Control of lipid oxidation during exercise: role of energy state and mitochondrial factors.

Despite considerable progress during recent years our understanding of how lipid oxidation (LOx) is controlled during exercise remains incomplete. This review focuses on the role of mitochondria and energy state in the control of LOx. LOx increases in parallel with increased energy demand up to an exercise intensity of about 50-60% of VO(2max) after which the contribution of lipid decreases. The switch from lipid to carbohydrate (CHO) is of energetic advantage due to the increased ATP/O(2) yield. In the low-intensity domain (<50%VO(2max)) a moderate reduction in energy state will stimulate both LOx and CHO oxidation and relative fuel utilization is mainly controlled by substrate availability and the capacity of the metabolic pathways. In the high-intensity domain (>60%VO(2max)) there is a pronounced decrease in energy state, which will stimulate glycolysis in excess of the substrate requirements of the oxidative processes. This will lead to acidosis, reduced levels of free Coenzyme A (CoASH) and reduced levels of free carnitine. Acidosis and reduced carnitine may limit the carnitine-mediated transfer of long-chain fatty acids (LCFA) into mitochondria and may thus explain the observed reduction in LOx during high-intensity exercise. Another potential mechanism, suggested in this review, is that Acyl-CoA synthetase (ACS), an initial step in LCFA catabolism, functions as a regulator of LOx. ACS activity is suggested to be under control of CoASH and energy state. Furthermore, evidence exists that additional control points exist beyond mitochondrial FA influx. The nature and site of this control remain to be investigated.

Modulation of hSlo BK current inactivation by fatty acid esters of CoA.

Lipid metabolism influences membrane proteins, including ion channels, in health and disease. Fatty acid esters of CoA are important intermediates in fatty acid metabolism and lipid biosynthesis. In the present study, we examined the effect of acyl-CoAs on hSlo BK currents. Arachidonoyl-CoA (C(20)-CoA) induced beta2-dependent inhibition of hSlo-alpha current when applied intracellularly but not extracellularly. This action was also mimicked by other long-chain acyl-CoAs such as oleoyl-CoA (C(18)-CoA) and palmitoyl-CoA (C(16)-CoA), but not acetyl-CoA (C(2)-CoA, shorter chain), suggesting that the length of acyl chains, rather than CoA headgroups, is critical. When hSlo-alpha inactivation was induced by a free synthetic cationic beta2 NH2-terminus inactivation ball peptide, long-chain acyl-CoAs inhibited hSlo-alpha current and facilitated inactivation. The precursor fatty acids also facilitated the ball peptide-induced inactivation in a chain length-dependent manner, whereas sphingosine (positively charged) slowed this inactivation. When the beta2-induced inactivation was compared with that of the ball peptide, there was a negative shift in the steady state inactivation, slower recovery, and a reduced voltage-dependence of inactivation onset. These data suggest that electrostatic interactions with the cytosolic inactivation domain of beta2 mediate acyl-CoA modulation of BK currents. BK channel inactivation may be a specific target for lipid modulation in physiological and pathophysiological conditions.

Biochemical and catalytic properties of three recombinant alcohol acyltransferases of melon. sulfur-containing ester formation, regulatory role of CoA-SH in activity, and sequence elements conferring substrate preference.

Alcohol acyltransferases (AAT) play a key role in the biosynthesis of ester aroma volatiles in fruit. Three ripening-specific recombinant AATs of cantaloupe Charentais melon fruit (Cm-AAT1, Cm-AAT3, and Cm-AAT4) are capable of synthesizing thioether esters with Cm-AAT1 being by far the most active. All proteins, as well as AAT(s) extracted from melon fruit, are active as tetramers of around 200 kDa. Kinetic analysis demonstrated that CoA-SH, a product of the reaction, is an activator at low concentrations and an inhibitor at higher concentrations. This was confirmed by the addition of phosphotransacetylase at various concentrations, capable of modulating the level of CoA-SH in the reaction medium. Site-directed mutagenesis of some amino acids that were specific to the Cm-AAT sequences into amino acids that were consensus to other characterized AATs greatly affected the selectivity of the original protein and the number of esters produced.

The inside tag.

An uncharged CoA precursor that can enter the cell is used for covalent, site-specific labeling of proteins inside living cells.

Determination of coenzyme A levels in Pyrococcus furiosus and other Archaea: implications for a general role for coenzyme A in thermophiles.

Physiologically significant levels of intracellular coenzyme A were identified in Pyrococcus furiosus, Thermococcus litoralis, and Sulfolobus solfataricus, suggesting a role for CoA as an important low molecular mass thiol in the thermophilic Archaea. In P. furiosus, cells grown in the presence of sulfur showed significantly higher levels of oxidized CoA compared with those grown in the absence of S(0). T. litoralis showed strikingly similar CoA levels, although with low disulfide levels in both the presence and absence of S(0). S. solfataricus showed similarly high levels of CoA thiol, with correspondingly low levels of the CoA disulfide. These results are consistent with the identification of a coenzyme A disulfide reductase (CoADR) in P. furiosus and horikoshii as well as the presence of CoADR homologues in the genomes of S. solfataricus and T. kodakaraensis.

Fatty acyl CoA-mediated inhibition of endoplasmic reticulum assembly.

The protein machinery that mediates homotypic fusion of mammalian endoplasmic reticulum (ER) membranes is becoming increasing well defined. However, little is known of how acylation of constituent membrane components might impact upon this event. This is particularly important as acylation has been shown to promote both fusion and fission of heterotypic membranes. Using a previously characterised cell-free ER fusion assay, I show here that incubation of membranes in the presence of either palmitoyl CoA or myristoyl CoA potently inhibits assembly. Furthermore, inhibition does not occur when membranes are incubated in the constituent palmitate or CoA moieties alone. These findings suggest that not only do palmitoyl CoA and myristoyl CoA inhibit ER assembly, but that they might instead be functioning to actively facilitate ER membrane fission.

[Coenzyme A biosynthesis as universal mechanism of conjugation of exogenous and multiple pantothenic acid functions]. / Biosintez kofermenta A--universal'nyi mekhanizm sopriazheniia ékzogennosti i mnozhestvennosti funktsii pantotenovoi kisloty.

Development of Academician R. V. Chagovets' ideas of the regulatory role of vitamins and their derivatives in thiol-containing compound metabolism and antioxidant system formation as well as in studying non-coenzymatic functions of B-vitamins and vitamin-binding proteins had a considerable effect on the almost 40-year studies on pantothenic acid metabolism and biochemical functions by scholars at the vitaminologic school in Grodno. The concept concerning the intracellular structure of the pantothenate coenzyme form, CoA, pool (content and ratio of CoA-SH, acetyl-CoA, short-chain and long-chain acyls-CoA, coenzyme disulfide forms and CoA-S-S-proteins) was substantiated as an important metabolic regulatory factor (including glutathione system redox potential), with changes being a principal mechanism of pantothenate derivative vitamin and pharmacotherapeutic activity implementation. The effect of the latter is mediated through the systems of CoA biosynthesis and phosphopantetheine proteins, changed CoA-S-S-protein levels, which in turn maintain the intracellular level of CoA-SH as well as cytosolic and mitochondrial transport of its vitamin-containing precursors. A universal CoA biosynthetic function was revealed in prevention of lipid peroxidation initiation and oxidative stress development.

CoenzymeA glutathione disulfide is a potent modulator of angiotensin II-induced vasoconstriction.

CoenzymeA glutathione disulfide (CoASSG) has recently been isolated from bovine adrenal glands and is assumed to play an important role in blood pressure (BP) control. We used the isolated perfused rat kidney to investigate the modulating effects of CoASSG on angiotensin II (AngII)-induced vasoconstriction. Permanent perfusion with CoASSG (1 micromol/L) for 60 min induced a significant (P < .05) shift to the left in the dose-response curve for AngII (about 3.1-fold), whereas the dose-response curve for norepinephrine (NE) was unaffected. During continuous perfusion with 1 micromol/L CoASSG, the repetitive application of 10 pmol AngII significantly increased its vasoconstriction by 170% +/- 14% (P < .05) and 235% +/- 50% (P < .05) for 60 and 120 min, respectively. The potentiation of AngII by permanent perfusion with CoASSG is dose- and time-dependent and shows a plateau at 120 min. Glutathione, oxidized coenzymeA, and coenzymeA (each 1 micromol/L) are not able to enhance the vasoconstriction induced by AngII. We conclude that CoASSG is able to potentiate the vasoactive properties of AngII, and that CoASSG might play an important role in BP regulation via modulating effects of AngII.

Amino acid selectivity in the aminoacylation of coenzyme A and RNA minihelices by aminoacyl-tRNA synthetases.

Coenzyme A (CoA-SH), a cofactor in carboxyl group activation reactions, carries out a function in nonribosomal peptide synthesis that is analogous to the function of tRNA in ribosomal protein synthesis. The amino acid selectivity in the synthesis of aminoacyl-thioesters by nonribosomal peptide synthetases is relaxed, whereas the amino acid selectivity in the synthesis of aminoacyl-tRNA by aminoacyl-tRNA synthetases is restricted. Here I show that isoleucyl-tRNA synthetase aminoacylates CoA-SH with valine, leucine, threonine, alanine, and serine in addition to isoleucine. Valyl-tRNA synthetase catalyzes aminoacylations of CoA-SH with valine, threonine, alanine, serine, and isoleucine. Lysyl-tRNA synthetase aminoacylates CoA-SH with lysine, leucine, threonine, alanine, valine, and isoleucine. Thus, isoleucyl-, valyl-, and lysyl-tRNA synthetases behave as aminoacyl-S-CoA synthetases with relaxed amino acid selectivity. In contrast, RNA minihelices comprised of the acceptor-TpsiC helix of tRNA(Ile) or tRNA(Val) were aminoacylated by cognate synthetases selectively with isoleucine or valine, respectively. These and other data support a hypothesis that the present day aminoacyl-tRNA synthetases originated from ancestral forms that were involved in noncoded thioester-dependent peptide synthesis, functionally similar to the present day nonribosomal peptide synthetases.

[Pantothenic acid].

Pantothenic acid is the antipellagra vitamin essential to many animals for growth and health. It is widely distributed in nature; appreciable amounts are found in liver and some microorganisms. Bound forms of pantothenic acid, such as coenzyme A and 4'-phosphopantetheine, play important roles in various metabolic processes, especially, in fatty acid synthesis and degradation.

Regulation of spinach chloroplast acetyl-CoA carboxylase.

We have investigated several factors which influence acetyl-CoA carboxylase (ACCase) activity in lysed spinach chloroplasts. (1) When assayed after rapid lysis of light-incubated chloroplasts, ACCase activity was 2-fold higher than activity from dark-incubated chloroplasts. Within 5 min after lysis, activity from dark-incubated chloroplasts increased, suggesting a transient inactivation or inhibition of ACCase in the dark. (2) When lysed chloroplast suspensions were incubated with 30 to 100 microM acetyl-CoA before starting assays, activity was 4-fold higher than if suspensions were not preincubated with acetyl-CoA. CoA, malonyl-CoA, propionyl-CoA, and butyryl-CoA also activated ACCase. Full acetyl-CoA activation required MgATP and was essentially complete after 8 min. ACCase activity decreased upon removal of acetyl-CoA by gel filtration and was partially restored by readdition of acetyl-CoA. Thus, ACCase activation by acetyl-CoA was reversible. (3) Dithiothreitol and thioredoxin stimulated ACCase activity, but only in preparations where ACCase activity was low. (4) ACCase was assayed in concentrations of ATP, ADP, NADPH, NADP+, Mg2+, and CO2/HCO-3, which are estimated to occur in the stroma of chloroplasts under illumination or darkness. ACCase activity from lysed chloroplast suspensions was 10-fold higher when illuminated conditions were used. However, this activity was still 5-fold to 10-fold lower than the rates required to sustain known in vivo rates of fatty acid synthesis and in vitro rates achieved under optimum assay conditions with saturating substrates.

Mitochondrial, but not peroxisomal, beta-oxidation of fatty acids is conserved in coenzyme A-deficient rat liver.

Hepatic coenzyme A (CoA) plays an important role in cellular lipid metabolism. Because mitochondria and peroxisomes represent the two major subcellular sites of lipid metabolism, the present study was designed to investigate the specific impact of hepatic CoA deficiency on peroxisomal as well as mitochondrial beta-oxidation of fatty acids. CoA deficiency (47% decrease in free CoA and 23% decrease in total CoA) was produced by maintaining weanling male Sprague-Dawley rats on a semipurified diet deficient in pantothenic acid (the precursor of CoA) for 5 weeks. Hepatic mitochondrial fatty acid oxidation of short-chain and long-chain fatty acids were not significantly different between control and CoA-deficient rats. Conversely, peroxisomal beta-oxidation was significantly diminished (38% inhibition) in livers of CoA-deficient rats compared to control animals. Peroxisomal beta-oxidation was restored to normal levels when hepatic CoA was replenished. It is postulated that since the role of hepatic mitochondrial beta-oxidation is energy production while peroxisomal beta-oxidation acts mainly as a detoxification system, the mitochondrial pathway of beta-oxidation is spared at the expense of the peroxisomal pathway when liver CoA plummets. The present study may offer an animal model to investigate mechanisms involved in peroxisomal diseases.

Inhibitors of coenzyme A-independent transacylase induce apoptosis in human HL-60 cells.

ET-18-O-CH3 (1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine) is an antiproliferative agent, blocking the growth of cancer cells both in vitro and in vivo. However, there is controversy regarding the mechanism leading to its antiproliferative effects. CoA-independent transacylase (CoA-IT) is an enzyme that remodels arachidonate between specific phospholipid donor and acceptor molecules in a variety of mammalian cells. ET-18-O-CH3 was found to be a potent inhibitor of CoA-IT (IC50, 0.5 microM), and kinetic analysis revealed that its inhibition was competitive with the lyso-phospholipid substrate. The goal of the current study was to explore the connection between inhibition of CoA-IT and antiproliferative effects using several structurally distinct inhibitors of CoA-IT. ET-18-O-CH3 and other inhibitors of CoA-IT were found to inhibit cell proliferation and thymidine incorporation into the DNA, as well as to induce apoptosis in human HL-60 monocytic leukemia cells. The mechanism of apoptosis induced by ET-18-O-CH3 appeared to be different from that induced by tumor necrosis factor; the former failed to activate NF-kappa B, whereas tumor necrosis factor did. Closer examination of the pharmacology of apoptosis in this model revealed that compounds that were structurally related to CoA-IT inhibitors, but lacked CoA-IT inhibitory activity, also failed to induce apoptosis. In addition, compounds that inhibited other enzymes that participate in arachidonic acid metabolism, cyclooxygenase, 5-lipoxygenase and phospholipase A2, did not induce apoptosis. Taken together, these results demonstrate that inhibition of CoA-IT can be linked to blockade of proliferation and the induction of apoptosis in HL-60 cells.

The apparent coupling between synthesis and posttranslational modification of Escherichia coli acyl carrier protein is due to inhibition of amino acid biosynthesis.

Acyl carrier protein (ACP) is modified on serine 36 by the covalent posttranslational attachment of 4'-phosphopantetheine from coenzyme A (CoA), and this modification is required for lipid biosynthesis. Jackowski and Rock (J. Biol. Chem 258:15186-15191, 1983) reported that upon depletion of the CoA pool by starvation for a CoA precursor, no accumulation of the unmodified form of ACP (apo-ACP) was detected. We report that this lack of apo-ACP accumulation results from decreased translation of the acpP mRNAs because of the limitation of the synthesis of glutamate and other amino acids made directly from tricarboxylic acid cycle intermediates.

Characterization of 2-ketoisovalerate ferredoxin oxidoreductase, a new and reversible coenzyme A-dependent enzyme involved in peptide fermentation by hyperthermophilic archaea.

Cell extracts of the proteolytic and hyperthermophilic archaea Thermococcus litoralis, Thermococcus sp. strain ES-1, Pyrococcus furiosus, and Pyrococcus sp. strain ES-4 contain an enzyme which catalyzes the coenzyme A-dependent oxidation of branched-chain 2-ketoacids coupled to the reduction of viologen dyes or ferredoxin. This enzyme, termed VOR (for keto-valine-ferredoxin oxidoreductase), has been purified from all four organisms. All four VORs comprise four different subunits and show amino-terminal sequence homology. T. litoralis VOR has an M(r) of ca. 230,000, with subunit M(r) values of 47,000 (alpha), 34,000 (beta), 23,000 (gamma), and 13,000 (delta). It contains about 11 iron and 12 acid-labile sulfide atoms and 13 cysteine residues per heterotetramer (alpha beta gamma delta), but thiamine pyrophosphate, which is required for catalytic activity, was lost during purification. The most efficient substrates (kcat/Km > 1.0 microM-1 s-1; Km < 100 microM) for the enzyme were the 2-ketoacid derivatives of valine, leucine, isoleucine, and methionine, while pyruvate and aryl pyruvates were very poor substrates (kcat/Km < 0.2 microM-1 s-1) and 2-ketoglutarate was not utilized. T. litoralis VOR also functioned as a 2-ketoisovalerate synthase at 85 degrees C, producing 2-ketoisovalerate and coenzyme A from isobutyryl-coenzyme A (apparent Km, 250 microM) and CO2 (apparent Km, 48 mM) with reduced viologen as the electron donor. The rate of 2-ketoisovalerate synthesis was about 5% of the rate of 2-ketoisovalerate oxidation. The optimum pH for both reactions was 7.0. A mechanism for 2-ketoisovalerate oxidation based on data from substrate-induced electron paramagnetic resonance spectra is proposed, and the physiological role of VOR is discussed.

GPI biosynthesis in mammalian cells: CoA-dependent acylation of GlcN-PI.

We have used microsomes prepared from murine lymphoma cell lines to investigate the individual reactions by which glycosylphosphatidylinositol (GPI) is synthesized in mammalian cells. Previously, GTP was found to specifically stimulate the second reaction in the pathway, the deacetylation of GlcNAc-PI to GlcN-PI. An additional GPI precursor was detected in incubations with GTP and was found to be GlcN-PI(acyl), the glycolipid proposed to be the third intermediate in mammalian GPI biosynthesis. Investigation into the factors that affect the formation of GlcN-PI(acyl) revealed that, in the presence of GTP, the addition of either CoA or palmitoyl-CoA to the incubation greatly enhanced the amount of this product made. CoA stimulation of this reaction persisted even when ATP was depleted and no formation of acyl-CoA was possible, indicating that the free CoA rather than an acyl-CoA is the actual effector of GlcN-PI acylation. Therefore, we propose that the third reaction in mammalian GPI biosynthesis is catalyzed by a CoA-dependent transacylase rather than an acyl-CoA acyltransferase.

Regulation of fatty acid biosynthesis in Escherichia coli.

Our understanding of fatty acid biosynthesis in Escherichia coli has increased greatly in recent years. Since the discovery that the intermediates of fatty acid biosynthesis are bound to the heat-stable protein cofactor termed acyl carrier protein, the fatty acid synthesis pathway of E. coli has been studied in some detail. Interestingly, many advances in the field have aided in the discovery of analogous systems in other organisms. In fact, E. coli has provided a paradigm of predictive value for the synthesis of fatty acids in bacteria and plants and the synthesis of bacterial polyketide antibiotics. In this review, we concentrate on four major areas of research. First, the reactions in fatty acid biosynthesis and the proteins catalyzing these reactions are discussed in detail. The genes encoding many of these proteins have been cloned, and characterization of these genes has led to a better understanding of the pathway. Second, the function and role of the two essential cofactors in fatty acid synthesis, coenzyme A and acyl carrier protein, are addressed. Finally, the steps governing the spectrum of products produced in synthesis and alternative destinations, other than membrane phospholipids, for fatty acids in E. coli are described. Throughout the review, the contribution of each portion of the pathway to the global regulation of synthesis is examined. In no other organism is the bulk of knowledge regarding fatty acid metabolism so great; however, questions still remain to be answered. Pursuing such questions should reveal additional regulatory mechanisms of fatty acid synthesis and, hopefully, the role of fatty acid synthesis and other cellular processes in the global control of cellular growth.

[Possible ways of regulating detoxifying processes in the alcohol dehydrogenase reaction with pantothenic acid derivatives]. / Vozmozhnye puti reguliatsii proizvodnymi pantotenovoi kisloty dezintoksikatsionnykh protsessov v alkogol'degidrogenaznoi reaktsii.

Oxidation of derivatives and precursors of pantothenic acid was studied in alcohol dehydrogenase reactions. Despite the presence of free hydroxymethyl groups in a number of pantothenic acid derivatives only panthenol with Km = 8 x 10(-3) M was shown to serve as a substrate for alcohol dehydrogenase from horse liver tissue (EC 1.1.1.1) Pantethine, sodium phosphopantothenate, CoA and acetyl-CoA decreased the rate of ethanol oxidation, where pantethine and sodium phosphopantothenate were competitive inhibitors, while CoA and acetyl-CoA inhibited the enzyme noncompetitively Ki = 1.2 x 10(-2) M, 2.1 x 10(-2) M, 4.4 x 10(-4) M and 5.1 x 10(-4) M, respectively. Metabolic precursors, which were different from pantothenic acid in their structure, were not involved in the alcohol dehydrogenase reaction. Possible regulation of alcohol intoxication using derivatives and precursors of vitamin B3 is discussed.

Recent findings on the regulatory functions of CoA and the normalizing activity on plasma lipids of exogenous CoA.

In recent years many studies have shown that coenzyme A (CoA) is not only an acyl carrier coenzyme but it also has an important role in the regulation of metabolic functions and cell activities such as transport from the Golgi cisternae. This regulatory role is carried out by CoA, its precursor, catabolites and acylated derivatives. The acylation (myristylation and palmitylation) process of peptides and proteins dependent on CoA seems to be an important regulatory mechanism of cell activities. Furthermore exogenous CoA has been shown to decrease the triacylglycerols, cholesterol and Apo B of plasma lipoproteins in man. This regulatory mechanism acts either on VLDL synthesis and secretion or on their plasma clearance. CoA also protects cell-membrane and plasma lipoproteins against the peroxidative action of oxygen free-radicals.

Coenzyme A-dependent, ATP-independent acylation of 2-acyl lysophosphatidylinositol in rat liver microsomes.

Phosphatidylinositol (PI) is synthesized from cytidine-diphosphodiacylglycerol (CDP-DAG) and inositol by the enzyme PI synthase. CDP-DAG is itself synthesized from phosphatidic acid and CTP. The observation that PI differs in fatty acid composition from its precursors CDP-DAG and phosphatidic acid led to the proposal that following its synthesis the fatty acids of PI are removed and replaced by others in a process called fatty acid remodelling. Previously, we used rat liver microsomes to study the molecular mechanisms of PI remodelling. Following its synthesis, PI is rapidly deacylated to form lysoPI which is reacylated to form new PI species. PI remodelling occurs predominantly at the 1-position. We demonstrate here that lysoPI can be acylated in the 1-position in an ATP-independent manner. The acylation of 2-acyl lysoPI by the coenzyme A-dependent, ATP-independent mechanism was examined. The acylation exhibits a pH optimum of 7.5, does not require a divalent cation, and is not inhibited by Ca2+ or Mg2+, although Zn2+ is a potent inhibitor. The apparent Km values for coenzyme A and 2-acyl lysoPI are 14 microM and 30 microM, respectively. The acylation of 2-acyl lysoPI incorporates primarily stearic acid into the 1-position of PI, as would be expected based on the fatty acid composition of steady-state PI in rat hepatocytes.