Rat liver bile acid CoA:amino acid N-acyltransferase: expression,characterization, and peroxisomal localization

Bile acid CoA:amino acid N-acyltransferase (BAT) is responsible for the amidation of bile acids with the amino acids taurine and glycine. Rat liver BAT (rBAT) cDNA was isolated from a rat liver lambdaZAP cDNA library and expressed in Sf9 insect cells using a baculoviral vector. rBAT displayed 65% amino acid sequence homology with human BAT (hBAT) and 85% homology with mouse BAT (mBAT). Similar to hBAT, expressed rBAT was capable of forming both taurine and glycine conjugates with cholyl-CoA. mBAT, which is highly homologous to rBAT, forms only taurine conjugated bile acids (Falany, C. N., H. Fortinberry, E. H. Leiter, and S. Barnes. 1997. Cloning and expression of mouse liver bile acid CoA: Amino acid N-acyltransferase. J. Lipid Res. 38: 86-95). Immunoblot analysis of rat tissues detected rBAT only in rat liver cytosol following homogenization and ultracentrifugation. Subcellular localization of rBAT detected activity and immunoreactive protein in both cytosol and isolated peroxisomes. Rat bile acid CoA ligase (rBAL), the enzyme responsible for the formation of bile acid CoA esters, was detected only in rat liver microsomes. Treatment of rats with clofibrate, a known peroxisomal proliferator, significantly induced rBAT activity, message, and immunoreactive protein in rat liver. Peroxisomal membrane protein-70, a marker for peroxisomes, was also induced by clofibrate, whereas rBAL activity and protein amount were not affected. In summary, rBAT is capable of forming both taurine and glycine bile acid conjugates and the enzyme is localized primarily in peroxisomes in rat liver.     

Effect of clofibrate treatment on carnitine acyltransferases in different subcellular fractions of rat liver

The subcellular distribution of carnitine acetyl-, octanoyl-, and palmitoyltransferase in the livers of normal and clofibrate-treated male rats was studied with isopycnic sucrose density gradient fraction.In normal liver 48% of total carnitine acetyltransferase activity was peroxisomal, 36% of the activity located in mitochondria and 16% in a membranous fraction containing microsomes. Carnitine octanoyltransferase and carnitine palmitoyltransferase were confined almost totally (77–81%) to mitochondria in normal liver.Clofibrate treatment increased the total activity of carnitine acetyltransferase over 30 times, whereas the total activities of the other two transferases were increased only 5-fold.From the three different subcellular carnitine acetyltransferases the mitochondrial one was not responsive to clofibrate treatment, i.e. the rise in mitochondrial activity was over 70-fold as contrasted to the 6- and 14-fold rises in peroxisomal and microsomal activities, respectively. After treatment mitochondria contained 79% of total activity.It is concluded that the clofibrate-induced increase of carnitine acetyltransferase activity is not due to the peroxisomal proliferation that occurs during clofibrate treatment. The rise in peroxisomal activity contributed only 8% to the total increase.After clofibrate treatment the greatest part of carnitine octanoyl- and palmitoyltrnasferase activities were located in mitochondria but a considerable amount of both activities was found also in the soluble fraction of liver.     

Effect of clofibrate treatment on carnitine acyltransferases in different subcellular fractions of rat liver.

The subcellular distribution of carnitine acetyl-, octanoyl-, and palmitoyl- transferase in the livers of normal and clofibrate-treated male rats was studied with isopycnic sucrose density gradient fractionation. In normal liver 48% of total carnitine acetyltransferase activity was peroxisomal, 36% of the activity located in mitochondria and 16% in a membranous fraction containing microsomes. Carnitine octanoyltransferase and carnitine palmitoyltransferase were confined almost totally (77--81%) to mitochondria in normal liver. Clofibrate treatment increased the total activity of carnitine acetyltransferase over 30 times, whereas the total activities of the other two transferases were increased only 5-fold. From the three different subcellular carnitine acetyltransferases the mitochondrial one was most responsive to clofibrate treatment, i.e. the rise in mitochondrial activity was over 70-fold as contrasted to the 6- and 14-fold rises in peroxisomal and microsomal activities, respectively. After treatment mitochondria contained 79% of total activity. It is concluded that the clofibrate-induced increase of carnitine acetyltransferase activity is not due to the peroxisomal proliferation that occurs during clofibrate treatment. The rise in peroxisomal activity contributed only 8% to the total increase. After clofibrate treatment the greatest part of carnitine octanoyl- and palmitoyltransferase activities were located in mitochondria but a considerable amount of both activities was found also in the soluble fraction of liver.     

Differential induction of peroxisomal oxidation of palmitic acid and 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoic acid in rat liver

The effect of feeding rats 20% partially hydrogenated marine oil (PHMO), 20% soybean oil, or clofibrate on the conversion of 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoic acid to cholic acid was studied in light mitochondrial (L) fractions prepared from liver. 20% PHMO gave a doubling both of the specific and of the total activity of the cholic acid formation compared to those found in the L-fraction from animals given standard pellets. 20% soybean oil induced the specific and the total activity to a lesser extent, 1.4- and 1.2-fold, respectively. The specific and total activity of the peroxisomal beta-oxidation of palmitic acid were induced 2.4- and 2.7-fold, respectively, by PHMO feeding. Soybean oil gave a smaller increase, 2-fold, in both specific and total activity. Clofibrate, a known peroxisomal proliferator, induced the specific and total activity of the peroxisomal fatty acid beta-oxidation 5.2- and 5.7-fold, respectively, whereas the specific activity of the cholic acid formation remained unchanged compared to standard pellet feeding. The same pattern was found in the postnuclear supernatants (E-fractions), excluding the possibility that different treatments caused different distributions of organelles between the fractions. This differential induction of two similar peroxisomal reaction sequences suggests that at least two mechanisms for peroxisomal induction exist.     

A diet rich in (n-3) fatty acids increases peroxisomal beta-oxidation activity and lowers plasma triacylglycerols without inhibiting glutathione-dependent detoxication activities in the rat liver

By using comparisons with a safflower oil diet (15% w/w) and a control, low-fat diet, the ability of a fish oil diet (15% MaxEPA) rich in the (n-3) fatty acids, eicosapentaenoic acid and docosahexaenoic acid, to alter hepatic activities has been determined in adult, male rats. Compared with the safflower diet, treatment for 2 weeks with the fish oil diet caused significant increases in the ratio of liver weight/body weight and the specific activities in liver homogenates of peroxisomal enzymes fatty acyl-CoA oxidase (263%) and catalase (149%) and caused a significant lowering of plasma triacylglycerol levels. Fish oil diets rich in (n-3) fatty acids should thus be placed in the category of hypotriglyceridemic agents which stimulate peroxisomal beta-oxidation activity. In contrast to the effects seen with the other hypotriglyceridemic, peroxisomal proliferating agents such as clofibrate, hepatic glutathione peroxidase and glutathione S-transferase activities are unchanged or are increased rather than inhibited with the fish oil diet.     

Studies on the intracellular distributions of soluble epoxide hydrolase and of catalase by digitonin-permeabilization of hepatocytes isolated from control and clofibrate-treated mice

Digitonin permeabilization of hepatocytes from control and clofibrate-treated (0.5% by mass, 10 days) male C57bl/6 mice was used to study the intracellular distributions of soluble ('cytosolic') epoxide hydrolase and of catalase. The following conclusions were drawn. (1) About 60% of the total soluble epoxide hydrolase activity in control mouse hepatocytes is situated in the cytosol. (2) The rest is not mitochondrial, but probably peroxisomal. (3) Of the total catalase activity in control mouse hepatocytes, 5-10% is found in the cytosol. (4) Treatment of mice with clofibrate increases the total hepatocyte activity of soluble epoxide hydrolase 4-fold, but does not influence the relative distribution of this enzyme between cytosol and peroxisomes. (5) The total catalase activity is increased 3.5-fold by clofibrate treatment and 15-35% of this activity is shifted from the peroxisomes to the cytosol.     

Enhancement of long-chain acyl-CoA hydrolase activity in peroxisomes and mitochondria of rat liver by peroxisomal proliferators

The present study has confirmed previous findings of long-chain acyl-CoA hydrolase activities in the mitochondrial and microsomal fractions of the normal rat liver. In addition, experimental evidence is presented in support of a peroxisomal localization of long-chain acyl-CoA hydrolase activity. (a) Analytical differential centrifugation of homogenates from normal rat liver revealed that this activity (using palmitoyl-CoA as the substrate) was also present in a population of particles with an average sedimentation coefficient of 6740 S, characteristic of peroxisomal marker enzymes. (b) The subcellular distribution of the hydrolase activity was greatly affected by administration of the peroxisomal proliferators clofibrate and tiadenol. The specific activity was enhanced in the mitochondrial fraction and in a population of particles with an average sedimentation coefficient of 4400 S, characteristic of peroxisomal marker enzymes. Three populations of particles containing lysosomal marker enzymes were found by analytical differential centrifugation, both in normal and clofibrate-treated rats. Our data do not support the proposal that palmitoyl-CoA hydrolase and acid phosphatase belong to the same subcellular particles. In livers from rats treated with peroxisomal proliferators, the specific activity of palmitoyl-CoA hydrolase was also enhanced in the particle-free supernatant. Evidence is presented that this activity at least in part, is related to the peroxisomal proliferation.     

Association of the liver peroxisomal fatty acyl-CoA beta-oxidation system with the synthesis of bile acids

The association of liver peroxisomal fatty acyl-CoA beta-oxidizing system (FAOS) with the synthesis of bile acids was investigated. When rats were given clofibrate, a peroxisome proliferator and stimulator of peroxisomal FAOS, the biosynthesis of bile acids was significantly increased. Di(2-ethylhexyl)phthalate, another peroxisome proliferator, also increased the biosynthesis of bile acids. On the other hand, administration of orotate, an inhibitor of mitochondrial FAOS activity, did not affect the biosynthesis. It is known that fatty acyl-CoA oxidase [EC 1.3.99.3] in peroxisomal FAOS conjugates with catalase [EC 1.11.1.6]. When the catalase activity of liver peroxisomes was irreversibly inhibited by administration of 3-amino-1,2,4-triazole (amino-triazole), the biosynthesis of bile acids was suppressed to about one-third, and the serum cholesterol level was increased. However, the bile acid components of the bile obtained from aminotriazole-treated rats were not essentially different from those of control rats, and no accumulation of intermediates of bile acid synthesis was found in this experiment. Peroxisomal FAOS activity of the liver from amino-triazole-treated rats was considerably lower than that of control liver. The above results indicate that liver peroxisomes play a role in the biosynthesis of bile acids in vivo.     

Subcellular organization of bile acid amidation in human liver: a key issue in regulating the biosynthesis of bile salts

To extend our knowledge of how the synthesis of free bile acids and bile salts is regulated within the hepatocyte, bile acid-CoA:amino acid N-acyltransferase and bile acid-CoA thioesterase activities were measured in subcellular fractions of human liver homogenates. Some bile acids, both conjugated and unconjugated, have been reported to be natural ligands for the farnesoid X receptor (FXR), an orphan nuclear receptor. The conversion of [(14)C]choloyl-CoA and [(14)C]chenodeoxycholoyl-CoA into the corresponding tauro- and glyco-bile acids or the free bile acids was measured after high-pressure liquid radiochromatography. There was an enrichment of the N-acyltransferase in the cytosolic and the peroxisomal fraction. Bile acid-CoA thioesterase activities were enriched in the cytosolic, peroxisomal, and mitochondrial fractions. The highest amidation activities of both choloyl-CoA and chenodeoxycholoyl-CoA were found in the peroxisomal fraction (15-58 nmol/mg protein/min). The K(m) was higher for glycine than taurine both in cytosol and the peroxisomal fraction.These results show that the peroxisomal de novo synthesis of bile acids is rate limiting for peroxisomal amidation, and the microsomal bile acid-CoA synthetase is rate limiting for the cytosolic amidation. The peroxisomal location may explain the predominance of glyco-bile acids in human bile. Both a cytosolic and a peroxisomal bile acid-CoA thioesterase may influence the intracellular levels of free and conjugated bile acids.     

Hepatic enzymes, CoASH and long-chain acyl-CoA in subcellular fractions as affected by drugs inducing peroxisomes and smooth endoplasmic reticulum

1. The activities of acyl-CoA hydrolase, catalase, urate oxidase and peroxisomal palmitoyl-CoA oxidation as well as the protein content and the level of CoASH and long-chain acyl-CoA were measured in subcellular fractions of liver from rats fed diets containing phenobarbital (0.1% w/w) or clofibrate (0.3% w/w). 2. Whereas phenobarbital administration resulted in increased microsomal protein, the clofibrate-induced increase was almost entirely attributed to the mitochondrial fraction with minor contribution from the light mitochondrial fraction. 3. The specific activity of palmitoyl-CoA hydrolase in the microsomal fraction was only slightly affected while the mitochondrial enzyme was increased to a marked extent (3-4-fold) by clofibrate. 4. Phenobarbital administration mainly enhanced the microsomal palmitoyl-CoA hydrolase. 5. The increased long-chain acyl-CoA and CoASH level observed after clofibrate treatment was mainly associated with the mitochondrial, light mitochondrial and cytosolic fractions, while the slight increase in the levels of these compounds found after phenobarbital feeding was largely of microsomal origin. 6. The findings suggest that there is an intraperoxisomal CoASH and long-chain acyl-CoA pool. 7. The specific activity of palmitoyl-CoA hydrolase, catalase and peroxisomal palmitoyl-CoA oxidation was increased in the lipid-rich floating layer of the cytosol-fraction. 8. The changes distribution of the peroxisomal marker enzymes and microsomal palmitoyl-CoA hydrolase after treatment with hypolipidemic drugs may be related to the origin of peroxisomes.     

The mechanism underlying the hypolipemic effect of perfluorooctanoic acid (PFOA), perfluorooctane sulphonic acid (PFOSA) and clofibric acid.

The influence of the peroxisomal proliferators perfluorooctanoic acid (PFOA), perfluorooctane sulphonic acid (PFOSA) and clofibric acid on lipid metabolism in rats was studied. Dietary treatment of male Wistar rats with these three compounds resulted in rapid and pronounced reduction in both cholesterol and triacylglycerols in serum. The concentration of liver triacylglycerols was increased by about 300% by PFOSA. Free cholesterol was increased by both perfluoro compounds. Cholesteryl ester was reduced to 50% by PFOSA as well by clofibrate. In hepatocytes from fed rats, all the compounds resulted in reduced cholesterol synthesis from acetate, pyruvate and hydroxymethyl glutarate, but there was no reduction of synthesis from mevalonic acid. The oxidation of palmitate was also increased in all groups. The perfluoro compounds, but not clofibrate, caused some reduction in fatty acid synthesis. The activity of liver HMG-CoA reductase was reduced to 50% or less in all treatment groups and all three compounds led to lower activity of acyl-CoA:cholesterol acyltransferase (ACAT). Changes in other enzymes related to lipid metabolism were inconsistent. The present data suggest that the hypolipemic effect of these compounds may, at least partly, be mediated via a common mechanism; impaired production of lipoprotein particles due to reduced synthesis and esterification of cholesterol together with enhanced oxidation of fatty acids in the liver.     

Effect of clofibrate application on morphology and enzyme content of liver peroxisomes.

Male albino rats (Sprague Dawley) were fed for 2-6 weeks on a diet containing 0.75% clofibrate. Liver cell fractions obtained from these animals were assayed for peroxisomal enzymes. In the cell homogenate the catalase activity was doubled, whereas the activity of urate oxidase was found to be only slightly depressed. The activity of carnitine acetyltransferase increased several times. In liver peroxisomes purified by isopycnic gradient centrifugation the specific activity of urate oxidase decreased appreciably showing that peroxisomes formed under the proliferative influence of clofibrate are not only modified with respect to their morphological characteristics but also to their enzymic equipment. This is also obvious from the changes in peroxisomal carnitine acetyltransferase activity which was enhanced by clofibrate to more than the fivefold amount. In purified mitochondria this enzyme was even more active: clofibrate advances both, the peroxisomal and the mitochondrial moiety of carnitine acetyltransferase. Morphological and cytochemical studies showed an increase in the number of microbodies and as compared to the controls microbodies were lying in groups more frequently. Small particles located closely adjacent to "normal" sized peroxisomes were found particularly after short feeding periods. While the number of coreless microbodies increased studies gave no clear evidence for an increase in marked shape irregularities of the peroxisomes.     

Spray-dried milk supplemented with alpha-linolenic acid or eicosapentaenoic acid and docosahexaenoic acid decreases HMG Co A reductase activity and increases biliary secretion of lipids in rats

In our earlier study, we have shown that rats fed spray-dried milk containing alpha-linolenic acid (LNA 18:3 n-3) or eicosapentaenoic acid (EPA 20:5 n-3) and docosahexaenoic acid (DHA 22:6 n-3) had significantly lower amounts of serum and liver cholesterol. To evaluate the mechanism for hypocholesterolemic effect of n-3 fatty acids containing milk formulation, we fed male Wistar rats with spray-dried milk containing linseed oil (LSO) (source of LNA) or fish oil (FO) (source of EPA+DHA) for 8 weeks. Feeding n-3 fatty acid containing milk formulation lowered the hepatic 3-hydroxy-methylglutaryl coenzyme A (HMG Co A) activity by 17-22% compared to rats given control diet devoid of n-3 fatty acids. The cholesterol level in liver microsomes was found to be decreased by 16% and 20%, respectively, in LSO and FO containing formulation fed rats. The bile flow was enhanced to an extent of 19-23% in experimental groups compared to control animals. The biliary cholesterol and phospholipid secretion was increased to an extent of 49-55% and 140-146%, respectively, in rats fed n-3 fatty acid containing formulation. The increase in the total bile acids secretion in bile was mainly reflected on an increase in the levels of taurine conjugated bile acids. These results indicated that n-3 fatty acid containing spray-dried milk formulation would bring about the hypocholesterolemic effect by lowering HMG Co A reductase activity in liver and by increasing the secretion of bile constituents.     

Increased uptake of fatty acids by the isolated rat liver after raising the fatty acid binding protein concentration with clofibrate

Following the administration of clofibrate to rats, the concentration of Z protein or fatty acid binding protein in liver cytosol increases by 98 %. Ligandin concentration remains unchanged. Isolated perfused livers of clofibrate-treated rats take up free fatty acids from the perfusate at a significantly higher rate (+ 76 %) than controls. Lipid synthesis from radioactive fatty acids is not modified by clofibrate administration. The yield of plasma membranes obtained from liver homogenates as well as their lipid composition are similar in control and clofibrate treated livers. These results seem to exclude the possibility that the enhancement of FFA uptake could result from an indirect effect of the drug on FFA metabolism and/or plasma membrane surface and thus support the view that Z protein plays a role in intracellular fatty acid transport in the liver.     

Clofibrate does not induce peroxisomal 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoyl coenzyme A oxidation in rat liver. Evidence that this reaction is catalyzed by an enzyme system different from that of peroxisomal acyl-coenzyme A oxidation

The effect of clofibrate treatment of rats on the peroxisomal conversion in vitro of 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoic acid into cholic acid in liver fractions has been investigated. No increase in the activity was observed after clofibrate treatment. In contrast, peroxisomal palmitate oxidation and palmitoyl-CoA oxidase activity increased several fold. It is concluded that the enzyme system responsible for the oxidative cleavage of the steroid side chain in bile acid formation is different from the enzyme system involved in the peroxisomal beta-oxidation of long chain fatty acids.     

Cardiac and hepatic acyl-CoA and acylcarnitine hydrolase activities in clofibrate-fed rabbits

Catalase activity in the heart of male rabbits was 21% of that found in the liver; clofibrate feeding (0.3% w/w for 10 days) resulted in an 80% increase in both cardiac and hepatic catalase activities. Fatty acyl-CoA oxidase activity in control heart was 11% of that found in control liver; this peroxisomal activity did not increase subsequent to clofibrate feeding. Only acyl-CoA hydrolase activity in the cardiac supernatant was elevated by clofibrate feeding. Acylcarnitine hydrolase activity was increased significantly in the homogenate, extract and supernatant of both heart and liver from the clofibrate-fed rabbit. Clofibrate feeding increased CoASH and carnitine tissue levels in heart and liver.     

Role of peroxisomal fatty acyl-CoA beta-oxidation in phospholipid biosynthesis

We have already reported that peroxisomal beta-oxidation has an anabolic function, supplying acetyl-CoA for bile acid biosynthesis [H. Hayashi and A. Miwa, 1989, Arch. Biochem. Biophys. 274, 582-589]. The anabolic significance of peroxisomal beta-oxidation was further investigated in the present study by using clofibrate, a peroxisome proliferator, as an experimental tool. Clofibrate suppressed 3-hydroxymethylglutaryl-CoA reductase activity (the key enzyme of cholesterol synthesis) and enhanced fatty acyl-CoA oxidase activity (the rate-limiting enzyme of beta-oxidation). Rats were fed a chow containing 0.25% clofibrate for 2 weeks, and then a bile duct fistula was implanted. [1-14C]lignoceric acid, which is degraded exclusively by peroxisomal FAOS, was injected into the rats 24 h after the operation. By this time, the secondary bile acids and pooled cholesterol which would normally be secreted into the bile are considered to have been exhausted from the liver. Clofibrate significantly decreased the incorporations of radioactivity into biliary bile acid (40% of the control) and cholesterol (50%), but did not affect biliary lipid contents. [14C]Acetyl-CoA formed by peroxisomal beta-oxidation of [1-14C]lignoceric acid was preferentially utilized for syntheses of long-chain fatty acids and phospholipids rather than synthesis of cholesterol or triglyceride. The radioactivities incorporated into the former two lipids were increased 2-fold over the control by administration of clofibrate, while the incorporation into triglyceride was decreased to approximately half. In particular, the incorporation into phosphatidylethanolamine was increased as much as 3.5-fold over the control. The contents of these lipids in the liver were not affected by clofibrate. The results suggest that peroxisomal beta-oxidation plays an important role in the biosynthesis of functional lipids such as phospholipids (this work), in addition to bile acids and cholesterol (previous report) by supplying acetyl-CoA.     

Presence and features of fatty acyl-CoA binding activity in rat hepatic peroxisomes

We studied the fatty acyl-CoA binding activity of rat liver peroxisomes. After subcellular fractionation of rat liver treated with or without clofibrate, a peroxisome proliferator, the binding activity with [1-(14)C]palmitoyl-CoA was detected in the light mitochondrial fraction in addition to the mitochondrial and cytosol fractions. After Nycodenz centrifugation of the light mitochondrial fraction, the binding activity was detected in peroxisomes. The peroxisomal activity depended on the incubation temperature and peroxisome concentration. The activity also depended on the concentration of 2-mercaptoethanol, and a plateau of activity was unexpectedly found at 2-mercaptoethanol concentrations from 20 to 40 mM. Clofibrate increased the total and specific activity of the fatty acyl-CoA binding of peroxisomes by 7.9 and 2.5 times compared with the control, respectively. In the presence of 20% glycerol at 0 degree C, approximately 90% of the binding activity was maintained for up to at least 3 wk. After successive treatment with an ultramembrane Amicon YM series, about 70% of the binding activity was detected in the M.W. 30,000-100,000 fraction. When the M.W. 30,000-100,000 fraction was added to the incubation mixture of the peroxisomal fatty acyl-CoA beta-oxidation system, a slight increase in the beta-oxidation activity was found. 2-Mercaptoethanol (20 mM) significantly activated the fatty acyl-CoA beta-oxidation system to 1.4 times control. After gel filtration of the M.W. 30,000-100,000 fraction, the peaks of fatty acyl-CoA binding protein showed broad elution profiles from 45,000 to 75,000. These results suggest that fatty acyl-CoA binding activity can be detected directly in peroxisomes and is increased by peroxisome proliferators. The high binding activity in the presence of higher concentrations of 2-mercaptoethanol indicates the importance of the SH group for binding. The apparent molecular weight of the binding protein may be from 45,000 to 75,000.     

Properties of a collagenase inhibitor partially purified from cultures of smooth muscle cells

1. The metabolism of [14-14C]erucate and [U-14C]palmitate has been investigated in perfused heart from rats fed 0.3% clofibrate for 10 days and from control rats. 2. The total uptake of fatty acids in the heart increased in the clofibrate fed group. Clofibrate increased the oxidation of [14-14C]erucic acid by 100% and the oxidation of [U-14C]palmitic acid by 30% compared to controls. 3. The chain-shortening of erucate to C20:1 and C18:1 fatty acids in the perfused heart was stimulated at least two-fold by clofibrate feeding. 4. The activity of the peroxisomal marker enzyme catalase increased 60%, the activity of cytochrome oxidase increased approx. 16% and the content of total coenzyme A increased 30% in heart homogenates from rats fed clofibrate compared to controls. 5. The isolated mitochondrial fraction from clofibrate fed rats showed an increased capacity for oxidation of palmitoylcarnitine and decanoylcarnitine, while the oxidation of erucoylcarnitine showed little change. 6. It is suggested that clofibrate increases the oxidation of [14-14C]erucic acid in the perfused heart by increasing the capacity for chain-shortening of [14-14C]erucate in the peroxisomal beta-oxidation system.     

Effect of clofibrate on intracellular enzyme distribution in the rat liver

The effect of chronic administration of a hypolipaemic agent--clofibrate--on the subcellular distribution of liver enzymes in male rats was studied. Clofibrate produced an increase in the number of peroxisomes and also enhanced the activity of aconitase and histidine: glyoxylate aminotransferase (HGA) in liver homogenate. Differential centrifugation of homogenate revealed an elevation of the relative amounts of catalase, HGA and isocitrate dehydrogenase in the soluble cell fraction in clofibrate pretreated animals. Clofibrate induced peroxisomal HGA but failed to alter the amounts of catalase, urate oxidase and isocitrate dehydrogenase in the particles. In both the experimental and control groups the activity of aconitase, malate dehydrogenase (NAD+), creatine phosphokinase and glutathione reductase was observed in mitochondrial fractions and was not detected in purified peroxisomes.