Characterization of the hepatic mixed function oxidase system in endrin-resistant and -susceptible pine voles

Studies were conducted to assess the contribution of the hepatic microsomal mixed function oxidase system to a 7.2-fold difference in susceptibility to the lethal effects of endrin between endrin-resistant and -susceptible pine voles, Microtus pinetorum. Evaluations of microsomal enzyme systems were conducted for basal and endrin-treated pine voles of both strains. The microsomal activity of ICR white mice was investigated to provide a species comparison. Maximal microsomal mixed function oxidase activities were determined in in vitro incubations for the model substrates ethylmorphine, aniline, and benzo(a)pyrene. V_max values were estimated for the rate of disappearance of benzo(a)pyrene in in vitro incubations. No significant strain differences in basal microsomal enzyme activity were found for the model substrates investigated, although activity was invariably higher in the resistant strain. The concentration of cytochrome P-450 was significantly higher in the resistant vole though actually less than 20% different. The occurrence of significant strain differences in the levels of microsomal enzyme activity induced by endrin were rare. Significant endrin treatment effects on the levels of microsomal enzyme activity for the pine vole were observed but the degree and direction of change depended on the substrate used. A marked species difference in microsomal mixed function oxidase activity was noted between pine voles and white mice. This was particularly evident for endrin-treated animals. The microsomal activity of endrin-treated white mice was greatly induced relative to basal levels. The degree of induction depended on the substrate used. The small strain differences in microsomal enzyme activity for the systems investigated were judged to be insufficient to explain the strain difference in susceptibility to endrin.     

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.     

Microsomal oxidase activities in relation to age and chlorcyclizine induction in American cockroach,Periplaneta americana,fat body,midgut and hindgut

Female adult American cockroaches, Periplaneta americana L., showed definite age-dependent changes in levels of activity of the microsomal mixed-function oxidases. Cytochrome P-450 levels, EPN-detoxication, and p-nitroanisole O-demethylation activities were very low in young adult insects but increased steadily reaching a natural peak at about 100 days in fat body and at about 90 days in midgut and hindgut. The activities then declined rapidly reaching levels of young insects at about 130 to 140 days of age. NADPH-neotetrazolium-reductase activity was high in young insects, declined later in adult life, and returned to a peak at about 100 days.Injections of chlorcyclizine, a known microsomal enzyme inducer, significantly increased levels of cytochrome P-450, EPN-detoxication, p-nitroanisole O-demethylation, and NADPH-NT-reductase activities in young cockroaches. The drug injections were effective, however, only before the natural activity peak was reached. Beyond this point the injections had no inductive effect indicating that the microsomal oxidases in this insect are uninducible when normal enzyme levels are falling.NADPH-NT-reductase activity in male cockroaches, while being somewhat higher than in females, showed a similar age-dependent curve with the peak occurring at about 120 days.Age-dependent carbaryl resistance in male and female insects tended to follow levels of the microsomal oxidase activities. Fifty to 60-day-old insects, however, tended to be more resistant to the insecticide than microsomal enzyme levels would indicate.RNA levels of normal female insects showed age-dependent curves similar to those of the microsomal enzyme activities, being low in young adults and reaching a peak at about 100 days. Chlorcyclizine injections had little or no effect on total microsomal RNA levels.     

Induction of glutathione S-aryl transferase by phenobarbital in the house fly

Induction of glutathione S-aryl transferase by phenobarbital was studied with three stains of house flies which differed in basal levels of the enzyme. The enzyme was shown to be inducible in two of the three strains tested and the amount of induction was inversely proportional to the basal level of enzyme activity. In dose-dependency tests, a high dose of phenobarbital, 10,000 ppm, was needed to cause significant levels of induction. In a time study, 48 hr was found to be the time at which the highest levels of induction occur. Similarities of this system to house fly microsomal oxidases are discussed.     

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.     

Phenobarbital induction of detoxifying enzymes in resistant and susceptible houseflies

Houseflies, Musca domestica, L., were treated with the drugs phenobarbital and 3-methylcholanthrene to study the effects of these compounds as inducing agents of the microsomal oxidases, heptachlor epoxidase, and p-nitroanisole O-demethylase, and of DDT-dehydrochlorinase. Phenobarbital was active when applied by injection or as part of the diet but inactive when topically applied. The resulting increases in heptachlor epoxidase activity were as much as 25-fold that of the untreated controls. The net increase in enzyme activity after phenobarbital treatment was greater in an insecticide-susceptible strain, WHO-SRS strain, than in a carbamate-resistant strain. However, the phenobarbital induced increases in DDT-dehydrochlorinase were greater, about 2-fold, in the resistant strains than in the susceptible strain.The optimum dose for phenobarbital was 1% in the diet for a period of 3 days. None of the treatments with 3-MC, feeding, injection, exposure to residues, or topical, were effective in induction.     

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.     

The effects of dicofol on induction of hepatic microsomal metabolism in rats

In a comparative study, the induction effects of dicofol, technical Kelthane, and DDT on hepatic microsomal and cytosolic enzyme activities in rats were compared with those effects produced by phenobarbital (PhB) and β-naphthoflavone (BNF). Male rats (ca. 250 g) were injected (ip) for 4 consecutive days with 1.0 ml of vehicle containing either dicofol (1.5, 15.0, 29.5, or 59.0 mM, Kelthane (dicofol content equal to 29.5 or 59.0 mM), DDT (59.0 mM), or BNF (36.7 mM). Liver weights, microsomal protein, and cytochrome P-450 concentrations and microsomal and cytosolic enzyme specific activities were measured. Dicofol produced dose-related increases in all of the parameters measured except liver weight and cytosolic epoxide hydrolase activity. At a concentration of 59.0 mM, dicofol increased the concentrations of microsomal protein (1.7-fold) and cytochrome P-450 (2.9-fold), and the specific activities of cytochrome c reductase (1.6-fold), ethoxycoumarin O-deethylase (2.3-fold), aminopyrine N-demethylase (3.0-fold), microsomal epoxide hydrolase (2.6-fold), and glutathione S-transferase (2.9-fold). The induction potency of dicofol was equivalent to Kelthane, DDT, and PhB at equimolar (59.0 mM) concentrations of chemical.     

Detoxication capacity in the honey bee,Apis mellifera L

Various detoxifying enzymes, including microsomal oxidases, glutathione S-transferases, esterases, epoxide hydrolase, and DDT-dehydrochlorinase, were assayed in adult worker bees (Apis mellifera L.) using midguts as the enzyme source. A cell-free system was used for all enzyme assays, except that microsomal oxidases required intact midgut because of the inhibitor encountered. Midgut microsomal preparations contained mainly cytochrome P-420, the inactive form of cytochrome P-450, which may explain the low microsomal oxidase activity in microsomes. All enzymes studied were active, suggesting that the high susceptibility of honey bees to insecticides is not due to low detoxication capacity. Sublethal exposure of honey bees to various insecticides had no effect on these enzyme activities, with the exception of permethrin which significantly stimulated the glutathione S-transferase, and malathion, which significantly inhibited the α-naphthylacetate esterase and carboxylesterase.     

Insect juvenile hormones: Induction of detoxifying enzymes in the housefly and detoxication by housefly enzymes

The cecropia juvenile hormone and three of its analogs were compared as inducers of microsomal epoxidase, O-demethylase, and DDT dehydrochlorinase in the housefly, Musca domestica L. The compounds were the cecropia juvenile hormone, methoprene, hydroprene, 6,7-epoxy-3,7-diethyl-1-[3,4-(methylenedioxy)phenoxy]-2-octene, and piperonyl butoxide, a well known insecticide synergist. The compounds were administered by feeding at levels up to 1% in the diet for 3 days to 1-day-old female adults. Enzymes were then prepared and assayed for their activity using heptachlor, p-nitroanisole, and DDT as substrates.There was approximately a twofold increase in the microsomal oxidases and a 50% increase in DDT dehydrochlorinase after the treatment with the cecropia juvenile hormone, while methoprene had some activity as an inducer of the epoxidase (30% increase) but no activity in the case of the O-demethylase or the dehydrochlorinase. Hydroprene had no effect on any of the enzyme systems, while 6,7-epoxy-3,7-diethyl-1-[3,4-(methylenedioxy)phenoxy]-2-octene was an inhibitor of the two microsomal oxidases. The latter compound and piperonyl butoxide were strong inducers of DDT dehydrochlorinase, causing approximately twofold increases in the activity of this enzyme.There was evidence that the microsomal preparations were able to metabolize and inactivate methoprene and hydroprene, the action being oxidative in the case of methoprene and both oxidative and hydrolytic in the case of hydroprene. The oxidative metabolism of the two juvenile hormone analogs by the microsomal preparations was inducible by the cecropia juvenile hormone and by phenobarbital and dieldrin.     

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.     

Bimodal effect of methylenedioxyphenyl compounds on detoxifying enzymes in the housefly

Thirteen methylenedioxyphenyl (MDP) compounds, including commercial insecticide synergists and juvenile hormone analogs, were compared in their effect on detoxifying enzymes in the housefly (Musca domestica). Flies were fed a diet containing 1% of the compounds for 3 days. Enzymes were then assayed in vitro for their activity using aldrin and DDT as substrates. Piperonyl butoxide (PB), sesamex, propyl isome, sulfoxide, safrole, isosafrole, 6,7-epoxy-3,7-diethyl-1-[3-4(methylenedioxy) phenoxy]-2-octene (MDP-JH I) and 6,7-epoxy-3-methyl-7-ethyl-1-[3,4-(methylenedioxy) phenoxy]-2-octene (MDP-JH II) all caused a bimodal effect, inhibiting microsomal epoxidase and inducing DDT-dehydrochlorinase in the resistant Isolan-B strain. Two of these, PB and MDP-JH I, gave similar results with the susceptible strain, stw;w⁵ and two resistant strains, Fc-B and Orlando-DDT. However, o-safrole, piperonylic acid, piperonal, 3,4-methylenedioxybenzyl acetate and methyl-(3,4-methylenedioxy) benzoate had little or no effect on the enzyme systems studied. The standard susceptible strain (WHO-SRS) responded to these compounds very differently. Among those tested, piperonyl butoxide, sesamex, safrole, and isosafrole were inducers of microsomal epoxidase, a 4-fold increase occurring after treatment with sesamex. Only MDP-JH II showed a marked inhibition of the epoxidase. These treatments did not effect DDT-dehydrochlorinase activity in this strain.The enhancement of DDT-dehydrochlorinase activity by the MDP compounds is associated with an increased rate of DDT dehydrochlorination in vivo. The stimulatory effect could be blocked by treatment with actinomycin D or cycloheximide.     

Dehydrogenation: A previously unreported pathway of lindane metabolism in mammals

This study presents evidence for the dehydrogenation of lindane by a hepatic microsomal mixed-function oxidase system. Preliminary investigation established that the incubation of lindane with rat liver homogenates produces a chlorinated, nonpolar compound identified as hexachlorocyclohexene. Differential centrifugation resulted in the sedimentation of most of the dehydrogenase activity in the microsomal fraction. Optimum in vitro assay conditions were established and it was found that the dehydrogenase system required molecular oxygen and reduced pyridine nucleotide coenzyme for maximum activity. Inhibition by SKF 525-A and CO suggested that the enzyme was cytochrome P-450 dependent. Lack of inhibition by cyanide indicated that the cytochrome b₅ desaturase system was probably not involved. Pretreatment of rats with DDT, which stimulates lindane metabolism, also induced significantly higher dehydrogenase activity. Both the in vivo and in vitro metabolism of hexachlorocyclohexene produced previously identified lindane metabolites. The existence of a cytochrome P-450 dependent mixed-function oxidase which catalyzes the dehydrogenation of lindane has not previously been reported and may be of importance in the metabolism of other xenobiotics.     

Cytochrome P-450 in insects. 7. Age dependency and phenobarbital induction of cytochrome P-450, P-450 reductase,and monooxygenase activities in the black blow fly (Phormia regina,Meigen)

Development and phenobarbital (PB) induction of microsomal cytochrome P-450, NADPH-cytochrome c (P-450) reductase, two epoxidation, and two O-demethylation activities were examined in chronologically timed populations of female black blow flies (Phormia regina, Meigen). Measurements of these enzymes started with the pharate adult stage and ended 5 days following eclosion. Induction occurred in all enzymes, even at 0.005% PB, and was maximum at 0.15%. Dramatic induction of the O-demethylation of 7-methoxy-4-methylcoumarin was observed in flies dosed with the maximum concentration of the drug. This monooxygenase activity increased to nearly 1400 times the level in control flies, whereas the other O-demethylation (methoxyresorufin) and the two epoxidation reactions exhibited considerably less change. Induction of the structural enzymes of this enzyme system were 10-fold for cytochrome P-450 and 5-fold for NADPH-cytochrome c (P-450) reductase. These data suggest that PB induces several P-450's in the blow fly, particularly one bearing a high degree of specificity for 7-methoxy-4-methycoumarin.     

Microsomal oxidase activity of three blowfly species and its induction by phenobarbital and β-naphtoflavone

Induction of the microsomal oxidase system by dietary phenobarbital and β-naphthoflavone was examined in three blowflies, Phormia regina (Mg.), Lucilia illustris (Mg.), and Eucalliphora lilica (Walk.). Responses were similar in adults and larvae of all species. Phenobarbital increased cytochrome P-450 levels up to 9-fold and aldrin epoxidase up to 138-fold. Increases in cytochrome P-450 and aldrin epoxidase caused by β-naphthoflavone were minor relative to those produced by phenobarbital. In toxicity experiments with carbaryl and propoxur tolerance was associated with the amount of microsomal oxidase activity. Using piperonyl butoxide to synergize carbaryl and propoxur there was no clear indication for the use of either the synergist ratio or synergist difference as an indicator of microsomal oxidase activity.     

Rat liver paraoxonase (paraoxon arylesterase)

Paraoxonase in the liver of male Sprague-Dawley rats was studied by using [phenyl-1-¹⁴C]paraoxon. Examination of the enzyme activity in subcellular fractions of liver homogenates indicated that hepatic paraoxonase is essentially a microsomal enzyme with a pH optimum of 7.5 to 7.8. Effects of calcium ions and EDTA on the enzyme suggested that active paraoxonase is a protein-calcium complex possibly with a range of affinity to calcium ion. Activity in homogenates declined with a half-life of 6 to 9 hr when stored at 0°C, apparently reflecting dissociation of calcium ions. Experiments with homogenates of perfused liver provided evidence that even without the contribution of calcium from blood, paraoxonase is almost fully active at the moment of homogenization. Possible reasons for the much reduced activity of paraoxonase in in vivo metabolism are discussed.     

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.     

Chemical structure-activity relationships of the inhibition of sterol biosynthesis by N-substituted morpholines in higher plants

Tridemorph and fenpropimorph as well as several related N-alkyl morpholines have been tested in vitro on the cycloeucalenol-obtusifoliol isomerase, a microsomal enzyme involved in higher plant sterol biosynthesis. The results showed that N-substituted morpholines inhibit powerfully the enzyme (I₅₀ = 0.4 μM for fenpropimorph). The following important molecular parameters of the inhibition could be determined: (i) the inhibitory capacity was probably related to the presence of a positive charge on the nitrogen atom, (ii) the length of the alkyl group was critical, with a maximum activity for n = 13 carbons in the case of a linear hydrocarbon chain, (iii) the presence of bulky substituents at the proximity of the nitrogen atom led to a strong decrease of the inhibitory power, (iv) in the fenpropimorph series where a chiral center is present at C-2 of the alkyl chain, a remarkable enantiomeric selectivity of the inhibition was observed, (v) the N-oxide derivative of fenpropimorph was shown to be as active as the parent compound. The N-alkyl morpholines have been also assayed on suspension cultures of bramble cells and led to a strong accumulation of 9β, 19-cyclopropyl- and Δ⁸-sterols. This result confirmed that the cycloeucalenol-obtusifoliol isomerase was a major target of the N-substituted morpholines and suggested that the Δ⁸ → Δ⁷-sterol isomerase was also a target for these chemicals. The molecular parameters implied in the in vivo accumulation of 9β, 19-cyclopropyl sterols were very similar to those resulting from the in vitro study. The chemical structure-inhibitory activity relationship of N-alkyl morpholines was discussed with respect to their fungicidal activity which has been described in a previous study [E. H. Pommer, Pestic. Sci. 15, 285 (1984)]. The comparison revealed that the better the inhibitory capacity on the cycloeucalenol-obtusifoliol isomerase was, the higher was the fungicidal activity in vivo.     

The effects of salinity and temperature on the in vitro metabolism of the organophosphorus insecticide fenitrothion by the blue crab,Callinectes sapidus

The in vitro metabolism of fenitrothion [O,O-dimethyl-O-(3-methyl-4-nitrophenyl)phosphorothioate] by subcellular fractions prepared from the hepatopancrease of blue crabs, Callinectes sapidus, which had been acclimated to either 22°C, 34‰ (parts per thousand); 22°C, 17‰; or 17°C, 34‰ seawater was investigated. In the microsomal fraction, fenitrothion was metabolized to fenitrooxon and 3-methyl-4-nitrophenol. Fenitrothion was metabolized to desmethyl fenitrothion in the cytosolic fraction. The rates of formation of the detoxification products, 3-methyl-4-nitrophenol and desmethyl fenitrothion, were greater in subcellular fractions prepared from crabs which had been acclimated to the lower salinity seawater. The rate of formation of the more toxic metabolite fenitrooxon was greater in the microsomal fraction prepared from crabs which had been acclimated to higher salinity water. All three of these metabolites were formed at considerably faster rates in subcellular fractions from crabs acclimated to and incubated at 22 than at 17°C. These results suggest that enzyme activity contributes to the increased in vivo toxicity of fenitrothion to blue crabs at elevated salinities and temperatures. Also, the observed differences in the rate of formation of the oxon have a greater effect on toxicity than differences in the rate of formation of 3-methyl-4-nitrophenol and desmethyl fenitrothion.