Effect of carnitine on mitochondrial oxidation of palmitoylcarnitine

The effects of carnitine on the metabolism of palmitoylcarnitine were studied by using isolated rat liver mitochondria. Particular attention was given to carnitine acyltransferase-mediated interactions between carnitine and the mitochondrial CoA pool. Carnitine concentrations less than 1.25mm resulted in an increased production of acetylcarnitine during palmitoylcarnitine oxidation. Despite this shunting of C₂ units to acetylcarnitine formation, no change was observed in the rate of oxygen consumption or major product formation (citrate or acetoacetate). Further, no changes were observed in the mitochondrial content of acetyl-CoA, total acid-soluble CoA or acid-insoluble acyl-CoA. These observations support the concept, based on studies in vivo, that the carnitine/acylcarnitine pool is metabolically sluggish and the acyl-group flux low as compared with the CoA/acyl-CoA pool. Acid-insoluble acyl-CoA content was decreased and CoA content increased at carnitine concentrations greater than 1.25mm. When [¹⁴C]carnitine was used in the incubations, it was demonstrated that this resulted from acid-insoluble acylcarnitine formation from intramitochondrial acid-insoluble acyl-CoA mediated by carnitine palmitoyltransferase B. Again, the higher carnitine concentrations resulted in no changes in the rates of oxygen consumption or major product formation. The above effects of carnitine were observed whether citrate or acetoacetate was the major product of oxidation. In contrast, an increase in acetyl-CoA concentration was observed at high carnitine concentrations only when acetoacetate was the product. Since the rate of acetoacetate production was not changed, these higher acetyl-CoA concentrations suggest that a new steady state had been established to maintain acetoacetate-production rates. Since there was no change in acetyl-CoA concentration when citrate was the major product, a change in the activity of the pathway utilizing acetyl-CoA for ketone-body synthesis and the potential regulation of this pathway must be considered.     

The effect of acute and prolonged ethanol treatment on the concentrations of coenzyme A, carnitine and their derivatives in rat liver

1. CoA, acetyl-CoA, long-chain acyl-CoA, carnitine, acetylcarnitine and long-chain acylcarnitine were measured in rat liver under various conditions. 2. Starvation caused an increase in the contents of these intermediates, except that of carnitine. 3. A single dose of ethanol had no effect on CoA content, whereas those of acetyl-CoA, acetylcarnitine and carnitine were increased and those of long-chain acyl-CoA and acylcarnitine were decreased. 4. Four weeks' adaptation to ethanol consumption did not change the effect of ethanol administration on these metabolites. 5. It is suggested that ethanol directly increases hepatic fatty acid synthesis and esterification. It is also suggested that this change is reversible and limited to the period of ethanol oxidation. 6. It is demonstrated that ethanol-induced triglyceride accumulation is not related to carnitine deficiency.     

Relationship between acid-soluble carnitine and coenzyme A pools in vivo

The relationship between the acid-soluble carnitine and coenzyme A pools was studied in fed and 24-h-starved rats after carnitine administration. Carnitine given by intravenous injection at a dose of 60μmol/100g body wt. was integrated into the animal's endogenous carnitine pool. Large amounts of acylcarnitines appeared in the plasma and liver within 5min of carnitine injection. Differences in acid-soluble acylcarnitine concentrations were observed between fed and starved rats after injection and reflected the acylcarnitine/carnitine relationship seen in the endogenous carnitine pool of the two metabolic states. Thus, a larger acylcarnitine production was seen in starved animals and indicated a greater source of accessible acyl-CoA molecules. In addition to changes in the amount of acylcarnitines present, the specific acyl groups present also varied between groups of animals. Acetylcarnitine made up 37 and 53% of liver acid-soluble acylcarnitines in uninjected fed and starved animals respectively. At 5min after carnitine injection hepatic acid-soluble acylcarnitines were 41 and 73% in the form of acetylcarnitine in fed and starved rats respectively. Despite these large changes in carnitine and acylcarnitines, no changes were observed in plasma non-esterified fatty acid or β-hydroxybutyrate concentrations in either fed or starved rats. Additionally, measurement of acetyl-CoA, coenzyme A, total acid-soluble CoA and acid-insoluble CoA demonstrated that the hepatic CoA pool was resistant to carnitine-induced changes. This lack of change in the hepatic CoA pool or ketone-body production while acyl groups are shunted from acyl-CoA molecules to acylcarnitines suggests a low flux through the carnitine pool compared with the CoA pool. These results support the concept that the carnitine/acid-soluble acylcarnitine pool reflects changes in, rather than inducing changes in, the hepatic CoA/acyl-CoA pool.     

Quantitation of the effect of L-carnitine on the levels of acid-soluble short-chain acyl-CoA and CoASH in rat heart and liver mitochondria

The steady state levels of mitochondrial acyl-CoAs produced during the oxidation of pyruvate, alpha-ketoisovalerate, alpha-ketoisocaproate, and octanoate during state 3 and state 4 respiration by rat heart and liver mitochondria were determined. Addition of carnitine lowered the amounts of individual short-chain acyl-CoAs and increased CoASH in a manner that was both tissue- and substrate-dependent. The largest effects were on acetyl-CoA derived from pyruvate in heart mitochondria using either state 3 or state 4 oxidative conditions. Carnitine greatly reduced the amounts of propionyl-CoA derived from alpha-ketoisovalerate, while smaller effects were obtained on the branched-chain acyl-CoA levels, consistent with the latter acyl moieties being poorer substrates for carnitine acetyltransferase and also poorer substrates for the carnitine/acylcarnitine translocase. The levels of acetyl-CoA in heart and liver mitochondria oxidizing octanoate during state 3 respiration were lower than those obtained with pyruvate. The rate of acetylcarnitine efflux from heart mitochondria during state 3 (with pyruvate or octanoate as substrate, in the presence or absence of malate with 0.2 mM carnitine) shows a linear response to the acetyl-CoA/CoASH ratio generated in the absence of carnitine. This relationship is different for liver mitochondria. These data demonstrate that carnitine can modulate the aliphatic short-chain acyl-CoA/CoA ratio in heart and liver mitochondria and indicate that the degree of modulation varies with the aliphatic acyl moiety.     

Formation of acetylcarnitine in muscle of horse during high intensity exercise

To study the changes in carnitine in muscle with spring exercise, two Thoroughbred horses performed two treadmill exercise tests. Biopsies of the middle gluteal were taken before, after exercise and after 12 min recovery. Resting mean muscle total carnitine content was 29.5 mmol.kg-1 dry muscle (d.m.). Approximately 88% was free carnitine, 7% acetylcarnitine and acylcarnitine was estimated at 5%. Exercise did not affect total carnitine, but resulted in a marked fall in free carnitine and almost equivalent rise in acetylcarnitine. The results are consistent with a role for carnitine in the regulation of the acetyl-CoA/CoA ratio during sprint exercise in the Thoroughbred horse by buffering excess production of acetyl units.     

Control of fatty acid metabolism in ischemic and hypoxic hearts

The effects of whole heart ischemia on fatty acid metabolism were studied in the isolated, perfused rat heart. A reduction in coronary flow and oxygen consumption resulted in lower rates of palmitate uptake and oxidation to CO2. This decrease in metabolic rate was associated with increased tissue levels of long chain acyl coenzyme A and long chain acylcarnitine. Cellular levels of acetyl-CoA, acetylcarnitine, free CoA, and free carnitine decreased. These changes in CoA and its acyl derivatives indicate that beta oxidation became the limiting step in fatty acid metabolism. The rate of beta oxidation was probably limited by high levels of NADH and FADH2 secondary to a reduced supply of oxygen. Tissue levels of neutral lipids showed a slight increase durning ischemia, but incorporation of [U-14C]palmitate into lipid was not altered significantly. Although both substrates for lipid synthesis were present in higher concentrations during ischemia, compartmentalization of long chain acyl-CoA in the mitochondrial matrix and alpha-glycerol phosphate in the cytosol may have accounted for the relatively low rate of lipid synthesis.     

Quantitation of the efflux of acylcarnitines from rat heart, brain, and liver mitochondria

The efflux of individual short-chain and medium-chain acylcarnitines from rat liver, heart, and brain mitochondria metabolizing several substrates has been measured. The acylcarnitine efflux profiles depend on the substrate, the source of mitochondria, and the incubation conditions. The largest amount of any acylcarnitine effluxing per mg of protein was acetylcarnitine produced by heart mitochondria from pyruvate. This efflux of acetylcarnitine from heart mitochondria is almost 5 times greater with 1 mM than 0.2 mM carnitine. Apparently the acetyl-CoA generated from pyruvate by pyruvate dehydrogenase is very accessible to carnitine acetyltransferase. Very little acetylcarnitine effluxes from heart mitochondria when octanoate is the substrate except in the presence of malonate. Acetylcarnitine production from some substrates peaks and then declines, indicating uptake and utilization. The unequivocal demonstration that considerable amounts of propionylcarnitine or isobutyrylcarnitine efflux from heart mitochondria metabolizing alpha-ketoisovalerate and alpha-keto-beta-methylvalerate provides evidence for a role (via removal of non-metabolizable propionyl-CoA or slowly metabolizable acyl-CoAs) for carnitine in tissues which have limited capacity to metabolize propionyl-CoA. These results also show propionyl-CoA must be formed during the metabolism of alpha-ketoisovalerate and that extra-mitochondrial free carnitine rapidly interacts with matrix short-chain aliphatic acyl-CoA generated from alpha-keto acids of branched-chain amino acids and pyruvate in the presence and absence of malate.     

Carnitine metabolism in livers and hearts of 48h-starved rats: the contribution of fat and carbohydrate to acylcarnitine formation

The work investigated the effects of administration of 2-tetradecylglycidate (TDG), an inhibitor of mitochondrial long-chain fatty acid oxidation, alone or in combination with glucose, on concentrations of free and acylated carnitine in livers and hearts of 48 h-starved rats. The only significant effect of TDG in the heart was to decrease [short-chain acylcarnitine]. This demonstrates that in heart, fat oxidation is linked to the formation of short-chain acylcarnitine. Cardiac [short-chain acylcarnitine] was not significantly decreased by TDG if the rats were also administered glucose, suggesting that acyl CoA derived from glucose may be used for short-chain acylcarnitine formation in TDG-treated rats. TDG significantly decreased in [free carnitine]. No changes in [short-chain acylcarnitine] were observed. This indicates that formation of short-chain acylcarnitine in liver is not determined by the rates of fat oxidation. It was calculated that at least 63% of the acyl-groups esterified to carnitine were generated by intramitochondrial beta-oxidation. The effects of glucose and TDG on hepatic concentrations of free and long-chain acylcarnitine were additive, suggesting that extramitochondrial fat oxidation can contribute to acylcarnitine formation in liver.     

Carnitine acetyltransferase in pea cotyledon mitochondria

Purified pea cotyledon mitochondria did not oxidise acetyl-CoA in the presence of carnitine. However, acetylcarnitine was oxidised. It was concluded that acetylcarnitine passed through the mitochondrial membrane barrier but acetyl-CoA did not. Only a sensitive radioactive assay detected carnitine acetyltransferase in intact mitochondrion or intact mitoplast preparations. When the mitochondria or mitoplasts were burst, acetyl-CoA substrate was available to the matrix carnitine acetyltransferase and a high activity of the enzyme was measured. The inner mitochondrial membrane is there-fore the membrane barrier to acetyl-CoA but acetylcarnitine is suggested to be transported through this membrane via an integral carnitine: acylcarnitine translocator. Evidence is presented to indicate that when the cotyledons from 48-h-grown peas are oxidising pyruvate, acetylcarnitine formed in the mitochondrial matrix by the action of matrix carnitine acetyltransferase may be transported to extra-mitochondrial sites via the membrane translocator.     

Disassociation between acidinsoluble acylcarnitines and ketogenesis following carnitine administration in vivo

1-Carnitine was administered to fed rats and the changes in plasma beta-hydroxybutrate concentration and liver acid-insoluble acylcarnitine content were assessed. One hour following injection of carnitine in doses greater than 1 mumol/100 g of body weight there was a dose-dependent increase in liver acid-insoluble acylcarnitine content to levels comparable to those seen in fasting. These increased levels were maintained for a least 2 h following injection. During the period following carnitine administration there was no increase in ketogenesis as evidenced by plasma beta-hydroxybutyrate concentrations. Since acid-insoluble acylcarnitines represent the product of carnitine palmitoyltransferase A, the results are interpreted as contradictory to the theory that this enzyme is rate-limiting and regulatory for ketogenesis.     

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.     

In vivo and in vitro intervention with L-carnitine prevents abnormal energy metabolism in isolated diabetic rat heart: chemical and phosphorus-31 NMR evidence

The beneficial effects of in vivo injections (200 mg/kg, twice daily) or in vitro perfusion (5.0 mM) of L-carnitine on an intrinsic abnormality in energy metabolism was investigated in isolated, perfused diabetic rat heart. Hearts were aerobically perfused for 60 min with elevated fatty acid substrate to simulate diabetic conditions. Phosphorus-31 nuclear magnetic resonance spectroscopy revealed a temporal decline in myocardial ATP levels (to approx 82%) during perfusion of diabetic hearts, but not in control hearts. This reduction was prevented by prior treatment in vivo with L-carnitine or by providing L-carnitine acutely in the perfusion medium. Chemical analysis of tissue extracts indicated that L-carnitine injections were effective in replenishing the decrease in total myocardial carnitine content which was present in diabetic hearts and in preventing the accumulation of long chain fatty acyl CoA. Perfusion with L-carnitine also attenuated the elevation of long chain fatty acyl CoA in diabetic hearts. This study gives additional support to the hypothesis that decreases in ATP which occur in the isolated, perfused diabetic heart are correlated with a concomitant elevation in long chain fatty acyl CoA, a known inhibitor of adenine nucleotide translocase. In the presence of elevated exogenous fatty acids, a primary deficiency in the total myocardial carnitine pool would result in elevations in tissue concentrations of long chain fatty acyl CoA since carnitine is a required carrier for transport of fatty acids into mitochondria. Replenishment of the carnitine in vivo was shown to be sufficient to prevent subsequent alteration in long chain fatty acyl CoA and ATP in isolated perfused diabetic hearts despite the burden of elevated fatty acid substrates.     

Aspects of carnitine ester metabolism in sheep liver

1. Carnitine acetyltransferase (EC 2.3.1.7) activity in sheep liver mitochondria was 76nmol/min per mg of protein, in contrast with 1.7 for rat liver mitochondria. The activity in bovine liver mitochondria was comparable with that of sheep liver mitochondria. Carnitine palmitoyltransferase activity was the same in both sheep and rat liver mitochondria. 2. The [free carnitine]/[acetylcarnitine] ratio in sheep liver ranged from 6:1 for animals fed ad libitum on lucerne to approx. 1:1 for animals grazed on open pastures. This change in ratio appeared to reflect the ratio of propionic acid to acetic acid produced in the rumen of the sheep under the two dietary conditions. 3. In sheep starved for 7 days the [free carnitine]/[acetylcarnitine] ratio in the liver was 0.46:1. The increase in acetylcarnitine on starvation was not at the expense of free carnitine, as the amounts of free carnitine and total acid-soluble carnitine rose approximately fivefold on starvation. An even more dramatic increase in total acid-soluble carnitine of the liver was seen in an alloxan-diabetic sheep. 4. The [free CoA]/[acetyl-CoA] ratio in the liver ranged from 1:1 in the sheep fed on lucerne to 0.34:1 for animals starved for 7 days. 5. The importance of carnitine acetyltransferase in sheep liver and its role in relieving ;acetyl pressure' on the CoA system is discussed.     

Deacylation of acetyl-coenzyme A and acetylcarnitine by liver preparations.

The breakdown of acetylcarnitine catalysed by extracts of rat and sheep liver was completely abolished by Sephadex G-25 gel filtration, whereas the hydrolysis of acetyl-CoA was unaffected. Acetyl-CoA and CoA acted catalytically in restoring the ability of Sephadex-treated extracts to break down acetylcarnitine, which was therefore not due to an acetylcarnitine hydrolase but to the sequential action of carnitine acetyltransferase and acetyl-CoA hydrolase. Some 75% of the acetyl-CoA hydrolase activity of sheep liver was localized in the mitochondrial fraction. Two distinct acetyl-CoA hydrolases were partially purified from extracts of sheep liver mitochondria. Both enzymes hydrolysed other short-chain acyl-CoA compounds and succinyl-CoA (3-carboxypropionyl-CoA), but with one acetyl-CoA was the preferred substrate.     

Relationships between carnitine and coenzyme A esters in tissues of normal and alloxan-diabetic sheep

1. The total acid-soluble carnitine concentrations of four tissues from Merino sheep showed a wide variation not reported for other species. The concentrations were 134, 538, 3510 and 12900nmol/g wet wt. for liver, kidney cortex, heart and skeletal muscle (M. biceps femoris) respectively. 2. The concentration of acetyl-CoA was approximately equal to the concentration of free CoA in all four tissues and the concentration of acid-soluble CoA (free CoA plus acetyl-CoA) decreased in the order liver>kidney cortex>heart>skeletal muscle. 3. The total amount of acid-soluble carnitine in skeletal muscle of lambs was 40% of that in the adult sheep, whereas the concentration of acid-soluble CoA was 2.5 times as much. A similar inverse relationship between carnitine and CoA concentrations was observed when different muscles in the adult sheep were compared. 4. Carnitine was confined to the cytosol in all four tissues examined, whereas CoA was equally distributed between the mitochondria and cytosol in liver, approx. 25% was present in the cytosol in kidney cortex and virtually none in this fraction in heart and skeletal muscle. 5. Carnitine acetyltransferase (EC 2.3.1.7) was confined to the mitochondria in all four tissues and at least 90% of the activity was latent. 6. Acetate thiokinase (EC 6.2.1.1) was predominantly (90%) present in the cytosol in liver, but less than 10% was present in this fraction in heart and skeletal muscle. 7. In alloxan-diabetes, the concentration of acetylcarnitine was increased in all four tissues examined, but the total acid-soluble carnitine concentration was increased sevenfold in the liver and twofold in kidney cortex. 8. The concentration of acetyl-CoA was approximately equal to that of free CoA in the four tissues of the alloxan diabetic sheep, but the concentration of acid-soluble CoA in liver increased approximately twofold in alloxan-diabetes. 9. The relationship between CoA and carnitine and the role of carnitine acetyltransferase in the various tissues is discussed. The quantitative importance of carnitine in ruminant metabolism is also emphasized.     

Effects of ciprofibrate and 2-[5-(4-chlorophenyl)pentyl]oxirane-2-carboxylate (POCA) on the distribution of carnitine and CoA and their acyl-esters and on enzyme activities in rats. Relation between hepatic carnitine concentration and carnitine acetyltransferase activity.

The effects of feeding the peroxisome proliferators ciprofibrate (a hypolipidaemic analogue of clofibrate) or POCA (2-[5-(4-chlorophenyl)pentyl]oxirane-2-carboxylate) (an inhibitor of CPT I) to rats for 5 days on the distribution of carnitine and acylcarnitine esters between liver, plasma and muscle and on hepatic CoA concentrations (free and acylated) and activities of carnitine acetyltransferase and acyl-CoA hydrolases were determined. Ciprofibrate and POCA increased hepatic [total CoA] by 2 and 2.5 times respectively, and [total carnitine] by 4.4 and 1.9 times respectively, but decreased plasma [carnitine] by 36-46%. POCA had no effect on either urinary excretion of acylcarnitine esters or [acylcarnitine] in skeletal muscle. By contrast, ciprofibrate decreased [acylcarnitine] and [total carnitine] in muscle. In liver, ciprofibrate increased the [carnitine]/[CoA] ratio and caused a larger increase in [acylcarnitine] (7-fold) than in [carnitine] (4-fold), thereby increasing the [short-chain acylcarnitine]/[carnitine] ratio. POCA did not affect the [carnitine]/[CoA] and the [short-chain acylcarnitine]/[carnitine] ratios, but it decreased the [long-chain acylcarnitine]/[carnitine] ratio. Ciprofibrate and POCA increased the activities of acyl-CoA hydrolases, and carnitine acetyltransferase activity was increased 28-fold and 6-fold by ciprofibrate and POCA respectively. In cultures of hepatocytes, ciprofibrate caused similar changes in enzyme activity to those observed in vivo, although [carnitine] decreased with time. The results suggest that: (1) the reactions catalysed by the short-chain carnitine acyltransferases, but not by the carnitine palmitoyltransferases, are near equilibrium in liver both before and after modification of metabolism by administration of ciprofibrate or POCA; (2) the increase in hepatic [carnitine] after ciprofibrate or POCA feeding can be explained by redistribution of carnitine between tissues; (3) the activity of carnitine acetyltransferase and [total carnitine] in liver are closely related.     

Changes in coenzyme A and carnitine concentrations in superovulated rats

Changes in the concentrations of total coenzyme A, acetyl CoA, free carnitine and acetylcarnitine were measured in ovaries from immature rats before and after superovulation with 50 I.U. pregnant mare's serum gonadotropin. In addition, the concentrations of total CoA and total acid-soluble carnitine were measured in liver, adrenal glands and skeletal muscle from the same rats. Ovarian concentrations of total CoA, free carnitine and acetylcarnitine increased 3-fold on gonadotropin stimulation, whereas there was no marked change in total CoA and acid-soluble carnitine concentrations in the other organs. In ovary, the ratio of free CoA to acetyl CoA was about 2:1 during the growth period of follicular development and during active steroidogenesis in the luteal phase, but less than 1 when replication stopped and ovulation occurred. These results show that during periods of high energy demand the ovary has a good capacity to accommodate fatty acid oxidation, and supports the evidence that fatty acids are the major source of reducing equivalents for steroidogenesis at these times.     

Acetylcarnitine formation during intense muscular contraction in humans

To study the changes in carnitine during intense muscular effort subjects underwent 4 min intermittent electrical stimulation of the quadriceps femoris muscle and on a separate occasion performed 4 min exercise on a bicycle ergometer. Biopsies of the vastus lateralis muscle were taken at rest and after 2 and 4 min of stimulation or exercise. Resting mean muscle total carnitine content was 20.0 mmol/kg dry muscle. Approximately 77% was free carnitine and 19% acetylcarnitine. Four minutes of stimulation or intense exercise did not effect total carnitine but did result in a marked fall in free carnitine and almost equivalent rise in acetylcarnitine. The results indicate that acetylcarnitine is a major metabolite formed during intense muscular effort and that carnitine may function in the regulation of the acetyl-CoA/CoA ratio by buffering excess production of acetyl units.     

Hyperammonemia decreases body fat content in rat

We have developed an animal model of hyperammonemia consisting of feeding rats a diet containing 20% (w/w) ammonium acetate. Ingestion of this diet markedly affects carcass composition, with a 46% reduction in lipid content. The ammonium diet alters levels of several key compounds involved in lipid metabolism. Long-chain acylcarnitine is increased in liver by approx. 60% while free carnitine and acetylcarnitine are unaffected. The hepatic content of acetyl-CoA increases by approx. 50%. The level of ketone bodies in blood increases by 32% but remains unchanged in liver. Our data indicate that hyperammonemia alters lipid metabolism and results in a significant decrease in body lipid content.