Cytochrome P-450 and NADPH cytochrome c reductase in rat brain: formation of catechols and reactive catechol metabolites.

Microsomes isolated from whole rat brain were found to contain cytochreme P-450 (0.025 to 0.051 nmoles/mg) and NADPH cytochrome $\text{c}$ reductase activity (26.0 to 55.0 nmoles/mg/min). The oxidation of estradiol to a reactive metabolite that became covalently bound to rat brain microsomal protein was inhibited 63% by an atmosphere of CO:O₂ (9:1), indicating the involvement of a cytochrome P-450 oxygenase. In contrast, this atmosphere had no effect on the binding of either the catechol estrogen, 2-hydroxyestradiol, or several catecholamines to rat brain microsomes. An antibody prepared against NADPH cytochrome $\text{c}$ reductase was found to decrease significantly both the formation of 2-hydroxyestradiol from estradiol by rat brain microsomes and the covalent binding of the catechol estrogen and catecholamines to rat brain microsomal protein.     

Comparison of ratios of covalent binding to total metabolism of the pulmonary toxin, 4-ipomeanol, In vitro in pulmonary and hepatic microsomes,and the effects of pretreatments with phenobarbital or 3-methylcholanthrene

Studies of the ratios of the amounts of 4-ipomeanol covalently bound to the total amounts metabolized support the view that the high rates of $\text{in}\text{vitro}$ pulmonary microsomal alkylation by 4-ipomeanol reflect high rates of NADPH-mediated metabolic activation of the compound rather than a relative deficiency of a microsomal detoxication pathway. Moreover, the ability of 3-methylcholanthene pretreatment, but not phenobarbital pretreatment, to shift the $\text{in}\text{vivo}$ target organ alkylation and toxicity of 4-ipomeanol from the lung to the liver in rats could not be explained by a major alteration in the balances between microsomal toxication and detoxication pathways measurable in the $\text{in}\text{vitro}$ systems examined, nor upon a major change in the nature of the reactive 4-ipomeanol metabolites produced in the lungs or livers of the pretreated animals.     

Hydroxylation of the carcinostatic 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) by rat liver microsomes

Ring hydroxylation of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea was shown to occur in the presence of liver microsomes prepared from both normal and phenobarbital induced rats. The metabolite was identified by mass spectrometry after selective extraction and purification by liquid chromatography. The microsomal catalyzed reaction was oxygen and NADPH dependent, inhibited by carbon monoxide and induced 4–5 fold by $\text{in vivo}$ phenobarbital pre-treatment. Phenobarbital induced microsomes hydroxylated the substrate at a rate of 17.6 nmoles/min/mg protein at 37°. A Type I difference spectrum was observed with phenobarbital induced microsomes that also displayed a substrate binding constant (K_s of 4 × 10^?5 M.     

Activation and detoxification of bromobenzene in extrahepatic tissues

Bromobenzene causes hepatic and extrahepatic toxicity in rats. Toxicity is related to the presence of covalently bound material in these tissues. A major bromobenzene metabolite, p-bromophenol, has been shown to give rise to covalently bound material in liver, lung and kidney $\text{in vivo}$, but is not toxic. p-Bromophenol is formed from bromobenzene in liver, lung and kidney microsomes and is subsequently metabolized to 4-bromocatechol and covalently bound material. Bromobenzene-3, 4-oxide generated $\text{in situ}$ by liver microsomes, is detoxified by kidney, liver and lung cytosol. The results suggest that the kidney toxicity caused by bromobenzene is probably not mediated by either bromobenzene-3, 4-oxide or the reactive metabolites of p-bromophenol. In contrast, bromobenzene-3, 4-oxide may play a role in the lung toxicity observed after bromobenzene administration. However, the covalently bound material found in extrahepatic tissues may be derived from both bromobenzene-3, 4-oxide or the reactive metabolites of p-bromophenol, which may be formed directly by these tissues or transported there from the liver.     

Covalent binding of an intermediate(s) in prostaglandin biosynthesis to guinea pig lung microsomal protein

We have investigated the possible covalent binding of intermediates in prostaglandin (PG) biosynthesis to tissue macromolecules. Following incubation of arachidonic acid -1-[14]C (AA) with guinea pig lung microsomes, radioactivity was associated with the microsomal protein which was not dissociated from the protein by exhaustive solvent extraction. Furthermore, filtration of the protein complex through a Sephadex G-25 column failed to dissociate the radioactivity from the protein. This probably indicates covalent binding of AA metabolite(s) to protein. [3]H-PGE₂, [3]H-PGF_2α, and [3]H-thromboxane B₂ (TXB₂) did not show this high affinity binding to microsomal protein. The covalent binding of AA metabolites was greatly reduced in denatured microsomes and was inhibited by the addition of glutathione (GSH) or indomethacin to the incubation mixtures. Chromatographic analysis of the water layers obtained from microsomal incubations with either [3]H-AA or [3]H-GSH suggested the presence of one or more glutathione conjugates derived from AA. These studies indicate that most likely an intermediate formed during PG synthesis from AA covalently binds to tissue macromolecules. This covalent binding may be of physiological and pathological significance.     

Activation of microsomal glutathione transferase activity by reactive intermediates formed during the metabolism of phenol

The activity of microsomal glutathione transferase was increased 1.7-fold in rat liver microsomes which carried out NADPH dependent metabolism of phenol. Known phenol metabolites were therefore tested for their ability to activate the microsomal glutathione transferase. The phenol metabolites benzoquinone and 1,2,4-benzenetriol both activated the glutathione transferase in microsomes 2-fold independently of added NADPH. However, NADPH was required to activate the enzyme in the presence of hydroquinone. Catechol did not activate the enzyme in microsomes. The purified enzyme was activated 6-fold and 8-fold by 5 mM benzenetriol and benzoquinone respectively. Phenol, catechol or hydroquinone had no effect on the purified enzyme. When microsomal proteins that had metabolized [14C]phenol were examined by SDS polyacrylamide gel electrophoresis and fluorography it was found that metabolites had bound covalently to a protein which comigrated with the microsomal glutathione transferase enzyme. We therefore suggest that reactive metabolites of phenol activate the enzyme by covalent modification. It is discussed whether the binding and activation has general implications in the regulation of microsomal glutathione transferase and, since some reactive metabolites might be substrates for the enzyme, their elimination through conjugation.     

Binding of benzo(a)pyrene to hepatic cytosolic protein enhances its microsomal oxidation

Sephadex G-100 gel permeation chromatography of rat liver cytosol saturated with ¹⁴C-benzo(a)pyrene (BP) resulted in two peaks of protein bound radioactivity. Glutathione-S-transferase (GST) activity (towards 1-chloro 2,4-dinitrobenzene as substrate) was eluted as a single major peak which coincided with one peak of protein bound BP. Oxidation of protein bound BP (GST rich fractions) by microsomes from control or 3-methylcholanthrene treated rats was significantly enhanced as compared to ethanol suspended BP. The formation of oxidized products from the protein-bound BP was dependent on incubation time and microsomal protein concentration, required NADPH and was inhibited by monooxygenase inhibitors α-napthoflavone, 1-benzylimidazole, metyrapone and SKF 525A. Coemergence of BP binding-protein with GST suggests that the soluble protein could be one of the glutathione-S-transferases.     

The roles of soluble factors in squalene epoxidation by rat liver microsomes.

Squalene epoxidation by rat liver microsomes requires a supernatant protein factor and an acidic phospholipid in addition to NADPH and molecular oxygen. This study has shown that both the protein factor and the phospholipid lipid are necessary for externally added squalene to bind to the catalytic site on microsomal membranes. The epoxidation of squalene thus bound or biosynthesized $\text{in}\text{situ}$ from mevalonic acid proceeds effectively if the protein factor is present. Thus, the supernatant protein factor seems to play a dual function in both the binding and epoxidation of squalene in the $\text{in}\text{vitro}$ assay system. The phospholipid is not required for the epoxidation of bound squalene.     

Prostaglandin endoperoxide synthetase-mediated metabolism of carcinogenic aromatic amines and their binding to DNA and protein

The arachidonic acid-dependent metabolism of the carcinogens, 2-naphthylamine, 4-aminobiphenyl, 2-aminofluorene, benzidine, and N-methyl-4-aminoazobenzene was mediated by a prostaglandin endoperoxide synthetase preparation. Phenacetin, a suspected carcinogen, was not a substrate but its deacetylated metabolite, $\text{p}$-phenetidine, was rapidly oxidized. For each arylamine, extensive metabolism (14–81%) was observed, resulting in high levels of products bound covalently to protein. A low level of binding to added DNA was also detected for each substrate, except $\text{p}$-phenetidine and N-methyl-4-aminoazobenzene. Chromatography of the ethyl acetate-extractable metabolites indicated that the major products were N-oxidized and/or C-oxidized derivatives.     

Direct fluorometric analysis of benzo(a)pyrene metabolite formation by mouse liver microsomes

We have examined the metabolites produced by in vitro incubation of benzo(a)pyrene with 3-methylcholanthrene-induced mice liver microsomes. Our objective was to observe directly a possible difference in microsomal enzyme systems of animal models having different susceptibility to chemical carcinogens. The metabolites produced by the two animal models,$\text{C57BL}\text{6J}$ and $\text{DBA}\text{2}$ mice, were analyzed by a highly sensitive, “three-dimensional” fluorescence plotting technique. The fluorescence spectra of the total ethyl acetate-soluble metabolites clearly indicate that the metabolites produced by $\text{DBA}\text{2}$ enzymes were predominantly monohydroxylated benzo(a)pyrene while those produced by the liver microsomes of $\text{C57BL}\text{6J}$ were highly enriched with the 7,8-dihydrodihydroxybenzo(a)pyrene type.     

Induction,modification and inhibition of rat liver microsomal benzo(a)pyrene hydroxylase; Correlation with the S-9-mediated mutagenicity of benzo(a)pyrene

The effects of various pretreatments $\text{in vivo}$ (3MC, PB, 2 and 4FAA) and of various inhibitors $\text{in vitro}$ (7,8 BF, SKF525A and MN ^R) on the activity of rat liver microsomal BP hydroxylase were analyzed and correlated with the S-9 mediated mutagenicity of BP. 3MC is the only treatment which both induces and modifies the hydroxylase activity; it also specifically increases the enzyme mediated mutagenicity. Miconazole ^R which inhibits all the tested microsomal preparations, also reduces the mutagenicity mediated by all the S-9 preparations whereas the inhibitory effects of 7,8 BF and SKF525A are limited respectively to enzyme preparations from 3MC induced and control or PB treated rats.     

The covalent binding of 3-methylindole metabolites to bovine tissue

Tritiated 3-methylindole (3MI) was administered intravenously to calves. Total and covalent bound radioactivity were measured in different tissues. Pulmonary tissue showed the highest concentration of covalent bound radioactivity. (G-³H) or (methyl-¹⁴C) 3MI became covalently bound to microsomal protein when incubated with bovine lung microsomes. This covalent binding was dependent on time, temperature, oxygen and NADPH and was inhibited by SKF-525A, cytochrome c, a carbon monoxide enriched atmosphere and cysteine. The microsomal enzyme system catalysing covalent binding of 3MI has the classical characteristics of a cytochrome P-450 dependent mixed function oxidase. Metabolic activation of 3MI to a highly electrophilic intermediate, may be fundamental in the pathogenesis of 3MI induced pulmonary damage.     

In vivo regulation of adipose tissue protein kinase by adenosine 3',5'-monophosphate mediated glucagon stimulation.

The cytochrome P-450 content of primary hepatocyte cultures was maintained at levels close to those found $\text{in vivo}$ by using a defined medium containing testosterone, thyroxine, hydrocortisone, estradiol, glucagon, insulin, linoleic acid and oleic acid. Using these cultures, [¹⁴C]aflatoxin B₁, a potent liver carcinogen, was metabolized primarily to water-soluble metabolites. In agreement with $\text{in vivo}$ results, aflatoxin M₁ was the only nonpolar metabolite detected. In addition, a significant portion of radioactivity was covalently bound to cell constituents. These results suggest that primary hepatocyte cultures may be a good model of the liver for studying the metabolism and mechanism of action of toxic chemicals.     

Cytochrome P-450-mediated oxidation of 2-hydroxyestrogens to reactive intermediates

2-Hydroxyestradiol, 2-hydroxyestrone and 2-hydroxy-17α-ethynylestradiol, oxidation products of naturally occurring estrogens and synthetic estrogens in some oral contraceptives were found to be converted by rat liver microsomes to reactive metabolites that become irreversibly bound to microsomal protein. The irreversible binding required microsomes, oxygen and NADPH. The NADPH could be replaced by a xanthine-xanthine oxidase system which is known to generate superoxide anions. The irreversible binding was substantially inhibited by superoxide dismutase, 30% in those incubations containing NADPH and 98% in those incubations containing the xanthine-xanthine oxidase system. Further studies with 2-hydroxyestradiol showed that microsomal cytochrome P-450 was rate limiting in the NADPH-dependent irreversible binding, because the binding was inhibited 62% by an antibody against NADPH-cytochrome $\text{c}$ reductase and 70% in an atmosphere of CO:O₂ (9:1) when compared to an atmosphere of N₂:O₂ (9:1). Phenobarbital, a known inducer of cytochrome P-450, had no effect on the irreversible binding of 2-hydroxyestradiol, whereas another inducer of P-450, pregnenolone-16α-carbonitrile, markedly increased the irreversible binding. In contrast, cobaltous chloride, an inhibitor of the synthesis of cytochrome P-450, decreased both P-450 and the irreversible binding. These results are consistent with a mechanism for irreversible binding of estrogens and 2-hydroxyestrogens to microsomes that requires oxidation of the catechol nucleus by cytochrome P-450-generated superoxide anion.     

3H-Benzene metabolism in rabbit bone marrow

An assay for benzene metabolism using ³H-benzene and high pressure liquid chromatography was developed. ³H-Benzene metabolism (2 pmoles benzene equivalents/mg protein/min) required the presence of a TPNH generating system and was inhibited 80% in the presence of a CO:O₂ (9:1) atmosphere. The products of ³H-benzene rabbit bone marrow microsomal metabolism were phenol and an unidentified metabolite. Cytochrome P-450 (26–51 pmoles/mg microsomal protein) and cytochrome $\text{c}$ reductase activity (7.8–21.0 nmole/mg microsomal protein/min) were detected in rabbit bone marrow.     

Danazol inhibits human adrenal 21-and 11β-hydroxylation invitro

The effects of danazol on steroidogenesis $\text{in}$$\text{vitro}$ in the 16–20 week old human fetal adrenal were examined by studying: 1) danazol binding to adrenal microsomal and mitochondrial cytochrome P-450, and 2) enzyme kinetics of danazol inhibition of the adrenal microsomal 21-hydroxylase and the mitochondrial llβ-hydroxylase. The addition of danazol to preparations of adrenal microsomes or mitochondria elicited a type I cytochrome P-450 binding spectrum. Danazol bound to microsomal cytochrome P-450 with a high affinity apparent spectral dissociation constant (Kg) of 1 μM and with a lower affinity K's of 10 μM. Danazol bound to mitochondrial cytochrome P-450 with a Kg of 5 μM. In addition, danazol competitively inhibited the microsomal 21-hydroxylase (apparent enzymatic inhibition constant K_I = 0.8 μM) and the mitochondrial 11β-hydroxylase (K_I = 3 μM). These findings demonstrate that low concentrations of danazol directly inhibit steroidogenesis in the human fetal adrenal $\text{in}$$\text{vitro}$.     

The non-covalent binding of benzo[a]pyrene and its hydroxylated metabolites to intracellular proteins and lipid bilayers

The non-covalent interactions of benzo[a]pyrene (BP) and several of its hydroxylated metabolites with ligandin, aminoazodye-binding protein A (Z-protein, fatty acid binding protein) and lecithin bilayers have been studied by equilibrium dialysis, an adsorption technique and fluorescence spectroscopy. Binding affinities expressed as $\text{v}\text{/c}$ (where $\text{v}$ = moles of BP or BP metabolite bound per mole of protein or lipid and c = unbound concentration), were measured at concentrations sufficiently low that there was no self-association of the unbound compounds as judged by their fluorescence characteristics. 3-Hydroxybenzo[a]pyrene (BP-3-phenol), 4,5-dihydro-4,5-dihydroxybenzo[a]pyrene (BP-4,5-dihydrodiol) and 7,8-dihydro-7,8-dihydroxybenzo[a]pyrene (BP-7,8-dihydrodiol) bind more strongly ($\text{v}\text{/c = 10}{}^5\text{?5 · 10}{}^5\text{l}\text{·}\text{mol}{}^{\mathrm{?1}}$) to all three binders than does BP itself ($\text{v}\text{/c = 10}{}^4\text{?7 · 10}{}^4\text{l}\text{·}\text{mol}{}^{\mathrm{?1}}$). 9,10-Dihydro-9,10-dihydroxybenzo[a]pyrene (BP-9,10-dihydrodiol) binds to ligandin with an affinity similar to those of the other BP metabolites studied here, but binds much less strongly to both protein A and lecithin ($\text{v}\text{/c = 10}{}^4$ and 3 · 10⁴ l · mol^?1, respectively). The low affinity of BP-9,10-dihydrodiol for lecithin would account for earlier findings that on incubation of BP with isolated rat hepatocytes, this metabolite egressed from the cells to the extracellular medium much more readily than either BP-4,5-dihydrodiol or BP-7,8-dihydrodiol.Calculations based on these results suggest that within hepatocytes BP and its metabolites, including BP-9,10-dihydrodiol, will be found almost exclusively associated (>98%) with lipid membranes.     

Alkylation and carbamoylation intermediates from the carcinostatic 1-(2-chloroethyl)-3-cyclohexyl -1-nitrosourea (CCNU)

Evidence is presented which shows that 1-(2-chloroethyl) -3-cyclohexyl-1-nitrosourea (CCNU) upon degradation provides a 2-chloroethyl alkylating intermediate, possibly 2-chloroethyl carbonium ion, and 2-chloroethanol. Thiol alkylation occurs $\text{in vivo}$ and a major urinary metabolite of CCNU is thiodiacetic acid. A rapid microsomal hydroxylation of the cyclohexyl ring occurs which yields varying ratios of at least five metabolites: cis or trans 2-hydroxy, trans- 3-hydroxy, cis-3-hydroxy, cis-4-hydroxy and trans-4- hydroxy-CCNU. $\text{In vivo}$ carbamoylation appears to not be due to cyclohexylisocyanate but to the various hydroxy-cyclohexylisocyanates which are formed from hydroxy CCNU metabolites.     

Crude oil effects on microsomal mixed-function oxidase system components in the striped mullet (Mugil cephalus)

The effects of exposure to two types of crude oil on microsomal mixed-function oxidase system components in livers of juvenile striped mullet ($\text{Mugil cephalus}$) were investigated. Mullet were exposed for 4 days to emulsified Empire Mix or Saudi Arabian crude oils at an initial concentration of 75 ppm and an average of 1 ppm in the water column. Liver size was increased by about 50% following exposure to both oils. Since neither total hepatic protein nor microsomal protein increased as rapidly as did liver size, the concentrations of both were reduced following oil exposures. The proportion of microsomal protein to total hepatic protein or wet weight was not altered following crude oil exposure. Both cytochromes P-450 and $\text{b}$₅ were induced following oil treatment. NADPH-dependent enzymes assayed with cytochrome $\text{c}$ and dichlorophenolindophenol as substrates showed increases in activity after exposure to Empire Mix crude oil but only the latter enzyme activity was increased on a microsomal protein basis following Saudi Arabian crude oil treatment. Activities of NADH cytochrome $\text{c}$ and NADH cytochrome $\text{b}$₅ reductases appeared to vary with the protein level. However, since liver size was increased, oil-treated mullet had more of all parameters measured than did control mullet. Although the acute toxicity of Saudi Arabian crude oil to mullet is greater than that of Empire Mix crude oil, Empire Mix crude oil had greater inductive effects on microsomal oxidase components.     

Activity and kinetic properties of basal aryl hydrocarbon hydroxylase during proliferation in the transformable C3H 10T12; CL8 cell line

Basal aryl hydrocarbon hydroxylase (AHH) activity and its kinetic properties were studied as a function of proliferation in C3H mouse embryo 10T$\text{1}\text{2}$ CL8 cells. Activity was low in freshly plated cells, increased during exponential growth, peaked at confluency, and then declined. The apparent K_m-values for benzo[a]pyrene (BP) and NADPH were less in proliferating (approx. 0.37 μM BP, 3.3 nM NADPH) than in confluent cells (0.74–1.39 μM BP, 33.4–53.4 nM NADPH). Cells at different growth states responded differently to benz[a]anthracene (BA) and aminophylline, an inhibitor of cyclic nucleotide phosphodiesterases. When cells were harvested at the mid log phase of growth, 12 h of exposure to aminophylline caused maximum induction, while 24 h of BA treatment were required. In contrast, at early confluence, 12 h of BA treatment gave the greatest levels of activity, while exposure to aminophylline did not induce AHH. In fact, decreases in activity were observed. These differences are indicative of different regulatory mechanisms for BA and aminophylline induction. They also suggest the regulation of basal AHH by cyclic nucleotides changes during growth. The exposure times giving maximum activity were used to determine the kinetic properties of BA-induced activity. As with basal AHH, the K_m-value for BP was less in log phase (0.2–0.4 μM BP) than in confluent cells (0.64–1.05 μM BP). Moreover, the K_m-values for BP and NADPH in control cultures at confluency (0.10–0.14 μM BP, 15.4–23.2 nM NADPH) were less than those for BA-treated cells (0.64 μM BP, 37.9–54.8 nM NADPH) under the same nutritional conditions. The finding that the K_m-value for BP is lower in rapidly dividing cells than in confluent cells may help to explain why proliferating cells are more susceptible to transforming agents.