Target inactivation analysis applied to determination of molecular weights of rat liver proteins in the purified state and in microsomal membranes

In principle, target inactivation analysis provides a means of determining the molecular weights (Mr) and states of aggregation of proteins in native environments where they are functionally active. We applied this irradiation technique to the rat liver microsomal membrane proteins: cytochrome b5, epoxide hydrolase, flavin-containing monooxygenase, NADH-ferricyanide reductase, NADPH-cytochrome P-450 reductase, and seven different forms of cytochrome P-450. Catalytic activities, spectral analysis of prosthetic groups, and sodium dodecyl sulfate-polyacrylamide electrophoresis/peroxidase-coupled immunoblotting were used to estimate apparent Mr values in rat liver microsomal membranes. Except in one case (cytochrome P-450PCN-E), the estimated Mr corresponded most closely to that of a monomer. Purified cytochrome P-450PB-B, NADPH-cytochrome P-450 reductase and epoxide hydrolase were also subjected to target inactivation analysis, and the results also suggested monomeric structures for all three proteins under these conditions. However, previous hydrodynamic and gel-exclusion results clearly indicate that all three of these proteins are oligomeric under these conditions. The discrepancy between target inactivation Mr estimates and hydrodynamic results is attributed to a lack of energy transfer between monomeric units. Thus, while P-450PCN-E may be oligomeric in microsomal membranes, target inactivation analysis does not appear to give conclusive results regarding the states of aggregation of these microsomal proteins.

Stability of drug metabolizing enzymes during the incubation conditions of the liver microsomal assay with non-induced and induced mouse liver S-9 fractions

The purpose of this work was to study the relative activities and stabilities of phase-I and phase-II drug metabolizing enzymes in incubation mixtures used in vitro genotoxicity testing in order to optimize the conditions of the assay, increase sensitivity and eliminate false negative results. Cytochrome P-450, NADPH-cytochrome P-450 (cytochrome c) reductase activity and various phase-I and phase-II enzyme activities of the drug-metabolizing system were determined in incubation mixtures used in liver microsomal assays. The behaviour of aminopyrine N-demethylase and p-nitroanisole O-demethylase activities as phase-I markers have been reported previously. Other activities measured were glutathione S-transferase, glutathione S-epoxide transferase and epoxide hydrase, and lipid peroxidation (LP) was determined. The experiments were carried out on liver S9 fractions derived from non-induced mice or mice induced with sodium phenobarbital (PB), and/or beta-naphthoflavone (beta-NF). The phase-II enzymes were much more stable (70-90% residual activity) than phase-I enzyme activities (35-60%) in all conditions tested. The residual cytochrome P-450 was approximately 70% stable and the remaining activity of NADPH-cytochrome c-reductase about 80%, indicating that this latter enzyme does not limit the rate of the monoxygenase system in these conditions. Phase-II enzymes were induced to a smaller extent (about 2 times) than in phase-I enzymes (5-6 times) by beta-NF + PB. NADPH-cytochrome c-reductase behaved as phase-II enzymes in this respect as well as for stability. LP was appreciably higher in non-induced than in induced animals. Treatment with the beta-NF + PB mixture, however, showed that induced enzymes were more stable than those obtained by simple induction with either beta-NF or PB alone. These results lead to the conclusion that prolonged incubation times in mutagenicity assays are unnecessary when considering the relative stabilities of the various phase-I and phase-II enzyme activities in the drug-metabolizing system.

The effect of tridiphane (2-(3,5-dichlorophenyl)-2-(2,2,2-trichloroethyl)oxirane) on hepatic epoxide-metabolizing enzymes: indications of peroxisome proliferation

Administration of tridiphane (Tandem, DOWCO 356, 2-(3,5-dichlorophenyl)-2-(2,2,2-trichloroethyl)oxirane) to male Swiss-Webster mice for 3 days at 100, 250, and 500 mg/kg (ip) resulted in increases in liver weight accompanied by an increase in mitotic index and increases in large particle and microsomal protein. Epoxide hydrolase (EH) activity towards cis-stilbene oxide (CSO, microsomal EH) was elevated in microsomes and cytosol, a decrease in microsomal cholesterol EH was found, and hydrolysis of trans-stilbene oxide (TSO, cytosolic EH) was elevated in the cytosol but not in the microsomes. Glutathione S-transferase (GST) activity was elevated in cytosol for CSO, TSO, and 1,2-dichloro-4-nitrobenzene (DCNB), with inconsistent responses found with 1-chloro-2,4-dinitrobenzene (CDNB) and 1,2-epoxy-3-(p-nitrophenoxy)propane (ENPP). Microsomal GST was not consistently effected by tridiphane. Clofibrate (500 mg/kg, 3 daily ip injections) treatment resulted in similar responses in liver size, microsomal protein, and the EHs. The increase in cytosolic EH activity previously has been noted only in animals treated with peroxisome proliferators. Examination of livers from mice treated with 250 mg/kg tridiphane revealed that an increase in hepatic peroxisomes was apparent after 3 days of treatment. This was accompanied by decreases in serum cholesterol and triglyceride levels and increases in liver carnitine acetyl transferase and cyanide-insensitive oxidation of palmitoyl-CoA. This study demonstrates that tridiphane does have in vivo effects on mammalian epoxide-metabolizing enzymes and extends the association of increased cytosolic epoxide hydrolase activity with peroxisome proliferation.

A new enzyme immunoassay of microsomal rat liver epoxide hydrolase

Antiserum against purified rat liver microsomal epoxide hydrolase was produced in the rabbit. We developed an enzyme-linked immunosorbent assay which is reliable with regard to its analytical criteria. The concentration of epoxide hydrolase was measured in liver microsomes of control rats and animals treated with F 1379 (250 mg/kg/day) for 5, 7, 14, and 21 days. This hypolipidemic drug was able to induce strong epoxide hydrolase activity and enhance protein concentration. The gradual increase in epoxide hydrolase concentration paralleled the increase of epoxide hydrolase activity, with stabilization occurring after the 14th until the 21st day of treatment.

Immunohistochemically demonstrated altered expression of cytochrome P-450 molecular forms and epoxide hydrolase in N-ethyl-N-hydroxyethylnitrosamine-induced rat kidney and liver lesions

A comparison of N-ethyl-N-hydroxyethylnistrosamine (EHEN)-induced preneoplastic and neoplastic lesions in the rat liver and kidney was made with respect to the expression of different drug metabolizing enzymes. Four cytochrome P-450 species (cyt. P-450 UT50, PB3a, MC1 and MC2) and microsomal epoxide hydrolase (mEHb) were investigated along with two glutathione S-transferase species (GST-P and A forms) earlier shown to be elevated in putative preneoplastic lesions in the liver and kidney, respectively. In contrast to the liver lesions, which showed clear decrease in all forms of cyt. P-450s and increase of mEHb, elevated levels of cyt. P-450 PB3a and, to a lesser extent, the other P-450 forms and early elevation to late decrease in mEHb characterized the renal tubular lesions. Thus opposite shift in enzyme phenotype was observed in carcinogen-induced focal lesions of the two organs. Variation in binding levels in the different nephron segments and zones of the liver acinus indicated physiological specialization with regard to the enzymes investigated and suggested that the altered phenotype of preneoplastic populations might be of adaptive significance.

DNA synthesis, mitotic index, drug-metabolising systems and cytogenetic analysis in regenerating rat liver. Comparison with bone marrow test after 'in vivo' treatment with cyclophosphamide

Rat-liver cells can be used to reveal "in vivo" clastogenic activity of indirect mutagens, provided that they are stimulated to divide by partial hepatectomy. In order to characterize the rat-liver metabolic capacity in such experimental conditions, several biochemical parameters were measured during the first 54-66 h of liver regeneration in Sprague-Dawley male rats, subjected to a partial hepatectomy. The levels of cytochrome P-450, the activities of styrene monooxygenase, epoxide hydrolase and glutathione-S-epoxide transferase were chosen as markers. All the enzymatic activities and the level of cytochrome P-450 decreased during the first 12 h after the hepatectomy to about 50% of the activities of the sham-operated rats considered as controls. Subsequent recovery of the metabolic capacity was not observed. DNA synthesis and the mitotic index were measured to find the most suitable time for metaphase analysis. DNA synthesis and the number of metaphases were maximal at, respectively, 22-25 and 28-31 h after partial removal of the liver. The sensitivity to clastogenic damage induced by "in vivo" treatment with cyclophosphamide (CPA) was assayed in regenerating liver cells by chromosome-aberration analysis. Different doses, ranging from 5 to 30 mg/kg b.w., were given i.p. to the rats 17 h before or 7 h after partial hepatectomy. Liver cells were collected 31 h after surgery. Clastogenic damage was greater when the drug was administered to the animals after the hepatectomy (24 h of exposure) than before (48 h of exposure). The sensitivity to CPA-induced damage was compared with a bone marrow cell test carried out on non-hepatectomized rats treated in the same way. The results indicated that in these conditions regenerating liver cells are more sensitive than bone marrow cells to the induction of chromosome aberrations by CPA.

Hepatic levels of cytosolic, microsomal and 'mitochondrial' epoxide hydrolases and other drug-metabolizing enzymes after treatment of mice with various xenobiotics and endogenous compounds

This study was performed in order to study the response of epoxide hydrolases in different subcellular compartments of mouse liver to treatment with various compounds. Male C57BL/6 mice were treated with 31 different compounds--including traditional inducers of xenobiotic-metabolizing systems, liver carcinogens, stilbene derivatives, endogenous compounds and various other drugs and xenobiotics. The effects on liver somatic index; protein contents in 'mitochondria', microsomes and cytosol prepared from the liver; epoxide hydrolase activity towards trans- or cis-stilbene oxide in these three fractions; microsomal cytochrome P-450 content; cytosolic and 'mitochondrial' glutathione transferase activity and cytosolic DT-diaphorase activity were then determined. Cytosolic epoxide hydrolase activity was induced by chlorinated paraffins, di(2-ethylhexyl)phthalate and clofibrate and depressed by alpha-naphthylisothiocyanate, 3-methylcholanthrene, benzil and quercitin. Radial immunodiffusion revealed similar changes in the amount of enzyme protein present, except for two cases, where the increase in amount was larger; and the enzyme seems to be inhibited by benzil. Microsomal epoxide hydrolase activity was induced by these same compounds and several others as well, including dibenzoylmethane, butylated hydroxyanisole and polychlorinated biphenyls. 'Mitochondrial' epoxide hydrolase activity towards trans-stilbene oxide was not affected by those compounds which induced the cytosolic enzyme, but increased about two-fold after treatment with 2-acetylaminofluorene, DL-ethionine, aflatoxin B1 and phenobarbital. There does not seem to be any co-regulation of different forms of epoxide hydrolase in mouse liver. In general small effects were observed on liver weight and protein contents in the different subcellular fractions. Polychlorinated biphenyls were the most potent of the 8 compounds which induced cytochrome P-450, while butylated hydroxyanisole induced cytosolic glutathione transferase activity to the highest extent. 'Mitochondrial' glutathione transferase activity was most induced by certain of the stilbene derivatives. The most potent inducers of DT-diaphorase activity were 3-methylcholanthrene, polychlorinated biphenyls and dinitrotoluene.

Immunochemical studies of microsomal membranes of rat preneoplastic and neoplastic hepatocytes

Heterogenous rabbit antisera were prepared against microsomal proteins of hyperplastic hepatic nodules (HPN) induced by chemicals, and were utilized to assess the antigenic differences of microsomal polypeptides within a normal liver, HPN, and hepatocellular carcinomas (HCC), utilizing immunodetection of antigens separated electrophoretically and transferred to nitrocellulose. Although most antigens were common to all microsomes, differences (increase or decrease) were noted in some polypeptides not only between the normal liver and HPN, but also between HPN and HCC. On the other hand, monoclonal antibodies against epoxide hydrolase (EH), which was initially found as the PN antigen, reacted to a single polypeptide with a molecular weight of 49,000 in all the microsomes. These results suggested that there is little molecular modification of EH during hepatic carcinogenesis.

Immunochemical characterization of human lung epoxide hydrolases

Immunochemical techniques were used to investigate the biochemical properties of human lung epoxide hydrolases. Two epoxide hydrolases with different immunoreactive properties were identified. These two epoxide hydrolases were found in both cytosolic and microsomal cell fractions. Immunotitration of enzyme activity showed that enzymes that catalyze the hydration of benzo(a)pyrene 4,5-oxide react with antiserum to rat microsomal epoxide hydrolase; those that hydrate trans-stilbene oxide do not. Immunotitration and Western blot experiments showed that microsomal and cytosolic benzo(a)pyrene 4,5-oxide hydrolases have significant structural homology. Immunohistochemical staining of human lung benzo(a)pyrene 4,5-oxide hydrolase showed that the enzyme is localized primarily in the bronchial epithelium. No cell type-specific localization was observed. An enzyme-linked immunosorbent assay was developed which allows direct quantitation of benzo(a)pyrene 4,5-oxide hydrolase protein. Levels of enzyme protein detected by this assay correlated well with enzyme levels determined by substrate conversion assays.

Characterization of multiple epoxide hydrolase activities in mouse liver nuclear envelope

A nuclear envelope-associated epoxide hydrolase in mouse liver that hydrates trans-stilbene oxide has been identified and characterized. This epoxide hydrolase is distinct from the enzyme in nuclear envelopes that hydrates benzo[a]pyrene 4,5-oxide and other arene oxides. This distinction was demonstrated by the criteria of pH optima, response to specific inhibitors in vitro, and precipitation by specific antibodies. The new epoxide hydrolase had a pH optimum of 6.8, was poorly inhibited by trichloropropene oxide, was potently inhibited by 4-phenylchalcone oxide, and did not bind to antiserum against benzo[a]pyrene 4,5-oxide hydrolase. This nuclear enzyme is similar in many of its properties to cytosolic and microsomal trans-stilbene oxide hydrolases and may be nuclear envelope-bound form of these other epoxide hydrolases. It differed from these other trans-stilbene oxide hydrolases in that its affinities for both trans-stilbene oxide (measured as apparent Km) and 4-phenylchalcone oxide (measured as I50) were 4- to 20-fold lower than those of either the cytosolic or microsomal forms.

Distribution and inducibility of cytosolic epoxide hydrolase in male Sprague-Dawley rats

Cytosolic epoxide hydrolase (cEH) activity has been determined in liver and various extrahepatic tissues of male Sprague-Dawley rats using trans-stilbene oxide (TSO) and trans-ethylstyrene oxide (TESO) as substrates. Large interindividual differences in the specific activity of cytosolic epoxide hydrolase in the liver from more than 80 individual rats were observed varying by a factor of 38. In a randomly selected group of five animals liver cEH varied by a factor of 3.9 and kidney cEH by a factor of 2.7, whereas liver microsomal epoxide hydrolase and lactate dehydrogenase showed only very low variations (1.4- and 1.1-fold, respectively). The individual relative activity of kidney cEH was related to that of the liver. Cytosolic epoxide hydrolase activity was present in all of six extrahepatic rat tissues investigated. Interestingly specific activities were very high in the heart and kidney (higher than in liver), followed by liver greater than brain greater than lung greater than testis greater than spleen. TSO and TESO hydrolases in subcellular fractions of rat liver were present at highest specific activities in the cytosolic and the heavy mitochondrial fraction. As indicated by the marker enzymes, catalase, urate oxidase and cytochrome oxidase, this organelle-bound epoxide hydrolase activity may be of peroxisomal and/or mitochondrial origin. In the microsomal fraction, TSO and TESO hydrolase activity is very low, whereas STO hydrolase activity is highest in this fraction and very low in cytosol. In kidney, subcellular distribution is similar to that observed in liver. None of the commonly used inducers of xenobiotic metabolizing enzymes caused significant changes in the specific activities of rat hepatic cEH (trans-stilbene oxide, alpha-pregnenolone carbonitrile, 3-methylcholanthrene, beta-naphthoflavone, isosafrole, butylated hydroxytoluene, 2,3,7,8-tetrachlorodibenzo-p-dioxin, dibenzo[a,h]anthracene, phenobarbitone). However, clofibrate, a hypolipidemic agent, very strongly induced rat liver cEH (about 5-fold), whereas microsomal epoxide hydrolase activity was not affected. Specific activity of kidney cEH was increased about 2-fold.

Xenobiotic metabolism in human alveolar type II cells isolated by centrifugal elutriation and density gradient centrifugation

Alveolar type II cells were isolated from five human lung specimens obtained during resection or lobectomy and enriched to 63-85% purity. Digestion with Sigma protease type XIV followed by centrifugal elutriation and Percoll density gradient centrifugation yielded 1.2 +/- 0.4 X 10(6) cells/g lung in the type II cell fractions. The activities of some enzymes involved in the metabolism of xenobiotics were determined in these freshly isolated type II cells and compared with activities in alveolar macrophages and fractions of unseparated cells from the same tissue samples. Reduced nicotinamide adenine dinucleotide phosphate-cytochrome c reductase activity was similar in the three cell fractions from all five patients (18-29 nmol/mg protein/min). An antibody to rabbit reduced nicotinamide adenine dinucleotide phosphate-cytochrome P-450 reductase inhibited reduced nicotinamide adenine dinucleotide phosphate-cytochrome c reduction as much as 70% in microsomal preparations of the isolated human pulmonary cells, although this same antibody barely reacted with microsomes of the human cells in a Western blot assay. Epoxide hydrolase activity was highest in the alveolar type II cells (1.08 +/- 0.17 nmol/mg protein/min). This activity was 6 times higher than in the alveolar macrophage or unseparated cell fractions. 7-Ethoxycoumarin deethylase activity, a cytochrome P-450-dependent pathway, was low or undetectable in the three cell fractions. Trace amounts of 7-ethoxyresorufin O-deethylase activity (0.5-1.5 pmol/mg protein/min) were detected in microsomes of the isolated human cells, even though a polycyclic hydrocarbon-inducible cytochrome P-450 which metabolizes 7-ethoxyresorufin (form 6 in rabbits) was not detected immunochemically.

The effects of metyrapone, chalcone epoxide, benzil, clotrimazole and related compounds on the activity of microsomal epoxide hydrolase in situ, in purified form and in reconstituted systems towards different substrates

The influence of metyrapone, chalcone epoxide, benzil and clotrimazole on the activity of microsomal epoxide hydrolase towards styrene oxide, benzo[a]pyrene 4,5-oxide, estroxide and androstene oxide was investigated. The studies were performed using liver microsomes from rats, rabbits, mice and humans; epoxide hydrolase purified from rat liver microsomes to apparent homogeneity; and the purified enzyme incorporated into liposomes composed of egg-yolk phosphatidylcholine or total rat liver microsomal lipids. All four effectors were found to activate the hydrolysis of styrene oxide by epoxide hydrolase in situ in rat liver microsomal membranes, in agreement with earlier findings. Epoxide hydrolase activity towards styrene oxide in liver microsomes from mouse, rabbit and man was also increased by all four effectors. The most striking effect was a 680% activation by clotrimazole in rat liver microsomes. However, none of the effectors activated microsomal epoxide hydrolase more than 50% when benzo[a]pyrene 4,5-oxide, estroxide or androstene oxide was used as substrate. Indeed, clotrimazole was found to inhibit microsomal epoxide hydrolase activity towards estroxide 30-50% and towards androstene oxide 60-90%. The effects of these four compounds were found to be virtually identical in the preparations from rats, rabbits, mice and humans. The effects of metyrapone, chalcone epoxide, benzil and clotrimazole on purified epoxide hydrolase were qualitatively the same as those on epoxide hydrolase in intact microsomes, but much smaller in magnitude. These effects were increased in magnitude only slightly by incorporation of the purified enzyme into liposomes made from egg-yolk phosphatidylcholine. However, when incorporation into liposomes composed of total microsomal lipids was performed, the effects seen were essentially of the same magnitude as with intact microsomes. When the extent of activation was plotted against effector concentration, three different patterns were found with different effectors. Activation of epoxide hydrolase activity towards styrene oxide by clotrimazole was found to be uncompetitive with the substrate and highly structure specific. On the other hand, inhibition of epoxide hydrolase activity towards androstene oxide by clotrimazole was found to be competitive in microsomes. It is concluded that the marked effects of these four modulators on microsomal epoxide hydrolase activity are due to an interaction with the enzyme protein itself, but that the presence of total microsomal phospholipids allows the maximal expression leading to similar degrees of modulation as those observed in intact microsomes.(ABSTRACT TRUNCATED AT 400 WORDS)

Pyruvate kinase isoenzymes in altered foci and carcinoma of rat liver

Pyruvate kinase (PK) isoenzymes, rate limiting for the last steps of glycolysis, were studied in normal rat liver, putative preneoplastic foci, neoplastic nodules and hepatocellular carcinoma. These lesions were produced by an initiation-promotion protocol: treatment with a single dose of N-nitrosomorpholine (NNM) was followed by feeding diets containing phenobarbital (PB) or alpha-hexachlorocyclohexane (alpha-HCH), or basal diet. PK was demonstrated (i) by immunocytochemistry on histological sections with antibodies specifically directed against the L and M2 isoenzymes, (ii) by electrophoretic separation of isoenzymes in homogenates from liver and larger tumors, and (iii) by electrophoretic separation of isoenzymes in parenchymal and stromal cells isolated from liver and tumors. Immunocytochemistry showed decreases of L-PK (L-PK-) in hepatocytes of most of the foci, nodules and carcinomas. Most L-PK- foci showed increases in gamma-glutamyltransferase (gamma-GT) and epoxide hydrolase (EH). PB or alpha-HCH treatment further decreased expression of L-PK in foci, but not in normal liver. Cells and foci with enhanced L-PK (L-PK+) were also found after carcinogen treatment. These did not show increases of gamma-GT or EH or any distinct morphological alterations with the exception of some which were basophilic ('tigroid') in H and E stained sections. No L-PK+ tumors were found. We could not demonstrate the M2-type PK in parenchymal cells of liver or any of the lesions described above. This isoenzyme was restricted to stromal cells in normal rat liver and in all stages of carcinogenesis as shown by immunohistology and by electrophoresis of preparations from isolated cell populations. However, stromal cells from hepatocellular carcinomas exhibited a 3-fold increase of M2-PK compared with stromal cells from normal liver. These results do not support an isoenzyme shift from L to M2-PK in the course of malignant transformation of hepatocytes as suggested previously.

The effect of dietary lipids and antioxidants on the activity of epoxide hydratase in the rat liver and intestine

The effect of varying the fatty acid composition of the lipid components of the diet on the activity of epoxide hydratase in the rat liver and intestinal mucosa has been studied. Feeding a 10% cod liver oil diet (containing 18% C20:5 and 11% C22:6) resulted in a 3-fold increase in epoxide hydratase activity in the liver and a 1.6-fold increase in the intestine compared to rats fed a fat-free diet. The activity of epoxide hydratase in rats fed a cod liver oil diet was significantly greater than that for the group fed a lard diet (containing mainly saturated and mono-unsaturated fatty acids) containing the same quantity of vitamin E. Thus, the enhancing effect of the cod liver oil diet was due to the polyunsaturated fatty acids in this oil. Dietary corn oil (58% C18:2) also stimulated epoxide hydratase activity in the liver but not in the intestine. Vitamin E levels of up to 500 mg/kg diet were ineffective at inducing epoxide hydratase activity in both the liver and intestine. Significant changes in the fatty acid composition of hepatic and intestinal microsomes took place when rats were fed diets of different fatty acid composition. These changes were such that the proportions of polyunsaturated fatty acids in the microsomal fractions reflected the amounts of these fatty acids in the dietary fat. Hepatic epoxide hydratase activity was found to be positively correlated to the proportion of polyunsaturated fatty acids in the microsomal fractions of the liver.

Xenobiotic metabolizing enzymes in genetically and chemically initiated mouse liver tumors

Chemically induced rat liver nodules and cancers characteristically demonstrate a limited capacity to activate xenobiotics to reactive species mainly because of decreased amounts of cytochrome P-450. These lesions also show enhancement of xenobiotic detoxication by such mechanisms as enzymic conjugation or reduction of cytotoxic species. We recently demonstrated a similar pattern of metabolic alteration in spontaneous mouse liver tumors. These findings suggested that certain phenotypic alterations attributed to chronic chemical exposure are inherent in the genetic program for carcinogenesis, and that they may arise independently of chronic exposure. To extend that study, we examined spontaneous and diethylnitrosamine-induced mouse liver tumors for nine enzyme activities commonly reported to be altered in chemically induced rat liver nodules and cancers. The activities of benzo(a)pyrene monooxygenase (EC 1.14.14.1), aminopyrene demethylase, cytochrome P-450 reductase, epoxide hydrolase (EC 3.3.2.3), and UDPglucuronosyl transferase (EC 2.4.1.17) in microsomes from spontaneous tumors relative to those from normal liver were 0.25, 0.43, 1.27, 0.90, and 0.51, respectively. Similar values were obtained with microsomes from chemically induced tumors. The activities of DT-diaphorase (EC 1.6.99.2), glutathione reductase (EC 1.6.4.2), glutathione S-transferase (EC 2.5.1.18), and glutathione peroxidase (EC 1.11.1.9) in cytosol from spontaneous tumors relative to cytosol from normal liver were 2.24, 2.0, 2.43, and 0.31, respectively. Similar values were obtained with cytosol from chemically induced tumors. These results demonstrated that a significant portion of the enzymic phenotype observed in chemically induced rat liver nodules and cancers, which may confer resistance to cytotoxic chemicals, is manifest in spontaneous and chemically induced mouse liver tumors. Further, initiated cells that exhibit this phenotype replicated and progressed in the absence of continued chemical selection.

Preferential binding of the carcinogen benzo[a]pyrene to DNA in active chromatin and the nuclear matrix

Rat liver nuclei or hepatocytes were incubated with the proximate carcinogen, benzo[a]pyrene (BP) and its ultimate carcinogen, anti-benzo[a]pyrene-7,8-diol-9,10-epoxide (BPDE). Following carcinogen exposure, nuclei were fractionated by micrococcal nuclease digestion and stepwise extraction to yield an active chromatin fraction enriched in transcribed versus non-transcribed genes, a bulk chromatin fraction, a high-salt-extracted chromatin fraction and a nuclear matrix fraction containing elevated concentrations of transcribed and nontranscribed genes. BP binds more readily to DNA of active chromatin and nuclear matrix than to bulk chromatin. Since low concentrations of BPDE also selectively damage active chromatin and matrix DNA, selectivity is not due to the subnuclear location of enzymes which activate BP to BPDE. Higher BPDE concentrations cause more uniform DNA damage. Selective carcinogen attack may result from an accessible DNA conformation in active chromatin and matrix or from partitioning of carcinogen in the nuclear membrane.

Loss of cytochrome P-450 from hepatic nuclear membranes of rats fed 2-acetylaminofluorene

The cytochrome P-450 content of nuclear membranes isolated from the livers of male Sprague-Dawley rats fed a semipurified diet containing 0.05% w/w 2-acetylaminofluorene (AAF) for 3 weeks, was only about 20% of the values in control rats fed the same diet devoid of AAF. This effect was apparent after only 1 week of AAF treatment and persisted in nuclear membranes from isolated hyperplastic nodules (HPN) generated by 4 cycles of interrupted AAF-feeding. The microsomal cytochrome P-450 content, on the other hand, remained at control levels after 1 week of AAF treatment, and it was only slightly decreased after 3 weeks. In contrast, microsomes from HPN generated by prolonged AAF treatment had markedly decreased amounts of cytochrome P-450. The AAF treatment also caused changes in cholesterol epoxide hydrolase activity, which paralleled those observed for cytochrome P-450 content. Nuclear membranes from livers of rats fed AAF for 3 weeks, and from isolated HPN, had only 30-50% of the cholesterol epoxide hydrolase activity present in controls, whereas the microsomal enzyme activity remained at control levels after 3 weeks of AAF feeding but was 50% depressed in microsomes from HPN. The selective loss of cytochrome P-450 and of cholesterol epoxide hydrolase in hepatic nuclear membrane, but not in microsomes, of rats fed AAF for 3 weeks suggests independent control for these enzymes in these two membrane fractions. Cytochrome P-450 plays a role both in the activation of AAF (N-hydroxylation) as well as in its detoxification (ring hydroxylation) whereas cholesterol epoxide hydrolase initiates the detoxification of cholesterol epoxide. Therefore, our findings suggest the hypothesis that AAF treatment causes an early loss, at the surface of the nucleus, of the last line of defense for detoxification of transforming or promoting metabolites generated by microsomal activation of natural substances such as cholesterol and of xenobiotics such as AAF.

Distribution and nature of epoxide hydrolase activity in subcellular organelles of mouse liver

Mouse liver light and heavy mitochondrial fractions contain significant epoxide hydrolase activity in addition to that present in the cytosol and microsomes. As the mitochondrial fraction itself contains a number of subfractions, experiments were designed to determine the localization of the epoxide hydrolase activity in these subfractions. Subcellular fractions were prepared using livers from 6- to 8-week-old Swiss-Webster male mice. Using trans-stilbene oxide (TSO) as substrate, the highest activity was localized in the cytosolic fraction, followed by the light mitochondrial fraction. Subfractionation of the light mitochondrial fraction by isopycnic sucrose density gradient resulted in the separation of mitochondria from peroxisomes as monitored by marker enzymes. The separation of these two subcellular organelles was also confirmed by the electron microscopic studies. Distribution of TSO-hydrolase activity in the sucrose density gradient fractions closely resembled the activity distribution of the peroxisomal markers catalase and urate oxidase, but significant activity was also found in mitochondria. Treatment of mice with clofibrate selectively induced TSO-hydrolase in the cytosol without affecting this enzyme activity in the peroxisomal fraction. There was no difference in the distribution pattern of TSO-hydrolase and marker enzymes in sucrose density gradients of mitochondrial fractions from clofibrate-treated and control mice. The epoxide hydrolase activity in the peroxisomes is immunologically similar to, and also has the same molecular weight as, the cytosolic epoxide hydrolase.

[Spectrofluorimetric method of determining epoxide hydrolase]

A spectrofluorometric procedure is developed for estimation of epoxide hydrolase activity using styrol oxide as a substrate. The data were plotted, reflecting the dependence of the enzymatic reaction on time, pH value and the substrate concentration. Activity of epoxide hydrolase was studied in various tissues and subcellular fractions of rat liver tissue.

Glucuronidation of 1-naphthol in nuclear and microsomal fractions of the human intestine

The glucuronyl transferase activity was measured with 1-naphthol as a substrate in nuclear and microsomal fractions of the human intestinal mucosa. The mucosa was obtained from different parts of the intestine. The rate of 1-naphthol glucuronidation ranged between 0.70 and 1.26 nmol/mg/min (nuclear fraction) and 0.21 and 0.54 nmol/mg/min (microsomal fraction). The average (+/- SEM) of the nuclear/microsomal ratios of the glucuronyl transferase was 2.48 +/- 0.19. The epoxide hydrolase activity towards styrene oxide was measured in the same subcellular fractions; it was undetectable in the nuclear fraction, whereas it was 0.46 +/- 0.04 nmol/mg/min (mean +/- SEM) in the microsomal fraction. The glucuronyl transferase activity was also measured in nuclear and microsomal fractions of the human liver. The activity (mean +/- SEM) was 1.14 +/- 0.21 nmol/mg/min (nuclei) and 5.00 +/- 0.80 (microsomes). The average of the nuclear to microsomal ratios (mean +/- SEM) was 0.32 +/- 0.03.

The regulation of cytosolic epoxide hydrolase in mice

The concentration of cytosolic epoxide hydrolase in untreated and clofibrate-treated mouse liver extracts was estimated by immunoblotting. Clofibrate treatment of mice was found to increase liver cytosolic epoxide hydrolase concentration by two fold, showing that the increase in cytosolic epoxide hydrolase in mouse liver after clofibrate treatment is primarily due to induction. The induced and uninduced cytosolic epoxide hydrolase, and epoxide hydrolase in the cytosolic and mitochondrial fractions were compared and found to be identical or very similar. Cytosolic epoxide hydrolases in kidney and liver were similar in molecular weight and antigenic properties.

Epoxide hydrolase is a marker for the smooth endoplasmic reticulum in rat liver

Epoxide hydrolase (EH, EC 3.3.2.3) was chosen as a potential marker for smooth endoplasmic reticulum, because this enzyme is inducible by drugs such as phenobarbital. The hypothesis was verified in rat liver using immunochemical and immunocytochemical techniques. Antibodies were raised to the purified protein. These antibodies were affinity purified using the enzyme immobilized on Sepharose Ultrogel. The specificity of the antibodies was assayed by immunoelectrotransfer (Western blot). The labelling of rat liver thin frozen sections with protein A-gold particles demonstrated that the antibodies specifically recognised smooth endoplasmic reticulum membranes. Rough endoplasmic reticulum, other intracellular organelles and plasma membrane were unlabelled.