Effects of pent-4-enoate on cellular redox state, glycolysis and fatty acid oxidation in isolated perfused rat heart

The metabolic effects of pent-4-enoate were studied in beating and potassium-arrested perfused rat hearts. The addition of 0.8mm-pent-4-enoate to the fluid used to perfuse a potassium-arrested heart resulted in a 70% increase in the O(2) consumption and a 66% decrease in the glycolytic flux as measured in terms of the de-tritiation of [3-(3)H]glucose, although the proportion of the O(2) consumption attributable to glucose oxidation decreased from an initial 30% to 10%. The pent-4-enoate-induced increase in O(2) consumption was only 15% in the beating heart. In the potassium-arrested heart, pent-4-enoate stimulated palmitate oxidation by more than 100% when measured in terms of the production of (14)CO(2) from [1-(14)C]palmitate, but in the beating heart palmitate oxidation was inhibited. Perfusion of the heart with pent-4-enoate had no effect on the proportion of pyruvate dehydrogenase found in the active form, in spite of large changes in the CoASH and acetyl-CoA concentrations and changes in their concentration ratios. The effects of pent-4-enoate on the cellular redox state were dependent on the ATP consumption of the heart. In the beating heart, pent-4-enoate caused a rapid mitochondrial NAD(+) reduction that subsequently faded out, so that the final state was more oxidized than the initial state. The arrested heart, however, remained in a more reduced state than initially, even after the partial re-oxidation that followed the initial rapid NAD(+) reduction. The ability of pent-4-enoate to increase or decrease fatty acid oxidation can be explained on the basis of the differential effects of pent-4-enoate on the concentration of citric acid-cycle intermediates under conditions of high or low ATP consumption of the myocardial cell. The proportion of the fatty acids in the fuel consumed by the heart is probably primarily determined by the regulatory mechanisms of glycolysis. When pent-4-enoate causes an increase in the citric acid-cycle intermediates, feedback inhibition of glycolysis results in an increase in the oxidation of fatty acids.     

The stereochemical course of phosphoryl transfer catalysed by Bacillus stearothermophilus and rabbit skeletal-muscle phosphofructokinase with a chiral [16O,17O,18O]phosphate ester.

1. Soluble extracts from rat heart and liver mitochondria were used to evaluate the early steps in the conversion of pent-4-enoyl-CoA into tricarboxylic acid-cycle intermediates. Hitherto the unresolved problem was the reduction of the double bond of pent-4-enoate. 2. Soluble extracts from heart mitochondria reduced pent-4-enoyl-CoA and penta-2,4-dienoyl-CoA in the presence of NADPH at rates (nmol/min per mg of protein) of 0.9 +/- 0.1 and 132 +/- 8 and from the liver mitochondria at the rates of 1.9 +/- 0.2 and 52 +/- 6 respectively. No reduction of acryloyl-CoA was found. 3. We show that primarily the double bond in position 4, not in position 2, of penta-2,4-dienoyl-CoA is reduced. 4. It is concluded that the principal metabolic pathway of penta-4-enoate is reduction of the double bond in position 4 after an initial oxidation of penta-2,4-dienoyl-CoA. The pent-2-enoyl-CoA thus formed can be further metabolized by the usual enzymes of beta-oxidation, and by the further metabolism of propionyl-CoA to tricarboxylic acid-cycle intermediates.     

Isolated rat heart mitochondria are able to metabolize pent-4-enoate to tricarboxylic acid-cycle intermediates.

The metabolism of four short-chain odd-number-carbon fatty acids, pentanoate, pent-4-enoate, propionate and acrylate, was studied in isolated rat heart mitochondria incubated in [14C]bicarbonate buffer. Under these conditions pentanoate was metabolized with a concomitant accumulation of malate and incorporation of 14CO2 into non-volatile compounds. The metabolism of propionate to tricarboxylic acid-cycle intermediates required the addition of ATP and oligomycin. After addition of a small amount of rotenone to the incubation medium, pent-4-enoate was metabolized with an increase in malate from less than 3 nmol/mg of protein to 34.0 +/- 1.5 nmol/mg in 40 min, during which time the amount of 14CO2 fixed in acid-stable compounds increased from 1.56 +/- 0.30 to 41.1 +/- 2.6 nmol/mg of protein. Acrylate was not metabolized under any of the conditions tested. The results show that cardiac mitochondria must have an enzyme system that is capable of reducing the double bond of either pent-4-enoate or its metabolities. That the metabolism of pent-4-enoate occurs through a reductive step and energy-dependent carboxylation is evident from the requirement for NAD+ reduction by partial inhibition of the mitochondrial respiratory chain and the presence of ATP and CO2. The results do not enable us to say whether the compound reduced is pent-4-enoyl-CoA or acryloyl-CoA.     

In vivo induction of 4-enoyl-CoA reductase by clofibrate in liver mitochondria and its effect on pent-4-enoate metabolism

Feeding of clofibrate to male rats leads to a 4–7 fold increase in the activity of the 4-enoyl-CoA reductase in the liver. Concomitantly the inhibition of fatty acid oxidation by pent-4-enoate is abolished, and an increased glucose formation in the presence of pent-4-enoate is observed. It is suggested that pent-4-enoate is converted to propionyl-CoA via the reaction sequence pent-4-enoyl-CoA→pent-2,4-dienoyl-CoA→pent-2-enoyl-CoA→propionyl-CoA + acetyl-CoA.     

Substrate inhibition in the tricarboxylic acid cycle

It has been shown in the experiments on rat liver mitochondria under glucose hexo-kinase load that excess of substrates of (1-20 mM) pyruvate, acetate, propionate, pent-4-enoate and malate may induce oxidation of NAD(P)H and inhibition of mitochondrial respiration (by 20-50% and more) due to a decreased rate of hydrogen production by tricarboxylic acid cycle. It has been concluded from the analysis of mathematical models and metabolite-testings which remove this inhibition that for pyruvate and acetate this inhibition is an autocatalytic one. It is related to a decreased level of CoA and oxaloacetate due to the formation of "traps" such as acetyl-CoA and alpha-kotoglutarate. For propionate and pent-4-enoate in the bicarbonate-free medium suppression of the flux in the cycle is concerned with a decreased level of CoA, acetyl-CoA and succionoyl CoA due to the accumulation of propionyl-CoA. It seems to be also concerned with the inhibition of citrate-synthetase and alpha-ketoglutarate-dehydrogenase by propionyl-CoA. Malate (in the presence of malonate) can inhibit respiration at the expense of direct inhibition of citrate-synthetase.     

Potentiation by ammonia of the metabolic effects of pent-4-enoate in isolated rat hepatocytes.

The metabolic effects of pent-4-enoate were studied in isolated rat hepatocytes; 1 mM-pent-4-enoate did not significantly inhibit gluconeogenesis from lactate, alanine and glycerol, but significantly decreased glucose synthesis from pyruvate. The addition of 1 mM-NH4Cl led to a drastic inhibition of glucose synthesis from all these substrates. In hepatocytes incubated with 10 mM-alanine and 1 mM-oleate, pent-4-enoate at 0.05-1 mM slightly inhibited glucose synthesis and ketogenesis. The addition of ammonia resulted in a dramatic potentiation of the metabolic effects of pent-4-enoate. Half-maximum effect of ammonia was observed at 0.2 mM concentration. Concomitant cellular concentrations of ATP and acetyl-CoA were also decreased by the addition of ammonia, as were lactate/pyruvate ratio and beta-hydroxybutyrate/acetoacetate ratio. These data suggest that ammonia seriously interferes with the cellular metabolism of pent-4-enoate and leads to a dramatic potentiation of its effects.     

Elimination and replenishment of tricarboxylic acid-cycle intermediates in myocardium.

1. The contribution of Co2 fixation to the anaplerotic mechanisms in the myocardium was investigated in isolated perfused rat hearts. 2. K+-induced arrest of the heart was used to elicit a transition in the concentrations of the intermediates of the tricarboxylic acid cycle. 3. Incorporation of 14C from [14]bicarbonate into tricarboxylic acid-cycle intermediates was measured and the rates of the reactions of the cycle were estimated by means of a linear optimization program which solves the differential equations describing a simulation model of the tricarboxylic acid cycle and related reactions. 4. The results showed that the rate of CO2 fixation is dependent on the metabolic state of the myocardium. Upon a sudden diminution of cellular ATP consumption, the pool size of the tricarboxylic acid-cycle metabolites increased and the rate of label incorporation from [14C]bicarbonate into the cycle metabolites increased simultaneously. The computer model was necessary to separate the rapid equilibration between bicarbonate and some metabolites from the potentially anaplerotic reactions. The main route of anaplerosis during metabolite accumulation was through malate + oxaloacetate. Under steady-state conditions there was a constant net outward flow from the tricarboxylic acid cycle via the malate + oxaloacetate pool, with a concomitant anaplerotic flow from metabolites forming succinyl-CoA (3-carboxypropionyl-CoA).     

Inhibition of urea synthesis by pent-4-enoate associated with decrease in N-acetyl-L-glutamate concentration in isolated rat hepatocytes

Pent-4-enoate at 0.1 to 1.0 mM strongly inhibited urea synthesis in isolated rat hepatocytes. Pent-4-enoate at the same concentrations markedly decreased concentrations of $\text{N-}\text{acetyl-}\text{L}\text{-glutamate}$, an essential activator of carbamoyl-phosphate synthase-I (EC 2.7.2.5), and the decrease was well parallel with the inhibition of urea synthesis by pent-4-enoate. This compound also lowered cellular concentrations of acetyl-CoA, a substrate of acetylglutamate synthase (EC 2.3.1.1). Pent-4-enoate in a dose of 1 mM did not significantly affect cellular concentrations of ATP, and had no direct effect on acetylglutamate synthase activity. These results suggest that the inhibition of urea synthesis by pent-4-enoate is due to decrease in $\text{N-}\text{acetyl-}\text{L}\text{-glutamate}$ concentration and that the decrease is probably brought about by decreased rate of its synthesis due to the lowered concentration of cellular acetyl-CoA.     

Biochemical effects of the hypoglycaemic compound pent-4-enoic acid and related non-hypoglycaemic fatty acids. Effects of the free acids and their carnitine esters on coenzyme A-dependent oxidations in rat liver mitochondria

1. The synthesis of pent-4-enoyl-l-carnitine, cyclopropanecarbonyl-l-carnitine and cyclobutanecarbonyl-l-carnitine is described. 2. Pent-4-enoate strongly inhibits palmitoyl-l-carnitine oxidation in coupled but not in uncoupled mitochondria. Pent-4-enoyl-l-carnitine strongly inhibits palmitoyl-l-carnitine oxidation in uncoupled mitochondria. Prior intramitochondrial formation of pent-4-enoyl-CoA is therefore necessary for inhibition. 3. There was a small self-limiting pulse of oxidation of pent-4-enoyl-l-carnitine during which the ability to inhibit the oxidation of subsequently added palmitoyl-l-carnitine developed. 4. Pent-4-enoate and pent-4-enoyl-l-carnitine are equally effective inhibitors of the oxidation of all even-chain acylcarnitines of chain length C(4)-C(16). Pent-4-enoyl-l-carnitine also inhibits the oxidation of pyruvate and of 2-oxoglutarate. 5. Pent-4-enoate strongly inhibits the oxidation of palmitate but not that of octanoate. This is presumably due to competition between octanoate and pent-4-enoate for medium-chain acyl-CoA ligase. 6. There was less inhibition of the oxidation of pyruvate by pent-4-enoyl-l-carnitine, and of palmitoyl-l-carnitine by cyclopropanecarbonyl-l-carnitine, after pre-incubation with 10mm-arsenate. This suggests that these inhibitions were caused either by depletion of free CoA or by increase of acyl-CoA concentrations, since arsenate deacylates intramitochondrial acyl-CoA. There was little effect on the inhibition of palmitoyl-l-carnitine oxidation by pent-4-enoyl-l-carnitine. 7. Penta-2,4-dienoate strongly inhibited palmitoyl-l-carnitine oxidation in coupled mitochondria; acrylate only inhibited slightly. 8. Pent-4-enoate (0.1mm) caused a rapid and almost complete decrease in free CoA and a large increase in acid-soluble acyl-CoA when incubated with coupled mitochondria. Cyclopropanecarboxylate caused a similar decrease in CoA, with an equivalent rise in acid-soluble acyl-CoA concentrations. n-Pentanoate caused extensive lowering of CoA and a large increase in acid-soluble acyl-CoA and acetyl-CoA concentrations. Octanoate caused a 50% lowering of CoA and an increase in acid-soluble acyl-CoA and acetyl-CoA concentrations. 9. Cyclopropanecarboxylate and n-pentanoate were less potent inhibitors of palmitate oxidation than was pent-4-enoate. 10. It is concluded that pent-4-enoate causes a specific inhibition of beta-oxidation after the formation intramitochondrially of its metabolites.     

Respiratory control in isolated perfused rat heart. Role of the equilibrium relations between the mitochondrial electron carriers and the adenylate system.

The effects of KCl-induced cardiac arrest on the redox state of the fluorescent flavoproteins and nicotinamide nucleotides and on that of cytochromes c and a were studied by surface fluorometric and reflectance spectrophotometric methods. These changes were compared with measurements of the concentrations of the adenylate system, creatine phosphate, some intermediates of the tricarboxylic acid cycle and reactants of the glutamate dehydrogenase system. KCl-induced cardiac arrest caused reduction of the fluorescent flavoproteins and nicotinamide nucleotides, oxidation of cytochromes c and a, inhibition of oxygen consumption and an increase in the ATP/(ADP X Pi) ratio. The increase in the latter was due mainly to a decrease in the concentration of Pi and an equivalent increase in creatine phosphate. The cytochromes c and a were maintained at equal redox potential and changed in parallel. When the redox state of the mitochondrial NAD couple was calculated from the glutamate dehydrogenase equilibrium, the free energy change (deltaG) corresponding to the potential difference between the NAD couple and cytochrome c was 115.8 kj/mol in the beating heart and 122.2 kj/mol in the arrested heart. The deltaG values of ATP hydrolysis calculated from the concentrations of ATP, Pi and ADP, corrected for bound ADP, were 111.1 kj/2 mol and 115.4 kj/2 mol in the beating and arrested heart respectively. The accumulation of citrate and the direction of the redox changes in the respiratory carriers indicate that the tricarboxylic acid cycle flux is controlled by the respiratory chain. The data also show a near equilibrium between the electron carriers and the adenylate system and suggest that the equilibrium hypothesis of mitochondrial respiratory control is applicable to intact myocardial tissue.     

Respiratory control in isolated perfused rat heart. Role of the equilibrium relations between the mitochondrial electron carriers and the adenylate system

The effects of KCl-induced cardiac arrest on the redox state of the fluorescent flavoproteins and nicotinamide nucleotides and on that of cytochromes c and a were studied by surface fluorometric and reflectance spectrophotometric methods. These changes were compared with measurements of the concentrations of the adenylate system, creatine phosphate, some intermediates of the tricarboxylic acid cycle and reactants of the glutamate dehydrogenase system.

KCl-induced cardiac arrest caused reduction of the fluorescent flavoproteins and nicotinamide nucleotides, oxidation of cytochromes c and a, inhibition of oxygen consumption and an increase in the ATP/(ADP × P_i) ratio. The increase in the latter was due mainly to a decrease in the concentration of P_i and an equivalent increase in creatine phosphate. The cytochromes c and a were maintained at equal redox potential and changed in parallel. When the redox state of the mitochondrial NAD couple was calculated from the glutamate dehydrogenase equilibrium, the free energy change (ΔG) corresponding to the potential difference between the NAD couple and cytochrome c was 115.8 kJ/mol in the beating heart and 122.2 kJ/mol in the arrested heart. The ΔG values of ATP hydrolysis calculated from the concentrations of ATP, P_i and ADP, corrected for bound ADP, were 111.1 kJ/2 mol and 115.4 kJ/2 mol in the beating and arrested heart respectively.

The accumulation of citrate and the direction of the redox changes in the respiratory carriers indicate that the tricarboxylic acid cycle flux is controlled by the respiratory chain. The data also show a near equilibrium between the electron carriers and the adenylate system and suggest that the equilibrium hypothesis of mitochondrial respiratory control is applicable to intact myocardial tissue.     

Effect of acetate and octanoate on tricarboxylic acid cycle metabolite disposal during propionate oxidation in the perfused rat heart

Tricarboxylic acid cycle pool size is determined by anaplerosis and metabolite disposal. The regulation of the latter during propionate metabolism was studied in isolated perfused rat hearts in the light of the characteristics of NADP-linked malic enzyme, which is inhibited by acetyl-CoA. The acetyl-CoA concentration was varied by infusions of acetate and octanoate, and the rate of metabolite disposal was calculated from a metabolic balance sheet compiled from the relevant metabolic fluxes. Propionate addition increased the tricarboxylic acid cycle pool size 4-fold and co-infusion of acetate or octanoate did not change it further. Propionate caused a decrease in the CoA-SH concentration and a 10-fold increase in the propionyl-CoA concentration. A paradoxical increase in the CoA-SH concentration was observed upon co-infusion of acetate in the presence of propionate, an effect probably caused by competitive inhibition of propionate activation. A more pronounced decline in the propionyl-CoA concentration was observed upon the co-infusion of octanoate. In a metabolic steady state, acetate and octanoate reduced propionate disposal only slightly, but did not increase the tricarboxylic acid cycle pool size. The results are in accord with the notion that the tricarboxylic acid pool size is mainly regulated by the anaplerotic mechanisms.     

Effect of pent-4-enoic acid, propionic acid and other short-chain fatty acids on citrulline synthesis in rat liver mitochondria.

19 The effect of pent-4-enoic acid, propionic acid and several other short-chain fatty acids on citrulline synthesis in rat liver mitochondria was studied. 2.Pent-4-enoate at 1 mM inhibited mitochondrial citulline synthesis by about 80-90%. It is concluded that pent-4-enoate inhibits citrulline synthesis by interfering with some aspect of mitochondrial energy metabolism. This results in impairment of mitochondrial ornithine uptake or depletion of mitochondrial ATP, which, in turn, impairs carbamoyl phosphate synthesis or both. Evidence in support of this conclusion includes: pent-4-enoate has no effect on citrulline synthesis supported by succinate or exogenous ATP; pent-4-enoate lowers the medium plus mitochondrial ATP concentration; finally, when glutamate is the oxidizable substrate, pent-4-enoate decreases the carbamoyl phosphate concentration in mitochondria incubated without ornithine to minimize citrulline synthesis and impairs the mitochondrial uptake of ornithine, but it has neither effect when succinate is the oxidizable substrate. 4. Propionate, butyrate and crotonate also inhibit mitochondrial citrulline synthesis, but much less than pent-4-enoate. 5. Acetate, pentanoate, pent-2-enoate, hexanoate, octanoate, isovalerate, tiglylate and alpha-methylbutyrate have little or no effect on mitochondrial citrulline synthesis.     

Accumulation and disposal of tricarboxylic acid cycle intermediates during propionate oxidation in the isolated perfused rat heart

The role of the metabolite disposal mechanisms in the regulation of the tricarboxylic acid cycle pool size was studied in isolated perfused rat hearts oxidizing 2 mM propionate. Malate and succinate accumulated during the propionate metabolism. A further 118% increase in the malate concentration and 600% increase in the succinate concentration and a slight inhibition of the propionate uptake were observed during a subsequent KCl-induced arrest of the heart metabolizing propionate. When the mechanical activity of the heart was restored, the malate and succinate concentrations returned to the same levels as before the arrest of the heart, but the propionate uptake did not rise significantly. The mean disposal rates of the tricarboxylic acid cycle metabolites during the cardiac arrest and subsequent restoration of the activity were 1.4 and 2.4 μmol/min per g dry weight, respectively. During cardiac arrest the malate carbon disposed was almost totally recovered as C₃ compounds, whereas after the increase in the ATP-consumption most of it was oxidized. The results show that propionate is oxidized by heart muscle at an appreciable rate but the disposal rate of the tricarboxylic acid cycle intermediates is not tightly regulated by the cellular energy state. Although the metabolite pool size of the tricarboxylic acid cycle responds to change in the ATP consumption, the energy state appears to have a greater effect on the fate of the C₃ compounds formed than on the actual rate of C₄ compound disposition.     

Inhibition of urea synthesis by pent-4-enoic acid: potentiation by ammonia

Pent-4-enoic acid inhibited ureagenesis approximatively 90% in rat hepatocytes incubated with pyruvate, ammonia and ornithine. Inhibition of ureagenesis was much less with alanine as substrate (approximatively 10%). The addition of ammonia led to a drastic dose-dependent inhibition of ureagenesis by pent-4-enoate. Half-maximum effect of ammonia was observed at 0.2 mM concentration. Concomitant cellular concentrations of N-acetylglutamate were also drastically modified by the addition of ammonia as was the accumulation of citrulline. These data suggest that ammonia may seriously interfere with the metabolism of pent-4-enoic acid and leads to a dramatic potentiation of its toxicity.     

Role of pyruvate carboxylation in the energy-linked regulation of pool sizes of tricarboxylic acid-cycle intermediates in the myocardium.

The increase in the metabolite pool size of the tricarboxylic acid cycle in the isolated perfused rat heart after a decrease in the ATP consumption by KCl-induced arrest was used to study the anaplerotic mechanisms. During net anaplerosis the label incorporation into the tricarboxylic acid-cycle intermediates from [1-14C]pyruvate increased and occurred mainly by pathways not involving prior release of the label to CO2. A method for determination of the specific radioactivity of mitochondrial pyruvate was devised, and the results corroborated the notion that tissue alanine can be used as an indicator of the specific radioactivity of intracellular pyruvate.     

The effect of hexokinase and tricarboxylic acid-cycle intermediates on fatty acid oxidation and formation of ketone bodies by rat-liver mitochondria

1. The oxidation of butyrate, hexanoate and octanoate by rat-liver mitochondria suspended in a tris-potassium chloride medium in the presence of malate and serum albumin has been investigated. 2. The oxidation of butyrate to acetoacetate was markedly decreased by the addition of a system competitive for ATP (hexokinase-glucose). 3. Serum albumin or tricarboxylic acid-cycle intermediates prevented the inhibition by hexokinase and in their presence a greater proportion of the oxygen consumption was contributed by the tricarboxylic acid cycle. The results suggest that the energy supply for fatty acid activation is either compartmentalized in a spatial or kinetic sense or there exists a special activating mechanism not involving ATP. 4. Malate and other tricarboxylic acid-cycle intermediates caused substantial reduction (to beta-hydroxybutyrate) of the acetoacetate formed during the oxidation of butyrate, hexanoate and octanoate.     

Biochemical effects of the hypoglycaemic compound pent-4-enoic acid and related non-hypoglycaemic fatty acids. Effects of their coenzyme A esters on enzymes of fatty acid oxidation

1. Pent-4-enoyl-CoA and its metabolites penta-2,4-dienoyl-CoA and acryloyl-CoA, as well as n-pentanoyl-CoA, cyclopropanecarbonyl-CoA and cyclobutanecarbonyl-CoA, were examined as substrates or inhibitors of purified enzymes of beta-oxidation in an investigation to locate the site of inhibition of fatty acid oxidation by pent-4-enoate. 2. The reactions of various acyl-CoA derivatives with l-carnitine and of various acyl-l-carnitine derivatives with CoA, catalysed by carnitine acetyltransferase, were investigated and V(max.) and K(m) values were determined. Pent-4-enoyl-CoA and n-pentanoyl-CoA were good substrates, whereas cyclobutanecarbonyl-CoA, cyclopropanecarbonyl-CoA and acryloyl-CoA reacted more slowly. A very slow rate with penta-2,4-dienoyl-CoA was detected. Pent-4-enoyl-l-carnitine, n-pentanoyl-l-carnitine and cyclobutanecarbonyl-l-carnitine were good substrates and cyclopropanecarbonyl-l-carnitine reacted more slowly. 3. Pent-4-enoyl-CoA and n-pentanoyl-CoA were substrates for butyryl-CoA dehydrogenase and for octanoyl-CoA dehydrogenase, and both compounds were equally effective competitive inhibitors of these enzymes with butyryl-CoA or palmitoyl-CoA respectively as substrates. V(max.), K(m) and K(i) values were determined. 4. None of the acyl-CoA derivatives inhibited enoyl-CoA hydratase or 3-hydroxybutyryl-CoA dehydrogenase. Penta-2,4-dienoyl-CoA was a substrate for enoyl-CoA hydratase when the reaction was coupled to that catalysed by 3-hydroxybutyryl-CoA dehydrogenase. 5. In a reconstituted sequence with purified enzymes crotonoyl-CoA was largely converted into acetyl-CoA, and pent-2-enoyl-CoA into acetyl-CoA and propionyl-CoA. Penta-2,4-dienoyl-CoA was slowly converted into acetyl-CoA and acryloyl-CoA. 6. Penta-2,4-dienoyl-CoA, a unique metabolite of pent-4-enoate, was the only compound that specifically inhibited an enzyme of the beta-oxidation sequence, 3-oxoacyl-CoA thiolase. The formation of penta-2,4-dienoyl-CoA could explain the strong inhibition of fatty acid oxidation in intact mitochondria by pent-4-enoate.     

In vivo modular control analysis of energy metabolism in contracting skeletal muscle

We used (31)P MRS (magnetic resonance spectroscopy) measurements of energetic intermediates [ATP, P(i) and PCr (phosphocreatine)] in combination with the analytical tools of metabolic control analysis to study in vivo energy metabolism in the contracting skeletal muscle of anaesthetized rats over a broad range of workload. According to our recent MoCA (modular control analysis) used to describe regulatory mechanisms in beating heart, we defined the energetic system of muscle contraction as two modules (PCr-Producer and PCr-Consumer) connected by the energetic intermediates. Hypoxia and electrical stimulation were used in this in vivo study as reasonably selective modulations of Producer and Consumer respectively. As quantified by elasticity coefficients, the sensitivities of each module to PCr determine the control of steady-state contractile activity and metabolite concentrations. The magnitude of the elasticity of the producer was high (4.3+/-0.6) at low workloads and decreased 5-fold (to 0.9+/-0.2) at high workloads. By contrast, the elasticity of the consumer remained low (0.5-1.2) over the range of metabolic rates studied. The control exerted by each module over contraction was calculated from these elasticities. The control of contraction was found on the consumer at low workloads and then swung to the producer, due to the workload-dependent decrease in the elasticity of producer. The workload-dependent elasticity and control pattern of energy production in muscle is a major difference from heart. Since module rate and elasticity depend on the concentrations of substrates and products, the absence of homoeostasis of the energetic intermediates in muscle, by contrast with heart, is probably the origin of the workload-dependent elasticity of the producer module.     

Protection of rats by clofibrate against the hypoglycaemic and toxic effects of hypoglycin and pent-4-enoate. An ultrastructural and biochemical study.

An ultrastructural and biochemical study of the toxic and hypoglycaemic effects of hypoglycin and pent-4-enoate was made on the livers of normal and clofibrate-fed rats. Injection of hypoglycin to rats doubles (from 22% to 44%) the volume fraction of mitochondria and decreases (from 1.05% to 0.26%) the volume fraction of peroxisomes in hepatocytes. The fast-acting toxin pent-4-enoate causes few ultrastructural changes except for the accumulation of lipids. In male adult rats fed with 0.5% clofibrate in their diet for 1-2 months, the volume fraction occupied by peroxisomes and mitochondria in hepatocytes rose to 6.26% and 29.5% respectively. Clofibrate feeding apparently protected the animals against the toxic, hypoglycaemic and hypothermic effects of hypoglycin and of pent-4-enoate, and completely prevented the ultrastructural damage caused by hypoglycin. After hypoglycin administration, hepatic mitochondrial butyryl-CoA dehydrogenase activity was inhibited by more than 90% and, surprisingly, the activity of the peroxisomal enzymes studied was largely preserved. When hypoglycin was given to rats fed on a clofibrate-containing diet, the oxidation of decanoylcarnitine, which was incomplete after hypoglycin treatment alone, remained incomplete with uncoupled mitochondria, but became apparently complete with coupled mitochondria. In the latter condition, there was a slowing of the rate during the last quarter of the pulse of oxygen uptake. Further, butyryl-CoA dehydrogenase activity was much less affected by hypoglycin in clofibrate-fed animals. Pent-4-enoate does not inhibit beta-oxidation in coupled mitochondria from clofibrate-treated rats.