Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Conditions for the isolation of rat hepatocytes that are responsive to insulin with regard to fatty acid synthesis were explored. Cells prepared according to the procedure of Ingebretsen and Wagle require the presence of fetal calf serum for insulin expression. Cells isolated by the Seglen method are the preparation of choice, since they respond to insulin in a simple, well-defined medium and, moreover, show much higher basal rates of fatty acid synthesis. In the latter cells isolated from fed male rats, the rate of fatty acid synthesis, as determined by tritium incorporation from [3H]H2O at 37 degrees C, is enhanced within 30 min after addition of insulin to the incubation medium; with glucagon, it is depressed. In the presence of insulin, the cellular content of malonyl coenzyme A is noticeably increased, whereas the concentrations of pyruvate, lactate, and citrate are not markedly affected. Glucagon, on the other hand, decreases the concentrations of all four intermediates. The activity of acetyl-CoA carboxylase is stimulated and depressed after addition of insulin and glucagon, respectively. In all conditions tested, the activity of acetyl-CoA carboxylase correlates with the rate of fatty acid synthesis, which in turn correlates with the cellular level of malonyl-CoA.
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PMID:Opposite effects of insulin and glucagon in acute hormonal control of hepatic lipogenesis. 46 8

We have measured rates of ketogenesis and malonyl-CoA contents of hepatocytes isolated from meal-fed rats under a variety of incubation conditions in order to determine the relationship between the intracellular malonyl-CoA level and the rate of ketogenesis. Evidence obtained from rat liver homogenates suggested that malonyl-CoA, which is a major determinant of fatty acid synthesis in vivo, also inhibits carnitine acyltransferase I (EC 2.3.1.21) and thereby decreases the rate of ketogenesis (McGarry, J.D., Mannaerts, G.P., and Foster, D.W. (1977) J. Clin. Invest. 60, 265-270). In hepatocytes from meal-fed rats, malonyl-CoA could be increased by glucose or lactate plus pyruvate and decreased by glucagon, oleic acid and the fatty acid synthesis inhibitor 5-(tetradecyloxy)-2-furoic acid. Malonyl-CoA varied from 14.8 +/- 1.2 to 1.4 +/- 0.1 nmol/g wet weight of cells. Rates of ketone body production varied from 0.10 +/- 0.01 to 0.96 +/- 0.06 mumol/min/g wet weight of cells and varied inversely with the malonyl-CoA content. Dixon plots and Cornish-Bowden plots of data suggest that malonyl-CoA is a competitive inhibitor of ketogenesis with a Ki of 2 nmol/g wet weight of cells. We conclude that in hepatocytes from meal-fed rats the cellular content of malonyl-CoA and the concentration of long chain fatty acid available to the cells are major determinants of the rate of ketogenesis.
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PMID:Ketogenesis and malonyl coenzyme A content of isolated rat hepatocytes. 63 84

Fatty acid synthesis and fatty acid oxidation were examined in rat hepatocytes under a variety of experimental conditions. In cells from fed animals, glucagon acutely switched the direction of fatty acid metabolism from synthesis to oxidation. Addition of lactate plus pyruvate had the opposite effect. The inhibitory action of glucagon on fatty acid synthesis and its stimulatory effect on fatty acid oxidation were largely, but not completely, offset by the simultaneous addition of lactate plus pyruvate. Changes in cellular citrate and malonyl-CoA levels indicated that glucagon exerted its inhibitory effect on fatty acid synthesis at two levels: (i) blockade of glycolysis; and (ii) partial inhibition of a more distal step, probably acetyl-CoA carboxylase. Under all conditions, fatty acid oxidation was related in a linear and reciprocal fashion to the rate of fatty acid synthesis and the tissue malonyl-CoA content. The latter fluctuated through a range of 1 to 6 nmol per g wet weight of cells. Since malonyl-CoA inhibits carnitine acyltransferase I of liver mitochondria with a Ki in the region of 1 to 2 micron, the present studies support the concept that this compound plays a pivotal role in the coordination of hepatic fatty acid synthesis and oxidation. The ketogenic effect of glucagon on liver appears to be manifested in large part through the ability of the hormone to reduce the tissue malonyl-CoA concentration.
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PMID:The role of malonyl-coa in the coordination of fatty acid synthesis and oxidation in isolated rat hepatocytes. 71 53

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 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

The effect of insulin on the properties of liver carnitine palmitoyltransferase I (CPT I) was assessed in conscious starved rats with the euglycemic hyperinsulinemic clamp. A 24-hour clamp was necessary to fully reverse the effect of starvation on liver malonyl-CoA concentration, CPT I maximal activity, and apparent km and Ki for malonyl-CoA. Since glucagon was not decreased during the clamp, insulin is the major factor involved in the regulation of CPT I.
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PMID:Effect of insulin on the properties of liver carnitine palmitoyltransferase in the starved rat: assessment by the euglycemic hyperinsulinemic clamp. 186 36

Previous work in this laboratory has shown that muscle malonyl-CoA, the inhibitor of carnitine palmitoyltransferase I (CPT I), decreased during exercise. Hepatic malonyl-CoA content decreases when glucose availability decreases such as during fasting or when the glucagon-to-insulin ratio increases such as during prolonged exercise or in response to insulin deficiency. To investigate the effect of glucose infusion on muscle malonyl-CoA during exercise, male rats were anesthetized (pentobarbital via venous catheters) at rest or after running (21 m/min, 15% grade) for 30 or 60 min. During exercise rats were infused with either glucose (0.625 g/ml) or saline at a rate of 1.5 ml/h. Gastrocnemius muscles and liver samples were frozen at liquid nitrogen temperature. Muscle malonyl-CoA decreased from 1.24 +/- 0.06 to 0.69 +/- 0.05 nmol/g with glucose infusion and to 0.43 +/- 0.04 nmol/g with saline infusion during 60 min of exercise. In the liver, glucose infusion prevented the drop in malonyl-CoA. This indicates that glucose infusion attenuates the progressive decline in muscle malonyl-CoA and prevents the decline in liver malonyl-CoA during prolonged exercise.
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PMID:Effect of glucose infusion on muscle malonyl-CoA during exercise. 205 26

The temporal changes in oleate oxidation, lipogenesis, malonyl-CoA concentration and sensitivity of carnitine palmitoyltransferase I (CPT 1) to malonyl-CoA inhibition were studied in isolated rabbit hepatocytes and mitochondria as a function of time after birth of the animal or time in culture after exposure to glucagon, cyclic AMP or insulin. (1) Oleate oxidation was very low during the first 6 h after birth, whereas lipogenesis rate and malonyl-CoA concentration decreased rapidly during this period to reach levels as low as those found in 24-h-old newborns that show active oleate oxidation. (2) The changes in the activity of CPT I and the IC50 (concn. causing 50% inhibition) for malonyl-CoA paralleled those of oleate oxidation. (3) In cultured fetal hepatocytes, the addition of glucagon or cyclic AMP reproduced the changes that occur spontaneously after birth. A 12 h exposure to glucagon or cyclic AMP was sufficient to inhibit lipogenesis totally and to cause a decrease in malonyl-CoA concentration, but a 24 h exposure was required to induce oleate oxidation. (4) The induction of oleate oxidation by glucagon or cyclic AMP is triggered by the fall in the malonyl-CoA sensitivity of CPT I. (5) In cultured hepatocytes from 24 h-old newborns, the addition of insulin inhibits no more than 30% of the high oleate oxidation, whereas it stimulates lipogenesis and increases malonyl-CoA concentration by 4-fold more than in fetal cells (no oleate oxidation). This poor effect of insulin on oleate oxidation seems to be due to the inability of the hormone to increase the sensitivity of CPT I sufficiently. Altogether, these results suggest that the malonyl-CoA sensitivity of CPT I is the major site of regulation during the induction of fatty acid oxidation in the fetal rabbit liver.
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PMID:Evidence that the sensitivity of carnitine palmitoyltransferase I to inhibition by malonyl-CoA is an important site of regulation of hepatic fatty acid oxidation in the fetal and newborn rabbit. Perinatal development and effects of pancreatic hormones in cultured rabbit hepatocytes. 216 69

Birth represents a dramatic change of nutrition from a fetal diet rich in carbohydrates and poor in fat to a neonatal diet rich in fat and poor in carbohydrates. Gluconeogenesis and ketogenesis are absent or very low in the fetal liver when the mother is correctly fed, and these metabolic pathways emerge after birth to reach adult values after 24 h. Gluconeogenesis increases rapidly in the liver of the newborn in parallel with the appearance of phosphoenolpyruvate carboxykinase (PEPCK), the rate-limiting enzyme of this metabolic pathway. The rise in plasma glucagon, the fall in plasma insulin and the resulting increase in liver cAMP which occur immediately after birth are the factors which induce the activation of liver PEPCK gene transcription. The appearance of ketogenesis is also controlled by the changes of plasma insulin and glucagon that increase the capacity for liver fatty acid oxidation by decreasing lipogenesis and malonyl-CoA concentration, by reducing the sensitivity of carnitine palmitoyl-CoA I to the inhibitory influence of malonyl-CoA, and by activating hydroxymethylglutaryl-CoA synthase by desuccinylation. Once liver PEPCK has reached adult value, i.e. 12 h after birth, other factors are involved in the regulation of hepatic gluconeogenesis. Indeed, the supply of gluconeogenic substrates and of free fatty acid is of crucial importance to support a high rate of gluconeogenesis and to maintain normoglycemia in the newborn. In the liver, fatty acid oxidation provides essential co-factors (acetyl-CoA, NADH and ATP) to support gluconeogenesis, and in peripheral tissue fatty acid oxidation inhibits glucose oxidation and stimulates the production of gluconeogenic precursors (lactate, pyruvate and alanine). Similar mechanisms are operative in human newborn. A defective hepatic fatty acid oxidation is likely to explain the frequent hypoglycemia observed in small-for-date neonates. Administration of oral triglycerides is an efficient mean to prevent hypoglycemia in these newborns.
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PMID:Metabolic adaptations to change of nutrition at birth. 226 17

The effects of pancreatic hormones and cyclic AMP on the induction of ketogenesis and long-chain fatty acid oxidation were studied in primary cultures of hepatocytes from fetal and newborn rabbits. Hepatocytes were cultivated during 4 days in the presence of glucagon (10(-6) M), forskolin (2 x 10(-5) M), dibutyryl cyclic AMP (10(-4) M), 8-bromo cyclic AMP (10(-4) M) or insulin (10(-7) M). Ketogenesis and fatty acid metabolism were measured using [1-14C]oleate (0.5 mM). In hepatocytes from fetuses at term, the rate of ketogenesis remained very low during the 4 days of culture. In hepatocytes from 24-h-old newborn, the rate of ketogenesis was high during the first 48 h of culture and then rapidly decreased to reach a low value similar to that measured in cultured hepatocytes from term fetuses. A 48 h exposure to glucagon, forskolin or cyclic AMP derivatives is necessary to induce ketone body production in cultured fetal hepatocytes at a rate similar to that found in cultured hepatocytes from newborn rabbits. In fetal liver cells, the induction of ketogenesis by glucagon or cyclic AMP results from changes in the partitioning of long-chain fatty acid from esterification towards oxidation. Indeed, glucagon, forskolin and cyclic AMP enhance oleate oxidation (basal, 12.7 +/- 1.6; glucagon, 50.0 +/- 5.5; forskolin, 70.6 +/- 5.4; cyclic AMP, 77.5 +/- 3.4% of oleate metabolized) at the expense of oleate esterification. In cultured fetal hepatocytes, the rate of fatty acid oxidation in the presence of cyclic AMP is similar to the rate of oleate oxidation present at the time of plating (85.1 +/- 2.6% of oleate metabolized) in newborn rabbit hepatocytes. In hepatocytes from term fetuses, the presence of insulin antagonizes in a dose-dependent fashion the glucagon-induced oleate oxidation. Neither glucagon nor cyclic AMP affect the activity of carnitine palmitoyltransferase I (CPT I). The malonyl-CoA concentration inducing 50% inhibition of CPT I (IC50) is 14-fold higher in mitochondria isolated from cultured newborn hepatocytes (0.95 microM) compared with fetal hepatocytes (0.07 microM), indicating that the sensitivity of CPT I decreases markedly in the first 24 h after birth. The addition of glucagon or cyclic AMP into cultured fetal hepatocytes decreased by 80% and 90% respectively the sensitivity of CPT I to malonyl-CoA inhibition. In the presence of cyclic AMP, the sensitivity of CPT I to malonyl-CoA inhibition in cultured fetal hepatocytes is very similar to that measured in cultured hepatocytes from 24-h-old newborns.
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PMID:Induction of ketogenesis and fatty acid oxidation by glucagon and cyclic AMP in cultured hepatocytes from rabbit fetuses. Evidence for a decreased sensitivity of carnitine palmitoyltransferase I to malonyl-CoA inhibition after glucagon or cyclic AMP treatment. 255 35


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