Detection of acyl-coenzyme a thioester intermediates of fatty acid β-oxidation as the N-acylglycines by negative-ion chemical ionization gas chromatography—Mass spectrometry

An analytical method for the separation and quantitation of acyl-CoA thioesters by gas chromatography—Mass spectrometry is described. The method utilizes glycine aminolysis of the acyl-CoA thiolesters, esterification with pentafluorobenzyl bromide followed by gas chromatographic separation, and detection by negative chemical ionization mass spectrometry of the N-acyl-pentafluorobenzyl glycinates. The glycine aminolysis provides over 100-fold discrimination against oxygen esters and obviates the difficulty of removing trace contaminants of free fatty acids. The limit of detection of the described methodology for palmitoyl-CoA has been found to be 300 fmol, which improves at shorter chain lengths. Baseline separation was obtained for a standard mixture of seven acyl-CoAs (60 pmol injected) containing butyryl-CoA, hexanoyl-CoA, octanoyl-CoA, decanoyl-CoA, lauroyl-CoA, myristoyl-CoA, and palmitoyl-CoA. The above procedure is also applicable to the α-β unsaturated and 3-hydroxyacyl-CoA derivatives, making it possible to quantify all of the intermediates in fatty acid oxidation, except the 3-ketoacyl-CoAs, in a single procedure.     

Peroxisomal beta-oxidation of long-chain fatty acids possessing different extents of unsaturation.

Rates of peroxisomal beta-oxidation were measured as fatty acyl-CoA-dependent NAD+ reduction, by using solubilized peroxisomal fractions isolated from livers of rats treated with clofibrate. Medium- to long-chain saturated fatty acyl-CoA esters as well as long-chain polyunsaturated fatty acyl-CoA esters were used. Peroxisomal beta-oxidation shows optimal specificity towards long-chain polyunsaturated acyl-CoA esters. Eicosa-8,11,14-trienoyl-CoA, eicosa-11,14,17-trienoyl-CoA and docosa-7,10,13,16-tetraenoyl-CoA all gave Vmax. values of about 150% of that obtained with palmitoyl-CoA. The Km values obtained with these fatty acyl-CoA esters were 17 +/- 6, 13 +/- 4 and 22 +/- 3 microM respectively, which are in the same range as the value for palmitoyl-CoA (13.8 +/- 1 microM). Myristoyl-CoA gave the higher Vmax. (110% of the palmitoyl-CoA value) of the saturated fatty acyl-CoAs tested. Substrate inhibition was mostly observed with acyl-CoA esters giving Vmax. values higher than 50% of that given by palmitoyl-CoA.     

CoA- and non-CoA-dependent retinol esterification in retinal pigment epithelium

Washed, buffered microsomes from bovine retinal pigment epithelium catalyze retinyl ester synthesis from retinol in the absence of an exogenous acyl donor. A plot of retinyl ester synthesis versus time reaches a plateau at 123 +/- 26 nmol of retinyl ester mg-1 microsomal protein, providing a minimum value of the concentration of the endogenous acyl donor. Fatty acyl-CoA analysis by three different methods employing high performance liquid chromatography resulted in the detection of less than 1 nmol mg-1 protein of acyl-CoA, indicating that fatty acyl-CoA is not the endogenous acyl donor. Stimulation of the rate of retinyl ester synthesis by palmitoyl-CoA or ATP, CoA, and palmitate is observed following its addition at the beginning of the reaction or after the endogenous acyl source has been exhausted by 20 min of reaction with retinol. Palmitate from [14C]palmitoyl-CoA is incorporated into retinyl ester at a rate similar to that for the incorporation of [3H] retinol, demonstrating the presence of an apparent acyl-CoA:retinol acyl transferase activity. The acyl group from palmitoyl-CoA can be transferred initially to a component of the microsomes and subsequently to retinol. The product of retinyl ester synthesis from all-trans-retinol and palmitoyl-CoA is all-trans-retinyl palmitate, indicating that the stereochemical configuration is retained during esterification. The kinetic parameters for the esterification of 11-cis-retinol and all-trans-retinol are similar.     

Palmitoyl-coenzyme A synthetase. Isolation of an enzyme-bound intermediate

An enzyme-bound intermediate of the overall reaction catalysed by rat liver microsomal long-chain fatty acyl-CoA synthetase is described. It was found to contain equimolar amounts of adenylate and fatty acid moieties bound to protein, and was stabilized by ATP. The intermediate reacted with CoA to give palmitoyl-CoA.     

Fatty acyl-coenzyme A is required for budding of transport vesicles from Golgi cisternae

We describe a new role for fatty acylation. Conditions were established under which vesicular transport from the cis to the medial Golgi compartment in vitro depends strongly upon the addition of a fatty acyl-coenzyme A, e.g., palmitoyl-CoA. Using an inhibitor of long-chain acyl-CoA synthetase, we demonstrate that the fatty acid has to be activated by CoA to stimulate transport. A nonhydrolyzable analog of palmitoyl-CoA competitively inhibits transport. Electron microscopy and biochemical studies show that fatty acyl-CoA is required for budding of (non-clathrin-) coated transport vesicles from Golgi cisternae and that budding is inhibited by the nonhydrolyzable analog.     

Determination of CoASH by high-performance liquid chromatography and its application in the assay of long-chain acyl-CoA derivatives.

A high-performance liquid chromatographic procedure is described for the determination of picomole amounts of CoASH, using a microparticulate, strong anion-exchange resin. The method was applied in a systematic study to optimize the conditions for alkaline hydrolysis of palmitoyl-CoA. The procedure, which ensures 100% recovery of CoASH by hydrolysis of paimitoyl-CoA, was found to be convenient also for the assay of the endogenous content of long-chain acyl-CoA derivatives in biological material.     

Acyl-CoA synthetase and the peroxisomal enzymes of beta-oxidation in human liver. Quantitative analysis of their subcellular localization.

The presence of acyl-CoA synthetase (EC 6.2.1.3) in peroxisomes and the subcellular distribution of beta-oxidation enzymes in human liver were investigated by using a single-step fractionation method of whole liver homogenates in metrizamide continuous density gradients and a novel procedure of computer analysis of results. Peroxisomes were found to contain 16% of the liver palmitoyl-CoA synthetase activity, and 21% and 60% of the enzyme activity was localized in mitochondria and microsomal fractions respectively. Fatty acyl-CoA oxidase was localized exclusively in peroxisomes, confirming previous results. Human liver peroxisomes were found to contribute 13%, 17% and 11% of the liver activities of crotonase, beta-hydroxyacyl-CoA dehydrogenase and thiolase respectively. The absolute activities found in peroxisomes for the enzymes investigated suggest that in human liver fatty acyl-CoA oxidase is the rate-limiting enzyme of the peroxisomal beta-oxidation pathway, when palmitic acid is the substrate.     

Fatty acid biosynthesis in Erlich cells. The mechanism of short term control by exogenous free fatty acids.

We have examined the mechanism by which extracellular free fatty acids regulate fatty acid biosynthesis in Ehrlich ascites tumor cells. De novo biosynthesis in intact cells was inhibited by stearate greater than oleate greater than palmitate greater than linoleate. The amount of citrate and long chain acyl-CoA in the cells was not changed appreciably by the addition of free fatty acids to the incubation medium, indicating than free fatty acids do not regulate fatty acid biosynthesis by changing the total intracellular content of these metabolites. By measuring the incorporation of labeled free fatty acids into acyl-CoA, however, it was determined that the fatty acid composition of the acyl-CoA poolwas changed dramatically to reflect the composition of the exogenous free fatty acids. The relative inhibitory effects of different free fatty acids appear to depend on the ability of their acyl-CoA derivatives to regulate acyl-CoA carboxylase activity. The acyl-CoA concentration needed to produce 50% inhibition of purified Ehrlich cell carboxylase was found to be 0.68 mum for stearoyl-CoA, 1.6 mum for oleoyl-CoA, 2.2 mum for palmitoyl-CoA, 23 mum for myristoyl-CoA, 30 mum for lauroyl-CoA, and 37 mum for linoleoyl-CoA. In contrast to their effects on de novo synthesis, all of the free fatty acids added except stearate stimulated chain elongation in intact cells. Microsomal chain elongation, the major system for elongation in Ehrlich cells, also was regulated by the composition of the cellular acyl-CoA pool. Lauroyl-CoA, myristoyl-CoA, and palmitoyl-CoA were good substrates for elongation by isolated microsomes; oleoyl-CoA, and linoleoyl-CoA were intermediate; and stearoyl-CoA was a very poor substrate. We conclude that free fatty acids regulate fatty acid biosynthesis by changing the composition of the cellular acyl-CoA pool. These changes control the rate of malonyl-CoA production and, because of the acyl-CoA substrate specificity of the microsomal elongation system, modulate the amount of malonyl-CoA used for chain elongation.     

High sensitivity quantitative lipidomics analysis of fatty acids in biological samples by gas chromatography-mass spectrometry

Historically considered to be simple membrane components serving as structural elements and energy storing entities, fatty acids are now increasingly recognized as potent signaling molecules involved in many metabolic processes. Quantitative determination of fatty acids and exploration of fatty acid profiles have become common place in lipid analysis. We present here a reliable and sensitive method for comprehensive analysis of free fatty acids and fatty acid composition of complex lipids in biological material. The separation and quantitation of fatty acids are achieved by capillary gas chromatography. The analytical method uses pentafluorobenzyl bromide derivatization and negative chemical ionization gas chromatography-mass spectrometry. The chromatographic procedure provides base line separation between saturated and unsaturated fatty acids of different chain lengths as well as between most positional isomers. Fatty acids are extracted in the presence of isotope-labeled internal standards for high quantitation accuracy. Mass spectrometer conditions are optimized for broad detection capacity and sensitivity capable of measuring trace amounts of fatty acids in complex biological samples. .     

Steady-state concentrations of coenzyme A, acetyl-coenzyme A and long-chain fatty acyl-coenzyme A in rat-liver mitochondria oxidizing palmitate

1. Fluorimetric assays are described for CoASH, acetyl-CoA and long-chain fatty acyl-CoA, and are sensitive to at least 50mumumoles of each. 2. Application of these assays to rat-liver mitochondria oxidizing palmitate in the absence and presence of carnitine indicated two pools of intramitochondrial CoA. One pool could be acylated by palmitate and ATP, and the other pool acylated by palmitate with ATP and carnitine, or by palmitoylcarnitine alone. 3. The intramitochondrial content of acetyl-CoA is increased by the oxidation of palmitate both in the absence and presence of l-malate. 4. The conversion of palmitoyl-CoA into acetyl-CoA by beta-oxidation takes place without detectable accumulation of acyl-CoA intermediates.     

Characterization of a fatty acyl-CoA reductase from Marinobacter aquaeolei VT8: a bacterial enzyme catalyzing the reduction of fatty acyl-CoA to fatty alcohol

Fatty alcohols are of interest as a renewable feedstock to replace petroleum compounds used as fuels, in cosmetics, and in pharmaceuticals. One biological approach to the production of fatty alcohols involves the sequential action of two bacterial enzymes: (i) reduction of a fatty acyl-CoA to the corresponding fatty aldehyde catalyzed by a fatty acyl-CoA reductase, followed by (ii) reduction of the fatty aldehyde to the corresponding fatty alcohol catalyzed by a fatty aldehyde reductase. Here, we identify, purify, and characterize a novel bacterial enzyme from Marinobacter aquaeolei VT8 that catalyzes the reduction of fatty acyl-CoA by four electrons to the corresponding fatty alcohol, eliminating the need for a separate fatty aldehyde reductase. The enzyme is shown to reduce fatty acyl-CoAs ranging from C8:0 to C20:4 to the corresponding fatty alcohols, with the highest rate found for palmitoyl-CoA (C16:0). The dependence of the rate of reduction of palmitoyl-CoA on substrate concentration was cooperative, with an apparent K(m) ~ 4 μM, V(max) ~ 200 nmol NADP(+) min(-1) (mg protein)(-1), and n ~ 3. The enzyme also reduced a range of fatty aldehydes with decanal having the highest activity. The substrate cis-11-hexadecenal was reduced in a cooperative manner with an apparent K(m) of ~50 μM, V(max) of ~8 μmol NADP(+) min(-1) (mg protein)(-1), and n ~ 2.     

Synthesis and characterization of cis-4-decenoyl-CoA, 3-phenylpropionyl-CoA, and 2,6-dimethylheptanoyl-CoA

The measurement of acyl-CoA dehydrogenase activities is an essential part of the investigation of patients with suspected defects in fatty acid oxidation. Multiple methods are available for the synthesis of the substrates used for measuring acyl-CoA dehydrogenase activities; however, the yields are low and the products are used without purification. In addition, the reported characterization of acyl-CoAs focuses on the CoA moiety, not on the acyl group. Here we describe the synthesis of three medium-chain acyl-CoAs from mixed anhydrides of the fatty acids using an aqueous-organic solvent mixture optimized to obtain the highest yield. First, cis-4-decenoic acid and 2,6-dimethylheptanoic acid were prepared (3-phenylpropionic acid is commercially available). These were characterized by gas chromatography/mass spectrometry (GC/MS), ¹H nuclear magnetic resonance (NMR), and ¹³C NMR. Then cis-4-decenoyl-CoA, 3-phenylpropionyl-CoA, and 2,6-dimethylheptanoyl-CoA were synthesized. These were then purified by ion exchange solid-phase extraction using 2-(2-pyridyl)ethyl-functionalized silica gel, followed by reversed-phase semipreparative high-performance liquid chromatography with ultraviolet detection (HPLC-UV). The purified acyl-CoAs were characterized by analytical HPLC-UV followed by data-dependent tandem mass spectrometry (MS/MS) analysis on the largest responding MS mass (HPLC-UV-MS-MS/MS) and ¹³C NMR. The yields of the purified acyl-CoAs were between 75% and 78% based on coenzyme A trilithium salt (CoASH). Acyl-CoA dehydrogenase activities were measured in rat skeletal muscle mitochondria using, as substrates, the synthesized cis-4-decenoyl-CoA, 3-phenylpropionyl-CoA, and 2,6-dimethylheptanoyl-CoA. These results were compared with the results using our standard substrates butyryl-CoA, octanoyl-CoA, and palmitoyl-CoA.     

Control of cardiac sodium pump by long-chain acyl coenzymes A

Since we had shown recently that fatty acyl-CoA derivatives stimulate (Na+ + K+)-ATPase activity at suboptimal ATP concentrations, we used sealed vesicles of beef heart sarcolemma to examine the effects of these compounds on the transport function of the enzyme. The sodium pump was detected in inside-out vesicles as a component of Na+ uptake that was dependent on intravesicular (extracellular) K+ and extravesicular (intracellular) ATP and was sensitive to vanadate and digitoxigenin. The pump flux was stimulated without a lag by palmitoyl-CoA (K0.5 = 3 microM) when ATP concentration was 50 microM, but not when it was 2 mM. Saturating palmitoyl-CoA reduced the K0.5 of ATP for the pump by a factor of 3-6. Raising the intracellular K+ concentration increased the K0.5 of ATP, and this effect of K+ was antagonized by palmitoyl-CoA. At concentrations up to 0.5 mM, palmitoyl-CoA had no effect on ATP-independent (passive) Na+ uptake. All tested long-chain acyl-CoA derivatives had effects similar to that of palmitoyl-CoA; but CoA, acetyl-CoA, and palmitic acid were ineffective. Palmitoyl carnitine and docosahexanoic acid, amphiphilic compounds with inhibitory and biphasic effects on the hydrolytic activity of purified (Na+ + K+)-ATPase, had purely inhibitory effects on the pump at high concentrations that also affected the passive fluxes. The data support the proposition that fatty acyl-CoA derivatives mimic the effect of ATP at a regulatory site and suggest that these intracellular liponucleotides may be involved in the control of the pump.     

Purification of rabbit myocardial cytosolic acyl-CoA hydrolase, identity with lysophospholipase, and modulation of enzymic activity by endogenous cardiac amphiphiles

Rabbit myocardial cytosolic acyl coenzyme A (acyl-CoA) hydrolase activity was purified to near-homogeneity by ammonium sulfate precipitation and ion-exchange, gel filtration, chromatofocusing, and hydroxylapatite chromatographies. Kinetic analysis of the purified protein demonstrated a maximum velocity of 24 mumol/(mg . min) and an apparent Michaelis constant of 50 microM. Cytosolic acyl-CoA hydrolase and lysophospholipase activities cochromatographed in every fraction of every step. The purified protein was a single band (Mr 23 000) after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and silver staining. These results suggest that cytosolic lysophospholipase and palmitoyl-CoA hydrolase activities are catalyzed by a single polypeptide with dual activities. Palmitoyl-CoA competitively inhibited lysophospholipase activity (Ki = 4 microM). Low concentrations (20 microM) of lysophosphatidylcholine or L-palmitoylcarnitine increased palmitoyl-CoA hydrolase activity at low palmitoyl-CoA concentrations but had little effect at high concentrations of palmitoyl-CoA. In contrast, high concentrations (100 microM) of lysophosphatidylcholine or L-palmitoylcarnitine inhibited palmitoyl-CoA hydrolase activity. The results suggest that interactions between endogenous cardiac amphiphiles and palmitoyl-CoA hydrolase contribute to the regulation of intracellular long-chain acyl-CoA concentrations and therefore potentially modulate fluxes of fatty acid through several biochemical pathways.     

Inhibition in vitro of acyl-CoA dehydrogenases by 2-mercaptoacetate in rat liver mitochondria.

In rat liver hypo-osmotically treated mitochondria, 2-mercaptoacetate inhibits respiration induced by palmitoyl-CoA, octanoate or butyryl-CoA only when the reaction medium is supplemented with ATP. Under this condition, NADH-stimulated respiration is not affected. In liver mitochondrial matrix, the presence of ATP is also required to observe a 2-mercaptoacetate-induced inhibition of acyl-CoA dehydrogenases tested with palmitoyl-CoA, butyryl-CoA or isovaleryl-CoA as substrate. As the oxidation of these substrates is also inhibited by the incubation medium resulting from the reaction of 2-mercaptoacetate with acetyl-CoA synthase, with conditions under which 2-mercaptoacetate has no effect, 2-mercaptoacetyl-CoA seems to be the likely inhibitory metabolite responsible for the effects of 2-mercaptoacetate. Kinetic experiments show that the main effect of the 2-mercaptoacetate-active metabolite is to decrease the affinities of fatty acyl-CoA dehydrogenases towards palmitoyl-CoA or butyryl-CoA and of isovaleryl-CoA dehydrogenase towards isovaleryl-CoA. Addition of N-ethylmaleimide to mitochondrial matrix pre-exposed to 2-mercaptoacetate results in the immediate reversion of the inhibitions of palmitoyl-CoA and isovaleryl-CoA dehydrogenations and in a delayed reversion of butyryl-CoA dehydrogenation. These results led us to conclude that (i) the ATP-dependent conversion of 2-mercaptoacetate into an inhibitory metabolite takes place in the liver mitochondrial matrix and (ii) the three fatty acyl-CoA dehydrogenases and isovaleryl-CoA dehydrogenase are mainly competitively inhibited by this compound. Finally, the present study also suggests that the inhibitory metabolite of 2-mercaptoacetate may bind non-specifically to, or induce conformational changes at, the acyl-CoA binding sites of these dehydrogenases.     

Developmental changes in the characteristics of peroxisomal fatty acid oxidation system in rat liver

Developmental changes in fatty acid oxidation system of rat liver peroxisomes were studied to compare with that of mitochondria. More apparent enhancement of peroxisomal palmitoyl-CoA oxidase was observed than mitochondrial palmitoyl-CoA dehydrogenase during prenatal (20-day fetal) to neonatal (1-day after birth) period. The characteristics of peroxisomal enzymes, fatty acyl-CoA oxidase and carnitime acyltransferase, on the bases of substrate specificities, were rapidly established within the 1 day after birth accompanied by the marked enhancement of these activities. These findings indicate that peroxisomal fatty acid oxidation system plays an important role for early growth of neonatal rats; this system may contribute to supplying short- to medium-chain fatty acyl-CoA and NADH₂ for mitochondrial energy formation system.     

Regulation of palmitoyl-CoA inhibition of mitochondrial adenine nucleotide transport by cytosolic fatty acid binding protein.

Defatted liver fatty acid binding protein (FABP) reverses the inhibitory effect of palmitoyl-CoA on adenine nucleotide transport in rat liver mitochondria; addition of titrating amounts of FABP to mitochondria pretreated with palmitoyl-CoA stimulates nucleotide transport and that activation parallels the removal of the inhibitor from mitochondria. This effect is specific only for FABP; all other cytosolic proteins which do not bind fatty acids do not influence nucleotide transport activity. Addition of free fatty acids (which can compete for ligand binding sites on FABP) to mitochondria pretreated with palmitoyl-CoA interferes with the reversal activity of FABP. Adding FABP alone to freshly isolated mitochondria also activates nucleotide transport activity suggesting that the originally submaximal activity is probably due to the presence of endogenous long-chain acyl-CoA esters in the mitochondrial preparation. Because FABP is present in relatively high concentration in most mammalian cells, these observations offer a likely explanation of why the potent inhibitory effects of long-chain acyl-CoA esters on adenine nucleotide transport in isolated mitochondria are not seen in the intact cell.     

Fatty acid metabolism in liver of rats treated with hypolipidemic sulphur-substituted fatty acid analogues

The purpose of this study was to investigate early biochemical changes and possible mechanisms via which alkyl(C12)thioacetic acid (CMTTD, blocked for beta-oxidation), alkyl(C12)thiopropionic acid (CETTD, undergo one cycle of beta-oxidation) and a 3-thiadicarboxylic acid (BCMTD, blocked for both omega- (and beta-oxidation) influence the peroxisomal beta-oxidation in liver of rats. Treatment of rats with CMTTD caused a stimulation of the palmitoyl-CoA synthetase activity accompanied with increased concentration of hepatic acid-insoluble CoA. This effect was already established during 12-24 h of feeding. From 2 days of feeding, the cellular level of acid-insoluble CoA began to decrease, whereas free CoASH content increased. Stimulation of [1-14C]palmitoyl-CoA oxidation in the presence of KCN, palmitoyl-CoA-dependent dehydrogenase (termed peroxisomal beta-oxidation) and palmitoyl-CoA hydrolase activities were revealed after 36-48 h of CMTTD-feeding. Administration of BCMTD affected the enzymatic activities and altered the distribution of CoA between acid-insoluble and free forms comparable to what was observed in CMTTD-treated rats. It is evident that treatment of peroxisome proliferators (BCMTD and CMTTD), the level of acyl-CoA esters and the enzyme activity involved in their formation precede the increase in peroxisomal and palmitoyl-CoA hydrolase activities. In CMTTD-fed animals the activity of cyanide-insensitive fatty acid oxidation remained unchanged when the mitochondrial beta-oxidation and carnitine palmitoyltransferase operated at maximum rates. The sequence and redistribution of CoA and enzyme changes were interpreted as support for the hypothesis that substrate supply is an important factor in the regulation of peroxisomal fatty acid metabolism, i.e., the fatty acyl-CoA species appear to be catabolized by peroxisomes at high rates only when uptake into mitochondria is saturated. Administration of CETTD led to an inhibition of mitochondrial fatty acid oxidation accompanied with a rise in the concentration of acyl-CoA esters in the liver. Consequently, fatty liver developed. The peroxisomal beta-oxidation was marginally affected. Whether inhibition of mitochondrial beta-oxidation may be involved in regulation of peroxisomal fatty acid metabolism and in development of fatty liver should be considered.     

A new,simple assay for long-chain acyl-CoA dehydrogenase in cultured skin fibroblasts using stable isotopes and GC-MS

In this paper, we present a new method for measurement of long-chain acyl-CoA dehydrogenase (LCAD) activities in cultured skin fibroblasts. The method is based upon gas chromatographic/mass spectrometric determination of 3-OH-hexadecanoic acid formed during incubation of fibroblasts in a medium containing palmitoyl-CoA and crotonase, to convert the enoyl-CoA ester produced into the 3-hydroxyacyl-CoA ester. The validity of the method demonstrated by the finding of a full deficiency of LCAD in fibroblasts from three patients with an established deficiency of LCAD.     

Acyl-CoA ligases from rat brain microsomes: an immunochemical study

Acyl-CoA ligase activities, solubilized from rat brain microsomes, were fractionated into three different peaks by hydroxyapatite chromatography. Based on physical and chemical properties, we suggested that peak A (pamitoyl-CoA ligase) and peak C (lignoceroyl-CoA ligase) were two different enzymes (A. Bhushan, R. P. Singh, and I. Singh (1986) Arch. Biochem. Biophys. 246, 374-380). We raised antibodies against purified liver microsomal palmitoyl-CoA ligase (EC 6.2.1.3) and examined the effect of this antibody on acyl-CoA ligase activities for palmitic, arachidonic and lignoceric acids in microsomal enzyme extract and different acyl-CoA ligase peaks from the hydroxyapatite column. In an enzyme activity assay system in microsomal extract, the antisera inhibited the palmitoyl-CoA ligase activity but had very little effect on the acyl-CoA ligase activities for arachidonic and lignoceric acids. This antisera inhibited the acyl-CoA ligase activities for these three fatty acids in peak A and had no effect on these activities in peak B or peak C. Western blot analysis demonstrated that antibody to liver microsomal palmitoyl-CoA ligase cross-reacted with only peak A (palmitoyl-CoA ligase), but not with peak B or peak C. This immunochemical study demonstrates that palmitoyl-CoA ligase does not share immunological determinants with acyl-CoA ligases in peaks B or C, thus demonstrating that palmitoyl-CoA ligase (peak A) is different from the arachidonoyl-CoA and lignoceroyl-CoA ligase activities in peaks B or C.