Carnitine transport into muscular cells. Inhibition of transport and cell growth by mildronate

Carnitine is involved in the transfer of fatty acids across mitochondrial membranes. Carnitine is found in dairy and meat products, but is also biosynthesized from lysine and methionine via a process that, in rat, takes place essentially in the liver. After intestinal absorption or hepatic biosynthesis, carnitine is transferred to organs whose metabolism is dependent on fatty acid oxidation, such as heart and skeletal muscle. In skeletal muscle, carnitine concentration was found to be 50 times higher than in the plasma, implicating an active transport system for carnitine. In this study, we characterized this transport in isolated rat myotubes, established mouse C2C12 myoblastic cells, and rat myotube plasma membranes and found that it was Na(+)-dependent and partly inhibited by a Na(+)/K(+) ATPase inhibitor. L-carnitine analogues such as D-carnitine and gamma-butyrobetaine interfere with this system as does acyl carnitine. Among these inhibitors, the most potent was mildronate (3-(2,2,2-trimethylhydrazinium)propionate), known as a gamma-butyrobetaine hydroxylase inhibitor. It also induced a marked decrease in carnitine transport into muscle cells. Removal of carnitine or treatment with mildronate induced growth inhibition of cultured C2C12 myoblastic cells. These data suggest that myoblast growth and/or differentiation is dependent upon the presence of carnitine.     

Inhibition of long-chain acyl-CoA synthetase by the peroxisome proliferator perfluorodecanoic acid in rat hepatocytes

Perfluorodecanoic acid (PFDA) is a potent peroxisome proliferator and is known to affect hepatic lipid metabolism in rats. The effects of PFDA on fatty acid utilization were examined in isolated rat hepatocyte suspensions and in rat liver mitochondria and microsomes. PFDA inhibited the oxidation of palmitic acid but not octanoic or pyruvic acids when hepatocytes were incubated with 1 mM PFDA. At this PFDA concentration the esterification of palmitic acid into triacylglycerols was also reduced. The activity of long-chain acyl-CoA synthetase (ACS), an enzyme essential for both oxidation and esterification of fatty acids, was reduced in hepatocytes incubated with 1 mM PFDA. Carnitine palmitoyltransferase (CPT), an important enzyme for the oxidation of long-chain fatty acids, was not altered in hepatocytes incubated with this PFDA concentration. In rat liver mitochondria, palmitate oxidation and ACS activity were reduced significantly (P less than 0.01) at a PFDA concentration that had no effect on CPT activity. The inhibition of ACS by PFDA was similar in liver mitochondria and microsome preparations. In mitochondria incubated with PFDA, the inhibition of ACS appears to be noncompetitive for the substrates palmitic acid and CoA. However, the ACS inhibition by PFDA appeared to be competitive for the ATP binding site of the enzyme. Several chain length perfluorinated fatty acids were examined for their ability to inhibit mitochondrial ACS. Short-chain perfluorinated fatty acids (perfluoroproprionic and -butyric acid) did not inhibit ACS activity. However, medium-chain perfluorinated acids (perfluorooctanoic, -ananoic and -decanoic acid) were found to be potent inhibitors of ACS in isolated mitochondria. Whether ACS inhibition is causally related to PFDA-induced peroxisome proliferation and altered lipid metabolism seen in vivo is yet to be determined.     

The inhibition of long-chain fatty acyl-CoA synthetase by enoximone in rat heart mitochondria.

The mechanism by which enoximone, a reported phosphodiesterase inhibitor, inhibits the oxidation of long-chain fatty acids was studied in isolated rat heart mitochondria using a series of 14C-labeled substrates. Enoximone decreased palmitate oxidation in a time- and concentration-dependent manner. Fifty percent inhibition of palmitate oxidation was achieved with 250 microM of enoximone. In contrast to its effect on palmitate, enoximone (250 microM) increased octanoate oxidation by 30%, whereas pyruvate oxidation was unaffected by enoximone. At that dose there was no effect on the oxidation of palmitoyl-CoA and palmitoyl carnitine. The degree of palmitate oxidation inhibited by enoximone was parallel to the inhibition of acyl-CoA synthetase in both rat heart mitochondria and microsomes. These results suggest that enoximone is a reversible inhibitor of long-chain fatty acyl-CoA synthetase. Moreover, the reaction, which is catalyzed by this enzyme, is a rate-limiting step in the pathway of fatty acid oxidation in rat heart mitochondria.     

3-(2,2,2-Trimethylhydrazinium)propionate (THP)--a novel gamma-butyrobetaine hydroxylase inhibitor with cardioprotective properties

A protein fraction containing gamma-butyrobetaine hydroxylase (sp.act. 1.54 mU/mg) was isolated from the rat liver by differential precipitation with ammonium sulphate. 3-(2,2,2-Trimethylhydrazinium)propionate (THP), a noncompetitive enzyme inhibitor, when administered orally to rats for 10 days (150 mg/kg) elicited a reduction in myocardial free carnitine and long-chain acyl carnitine content by 63.7 and 74.3%, respectively. This reduction in free carnitine concentration causes a suppression of the free fatty acid oxidation, as measured by the production of 14CO2 and ketone bodies. The inhibition of fatty acid oxidation is particularly manifest when their metabolism is stimulated by feeding a fat-rich diet to the animals or in fasting rats. The inhibition of fatty acid metabolism at the stage of activation (acyl carnitine formation) can account for the cardioprotective effect of THP, which is assessed by its ability to prevent a decrease in ATP level and myocardial energy charge as well as to prevent a rise in creatine phosphokinase and lactic dehydrogenase (myocardium-specific isozyme) activity in rat blood serum in response to isoproterenol and epinephrine. Regulation of the carnitine-dependent fatty acid metabolism in ischaemia is a pathogenetically justified approach to pharmacological treatment of ischaemic myocardium. In its biochemical mechanism, THP significally distinguishes itself from other known inhibitors of fatty acid oxidation.     

Effect of methylglyoxal bis(guanylhydrazone) on hepatic, heart and skeletal muscle mitochondrial carnitine palmitoyltransferase and beta-oxidation of fatty acids

Methylglyoxal bis(guanylhydrazone) (MGBG) is an antileukemic agent and a structural polyamine analogue which inhibits S-adenosyl methionine decarboxylase. However, MGBG also produces profound mitochondrial structural damage and inhibition of fatty acid oxidation. Carnitine palmitoyltransferase-A (CPT-A) is located on the outer surface of the inner mitochondrial membrane and is the putative rate-controlling enzyme for mitochondrial long-chain fatty acid oxidation. The present experiments were designed to determine if MGBG inhibits CPT-A. Liver, heart and skeletal muscle mitochondria were isolated from rats following 24 hr of starvation. Measuring the reaction in the direction of palmitoylcarnitine plus CoA formation from palmitoyl-CoA plus carnitine ("forward reaction"), MGBG was competitive with l-carnitine. The MGBG CPT-A Ki values were (mM): liver, 5.0 +/- 0.6 (N = 15); heart 3.2 +/- 1.2 (N = 3); and skeletal muscle, 2.8 +/- 1.0 (N = 3). Lysis of hepatic mitochondria with Triton X-100 yielded a Ki of 4.0 +/- 2.0, which was not significantly different from intact mitochondria or inverted vesicles (4.9 mM). Purified hepatic CPT had a Ki of 4.2 mM. MGBG did not inhibit purified CPT in the "reverse reaction" (palmitoyl-CoA plus carnitine formation from palmitoylcarnitine plus CoA). Spermine and spermidine, which are structurally similar to MGBG, did not inhibit either CPT activity or acid-soluble product formation from 1-[14C]palmitoyl-CoA. MGBG inhibited mitochondrial state 3 oxidation rates of palmitoyl-CoA and palmitoylcarnitine, as well as of glutamate. However, the fatty acid substrates were considerably more sensitive than glutamate to MGBG inhibition. MGBG also increased hepatic mitochondrial aggregation which was reversed by l-carnitine. Fluorescence polarization, using 1,6-diphenyl-1,3,5-hexatriene (DPH) as a probe, indicated that MGBG increased membrane rigidity in a dose-dependent manner. This effect was not altered by l-carnitine. MGBG also inhibited purified pigeon breast carnitine acetyltransferase (CAT; Ki = 1.6 mM). While MGBG appeared to be competitive with l-carnitine for both CPT and CAT, MGBG also exhibits a number of effects which may be mediated through membrane interaction and which are not reversed by carnitine.     

Synthesis and activity of nonhydrolyzable pseudomonic acid analogues

Several series of pseudomonic acid analogues have been prepared that incorporate modified functionalities in place of the C1-C3 alpha,beta-unsaturated ester group. The inhibition of isoleucyl-tRNA synthetase and the in vitro activity of these compounds against various Gram-positive and Gram-negative strains are described. Several derivatives showed enzyme inhibition equivalent to or better than that of methyl pseudomonate (3), while lacking the hydrolyzable ester group at C1. These analogues include the corresponding phenyl ketone and the ether 12. The long-chain ketone 24 exhibited similar in vitro activity as the parent ester.     

Inhibition of mitochondrial carnitine palmitoyltransferases by adriamycin and adriamycin analogues

Adriamycin (ADR; doxorubicin) and its highly lipophilic, less toxic analogue N-benzyl-adriamycin-14-valerate (AD 198) were found to inhibit rat heart and liver carnitine palmitoyltransferases of both mitochondrial outer and inner membranes. The outer membrane enzyme was more sensitive to inhibition by these drugs than the inner membrane enzyme, and AD 198 was a more potent inhibitor of these enzymes than ADR. Other analogues of ADR, N-trifluoroacetyladriamycin-14-valerate (AD 32) and N-trifluoroacetyladriamycin-14-O-hemiadipate (AD 143), which are documented as being noncardiotoxic, were also more potent inhibitors of the mitochondrial carnitine palmitoyltransferases than ADR. Overall, the cardiac mitochondrial carnitine palmitoyltransferases seemed to be slightly more sensitive to the inhibitory effects of ADR and its analogues than the liver enzyme. ADR was an uncompetitive inhibitor with respect to palmitoyl-CoA and a noncompetitive inhibitor with respect to carnitine for both mitochondrial outer and inner membrane enzymes. Our data suggest that mitochondria can take up ADR and concentrate it within the matrix, as is known to happen with other positively-charged compounds. More ADR was found associated with the mitochondrial inner membrane than with the outer membrane; this could be due to the greater protein content of the inner membrane rather than drug binding to cardiolipin. Although inhibition of cardiac inner membrane carnitine palmitoyltransferase has been implicated previously as part of the cardiotoxicity mechanism of ADR, the present findings with ADR and its noncardiotoxic analogues do not support this view.     

Changes in hepatic lipid metabolism associated with lipid accumulation and its reversal in rats given the peroxisome proliferator LY171883

Dietary administration of 0.05, 0.1, and 0.3% LY171883 to rats for 1 day caused a dose-related increase in hepatic triglycerides. When added to rat liver mitochondria in vitro, LY171883 caused competitive inhibition of carnitine palmitoyltransferase 1 (CPT-1), the rate-limiting enzyme for mitochondrial fatty acid oxidation. This effect appears to be involved in the lipid accumulation. The hepatic triglycerides in rats given 0.1% LY171883 increased progressively through 3 months of treatment. In contrast, hepatic triglycerides in high-dose rats returned to control levels by Day 3 and remained there throughout the study. The regression of the lipid corresponded with increases in hepatic peroxisomal beta-oxidation, mitochondrial beta-oxidation, and CPT-1 activity of up to 13-, 7-, and 3.2-fold, respectively. The 0.1% dose increased these parameters modestly compared to those of high-dose rats (2-, 3-, and 1.6-fold, respectively). Addition of LY171883 to mitochondria from rats given dietary treatment for 2 weeks inhibited CPT-I by the same percentage as in control mitochondria. In mid-dose rats, the induction of CPT-I was largely negated by LY171883 in vitro. Even with the inhibition, CPT-I activity in mitochondria from high-dose rats remained 2-fold higher than that in untreated controls. The data suggest that the induction of CPT-I in high-dose rats was sufficient to overcome the inhibitory action of LY171883. The increased oxidative capacity in peroxisomes and mitochondria led to the regression of the lipid in high-dose rats. The more modest increases in fatty acid oxidation in rats given 0.1% LY171883 were not sufficient to reverse the lipid accumulation.     

Synthesis and structure-activity relationship of small-molecule malonyl coenzyme A decarboxylase inhibitors

The discovery and structure-activity relationship of first-generation small-molecule malonyl-CoA decarboxylase (MCD; CoA = coenzyme A) inhibitors are reported. We demonstrated that MCD inhibitors increased malonyl-CoA concentration in the isolated working rat hearts. Malonyl-CoA is a potent, endogenous, and allosteric inhibitor of carnitine palmitoyltransferase-I (CPT-I), a key enzyme for mitochondrial fatty acid oxidation. As a result of the increase in malonyl-CoA levels, fatty acid oxidation rates were decreased and the glucose oxidation rates were significantly increased. Demonstration of in vivo efficacy of methyl 5-(N-(4-(1,1,1,3,3,3-hexafluoro-2-hydroxypropan-2-yl)phenyl)morpholine-4-carboxamido)pentanoate (6u) in a pig ischemia model indicated that MCD inhibitors may be useful for treating ischemic heart diseases.     

Alkylthio acetic acids (3-thia fatty acids)--a new group of non-beta-oxidizable peroxisome-inducing fatty acid analogues--II. Dose-response studies on hepatic peroxisomal- and mitochondrial changes and long-chain fatty acid metabolizing enzymes in rats

The activity of key enzymes involved in oxidation and esterification of long-chain fatty acids was investigated after male Wistar rats were treated with different doses of sulfur substituted fatty acid analogues, 1,10-bis(carboxymethylthiodecane) (BCMTD, non-beta-oxidizable and non-omega-oxidizable), 1-mono(carboxymethylthiotetradecane) (CMTTD, trivial name, alkylthio acetic acid, non-beta-oxidizable) and 1-mono(carboxyethylthiotetradecane) (CETTD trivial name, alkylthio propionic acid, beta-oxidizable). The sulfur substituted dicarboxylic acid and the alkylthio acetic acid induced in a dose-dependent manner the mitochondrial, microsomal and especially the peroxisomal palmitoyl-CoA synthetase activity, the mitochondrial and cytosolic palmitoyl-CoA hydrolase activity, the mitochondrial and especially the microsomal glycerophosphate acyltransferase activity and the peroxisomal beta-oxidation, especially revealed in the microsomal fraction. Morphometric analysis of randomly selected hepatocytes revealed that BCMTD and CMTTD treatment increased the number, size and volume fraction of peroxisomes and mitochondria. Thus, the observed changes in the specific activity of fatty acid metabolizing enzymes with multiple subcellular localization can partly be explained as an effect of changes in the s-values of the organelles as proliferation of mitochondria and peroxisomes occurred. The most striking effect of the alkylthio propionic acid was the formation of numerous fat droplets in the liver cells and enhancement of the hepatic triglyceride level. This was in contrast to BCMTD treatment which decreased the hepatic triglyceride content. In conclusion, the results provide evidence that administration of non-beta-oxidizable fatty acid analogues had much higher in vivo potency in inducing hepatomegaly and key enzymes involved in fatty acid metabolism, including proliferation of peroxisomes and mitochondria than is exhibited in the beta-oxidizable, alkylthio propionic acid. Moreover, the dicarboxylic acid was apparently three to six times more potent than the alkylthio acetic acid in inducing peroxisomal beta-oxidation and peroxisome proliferation when considered on a mumol/day basis. As palmitic acid and hexadecanedioic acid only marginally affected these hepatic responses, it is conceivable that the potency of the selected compounds as proliferators of peroxisomes and inducers of the associated enzymes depends on their accessibility for beta-oxidation.     

Fatty acid oxidation in hepatic peroxisomes and mitochondria after treatment of rats with di(2-ethylhexyl)phthalate

Rats were fed a diet containing di(2-ethylhexyl)-phthalate, which increases the number of peroxisomes and mitochondria in the liver. This proliferation does not change the ratio of phospholipid to protein in mitochondria or microsomes, but causes certain changes in the fatty acid composition of the phospholipids. The highest rates of peroxisomal and mitochondrial beta-oxidation are obtained with 12:0 and 16:0 fatty acids as substrates, respectively. A 3-4 fold increase in the rate of beta-oxidation by both organelles is caused by DEHP treatment, but there are no qualitative changes in the relative rates of oxidation of individual fatty acids. Short- and medium-chain carnitine acyltransferases in peroxisomes, microsomes and mitochondria, as well as the mitochondrial long-chain carnitine acyltransferase are induced to various extents. These results indicate that the increased beta-oxidation of fatty acids caused by phthalate treatment involves the same peroxisomal and mitochondrial pathways which operate under normal conditions.     

Carnitine palmitoyl transferase-I inhibition is not associated with cardiac hypertrophy in rats fed a high-fat diet

1. Cardiac lipotoxicity is characterized by hypertrophy and contractile dysfunction and can be triggered by impaired mitochondrial fatty acid oxidation and lipid accumulation. The present study investigated the effect of dietary fatty acid intake alone and in combination with inhibition of mitochondrial fatty acid uptake with the carnitine palmitoyl transferase (CPT)-I inhibitor oxfenicine. Long-chain fatty acids activate peroxisome proliferator-activated receptors (PPAR), thus mRNA levels of PPAR target genes were measured. 2. Rats were untreated or given the CPT-I inhibitor oxfenicine (150 mg/kg per day) and were fed for 8 weeks with either: (i) standard low-fat chow (10% of energy from fat); (ii) a long-chain saturated fatty acid diet; (iii) a long-chain unsaturated fatty acid diet; or (iv) a medium-chain fatty acid diet (which bypasses CPT-I). High-fat diets contained 60% of energy from fat. 3. Cardiac triglyceride content was increased in the absence of oxfenicine in the saturated fat group compared with other diets. Oxfenicine treatment further increased cardiac triglyceride stores in the saturated fat group and caused a significant increase in the unsaturated fat group. Despite elevations in triglyceride stores, left ventricular mass, end diastolic volume and systolic function were unaffected. 4. The mRNA levels of PPAR-regulated genes were increased by the high saturated and unsaturated fat diets compared with standard chow or the medium chain fatty acid chow. Oxfenicine did not further upregulate PPARalpha target genes within each dietary treatment group. 5. Taken together, the data suggest that consuming a high-fat diet or inhibiting CPT-I do not result in cardiac hypertrophy or cardiac dysfunction in normal rats.     

Carnitine palmitoyltransferase: a viable target for the treatment of NIDDM?

Inhibition of fatty acid oxidation is well recognized as a potentially effective mechanism for controlling glycemia in non-insulin-dependent diabetes mellitus (NIDDM). However, a direct targeting of inhibition of the intramitochondrial beta-oxidation pathway or an indirect modulation of fatty acid oxidation by inhibition of substrate release from adipose stores has been fraught with lack of efficacy, unacceptable side-effects or both. Focus has therefore recently been directed towards the carnitine palmitoyltransferase (CPT) system, a three-component system necessary for the transfer of long-chain fatty acids into the intramitochondrial matrix. This article will briefly review the background for fatty acid oxidation inhibition in NIDDM and then focus on the progress in the biological understanding and drug discovery targeting of the CPT system for the treatment of NIDDM. Based upon the review, it is concluded that mechanism-based hepatic and myocardial toxicities in normal animals and a potential for a lack of human efficacy may pose insurmountable hurdles for the development of CPT inhibitors for the treatment of NIDDM.     

Short term treatment by fenofibrate enhances oxidative activities towards long-chain fatty acids in the liver of lean Zucker rats

Lean Zucker rats were dosed orally for 1 week with fenofibrate (100 mg/kg/day). Liver weights of treated rats, expressed as per cent of body weight, were increased, while protein, DNA and triacylglycerol contents were not changed to any great extent per gram of liver, but increased when expressed per whole liver. Compared with the control animals, activities of fatty acid oxidase, of the peroxisomal fatty acid-oxidizing system and of catalase were markedly enhanced by fenofibrate, both per gram of liver and per total liver, while urate oxidase activity was slightly depressed when expressed per gram of liver. The activity of cytochrome c oxidase used as a mitochondrial marker was only higher when expressed per total liver. Besides, fenofibrate treatment induced a pronounced increase in the mitochondrial activities of carnitine palmitoyl- and acetyltransferases, of palmitoyl-CoA dehydrogenase and of carnitine-dependent oleate oxidation. Fenofibrate also enhanced significantly the carnitine content in liver and hepatic mitochondria. Malonyl-CoA content per gram of liver was found to be twice as high as in control rats, while the sensitivity of carnitine acyltransferase I to malonyl-CoA inhibition was hardly altered. The drug enhanced the percentage of palmitic acid in lipids of liver, but not in adipose tissues. The present data show that fenofibrate induced greater oxidative activities towards fatty acids, even in the lean animal. This stimulation could be related to the energy used for building new cells. In turn, at the same time of treatment, an enhanced fatty acid synthesis would provide specific fatty acids for the formation of new membranes. This latter effect will eventually disappear and the maintenance of a higher fatty acid oxidation may explain part of the overall hypolipaemic effect of fenofibrate.     

Reversible inhibitors of the gastric (H+/K+)-ATPase. 1. 1-Aryl-4-methylpyrrolo[3,2-c]quinolines as conformationally restrained analogues of 4-(arylamino)quinolines

The 4-(arylamino)quinoline 4, previously described as an antiulcer compound, is shown to be an inhibitor of the gastric (H+/K+)-ATPase. It is postulated that 1-arylpyrrolo[3,2-c]quinolines 6 act as conformationally restrained analogues of 4. A series of derivatives of 6 has been prepared and shown to be potent inhibitors of the target enzyme in vitro. Substitution in the ortho position of the aryl ring is important for activity. Unsaturation in the 5-membered ring makes little difference, but introduction of heteroatoms into the same ring markedly reduces activity. In more detailed kinetic experiments, 15c and 4 both show reversible, K(+)-competitive binding to the enzyme, with submicromolar Ki values. The compounds appear to act at the lumenal face of the enzyme and to require protonation for activity. Several compounds in the series are shown to be potent inhibitors of pentagastrin-stimulated acid secretion in the rat.     

Dissociation between metabolic and efficiency effects of perhexiline in normoxic rat myocardium

The antianginal agent perhexiline inhibits rat cardiac carnitine palmitoyltransferase-1 (CPT-1) and CPT-2, key enzymes for mitochondrial transport of long-chain fatty acids. We tested the hypothesis that perhexiline, in therapeutic concentrations (2 microM), inhibits palmitate oxidation and enhances glucose oxidation in isolated rat cardiomyocytes and in the working rat heart, thereby increasing efficiency of oxygen utilization. In isolated cardiomyocytes, perhexiline (2 microM) exerted no acute effects on palmitate oxidation, but after 48 hours pre-exposure oxidation was inhibited by perhexiline (2 to 10 microM) by 15% to 35% (P < 0.0002). In non-ischemic working rat hearts (3%BSA, 0.4 mM palmitate, 11 mM glucose, 100 microU/mL insulin) perhexiline (2 microM) had no significant acute effect on cardiac efficiency, palmitate or glucose oxidation, but 24 hours pretreatment with transdermal perhexiline increased cardiac work (by 29%, P < 0.05) and cardiac efficiency (by 30%, P < 0.02) without significant effects on palmitate oxidation. The selective CPT-1 inhibitor oxfenicine (2 mM) inhibited palmitate oxidation and enhanced glucose oxidation, but failed to enhance cardiac efficiency. In conclusion, in the non-ischemic working rat heart, perhexiline increases myocardial efficiency by a mechanism(s) that is largely or entirely independent of its effects on CPT. Effects on cardiac efficiency during ischemia, and with changes in fatty acid oxidation after longer perhexiline pretreatment remain to be determined.     

Growth reduction in glioma cells after treatment with tetradecylthioacetic acid: changes in fatty acid metabolism and oxidative status

During aerobic metabolism, a small amount of partially reduced oxygen is produced, yielding reactive oxygen species (ROS). Peroxisomes and mitochondria are major contributors to cellular ROS production, which is normally balanced by consumption by antioxidants. The fatty acid analogue tetradecylthioacetic acid (TTA) promotes mitochondrial and peroxisomal proliferation, and may induce oxidative stress and change the growth potential of cancer cells. In the present study, we found that TTA reduced [(3)H]thymidine incorporation in the glioma cell lines BT4Cn (rat), D54Mg (human), and GaMg (human) in a dose- and time-dependent manner. The 50% inhibitory TTA doses were approximately 125 microM for BT4Cn and D54Mg cells and 40 microM for GaMg cells after 4 days. alpha-Tochopherol counteracted this inhibition in GaMg cells. TTA enhanced the oxidation of [1-(14)C]palmitic acid, which could be explained by stimulation of enzymes involved in peroxisomal (fatty acyl-CoA oxidase) and/or mitochondrial (carnitine palmitoyltransferase) fatty acid oxidation. The glutathione content and the activities of glutathione peroxidase, glutathione reductase, and glutathione S-transferase were differentially affected. Increased malondialdehyde (MDA) production was seen in TTA-treated GaMg and D54Mg cells, but not in BT4Cn cells, in vitro. In BT4Cn tumor tissue from TTA-treated rats, MDA was increased while the alpha-tocopherol content tended to decrease. TTA increased the level of cytosolic cytochrome c in BT4Cn cells, which suggests induction of apoptotic cascades. Although several mechanisms are likely to be involved in the TTA-mediated effects on growth, we propose that modulation of cellular redox conditions caused by changes in fatty acid metabolism may be of vital importance.     

The synthesis, and structure-activity relationships of some long chain acyl carnitine esters on the coronary circulation of the rat isolated heart.

The synthesis of the isopropyl ester of carnitine and a series of fatty acid derivatives with fatty acid lengths C8-C30 is described. Bolus doses of these compounds (0.03-300 nmol) showed coronary vasodilator activity in the rat isolated heart. Increasing fatty acid chain length from C8 to C16 resulted in an increased vasodilator potency. Longer lasting vasodilation was observed with the C20 compound. Increasing fatty acid chain length to C30 was associated with a small dilator response preceded by vasoconstriction.     

Hypocarnitinaemia induced by sodium pivalate in the rat is associated with left ventricular dysfunction and impaired energy metabolism

Carnitine is a naturally occurring compound that is essential in energy metabolism of the mammalian heart. In addition to its essential role in facilitating beta-oxidation, carnitine eliminates excess toxic acyl residues and regulates the mitochondrial acetyl coenzyme A (CoA)/CoA ratio. Thus, it is not surprising that patients with carnitine deficiency syndromes exhibit defects in energy metabolism and in some cases demonstrate left ventricular dysfunction. Pivalic acid is commonly used to create prodrugs, such as pivampicillin and pivmecillinam, to facilitate enteral absorption and increase oral bioavailability. Pivalic acid released from the drug following absorption readily forms an ester with carnitine, which is then excreted as pivaloylcarnitine. Sustained loss of carnitine in the form of this ester induces a state of carnitine deficiency, exemplified by low plasma and tissue carnitine content. This review examines the effects in the rat of short- and long-term sodium pivalate treatment on: (1) cardiac carnitine content; (2) in vitro mechanical function; (3) markers of glycolytic and fatty acid metabolism; and (4) energy substrate metabolism. Treatment with sodium pivalate induces a gradual loss of cardiac carnitine content for up to 12 weeks. Doubling the duration of treatment is not associated with any further decrease in cardiac carnitine content. While heart function following short-term treatment (2 weeks) is normal under aerobic conditions, impaired recovery of function following ischaemia is seen. In contrast, long-term treatment (11-28 weeks) is associated with impaired heart function, which is dependent on workload and substrate availability. Impaired heart function is also associated with reductions in activity of 3-hydroxyacyl CoA dehydrogenase and rates of fatty acid oxidation. However, to maintain adenosine triphosphate production, glucose metabolism, expressed as hexokinase activity and glucose oxidation, is increased in carnitine-deficient hearts. Hearts from sodium pivalate-treated animals demonstrate a cardiomyopathy that is dependent on duration of treatment, workload and substrate supply. This model of hypocarnitinaemia may thus be useful to study the metabolic and cardiac consequences of carnitine-deficiency syndromes.