The interaction of vinyl chloride with rat hepatic microsomal cytochrome P-450 in vitro.

In the presence of hepatic microsomes, vinyl chloride produces a ‘type I’ difference spectrum and stimulates carbon monoxide inhibitable NADPH consumption. A comparison of the binding and Michaelis parameters for the interaction of vinyl chloride with uninduced, phenobarbital and 3-methylcholanthrene induced microsomes indicates that the binding and metabolism of vinyl chloride is catalyzed by more than one type P-450 cytochrome, but predominantly by cytochrome P-450. Metabolites of vinyl chloride from this enzyme system decrease the levels of cytochrome P-450 and microsomal heme, but not cytochrome $\text{b}$₅ or NADPH-cytochrome $\text{c}$ reductase $\text{in vitro}$.     

Studies on the interaction of furan with hepatic cytochrome P-450

In vitro incubation of rat liver micro-somes with [¹⁴C]-furan in the presence of NADPH resulted in the covalent incorporation of furan-derived radioactivity in microsomal protein. Compared to microsomes from untreated rats a two- to threefold increase in binding was observed with microsomes from phenobarbital-treated rats and a four- to five-fold increase was observed with microsomes from rats pretreated with imidazole or pyrazole. Covalent binding was reduced with microsomes from rats pretreated with β-naphthoflavone. Chemicals containing an amine group (semicarbazide), those in which the amine group is blocked but have a free thiol group (N-acetylcysteine), and those which have both an amine and a thiol group (glutathione) effectively blocked binding of [¹⁴C]-furan to microsomal protein. A decrease in cytochrome P-450 (P-450) content and decreases in the activities of P-450-dependent aniline hydroxylase, 7-ethoxycoumarin-O-deethylase (BCD), and 7-ethoxyresorufin-O-deethylase (ERD) was observed 24 hours after a single oral administration of 8 or 25 mg/kg of furan, suggesting that the reactive intermediate formed during P-450 catalyzed metabolism could be binding with nucleophilic groups within the P-450. In vitro studies indicated a significant decrease in the activity of aniline hydroxylase in pyrazole microsomes and BCD in phenobarbital microsomes without any significant change in the CO-binding spectrum of P-450 or in the total microsomal heme content, suggesting that furan inhibits the P-450s induced by PB and pyrazole. An almost equal distribution of furan-derived radioactivity in the heme and protein fractions of the CO-binding particles after In vitro treatment of microsomes with furan suggests binding of furan metabolites with heme and apoprotein of P-450, and, probably, due to this interaction, furan is acting as a suicide inhibitor of P-450.     

Studies on the interaction of steroid substrates with adrenal microsomal cytochrome P-450 (P-450C21) in liposome membranes

Cytochrome P-450 (P-450C21), purified from bovine adrenocortical microsomes, was incorporated into the single bilayer liposomes of egg yolk phosphatidylcholine by gel filtration, using a high pressure liquid chromatography system. Interaction of the steroid substrates, 17 alpha-hydroxyprogesterone and progesterone, with P-450C21 in the liposomes was studied in the equilibrium state by measuring substrate-induced spectral change. The apparent dissociation constant of the P-450C21-substrate complex increased with phosphatidylcholine concentration in the system, showing the substrate to be partitioned between the aqueous and lipid phases. Partition coefficients, determined by equilibrium dialysis and the Hummel-Dreyer method, were 3500 for progesterone and 2000 for 17 alpha-hydroxyprogesterone at 25 degrees C. The binding process of the substrates to P-450C21 in the liposomes and their dissociation were measured by a stopped flow method. The apparent rate of substrate binding to P-450C21 in the liposomes was not effected by substrate partitioning, indicating partitioning to occur much more quickly than substrate binding to P-450C21. Absorption changes observed in the stopped flow experiments were analyzed at a rapid equilibrium of partitioning. Based on these results, the substrate binding site of P-450C21 was concluded to face the lipid phase of the liposome membranes.     

The effect of ethanol on drug oxidations in vitro and the significance of ethanol-cytochrome P-450 interaction

The effect of ethanol on N-demethylation of aminopyrine in rat liver slices and in the microsomal fraction and on microsomal hydroxylation of pentobarbital and aniline was studied. With liver slices N-demethylation of aminopyrine was stimulated by 35–40% at low ethanol concentrations (2mm), whereas no stimulation occurred at high concentrations (100mm). With the liver microsomal fraction, an inhibitory effect was observed only at high ethanol concentrations (100mm). This was also observed with the other drugs studied. In agreement with these results, only at a high concentration did ethanol interfere with the binding of drug substrates to cytochrome P-450. Further, as previously reported, ethanol produced a reverse type I spectral change when added to the liver microsomal fraction. Evidence that this spectral change is due to removal of substrate, endogenously bound to cytochrome P-450, is reported. A dual effect of ethanol is assumed to explain the present findings; in liver slices, at a low ethanol concentration, the enhanced rate of drug oxidation is the result of an increased NADH concentration, whereas the inhibitory effect observed with the microsomal fraction at high ethanol concentration is due to the interference by ethanol with the binding of drug substrates to cytochrome P-450.     

Cytochrome P-450 and halothane metabolism. Decrease in rat liver microsomal P-450 in vitro

Anaerobic in vitro incubation of microsomes from phenobarbital(PB)-induced rats with halothane results in an irreversible decrease of measurable cytochrome P-450. There is a parallel decrease in heme content under the same incubation conditions. However, microsomes from 3-methylcholanthrene(3-MC)-induced or untreated animals do not show a reduction in cytochrome P-450 content. Aerobic incubation with halothane results in a decrease of cytochrome P-450 which can be completely reversed by dialysis or the addition of potassium ferricyanide. These latter treatments only partially restore the cytochrome P-450 levels following anaerobic incubations. The decrease in cytochrome caused by halothane is not associated with measureable heme N-alkyl adduct formation; lipid peroxidation does not play a role as indicated by the lack of effect of 1 mM EDTA or a decrease in glucose-6-phosphatase activity. Halothane metabolites are bound irreversibly to microsomal protein as determined by gel electrophoresis only when the oxygen concentration is very low. The mechanism of cytochrome P-450 decrease is consistent with the formation of a reactive metabolite which binds to the protein portion and also destroys heme.     

Rotation and interaction with epoxide hydrase of cytochrome P-450 in proteoliposomes

Purified rat liver cytochrome P-450MC or P-450PB was co-reconstituted with epoxide hydrase in liposomal vesicles made of phosphatidylcholine, phosphatidylethanolamine, and phosphatidylserine at a lipid to protein weight ratio of 5 by the cholate dialysis procedure. Rotational diffusion of the cytochromes was measured by observing the decay of absorption anisotropy, r(t), after photolysis of the heme.CO complex by a vertically polarized laser flash. Analysis of r(t) was based on a "rotation-about-membrane-normal" model. The measurements were used to investigate interactions of cytochrome P-450MC or P-450PB with epoxide hydrase. Different rotational mobilities of the two cytochromes were observed. The amount of mobile molecules was 78% for cytochrome P-450MC and 91% for P-450PB, and the rest was immobile within the experimental time range of 1 ms. In the presence of epoxide hydrase 85% of cytochrome P-450MC and 96% of P-450PB were mobile. Cross-linking of epoxide hydrase by anti-epoxide hydrase antibodies resulted in a drastic immobilization of the cytochromes, reducing the mobile population to 49% for P-450MC and to 60% for P-450PB. The rotational relaxation times phi of the mobile populations ranged from 210 to 283 microseconds. These results imply that both cytochromes P-450MC and P-450PB transiently associate with epoxide hydrase in liposomal membranes. Further analysis of the data showed that the angle between the heme plane of P-450MC and the membrane is 48 degrees or 62 degrees, different from the value of 55 degrees reported previously for P-450PB (Gut, J., Richter, C., Cherry, R. J., Winterhalter, K. H., and Kawato, S. (1983) J. Biol. Chem. 258, 8588-8594).     

Zwitterionic detergent mediated interaction of purified cytochrome P-450LM4 from 5,6-benzoflavone-treated rabbits with MADPH-cytochrome P-450 reductase

Hydroxylation of acetanilide catalyzed by purified cytochrome P-450LM4 and NADPH-cytochrome P-450 reductase was reconstituted with the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS). The optimum rate of production of 4-hydroxyacetanilide was observed between 3 and 7 mM CHAPS and was about half that with 0.05 mM dilauroylglyceryl-3-phosphocholine (di-12-GPC). At higher detergent concentrations, hydroxylase activity decreased until at 15-20 mM CHAPS the system was inactive. The effect of CHAPS on the state of aggregation of P-450LM4 and on interaction between the cytochrome and P-450 reductase alone and under turnover conditions was investigated by ultracentrifugation. At 4 mM CHAPS, P-450LM4 was hexameric to heptameric (Mr 369,000). Neither reductase nor reductase plus acetanilide and NADPH altered the state of P-450LM4 aggregation, suggesting that a stable 1:1 P-450/reductase complex did not form under turnover conditions. Replacing CHAPS with 0.05 mM di-12-GPC resulted in formation of heterogeneous P-450 oligomers (Mr greater than 480,000). At CHAPS concentrations where substrate hydroxylation did not occur (15 and 22 mM), P-450LM4 was shown by sedimentation equilibrium measurements to be dimeric and monomeric, respectively. P-450 reductase was shown to reduce monomeric P-450LM4 in the presence of NADPH. Thus, the dependence of hydroxylase activity on [CHAPS] may be related to the state of aggregation of the cytochrome. An apparent correlation between P-450 aggregation state and NADPH-supported hydroxylation was also observed with phenobarbital-inducible P-450LM2 in the presence of detergents [Dean, W.L., & Gray, R.D. (1982) J. Biol. Chem. 257, 14679-14685; Wagner, S.L., Dean, W.L., & Gray, R.D. (1984) J. Biol. Chem. 259, 2390-2395].     

The interaction of aliphatic analogs of methylene-dioxyphenyl compounds with cytochromes P-450 and P-420.

The spectra resulting from the interaction of a series of substituted dioxolanes with microsomal cytochromes P-450 or P-420, as well as purified cytochrome P-450, were measured. With the exception of dioxolane, 4-methyldioxolane and 4-ethyldioxolane, these compounds interacted with ferric cytochrome P-450 to give complexes exhibiting type I optical difference spectra, and, after incubation with NADPH, spectra with peaks at about 430 nm. These complexes, as well as those formed from dioxolanes in the presence of cumene hydroperoxide, inhibit the binding of CO to the cytochrome. Consideration of the known chemistry of dioxolanes, together with recent advances in the understanding of double Soret spectra, lead to a possible explanation for the differences between the spectra of dioxolanes and their aromatic analogs, the methylenedioxyphenyl compounds.     

Isolation of the membrane-binding peptide of NADPH-cytochrome P-450 reductase. Characterization of the peptide and its role in the interaction of reductase with cytochrome P-450

A peptide identified as the membrane-associated segment of NADPH-cytochrome P-450 reductase has been generated by steapsin protease treatment of vesicle-incorporated reductase and isolated by preparative gel electrophoresis. This peptide remains associated with vesicles when steapsin protease digests of vesicle-incorporated reductase were fractionated by Sepharose 4B chromatography, confirming its identity as the membrane-binding peptide. The molecular weight of the membrane-binding peptide was 6400 as determined by gel filtration in 8 M guanidine hydrochloride, and its amino acid content was not especially hydrophobic. The activity of reconstituted hydroxylation systems consisting of reductase, cytochrome P-446, and dilauroyl phosphatidylcholine was not inhibited by large molar excesses of purified membrane-binding peptide. Moreover, when purified reductase and cytochrome P-446 were added to liposomes which contained the membrane-binding peptide, it was determined that mixed function oxidase activity was reconstituted as effectively as when vesicles without the membrane-binding peptides were used. Similar results were obtained with reductase, cytochrome P-450, and detergent-solubilized liposomes (with or without the membrane-binding peptide). Thus, the membrane-binding peptide does not appear to interact with either of these two forms of the hemoprotein in a site-specific manner to prevent reconstitution of hydroxylation activity.     

Role of electrostatic interactions in the reaction of NADPH-cytochrome P-450 reductase with cytochromes P-450

Chemical modification of cytochrome P-450 reductase was used to determine the involvement of charged amino acids in the interaction between the reductase and two forms of cytochrome P-450. Acetylation of 11 lysine residues of the reductase with acetic anhydride yielded a 20-40% decrease in the apparent Km of the reductase for cytochrome P-450b or cytochrome P-450c using either 7-ethoxycoumarin or benzphetamine as substrates. A 20-45% decrease in the Vmax was observed except for cytochrome P-450b with 7-ethoxycoumarin as substrate, where there was a 27% increase. Modification of carboxyl groups on the reductase with 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide (EDC) and methylamine, glycine methyl ester, or taurine as nucleophiles inhibited the interaction with the cytochromes P-450. We were able to modify 4.0, 7.9, and 5.9 carboxyl groups using methylamine, glycine methyl ester, or taurine, respectively. The apparent Km for cytochrome P-450c or cytochrome P-450b was increased 1.3- to 5.2-fold in a reconstituted monooxygenase assay with 7-ethoxycoumarin or benzphetamine as substrate. There were varied effects on the Vmax. There was no significant change in the conformation of the reductase upon chemical modification with either acetic anhydride or EDC. These results strongly suggest that electrostatic interactions as well as steric constraints play a role in the binding and electron transfer step(s) between the reductase and cytochrome P-450.     

Distribution of cytochrome P-450 monoxygenase enzymes in the nasal mucosa of hamster and rat

Deposition of inhaled particulates onto the respiratory mucosa is relatively great in that portion of the nasal cavity unprotected by ciliated, goblet, or keratinized superficial cells. The cytochrome P-450 system is an important enzyme system involved in the biotransformation of xenobiotics into metabolites that are more readily absorbed. To examine the transitional region caudal to the nasal vestibule, nasal tissues of hamster and rat were prepared for immunocytochemistry. Blocks of tissue representing four levels along the long axis of the nasal cavity were examined. Paraffin sections were processed through the avidin-biotin peroxidase procedure, with diaminobenzidine tetrahydrochloride as the chromagen. Enzyme localization was accomplished through the use of antibodies for three rabbit cytochrome P-450 isozymes; 2, 5, and 6 (subfamilies IIB, IVB, and IA, respectively); and for rabbit NADPH-cytochrome P-450 reductase. Enzyme distribution was similar in both hamster and rat nasal tissues except in cells of striated and intercalated ducts of nasal glands and in cells of the nasolacrimal duct where immunoreactivity was greater in the hamster. Immunoreactivity for reductase and isozyme 2 was intense in nonciliated cells lining the nonolfactory epithelium, in sustentacular cells of the olfactory epithelium, and in acinar cells of olfactory glands. Distribution of reaction products to isozyme 5 and 6 were similar to but not so intense as those of reductase and isozyme 2. Reaction products for reductase and isozyme 2 occurred generally in the same cellular and intracellular regions with the following exceptions: isozyme 2 was more concentrated in cells of striated ducts and of the nasolacrimal duct, and reductase was more abundant in intercalated ducts of nasal glands.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rotation of cytochrome P-450. II. Specific interactions of cytochrome P-450 with NADPH-cytochrome P-450 reductase in phospholipid vesicles

Purified rat liver microsomal cytochrome P-450 and NADPH-cytochrome P-450 reductase were co-reconstituted in phosphatidylcholine-phosphatidylethanolamine-phosphatidylserine vesicles using a cholate dialysis technique. The co-reconstitution of the enzymes was demonstrated in proteoliposomes fractionated by centrifugation in a glycerol gradient. The proteoliposomes catalyzed the N-demethylation of a variety of substrates. Rotational diffusion of cytochrome P-450 was measured by detecting the decay of absorption anisotropy r(t), after photolysis of the heme.CO complex by a vertically polarized laser flash. The rotational mobility of cytochrome P-450, when reconstituted alone, was found to be dependent on the lipid to protein ratio by weight (L/P450) (Kawato, S., Gut, J., Cherry, R. J., Winterhalter, K. H., and Richter, C. (1982) J. Biol. Chem. 257, 7023-7029). About 35% of cytochrome P-450 was immobilized and the rest was rotating with a mean rotational relaxation time phi 1 of about 95 mus in L/P450 = 1 vesicle. In L/P450 = 10 vesicles, about 10% of P-450 was immobile and the rest was rotating with phi 1 congruent to 55 mus. Co-reconstitution of equimolar amounts of NADPH-cytochrome P-450 reductase into the above vesicles results in completely mobile cytochrome P-450 with a phi 1 congruent to 40 mus. Only a small decrease in the immobile fraction of cytochrome P-450 is observed when the molar ratio of cytochrome P-450 to the reductase is 5. The results suggest the formation of a monomolecular 1:1 complex between cytochrome P-450 and NADPH-cytochrome P-450 reductase in the liposomes.     

Effect of temperature on the interaction of cytochrome P-450 with a variety of amines

The interaction of cytochrome P-450 of rat liver microsomes with six amines have been investigated in Tris-HCL buffer pH 7.4 within the temperature range of 20--37 degrees C by the differential spectrophotometry method. Dissociation constants for the amine-cytochrome-P-450 complexes have been determined. The interaction of type I substrate, 1,2,7-trimethyl-decahydroquinolone-4, is characterized by the value of Ks(I)=4.14 exp (--6250/RT) mole/1. A value of Ks(II)=10(-8) exp (+6500/RT) mole/1 has been obtained for type II substrate, monomethylaniline. Association of 1,2,7-trimethyldecahydroquinolone-4 to cytochrome P-450 decreases with temperature, where as with monomethylaniline the reverse tendency is observed. Thermodynamic parameters delta H, delta F and delta S characterising the interaction of amines with cytochrome P-450 are evaluated.