Cytochrome P-450 in insects: 2. Multiple forms in the flesh fly (Sarcophaga bullata,Parker), and the blow fly (Phormia regina (Meigen))

Microsomes prepared from the abdomens of the flesh fly (Sarcophaga bullata, Parker) and the blow fly (Phormia regina (Meigen)) contain approximately one-fifth and one-eighth as much cytochrome P-450, respectively, as those prepared from house fly (Musca domestica, L.) abdomens. These values correlate well with the microsomal aldrin epoxidase activity of the three species and with their respective susceptibilities to the insecticide, propoxur. When the microsomes of the flesh fly and the blow fly are solubilized by treatment with deoxycholate and resolved by ion-exchange chromatography on DEAE-cellulose and hydroxylapatite, four chromatographically distinct fractions containing cytochrome P-450 are obtained. Spectrophotometric assays of the cytochrome P-450 in these fractions indicate purifications of two-to sixfold for the flesh fly hemoprotein and two-to eightfold for that of the blow fly. SDS-Polyacrylamide gel electrophoresis of the four column fractions from the flesh fly microsomes indicates that six hemoproteins in the 40,000–60,000 molecular weight range are present. In similar experiments with blow fly fractions containing approximately the same amount of cytochrome P-450 no high molecular weight hemoproteins could be detected. This result is interpreted, with other evidence, as an indication of the greater instability of the blow fly hemoprotein. The results indicate that multiple forms of cytochrome P-450 are present in both species but there is insufficient data on which to estimate the number of such forms.     

Cytochrome P-450 in insects. 6. Age dependency and phenobarbital induction of cytochrome P-450, P-450 reductase,and monooxygenase activities in susceptible and resistant strains of Musca domestica

Development and phenobarbital (PB) induction of microsomal cytochrome P-450, cytochrome P-450 reductase, two epoxidation, and two O-demethylation activities were examined in chronologically timed populations of insecticide-susceptible (NAIDM) and -resistant (Rutgers) house flies. Measurements of these enzymes started with the pharate adult stage and ended 5 days following eclosion. Untreated insects of both strains had comparable reductase levels, whereas cytochrome P-450 and associated monooxygenase activities were 1.5-fold or more higher in Rutgers. Maximum induction, as well as toxicity, occurred at a lower PB concentration in NAIDM than Rutgers. The drug caused consistently higher increases in enzymes and activities within 12 hr of starting treatment in both strains. When PB was withdrawn from treated flies (both strains) 48 hr after treatment began, specific activities (product min^?1 mg protein^?1) in all enzymes returned to control values in 24 hr while metabolic capacity (product min^?1 insect^?1) achieved control values within 48 hr. The changes in turnover numbers (pmol product min^?1 pmol P-450^?1), in conjunction with the differences in the monooxygenation of the four substrates, suggest that PB treatment induced both a quantitative and qualitative change in NAIDM monooxygenation but only a quantitative change in Rutgers monooxygenation.     

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.     

Spectral interactions of insecticide synergists with microsomal cytochrome P-450 from insecticide-resistant and susceptible house flies

The spectral interactions of 45 insecticide synergists and related compounds with oxidized and reduced cytochrome P-450 from microsomes of insecticide-resistant and -susceptible house flies were investigated. The type III interaction typical of piperonyl butoxide was the most common spectral interaction for the compounds studied. In addition to this, several other varients of the type III interaction were noted. In general these responses with house fly microsomes were similar to those reported for mammals, although some minor species and strain differences were observed. The cytochrome P-450 from susceptible house flies, although reported previously not to exhibit type I difference spectra with many xenobiotics, was found to elicit this spectral response with several methylenedioxyphenyl compounds.     

Comparative enzyme activities and cytochrome P-450 levels of some rat tissues with respect to their metabolism of several pesticides

Cytochrome P-450, A- and B-esterase, amidase, and glutathione S-aryl transferase were assayed in the postmitochondrial centrifugal fraction, microsomes, and supernatant of rat liver, lungs, kidneys, and testes. Liver microsomes contained the highest P-450 levels and A-esterase activity. B-esterase activity was more generally distributed and higher in the microsomal tissue fractions. Microsomal amidase activity was highest in rat lung and lowest in the liver (per mg protein). Glutathione S-aryl transferase activity was highest in the liver. The in vitro metabolism of carbaryl, phosphamidon, and chlorotoluron by the various centrifugal fractions revealed many differences. Carbaryl metabolism was greater in the liver microsomal fractions than in any other preparation. 1-Naphthol was the major metabolite in all tissue fractions. Although very little metabolism of phosphamidon occurred in the rat, metabolism in the rat liver postmitochondrial fraction was slightly higher with respect to the production of metabolites than in the supernatant and microsomes combined. Chlorotoluron was not metabolized by any of the tissue fractions of the rat. At least a low level of activity toward some compounds was observed in all tissues, but this study confirmed that the liver was the most active metabolizing tissue as well as having the highest levels of enzymatic activity usually associated with pesticide metabolism.     

Effects of Cytochrome P450-Interacting Plant Growth Retardants,Fungicides and Related Compounds on Cell Development and Phase-I Biotransformation Capacity of Unicellular Photoautotrophic Green Algae

Fourteen compounds (paclobutrazol, triadimenol, BAS111..W, propiconazole, tetcyclacis, prochloraz, metyrapone, piperonyl butoxide, 1-aminobenzotriazole, fenpropimorph, propham, prohexadione, mepiquat chloride and chlormequat chloride), most of them established inhibitors of cytochrome P450-dependent mixed function oxygenases and used as pesticides, especially plant growth regulators or fungicides, were applied to the non-target organisms Chlorella fusca and Chlorella sorokiniana, two species of photoautotrophic unicellular green algae. The inhibitory properties of these compounds were evaluated by comparing concentration/response relationships for the integral parameters of cell volume growth and cell division with those for the P450-dependent O-dealkylase activity measured in vivo using 7-ethoxycoumarin and 7-ethoxyresorufin as xenobiotic model substrates for phase-I biotransformation. The results obtained indicate a strong algicidal activity for some of these compounds, with differential sensitivity of the order: cell division>O-dealkylation>cell volume increase. EC₅₀ values for cell division of C. fusca ranged from 0·1 to 9·3 μmol litre⁻¹ for prochloraz and paclobutrazol, respectively. Furthermore, in most cases, concentrations around 10 μmol litre⁻¹ limited significantly the capacity for cytochrome P450 O-dealkylase activity.     

Methylenedioxyphenyl complexes with microsomal cytochrome P-450: In vivo complex formation in rat liver and in midgut tissues of the Southern armyworm (Spodoptera eridania)

The capacity of several methylenedioxyphenyl insecticide synergists to generate metabolite complexes with cytochrome P-450 was studied in midgut tissues of the Southern armyworm (Spodoptera eridania). Examination of the NADH-reduced versus oxidized spectra from methylene-dioxyphenyl-induced midgut indicated that isosafrole, dihydrosafrole, and 4-ethoxy-1,2-methylenedioxybenzene generated metabolite complexes with a principal absorbance maximum at 427 nm and smaller absorbance maxima near 460 and 556 nm. Further studies with 2-n-heptylbenzimidazole showed that the complex between insect cytochrome P-450 and dihydrosafrole was unusually resistant to displacement. Initial rates of complex displacement in insect microsomes were found to be approximately an order of magnitude slower than those of the corresponding complexes in rat hepatic microsomes. Nevertheless, with the exception of the dihydrosafrole complex in insect microsomes, the “time to half-maximal displacement” parameter was found to be very similar for each complex. These findings indicate that the formation of dissociable complexes between cytochrome P-450 and the methylenedioxyphenyl metabolite occurs in both insect midgut and rat hepatic microsomes after in vivo exposure. From the present study it would appear that dihydrosafrole may constitute a useful probe to distinguish binding sites within insect and mammalian cytochrome P-450.