ATP-independent fatty acyl-coenzyme A synthesis from phospholipid: coenzyme A-dependent transacylation activity toward lysophosphatidic acid catalyzed by acyl-coenzyme A:lysophosphatidic acid acyltransferase

CoA-dependent transacylation activity in microsomes is known to catalyze the transfer of fatty acids between phospholipids and lysophospholipids in the presence of CoA without the generation of free fatty acids. We previously found a novel acyl-CoA synthetic pathway, ATP-independent acyl-CoA synthesis from phospholipids. We proposed that: 1) the ATP-independent acyl-CoA synthesis is due to the reverse reaction of acyl-CoA:lysophospholipid acyltransferases and 2) the reverse and forward reactions of acyltransferases can combine to form a CoA-dependent transacylation system. To test these proposals, we examined whether or not recombinant mouse acyl-CoA:1-acyl-sn-glycero-3-phosphate (lysophosphatidic acid, LPA) acyltransferase (LPAAT) could catalyze ATP-independent acyl-CoA synthetic activity and CoA-dependent transacylation activity. ATP-independent acyl-CoA synthesis was indeed found in the membrane fraction from Escherichia coli cells expressing mouse LPAAT, whereas negligible activity was observed in mock-transfected cells. Phosphatidic acid (PA), but not free fatty acids, served as an acyl donor for the reaction, and LPA was formed from PA in a CoA-dependent manner during acyl-CoA synthesis. These results indicate that the ATP-independent acyl-CoA synthesis was due to the reverse reaction of LPAAT. In addition, bacterial membranes containing LPAAT catalyzed CoA-dependent acylation of LPA; PA but not free fatty acid served as an acyl donor. These results indicate that the CoA-dependent transacylation of LPA consists of 1) acyl-CoA synthesis from PA through the reverse action of LPAAT and 2) the transfer of the fatty acyl moiety of the newly formed acyl-CoA to LPA through the forward reaction of LPAAT.     

Carnitine palmitoyltransferase activities: Effects of serum albumin,acyl-CoA binding protein and fatty acid binding protein

The carnitine palmitoyltransferase activity of various subcellular preparations measured with octanoyl-CoA as substrate was markedly increased by bovine serum albumin at low M concentrations of octanoyl-CoA. However, even a large excess (500 M) of this acyl-CoA did not inhibit the activity of the mitochondrial outer carnitine palmitoyltransferase, a carnitine palmitoyltransferase isoform that is particularly sensitive to inhibition by low M concentrations of palmitoyl-CoA. This bovine serum albumin stimulation was independent of the salt activation of the carnitine palmitoyltransferase activity. The effects of acyl-CoA binding protein (ACBP) and the fatty acid binding protein were also examined with palmitoyl-CoA as substrate. The results were in line with the findings of stronger binding of acyl-CoA to ACBP but showed that fatty acid binding protein also binds acyl-CoA esters. Although the effects of these proteins on the outer mitochondrial carnitine palmitoyltransferase activity and its malonyl-CoA inhibition varied with the experimental conditions, they showed that the various carnitine palmitoyltransferase preparations are effectively able to use palmitoyl-CoA bound to ACBP in a near physiological molar ratio of 1:1 as well as that bound to the fatty acid binding protein. It is suggested that the three proteins mentioned above effect the carnitine palmitoyltransferase activities not only by binding of acyl-CoAs, preventing acyl-CoA inhibition, but also by facilitating the removal of the acylcarnitine product from carnitine palmitoyltransferase. These results support the possibility that the acyl-CoA binding ability of acyl-CoA binding protein and of fatty acid binding protein have a role in acyl-CoA metabolismin vivo.Abbreviations ACBP acyl-CoA binding protein - BSA bovine serum albumin - CPT carnitine palmitoyltransferase - CPT₀ malonyl-CoA sensitive CPT of the outer mitochondrial membrane - CPT malonyl-CoA insensitive CPT of the inner mitochondrial membrane - OG octylglucoside - OMV outer membrane vesicles - IMV inner membrane vesicles Affiliated to the Department of Experimental Medicine, University of Montreal     

Peroxisomal fatty acyl-coenzyme A oxidation in chicken liver

The activities of antimycin A-insensitive palmitoyl-CoA oxidation and of palmitoyl-CoA oxidase in peroxisomes from chicken liver were similar to those of rat liver. Catalase and d-amino acid oxidase activities in peroxisomes from chicken liver were lower than those of rat liver and urate oxidase was not detected. Carnitine acetyltransferase and palmitoyltransferase levels in chicken liver were 18- and 2-fold higher, respectively, than those of rat liver. Peroxisomal palmitoyl-CoA oxidation of chicken liver was inhibited by cyanide, in contrast to that of rat liver, although it was insensitive to antimycin A. Subcellular distribution of this enzyme was similar to that of rat liver; i.e., it was located only in the peroxisomes. The fatty acyl-CoA oxidase had a higher affinity toward medium- to long-chain fatty acyl-CoAs (C₈ to C₁₆) than shorter-chain analogs. The fatty acyl-CoA dehydrogenase had a broad affinity toward fatty acyl-CoAs (C₄ to C₁₈). Carnitine acetyltransferase was distributed equally in both peroxisomes and mitochondria. Carnitine palmitoyltransferase was distributed in the proportion of 20 and 80% in peroxisomes and mitochondria, respectively.     

Free fatty acid determination by peroxidase catalysed luminol chemiluminescence

A sensitive, specific, and partly automatic method for the analysis of free fatty acids is described. The assay involves activation of free fatty acids by acyl-CoA synthetase (EC 6.2.1.3) followed by oxidation of the thioesters by acyl-CoA oxidase. The H₂O₂ formed is determined in a reaction catalysed by horseradish peroxidase (EC 1.11.1.7) using luminol as electron donor. The assay has a linear range of 0.05 to 5 nmol of different free fatty acids (C₁₀-C₁₈) in the original sample. The efficiency of the method toward capric, lauric, myristic, palmitic, palmitoleic, stearic, oleic, and linoleic acid measured as recovery of light emission compared to that of H₂O₂ standards, was over 90%. AffiGel 501 was used to covalently bind the free thiol group in CoASH eliminating interference of this substance in the peroxidase-luminol reaction.     

Regulatory effects of fatty acyl-coenzyme A derivatives on phosphate-activated pig brain and kidney glutaminase in vitro.

1. Fatty n-acyl-CoA derivatives in the concentration range 5muM-0.1mM and with 5-18 fatty acyl carbons have dual effects on phosphate-activated glutaminase from pig brain and kidney. Generally, fatty acyl-CoA derivatives in low concentrations activate the enzyme, but inhibit at higher concentrations; phosphate and citrate potentiate the activation, displaying positive co-operatively, and protect against inactivation. The fatty acyl-CoA derivatives affect glutaminase similarly to Bromothymol Blue, but differently from acetyl-CoA, which activates the enzyme only at very low phosphate or citrate concentrations. 2. Saturated fatty acyl-CoA derivatives, with 5-10 fatty acyl carbons, only activate the enzyme in the concentration range 0-0.1 mM. When the fatty acyl chain is elongated, the fatty acyl-CoA derivatives gradually become more powerful inhibitors of glutaminase at the expense of their activating capacity. In particular, palmitoyl-CoA and stearoyl-CoA are strong inhibitors at concentrations (10 muM) at which the corresponding free fatty acids and fatty acyl-carnitine derivatives have no effect. 3. The unsaturated fatty acyl-CoA derivatives, oleoyl-CoA and linoleoyl-CoA, behave as potent activators in the lower part of the concentration range tested (0-0.05mM), and as inhibitors in the upper part of this range (0.02-0.10mM). Oleic acid and linoleic acid have similar properties, but their activating capacity is less pronounced. 4. Phosphate both prevented and reversed the inhibition, but no restoration of activity was possible once the enzyme became inactivated. 5. By changing the pH from 7.0 to 8.0 the activating capacity of the fatty acyl-CoA derivatives is increased, as is their concentration range for activation. 6. The fatty acyl-CoA derivatives are somewhat more potent activator for brain glutaminase, but otherwise they affect the two enzymes similarly.     

Metabolism of propionic acid to a novel acyl-coenzyme A thioester by mammalian cell lines and platelets

Metabolism of propionate involves the activated acyl-thioester propionyl-CoA intermediate. We employed LC-MS/MS, LC-selected reaction monitoring/MS, and LC-high-resolution MS to investigate metabolism of propionate to acyl-CoA intermediates. We discovered that propionyl-CoA can serve as a precursor to the direct formation of a new six-carbon mono-unsaturated acyl-CoA. Time course and dose-response studies in human hepatocellular carcinoma HepG2 cells demonstrated that the six-carbon mono-unsaturated acyl-CoA was propionate-dependent and underwent further metabolism over time. Studies utilizing [¹³C₁]propionate and [¹³C₃]propionate suggested a mechanism of fatty acid synthesis, which maintained all six-carbon atoms from two propionate molecules. Metabolism of 2,2-[²H₂]propionate to the new six-carbon mono-unsaturated acyl-CoA resulted in the complete loss of two deuterium atoms, indicating modification at C2 of the propionyl moiety. Coelution experiments and isotopic tracer studies confirmed that the new acyl-CoA was trans-2-methyl-2-pentenoyl-CoA. Acyl-CoA profiles following treatment of HepG2 cells with mono-unsaturated six-carbon fatty acids also supported this conclusion. Similar results were obtained with human platelets, mouse hepatocellular carcinoma Hepa1c1c7 cells, human bronchoalveolar carcinoma H358 cells, and human colon adenocarcinoma LoVo cells. Interestingly, trans-2-methyl-2-pentenoyl-CoA corresponds to a previously described acylcarnitine tentatively described in patients with propionic and methylmalonic acidemia. We have proposed a mechanism for this metabolic route consistent with all of the above findings.     

Continuous recording of long-chain acyl-coenzyme a synthetase activity using fluorescently labeled bovine serum albumin

The fluorescence-based long-chain fatty acid probe BSA-HCA (bovine serum albumin labeled with 7-hydroxycoumarin-4-acetic acid) is shown to respond to binding of long-chain acyl-CoA thioesters by quenching of the 450 nm fluorescence emission. As determined by spectrofluorometric titration, binding affinities for palmitoyl-, stearoyl-, and oleoyl-CoA (Kd = 0.2-0.4 microM) are 5-10 times lower than those for the corresponding nonesterified fatty acids. In the presence of detergent (Chaps, Triton X-100, n-octylglucoside) above the critical micelle concentration, acyl-CoA partitions from BSA-HCA and into the detergent micelles. This allows BSA-HCA to be used as a fluorescent probe for continuous recording of fatty acid concentrations in detergent solution with little interference from acyl-CoA. Using a calibration of the fluorescence signal with fatty acids in the C14 to C20 chain-length range, fatty acid consumption by Pseudomonas fragi and rat liver microsomal acyl-CoA synthetase activities are measured down to 0.05 microM/min with a data sampling rate of 10 points per second. This new method provides a very promising spectrofluorometric approach to the study of acyl-CoA synthetase reaction kinetics at physiologically relevant (nM) aqueous phase concentrations of fatty acid substrates and at a time resolution that cannot be obtained in isotopic sampling or enzyme-coupled assays.     

A soluble acyl-coenzyme A oxidase from the yeast Candida utilis.

trans-2-Enoyl-CoA and two unidentified polar compounds were synthesized from the corresponding long-chain acyl-CoA by a particle-free supernatant fraction obtained from Candida utilis. The enzyme was unreactive toward free fatty acids but desaturated all long-chain acyl CoAs tested (14:0, 16:0, 18:1, 18:2). Molecular oxygen was the only required cofactor. Phenazine methosulfate and 2,6-dichloroindophenol did not replace the requirement for oxygen. The activity was inhibited specifically by NADPH and stimulated by linoleic acid or linolenic acid. The enzyme was not active in log phase cultures, but was detected only in stationary phase cells. Introduction of the trans-2-double bond was confirmed by gas-liquid chromatography, thin-layer chromatography, mass spectrometry, catalytic hydrogenation, oxidative cleavage, and chemical reactivity of the product toward nucleophilic addition.     

Brain acyl-coenzyme A hydrolase: distribution, purification and properties

Rat brain acyl-CoA hydrolase enzymes which hydrolyse C₂, C₄, C₈ and C₁₆ derivatives were localized primarily in the soluble, 144,000 g, supernatant fluid. With octanoyl-CoA as substrate, long-chain acyl-CoA hydrolase activity was greater in the pons, medulla and midbrain than in the cerebral cortex and caudate nucleus. The long-chain acyl-CoA hydrolase enzyme was purified from bovine brain stems to a specific activity of 4-61 n mol of palmitoyl-CoA hydrolysed per min per mg protein. The K_m values for palmitoyl-CoA and octanoyl-CoA were 5 μm and 14 μ/m , respectively. Activity of the enzyme was inhibited by bovine serum albumin and ρ-chloromercuribenzoate. The partially purified enzyme protein was found to have approximately eight titratable sulphydryl residues per 10⁵ g of protein. Studies of the molecular weight of the enzyme indicated the presence of associated and dissociated forms with molecular weights of approximately 96,000 and 46,000 respectively.     

Involvement of acyl exchange between acyl-CoA and phosphatidylcholine in the remodelling of phosphatidylcholine in microsomal preparations of rat lung

Microsomal membrane preparations from rat lung catalyse the incorporation of radioactive linolenic acid from [14C]linolenoyl-CoA into position 2 of sn-phosphatidylcholine. The incorporation was stimulated by bovine serum albumin and free CoA. Free fatty acids in the incubation mixtures were not utilised in the incorporation into complex lipids. Fatty acids were transferred to the acyl-CoA pool during the incorporation of linolenic acid into phosphatidylcholine. An increase in lysophosphatidylcholine occurred in incubations containing both bovine serum albumin and free CoA and in the absence of acyl-CoA. The results were consistent with an acyl-CoA: lysophosphatidylcholine acyltransferase operating in both a forwards and backwards direction and thus catalysing the acyl exchange between acyl-CoA and position 2 of sn-phosphatidylcholine. In incubations with mixed species of acyl-CoAs, palmitic acid was the major fatty acid substrate transferred to phosphatidylcholine in acyl exchange, whereas this acid was completely selected against in the acylation of added lysophosphatidylcholine. The selectivity for palmitoyl-CoA was particularly enhanced when the mixed acyl-CoA substrate was presented to the microsomes in molar concentrations equivalent to the molar ratios of the fatty acids in position 2 of sn-phosphatidylcholine. During acyl exchange, the predominant fatty acid transferred to phosphatidylcholine from acyl-CoA was palmitic acid, whereas arachidonic acid was particularly selected for in the reverse reaction from phosphatidylcholine to acyl-CoA. A hypothesis is presented to explain the differential selectivity for acyl species between the forward and backward reactions of the acyltransferase that is based upon different affinities of the enzyme for substrates at high and low concentrations of acyl donor. Acyl exchange between acyl-CoA and phosphatidylcholine offers, therefore, a possible mechanism for the acyl-remodelling of phosphatidylcholine for the production of lung surfactant.     

Production of stable isotope-labeled acyl-coenzyme A thioesters by yeast stable isotope labeling by essential nutrients in cell culture

Acyl-coenzyme A (CoA) thioesters are key metabolites in numerous anabolic and catabolic pathways, including fatty acid biosynthesis and β-oxidation, the Krebs cycle, and cholesterol and isoprenoid biosynthesis. Stable isotope dilution-based methodology is the “gold standard” for quantitative analyses by mass spectrometry. However, chemical synthesis of families of stable isotope-labeled metabolites such as acyl-CoA thioesters is impractical. Previously, we biosynthetically generated a library of stable isotope internal standard analogs of acyl-CoA thioesters by exploiting the essential requirement in mammals and insects for pantothenic acid (vitamin B5) as a metabolic precursor for the CoA backbone. By replacing pantothenic acid in the cell medium with commercially available [¹³C₃¹⁵N₁]-pantothenic acid, mammalian cells exclusively incorporated [¹³C₃¹⁵N₁]-pantothenate into the biosynthesis of acyl-CoA and acyl-CoA thioesters. We have now developed a much more efficient method for generating stable isotope-labeled CoA and acyl-CoAs from [¹³C₃¹⁵N₁]-pantothenate using stable isotope labeling by essential nutrients in cell culture (SILEC) in Pan6-deficient yeast cells. Efficiency and consistency of labeling were also increased, likely due to the stringently defined and reproducible conditions used for yeast culture. The yeast SILEC method greatly enhances the ease of use and accessibility of labeled CoA thioesters and also provides proof of concept for generating other labeled metabolites in yeast mutants.     

Palmitoyl-CoA synthetase on the external surface of isolated rat hepatocytes

After incubating isolated rat hepatocytes with [1-¹⁴C]palmitic acid, CoA and ATP (+MgCl₂), a significant amount of [1-¹⁴C]palmitoyl-CoA was found in the incubation medium. There was no correlation between its rate of synthesis and the degree of intactness of the cells. The results indicate that there is a long-chain fatty acyl-CoA synthetase active on the external surface of the hepatocyte plasma membrane. The activity of this enzyme was negligible in primary cultures of rat hepatocytes, suggesting that the exofacial long-chain acyl-CoA synthetase is an artifact of the collagenase perfusion technique used to prepare the hepatocytes.     

Monounsaturated fatty acyl-coenzyme A is predictive of atherosclerosis in human apoB-100 transgenic, LDLr-/- mice

ACAT2, the enzyme responsible for the formation of cholesteryl esters incorporated into apolipoprotein B-containing lipoproteins by the small intestine and liver, forms predominantly cholesteryl oleate from acyl-CoA and free cholesterol. The accumulation of cholesteryl oleate in plasma lipoproteins has been found to be predictive of atherosclerosis. Accordingly, a method was developed in which fatty acyl-CoA subspecies could be extracted from mouse liver and quantified. Analyses were performed on liver tissue from mice fed one of four diets enriched with one particular type of dietary fatty acid: saturated, monounsaturated, n-3 polyunsaturated, or n-6 polyunsaturated. We found that the hepatic fatty acyl-CoA pools reflected the fatty acid composition of the diet fed. The highest percentage of fatty acyl-CoAs across all diet groups was in monoacyl-CoAs, and values were 36% and 46% for the n-3 and n-6 polyunsaturated diet groups and 55% and 62% in the saturated and monounsaturated diet groups, respectively. The percentage of hepatic acyl-CoA as oleoyl-CoA was also highly correlated to liver cholesteryl ester, plasma cholesterol, LDL molecular weight, and atherosclerosis extent. These data suggest that replacing monounsaturated with polyunsaturated fat can benefit coronary heart disease by reducing the availability of oleoyl-CoA in the substrate pool of hepatic ACAT2, thereby reducing cholesteryl oleate secretion and accumulation in plasma lipoproteins.     

EFFECT OF FATTY-ACID DOUBLE-BOND POSITION ON THE SELECTIVITY OF RAT-BRAIN ENZYMES: THE INCORPORATION OF OLEIC AND CIS-VACCENIC ACIDS INTO LYSOLECITHIN IN VITRO

Abstract— —Selectivity in the esterification of fatty acids to lysolecithin by rat-brain enzymes in vitro was investigated using free fatty acids (activation plus esterification) and CoA esters (esterification) of two naturally-occurring monoenoic fatty-acid isomers, oleic acid [18:1 (n - 9)] and cis-vaccenic acid [18:1 (n - 7)]. Esterification of free acids to l-acyl-sn-glycero-3-phosphorylcholine (1-acyl GPC) was dependent on CoA and ATP, and was stimulated by MgCl₂ and NaF. Under comparable conditions, fatty-acid activation (acyl-CoA synthetase [acid: CoA ligase (AMP)] EC 6.2.1.3.) appeared to be rate-limiting to 1-acyl GPC acyltransferase (acyl-CoA:l-acylglycero-3-phosphocholine O-acyltrans-ferase, EC 2.3.1.23.), since rates were always less with free fatty acids than with the CoA esters. A comparison of substrate curves obtained with free fatty acids and CoA esters suggests a preference for oleic acid during activation. Acyltransferase activity with 2-acyl GPC was similar with both acyl-CoA isomers, whereas with 1-acyl GPC, activity with oleoyl-CoA consistently exceeded that with cis-vaccenoyl-CoA. This difference between patterns of selectivity in esterification of positions 1 and 2 of lecithin suggests that separate enzymes catalyze the two reactions. The transfer of the isomers to the 2 position was affected in a similar manner by changes in pH and temperature, as well as in protein, fatty acid (or acyl-CoA), and 1-acyl GPC concentrations. Patterns of incorporation with simultaneous incubation of both isomers suggests one enzyme. Differences in acyltransferase activity with the two isomerie acyl-CoA's were observed in subcellular distribution, activity changes with brain maturation, and loss of activity on preincubation of microsomes at 45C. From these results it is not certain whether oleic and cis-vaccenic acids are esterified to the 2 position by separate enzymes, or by one enzyme with different affinities for the isomers. However, the investigation clearly indicates that acyltransferases, and possibly acyl-CoA synthetases in brain possess selectivity related to subtle differences in double-bond position. These selectivities probably are important in determining the specific fatty-acid composition of the complex lipids of brain.     

Adipose triglyceride lipase activity is inhibited by long-chain acyl-coenzyme A

Adipose triglyceride lipase (ATGL) is required for efficient mobilization of triglyceride (TG) stores in adipose tissue and non-adipose tissues. Therefore, ATGL strongly determines the availability of fatty acids for metabolic reactions. ATGL activity is regulated by a complex network of lipolytic and anti-lipolytic hormones. These signals control enzyme expression and the interaction of ATGL with the regulatory proteins CGI-58 and G0S2. Up to date, it was unknown whether ATGL activity is also controlled by lipid intermediates generated during lipolysis. Here we show that ATGL activity is inhibited by long-chain acyl-CoAs in a non-competitive manner, similar as previously shown for hormone-sensitive lipase (HSL), the rate-limiting enzyme for diglyceride breakdown in adipose tissue. ATGL activity is only marginally inhibited by medium-chain acyl-CoAs, diglycerides, monoglycerides, and free fatty acids. Immunoprecipitation assays revealed that acyl-CoAs do not disrupt the protein–protein interaction of ATGL and its co-activator CGI-58. Furthermore, inhibition of ATGL is independent of the presence of CGI-58 and occurs directly at the N-terminal patatin-like phospholipase domain of the enzyme. In conclusion, our results suggest that inhibition of the major lipolytic enzymes ATGL and HSL by long-chain acyl-CoAs could represent an effective feedback mechanism controlling lipolysis and protecting cells from lipotoxic concentrations of fatty acids and fatty acid-derived lipid metabolites.     

Elongation of acyl-CoAs by microsomes from etiolated leek seedlings

Long chain fatty acid synthesis was studied using etiolated leek seedling microsomes. In the presence of ATP, [2-¹⁴C]malonyl-CoA was incorporated into fatty acids of C₁₆C₂₆. The omission of ATP, even in the presence of acetyl-CoA, led to a complete loss of activity, which was restored by addition of exogeneous acyl-CoAs. Comparison of acyl-CoA (C₁₂C₂₄) elongation showed that stearoyl-CoA, in the presence of [2-¹⁴C]malonyl-CoA, was the more efficient precursor leading to the formation of fatty acids having a chain length of C₂₀C₂₆. [1-¹⁴C]C₁₆CoA and [1-¹⁴C]C₁₈CoA were elongated in the presence of malonyl-CoA, without degradation of the acyl chain. The time-course and the malonyl-CoA concentration curves showed that [1-¹⁴C]C₁₈CoA was a better primer than [1-¹⁴C]C₁₆CoA. Acyl-CoA elongation was also studied over the concentration range 4.5–45 μM [1-¹⁴C]C₁₈CoA. Comparison of the radioactivity incorporated into the fatty acids formed using [2-¹⁴C]malonyl-CoA in the presence of C₁₈CoA, on the one hand, and [1-¹⁴C]C₁₈CoA in the presence of malonyl-CoA, on the other, demonstrated clearly that the acyl chain of the acyl-CoA was elongated by malonyl-CoA.     

Some properties and subcellular distribution of acyl-coenzyme A: retinol acyltransferase activity in rat testes

The present study was conducted to examine esterification of retinol by testicular microsomes. The microsomes were isolated from rat testes and were incubated under varying assay conditions with [3H]retinol. [3H]Retinylpalmitate was identified by reversed-phase high-performance liquid chromatography as an esterified product. The rate of esterification was increased by the addition of a fatty acyl-CoA. Coenzyme A esters of oleic, palmitic and stearic acids were equally effective substrates for retinol esterification. A 17-fold increase was observed in the presence of palmitoyl-CoA when microsomes had been pretreated with hydroxylamine, a reagent that reacts with coenzyme A thioesters to form hydroxamic acids. The esterifying activity was stimulated by the addition of dithiothreitol (4 mM) and fatty acid-free bovine serum albumin (1 mg/ml). The optimal concentrations for retinol and palmitoyl-CoA were 40 microM and 30-40 microM, respectively. The enzyme activity was inhibited by p-hydroxymercuribenzoate, sodium taurocholate and 5,5'-dithiobis-(2-nitrobenzoic acid), but not by EDTA. The enzyme activity was highest in microsomes (36%). However, some activity was present in mitochondria (29%). These results clearly show the presence of a fatty acyl-CoA: retinol acyltransferase that catalyzes the esterification of retinol in rat testes.     

Cellular fatty acid-binding proteins: current concepts and future directions

Summary At least three different proteins are implicated in the cellular transport of fatty acid moieties: a plasmalemmal membrane and a cytoplasmic fatty acid-binding protein (FABP_PM and FABP_C, respectively) and cytoplasmic acyl-CoA binding protein (ACBP). Their putative main physiological significance is the assurance that long-chain fatty acids and derivatives, either in transit through membranes or present in intracellular compartments, are largely complexed to proteins. FABP_C distinguishes from the other proteins in that distinct types of FABP_C are found in remarkable abundance in the cytoplasmic compartment of a variety of tissues. Although their mechanism of action is not yet fully elucidated, current knowledge suggests that the function of this set of proteins reaches beyond simply aiding cytoplasmic solubilization of hydrophobic ligands, but that they can be assigned several regulatory roles in cellular lipid homeostasis.     

Characterization of an acyl-coenzyme a thioesterase associated with the envelope of spinach chloroplasts

The enzymic hydrolysis of acyl-coenzyme A occurs in intact and purified chloroplasts. The different components of spinach chloroplasts were separated after a slight osmotic shock and the purified envelope membranes were shown to be the site of very active acyl-CoA thioesterase activity (EC 3.1.2.2.). The enzyme, which had a pH optimum of 9.0, was not affected by sulfhydryl reagents or by serine esterase inhibitors. However, the acyl-CoA thioesterase was strongly inhibited by unsaturated fatty acids, especially oleic acid, at concentrations above 100 micromolar. In marked contrast, saturated fatty acids had only a slight effect on the thioesterase activity. Substrate specificities showed that the velocity of the reaction increased with the chain length of the substrate from decanoyl-CoA to myristoyl-CoA and then decreased with the chain length from myristoyl-CoA to stearoyl-CoA. Interestingly, oleoyl-CoA was only slowly hydrolyzed. These results suggest that the envelope acyl-CoA thioesterase coupled with an envelope acyl-CoA synthetase may be involved in a switching system which indirectly allows acyl transfer from acyl carrier protein derivatives to unsaturated acyl-CoA derivatives and ensures the predominance of unsaturated 18 carbon fatty acids in plants. Furthermore, the position of both acyl-CoA thioesterase and synthetase in the envelope membranes suggest that these two enzymes may be involved in the transport of oleic acid from the stroma phase to the cytosol compartment of the leaf cell.