Long-chain acyl-CoA esters and acyl-CoA binding protein are present in the nucleus of rat liver cells.

A detailed analysis of the subcellular distribution of acyl-CoA esters in rat liver revealed that significant amounts of long-chain acyl-CoA esters are present in highly purified nuclei. No contamination of microsomal or mitochondrial marker enzymes was detectable in the nuclear fraction. C16:1 and C18:3-CoA esters were the most abundant species, and thus, the composition of acyl-CoA esters in the nuclear fraction deviates notably from the overall composition of acyl-CoA esters in the cell. After intravenous administration of the non-beta-oxidizable [(14)C]tetradecylthioacetic acid (TTA), the TTA-CoA ester could be recovered from the nuclear fraction. Acyl-CoA esters bind with high affinity to the ubiquitously expressed acyl-CoA binding protein (ACBP), and several lines of evidence suggest that ACBP functions as a pool former and transporter of acyl-CoA esters in the cytoplasm. By using immunohistochemistry, immunofluorescence microscopy, and immunoelectron microscopy we demonstrate that ACBP localizes to the nucleus as well as the cytoplasm of rat liver cell and rat hepatoma cells, suggesting that ACBP may also be involved in regulation of acyl-CoA-dependent processes in the nucleus.

Mitochondrial 3-hydroxy-3-methylglutaryl coenzyme A synthase and carnitine palmitoyltransferase II as potential control sites for ketogenesis during mitochondrion and peroxisome proliferation.

3-Thia fatty acids are potent hypolipidemic fatty acid derivatives and mitochondrion and peroxisome proliferators. Administration of 3-thia fatty acids to rats was followed by significantly increased levels of plasma ketone bodies, whereas the levels of plasma non-esterified fatty acids decreased. The hepatic mRNA levels of fatty acid binding protein and formation of acid-soluble products, using both palmitoyl-CoA and palmitoyl-L-carnitine as substrates, were increased. Hepatic mitochondrial carnitine palmitoyltransferase (CPT) -II and 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) synthase activities, immunodetectable proteins, and mRNA levels increased in parallel. In contrast, the mitochondrial CPT-I mRNA levels were unchanged and CPT-I enzyme activity was slightly reduced in the liver. The CoA ester of the monocarboxylic 3-thia fatty acid, tetradecylthioacetic acid, which accumulates in the liver after administration, inhibited the CPT-I activity in vitro, but not that of CPT-II. Acetoacetyl-CoA thiolase and HMG-CoA lyase activities involved in ketogenesis were increased, whereas the citrate synthase activity was decreased. The present data suggest that 3-thia fatty acids increase both the transport of fatty acids into the mitochondria and the capacity of the beta-oxidation process. Under these conditions, the regulation of ketogenesis may be shifted to step(s) beyond CPT-I. This opens the possibility that mitochondrial HMG-CoA synthase and CPT-II retain some control of ketone body formation.

On the effects of thia fatty acid analogues on hydrolases involved in the degradation of metabolisable and non-metabolisable acyl-CoA esters.

1. We investigated the nature and roles of various xenobiotic acyl-CoA hydrolases in liver subcellular fractions from rat treated with sulphur-substituted (thia) fatty acids. To contribute to our understanding of factors influencing enzymes involved in the degradation of activated fatty acids, the effects on these activities of the oppositely acting thia fatty acid analogues, the peroxisome proliferating 3-thia fatty acids (tetradecylthioacetic acid and 3-dithiacarboxylic acid), which are blocked for beta-oxidation, and a non-peroxisome-proliferating 4-thia fatty acid (tetradecylthiopropionic acid), which undergoes one cycle of beta-oxidation, were studied. 2. The hepatic subcellular distributions of palmitoyl-CoA, tetradecylthioacetyl-CoA and tetradecylthiopropionyl-CoA hydrolase activities were similar to each other in the control and 3-thia fatty acid-treated rat. In control animals, most of these hydrolases were located in the microsomal fraction, but after treatment with the 3-thia fatty acids, the specific activities of the mitochondrial, peroxisomal, and cytosolic palmitoyl-CoA, tetradecylthioacetyl-CoA, and tetradecylthiopropionyl-CoA hydrolase activities were significantly increased. This increase in activity was seen mostly for the enzymes using tetradecylthiopropionyl-CoA and tetradecylthioacetyl-CoA as substrates. The increased mitochondrial activities for these two substrates were seen already after 1 day of treatment, whereas the peroxisomal activities increased after 3 days. No stimulation was seen after treatment with the 4-thia fatty acid analogue, tetradecylthiopropionic acid, but a decrease in peroxisomal hydrolase activities for all three substrates was observed. 3. The cellular distributions of clofibroyl-CoA, POCA-CoA, and sebacoyl-CoA hydrolase activities were different from those of the 'long-chain acyl-CoA' hydrolases mentioned above both in the normal and 3-thia fatty acid treated rat. This group of hydrolases was found in the mitochondrial, peroxisomal, and cytosolic fractions. 3-Thia fatty acid treatment increased the activities of clofibroyl-CoA and sebacoyl-CoA hydrolases in all three fractions. Clofibroyl-CoA and sebacoyl-CoA hydrolase activities were increased after 1 day of treatment. Only the cytosolic POCA-CoA hydrolase was stimulated after 3-thia fatty acid treatment after only 1 day of treatment, whereas treatment with the 4-thia fatty acid led to an increase of enzyme activity in the mitochondrial and peroxisomal fractions. 4. Based on the subcellular distributions and specific activities, we suggest that several enzymes exist which may act as regulators of intracellular acyl-CoA levels.

Effect of 3-thia fatty acids on the lipid composition of rat liver, lipoproteins, and heart.

To investigate the importance of factors influencing the fatty acid composition, lipid and lipoprotein metabolism in the rat, the effect of 3-thia fatty acids of chain-length ranging from octyl- to hexadecylthioacetic acid were studied. In liver, very low density lipoprotein (VLDL), and low density lipoprotein (LDL), the hypolipidemic 3-thia fatty acids, namely C12-S-acetic acid to C14-S-acetic acid increased the amount of monoenes, especially oleic acid (18:ln-9). In contrast, the content of polyunsaturated fatty acids in liver, VLDL, and LDL decreased, mostly attributed to a reduction of eicosapentaenoic acid (EPA, 20:5n-3). Noteworthy, the hypolipidemic 3-thia fatty acids reduced the amount of arachidonic acid (AA, 20:4n-6) in LDL and HDL. 3-Thia fatty acids accumulated in the liver. In heart, as in liver, 3-thia fatty acids replaced fatty acids of chain-length homologues. In contrast to liver, we were unable to detect any changes in 18:ln-9. However, the n-3 polyunsaturated fatty acid content increased, particularly 20:5n-3 and docosahexaenoic acid (DHA, 22:6n-3) leading to an increased n-3/n-6 ratio. In conclusion, this study demonstrates that hypolipidemic 3-thia fatty acids change the fatty acid composition of organs and lipoproteins. These changes are linked to the expression and activity of hepatic delta9-desaturase, fatty acid oxidation, and displacement of normal fatty acids by 3-thia fatty acids. The fatty acid composition is regulated differently in liver and heart after administration of hypolipidemic 3-thia fatty acids.

Chronic administration of eicosapentaenoic acid and docosahexaenoic acid as ethyl esters reduced plasma cholesterol and changed the fatty acid composition in rat blood and organs.

Fish oils rich in n-3 fatty acids have been shown to decrease plasma lipid levels, but the underlying mechanism has not yet been elucidated. This investigation was performed in order to further clarify the effects of purified ethyl esters of eicosapentaenoic acid (EPA-EE) and docosahexaenoic acid (DHA-EE) on lipid metabolism in rats. The animals were fed EPA-EE, DHA-EE, palmitic acid, or corn oil (1 g/kg/d) by orogastric intubation along with a chow background diet for three months. At the end the animals were sacrificed. Plasma and liver lipids were measured, as well as lipid-related enzyme activities and mRNA levels. The fatty acid composition of plasma and different tissues was also determined. This study shows that, compared to the corn oil control, EPA-EE and DHA-EE lowered plasma cholesterol level, whereas only EPA-EE lowered the amount of plasma triacylglycerol. In liver peroxisomes, both EE preparations increased fatty acyl-CoA oxidase FAO activities, and neither altered 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase activities. In liver microsomes, EPA-EE raised HMG-CoA reductase and acyl-CoAicholesterol acyltransferase activities, whereas DHA-EE lowered the former and did not affect the latter. Neither product altered mRNA levels for HMG-CoA reductase, low density lipoprotein-receptor, or low density lipoprotein-receptor related protein. EPA-EE lowered plasma triacylglycerol, reflecting lowered very low density lipoprotein secretion, thus the cholesterol lowering effect in EPA-EE-treated rats may be secondary to the hypotriacylglycerolemic effect. An inhibition of HMG-CoA reductase activity in DHA-EE treated rats may contribute to the hypocholesterolemic effect. The present study reports that 20:5n-3, and not 22:6n-3, is the fatty acid primarily responsible for the triacylglycerol lowering effect of fish oil. Finally, 20:5n-3 was not converted to 22:6n-3, whereas retroconversion of 22:6n-3 to 20:5n-3 was observed.

Tetradecylthioacetic acid incorporated into very low density lipoprotein: changes in the fatty acid composition and reduced plasma lipids in cholesterol-fed hamsters.

The mechanism behind the hypolipidemic effect of tetradecylthioacetic acid (CMTTD, a non-beta-oxidizable 3-thia fatty acid) was studied in hamsters fed a high cholesterol diet (2%), which resulted in hyperlipidemia. Treating hyperlipidemic hamsters with CMTTD resulted in a progressive hypocholesterolemic and hypotriacylglycerolemic effect. Decreased plasma cholesterol was followed by a 39% and 30% reduction in VLDL-cholesterol and LDL-cholesterol, respectively. In contrast, the HDL-cholesterol content was not affected, thus decreasing the VLDL-cholesterol/HDL-cholesterol and LDL-cholesterol/HDL-cholesterol ratios. 3-Hydroxy-3-methylglutaryl- (HMG) CoA reductase activity and its mRNA level were unchanged after CMTTD administration. Also, the LDL receptor and LDL receptor-related protein (LRP-4) mRNAs were unchanged. The decrease in plasma triacylglycerol was accompanied by a 45% and 56% reduction in VLDL-triacylglycerol and LDL-triacylglycerol, respectively. The hypolipidemic effect of CMTTD was followed by a 1.4-fold increase in mitochondrial fatty acid oxidation and a 2.3-fold increase in peroxisomal fatty acid oxidation. CMTTD treatment led to an accumulation of dihomo-gamma-linolenic acid (20:3n-6) in liver, plasma, very low density lipoprotein, and heart. Noteworthy, CMTTD accumulated more in the heart, plasma, and VLDL particles compared to the liver, and in the VLDL particle alpha-linolenic acid (18:3n-3) decreased whereas eicosatetraenoic acid (20:4n-3) increased. In addition, linoleic acid (18:2n-6) and the total amount of polyunsaturated fatty acids decreased, the latter mainly due to a decrease in n-6 fatty acids. The present data show that CMTTD was detected in plasma and incorporated into VLDL, liver, and heart. The relative incorporation (mol%) of CMTTD was heart > VLDL > liver. In conclusion, CMTTD causes both a hypocholesterolemic and hypotriacylglycerolemic effect in hyperlipidemic hamsters.

Rapid method for the separation and detection of tissue short-chain coenzyme A esters by reversed-phase high-performance liquid chromatography.

A simple and rapid method for the separation and identification of tissue levels of short chain coenzyme A (CoA) esters by a reversed-phase high-performance liquid chromatography with ultraviolet-visible adsorbance detection is described. Samples of liver, heart and kidney tissues were homogenised in 5% sulfosalicylic acid containing 50 microM of dithioerythritol in 1:9 w/v proportion. Following centrifugation, 20 microliters of the supernatant were directly injected onto a 3-micron ODS C18 column (100 x 4.6 mm I.D.). The separation of acetyl-CoA, malonyl-CoA, methylmalonyl-CoA, succinyl-CoA, propionyl-CoA and free CoASH was achieved in less than 20 min using gradient elution with sodium phosphate, sodium acetate and methanol at a constant flow-rate of 1.5 ml/min. The lowest detection limit was 3 pmol.

Subcellular localisation and induction of NADH-sensitive acetyl-CoA hydrolase and propionyl-CoA hydrolase activities in rat liver under lipogenic conditions after treatment with sulfur-substituted fatty acids.

The effects of sulfur-substituted fatty acid analogues on the subcellular distribution and activities of acetyl-CoA and propionyl-CoA hydrolases in rats fed a high carbohydrate diet were studied. Among subcellular fractions of liver homogenates from rats fed a high carbohydrate diet (20%), the acetyl-CoA and propionyl-CoA hydrolase activities are found in the mitochondrial, peroxisome-enriched and cytosolic fractions. We have shown that the subcellular distribution of acetyl-CoA hydrolase appears to be different from the distribution propionyl-CoA hydrolase activity. Thus, the highest specific activity of acetyl-CoA hydrolase was found in the mitochondrial fraction, whereas the highest specific activity of propionyl-CoA hydrolase was found in the peroxisome-enriched fraction. Rats treated with sulfur-substituted fatty acids, i.e., 3-thiadicarboxylic acid (400 mg/day per kg body weight), showed a significant increase in acetyl-CoA hydrolase activity where the peroxisomal and cytosolic hydrolases were increased 3.9- and 2.7-fold, respectively, compared to palmitic acid treated rats. Similar results were obtained with tetradecylthioacetic acid treated rats. Propionyl-CoA hydrolase activities, in rats treated with these two peroxisome proliferating fatty acid analogues showed increased activity mainly in the mitochondrial and the cytosolic subcellular fractions. Acetyl-CoA hydrolase activity was sensitive to NADH, whereas no stimulation of the propionyl-CoA hydrolase activity was observed in the presence of NADH. The hepatic amounts of acetyl-CoA, propionyl-CoA, and free CoASH were elevated after sulfur-substituted fatty acid treatment. Sulfur-substituted fatty acids also elevated the specific acetyl-CoA hydrolase activity in the mitochondrial fraction and the propionyl-CoA hydrolase activity in the light-mitochondrial fraction. These results, therefore, suggest that acetyl-CoA hydrolase and propionyl-CoA hydrolase are two distinct proteins and that these two enzymes have a multiorganelle localisation.

Homocysteine remethylation during nitrous oxide exposure of cells cultured in media containing various concentrations of folates.

Nitrous oxide irreversibly inactivates cob(I)alamin, which serves as a cofactor of the enzyme methionine synthase catalyzing the remethylation of homocysteine to methionine. In patients exposed to nitrous oxide, increase in plasma homocysteine is a responsive indicator of cob(I)alamin inactivation. In the present work, we measured the inactivation of methionine synthase and the concurrent homocysteine export rate of two murine and four human cell lines during nitrous oxide exposure. When cultured in a standard medium with high content (2.3 microM) of folic acid, the methionine synthase of all cell types was inactivated at an initial rate of 0.05 to 0.14 h-1. The inactivation curves leveled off, and a residual activity of 15 to 45% was observed after 48 h of nitrous oxide exposure. The rate and extent of the nitrous oxide-induced inactivation were markedly reduced when the cells were transferred and cultured (greater than 10 days) in a medium containing low concentration (10 nM) of 5-methyltetrahydrofolate. The methionine synthase inactivation increased in a dose-dependent manner when the 5-methyltetrahydrofolate content of the medium was increased from 3 nM to 2.3 microM. The inactivation of methionine synthase was associated with a marked enhancement of homocysteine export rate of murine fibroblasts and a moderate increase in export from two human glioma cell lines. In contrast, in three leukemic cell lines (murine T-lymphoma R 1.1 cells, human promyelocytic leukemia HL-60 cells and human acute myelogenous leukemia KG-1a cells), the homocysteine export rates were not increased during nitrous oxide exposure. In the responsive murine fibroblasts and the glioma cells, the homocysteine export rate varied inversely to the changes in methionine synthase activity induced by nitrous oxide exposure at different concentrations of folate in the medium. The enhancement of homocysteine export rate of some cell types during nitrous oxide exposure probably reflects inhibition of homocysteine remethylation in intact cells, and highlights the utility of extracellular homocysteine as an indicator of metabolic flux through the methionine synthase pathway. No enhancement of homocysteine export despite inactivation of methionine synthase in three leukemic cell lines questions the functional state of the enzyme in these cells.

A nonradioactive assay for N5-methyltetrahydrofolate-homocysteine methyltransferase (methionine synthase) based on o-phthaldialdehyde derivatization of methionine and fluorescence detection.

The enzyme N5-methyltetrahydrofolate-homocysteine methyltransferase (methionine synthase, EC 2.1.1.13) catalyzes the conversion of homocysteine to methionine in the presence of a reducing system. N5-Methyltetrahydrofolate serves as a methyl donor in this reaction. An assay for the enzyme is described, which is based on methionine quantitation by o-phthaldialdehyde (OPA) derivatization and reversed-phase liquid chromatography. The enzymatic reaction is linear for at least 120 min under reducing conditions (125 mM 2-mercaptoethanol) and running the assay below an oil layer. This reducing system does not interfere with formation of the methionine-OPA adduct, which is separated from interfering compounds and an internal standard (norvaline) by a mobile phase adjusted to pH 5.0. The inclusion of internal standard increases the precision of the assay and corrects for the variable fluorescence yield due to occasional inaccurate pH adjustment before the derivatization step. Norvaline was suitable for this purpose because it elutes close to methionine and is not a natural amino acid present in biological extracts. This nonradioactive assay for methionine synthase was evaluated by comparison with a conventional method based on isolation of radioactive methionine by anion-exchange chromatography and by determination of enzyme activity in extract from cultured cells and liver.