue source examined. In general, fat bodies were more inducible than midguts with respect to these detoxification enzymes, especially the microsomal oxidases. The induction by atrazine was associated with decreased toxicity of carbaryl, permethrin and indoxacarb, but increased toxicity of methyl parathion, phorate, and trichlorfon.     

Biochemical studies on sheep body louse Bovicola ovis (Schrank) (Phthiraptera: Trichodectidae): comparison of pyrethroid and organophosphate resistant and susceptible strains

Strains of sheep louse Bovicola ovis (Schrank) with various levels of resistance to pyrethroid and one strain with high degree of resistance to organophosphate (OP) insecticides were used to investigate the biochemical mechanisms of insecticide resistance, i.e., enhanced levels of general esterases, specific acetylcholinesterases (AChE), glutathione S-transferase (GST), and mixed function oxidases. Native gel electrophoresis combined with quantitative enzyme assays showed analogous expression profiles of several esterase isozymes in all the strains tested. The determination of the sensitivity of each esterase isozyme to five inhibitors (acetylthiocholine iodide, butyrylthiocholine iodide, paraoxon eserine sulfate, and pCMB) led to the identification of nine esterases in the B. ovis strain. Gel electrophoresis results are supported by enzyme assay studies where, except for the OP resistant strain, no differences in esterase activities were detected in all the pyrethroid resistant and susceptible strains assayed. Statistical analyses demonstrated that some strains have elevated GST activities compared to the susceptible reference strain.     

Effect of dihydrodillapiole on pyrethroid resistance associated esterase inhibition in an Indian population of Spodoptera litura (Fabricius)

Resistance in Spodoptera litura (Fabricius) has been attributed to enhanced detoxification of insecticides by increased levels of esterases, oxidases and/or glutathione S-transferases. Enzyme inhibiting insecticide synergists can be employed to counter increased levels of such enzymes in S. litura. Dihydrodillapiole induced synergism of pyrethroid toxicity was examined in the laboratory-reared third instar larval population of S. litura collected in Delhi (susceptible), and Guntur (resistant) region of Andhra Pradesh, India. The Guntur population was found to be 7.04 and 10.19 times resistant to cypermethrin and lambdacyhalothrin, respectively. The activity of cypermethrin, lambdacyhalothrin and profenophos against susceptible and resistance populations of S. litura, was gradually increased when used along with a plant-derived insecticide synergist dihydrodillapiole. The α-naphthyl acetate hydrolysable esterase activity in Delhi population was less as compared to the Guntur population. Resistance associated esterases in Delhi population were inhibited by pre-treatment with dihydrodillapiole. The esterase level in insect was instantly reduced initially, sustained for about 3 h and equilibrated at 4 h post treatment. The esterase activity of Guntur population was increased to 1.28 μmoles/mg/min at 2 h post treatment and subsequently reduced to lower than 0.70 μmoles at 4-12 h post treatment. The variation in esterase activity is suggestive of its homeostatic regulation in test populations. Dihydrodillapiole thus caused significant reduction of resistance in S. litura to cypermethrin, lambda cyhalothrin and profenophos.     

The biochemical basis of resistance to organophosphorus insecticides in the sheep blowfly, Lucilia cuprina

The metabolism in vivo and in vitro of [¹⁴C]parathion and [¹⁴C]paraoxon was studied in a susceptible (LS) and an organophosphorus-resistant (Q) strain of the sheep blowfly, Lucilia cuprina. Both strains detoxified the insecticides in vivo via a number of pathways, but the resistant strain produced more of the metabolites diethyl phosphate and diethyl phosphorothionate. No difference was found between strains in the rate of penetration of the compounds used. Also, in vitro studies showed no difference between strains in the sensitivity of head acetylcholinesterase to inhibition by paraoxon. Both the microsomal and the 100,000g supernatant fractions degraded paraoxon, but resistance in Q could be explained by the eightfold greater rate of diethyl phosphate production with or without added NADPH. Parathion was also degraded to diethyl phosphorothionate by an NADPH-requiring enzyme in microsomal preparations from both strains. However, Q produced significantly more diethyl phosphorothionate in vivo than LS. It was concluded that organophosphorus resistance in Q was due mainly to a microsomal phosphatase hydrolyzing phosphate but not phosphorothionate esters, probably enhanced by a microsomal oxidase detoxifying the latter.     

DDE increases the toxicity of parathion to coturnix quail

Adult male Japanese quail (Coturnix coturnix) were exposed to DDE or chlordane in the diet and subsequently dosed with parathion or paraoxon. Pretreatment with 5 or 50 ppm DDE in the diet for 12 weeks resulted in increased cholinesterase (ChE) activity in plasma, but not in the brain. Dietary concentrations of 5 and 50 ppm DDE caused increased susceptibility of quail that were challenged with parathion or paraoxon. The increased mortality resulting from DDE pretreatment was reflected in brain ChE inhibition. The synergistic action of DDE was apparent after 3 days of exposure to 50 ppm DDE and 1 week of exposure to 5 ppm DDE. Birds exposed for 3 weeks to 5 or 50 ppm DDE retained their DDE-potentiated sensitivity to parathion after 2 weeks on clean diet. Chlordane pretreatment resulted in decreased susceptibility (antagonism) to parathion, but not to paraoxon dosage. Implications of differing responses in ChE and mortality among controls, DDE-, and chlordane-pretreated birds after parathion or paraoxon dosage are discussed.     

Comparative toxicity,absorption, and metabolism of chlorpyrifos and its dimethyl homologue in methyl parathion-resistant and -susceptible tobacco budworms

Chlorpyrifos (Dowco 179) and its dimethyl homologue, chlorpyrifosmethyl (Dowco 214), were used to study the influence of the O,O-dialkyl group of organophosphorus insecticides on toxicity, absorption, and metabolism among larvae of the tobacco budworm [Heliothis virescens (F.)] from strains that were resistant (R) and susceptible (S) to methyl parathion. In toxicity tests, chlorpyrifos and chlorpyrifosmethyl were more toxic than methyl parathion to 3rd-stage R larvae but less toxic to S larvae. Chlorpyrifosmethyl was more toxic (3–4 ×) than chlorpyrifos to both strains of larvae, and the results of absorption studies indicated that the toxicity differential of the homologues may be explained in part by the more rapid absorption of the dimethyl form. Studies of the in vivo metabolism of both Dowco compounds indicated that each was degraded mainly by the cleavage of the pyridylphosphate linkage. In vitro tests demonstrated that the NADPH-dependent microsomal oxidases were of primary importance in detoxification, while glutathione (GSH)-dependent mechanisms (aryl- and alkyltransferases) present in the soluble cell fractions were of lesser importance. O-dealkylation occurred only with chlorpyrifosmethyl. The R larvae demonstrated greater capability in detoxifying both compounds in the comparative in vivo and in vitro studies of metabolism, but the differences were more apparent during the 5th instar than during the 3rd instar.     

Degradation of parathion applied to peach leaves.

Parathion was applied to peach trees in three different formulations 70 days before harvest. Leaf samples were taken periodically through the 70-day period and gas-liquid chromatographic analyses were conducted for dislodgable and penetrated residues. Analyses were also conducted for paraoxon and the s-ethyl isomer of parathion. Punched samples were compared to whole-leaf samples; generally residue levels for both types corresponded closely. A new experimental formulation, encapsulated parathion, produced highest levels of total parathion throughout the 70-day study, but even this formulation resulted in low total residue levels around 1 ppm at time of harvest. Degradation of the s-ethyl isomer of parathion was generally very rapid in all formulations studied. Dislodgable residues of paraoxon may be significant in some formulations and should be included in parathion degradation studies. Much of the parathion found on peach leaves throughout the growing season was dislodgable residue, but this depended considerably on the formulation used.     

The biochemistry of insecticide resistance in Anopheles sacharovi: Comparative studies with a range of insecticide susceptible and resistant Anopheles and Culex species

Fourth instar larvae, the progeny from wild-caught Anopheles sacharovi females, were subjected to a number of biochemical tests and the results were compared to those from similar tests on laboratory insecticide resistant and susceptible strains of anopheline and culicine mosquitoes. DDT resistance in An. sacharovi is associated with the ability to rapidly metabolise DDT to DDE. The organophosphorus and carbamate resistance was not associated with quantitative changes in esterases, multifunction oxidases, or glutathione S-transferase. The acetylcholinesterase was less sensitive to malaoxon and propoxur than laboratory susceptible An. albimanus, and plots of inhibition suggest that the population was polymorphic for more than one form of acetylcholinesterase. Metabolism studies on malathion and pirimiphos methyl did not indicate resistance due to increased metabolism. There was no evidence of penetration barriers contributing to resistance to either DDT or malathion, and there was no indication of any resistance to pirimiphos methyl in our tests.     

An evaluation of the role of oxidative enzymes in Colorado potato beetle resistance to carbamate insecticides

Carbofuran and carbaryl LD₅₀ values were determined with and without piperonyl butoxide pretreatment for a resistant (New Jersey) and two susceptible (Utah and Netherland) populations of Colorado potato beetle larvae. Similar bioassays were conducted with carbofuran for resistant (Rutgers) and susceptible (NAIDM) adult house flies. The degree of resistance development by New Jersey Colorado potato beetles (RR = 848) was greater than that of the laboratory-selected colony of Rutgers house flies (RR = 583). Comparisons of synergist difference calculations including “percentage synergism” (%S), “log percentage synergism” (L%S), and “relative percentage synergism (R%S) for the resistant (R) and the susceptible (S) populations indicated the possibility that monooxygenases and other resistance mechanisms may be involved in Colorado potato beetle resistance to these carbamates. Monooxygenase involvement in resistance of Rutgers house flies was demonstrated in vitro by a 4-fold enhancement of p-nitroanisole O-demethylation over that of NAIDM house flies. O-demethylation of p-nitroanisole could not be demonstrated for potato beetle larvae. Colorado potato beetle resistance was associated with increases in microsomal levels of NADPH-cytochrome c reductase (ca. 2-fold) and NADPH oxidation (1.2-fold). The inability to measure O-demethylation in Colorado potato beetles may have been due to the solubilization of NADPH-cytochrome c reductase during microsomal preparation. Significant differences between resistant and susceptible Colorado potato beetle larvae were not observed in the penetration of [¹⁴C]carbaryl. Excretion of the radiocarbon may have been significantly greater in the resistant New Jersey population, but some of the insecticide may have also rubbed off the cuticle. This increased capacity for excretion, combined with increased levels of monooxygenase enzymes, could account for the high resistance level of this population.