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)

The main hormones involved in ketone-body metabolism are the anabolic hormone insulin and the primarily catabolic hormones, glucagon, cortisol, catecholamines and growth hormone. These hormones may regulate ketone-body metabolism at three sites: adipose tissue, by regulating fatty acid supply to the liver; the liver itself, by determining the relative activities of the re-esterification and fatty acid oxidation pathways; and the periphery, by influencing the rate of extrahepatic utilization of ketone bodies. The first two are quantitatively the most important. Insulin acts on all three regulatory sites. In adipose tissue lipolysis is inhibited and re-esterification enhanced with consequent decrease of fatty acid release. Both these processes are extremely insulin-sensitive. In the liver insulin increases fatty acid synthesis and esterification. At the same time malonyl-CoA formation is increased, which inhibits the acylcarnitine transferase system and thus decreases the transport of fatty acids into mitochondria and hence fatty acid oxidation and ketogenesis. Insulin also has a small stimulatory effect on extrahepatic ketone-body utilization. The effects of glucagon depend on whether insulin is present. In normal man glucagon stimulates insulin secretion and the predominant effect is that of insulin, i.e. decreased ketogenesis. In insulin deficiency glucagon has a mild stimulatory effect on lipolysis, increasing fatty acid supply to the liver. The main effects of glucagon are, however, on the liver. It activates the carnitine acyltransferase system through inhibition of malonyl-CoA synthesis. Fatty acid oxidation is increased and ketogenesis enhanced. The overall effect on the liver depends on the relative amounts of insulin and glucagon present. Studies with somatostatin show that glucagon can increase ketogenesis acutely when insulin secretion is inhibited in normal man, but the effects are short-lived. Cortisol has similar effects to glucagon. In the presence of insulin there is a small increase in fatty acid mobilization from adipose tissue, secondary to impaired glucose entry, and perhaps a small effect on lipolysis itself. This fatty acid is, however, directed to triacylglycerol in the liver. In insulin deficiency, again demonstrated by somatostatin infusion, the incoming fatty acidstone-body formation. The mechanism remains obscure. Catecholamines, in contrast, have their most potent effects on adipose tissue, stimulating lipolysis and fatty acid release even in the presence of insulin. They thus act mainly by enhancing precursor supply and have only minor effects on liver and no effect on peripheral utilization. Growth hormone, like glucagon, has little effect in the presence of insulin, but can enhance ketogenesis in insulin deficiency, although again the mechanism is unknown. Thus in normally fed man the effects of insulin will be overriding and little ketogenesis occurs because of limited fatty acid availability in the liver...
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PMID:Hormonal regulation of ketone-body metabolism in man. 74 14

The enhancement of long-chain fatty acid oxidation and ketogenesis in the perfused rat liver, whether induced acutely by treatment of fed animals with anti-insulin serum or glucagon, or over the longer term by starvation or the induction of alloxan diabetes, was found to ba accompanied by a proportional elevation in the tissue carnitine content. Moreover, when added to the medium perfusing livers from fed rats, carnitine stimulated ketogenesis from oleic acid. The findings suggest that the increased fatty acid flux through the carnitine acyltransferase (carnitine palmitoyl-transferase; palmitoyl-CoA:L-carnitine O-palmitoyltransferase; EC 2.3.1.21) reaction brought about by glucagon excess, with or without insulin deficiency, is mediated, at least in part, by elevation in the liver carnitine concentration.
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PMID:Role of carnitine in hepatic ketogenesis. 106 Jan 16

Hepatocytes respond to stimulation by glycogenolytic agonists acting via phosphoinositide (PI) breakdown through oscillations of the free cytosolic concentration of Ca2+ ([Ca2+]cyt.). Since the second-messenger repertoire of hepatocytes includes many other factors besides Ca2+, we investigated to what degree the regulation of [Ca2+]cyt. oscillations is integrated into these other signalling systems. [Ca2+]cyt. was recorded in single rat hepatocytes by using the Ca(2+)-indicator fura-2. Parallel stimulation with phenylephrine (an alpha 1-adrenergic agonist of PI breakdown) and glucagon resulted in a synergistic stimulation of [Ca2+]cyt. oscillations. Direct activation of the cyclic-AMP-dependent pathway with several stimuli (forskolin, 8-bromo cyclic AMP, 8-CPT cyclic AMP) mimicked the response to glucagon. In contrast, [Ca2+]cyt. oscillations induced by various combinations of these agonists could be antagonized by the glycogenic hormone insulin. As one of the options in the insulin-signalling network, we tested a diacylglycerol activator of protein kinase C, DiC8. It also acted as an inhibitor of [Ca2+]cyt. oscillations. We investigated how these observations could be reconciled with our previously introduced model of [Ca2+]cyt. oscillations in hepatocytes [Somogyi and Stucki (1991) J. Biol. Chem. 266, 11068-11077]. First of all, the effect of calmodulin inhibitors (calmidazolium and CGS 9343 B), acting at the core of our model on the feedback of Ca2+ on Ins(1,4,5)P3-induced Ca2+ release, was not altered by the new modulators. In addition, all agonists and antagonists could be used interchangeably in combination and introduced no significant change in the oscillatory pattern or spike shape. Since the response was solely limited to frequency modulation, over- or understimulation of the oscillatory system, there is no need to create a new oscillator or to introduce further reaction steps into the core of the model. We conclude that the regulation of [Ca2+]cyt. via the explored second-messenger pathways can be embedded into the oscillatory system as modulation of rate constants already present in this model.
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PMID:Modulation of cytosolic-[Ca2+] oscillations in hepatocytes results from cross-talk among second messengers. The synergism between the alpha 1-adrenergic response, glucagon and cyclic AMP, and their antagonism by insulin and diacylglycerol manifest themselves in the control of the cytosolic-[Ca2+] oscillations. 132 20

The regulation of acetyl-CoA carboxylase (ACC) by glucose and other fuel molecules has been examined in Fao Reuber hepatoma cells and Syrian hamster insulin tumor (HIT) cells in order to determine whether lipogenic substrates acutely alter ACC activity and to examine the mechanism of such regulation. In Fao cells, preincubated in simple medium without substrates, glucose addition results in a rapid activation of ACC. This effect, mimicked by other fuels such as lactate, is characterized by an increase in enzyme Vmax and a decrease in the activation constant for citrate. Several lines of evidence indicate that this activation of ACC is due to enzyme dephosphorylation, including the kinetic changes observed, the persistence of enzyme activation through ACC isolation, the necessity of inclusion of sodium fluoride/EDTA in the cell lysis buffer for preservation of the glucose-induced change, and the direct demonstration of diminished 32P-labeling of ACC after glucose exposure. Identical effects of glucose are also observed in HIT cells, although the ACC activation is smaller in magnitude and less sensitive than that observed in Fao cells. Other insulin secretagogues such as glutamine, lactate, and isobutylmethylxanthine are also found to activate HIT ACC. Others have suggested that glucose-induced changes in malonyl-CoA in beta-cells may be linked to glucose-induced insulin secretion. However, studies conducted in late passage HIT cells, which fail to secrete insulin in response to glucose stimulation, reveal the same glucose-induced activation seen in early passages, secretion-competent HIT cells, suggesting that glucose-induced ACC activation is not by itself sufficient to provoke insulin secretion. Taken together, these findings indicate that glucose and other fuel molecules can play a major role in the rapid regulation of the fatty acid synthesis pathway. The activation of fatty acid synthesis by substrate-induced ACC dephosphorylation insures ultimate fuel storage of glucose-derived carbon as fatty acid, while substrate-induced increases in the ACC product, malonyl CoA, would serve to simultaneously limit the rate of fatty acid oxidation through its allosteric regulation of carnitine palmitoyltransferase I.
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PMID:Glucose regulation of acetyl-CoA carboxylase in hepatoma and islet cells. 134 95

The interaction of gluconeogenesis and fatty acid oxidation in isolated sheep hepatocytes was studied. Addition of tetradecylglycidic acid, an inhibitor of carnitine palmitoyltransferase I (EC 2.3.1.21), to isolated hepatocytes inhibited gluconeogenesis from a mixture of pyruvate plus lactate and from propionate alone. Inhibition constants for tetradecylglycidic acid on gluconeogenesis were 4.77 +/- 1.00 microM and 7.25 +/- 1.52 microM, respectively, for pyruvate plus lactate and for propionate as gluconeogenic substrates. The inhibition constants were not different. At the highest substrate concentrations examined, gluconeogenesis from pyruvate plus lactate and from propionate in the presence of 10 microM tetradecylglycidic acid was 47.3 and 41.4% of their respective controls. Similar to previous observations with butyrate, caproate addition inhibited gluconeogenesis from propionate by isolated hepatocytes and was unable to prevent inhibition of gluconeogenesis induced by tetradecylglycidic acid. Carnitine palmitoyltransferase I activity was lower in mitochondria isolated from hepatocytes preincubated with insulin than in control hepatocytes. The data suggest 1) that maximum rates of gluconeogenesis in isolated sheep hepatocytes from either pyruvate plus lactate or from propionate as gluconeogenic substrates require beta-oxidation, 2) that intermediates common to the metabolism of butyrate and caproate may be involved in the inhibition of propionate conversion to glucose by isolated sheep hepatocytes, and 3) that carnitine palmitoyltransferase I activity in isolated sheep hepatocytes can be modulated by insulin treatment.
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PMID:Interactions between gluconeogenesis and fatty acid oxidation in isolated sheep hepatocytes. 140 66

To examine the signals regulating cardiac growth and molecular structure of subcellular organelles, cardiac hypertrophy was induced in rats by constriction of the abdominal aorta for 12-13 wk or by treatment with a carnitine palmitoyltransferase I inhibitor, etomoxir (12-15 mg/kg body wt) for 12-13 wk. In contrast to pressure overload, etomoxir redistributed the myosin isozyme population from V3 to V1 and increased the sarcoplasmic reticulum (SR) Ca(2+)-stimulated ATPase activity. When rats with pressure-overloaded hearts were treated with etomoxir, the cardiac hypertrophy was increased whereas the shift in myosin isozymes from V1 to V3 was prevented and the depression in SR Ca(2+)-stimulated ATPase activity was reversed. Plasma thyroid hormone and insulin concentrations were not altered but triglyceride concentrations were reduced in etomoxir-treated rats with pressure overload. The data demonstrate a dissociation between cardiac muscle growth and changes in subcellular organelles and indicate that a shift in myocardial substrate utilization may represent an important signal for molecular remodeling of the heart.
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PMID:Modification of subcellular organelles in pressure-overloaded heart by etomoxir, a carnitine palmitoyltransferase I inhibitor. 153 68

The development of long-chain fatty acid (LCFA) oxidation, either in the liver for ketone body and energy productions or in peripheral tissues as oxidative fuels, is essential for the newborn mammals. At least in the liver, the postnatal development of LCFA oxidation and ketogenesis seems regulated by pancreatic hormones which plasmatic concentrations are markedly changed at birth (fall in insulin and rise in glucagon levels). In cultured hepatocytes from rabbit fetuses (no LCFA oxidation), the addition of glucagon or cyclic AMP induces LCFA oxidation at a level similar to that found in 24-h-old newborns (high LCFA oxidation). The presence of insulin inhibits totally the effects of glucagon. It seems that carnitine palmitoyltransferase I (CPT I), a key enzyme of LCFA oxidation, represents the main site for hormonal control of LCFA oxidation. This regulation is not due to changes in the hepatic malonyl-CoA concentration (a metabolic intermediate in lipogenesis and a potent inhibitor of CPT I) but to modifications in the sensitivity of CPT I to malonyl-CoA inhibition. The molecular mechanisms responsible for the changes in the sensitivity of CPT I are discussed.
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PMID:Hormonal control of fatty acid oxidation during the neonatal period. 156 51

Circulating levels of insulin-like growth factor-binding protein-1 (IGFBP-1) and the abundance of hepatic IGFBP-1 mRNA are increased in streptozotocin-diabetic rats and are regulated in accordance with insulin and metabolic status. We recently purified rat IGFBP-1 from medium conditioned by well differentiated rat H4IIE hepatoma cells. Since this cell line provides a useful model for examining the effects of hormones on hepatocellular function, we used H4IIE cells to examine the relative role that insulin and other factors may play in the regulation of IGFBP-1 production. H4IIE cells were stabilized in serum-free medium, then treated with specific hormones. The availability of IGFBPs in conditioned medium was estimated by [125I]IGF-I binding assay, and specific BPs were assessed by Western ligand and immunoblot analyses. The abundance of IGFBP-1 mRNA was determined by Northern and slot blot analysis. Initial studies revealed that [125I]IGF-I-binding activity in conditioned medium was reduced after 24-h incubation with 100 nM insulin (52 +/- 4% of control; P less than 0.001). In contrast, binding activity was increased after only 4 h of incubation with 75 microM 8-(4-chlorophenylthio)cAMP (8-CPT-cAMP) or 1 microM dexamethasone (P less than 0.001 vs. control for each), but these effects were prevented by insulin. Ligand and immunoblotting demonstrated that insulin decreased the production of 32K and 34K forms of IGFBP-1, while both 8-CPT-cAMP and dexamethasone increased the production of IGFBP-1; again, insulin prevented the effects of 8-CPT-cAMP and dexamethasone. Of note, 1 microM rat GH, testosterone, progesterone, or 17 beta-estradiol had no effect on either IGF-binding activity or IGFBP-1 production. Northern and slot blot analyses revealed that 100 nM insulin profoundly lowered the abundance of IGFBP-1 mRNA in H4IIE cells (4 +/- 0.6% of control at 4 h; P less than 0.001), while IGFBP-1 mRNA was increased 2-fold during incubation with 75 microM 8-CPT-cAMP (P less than 0.001) and 9-fold with 1 microM dexamethasone (P less than 0.001). Once again, the effect of insulin was dominant; insulin both prevented and reversed the effects of maximally effective concentrations of 8-CPT-cAMP and dexamethasone. To determine whether this effect of insulin reflected altered generation or stability of IGFBP-1 mRNA, H4IIE cells were incubated with 2.5 micrograms/ml actinomycin-D with or without insulin, and mRNA was quantitated by Northern blot.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Multihormonal regulation of insulin-like growth factor-binding protein-1 in rat H4IIE hepatoma cells: the dominant role of insulin. 170 55

The mechanisms by which noradrenaline, lipolytic agents and long-chain fatty acids stimulate glucose transport were investigated in rat brown adipocytes. Glucose transport was evaluated with tracer D-[U-14C]glucose and cell respiration was measured polarographically. Noradrenaline increased basal oxygen consumption (8-10-fold) and glucose transport (4-5-fold) in a dose-dependent manner, with a maximal stimulation at 100 nM. The stimulatory effects of noradrenaline on respiration and glucose transport were selectively mimicked by dibutyryl cyclic AMP (DBcAMP), 3-isobutyl-1-methylxanthine, cholera toxin and physiological concentrations of palmitic acid. Cytochalasin B completely blocked the effects of these agents on glucose transport. The beta-adrenergic antagonist propranolol inhibited noradrenaline-induced glucose transport, but did not affect the action of DBcAMP, palmitic acid or cholera toxin on this process. The specific inhibitor of mitochondrial carnitine palmitoyltransferase, 2-tetradecylglycidic acid (McN 3802) (50 microM), inhibited the stimulatory effects of noradrenaline (100 nM) and palmitic acid (0.5 mM) on both glucose transport and mitochondrial respiration. Significantly, McN 3802 failed to affect insulin (1 nM) action under identical experimental conditions. These results demonstrate that (a) the stimulatory effects of noradrenaline on brown-adipocyte respiration and glucose transport can be dissociated from those induced by insulin, and (b) noradrenaline increases glucose transport indirectly, by activating adenylate cyclase via beta-adrenergic pathways and by stimulating mitochondrial oxidation of fatty acids.
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PMID:Noradrenaline stimulates glucose transport in rat brown adipocytes by activating thermogenesis. Evidence that fatty acid activation of mitochondrial respiration enhances glucose transport. 171 31

Epidemiological studies have clearly shown that the so-called metabolic syndrome which is linked to insulin resistance and a reduced glucose utilization of muscle represents an important risk factor for cardiovascular disease. However, only little is known of the intracellular consequences of insulin resistance. An important feature of an altered substrate utilization is related to signal transduction of gene expression. For the example of myosin heavy chain expression, it is shown that metabolic signals exist which reflect the fuel flux and substrate utilization of the heart muscle cell. The signals were characterized in functional states of the heart associated with altered metabolic influences (fasting, diabetes, sucrose feeding, increased calorie intake, carnitine palmitoyltransferase inhibition). In the pressure-overloaded heart, metabolic interventions which are expected to increase glucose utilization (sucrose feeding, captopril treatment) have a pronounced effect. Although a link with gene expression remains to be established, it should be noted that the sarcoplasmic reticulum Ca(2+)-pump activity seems to be affected in a functionally comparable manner. It is concluded that metabolic signals alter the protein phenotype of heart muscle and it is expected that a deranged signal transduction affects, not only the heart, but also vascular muscle.
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PMID:The metabolic syndrome and signal transduction of gene expression. 183 54


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