The effect of O,S,S,-trimethyl phosphorodithioate on the in vivo metabolism of phenthoate in the rat     

S.G.K. Lee  T.R. Fukuto 《Pesticide biochemistry and physiology》1985,23(2):240-246

The in vivo metabolism of phenthoate (O,O-dimethyl S-[α-(carboethoxy)benzyl]phosphorodithioate) was followed in rats after oral administration of a nontoxic dose of 100 mg/kg. The same metabolic study was conducted following coadministration of 0.5% O,S,S-trimethyl phosphorodithioate (OSS-Me). When administered alone, phenthoate was metabolized principally by carboethoxy ester hydrolysis and cleavage of the PO and CS bonds, resulting in at least six metabolites. The primary urinary metabolite excreted was phenthoate acid. Coadministration of 0.5% OSS-Me did not alter the types of metabolites excreted. However, a reduction of the carboxylesterase-catalyzed product (phenthoate acid) was observed, indicating that the enzyme responsible for the major pathway of phenthoate detoxication was inhibited. Alternate detoxication processes did not compensate for the reduction in carboxylesterase-catalyzed detoxication. It was concluded that inhibition of the carboxylesterase enzymes is the major cause of the potentiation of phenthoate toxicity by OSS-Me.  相似文献   

in vitro metabolism of azinphosmethyl in susceptible and resistant houseflies     

Naoki MotoyamaW.C. Dauterman 《Pesticide biochemistry and physiology》1972

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.  相似文献   

Metabolism of O,O-dimethyl S-[α-carboethoxy)benzyl]phosphorodithioate (phenthoate) in the white mouse and house flies     

Dennis Y. Takade  Thurman Allsup  Abdallah Khasawinah  T.S. Kao  T.R. Fukuto 《Pesticide biochemistry and physiology》1976,6(4):367-376

The metabolism of O,O-dimethyl S-[α-(carboethoxy)benzyl]phosphorodithioate (phenthoate), an organophosphorus insecticide of low mammalian toxicity, was investigated in white mice and in susceptible and resistant strains of house flies. Phenthoate was metabolized rapidly in the mouse to a wide variety of detoxication products and only an insignificant amount of phenthoate oxon was detected. The same detoxication products were produced in house flies but, compared to the mouse, substantial amounts of phenthoate oxon also were found. The selective toxicity of phenthoate between insect and mammal is attributable to the difference in the accumulation of the oxon.  相似文献   

Fipronil metabolism,oxidative sulfone formation and toxicity among organophosphate‐ and carbamate‐resistant and susceptible western corn rootworm populations     

Michael E Scharf  Blair D Siegfried  Lance J Meinke  Laurence D Chandler 《Pest management science》2000,56(9):757-766

Fipronil toxicity and metabolism were studied in two insecticide‐resistant, and one susceptible western corn rootworm (Diabrotica virgifera virgifera, LeConte) populations. Toxicity was evaluated by exposure to surface residues and by topical application. Surface residue bioassays indicated no differences in fipronil susceptibility among the three populations. Topical bioassays were used to study the relative toxicity of fipronil, fipronil + the mono‐oxygenase inhibitor piperonyl butoxide, and fipronil's oxidative sulfone metabolite in two populations (one resistant with elevated mono‐oxygenase activity). Fipronil and fipronil‐sulfone exhibited similar toxicity and application of piperonyl butoxide prior to fipronil resulted in marginal effects on toxicity. Metabolism of [¹⁴C]fipronil was evaluated in vivo and in vitro in the three rootworm populations. In vivo studies indicated the dominant pathway in all populations to be formation of the oxidative sulfone metabolite. Much lower quantities of polar metabolites were also identified. In vitro studies were performed using sub‐cellular protein fractions (microsomal and cytosolic), and glutathione‐agarose purified glutathione‐S‐transferase. Oxidative sulfone formation occurred almost exclusively in in vitro microsomal reactions and was increased in the resistant populations. Highly polar metabolites were formed exclusively in in vitro cytosolic reactions. In vitro reactions performed with purified, cytosolic glutathione‐S‐transferase (MW = 27 kDa) did not result in sulfone formation, although three additional polar metabolites not initially detectable in crude cytosolic reactions were detected. Metabolism results indicate both cytochromes P450 and glutathione‐S‐transferases are important to fipronil metabolism in the western corn rootworm and that toxic sulfone formation by P450 does not affect net toxicity. © 2000 Society of Chemical Industry  相似文献   

Transformation of aldicarb sulfoxide and aldicarb sulfone in four water-saturated sandy subsoils     

Johan H. Smelt  Ariette E. Van De Peppel-Groen  Minze Leistra 《Pest management science》1995,44(4):323-334

The transformation of aldicarb sulfoxide and aldicarb sulfone was studied in incubations with water-saturated subsoils under simulated field conditions at 10°C. The subsoils were collected at four locations from beneath the water table at a depth of 2.5 to 3.5 m. In three of the subsoils, the half-life of sulfoxide, incubated at concentrations of 0.14-0.17 mg litre^?1, ranged from 0.7 to 2.8 years. At higher concentrations (8-13 mg litre^?1), its half-life ranged from 3.4 to 6.4 years. At the lower concentration, a large fraction of sulfoxide was transformed into sulfone. The rates of transformation of the sulfone at the lower concentration in the three subsoils corresponded to half-lives of 3.3 to 8.1 years, but in only one subsoil was a significant transformation rate (half-life 6.7 years) measured at the higher concentration during the 2.3-year incubation period. The half-lives at the lower concentrations were more like those in field studies, and perhaps would still underestimate transformation rates under field conditions. After a year, 2.5-15% of the higher sulfoxide and sulfone doses had been trapped as [¹⁴C] carbon dioxide. In the fourth subsoil, with more anaerobic conditions, the half-life of sulfoxide at both concentrations was less than 0.02 year and that of sulfone was about 0.04 year. Four or five radio-labelled transformation products could be traced in this subsoil and about half of the dose of both compounds was trapped as [¹⁴C] carbon dioxide.  相似文献   

Metabolic resistance mechanisms of the housefly (Musca domestica) resistant to pyraclofos     

Si-Woo Lee  Kazunari Ohta  Toshio Shono 《Pesticide biochemistry and physiology》2006,85(2):76-83

In vivo and in vitro metabolism of pyraclofos labeled with ¹⁴C on benzene ring was studied in the pyraclofos-resistant and -susceptible female houseflies. In vivo metabolism studies, the metabolic rate of pyraclofos was the same in both strains. Pyraclofos primarily undergoes metabolic detoxification by cleavage of P-S-alkyl bond, and cleavage of the P-O-aryl bond followed by CHP [1-(4-chlorophenyl)-4-hydroxypyrazole]]-glucose conjugation. Cleavage of P-O-aryl bond and CHP-glucose conjugation is more predominant in the resistant strain whereas the cleavage of P-S-propyl bond resulting in EHP-CHP [O-1-(4-chlorophenyl)pyrazol-4-yl ethyl hydrogen phosphate] is more preferred in the susceptible strain. CHP production by P-O-aryl bond cleavage was controlled by P450 monooxygenase and esterase. UDP-glucosyltransferase appeared to play an important role in the pyraclofos metabolism of the resistant strain. Production of CHP-glucose conjugate was largely reduced by piperonyl butoxide and S,S,S-tributylphosphorotrithioate in both strains. EHP-CHP production seemed to be controlled by P450 monooxygenase and stimulated by UDP-glucose.  相似文献   

Metabolism of O,O,S-trimethyl phosphorothioate in rats after oral administration of a toxic dose,and the effect of coadministration of its antagonistic thionate isomer     

A.J. Gray  T.R. Fukuto 《Pesticide biochemistry and physiology》1984,22(3):295-311

The in vivo metabolism of [¹⁴CH₃S]- and [¹⁴CH₃O]O,O,S-trimethyl phosphorothioate (OOS) was followed in rats after oral administration of threshold or LD₅₀ toxic doses of 20 or 60 mg/kg. Similar metabolic studies were conducted with coadministration of 1% O,O,O-trimethyl phosphorothionate (OOO), which prevented all signs of delayed toxicity, including weight loss. When administered alone, OOS was metabolized mainly (50–60%) via removal of the CH₃S moiety, which was largely converted to expired CO₂. Approximately 20% of the compound was O-demethylated, presumably by conjugation with glutathione, and then further metabolized to CO₂. Major urinary products were identified as O,O-dimethyl phosphoric acid (50–60%) and O,S-dimethyl phosphorothioic acid (～20%). Coadministration of OOO caused a slight decrease (～5%) in the cleavage of the CH₃S moiety, indicated by a reduction in ¹⁴CO₂ from [¹⁴CH₃S]OOS and a quantitatively similar increase in the formation of O,S-dimethyl phosphoric acid. Limited pharmacokinetic studies indicated that OOS was rapidly absorbed and distributed throughout the body. Coadministration of 1% OOO caused a slight increase in the blood half-life of parent OOS when administered at 60 mg/kg. It was concluded that a small proportion of the cleavage of the CH₃S moiety from OOS is involved in the intoxication process, and that this intoxication reaction is specifically inhibited by OOO.  相似文献   

Differential metabolism of sulfoximine and neonicotinoid insecticides by Drosophila melanogaster monooxygenase CYP6G1     

Thomas C. Sparks  Gerrit J. DeBoerNick X. Wang  James M. HaslerMichael R. Loso  Gerald B. Watson 《Pesticide biochemistry and physiology》2012,103(3):159-165

Sulfoxaflor [N-[methyloxido[1-[6-(trifluoromethyl)-3-pyridinyl]ethyl]-λ⁴-sulfanylidene] cyanamide] is in development as the first product from the new sulfoximine class of insect control agents. Highly effective against a variety of sap-feeding pest insects, available data indicate no cross-resistance to sulfoxaflor in pest insect strains that exhibit high levels of resistance to neonicotinoids and other insecticides. In vitro studies of the cytochrome P450 monooxygenase CYP6G1 from Drosophila melanogaster, expressed in a Drosophila cell line, show very high levels of metabolism for a variety of neonicotinoids, but not for sulfoxaflor and its chloropyridine-analog. A sulfoxaflor analog with nitrogen in place of the carbon in the bridge between the pyridine and sulfoximine moiety shows a modest degree of metabolism. In silico homology modeling of the CYP6G1 with the sulfoximines and neonicotinoids suggests that steric effects may limit interactions of the sulfoximines with the reactive heme-oxo complex. A distinct relationship was identified for the summed Hückel charges and the degree of metabolism observed. These observations help explain the lack of sulfoxaflor metabolism by CYP6G1, and in turn provide a basis for the lack of cross-resistance to sulfoxaflor in insecticide resistant strains of pest insects.  相似文献   

Biotransformation of dimethoate by cell culture systems     

H.H. North  R.E. Menzer 《Pesticide biochemistry and physiology》1972

Dimethoate [O,O-dimethyl S-(N-methylcarbamoylmethyl) phosphorodithioate] was oxidatively metabolized by primary human embryonic lung cells in culture. Over 95% of the recovered radioactivity after incubation with ¹⁴C-labeled dimethoate resulted from oxidative metabolites, with the remainder being water soluble. Thus, oxidative metabolism of dimethoate predominated over hydrolytic metabolism in the cell culture system, in contrast to the whole rat where the opposite is true. The sequence of reactions was similar to that found in rats. Dimethoate was desulfurated to yield dimethoxon and both compounds were N-demethylated. Metabolism of dimethoate in mouse fibroblast L-929 cell cultures revealed up to 35% of dimethoate carboxylic acid as the only compound other than dimethoate present.  相似文献   

Toxicity and metabolism of methomyl in the European corn borer     

R.J. Kuhr  C.W. Hessney 《Pesticide biochemistry and physiology》1977,7(4):301-308

The contact and oral toxicity of methomyl (S-methyl N-[(methylcarbamoyl)oxy] thioacetimidate) was similar for two different strains of European corn borer, Ostrinia nubilalis (Hübner). In each case, third- and fourth-instar larvae were equally susceptible, but fifth-instar insects were considerably more difficult to kill. In vivo and in vitro studies revealed that borers from both strains metabolized methomyl via a mixed-function oxidase system to water-soluble products which could not be cleaved by acid or hydrolytic enzymes. By far, the greatest metabolic activity was localized in fat body tissues of last-instar larvae, and although both strains metabolized methomyl at a similar rate, a large difference was found in the rate of metabolism of methomyl oxime.  相似文献   

Comparative metabolism of atrazine and EPTC in proso millet (Panicum miliaceum L.) and corn     

G. Ezra  G.R. Stephenson 《Pesticide biochemistry and physiology》1985,24(2):207-212

The purpose of this study was to examine the differential activities of proso millet (Panicum miliaceum L.) and corn (Zea mays L.) with respect to atrazine [2-chloro-4-(ethylamino)-6-(isopropylamino)-S-triazine] and EPTC (S-ethyldipropyl thiocarbamate) metabolism. GSH-S-transferase was isolated from proso millet shoots and roots. When assayed spectrophotometrically using CDNB (1-chloro 2,4-dinitrobenzene) as a substrate, the shoot enzyme had only 10% of the activity of corn shoot enzyme while the root enzyme had 33% the activity of corn root enzyme. However, when proso millet shoot GSH-S-transferase was assayed in vitro using ¹⁴C-ring-labeled atrazine, it degraded the atrazine to water-soluble products at the same rate as the corn shoot enzyme. Incubation of excised proso millet and corn roots with [¹⁴C]EPTC indicated that uptake of EPTC was similar in both plants. However, proso millet metabolized the EPTC to water-soluble products at only half the rate of corn. Glutathione levels of proso millet roots were 35.9 μg GSH/g fresh wt, compared with 65.4 μg GSH/g fresh wt for corn. However, a 2.5-day pretreatment with R-25788 (N,N-diallyl-2-2-dichloroacetamide) elevated proso millet GSH levels to 62.7 μg GSH/g fresh wt. R-25788 did not elevate the activity of proso millet GSH-S-transferase, in contrast to its effects on corn. We conclude that differences in response to atrazine and EPTC in proso millet and corn are a result of their differential metabolism.  相似文献   

Mechanisms of resistance to diflubenzuron in the house fly, Musca domestica (L.)     

Gajanan D. Pimprikar  George P. Georghiou 《Pesticide biochemistry and physiology》1979,12(1):10-22

The mechanisms of resistance to the chitin synthesis inhibitor diflubenzuron were investigated in a diflubenzuron-selected strain of the house fly (Musca domestica L.) with > 1000 × resistance, and in an OMS-12-selected strain [O-ethyl O-(2,4-dichlorophenyl)phosphoramidothioate] with 380 × resistance to diflubenzuron. In agreement with the accepted mode of action of diflubenzuron, chitin synthesis was reduced less in larvae of the resistant (R) than of a susceptible (S) strain. Cuticular penetration of diflubenzuron into larvae of the R strains was about half that of the S. Both piperonyl butoxide and sesamex synergized diflubenzuron markedly in the R strains, indicating that mixed-function oxidase enzymes play a major role in resistance. Limited synergism by DEF (S,S,S-tributyl phosphorotrithioate) and diethylmaleate indicated that esterases and glutathione-dependent transferases play a relatively small role in resistance. Larvae of the S and R strains exhibited a similar pattern of in vivo cleavage of ³H- and ¹⁴C-labeled diflubenzuron at N₁C₂ and N₁C₁ bonds. However, there were marked differences in the amounts of major metabolites produced: R larvae metabolized diflubenzuron at considerably higher rates, resulting in 18-fold lower accumulation of unmetabolized diflubenzuron by comparison with S larvae. Polar metabolites were excreted at a 2-fold higher rate by R larvae. The high levels of resistance to diflubenzuron in R-Diflubenzuron and R-OMS-12 larvae are due to the combined effect of reduced cuticular penetration, increased metabolism, and rapid excretion of the chemical.  相似文献   

Reductive and oxidative metabolism of triazolylmethanes by two basidiomycete fungi     

A.H.B. Deas  D.R. Clifford 《Pesticide biochemistry and physiology》1984,22(3):276-284

The metabolism of [¹⁴C]triadimefon, triadimenol, diclobutrazol, and the oxo-analogue of diclobutrazol by the basidiomycete fungi Coriolus versicolor and Rhizoctonia solani was studied. Reduction of >C = 0 to >CHOH (activation) was more important for triadimefon than oxo-diclobutrazol. Conversely, oxidation of >CHOH to >C = 0 (deactivation) occurred to a greater extent with diclobutrazol than triadimenol. Formation of primary alcohol metabolites, a possible detoxication route, occurred more with diclobutrazol and its oxo-analogue than with triadimefon and triadimenol. The implications of the reduction/oxidation processes and primary alcohol formation on fungitoxicity of the applied triazolymethane are discussed. The enantiomeric composition of metabolically produced triadimenol is discussed in relation to the in vitro activity of triadimefon supplied against each fungus.  相似文献   

In vitro metabolism of pentachloronitrobenzene to pentachloromethylthiobenzene by onion: Characterization of glutathione S-transferase,cysteine C-S lyase,and S-adenosylmethionine methyl transferase activities     

Gerald L. Lamoureux  Donald G. Rusness 《Pesticide biochemistry and physiology》1980,14(1):50-61

Pentachloromethylthiobenzene (PCTA) was synthesized in vitro from pentachloronitrobenzene (PCNB) at pH 7.9 by an enzyme system from onion root that required dithiothreitol, glutathione, and S-adenosylmethionine. The soluble enzyme system was isolated from onion root by ammonium sulfate fractionation and differential centrifugation. The system contained glutathione S-transferase activity with PCNB, C-S lyase activity with S-(pentachlorophenyl)cysteine, S-adenosylmethionine methyl transferase activity with pentachlorothiophenol (PCTP), and presumably several peptidase activities. All activities were stable when the crude enzyme system was stored at ?25°C. Evidence for the following sequence of reactions in PCTA synthesis was presented: PCNB→¹S-(pentachlorophenyl)glutathione→²S-(pentachlorophenyl)-γ-glutamylcysteine→³S-(pentachlorophenyl)cysteine→⁴ PCTP→⁵ PCTA. The first reaction was studied with [¹⁴C]PCNB. Reactions 2–4 were studied with S-([¹⁴C]pentachlorophenyl)glutathione, S-([¹⁴C]pentachlorophenyl)cysteine, and peptide inhibitors. Reaction 5 was studied with [¹⁴C]PCTP, S-[¹⁴C]adenosylmethionine, and inhibitors. The possible use of the enzyme system in the characterization of other glutathione conjugates was discussed.  相似文献   

Metabolism of fenitrothion by organophosphorus-resistant and -susceptible house flies, Musca domestica L     

Masashi Ugaki  Toshio Shono  Jun-ichi Fukami 《Pesticide biochemistry and physiology》1985,23(1):33-40

The metabolism of fenitrothion was investigated in highly resistant (Akita-f) and susceptible (SRS) strains of the house fly, Musca domestica L. The Akita-f strain was 3500 times more resistant to fenitrothion than the SRS strain. Fenitrothion, topically applied to the flies, was metabolized in vivo far faster in the Akita-f strain than in the SRS strain. In vitro studies revealed that fenitrothion was metabolized by a cytochrome P-450-dependent monooxygenase system and glutathione S-transferases. The former oxidase system metabolized fenitrothion in vitro into fenitrooxon and 3-methyl-4-nitrophenol as major metabolites, and into 3-hydroxymethyl-fenitrothion and 3-hydroxymethyl-fenitrooxon as minor metabolites. Glutathione S-transferases metabolized fenitrothion into desmethylfenitrothion. The cytochrome P-450-dependent monooxygenase system and glutathione S-transferases of the resistant Akita-f strain had 1.4 to 2.2 times and 9.7 times, respectively, as great activities as those of the susceptible SRS strain. These results suggest the importance of glutathione S-transferases in fenitrothion resistance in the Akita-f strain.  相似文献   

Studies on residues and the metabolic pathway of methidathion in tomato fruit     

Harishchandra M. Chopade  Walter C. Dauterman  Bruce J. Simoneaux 《Pest management science》1981,12(1):17-26

The residues and metabolism of methidathion [S-(2, 3-dihydro-5-methoxy-2-oxo-1, 3, 4-thiadiazol-3-ylmethyl) O, O-dimethyl phosphorodithioate] and its secondary metabolites: demethyl-methidathion [S-(2, 3-dihydro-5-methoxy-2-oxo-1, 3, 4-thiadiazol-3-ylmethyl) O-methyl O-hydrogen phosphorodithioate] ( IV ), the sulphide (2,3-dihydro-5-methoxy-3-methylthiomethyl-1,3,4-thiadiazol-2-one) ( I ), tsulphoxide(2,3-dihydro-5-methoxy-3- methylsulphinylmethyl-1,3,4-thiadiazol-2-one) ( II ) and the sulphone (2,3-dihydro-5-methoxy-3-methylsulphonylmethyl-1,3,4-thiadiazol-2-one ( III ) were studied in laboratory-treated tomato fruit. The metabolites and residues of methidathion were determined for the applied doses of 1, 7 and 14 mg of methidathion kg^?1 of fruit. Methidathion was metabolised extensively over a 14-day period. The amount of metabolites formed was a function of both the applied dose as well as the time after application. Major water-soluble metabolites were found to be IV and the cysteine conjugate S-(2,3-dihydro-5-methoxy-2-oxo-1,3,4-thiadiazol-3-ylmethyl)-L-cysteine ( VI ). The chloroform-soluble metabolites were identified as the oxygen analogue of methidathion [S-(2,3-dihydro-5-methoxy-2-oxo-1,3,4-thiadiazol-3-ylmethyl) O, O-dimethyl phosphorothioate] ( V ), the sulphoxide II , and the hydroxy compound 2,3-dihydro-3-hydroxymethyl-5-methoxy-1,3,4-thiadiazol-2-one. The oxygen analogue of methidathion ( V ) was found in small amounts, corresponding to <5% of the added methidathion. Demethyl-methidathion ( IV ) appeared to be a precursor in the formation of the cysteine conjugate VI . The sulphide I seemed to be more reactive in forming the cysteine conjugate than the sulphoxide II or the sulphone III .  相似文献   

Accumulation pattern and insecticidal effect of aldicarb in cotton following soil treatment for the control of the tobacco whitefly (Bemisia tabaci)     

N. Aharonson  Lea Muszkat  I. Neubauer 《Phytoparasitica》1984,12(2):127-134

The accumulation pattern of the pesticide aldicarb [2-methyl-2-(methylthio) propionaldehyde O-(methylcarbamoyl)-oxime] and of its sulfoxide and sulfone metabolites was studied in field-grown cotton, following soil treatments at various intervals from planting. Control of the tobacco whitefly(Bemisia tabaci) was determined and correlated with the concentration of aldicarb and of its metabolites in cotton leaves. The main constituent found in the leaves was aldicarb sulfoxide, which reached its maximum concentration there at about 22 days post-treatment. Late application of the insecticide (mid-July) resulted in higher concentrations toward the end of the growing season and so gave improved control of the pest. Results are presented for residues in young and mature leaves and in the seeds.  相似文献   

The biochemical basis of malathion resistance in the sheep blowfly,Lucilia cuprina     

《Pesticide biochemistry and physiology》1986,26(3):302-309

The in vivo and in vitro metabolism of [¹⁴C]malathion was studied in susceptible (LS) and malathion resistant (RM) strains of the sheep blowfly, Lucilia cuprina (Wiedemann). No difference was found between strains in the penetration, excretion, storage, or inhibitory potency of the insecticide. However, RM degraded malathion to its α- and β-monocarboxylic acid metabolites more rapidly than LS, both in vivo and in vitro. This enhanced degradation of [¹⁴C]malathion occurred in vitro in both mitochondrial and microsomal fractions of resistant flies. Kinetic analysis revealed that these fractions degraded malathion by discrete mechanisms. The enzymes from the mitochondria of both strains had the same K_m, whereas the microsomal enzyme from the RM strain had a fivefold higher K_m than that from the LS strain. Studies of esterase activities and the effect of enzyme inhibitors showed that both the mitochondrial and microsomal resistance mechanisms were the result of enhanced carboxylesterase activity. It was concluded that increased carboxylesterase detoxification of malathion adequately explained the high level of malathion resistance in RM if rate-limiting factors such as cuticular penetration were taken into account.  相似文献   

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

P.B. Hughes  A.L. Devonshire 《Pesticide biochemistry and physiology》1982,18(3):289-297

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.  相似文献   

Absence of enhanced detoxication of permethrin in pyrethroid-resistant house flies     

Donald H. DeVries  George P. Georghiou 《Pesticide biochemistry and physiology》1981,15(3):242-252

The mechanisms of resistance to pyrethroids were studied in a permethrin-selected (147-R) strain of the house fly, Musca domestica L. Approximately 12-fold synergism was obtained with a mixture of (1R)-trans-permethrin:piperonyl butoxide (1:5) so that the resistance decreased from 97-fold to 22-fold. Tests with the esterase inhibitor S,S,S-tributyl phosphorotrithioate produced very little synergism in either the resistant (R) strain (1.6-fold) or the susceptible (S) strain (1.9-fold). An investigation of the microsomal components revealed that compared to the S strain, the R strain demonstrated twice as much cytochrome P-450 and cytochrome b₅ and double the rate of NADPH-cytochrome c reductase activity. In addition, the rate of p-nitroanisole O-demethylation was found to be six times greater in the R strain. An in vivo accumulation study showed that the R strain displayed a decreased rate of penetration of trans-[¹⁴C]permethrin. When treated at equitoxic doses the R strain was found to tolerate 50-fold more internal permethrin than the S strain. An in vitro metabolism study indicated that there was no difference between strains in the overall rate of metabolism of trans-[¹⁴C]permethrin. The evidence obtained supports the conclusion that several resistance factors are involved but that decreased sensitivity of the nervous system to the action of pyrethroids is the principal mechanism of resistance in the 147-R strain.  相似文献