palmitoyl-CoA Oxidase Research Articles

Human HepG2 and Rat Fao Hepatic-Derived Cell Lines Show Different Responses to Ciprofibrate, a Peroxisome Proliferator: Analysis by Flow Cytometry

Peroxisome proliferators, and especially hypolipidemic drugs such as ciprofibrate, are known to be hepatocarcinogens in rodents, but their effect in humans is controversial. In an attempt to investigate the effects of ciprofibrate at a cellular level, the analysis of individual whole cells was performed by flow cytometry on samples from two hepatic-derived cell lines: the rat Fao cell line and the human HepG2 cell line. The increase of light scatter signals in rat Fao cells treated for 3 days with ciprofibrate at 250 μMwas related to modifications of intrinsic cellular parameters, such as size and cytoplasmic granularity. Conversely, no variations appeared in human HepG2-treated cells. Moreover, the study of the cell cycle distribution of asynchronously growing cells showed an increase in the percentage of proliferative cells in Fao-treated cells, but not in HepG2-treated cells. In order to give a simultaneous assessment of changes in cellular parameters and cell metabolism, these flow cytometric experiments were completed with the measurements of the palmitoyl–CoA oxidase activity, used as a marker of peroxisome proliferation. The cellular modifications in the rat Fao cell line were accompanied by a great increase in this enzymatic activity, whereas the human HepG2 cell line, which failed to exhibit changes of cytometric data, presented no, or weak, increase in this oxidase activity. The cellular modifications observed in the rat Fao cell line may be related to the well-known hepatocarcinogenicity of ciprofibrate in rodents, whereas the absence of response of HepG2 cells is in favor of the noncarcinogenicity of this drug in humans. This report validates another methodological approach for the investigation of the safety of peroxisome proliferators in humans.

Difference between Guinea Pig and Rat in the Liver Peroxisomal Response to Equivalent Plasmatic Level of Ciprofibrate

Guinea pig was previously classified as a species nonresponsive to peroxisome proliferators. However, none of the previous reports was based on pharmacokinetic data. Here, after a comparative pharmacokinetic study between guinea pig and rat, we evaluate the guinea pig liver peroxisomal response to ciprofibrate, a hypolipemic agent and a potent peroxisome proliferator in rat. (1) Pharmacokinetic results show that plasmatic concentrations of ciprofibrate are equivalent in guinea pig and rat when guinea pigs are treated with ciprofibrate at 30 mg/kg twice a day and rats are treated at 3 mg/kg once a day. (2) The treatment of guinea pigs at 30 mg/kg twice a day for 2 weeks leads to a significant increase in the liver peroxisomal palmitoyl-CoA oxidase activity (×1.6) and also in the microsomal ω-laurate hydroxylase activity (×1.8). These increases are in accordance with the changes in polypeptide patterns of isolated liver peroxisomes as well as in the immunoblotting of acyl-CoA oxidase. It is deduced that a weak, but significant, peroxisome proliferation can occur in guinea pig liver after a ciprofibrate treatment at dosages corresponding to equivalent plasmatic concentrations of the drug between guinea pig and rat. (3) The hybridization of guinea pig liver RNA with the rat liver-inducible acyl-CoA oxidase cDNA probe shows a decrease in the corresponding heterologuous mRNA content after treatment with ciprofibrate at 30 mg/kg twice a day. This result contrasts with the slight increase observed in immunodetection and in enzymatic assays, suggesting the existence of at least two different acyl-CoA oxidases in guinea pig liver peroxisomes.

L-Lactate Dehydrogenase A4- and A3B Isoforms Are Bona Fide Peroxisomal Enzymes in Rat Liver: EVIDENCE FOR INVOLVEMENT IN INTRAPEROXISOMAL NADH REOXIDATION

The subcellular localization of l-lactate dehydrogenase (LDH) in rat hepatocytes has been studied by analytical subcellular fractionation combined with the immunodetection of LDH in isolated subcellular fractions and liver sections by immunoblotting and immunoelectron microscopy. The results clearly demonstrate the presence of LDH in the matrix of peroxisomes in addition to the cytosol. Both cytosolic and peroxisomal LDH subunits have the same molecular mass (35.0 kDa) and show comparable cross-reactivity with an anti-cytosolic LDH antibody. As revealed by activity staining or immunoblotting after isoelectric focussing, both intracellular compartments contain the same liver-specific LDH-isoforms (LDH-A4 > LDH-A3B) with the peroxisomes comprising relatively more LDH-A3B than the cytosol. Selective KCl extraction as well as resistance to proteinase K and immunoelectron microscopy revealed that at least 80% of the LDH activity measured in highly purified peroxisomal fractions is due to LDH as a bona fide peroxisomal matrix enzyme. In combination with the data of cell fractionation, this implies that at least 0.5% of the total LDH activity in hepatocytes is present in peroxisomes. Since no other enzymes of the glycolytic pathway (such as phosphoglucomutase, phosphoglucoisomerase, and glyceraldehyde-3-phosphate dehydrogenase) were found in highly purified peroxisomal fractions, it does not seem that LDH in peroxisomes participates in glycolysis. Instead, the marked elevation of LDH in peroxisomes of rats treated with the hypolipidemic drug bezafibrate, concomitantly to the induction of the peroxisomal beta-oxidation enzymes, strongly suggests that intraperoxisomal LDH may be involved in the reoxidation of NADH generated by the beta-oxidation pathway. The interaction of LDH and the peroxisomal palmitoyl-CoA beta-oxidation system could be verified in a modified beta-oxidation assay by adding increasing amounts of pyruvate to the standard assay mixture and recording the change of NADH production rates. A dose-dependent decrease of NADH produced was simulated with the lowest NADH value found at maximal LDH activity. The addition of oxamic acid, a specific inhibitor of LDH, to the system or inhibition of LDH by high pyruvate levels (up to 20 mm) restored the NADH values to control levels. A direct effect of pyruvate on palmitoyl-CoA oxidase and enoyl-CoA hydratase was excluded by measuring those enzymes individually in separate assays. An LDH-based shuttle across the peroxisomal membrane should provide an efficient system to regulate intraperoxisomal NAD+/NADH levels and maintain the flux of fatty acids through the peroxisomal beta-oxidation spiral.

Induction of peroxisomal beta-oxidation and P-450 4A-dependent activities by pivalic and trichloroacetic acid in rat liver and kidney.

The influence of pivalic acid (PIV), a compound often used to make pro-drugs, and of the structurally related trichloroacetic acid (TCA), on several hepatic and renal enzymes was investigated in Sprague-Dawley rats, following a 4-day treatment period. The PIV and TCA treatments resulted in a similar and selective induction (2-3 times) of peroxisomal palmitoyl-CoA oxidase and the cytochrome P-450 4A dependent microsomal (omega)- and (omega-1)-lauric acid activities, both in liver and kidney. Western blot analysis of liver and kidney microsomes from PIV- and TCA-treated rats, using antibody to the P-450 4A1, revealed induction of members of the P-450 4A subfamily. These results suggest that PIV, like TCA, is a renal and hepatic peroxisome proliferator in rats, and further support the previously indicated close association between the peroxisomal fatty acid beta-oxidation enzymes and microsomal P-450 4A sub-family enzymes.

Assignment of the human peroxisomal palmitoyl-CoA oxidase gene to chromosome 17q23-qter by PCR technique.

Human peroxisomal palmitoyl-CoA oxidase plays a pivotal role in the beta-oxidation of fatty acids. Its importance is reflected by the severity of the disease associated with its deficiency in man. The gene was previously mapped to chromosome 17q25 with a FISH technique and is now confirmed using a PCR technique.

Overexpression and Characterization of the Human Peroxisomal Acyl-CoA Oxidase in Insect Cells

Human liver peroxisomes contain two acyl-CoA oxidases, namely, palmitoyl-CoA oxidase and a branched chain acyl-CoA oxidase. The palmitoyl-CoA oxidase (ACOX) oxidizes the CoA esters of straight chain fatty acids and prostaglandins and donates electrons directly to molecular oxygen, thereby producing H2O2. The inducibility of this H2O2-generating ACOX in rat and mouse liver by peroxisome proliferators and the postulated role of the resulting oxidative stress in hepatocarcinogenesis generated interest in characterizing the structure and function of human ACOX. We have constructed a full-length cDNA encoding a 660-amino acid residue human ACOX and produced a catalytically active human ACOX protein at high levels in Spodoptera frugiperda (Sf9) insect cells using the baculovirus vector. Immunoblot analysis demonstrated that the full-length 72-kDa polypeptide (component A) was partially processed into its constituent 51-kDa (component B) and 21-kDa (component C) products, respectively. Recombinant protein (approximately 20 mg/l x 10(9) cells) was purified to homogeneity by a single-step procedure on a nickel-nitrilo-triacetic acid affinity column. Using the purified enzyme, Km and Vmax values for palmitoyl-CoA were found to be 10 microM and 1.4 units/mg of protein, respectively. The maximal activities for saturated fatty acids were observed with C12-18 substrates. The overexpressed human ACOX protein was identified in the cytoplasm of the insect cells by immunocytochemical staining. Individual expression of either the truncated ACOX 51-kDa (component B) or the 21-kDa (component C) revealed lack of enzyme activity, but co-infection of the insect cells with recombinant viruses expressing components B and C resulted in the formation of an enzymatically active heterodimeric B+C complex which could subsequently be inactivated by dissociating with detergent.

Modification of lipoperoxidative effects of dichloroacetate and trichloroacetate is associated with peroxisome proliferation

Pretreatment of male B6C3F 1 mice with clofibric acid (CFA) or trichloroacetic acid (TCA) in the drinking water results in a marked decrease in the lipoperoxidative response as measured by the production of thiobarbituric acid reactive substances (TBARS) in mouse liver homogenates following acute dosing with TCA or dichloroacetic acid (DCA). Pretreatment with TCA or CFA also increased palmitoyl-CoA oxidase activity, microsomal 12-(ω) hydroxylation of lauric acid and expression of P450 4A isoforms. At the doses utilized, DCA-pretreatment did not increase the level of P450 4A protein, or markers of peroxisome proliferation. However, DCA-pretreatment did result in enhanced levels of TBARS, following acute dosing with DCA, compared to controls. Pretreatment with DCA, TCA, or CFA did not alter p-nitrophenol hydroxylation (an assay specific for P450 2E1), and no increases in immunodetectable P450 2E1, 4A, 1A1/2, 2B1/2 or 3A1 protein were observed. Assays from CFA- and TCA-pretreated mice suggest that the reduction in the TBARS response seen in TCA-pretreated animals results from activities associated with peroxisome proliferation. This might result from the induction of systems efficient in scavenging of peroxide intermediates or detoxification of aldehyde by-products of lipid peroxidation.

Peroxisomal beta-oxidation. Purification of four novel 3-hydroxyacyl-CoA dehydrogenases from rat liver peroxisomes.

Peroxisomes are capable of beta-oxidizing a variety of substrates including the CoA esters of straight chain fatty acids, 2-methyl-branched fatty acids and the bile acid intermediates di- and trihydroxycoprostanic acids. The first reaction of peroxisomal beta-oxidation is catalyzed by an acyl-CoA oxidase. Rat liver peroxisomes contain three acyl-CoA oxidases: 1) palmitoyl-CoA oxidase, oxidizing straight chain acyl-CoAs; 2) pristanoyl-CoA oxidase, oxidizing 2-methyl-branched acyl-CoAs; and 3) trihydroxycoprostanoyl-CoA oxidase, oxidizing the CoA esters of the bile acid intermediates (Van Veldhoven, P.P., Vanhove, G., Asselberghs, S., Eyssen, H. J., and Mannaerts, G. P. (1992) J. Biol. Chem. 267, 20065-20074). We have now investigated whether the third step of peroxisomal beta-oxidation, catalyzed by a 3-hydroxyacyl-CoA dehydrogenase, is also catalyzed by multiple enzymes, using the 3-hydroxyacyl-CoA derivatives of palmitic acid, 2-methylpalmitic acid, and trihydroxycoprostanic acid as the substrates to monitor the dehydrogenase activities. In order to avoid contamination with mitochondrial 3-hydroxyacyl-CoA dehydrogenases, highly purified peroxisomes from untreated rats were employed as the enzyme source. Subfractionation of the peroxisomes revealed that the major portion of the dehydrogenase activities with all three substrates was present in the peripheral membrane protein fraction. Separation of this fraction on various chromatographic columns resulted in the purification of the well known multifunctional protein, a 78-kDa monomeric protein that displays 3-hydroxyacyl-CoA dehydrogenase plus hydratase activity, as well as of four additional novel dehydrogenases with different substrate specificities. Three of the enzymes are monomeric proteins of 35 kDa, 56 kDa, and 79 kDa, respectively. The latter enzyme also displays hydratase activity. The fourth enzyme is a dimer of 89 kDa, the subunits of which form a doublet at 40 kDa. The exact physiological role of each of the 3-hydroxyacyl-CoA dehydrogenases requires further investigation.

Evaluation of Oxidative Processes in Human Pigment Epithelial Cells Associated with Retinal Outer Segment Phagocytosis

To investigate the nature of the oxidative event that occurs during phagocytosis of retinal outer segments (ROS) by cultured human retinal pigment epithelial (RPE) cells, cells were incubated with isolated bovine ROS labeled with either the fluorescent probe carboxy-SNAFL-2 or the nonfluorescent, oxidizable probe 2′,7′dichlorodihydrofluorescein (H2DCF). The increase in fluorescence following phagocytosis was measured by a flow cytometer. Other measurements included: oxygen consumption using a Clark-type oxygen electrode, extracellular superoxide release by superoxide dismutase inhibitable lucigenin chemiluminescence, intracellular hydrogen peroxide (H2O2) production, and the effect of catalase inhibition on cellular thiobarbituric acid-reactive substances (TBARS) caused by phagocytosis. The activities of the enzymes NADPH oxidase and palmitoyl-CoA oxidase were also measured. H2DCF attached to bovine ROS was oxidized during phagocytosis with a time course suggesting oxidation subsequent to ROS uptake. Measurements of oxygen consumption showed a time-dependent increase of 10%, 4 h after ROS feeding, attributable to a doubling of the cyanide-resistant oxygen consumption. Intracellular H2O2 production also doubled 4 h after ROS phagocytosis. ROS uptake by RPE cells produced no significant extracellular superoxide, while extracellular superoxide production was readily demonstrated in a control macrophage cell line. Enzyme activity measurements showed that incubation of RPE cells with ROS doubled catalase activity without affecting superoxide dismutase or glutathione peroxidase activities. Inhibition of catalase during ROS uptake increased TBARS by 66%. Other enzyme activity measurements showed that human RPE cells possess both NADPH oxidase and palmitoyl-CoA oxidase activities. We conclude that ROS phagocytosis subjects RPE cells to an oxidative event on the same order of magnitude as measured in a macrophage. The event is not an extracellular macrophage-type respiratory burst and may be due to intracellular H2O2 resulting from an NADPH oxidase in the phagosome or from β-oxidation of ROS lipids in peroxisomes. Irrespective of case, the enzyme catalase appears to be essential in protecting the RPE cell against reactive oxygen species produced during phagocytosis.

Estimation of peroxisomal beta-oxidation in rat heart by a direct assay of acyl-CoA oxidase.

The contribution of peroxisomes to palmitate beta-oxidation in rat heart was estimated by either inhibiting mitochondrial beta-oxidation or measuring the activity of acyl-CoA oxidase. When respiratory inhibitors such as KCN or antimycin plus rotenone, or inhibitors of mitochondrial fatty acid uptake such as 2-tetradecylglycidic acid or 2-bromopalmitate, were used, degrees of inhibitions ranging from 24% to 87% were observed for palmitate beta-oxidation by a rat heart homogenate. Although the oxidation of palmitoyl-L-carnitine by coupled rat heart mitochondria was almost completely (94%) inhibited by KCN, the inhibition by antimycin plus rotenone was incomplete (77%) and was stimulated by L-carnitine. A direct assay of acyl-CoA oxidase, based on the spectrophotometric measurement at 300 nm of 2,4-decadienoyl-CoA formation from 4-trans-decenoyl-CoA, was evaluated with the aim of obtaining reliable values for the activity of this enzyme, which is presumed to catalyse the rate-limiting step of peroxisomal beta-oxidation. Activities determined by use of this assay were much higher than activities obtained by a coupled assay [Small, Burdett and Connock (1985) Biochem. J. 227, 205-210] commonly used to measure the activity of acyl-CoA oxidase. However, both methods yielded the same relative activities with different tissue homogenates. Based on an estimated palmitoyl-CoA oxidase activity of 0.3 nmol/min per mg of protein, the contribution of peroxisomes to palmitate beta-oxidation in a rat heart homogenate would optimally be 4%, and most likely is several-fold lower.

Heterogeneity in di/Trihydroxycholestanoic Acidaemia

Peroxisomes play an important role in the degradation of, among others, very long chain fatty acids (VLCFA), phytanic and pristanic acids, and pipecolic acid, and in the formation of primary bile acids, cholic acid and chenodeoxycholic acid, by {j-oxidation of diand trihydroxycholestanoic acids (DHCA and THCA). Recently, two cases have been described of di/trihydroxycholestanoic acidaemia due to a presumed THCA-CoA oxidase deficiency.L? In the first patient! next to accumulation of DHCA and THCA in plasma, an elevated plasma phytanic acid level was observed as the only additional biochemical abnormality. Since phytanic acid a-oxidation, measured in cultured fibroblasts as the production of 14COZ from [1_l4C] phytanic acid, was normal, accumulation of phytanic acid was explained by an inhibitory effect of the accumulating bile acid intermediates on phytanic acid a-oxidation. In the second patientaccumulation of DHCA and THCA in plasma was associated with undetectable THCACoA oxidase activity in post mortem liver, although the significance of this finding may be questioned since activities of palmitoyl-CoA oxidase and catalase were also found to be decreased, probably due to the long delay between the moment of death and the time of tissue sampling. Although both patients were assumed to suffer from a common enzyme defect, their clinical presentation was different. Since accumulation of phytanic acid (which was observed only in patient 1) may not only result from a primary defect in phytanic acid a-oxidation, but may also be secondary to a defective pristanic acid {j-oxidation,3

Cetaben and fibrates both influence the activities of peroxisomal enzymes in different ways

The effects of cetaben and clofibric acid were compared on the activities of peroxisomal enzymes in the liver and kidney of male Wistar rats. Cetaben at 200 mg kg body wt increased the activities of all of the enzymes in the liver that were studied two to eight times, whereas the changes induced by the same dose of clofibric acid increased some of the enzymes and decreased others. In the kidney, cetaben increased the activities of all investigated peroxisomal enzymes, while clofibric acid only increased the activity of palmitoyl-CoA oxidase. The data obtained in the dose-response study of cetaben revealed a significant rise in the activities of peroxisomal enzymes in both the liver and kidney at doses of 50–100 mg/kg body wt administered over 10 days, but the maximal effect was observed at 250 mg/kg. Palmitoyl-CoA oxidase and d-amino acid oxidase respond most markedly to cetaben. Cetaben could represent an atypical peroxisomal proliferator, since it increased the activities of all peroxisomal enzymes investigated. The fact that the individual components localized in the peroxisomes do not change markedly could be of importance with respect to the function and physical properties of peroxisomes.

Bacterial short-chain acyl-CoA oxidase: production, purification and characterization

An Arthrobacter nicotianae strain has been found to produce an inducible acyl coenzyme A (CoA) oxidase. Nine times more butyryl-CoA oxidase activity, compared to palmitoyl-CoA oxidase, was found in the cell extract. The addition of flavin adenine dinucleotide (FAD) caused an increase in acyl-CoA oxidase activity and thermal stability. The purified enzyme exhibited a relative molecular mass of 50 000 on sodium dodecyl sulphate-polyacrylamide gel electrophoresis and 100 000 under non-denaturing conditions. Acyl-CoA oxidase from Arthrobacter nicotianae is highly specific towards short-chain fatty acids. The fastest O2 uptake was observed with butyryl-CoA as substrate. The enzyme is inhibited by silver and mercury salts.

Effects of the peroxisome proliferator mono(2-ethylhexyl)phthalate in primary hepatocyte cultures derived from rat, guinea pig, rabbit and monkey: Relationship between interspecies differences in biotransformation and peroxisome proliferating potencies

Primary hepatocyte cultures derived from rat, rabbit, guinea pig and monkey have been treated in vitro with metabolites of di(2-ethylhexyl)phthalate, i.e. mono(2-ethylhexyl)phthalate (MEHP), mono(5-carboxy-2-ethylpentyl)phthalate (metabolite V) and mono(2-ethyl-5-oxohexyl)-phthalate (metabolite VI). In rat hepatocyte cultures MEHP and metabolite VI were equally potent in inducing peroxisome proliferation, while metabolite V was much less potent. In rat hepatocytes a 50% increase in both peroxisomal palmitoyl-CoA oxidase activity and microsomal lauric acid ω-hydroxylation activity was found after treatment with 5–15 μM MEHP. In guinea pig, rabbit and monkey hepatocyte cultures, a 50% increase in peroxisomal palmitoyl-CoA oxidase activity was found after treatment with 408–485 μM MEHP. No induction of lauric acid ω-hydroxylation activity was found. These results indicate that peroxisome proliferation can be induced by MEHP in rabbit, guinea pig and monkey hepatocytes, but that these species are at least 30-fold less sensitive to peroxisome proliferation induction than rats. The proposed mechanistic inter-relationship between induction of lauric acid ω-hydroxylation activity and peroxisome proliferation is found in rat hepatocytes, but not in hepatocytes of the other three species. Treatment of guinea pig hepatocyte cultures with MEHP resulted in an increase in triglyceride concentrations in the hepatocytes. In rat and rabbit hepatocyte cultures, triglyceride concentrations were much less altered by MEHP. In monkey hepatocytes a decrease in hepatic triglyceride concentration was found after treatment with MEHP. These effects are in agreement with in vivo effects observed before. After treatment of primary hepatocyte cultures with MEHP, high concentrations of ω- and (ω-1)-hydroxylated metabolites of MEHP were found in media from rat, rabbit and guinea pig cultures. The formation of these metabolites did not decline in time. During treatment the metabolite profile in media from rat hepatocyte cultures moved towards ω-hydroxy metabolites of MEHP. In media from monkey hepatocyte cultures the lowest concentrations of hydroxylated metabolites were determined. No major species differences were found in the potency to form oxidized MEHP metabolites, and thus no unique metabolite differences were found, which could explain the species differences in sensitivity for peroxisome proliferation.

The CoA esters of 2-methyl-branched chain fatty acids and of the bile acid intermediates di- and trihydroxycoprostanic acids are oxidized by one single peroxisomal branched chain acyl-CoA oxidase in human liver and kidney

Rat liver peroxisomes contain three acyl-CoA oxidases: palmitoyl-CoA oxidase, which oxidizes the CoA esters of straight chain fatty acids and prostaglandins; pristanoyl-CoA oxidase, which oxidizes the CoA esters of 2-methyl-branched fatty acids (e.g. pristanic acid); and trihydroxycoprostanoyl-CoA oxidase, which oxidizes the CoA esters of the bile acid intermediates di- and trihydroxycoprostanic acids (Van Veldhoven, P. P., Vanhove, G., Asselberghs, S., Eyssen, H. J., and Mannaerts, G. P. (1992) J. Biol. Chem. 267, 20065-20074). In the present report we demonstrate that human liver peroxisomes contain only two acyl-CoA oxidases: palmitoyl-CoA oxidase, which oxidizes the CoA esters of straight chain fatty acids and prostaglandins, and a novel branched chain acyl-CoA oxidase, which oxidizes the CoA esters of 2-methyl-branched fatty acids as well as those of the bile acid intermediates (which also possess a 2-methyl substitution in their side chains). The branched chain acyl-CoA oxidase was purified to near homogeneity by means of column chromatography. It appeared to be a 70-kDa monomeric protein that did not cross-react with antisera raised against rat palmitoyl-CoA oxidase and pristanoyl-CoA oxidase. No indication was found for the presence of a separate trihydroxycoprostanoyl-CoA oxidase in human liver. The branched chain acyl-CoA oxidase was present also in human kidney, suggesting that it is expressed in other extrahepatic tissues as well. Our results explain a number of clinical-chemical observations made in certain cases of peroxisomal beta-oxidation disorders.

Acylcarnitine formation and fatty acid oxidation in hepatocytes from rats treated with tetradecylthioacetic acid (a 3-thia fatty acid)

In livers of rats fed a single morning dose of 100 mg tetradecylthioacetic acid (TTA) total long-chain acyl-CoA increased significantly to 3 times control levels within 6 h, then the level declined almost to control value within the next morning. Hepatic malonyl-CoA was reduced 75% 6 h after TTA treatment. From 6 to 24 h malonyl-CoA increased about 10-fold to about 3 times that of controls. Paradoxically there was nearly a 2-fold higher oxidation of both [1− 14C]palmitic acid (0.5 mM) and [1− 14C]oleic acid (0.5 mM) in hepatocytes isolated from rats 24 h after TTA treatment compared to controls. After 6 h, when malonyl-CoA was at a minimum in vivo, fatty acid oxidation in cells was not increased. Acylcarnitine formation in digitonin permeabilized hepatocytes isolated 24 h after administration of TTA was increased both in the absence and in the presence of malonyl-CoA. At 24 h peroxisomal palmitoyl-CoA oxidase activity was not increased. The results suggest that an increased CPT activity and increased acylcarnitine formation in the presence of malonyl-CoA is a delayed response to increased acyl-CoA levels. Furthermore, in hepatocytes isolated after 24 h incorporation of [1- 14C]oleic acid into triacylglycerols was significantly reduced. The data show that in hepatocytes isolated from rats 24 h after administration of a single dose of TTA, there is a diversion of hepatic acyl-CoA from synthesis of triacylglycerols into β-oxidation in the mitochondria.

Stimulation of peroxisomal palmitoyl-CoA oxidase activity by ciprofibrate in hepatic cell lines: Comparative studies in Fao, MH 1C 1 and HepG2 cells

The response of two rat cell lines, Fao and MH1C1, and one human cell line, HepG2, to the peroxisome proliferator ciprofibrate, was studied. Using a fluorometric assay for palmitoyl-CoA oxidase, the dose- and time-dependent increase of this enzymatic activity was determined. From the lowest concentration (100 microM) stimulation is evident in the two rat cell lines. In the Fao line, the activity was stimulated reaching a seven-fold increase over the control level at 250 microM after 72 h of treatment. In the MH1C1 line, the maximum stimulation, four- to five-fold, was obtained at 250 and 500 microM after 72 h. In the HepG2 cell line, activity increased two-fold at 250 microM after 72 h reaching a three-fold increase at 1000 microM after 48 h. Ciprofibrate was more toxic to Fao cells than to MH1C1 and HepG2 cells which is also the order of the acyl-CoA oxidase stimulation by ciprofibrate. These preliminary results suggest that the two rat cell lines are appropriate for investigating the induction of peroxisomal beta-oxidation enzymes and the expression of their genes. The HepG2 cell line is a complementary model for the study of interspecies differences in the response to peroxisomal proliferators and of the peroxisomal functions implied in the lipid metabolism of human liver.

Substrate specificities of rat liver peroxisomal acyl-CoA oxidases: palmitoyl-CoA oxidase (inducible acyl-CoA oxidase), pristanoyl-CoA oxidase (non-inducible acyl-CoA oxidase), and trihydroxycoprostanoyl-CoA oxidase.

Rat liver peroxisomes contain three acyl-CoA oxidases:palmitoyl-CoA oxidase, pristanoyl-CoA oxidase, and trihydroxycoprostanoyl-CoA oxidase. The three oxidases were separated by anion-exchange chromatography of a partially purified oxidase preparation, and the column eluate was analyzed for oxidase activity with different acyl-CoAs. Short chain mono (hexanoyl-) and dicarboxylyl (glutaryl-)-CoAs and prostaglandin E2-CoA were oxidized exclusively by palmitoyl-CoA oxidase. Long chain mono (palmitoyl-) and dicarboxylyl (hexadecanedioyl-)-CoAs were oxidized by palmitoyl-CoA oxidase and pristanoyl-CoA oxidase, the former enzyme catalyzing approximately 70% of the total eluate activity. The very long chain lignoceroyl-CoA was also oxidized by palmitoyl-CoA oxidase and pristanoyl-CoA oxidase, the latter enzyme catalyzing approximately 65% of the total eluate activity. Long chain 2-methyl branched acyl-CoAs (2-methylpalmitoyl-CoA and pristanoyl-CoA) were oxidized for approximately 90% by pristanoyl-CoA oxidase, the remaining activity being catalyzed by trihydroxycoprostanoyl-CoA oxidase. The short chain 2-methylhexanoyl-CoA was oxidized by trihydroxycoprostanoyl-CoA oxidase and pristanoyl-CoA oxidase (approximately 60 and 40%, respectively, of the total eluate activity). Trihydroxycoprostanoyl-CoA was oxidized exclusively by trihydroxycoprostanoyl-CoA oxidase. No oxidase activity was found with isovaleryl-CoA and isobutyryl-CoA. Substrate dependences of palmitoyl-CoA oxidase and pristanoyl-CoA oxidase were very similar when assayed with the same (common) substrate. Since the two oxidases were purified to a similar extent and with a similar yield, the contribution of each enzyme to substrate oxidation in the column eluate probably reflects its contribution in the intact liver.

Biochemical characterization of a variant form of cytosolic epoxide hydrolase induced by parental exposure to N-ethyl-N-nitrosourea.

1. ENU4 mice express a protein variant originally detected in a CBF1 mouse sired by a C57BL/6 mouse exposed to N-ethyl-N-nitrosourea. It appears to be an isoelectric point variant of cytosolic epoxide hydrolase. Affinity purified cytosolic epoxide hydrolase from ENU4 mice has a pI of approximately 5.1 compared to 5.6 in other mouse strains. 2. Clofibrate induced cytosolic epoxide hydrolase to similar levels in five strains of mice. However, CBF1 and ENU4 mice were more sensitive to the induction of palmitoyl CoA oxidase activity. 3. Except for isoelectric point, the physico- and immunochemical properties of cytosolic epoxide hydrolase from ENU4 mice were similar to those of the other mouse strains. Substrate specificities for five of six substrates tested were also similar.

Microsomal lauric acid hydroxylase activities after treatment of rats with three classical cytochrome P450 inducers and peroxisome proliferating compounds

In order to investigate a proposed relationship between induction of hepatic microsomal lauric acid hydroxylase activity and peroxisome proliferation in the liver, male Wistar rats were treated with peroxisome proliferating compounds, and the lauric acid hydroxylase activity, the immunochemical detectable levels of cytochrome P450 4A1 and the activities of peroxisomal enzymes were determined. In addition, the levels of cytochrome P450 4A1 and lauric acid hydroxylase activities were studied after treatment of rats with three cytochrome P450 inducers. After treatment with aroclor-1254, phenobarbital or 3-methylcholanthrene total cytochrome P450 was 1.7–2.7 times induced. However, no induction of lauric acid ω-hydroxylase activities or P450 4A1 levels were found. After treatment of rats with di(2-ethylhexyl)phthalate (DEHP) a dose-dependent induction of lauric acid ω-hydroxylase activities, levels of cytochrome P450 4A1 and peroxisomal fatty acid β-oxidation was found. Even at a dose-level of 100 mg DEPH/kg body weight per day a significant induction of these activities was observed. the main metabolites of DEHP, mono(2-ethylhexyl)phthalate and 2-ethyl-1-hexanol, also caused an induction of levels of P450 4A1, lauric acid ω-hydroxylase activities and the activity of peroxisomal palmitoyl-CoA oxidase. 2-Ethyl-1-hexanoic acid did not influence lauric acid ω-hydroxylase activities, but did induce levels of P450 4A1 and palmitoyl-CoA oxidase activities. Three other compounds (perfluoro-octanoic acid, valproate and nafenopin) induced both lauric acid ω-hydroxylase activity and peroxisomal palmitoyl-CoA oxidase activity. the plasticizer, di(2-ethylhexyl)adipate, did not induce leveis of P450 4A1, lauric acid ω-hydroxylase activities or palmitoyl-CoA oxidase activities. With the compounds tested a close association between the induction of lauric acid ω-hydroxylase activities and peroxisomal palmitoyl-CoA oxidase activity was found. These data support the theory that peroxisome proliferating compounds do induce lauric acid ω-hydroxylase activities and that there might be a mechanistic inter-relationship between peroxisome proliferation and induction of lauric acid ω-hydroxylase activities.