Peroxisomal fatty acid oxidation is a substantial source of the acetyl moiety of malonyl-CoA in rat heart

Little is known about the sources of acetyl-CoA used for the synthesis of malonyl-CoA, a key regulator of mitochondrial fatty acid oxidation in the heart. In perfused rat hearts, we previously showed that malonyl-CoA is labeled from both carbohydrates and fatty acids. This study was aimed at assessing the mechanisms of incorporation of fatty acid carbons into malonyl-CoA. Rat hearts were perfused with glucose, lactate, pyruvate, and a fatty acid (palmitate, oleate or docosanoate). In each experiment, substrates were (13)C-labeled to yield singly or/and doubly labeled acetyl-CoA. The mass isotopomer distribution of malonyl-CoA was compared with that of the acetyl moiety of citrate, which reflects mitochondrial acetyl-CoA. In the presence of labeled glucose or lactate/pyruvate, the (13)C labeling of malonyl-CoA was up to 2-fold lower than that of mitochondrial acetyl-CoA. However, in the presence of a fatty acid labeled in its first acetyl moiety, the (13)C labeling of malonyl-CoA was up to 10-fold higher than that of mitochondrial acetyl-CoA. The labeling of malonyl-CoA and of the acetyl moiety of citrate is compatible with peroxisomal beta-oxidation forming C(12) and C(14) acyl-CoAs and contributing >50% of the fatty acid-derived acetyl groups that end up in malonyl-CoA. This fraction increases with the fatty acid chain length. By supplying acetyl-CoA for malonyl-CoA synthesis, peroxisomal beta-oxidation may participate in the control of mitochondrial fatty acid oxidation in the heart. In addition, this pathway may supply some acyl groups used in protein acylation, which is increasingly recognized as an important regulatory mechanism for many biochemical processes.     

Proline and hepatic lipogenesis

The effects of proline on lipogenesis in isolated rat hepatocytes were determined and compared with those of lactate, an established lipogenic precursor. Proline or lactate plus pyruvate increased lipogenesis (measured with 3H2O) in hepatocytes from fed rats depleted of glycogen in vitro and in hepatocytes from starved rats. Lactate plus pyruvate but not proline increased lipogenesis in hepatocytes from starved rats. ( - )-Hydroxycitrate, an inhibitor of ATP-citrate lyase, partially inhibited incorporation into saponifiable fatty acid of 3H from 3H2O and 14C from [U-14C]lactate with hepatocytes from fed rats. Incorporation of 14C from [U-14C]proline was completely inhibited. Similar complete inhibition of incorporation of 14C from [U-14C]proline by ( - )-hydroxycitrate was observed with glycogen-depleted hepatocytes or hepatocytes from starved rats. Inhibition of phosphoenolpyruvate carboxykinase by 3-mercaptopicolinate did not inhibit the incorporation into saponifiable fatty acid of 3H from 3H2O or 14C from [U-14C]proline or [U-14C]lactate. Both 3-mercaptopicolinate and ( - )-hydroxycitrate increased lipogenesis (measured with 3H2O) in the absence or presence of lactate or proline with hepatocytes from starved rats. The results are discussed with reference to the roles of phosphoenolpyruvate carboxykinase, mitochondrial citrate efflux, ATP-citrate lyase and acetyl-CoA carboxylase in proline- or lactate-stimulated lipogenesis.     

The Contribution of Citrate to the Synthesis of Acetyl Units in Synaptosomes of Developing Rat Brain

Abstract: The activities of pyruvate dehydrogenase, citrate synthase, and choline acetyltransferase in rat brain synaptosomes increased during on-togenesis by 3 and 14 times, respectively. Activity of ATP-citrate lyase decreased by 26% during the same period. Pyruvate consumption by synapto-somes from 1-day-old animals was 40% lower than that found in older rats; however, citrate efflux from intrasynaptosomal mitochondria in immature synaptosomes was over twice as high as that in mature ones. The rates of production of synaptoplasmic acetyl-CoA, ATP-citrate lyase were 1.03, 1.40, and 0.49 nmol/min/mg protein in 1-, 10-day-old, and adult rats, respectively. 3-Bromopyruvate (0.5 m M ) inhibited pyruvate consumption by 70% and caused a complete block of citrate utilization by citrate lyase in every age group. Parameters of citrate metabolism in cerebellar synaptosomes were the same as those in cerebral ones. These data indicate that production of acetyl-CoA. from citrate in synaptoplasm may be regulated either by adaptative, age-dependent changes in permeability and carrier capacity of the mitochondrial membrane or by the inhibition of synthesis of intramitochondrial acetyl-CoA. ATP-citrate lyase activity is not a rate-limiting factor in this process. Metabolic fluxes of pyruvate to cytoplasmic citrate and acetyl-CoA. are presumably the same in both cholinergic and noncholinergic nerve endings. The significance of citrate release from intrasynaptosomal mitochondria as a regulatory step in acetylcholine synthesis is discussed.     

Pyruvate metabolism by lymphocytes: evidence for an additional ketogenic tissue

The rate of utilization of pyruvate (at various concentrations) was measured in lymphocytes prepared from rat mesenteric lymph nodes. The quantitative contribution of pyruvate to CO2, lactate, aspartate, alanine, citrate, acetate, acetyl-CoA and ketone bodies accounted for the pyruvate metabolized. Pyruvate utilization was depressed by increasing concentrations of pyruvate. The maximum catalytic activities and selected intracellular distributions of the following enzymes of pyruvate, citrate and acetyl-CoA metabolism were measured: citrate synthase, ATP-citrate lyase, lactate dehydrogenase, acetyl-CoA hydrolase, acetylcarnitine transferase, NAD+- and NADP+- isocitrate dehydrogenases, HMG-CoA lyase, HMG-CoA synthase, Pyruvate dehydrogenase, acetoacetyl-CoA thiolase, 3-oxoacid-CoA transferase, 3-hydroxybutyrate dehydrogenase and pyruvate carboxylase. Acetyl-CoA formed from pyruvate did not contribute to the respiratory energy metabolism of resting lymphocytes. Instead acetyl-CoA was converted to acetoacetate by reactions which may favour the pathway catalyzed by acetoacetyl-CoA thiolase and 3-oxoacid-CoA transferase. Acetate, acetyl- and palmitoyl-carnitine inhibited the decarboxylation of [1-14C] pyruvate. These observations may be connected with the suppression of pyruvate utilization by increased pyruvate substrate concentration. Only very small amounts of either pyruvate or acetate were incorporated into lipids in resting lymphocytes. The amounts incorporated were partitioned in approximately the same pattern into FFA, T.G., cholesterol and cholesterol esters. Taken together the data show that pyruvate metabolism is directed inter alia at the formation of acetoacetate which may serve as a lipid synthesis precursor. When pyruvate utilization and metabolism was enhanced by concanavalin A, then acetoacetate formation was not favoured and from this it is proposed that the acetyl units may then be directed into lipid synthesis and may also make a contribution to the energy metabolism of the activated lymphocyte.     

Regional and Subcellular Distribution of ATP-Citrate Lyase and Other Enzymes of Acetyl-CoA Metabolism in Rat Brain

The activities of ATP-citrate lyase in frog, guinea pig, mouse, rat, and human brain vary from 18 to 30 μmol/h/g of tissue, being several times higher than choline acetyltransferase activity. Activities of pyruvate dehydrogenase and acetyl coenzyme A synthetase in rat brain are 206 and 18.4 μmol/h/g of tissue, respectively. Over 70% of the activities of both choline acetyltransferase and ATP-citrate lyase in secondary fractions are found in synaptosomes. Their preferential localization in synaptosomes and synaptoplasm is supported by RSA values above 2. Acetyl CoA synthetase activity is located mainly in whole brain mitochondria (RSA, 2.33) and its activity in synaptoplasm is low (RSA, 0.25). The activities of pyruvate dehydrogenase, citrate synthase, and carnitine acetyltransferase are present mainly in fractions C and B_p. No pyruvate dehydrogenase activity is found in synaptoplasm. Striatum, cerebral cortex, and cerebellum contain similar activities of pyruvate dehydrogenase, citrate synthase, carnitine acetyltransferase, fatty acid synthetase, and acetyl-CoA hydrolase. Activities of acetyl CoA synthetase, choline acetyltransferase and ATP-citrate lyase in cerebellum are about 10 and 4 times lower, respectively, than in other parts of the brain. These data indicate preferential localization of ATP-citrate lyase in cholinergic nerve endings, and indicate that this enzyme is not a rate limiting step in the synthesis of the acetyl moiety of ACh in brain.     

Inhibition of the synthesis of acetylcholine in rat brain slices by (-)-hydroxycitrate and citrate

Abstract: Slices of rat caudate nucleus were incubated in a solution of 123 mM-NaCl, 5 mM-KCl, 1.2 mM-MgCl₂, 1.2 mM-NaH₂PO₄, 25 mM-NaHCO₃, 0.2 mM-choline chloride, 0.058 mM-paraoxon, 1 mM-EGTA, and oxidizable substrates. (−)-Hydroxycitrate, a specific inhibitor of ATP-citrate lyase (EC 4.1.3.8), used at a concentration of 2.5 mM, inhibited the synthesis of acetylcholine (ACh) from [1,5-¹⁴C]citrate by 82–86%, but that from [U-¹⁴C]glucose by only 33%, from [2-¹⁴C]pyruvate by 24% and from [1-¹⁴C-acetyl]carnitine by 8%; the production of ¹⁴CO₂ from these substrates was not substantially changed. The synthesis of ACh from glucose and pyruvate was in hibited also by citrate; 2.5 mM- and 5 mM-citrate diminished it by 43% and 66%, respectively; the production of from [U-¹⁴C]glucose and from [1-¹⁴C]pyruvate was not affected. The mechanism of the inhibitory effect of citrate on the synthesis of ACh is not clear; the possibility is discussed that citrate alters the intracellular milieu in cholinergic neurons by chelating the intracellular Ca²⁺ and decreases the supply of mitochondrial acetyl-CoA to the cytosol. The results with (−)-hydroxycitrate indicate that the cleavage of citrate by ATP-citrate lyase is not responsible for the supply of more than about one-third of the acetyl-CoA which is used for the synthesis of ACh when glucose or pyruvate are the main oxidizable substrates. This proportion may be even smaller, since (−)-hydroxycitrate possibly affects the synthesis of ACh from glucose and pyruvate by a mechanism (unknown) similar to that of citrate, rather than by the inhibition of ATP-citrate lyase.     

Mass isotopomer study of anaplerosis from propionate in the perfused rat heart

Anaplerosis from propionate was investigated in rat hearts perfused with 0-2mM [(13)C(3)]propionate and physiological concentrations of glucose, lactate, and pyruvate. The data show that when the concentration of [(13)C(3)]propionate was raised from 0 to 2mM, total anaplerosis increased from 5% to 16% of the turnover of citric acid cycle intermediates. Then, [(13)C(3)]propionate abolished anaplerosis from endogenous substrates, glucose, lactate, and pyruvate. Also, while the contents of propionyl-CoA and methylmalonyl-CoA increased with [(13)C(3)]propionate concentration, the content of succinyl-CoA decreased, presumably via activation of succinyl-CoA hydrolysis by a decrease in free CoA. Under our conditions, [(13)C(3)]propionate was a purely anaplerotic substrate since there was no labeling of mitochondrial acetyl-CoA, reflected by the labeling of the acetyl moiety of citrate.     

ATP-Citrate Lyase and Other Enzymes of Acetyl-CoA Metabolism in Fractions of Small and Large Synaptosomes from Rat Brain Hippocampus and Cerebellum

The activities of choline acetyltransferase and ATP-citrate lyase were significantly correlated (r = 0.995) in fractions of small and large synaptosomes isolated from rat hippocampus and cerebellum. The activities of these two enzymes did not correlate with those of pyruvate dehydrogenase, carnitine acetyltransferase, citrate synthase, acetyl-CoA synthetase, lactate dehydrogenase, or with the rate of high-affinity glutamate uptake in the synaptosomal fractions. The results provide additional evidence linking ATP-citrate lyase to the cholinergic system in the brain.     

Intracellular localization of enzymes in white-adipose-tissue fat-cells and permeability properties of fat-cell mitochondria. Transfer of acetyl units and reducing power between mitochondria and cytoplasm

1. A method is described for extracting separately mitochondrial and extramitochondrial enzymes from fat-cells prepared by collagenase digestion from rat epididymal fat-pads. The following distribution of enzymes has been observed (with the total activities of the enzymes as units/mg of fat-cell DNA at 25 degrees C given in parenthesis). Exclusively mitochondrial enzymes: glutamate dehydrogenase (1.8), NAD-isocitrate dehydrogenase (0.5), citrate synthase (5.2), pyruvate carboxylase (3.0); exclusively extramitochondrial enzymes: glucose 6-phosphate dehydrogenase (5.8), 6-phosphogluconate dehydrogenase (5.2), NADP-malate dehydrogenase (11.0), ATP-citrate lyase (5.1); enzymes present in both mitochondrial and extramitochondrial compartments: NADP-isocitrate dehydrogenase (3.7), NAD-malate dehydrogenase (330), aconitate hydratase (1.1), carnitine acetyltransferase (0.4), acetyl-CoA synthetase (1.0), aspartate aminotransferase (1.7), alanine aminotransferase (6.1). The mean DNA content of eight preparations of fat-cells was 109mug/g dry weight of cells. 2. Mitochondria showing respiratory control ratios of 3-6 with pyruvate, about 3 with succinate and P/O ratios of approaching 3 and 2 respectively have been isolated from fat-cells. From studies of rates of oxygen uptake and of swelling in iso-osmotic solutions of ammonium salts, it is concluded that fat-cell mitochondria are permeable to the monocarboxylic acids, pyruvate and acetate; that in the presence of phosphate they are permeable to malate and succinate and to a lesser extent oxaloacetate but not fumarate; and that in the presence of both malate and phosphate they are permeable to citrate, isocitrate and 2-oxoglutarate. In addition, isolated fat-cell mitochondria have been found to oxidize acetyl l-carnitine and, slowly, l-glycerol 3-phosphate. 3. It is concluded that the major means of transport of acetyl units into the cytoplasm for fatty acid synthesis is as citrate. Extensive transport as glutamate, 2-oxoglutarate and isocitrate, as acetate and as acetyl l-carnitine appears to be ruled out by the low activities of mitochondrial aconitate hydratase, mitochondrial acetyl-CoA hydrolyase and carnitine acetyltransferase respectively. Pathways whereby oxaloacetate generated in the cytoplasm during fatty acid synthesis by ATP-citrate lyase may be returned to mitochondria for further citrate synthesis are discussed. 4. It is also concluded that fat-cells contain pathways that will allow the excess of reducing power formed in the cytoplasm when adipose tissue is incubated in glucose and insulin to be transferred to mitochondria as l-glycerol 3-phosphate or malate. When adipose tissue is incubated in pyruvate alone, reducing power for fatty acid, l-glycerol 3-phosphate and lactate formation may be transferred to the cytoplasm as citrate and malate.     

ATP citrate lyase in cholinergic nerve endings

The activity of ATP-citrate lyase in homogenates of five selected rat brain regions varied from 2.93 to 6.90 nmol/min/mg of protein in the following order: cerebellum < hippocampus < parietal cortex < striatum < medulla oblongata and that of the choline acetyltransferase from 0.15 to 2.08 nmol/min/mg of protein in cerebellum < parietal cortex < hippocampus=medulla oblongata < striatum. No substantial differences were found in regional activities of lactate dehydrogenase, pyruvate dehydrogenase, citrate synthase or acetyl-CoA synthase. High values of relative specific activities for both choline acetyltransferase and ATP-citrate lyase were found in synaptosomal and synaptoplasmic fractions from regions with a high content of cholinergic nerve endings. There are significant correlations between these two enzyme activities in general cytocol (S₃), synaptosomal (B) and synaptoplasmic (B_s) fractions from the different regions (r=0.92–0.99). These data indicate that activity of ATP-citrate lyase in cholinergic neurons is several times higher than that present in glial and noncholinergic neuronal cells.     

Citrate release by perfused rat hearts: a window on mitochondrial cataplerosis

Cytosolic citrate is proposed to play a crucial role in substrate fuel selection in the heart. However, little is known about factors regulating the transfer of citrate from the mitochondria, where it is synthesized, to the cytosol. Further to our observation that rat hearts perfused under normoxia release citrate whose (13)C labeling pattern reflects that of mitochondrial citrate (B. Comte, G. Vincent, B. Bouchard, and C. Des Rosiers. J. Biol. Chem. 272: 26117-26124, 1997), we report here data indicating that this citrate release is a specific process reflecting the mitochondrial efflux of citrate, a process referred to as cataplerosis. Indeed, measured rates of citrate release, which vary between 2 and 21 nmol/min, are modulated by the nature and concentration of exogenous substrates feeding acetyl-CoA (fatty acid) and oxaloacetate (lactate plus pyruvate) for the mitochondrial citrate synthase reaction. Such release rates that represent at most 2% of the citric acid cycle flux are in agreement with the activity of the mitochondrial tricarboxylate transporter whose participation is also substantiated by 1) parallel variations in citrate release rates and tissue levels of citrate plus malate, the antiporter, and 2) a lowering of the citrate release rate by 1,2, 3-benzenetricarboxylic acid, a specific inhibitor of the transporter. Taken together, the results from the present study indicate that citrate cataplerosis is modulated by substrate supply, in agreement with the role of cytosolic citrate in fuel partitioning, and occurs, at least in part, through the mitochondrial tricarboxylate transporter.     

Halothane-Induced Alterations of Glucose and Pyruvate Metabolism in Rat Cerebra Synaptosomes

Synaptosomes isolated from rat cerebra were used to study the effects of the inhalational anesthetic, halothane, on cholinergic processes. To identify possible mechanisms responsible for the depression of acetylcholine synthesis, we examined the effects of halothane on precursor metabolite metabolism involved with supplying the cytosol with acetyl-CoA for acetylcholine synthesis. Three percent halothane/air (vol/vol) depressed 14CO2 evolution from labeled pyruvate and glucose. Steady-state 14CO2 evolution from [1-14C]glucose was depressed 84% by halothane, while 14CO2 evolution from [6-14C]glucose and [3,4-14C]glucose was decreased 67 and 52%, respectively, when compared with control conditions. Halothane inhibited the activities of both pyruvate dehydrogenase (14% depression) and ATP-citrate lyase (32% depression). Total synaptosomal acetyl-CoA concentrations were unaffected by halothane. Three percent halothane/air (vol/vol) caused a 77% increase in medium glucose depletion rate from 1.38 nmol (mg protein)-1 min-1 to 2.44 nmol (mg protein)-1 min-1. Production of lactate by the synaptosomes in the presence of halothane increased by 231% from a control rate of 1.44 nmol (mg protein)-1 min-1 to 4.77 nmol (mg protein)-1 min-1. Lactate production rate from pyruvate was also enhanced by 56% in the presence of halothane. These data lend support to the concept that the NAD+/NADH potential may be involved in the halothane-induced depression of acetylcholine synthesis.     

Metabolic phenotyping of the diseased rat heart using 13C-substrates and ex vivo perfusion in the working mode

The objective of the present study was to compare energy substrate fluxes through metabolic pathways leading to mitochondrial citrate synthesis and release in normal and diseased rat hearts using ¹³C-substrates and mass isotopomer analysis by gas chromatography-mass spectrometry (GCMS). This study was prompted by our previous finding of a modulated citrate release by perfused rat hearts and by the possibility that a dysregulated myocardial citrate release represents a specific chronic alteration of energy metabolism in cardiac patients. The 15-week-old spontaneously hypertensive rat (SHR) was chosen as our animal model of disease and the Wistar-Kyoto (WKY) rat as its matched control. Ex vivo work-performing hearts were perfused with a semi-recirculating buffer containing physiological concentrations of unlabeled (glucose) and ¹³C-labeled ([U-¹³C₃](lactate + pyruvate) and/or [1-¹³C]oleate) substrates. In parallel to the continuous monitoring of indices of the heart's functional and physiological status, the following metabolic parameters were documented: (i) citrate release rates and citric acid cycle intermediate tissue levels, (ii) the contribution of fatty acids as well as pyruvate decarboxylation and carboxylation to citrate synthesis, and (iii) lactate and pyruvate uptake and efflux rates. Working hearts from both rat species showed a similar percent contribution of carbohydrates for citrate synthesis through decarboxylation (70%) and carboxylation (10%). SHR hearts showed the following metabolic alterations: a higher citrate release rate, which was associated with a parallel increase in its tissue level, a lower contribution of oleate -oxidation to citrate synthesis, and an accelerated efflux rate of unlabeled lactate from glycolysis. These metabolic changes were not explained by differences in myocardial oxygen consumption, cardiac performance or efficiency, nor correlated with indices of tissue necrosis or ischemia. This study demonstrates how the alliance between ex vivo semi-recirculating working perfused rat hearts with ¹³C-substrates and mass isotopomer analysis by GCMS, can provide an unprecedented insight into the metabolic phenotype of normal and diseased rat hearts. The clinical relevance of metabolic alterations herein documented in the SHR heart is suggested by its resemblance to those reported in cardiac patients. Taken altogether, our results raise the possibility that the increased citrate release of diseased hearts results from an imbalance between citrate synthesis and utilization rates, which becomes more apparent under conditions of substrate abundance.     

De novo fatty acid synthesis by freshly isolated alveolar type II epithelial cells

Fatty acid synthesis was studied in freshly isolated type II pneumocytes from rabbits by 3H2O and (U-14C)-labeled glucose, lactate and pyruvate incorporation and the activity of acetyl-CoA carboxylase. The rate of lactate incorporation into fatty acids was 3-fold greater than glucose incorporation; lactate incorporation into the glycerol portion of lipids was very low but glucose incorporation into this fraction was approximately equal to incorporation into fatty acids. The highest rate of de novo fatty acid synthesis (3H2O incorporation) required both glucose and lactate. Under these circumstances lactate provided 81.5% of the acetyl units while glucose provided 5.6%. Incubations with glucose plus pyruvate had a significantly lower rate of fatty acid synthesis than glucose plus lactate. The availability of exogenous palmitate decreased de novo fatty acid synthesis by 80% in the isolated cells. In a cell-free supernatant, acetyl-CoA carboxylase activity was almost completely inhibited by palmitoyl-CoA; citrate blunted this inhibition. These data indicate that the type II pneumocyte is capable of a high rate of de novo fatty acid synthesis and that lactate is a preferred source of acetyl units. The type II pneumocyte can rapidly decrease the rate of fatty acid synthesis, probably by allosteric inhibition of acetyl-CoA carboxylase, if exogenous fatty acids are available.     

Effects of dichloroacetate on the metabolism of glucose, pyruvate, acetate, 3-hydroxybutyrate and palmitate in rat diaphragm and heart muscle in vitro and on extraction of glucose, lactate, pyruvate and free fatty acids by dog heart in vivo

1. The extractions of glucose, lactate, pyruvate and free fatty acids by dog heart in vivo were calculated from measurements of their arterial and coronary sinus blood concentration. Elevation of plasma free fatty acid concentrations by infusion of intralipid and heparin resulted in increased extraction of free fatty acids and diminished extractions of glucose, lactate and pyruvate by the heart. It is suggested that metabolism of free fatty acids by the heart in vivo, as in vitro, may impair utilization of these substrates. These effects of elevated plasma free fatty acid concentrations on extractions by the heart in vivo were reversed by injection of dichloroacetate, which also improved extraction of lactate and pyruvate by the heart in vivo in alloxan diabetes. 2. Sodium dichloroacetate increased glucose oxidation and pyruvate oxidation in hearts from fed normal or alloxan-diabetic rats perfused with glucose and insulin. Dichloroacetate inhibited oxidation of acetate and 3-hydroxybutyrate and partially reversed inhibitory effects of these substrates on the oxidation of glucose. In rat diaphragm muscle dichloroacetate inhibited oxidation of acetate, 3-hydroxybutyrate and palmitate and increased glucose oxidation and pyruvate oxidation in diaphragms from alloxan-diabetic rats. Dichloroacetate increased the rate of glycolysis in hearts perfused with glucose, insulin and acetate and evidence is given that this results from a lowering of the citrate concentration within the cell, with a consequent activation of phosphofructokinase. 3. In hearts from normal rats perfused with glucose and insulin, dichloroacetate increased cell concentrations of acetyl-CoA, acetylcarnitine and glutamate and lowered those of aspartate and malate. In perfusions with glucose, insulin and acetate, dichloroacetate lowered the cell citrate concentration without lowering the acetyl-CoA or acetylcarnitine concentrations. Measurements of specific radioactivities of acetyl-CoA, acetylcarnitine and citrate in perfusions with [1-(14)C]acetate indicated that dichloroacetate lowered the specific radio-activity of these substrates in the perfused heart. Evidence is given that dichloroacetate may not be metabolized by the heart to dichloroacetyl-CoA or dichloroacetylcarnitine or citrate or CO(2). 4. We suggest that dichloroacetate may activate pyruvate dehydrogenase, thus increasing the oxidation of pyruvate to acetyl-CoA and acetylcarnitine and the conversion of acetyl-CoA into glutamate, with consumption of aspartate and malate. Possible mechanisms for the changes in cell citrate concentration and for inhibitory effects of dichloroacetate on the oxidation of acetate, 3-hydroxybutyrate and palmitate are discussed.     

Utilization of Citrate, Acetylcarnitine, Acetate, Pyruvate and Glucose for the Synthesis of Acetylcholine in Rat Brain Slices

Slices of rat caudate nuclei were incubated in saline media containing choline, paraoxon, unlabelled glucose, and [1,5-14C] citrate, [1-14C-acetyl]carnitine, [1-14C]acetate, [2-14C]pyruvate, or [U-14C]glucose. The synthesis of acetyl-labelled acetylcholine (ACh) was compared with the total synthesis of ACh. When related to the utilization of unlabelled glucose (responsible for the formation of unlabelled ACh), the utilization of labelled substrates for the synthesis of the acetyl moiety of ACh was found to decrease in the following order: [2-14C]pyruvate greater than [U-14C]glucose greater than [1-14C-acetyl]carnitine greater than [1,5-14C]citrate greater than [1-14C]acetate. The utilization of [1,5-14C]citrate and [1-14C]acetate for the synthesis of [14C]ACh was low, although it was apparent from the formation of 14CO2 and 14C-labelled lipid that the substrates entered the cells and were metabolized. The utilization of [1,5-14C]citrate for the synthesis of [14C]ACh was higher when the incubation was performed in a medium without calcium (with EGTA); that of glucose did not change, whereas the utilization of other substrates for the synthesis of ACh decreased. The results indicate that earlier (indirect) evidence led to an underestimation of acetylcarnitine as a potential source of acetyl groups for the synthesis of ACh in mammalian brian; they do not support (but do not disprove) the view that citrate is the main carrier of acetyl groups from the intramitochondrial acetyl-CoA to the extramitochondrial space in cerebral cholinergic neurons.     

Peroxisomal and mitochondrial oxidation of fatty acids in the heart, assessed from the 13C labeling of malonyl-CoA and the acetyl moiety of citrate

We previously showed that a fraction of the acetyls used to synthesize malonyl-CoA in rat heart derives from partial peroxisomal oxidation of very long and long-chain fatty acids. The 13C labeling ratio (malonyl-CoA)/(acetyl moiety of citrate) was >1.0 with 13C-fatty acids, which yields [13C]acetyl-CoA in both mitochondria and peroxisomes and < 1.0 with substrates, which yields [13C]acetyl-CoA only in mitochondria. In this study, we tested the influence of 13C-fatty acid concentration and chain length on the labeling of acetyl-CoA formed in mitochondria and/or peroxisomes. Hearts were perfused with increasing concentrations of labeled docosanoate, oleate, octanoate, hexanoate, butyrate, acetate, or dodecanedioate. In contrast to the liver, peroxisomal oxidation of 1-13C-fatty acids in heart does not form [1-13C]acetate. With [1-13C]docosanoate and [1,12-13C2]dodecanedioate, malonyl-CoA enrichment plateaued at 11 and 9%, respectively, with no detectable labeling of the acetyl moiety of citrate. Thus, in the intact rat heart, docosanoate and dodecanedioate appear to be oxidized only in peroxisomes. With [1-13C]oleate or [1-13C]octanoate, the labeling ratio >1 indicates the partial peroxisomal oxidation of oleate and octanoate. In contrast, with [3-13C]octanoate, [1-13C]hexanoate, [1-13C]butyrate, or [1,2-13C2]acetate, the labeling ratio was <0.7 at all concentrations. Therefore, in rat heart, (i) n-fatty acids shorter than 8 carbons do not undergo peroxisomal oxidation, (ii) octanoate undergoes only one cycle of peroxisomal beta-oxidation, (iii) there is no detectable transfer to the mitochondria of acetyl-CoA from the cytosol or the peroxisomes, and (iv) the capacity of C2-C18 fatty acids to generate mitochondrial acetyl-CoA decreases with chain length.     

Metabolic studies of pyruvate- and lactate-perfused guinea pig hearts by 13C NMR. Determination of substrate preference by glutamate isotopomer distribution

Guinea pig hearts perfused in vitro with 99% enriched [3-13C]pyruvate and [3-13C]lactate have been examined by 13C NMR spectroscopy at 75.45 MHz. Resonances from the intracellular metabolites, glutamate, aspartate, alanine, citrate, malate, lactate, and acetylcarnitine are detected in the [3-13C]pyruvate-perfused hearts while glutamate is the only metabolite observed in the [3-13C]lactate-perfused hearts. Extracts obtained from individual freeze-clamped hearts run under high resolution conditions show similar distributions of metabolites indicating that the intracellular concentrations of these metabolites are indeed quite dependent upon the substrate being utilized. The excellent signal to noise in the spectra of lactate-perfused hearts allows observation of spin-spin coupling between 13C-enriched nuclei in the various glutamate isotopomers within the intact heart. It is shown that the steady-state distribution of glutamate isotopomers is determined by the amount of 12C- versus 13C-enriched acetyl-CoA entering the citric acid cycle and this provides the basis for a direct determination of substrate utilization by the heart in the presence of competing substrates. Similar information may be derived from the 13C spectrum of an extract prepared from a single [3-13C]pyruvate-perfused heart. Our results indicate that lactate is preferred over glucose by the guinea pig heart even in the presence of insulin.     

Carnitine stimulation of glucose oxidation in the fatty acid perfused isolated working rat heart.

The effects of L-carnitine on myocardial glycolysis, glucose oxidation, and palmitate oxidation were determined in isolated working rat hearts. Hearts were perfused under aerobic conditions with perfusate containing either 11 mM [2-3H/U-14C]glucose in the presence or absence of 1.2 mM palmitate or 11 mM glucose and 1.2 mM [1-14C]palmitate. Myocardial carnitine levels were elevated by perfusing hearts with 10 mM L-carnitine. A 60-min perfusion period resulted in significant increases in total myocardial carnitine from 4376 +/- 211 to 9496 +/- 473 nmol/g dry weight. Glycolysis (measured as 3H2O production) was unchanged in carnitine-treated hearts perfused in the absence of fatty acids (4418 +/- 300 versus 4547 +/- 600 nmol glucose/g dry weight.min). If 1.2 mM palmitate was present in the perfusate, glycolysis decreased almost 2-fold compared with hearts perfused in the absence of fatty acids. In carnitine-treated hearts this drop in glycolysis did not occur (glycolytic rates were 2911 +/- 231 to 4629 +/- 460 nmol glucose/g dry weight.min, in control and carnitine-treated hearts, respectively. Compared with control hearts, glucose oxidation rates (measured as 14CO2 production from [U-14C]glucose) were unaltered in carnitine-treated hearts perfused in the absence of fatty acids (1819 +/- 169 versus 2026 +/- 171 nmol glucose/g dry weight.min, respectively). In the presence of 1.2 mM palmitate, glucose oxidation decreased dramatically in control hearts (11-fold). In carnitine-treated hearts, however, glucose oxidation was significantly greater than control hearts under these conditions (158 +/- 21 to 454 +/- 85 nmol glucose/g dry weight.min, in control and carnitine-treated hearts, respectively). Palmitate oxidation rates (measured as 14CO2 production from [1-14C]palmitate) decreased in the carnitine-treated hearts from 728 +/- 61 to 572 +/- 111 nmol palmitate/g dry weight.min. This probably occurred secondary to an increase in overall ATP production from glucose oxidation (from 5.4 to 14.5% of steady state myocardial ATP production). The results reported in this study provide direct evidence that carnitine can stimulate glucose oxidation in the intact fatty acid perfused heart. This probably occurs secondary to facilitating the intramitochondrial transfer of acetyl groups from acetyl-CoA to acetylcarnitine, thereby relieving inhibition of the pyruvate dehydrogenase complex.     

Acute control of fatty acid synthesis by cyclic AMP in the chick liver cell: possible site of inhibition of citrate formation.

Glucagon and N,(6)O(2)-dibutyryl cyclic adenosine 3',5'-cyclic monophosphate (Bt(2)cAMP) inhibit fatty acid synthesis from acetate by more than 90% and prevent citrate formation in chick hepatocytes metabolizing glucose. With substrates that enter glycolysis at or below triose-phosphates, e.g., fructose, lactate, or pyruvate, Bt(2)cAMP has no effect on the citrate level and its inhibitory effect on fatty acid synthesis is substantially reversed. Because acetyl-CoA carboxylase requires a tricarboxylic acid activator for activity, it is proposed that regulation of fatty acid synthesis by Bt(2)cAMP is due, in part, to changes in the citrate level. Reduced citrate formation appears to result from a cAMP-induced inhibition of glycolysis. Bt(2)cAMP inhibits (14)CO(2) production from [1-(14)C]-, [6-(14)C]-, and [U-(14)C]glucose and has little effect on (14)CO(2) formation from [1-(14)C]- or [2-(14)C]pyruvate or from [1-(14)C]fructose. [(14)C]Lactate formation from glucose is depressed 50% by Bt(2)cAMP. In the presence of an inhibitor of mitochondrial pyruvate transport lactate accumulation is enhanced, but continues to be lowered 50% by Bt(2)cAMP. The activity of phosphofructokinase is greatly decreased in Bt(2)cAMP-treated cells while the activities of pyruvate kinase and acetyl-CoA carboxylase are unaffected. It appears that decreased glycolytic flux and decreased citrate formation result from depressed phosphofructokinase activity. Fatty acid synthesis from [(14)C]acetate is partially inhibited by Bt(2)cAMP in the presence of fructose, lactate, and pyruvate despite a high citrate level. Incorporation of [(14)C]fructose, [(14)C]pyruvate, or [(14)C]lactate into fatty acids is similarly depressed by Bt(2)cAMP. Synthesis of cholesterol from [(14)C]acetate or [2-(14)C]pyruvate is unaffected by Bt(2)cAMP. These results implicate a second site of inhibition of fatty acid synthesis by Bt(2)cAMP that involves the utilization, but not the production, of cytoplasmic acetyl-CoA.-Clarke, S. D., P. A. Watkins, and M. D. Lane. Acute control of fatty acid synthesis by cyclic AMP in the chick liver cell: possible site of inhibition of citrate formation.