Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.3.1.21 (CPT)
 4,580 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. A permeabilized isolated rat liver cell preparation was developed to achieve selective permeabilization of the cell membrane to metabolites and to allow the assay of mitochondrial overt carnitine palmitoyltransferase (CPT I) activity in situ. By performing the digitonin-induced permeabilization in the presence of fluoride and bivalent-metal-cation sequestrants, it was possible to demonstrate that the activity of other enzymes, which are regulated by reversible phosphorylation, was preserved during the procedure and subsequent washing of cells before assay. 2. CPT activity at a sub-optimal palmitoyl-CoA concentration was almost totally (approximately 90%) inhibited by malonyl-CoA, indicating that mitochondrial CPT I was largely measured in this preparation. 3. The palmitoyl-CoA-saturation and malonyl-CoA-inhibition curves for CPT activity in permeabilized cells were very similar to those obtained previously for the enzyme in isolated liver mitochondria. Moreover, starvation and diabetes had the same effects on enzyme activity, affinity for palmitoyl-CoA and malonyl-CoA sensitivity of CPT I in isolated cells as found in isolated mitochondria. These physiologically induced changes persisted through the cell preparation and incubation period. 4. Neither incubation of cells with glucagon or insulin nor incubation with pyruvate and lactate before permeabilization resulted in alterations of these parameters of CPT I in isolated cells. 5. The results are discussed in relation to the temporal relationships of changes in the activity and properties of CPT I in vivo in relation to the effects of insulin and glucagon on fatty acid metabolism in vivo.
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PMID:Use of a selectively permeabilized isolated rat hepatocyte preparation to study changes in the properties of overt carnitine palmitoyltransferase activity in situ. 328 53

An assay procedure for carnitine palmitoyltransferase is described which allows rapid measurement of the overt activity of this enzyme in isolated rat hepatocytes. In a one-step procedure digitonin permeabilizes the plasma membrane and at the same time carnitine palmitoyltransferase activity is measured. The use of the present procedure shows that carnitine palmitoyltransferase activity is regulated on the short term by different types of agonists. Thus, insulin, epidermal growth factor, vasopressin and the phorbol ester PMA inhibit carnitine palmitoyltransferase activity, whereas glucagon treatment renders the enzyme more active. These changes in enzyme activity coincide with corresponding changes in the rate of fatty acid oxidation.
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PMID:Short-term regulation of carnitine palmitoyltransferase activity in isolated rat hepatocytes. 334 11

The specific carnitine palmitoyltransferase I (CPT I)-inhibitor POCA - sodium-2(5-(4-chlorphenyl)pentyl-oxirane carboxylate - was used in isolated perfused hearts of acutely diabetic, ketotic (AD, 100 mg streptozotocin/kg body weight), chronically diabetic (CD, 60 mg streptozotocin/kg body weight), and obese ZUCKER rats (fa/fa) to study different forms of insulin resistance. In hearts of AD rats an absolute insulin resistance was observed which could be attenuated by perfusion of the hearts with POCA (10 microM). The insulin sensitivity could be fully restored and was not any longer significantly different from control hearts. In hearts of CD rats, which show a relative insulin resistance, POCA only slightly stimulated glucose oxidation and uptake, but the total rate of uptake and conversion of glucose as well as the responsiveness of these hearts to insulin remained low. In hearts of obese ZUCKER rats, the rate of glucose oxidation was accelerated to control levels by perfusion with POCA, however, the rate of glycolysis and glucose uptake remained reduced as compared to controls. Thus, POCA shifted the glucose metabolism by stimulating oxidation without normalizing the reduced glucose uptake. It follows that in hearts of AD rats the insulin resistance is due to the accelerated lipid metabolism described and is, therefore, fully reversible if the oxidation of fatty acids is inhibited. In hearts of ZUCKER rats a form of insulin resistance mediated by lipid metabolism seems to be responsible for the reduced glucose oxidation and the lowered rate of glycolysis. The insulin resistance can be eliminated and has to be distinguished from a defect in the glucose uptake system not affected by POCA. In hearts of CD rats insulin resistance is not dependent on disturbances in lipid metabolism and is practically not influenced by POCA. Thus, a CPI I-inhibitor might be useful to differentiate various forms of insulin resistance and therapeutically beneficial in forms mediated by lipid metabolic defects.
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PMID:Influence of the carnitine palmitoyltransferase inhibitor POCA on myocardial performance and metabolism of insulin resistant rats. 338 70

The metabolic actions of porcine insulin and biosynthetic human proinsulin on fatty acid and glucose metabolism were studied in rat hepatocytes cultured in monolayer for 24 h. Our aim was to establish whether proinsulin action in the liver is similar to insulin action and whether the relative potencies of the two hormones are the same for different metabolic processes. Proinsulin and insulin exerted a similar maximal inhibitory effect on ketone body formation from palmitate and on gluconeogenesis from pyruvate. The half-maximal effective concentration of proinsulin was 11-13 times that of insulin. The antiketogenic effects of insulin and proinsulin were associated with an increased glycerol 3-phosphate content and a decreased affinity of carnitine palmitoyltransferase for its substrate palmitoyl-CoA. When the basal rate of ketogenesis was increased with isobutyl methylxanthine, the half-maximal effective concentrations of both proinsulin and insulin were decreased, but the relative potency of the two hormones was unchanged. Proinsulin and insulin exerted similar maximal stimulatory effects on glycogen synthesis and on the activities of pyruvate kinase, glucose 6-phosphate dehydrogenase, phosphogluconate dehydrogenase, and malic enzyme. The half-maximal effective concentration of proinsulin was 10-30 times that of insulin. These findings are consistent with receptor binding studies on liver membranes that suggest that proinsulin interacts with insulin-specific and not proinsulin-specific receptors. Our findings also suggest that proinsulin action does not differ from insulin action at a postreceptor site.
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PMID:Regulation of ketogenesis, gluconeogenesis, and glycogen synthesis by insulin and proinsulin in rat hepatocyte monolayer cultures. 353 Aug 57

The influence of a non-ketonic, chronically diabetic state (60 mg/kg streptozotocin) on cardiac function and metabolism was studied under in vivo conditions by inserting a Millar-tip catheter into the left ventricle and in the model of the isolated perfused heart. In vivo heart rate and maximal left ventricular systolic pressure were reduced after a diabetes duration of 4 and 12 weeks. The maximal rise and fall in left ventricular pressure progressively declined with the duration of diabetes. The reduced myocardial function was associated with a loss in ATP and adenine nucleotides. In the perfused heart of chronically diabetic rats, heart function was also impaired and could not be restored in vitro by perfusion with glucose and insulin. In the presence of octanoate--a substrate which can be metabolized independently from insulin--heart function of diabetic rats was improved, but remained lowered as compared to controls. Since the content of myocardial creatine phosphate was reduced in diabetic hearts perfused with octanoate, these findings indicate that the suppression of cardiac performance is not only a result of an impaired glucose metabolism, but of a more general defect in energy provision and utilization. In contrast to hearts of acutely diabetic, ketotic rats most often used, the rate of lipolysis of endogenous triglycerides and the contribution of fatty acids to energy production was low in the chronically diabetic state. Inhibition of fatty acid oxidation by an inhibitor of carnitine palmitoyltransferase (CPTI) did not restore the reduced responsiveness of diabetic hearts to insulin. Analysis of intracardiac metabolites revealed that in the perfused heart of chronically diabetic rats glucose-6-phosphate and citrate do not accumulate as in hearts of ketotic, diabetic rats. Therefore, the impaired glucose metabolism presumably reflects a reduced uptake of glucose rather than in inhibition of glycolysis as in hearts of ketotic, diabetic rats.
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PMID:Myocardial performance and metabolism in non-ketotic, diabetic rat hearts: myocardial function and metabolism in vivo and in the isolated perfused heart under the influence of insulin and octanoate. 354 78

The effects of the glucocorticoid dexamethasone on fatty acid and pyruvate metabolism were studied in rat hepatocyte cultures. Parenchymal hepatocytes were cultured for 24 h with nanomolar concentrations of dexamethasone in either the absence or the presence of insulin (10 nM) or dibutyryl cyclic AMP (1 microM BcAMP). Dexamethasone (1-100 nM) increased the rate of formation of ketone bodies from 0.5 mM-palmitate in both the absence and the presence of BcAMP, but inhibited ketogenesis in the presence of insulin. Dexamethasone increased the proportion of the palmitate metabolized that was partitioned towards oxidation to ketone bodies, and decreased the cellular [glycerol 3-phosphate]. The latter suggests that the increased partitioning of palmitate to ketone bodies may be associated with decreased esterification to glycerolipid. The Vmax. of carnitine palmitoyltransferase (CPT) and the affinity of CPT for palmitoyl-CoA were not affected by dexamethasone, indicating that the increased ketogenesis was not due to an increase in enzymic capacity for long-chain acylcarnitine formation. Dexamethasone and BcAMP, separately and in combination, increased gluconeogenesis. In the presence of insulin, however, dexamethasone inhibited gluconeogenesis. Changes in gluconeogenesis thus paralleled changes in ketogenesis. Dexamethasone decreased the [3-hydroxybutyrate]/[acetoacetate] ratio, despite increasing the rate of ketogenesis and presumably the mitochondrial production of reducing equivalents. The more oxidized mitochondrial NADH/NAD+ redox couple with dexamethasone is probably due either to an increased rate of electron transport or to increased transfer of mitochondrial reducing equivalents to the cytoplasm.
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PMID:Regulation of ketogenesis, gluconeogenesis and the mitochondrial redox state by dexamethasone in hepatocyte monolayer cultures. 382 16

The effects of streptozotocin-induced diabetes and the subsequent treatment of diabetic animals with insulin were studied using a dose of streptozotocin that produces highly ketotic animals 48 h after injection. Carnitine palmitoyltransferase of diabetic animals had apparent Ki values for malonyl-CoA that were approximately 10 times greater than control animals, indicating a greatly decreased affinity for malonyl-CoA in the diabetic state. Subsequent treatment of diabetic animals with insulin for 5 days produced non-ketotic animals with normal blood glucose, and the affinity of carnitine palmitoyltransferase for malonyl-CoA was increased to the control level. Treatment of other groups of ketotic diabetic animals with insulin produced substantial changes in the carnitine palmitoyltransferase apparent Ki value for malonyl-CoA within 4 h. These results suggest that insulin modulates the ketotic state, at least in part, by increasing the affinity of carnitine palmitoyltransferase for malonyl-CoA to bring about inhibition of fatty acid oxidation and ketogenesis.
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PMID:Alteration of the apparent Ki of carnitine palmitoyltransferase for malonyl-CoA by the diabetic state and reversal by insulin. 389 56

The characteristics of inhibition of carnitine palmitoyltransferase (CPT) I by malonyl-CoA were studied for the enzyme in mitochondria isolated from sheep liver, a tissue with a very low rate of fatty acid synthesis. Malonyl-CoA was as potent in inhibiting the sheep liver enzyme as in inhibiting the enzyme in rat liver mitochondria. CPT I in guinea-pig liver mitochondria was also similarly inhibited. The inhibition showed the same time-dependent characteristics previously established for the rat liver enzyme. Methylmalonyl-CoA was as effective an inhibitor of CPT I as malonyl-CoA in sheep liver mitochondria, but did not affect CPT I activity in mitochondria from rat or guinea-pig liver. The concentrations of malonyl-CoA required to inhibit CPT I in sheep liver mitochondria in vitro were similar to those found in freeze-clamped sheep liver samples (about 7 nmol of malonyl-CoA/g wet wt.). In sheep liver cells the content of malonyl-CoA was only one-tenth of that observed in vivo when glucose only was added to the incubation medium. Inclusion of acetate and/or insulin increased the malonyl-CoA content about 10-fold, to values similar to those observed in vivo. The rate of fatty acid synthesis in sheep liver cells was about 1% of that observed in rat liver, but was correlated with the concentrations of malonyl-CoA in the cells under various incubation conditions. These observations are discussed in relation to (i) the regulatory role of malonyl-CoA in tissues that have a low capacity for fatty acid synthesis, and (ii) the utilization by sheep liver of propionate as a gluconeogenic precursor.
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PMID:Regulation of carnitine palmitoyltransferase activity by malonyl-CoA in mitochondria from sheep liver, a tissue with a low capacity for fatty acid synthesis. 408 27

The effect of (+)-decanoylcarnitine, a potent inhibitor of long-chain acylcarnitine transferase, was tested for its ability to inhibit hepatic ketogenesis both in the isolated perfused liver and in vivo in severely ketotic alloxan diabetic rats. In vitro the inhibitor caused an almost complete block in ketone body production. In vivo (+)-decanoylcarnitine caused a rapid reversal of ketosis under conditions where large doses of insulin had little effect. A combination of the two agents produced an even more striking fall in plasma ketone levels.While (+)-decanoylcarnitine alone had no effect on plasma glucose levels it enhanced the hypoglycemic effect of insulin in anesthetized animals. Loss of this effect was noted in nonanesthetized animals, possibly as a result of increased muscle activity. Studies in the isolated perfused liver indicated that the blockade of fatty acid oxidation and ketogenesis produced by (+)-decanoylcarnitine was rapidly reversible upon removal of the inhibitor.
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PMID:Acute reversal of experimental diabetic ketoacidosis in the rat with (+)-decanoylcarnitine. 463 91

Ketone bodies accumulate in the plasma in conditions of fasting and uncontrolled diabetes. The initiating event is a change in the molar ratio of glucagon:insulin. Insulin deficiency triggers the lipolytic process in adipose tissue with the result that free fatty acids pass into the plasma for uptake by liver and other tissues. Glucagon appears to be the primary hormone involved in the induction of fatty acid oxidation and ketogenesis in the liver. It acts by acutely dropping hepatic malonyl-CoA concentrations as a consequence of inhibitory effects exerted in the glycolytic pathway and on acetyl-CoA carboxylase (EC 6.4.1.2). The fall in malonyl-CoA concentration activates carnitine acyltransferase I (EC 2.3.1.21) such that long-chain fatty acids can be transported through the inner mitochondrial membrane to the enzymes of fatty acid oxidation and ketogenesis. The latter are high-capacity systems assuring that fatty acids entering the mitochondria are rapidly oxidized to ketone bodies. Thus, the rate-controlling step for ketogenesis is carnitine acyltransferase I. Administration of food after a fast, or of insulin to the diabetic subject, reduces plasma free fatty acid concentrations, increases the liver concentration of malonyl-CoA, inhibits carnitine acyltransferase I and reverses the ketogenic process.
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PMID:The regulation of ketogenesis. 612 45


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