Metabolism of cisanilide (cis-2,5-dimethyl-1-pyrrolidinecarboxanilide) by excised leaves and cell suspension cultures of carrot and cotton

Major methanol-soluble metabolites of cisanilide (cis-2,5-dimethyl-1-pyrrolidinecarboxanilide) were isolated from excised, pulse-treated carrot and cotton leaves. They were identified as O-glucoside conjugates of primary aryl and alkyl oxidation products, 2,5-dimethyl-1-pyrrolidine-4-hydroxycarboxanilide and 2,5-dimethyl-3-hydroxy-1-pyrrolidinecarboxanilide. Comparative studies with carrot and cotton cell cultures showed similar initial pathways of cisanilide metabolism. Time-course studies with [¹⁴C-pyrrolidine]- and [¹⁴C-phenyl]cisanilide showed little, if any, cleavage of the herbicide molecule in either excised leaves or cell cultures. Quantitative differences in the metabolism of cisanilide by cell cultures and excised leaves included; a reduced capacity of cell cultures to form secondary glycoside conjugates and an increased ability of cell cultures to form methanol-insoluble residues.     

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.     

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.     

Herbicide perfluidone (1,1,1-trifluoro-N-[2-methyl-4-(phenylsulfonyl)phenyl]methanesulfonamide): Its metabolism in rats and chickens

Rats and chickens were each given a single oral dose (10 or 100 mg/kg body wt) of 1,1,1-trifluoro-N-[2-methyl-4-(phenylsulfonyl)phenyl-¹⁴C(U)]methanesulfonamide ([¹⁴C]perfluidone). Depending on the size of the dose, from 8.4 to 36.2% of the [¹⁴C] was eliminated in the urine and from 36.4 to 85.4% was eliminated in the feces within 48 hr after dosing. Less than 1% of the [¹⁴C] given to laying hens as [¹⁴C]perfluidone was present in the eggs produced during the first 96 hr after dosing. The percentage of the administered [¹⁴C] that remained in these animals (body with G.I. tract and contents removed) varied from 0.34 (96 hr after dosing) to 1.68% (48 hr after dosing). ¹⁴C-labeled compunds in the urine and feces from the rats and chickens were purified by solvent extraction, column chromatography, and gas-liquid chromatography, and then identified by infrared and mass spectrometry. The parent compound was the major ¹⁴C-labeled component in the urine and feces of both animals. 1,1,1-Trifluoro-N-[2-methyl-4-(3-hydroxyphenylsulfonyl)phenyl]methanesulfonamide was present in the feces of both animals. The proposed structures of other metabolites were 1,1,1-trifluoro-N-hydroxy-N-[2-methyl-4-(phenylsulfonyl)phenyl]methanesulfonamide (rat urine) and 1,1,1-trifluoro-N-{2-methyl-4-[(methylsulfonyl)-phenylsulfonyl]phenyl}methanesulfonamide (chicken urine).     

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.     

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.     

The metabolism of the nonionic surfactant 14C-labeled α[p-1,1,3,3-tetramethylbutyl)phenyl]-ω-hydroxyhexa(oxyethylene) in the goat

A goat given a single dose of ¹⁴C-labeled α-[p-(1,1,3,3-tetramethylbutyl)phenyl]-ω-hydroxyhexa(oxyethylene) ([¹⁴C]TOP-6EOH) eliminated 18% of the ¹⁴C in the urine and 77% in the feces within 96 hr after dosing. Another goat (surgically modified for total bile collection) given a single dose of [¹⁴C]TOP-6EOH eliminated 81% of the ¹⁴C in the bile, 17% in the urine, and only 6% in the feces. When ¹⁴C-bile from the animal in the second study was perfused into the small intestine of a third goat, 72% of the ¹⁴C was eliminated in the feces, 20% in the bile, and 6% in the urine within 96 hr. Eighteen different types of metabolites accounting for most of the ¹⁴C in the bile and urine were isolated, derivatized, and then characterized by mass spectral analysis. The [¹⁴C]TOP-6EOH was metabolized by: (i) oxidation of the alkyl group to give alcohols and acids, (ii) oxidation of the terminal ethylene oxide moiety to an acid, (iii) cleavage of the polyoxyethylene side chain, (iv) combinations of i–iii, and (v) conjugation of the products of i–iv.     

Comparative metabolism of six ethoxychlor analogs and DDT in DDT-resistant and susceptible strains of the house fly Musca domestica L

The metabolic fate of six ³H-ring-substituted ethoxychlor analogs with altered aliphatic moieties and [¹⁴C]p,p′-DDT was investigated in susceptible and DDT-resistant strains of the house fly Musca domestica Linnaeus. The chloroalkane analogs, dichloroethane, chloropropane, and dichloropropane were primarily metabolized to the corresponding dehydrochlorinated products. This pathway was relatively more prominent in the resistant strain than in the susceptible strain. Biotransformation and detoxication of the isobutane, nitropropane, and neopentane derivatives was through microsomal oxidation (O-deethylation) of aryl ethoxy degradophores, and oxidation of the aliphatic moieties to produce the corresponding benzophenones, with no substantial differences between the resistant and susceptible strain. There was a strong correlation between the Taft ($\text{σ}{}^1$) values for the altered aliphatic moieties of chloroalkane analogs and their rate of dehydrochlorination in both the strains. These results suggest the importance of altered aliphatic moieties in developing resistance-proof DDT derivatives.     

The metabolism of chlorotoluron in the rat

The metabolic fate of ¹⁴C-labeled chlorotoluron, i.e., 1-(3-chloro-4-methyl[⁴C]-phenyl)-3,3-dimethyl urea, was followed in rats. After a single oral dose the radioactivity was preferably excreted with the urine. Nine of the eleven urinary metabolites isolated, were identified by spectroscopic and derivatization techniques, whereas the structure of the remaining two metabolites was only partially elucidated. N-Demethylation and stepwise oxidation of the ring methyl group to hydroxymethyl and carboxyl derivatives were found as the major metabolic mechanisms. Both mechanisms proceeded simultaneously so that the isolated metabolites showed all combinations of N-demethylation and ring methyl group oxidation in their structures. One of these metabolites was an N-formyl derivative, being probably an intermediate product of demethylation. In the urine of rats fed doses of [¹⁴C]chlorotoluron higher than 50 mg/kg three additional metabolites with different degrees of N-dealkylation were found, the ring methyl group of which was transformed to a methylthio methyl group. The metabolites identified in the faeces were of the same type as those found in the urine. Based on the structures of the metabolites elucidated, a metabolic pathway of chlorotoluron in the rat is presented.     

Alfalfa metabolism of propham

Root-treated alfalfa absorbs, translocates, and metabolizes [phenyl-¹⁴C]isopropyl carbanilate ([¹⁴C]propham). After 7 days of root treatment, the distribution of radiolabel was 73% for shoots and 27% for roots. Shoots and roots were extracted and separated into the polar, nonpolar, and solid residual components using a mixture of chloroform, methanol and water. The insoluble residues accounted for approximately 40% of the ¹⁴C found in shoots and roots. The nonpolar fraction (6.1% of the radiolabel in shoots and roots) was not characterized, but was shown to be some component other than parent propham. Propham was not found in either shoots or roots. The polar metabolites were partly purified on Amberlite XAD-2. Cellulase-liberated aglycones were derivatized and separated by high-performance liquid and gas-liquid chromatography. The infrared, nuclear magnetic resonance, and mass spectral data showed that the polar metabolites of alfalfa shoots and roots were glycoside conjugates of isopropyl 2-hydroxycarbanilate (2-hydroxypropham) and isopropyl 4-hydroxycarbanilate (4-hydroxypropham). Conjugated 4-hydroxypropham accounted for 45.9% of the ¹⁴C in the shoots and 3.4% of the ¹⁴C in the roots. Conjugated 2-hydroxypropham accounted for 3.4% of the ¹⁴C in the shoots and 1.4% of the ¹⁴C in the roots.     

Localizing the action of two thiadiazolyl herbicidal derivatives

Enzymatically isolated leaf cells from navy beans (Phaseolus vulgaris L., cv. “Tuscola”) were used to study the effect of buthidazole (3-[5-(1,1-dimethylethyl)-1,3,4-thiadiazol-2-yl]-4-hydroxy-1-methyl-2-imidazolidinone) and tebuthiuron (N-[5-(1,1-dimethylethyl)-1,3,4-thiadiazol-2-yl]-N,N′-dimethylurea) on photosynthesis, protein, ribonucleic acid (RNA), and lipid synthesis. The incorporation of NaH¹⁴CO₃, [¹⁴C]leucine, [¹⁴C]uracil, and [¹⁴C]acetic acid as substrates for the respective metabolic process was measured. Time-course and concentration studies included incubation periods of 30, 60, and 120 min and concentrations of 0.1, 1, 10, and 100 μM of both herbicides. Photosynthesis was very sensitive to both buthidazole and tebuthiuron and was inhibited in 30 min by 0.1 μM concentrations. RNA and lipid syntheses were inhibited 50 and 87%, respectively, by buthidazole and 42 and 64%, respectively, by tebuthiuron after 120 min at 100 μM concentration. Protein synthesis was not affected by any herbicide at any concentration or any exposure time period. The inhibitory effects of buthidazole and tebuthiuron on RNA and lipid syntheses may be involved in the ultimate herbicidal action of these herbicidal chemicals.     

Metabolism of dibutyl-14C-labeled dibutylaminosulfenyl derivative of carbofuran in the cotton plant

The fate of the di-n-butylaminosulfenyl moiety in 2,3-dihydro-2,2-dimethyl-7-benzofuranyl (di-n-butylaminosulfenyl)(methyl)carbamate (DBSC or Marshal) was studied in the cotton plant at 1, 3, 6, and 10 days following foliage treatment with [di-n-butylamino-¹⁴C]DBSC. Dibutylamine and two major radioactive metabolites were obtained following extraction of the plant tissue with a methanol-buffer containing N-ethylmaleimide (NEM), a sulfhydryl scavenger which was added to prevent the cleavage of the NS bond during the workup procedure. The most adundant radioactive material recovered from plants was identified as a product arising from the reaction between NEM and dibutylamine. Extraction of plant tissue with straight methanol-buffer solution or with methol-buffer containing other sulfhydryl scavengers resulted in 57–86% of the applied radioactivity being recovered as dibutylamine in the organosoluble fraction. When [¹⁴C]dibutylamine was applied to cotton leaves, most of the radioactivity, i.e., 96% of the total recovered radioactivity, was found in the organosoluble fraction as dibutylamine. Dibutylamine is the major metabolite of [di-n-butylamino-¹⁴C]DBSC in the cotton plant.     

Alternate pathways of metribuzin metabolism in soybean: Formation of N-glucoside and homoglutathione conjugates

Metribuzin [4-amino-6-tert-butyl-3(methylthio)-1,2,4-triazin-5(4H)-one] metabolism was studied in soybean [Glycine max (L.) Merr. Tracy]. Pulse treatment studies with seedlings and excised mature leaves showed that [5-¹⁴C]metribuzin was absorbed rapidly and translocated acropetally. In seedlings, >97% of the root-absorbed ¹⁴C was present in foliar tissues after 24 hr. In excised leaves, 50–60% of the absorbed ¹⁴C remained as metribuzin 48 hr after pulse treatment, 12–20% was present as polar metabolites, and 20–30% was present as an insoluble residue. Metabolites were isolated by solvent partitioning, and were purified by adsorption, ion-exchange, thin-layer, and high-performance liquid chromatography. The major metabolite (I) was identified as a homoglutathione conjugate, 4-amino-6-tert-butyl-3-S-(γ-glutamyl-cysteinyl-β-alanine)-1,2,4-triazin-5(4H)-one. Metabolite identification was confirmed by qualitative analysis of amino acid hydrolysis products, fast atom bombardment (FAB), and chemical ionization (CI) mass spectrometry, and by comparison with a reference glutathione conjugate synthesized in vitro with a hepatic microsomal oxidase system from rat. Minor metabolites were identified as an intermediate N-glucoside conjugate (II), a malonyl N-glucoside conjugate (III), and 4-malonylamido-6-tert-butyl-1,2,4-triazin-3,5(2H,4H)-dione (N-malonyl DK, IV) by CI and FAB mass spectrometry. Alternative pathways of metribuzin metabolism are proposed.     

Metabolism of bromoxynil octanoate in growing wheat

[¹⁴C]ring-Bromoxynil octanoate was applied to the leaves of wheat seedlings, which were cultivated in a growth cabinet under controlled conditions for 14 days. Fractionation of the metabolites present in the treated leaves, which accounted for about 63% of the radioactivity applied, indicated a complex metabolic pathway resulting from initial hydrolysis to free bromoxynil, followed by three consecutive or concurrent steps (a) hydrolysis of the cyano group to the amide and carboxylic acid, followed by decarboxylation to 2,6-dibromophenol (0.5% of the ¹⁴C applied), (b) replacement of one or both bromine atoms by hydroxy groups to 3-bromo-4,5-dihydroxybenzonitrile (1.3 %) and 3,4,5-trihydroxybenzo-nitrile (0.6 %) or their hydrolysis products, (c) replacement of one or both bromine atoms by hydrogen, giving 3-bromo-4-hydroxybenzonitrile (1.9 %) and 4-hydroxy-benzonitrile (0.6%) or their hydrolysis products. Some of the phenolic acids or phenols formed are natural plant constituents. The metabolites identified represented in all about 11 % of the herbicide applied, but no individual metabolite accounted for more than a small proportion of it.     

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

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.     

Mercapturic acid formation in the metabolism of propachlor,CDAA, and fluorodifen in the rat

When [¹⁴C]F₃-fluorodifen (2,4′-dinitro-4-trifluoromethyl diphenylether), carbonyl-[¹⁴C]CDAA (N,N-diallyl-2-chloroacetamide), and carbonyl-¹⁴C-propachlor (2-chloro-N-isopropylacetanilide) were fed to rats, 57 to 86% of the ¹⁴C was excreted via the urine within 48 hr. Although very little radioactivity was excreted in the feces of CDAA-treated rats, 15–22% of the ¹⁴C was excreted in the feces of propachlor- of fluorodifentreated rats and an average of 8% of the ¹⁴C remained in these rats 48 hr after treatment. Oxidation of the ¹⁴C label to [¹⁴C]O₂ was not a major process in the metabolism of these herbicides. The only major radioactive metabolite present in the 24-h urine of fluorodifen-treated rats, 2-nitro-4-trifluoromethylphenyl mercapturic acid, accounted for 41% of the administered dose of ¹⁴C. In the metabolism of CDAA, the corresponding mercapturic acid accounted for 76% of the dose; it was the only major metabolite present in the 24-h urine. In contrast, three major metabolites were detected in the 24-h urine of propachlortreated rats, and the mercapturic acid accounted for only 20% of the dose. The mercapturic acid of each herbicide was identified by mass spectrometry.     

Degradation of fluometuron by Rhizoctonia solani

Degradation studies of fluometuron [Cotoran, 1,1-dimethyl-3-(α,α,α-trifluoro-m-tolyl)urea] by Rhizoctonia solani have been conducted to elucidate further the pathway of degradation. Analysis by thin-layer chromatography and autoradiography demonstrated that R. solani degraded 88% of fluometuron (¹⁴CF_3^?) into seven nonpolar metabolites after 35 days of incubation. Trace amounts of polar, water-soluble products were detected, but no ¹⁴CO₂ or radioactive volatile products were detected. Two of the major metabolites were identified by thin-layer chromatography and ultraviolet spectroscopy as 1-methyl-3-(α,α,α-trifluorotolyl)urea and (3-trifluoromethylphenyl)urea, which indicated a stepwise demethylation of fluometuron. The remaining five metabolites have not been identified and have not been previously reported in the literature. Time course experiments and metabolite degradative studies indicated that the sequence of degradation involved a multibranched pathway which did not include CO₂ evolution. The proposed pathway does not include the conversion of fluometuron to the aniline derivative as has been reported for other urea herbicides. All of the data from this study indicate the incomplete degradation of fluometuron which suggests a cometabolic degradative pathway.     

Biotransformations of photoheptachlor in the rat: II. Analysis and origin of major metabolites

The metabolites isolated and purified from the excreta of the rats treated with [¹⁴C]photoheptachlor were analyzed by gc-mass spectrometry. Molecular structure of two of the major metabolites indicated that they were produced by hydroxylations at two different CCl bonds of photoheptachlor. One of these metabolites was conjugated with glucuronic acid, the other with an unknown compound. Hepatic origin of the products was shown by concordance of the in vitro and in vivo study. Most of the radioactivity in fat, skin, liver, kidney, and muscle tissues of male and female rats was organosoluble containing photoheptachlor and its nonpolar metabolites.     

Metribuzin metabolism as the basis for tolerance in barley (Hordeum vulgare L.)*

Metabolism of ¹⁴C-5 (ring)-metribuzin was studied in Steptoe (tolerant) and Morex (susceptible) barley (Hordeum vulgare L.) cultivars, 1, 4, and 8 days following a single application to roots. Both cultivars contained similar ether-soluble metribuzin metabolites and five water-soluble metabolites. Water-soluble compounds increased from 12 to 53% of the total ¹⁴C recovered for Steptoe and 5–17% for Morex between 1 day and 8 days, respectively, whereas the percentage of ether-soluble metabolites decreased. Ninhydrin reacting compounds were the major water-soluble metabolites in the leaf blades 8 days after treatment. On a d.p.m. mg^?1 dry weight basis, Steptoe leaves had five times more water-soluble material than Morex leaves and half the quantity of ether-soluble compounds. Metribuzin comprised 83 and 89% of the ether-soluble compounds in leaves of Morex and Steptoe, respectively, at 8 days. Terminal radioactivity comprised between 19% and 26% of total radioactivity for both cultivars as early as 1 day after application, with little change over 8 days. Rapid metabolism of metribuzin to non-phytotoxic water-soluble conjugates and terminal residues was the major mechanism responsible for the differential tolerance between these two barley cultivars.     

Role of a microsomal carboxylesterase in reducing the action of malathion in eggs of Triatoma infestans

A microsomal malathion carboxylesterase present in Triatoma infestans eggs was active from the first day of embryonic development. This microsomal egg malathionase (MEM) showed a unique band in polyacrilamide gel electrophoresis (PAGE) when malathion was used as substrate. In vivo metabolism of [¹⁴C]malathion during all embryonic development showed a 10% degradation due to carboxylesterases. The in vitro evaluation of the same metabolic pathway catalyzed by the microsomal fraction of T. infestans eggs showed partial inhibition by paraoxon. α- and β-malathion monoacids were identified as the main metabolites of the in vivo and in vitro metabolic pathways. The carboxylesterase band that appeared in PAGE (MEM) from the first day of embryonic development could be the main cause of malathion tolerance in T. infestans eggs.