UMLS:C0038187 - FACTA Search

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Query: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In liver, insulin and glucose acutely increase the concentration of malonyl-CoA by dephosphorylating and activating acetyl-CoA carboxylase (ACC). In contrast, in incubated rat skeletal muscle, they appear to act by increasing the cytosolic concentration of citrate, an allosteric activator of ACC, as reflected by increases in the whole cell concentrations of citrate and malate [Saha, A. K., D. Vavvas, T. G. Kurowski, A. Apazidis, L. A. Witters, E. Shafrir, and N. B. Ruderman. Am. J. Physiol. 272 (Endocrinol. Metab. 35): E641-E648, 1997]. We report here that sustained increases in plasma insulin and glucose may also increase the concentration of malonyl-CoA in rat skeletal muscle in vivo by this mechanism. Thus 70 and 125% increases in malonyl-CoA induced in skeletal muscle by infusions of glucose for 1 and 4 days, respectively, and a twofold increase in its concentration during a 90-min euglycemic-hyperinsulinemic clamp were all associated with significant increases in the sum of whole cell concentrations of citrate and/or malate. Similar correlations were observed in muscle of the hyperinsulinemic fa/fa rat, in denervated muscle, and in muscle of rats infused with insulin for 5 h. In muscle of 48-h-starved rats 3 and 24 h after refeeding, increases in malonyl-CoA were not accompanied by consistent increases in the concentrations of malate or citrate. However, they were associated with a decrease in the whole cell concentration of long-chain fatty acyl-CoA (LCFA-CoA), an allosteric inhibitor of ACC. The results suggest that increases in the concentration of malonyl-CoA, caused in rat muscle in vivo by sustained increases in plasma insulin and glucose or denervation, may be due to increases in the cytosolic concentration of citrate. In contrast, during refeeding after starvation, the increase in malonyl-CoA in muscle is probably due to another mechanism.
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PMID:Cytosolic citrate and malonyl-CoA regulation in rat muscle in vivo. 1036 15

The aim of the present study was to investigate the hepatic regulation and beta-oxidation of long-chain fatty acids in peroxisomes and mitochondria, after 3-thia- tetradecylthioacetic acid (C14-S-acetic acid) treatment. When palmitoyl-CoA and palmitoyl-L-carnitine were used as substrates, hepatic formation of acid-soluble products was significantly increased in C14-S-acetic acid treated rats. Administration of C14-S-acetic acid resulted in increased enzyme activity and mRNA levels of hepatic mitochondrial carnitine palmitoyltransferase (CPT)-II. CPT-II activity correlated with both palmitoyl-CoA and palmitoyl-L-carnitine oxidation in rats treated with different chain-length 3-thia fatty acids. CPT-I activity and mRNA levels were, however, marginally affected. The hepatic CPT-II activity was mainly localized in the mitochondrial fraction, whereas the CPT-I activity was enriched in the mitochondrial, peroxisomal, and microsomal fractions. In C14-S-acetic acid-treated rats, the specific activity of peroxisomal and microsomal CPT-I increased, whereas the mitochondrial activity tended to decrease. C14-S-Acetyl-CoA inhibited CPT-I activity in vitro. The sensitivity of CPT-I to malonyl-CoA was unchanged, and the hepatic malonyl-CoA concentration increased after C14-S-acetic acid treatment. The mRNA levels of acetyl-CoA carboxylase increased. In hepatocytes cultured from palmitic acid- and C14-S-acetic acid-treated rats, the CPT-I inhibitor etomoxir inhibited the formation of acid-soluble products 91 and 21%, respectively. In contrast to 3-thia fatty acid treatment, eicosapentaenoic acid treatment and starvation increased the mitochondrial CPT-I activity and reduced its malonyl-CoA sensitivity. Palmitoyl-L-carnitine oxidation and CPT-II activity were, however, unchanged after either EPA treatment or starvation. The results from this study open the possibility that the rate control of mitochondrial beta-oxidation under mitochondrion and peroxisome proliferation is distributed between an enzyme or enzymes of the pathway beyond the CPT-I site after 3-thia fatty acid treatment. It is suggested that fatty acids are partly oxidized in the peroxisomes before entering the mitochondria as acylcarnitines for further oxidation.
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PMID:3-Thia fatty acid treatment, in contrast to eicosapentaenoic acid and starvation, induces gene expression of carnitine palmitoyltransferase-II in rat liver. 1038 Jan 16

The aim was to establish whether increased cardiac fatty acid oxidation in hyperthyroidism is due to direct alterations in cardiac metabolism which favour fatty acid oxidation and/or whether normal regulatory links between changes in glucose supply and fatty acid oxidation are dysfunctional. Euthyroid rats were sampled in the absorptive state or after 48 h starvation. Rats were rendered hyperthyroid by injection of tri-iodothyronine (1000 microg/kg body wt. per day; 3 days). We evaluated the regulatory significance of direct effects of hyperthyroidism by measuring rates of palmitate oxidation in the absence or presence of glucose using cardiac myocytes. The results were examined in relation to the activity/regulatory characteristics of cardiac carnitine palmitoyltransferase (CPT) estimated by measuring rates of [3H]palmitoylcarnitine formation from [3H]carnitine and palmitoyl-CoA by isolated mitochondria. To define the involvement of other hormones, we examined whether hyperthyroidism altered basal or agonist-stimulated cardiac cAMP concentrations in cardiac myocytes and whether the effects of hyperthyroidism could be reversed by 24 h exposure to insulin infused subcutaneously (2 i. u. per day; Alzet osmotic pumps). Rates of 14C-palmitate oxidation (to 14CO2) by cardiac myocytes were significantly increased (1.6 fold; P< 0.05) by hyperthyroidism, whereas the percentage suppression of palmitate oxidation by glucose was greatly diminished. Cardiac CPT activities in mitochondria from hyperthyroid rats were 2-fold higher and the susceptibility of cardiac CPT activity to inhibition by malonyl-CoA was decreased. These effects were not mimicked by 48 h starvation. The decreased susceptibility of cardiac CPT activities to malonyl-CoA inhibition in hyperthyroid rats was normalised by 24 h exposure to elevated insulin concentration. Acute insulin addition did not influence the response to glucose in cardiac myocytes from euthyroid or hyperthyroid rats and basal and agonist-stimulated cAMP concentrations were unaffected by hyperthyroidism in vivo. The data provide insight into possible mechanisms by which hyperthyroidism facilitates fatty acid oxidation by the myocardium, identifying changes in cardiac CPT activity and malonyl-CoA sensitivity that would be predicted to render cardiac fatty acid oxidation less sensitive to external factors influencing malonyl-CoA content, and thereby to favour fatty acid oxidation. The increased CPT activity observed in response to hyperthyroidism may be a consequence of an impaired action of insulin but occurs through a cAMP-independent mechanism.
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PMID:Hyperthyroidism facilitates cardiac fatty acid oxidation through altered regulation of cardiac carnitine palmitoyltransferase: studies in vivo and with cardiac myocytes. 1042 24

Liver microsomal fractions contain a malonyl-CoA-inhibitable carnitine acyltransferase (CAT) activity. It has been proposed [Fraser, Corstorphine, Price and Zammit (1999) FEBS Lett. 446, 69-74] that this microsomal CAT activity is due to the liver form of carnitine palmitoyltransferase 1 (L-CPT1) being targeted to the endoplasmic reticulum (ER) membrane as well as to mitochondria, possibly by an N-terminal signal sequence [Cohen, Guillerault, Girard and Prip-Buus (2001) J. Biol. Chem. 276, 5403-5411]. COS-1 cells were transiently transfected to express a fusion protein in which enhanced green fluorescent protein was fused to the C-terminus of L-CPT1. Confocal microscopy showed that this fusion protein was localized to mitochondria, and possibly to peroxisomes, but not to the ER. cDNAs corresponding to truncated (amino acids 1-328) or full-length L-CPT1 were transcribed and translated in the presence of canine pancreatic microsomes. However, there was no evidence of authentic insertion of CPT1 into the ER membrane. Rat liver microsomal fractions purified by sucrose-density-gradient centrifugation contained an 88 kDa protein (p88) which was recognized by an anti-L-CPT1 antibody and by 2,4-dinitrophenol-etomoxiryl-CoA, a covalent inhibitor of L-CPT1. Abundance of p88 and malonyl-CoA-inhibitable CAT activity were increased approx. 3-fold by starvation for 24 h. Deoxycholate solubilized p88 and malonyl-CoA-inhibitable CAT activity from microsomes to approximately the same extent. The microsomal fraction contained porin, which, relative to total protein, was as abundant as in crude mitochondrial outer membranes fractions. It is concluded that L-CPT1 is not targeted to the ER membrane and that malonyl-CoA CAT in microsomal fractions is L-CPT1 that is derived from mitochondria, possibly from membrane contact sites.
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PMID:The liver isoform of carnitine palmitoyltransferase 1 is not targeted to the endoplasmic reticulum. 1240 Nov 13

Liver contains two pyruvate dehydrogenase kinases (PDKs), namely PDK2 and PDK4, which regulate glucose oxidation through inhibitory phosphorylation of the pyruvate dehydrogenase complex (PDC). Starvation increases hepatic PDK2 and PDK4 protein expression, the latter occurring, in part, via a mechanism involving peroxisome proliferator-activated receptor-alpha (PPARalpha). High-fat feeding and hyperthyroidism, which increase circulating lipid supply, enhance hepatic PDK2 protein expression, but these increases are insufficient to account for observed increases in hepatic PDK activity. Enhanced expression of PDK4, but not PDK2, occurs in part via a mechanism involving PPAR-alpha. Heterodimerization partners for retinoid X receptors (RXRs) include PPARalpha and thyroid-hormone receptors (TRs). We therefore investigated the responses of hepatic PDK protein expression to high-fat feeding and hyperthyroidism in relation to hepatic lipid delivery and disposal. High-fat feeding increased hepatic PDK2, but not PDK4, protein expression whereas hyperthyroidism increased both hepatic PDK2 and PDK4 protein expression. Both manipulations decreased the sensitivity of hepatic carnitine palmitoyltransferase I (CPT I) to suppression by malonyl-CoA, but only hyperthyrodism elevated plasma fatty acid and ketone-body concentrations and CPT I maximal activity. Administration of the selective PPAR-alpha activator WY14,643 significantly increased PDK4 protein to a similar extent in both control and high-fat-fed rats, but WY14,643 treatment and hyperthyroidism did not have additive effects on hepatic PDK4 protein expression. PPARalpha activation did not influence hepatic PDK2 protein expression in euthyroid rats, suggesting that up-regulation of PDK2 by hyperthyroidism does not involve PPARalpha, but attenuated the effect of hyperthyroidism to increase hepatic PDK2 expression. The results indicate that hepatic PDK4 up-regulation can be achieved by heterodimerization of either PPARalpha or TR with the RXR receptor and that effects of PPARalpha activation on hepatic PDK2 and PDK4 expression favour a switch towards preferential expression of PDK4.
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PMID:Investigation of potential mechanisms regulating protein expression of hepatic pyruvate dehydrogenase kinase isoforms 2 and 4 by fatty acids and thyroid hormone. 1243 72

The mitochondrial pyruvate dehydrogenase complex (PDC) catalyses the oxidative decarboxylation of pyruvate, and links glycolysis to the tricarboxylic acid cycle and ATP production. Adequate flux through PDC is important in tissues with a high ATP requirement, in lipogenic tissues (since it provides cytosolic acetyl-CoA for fatty acid (FA) synthesis), and in generating cytosolic malonyl-CoA, a potent inhibitor of carnitine palmitoyltransferase (CPT I). Conversely, suppression of PDC activity is crucial for glucose conservation when glucose is scarce. This review describes recent advances relating to the control of mammalian PDC activity by phosphorylation (inactivation) and dephosphorylation (activation, reactivation), in particular regulation of PDC by pyruvate dehydrogenase kinase (PDK) which phosphorylates and inactivates PDC. PDK activity is that of a family of four proteins (PDK1-4). PDK2 and PDK4 appear to be expressed in most major tissues and organs of the body, PDK1 appears to be limited to the heart and pancreatic islets, and PDK3 is limited to the kidney, brain and testis. PDK4 is selectively upregulated in the longer term in most tissues and organs in response to starvation and hormonal imbalances such as insulin resistance, diabetes mellitus and hyperthyroidism. Parallel increases in PDK2 and PDK4 expression appear to be restricted to gluconceogenesic tissues, liver and kidney, which take up as well as generate pyruvate. Factors that regulate PDK4 expression include FA oxidation and adequate insulin action. PDK4 is also either a direct or indirect target of peroxisome proliferator-activated receptor (PPAR) alpha. PPAR alpha deficiency in liver and kidney restricts starvation-induced upregulation of PDK4; however, the role of PPAR alpha in heart and skeletal muscle appears to be more complex. These observations may have important implications for the pharmacological modulation of PDK activity (e.g. use of PPAR alpha activators) for the control of whole-body glucose, lipid and lactate homeostasis in disease states and suggest that therapeutic interventions must be tissue targeted so that whole-body fuel homeostasis is not adversely perturbed.
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PMID:Therapeutic potential of the mammalian pyruvate dehydrogenase kinases in the prevention of hyperglycaemia. 1247 89

beta-Ketoacyl-acyl carrier protein (ACP) synthase III (KAS III, also called acetoacetyl-ACP synthase) encoded by the fabH gene is thought to catalyze the first elongation reaction (Claisen condensation) of type II fatty acid synthesis in bacteria and plant plastids. However, direct in vivo evidence that KAS III catalyzes an essential reaction is lacking, because no mutant organism deficient in this activity has been isolated. We report the first bacterial strain lacking KAS III, a fabH mutant constructed in the Gram-positive bacterium Lactococcus lactis subspecies lactis IL1403. The mutant strain carries an in-frame deletion of the KAS III active site region and was isolated by gene replacement using a medium supplemented with a source of saturated and unsaturated long-chain fatty acids. The mutant strain is devoid of KAS III activity and fails to grow in the absence of supplementation with exogenous long-chain fatty acids demonstrating that KAS III plays an essential role in cellular metabolism. However, the L. lactis fabH deletion mutant requires only long-chain unsaturated fatty acids for growth, a source of long-chain saturated fatty acids is not required. Because both saturated and unsaturated fatty acids are required for growth when fatty acid synthesis is blocked by biotin starvation (which prevents the synthesis of malonyl-CoA), another pathway for saturated fatty acid synthesis must remain in the fabH deletion strain. Indeed, incorporation of [1-14C]acetate into fatty acids in vivo showed that the fabH mutant retained about 10% of the fatty acid synthetic ability of the wild-type strain and that this residual synthetic capacity was preferentially diverted to the saturated branch of the pathway. Moreover, mass spectrometry showed that the fabH mutant retained low levels of palmitic acid upon fatty acid starvation. Derivatives of the fabH deletion mutant strain were isolated that were octanoic acid auxotrophs consistent with biochemical studies indicating that the major role of FabH is production of short-chain fatty acid primers. We also confirmed the essentiality of FabH in Escherichia coli by use of a plasmid-based gene insertion/deletion system. Together these results provide the first genetic evidence demonstrating that FabH conducts the major condensation reaction in the initiation of type II fatty acid biosynthesis in both Gram-positive and Gram-negative bacteria.
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PMID:Beta-ketoacyl-acyl carrier protein synthase III (FabH) is essential for bacterial fatty acid synthesis. 1452 10

Rat hearts were perfused for 1 h with 5 mm glucose with or without palmitate or oleate at concentrations characteristic of the fasting state. The inclusion of fatty acids resulted in increased activities of the alpha-1 or the alpha-2 isoforms of AMP-activated protein kinase (AMPK), increased phosphorylation of acetyl-CoA carboxylase and a decrease in the tissue content of malonyl-CoA. Activation of AMPK was not accompanied by any changes in the tissue contents of ATP, ADP, AMP, phosphocreatine or creatine. Palmitate increased phosphorylation of Thr172 within AMPK alpha-subunits and the activation by palmitate of both AMPK isoforms was abolished by protein phosphatase 2C leading to the conclusion that exposure to fatty acid caused activation of an AMPK kinase or inhibition of an AMPK phosphatase. In vivo, 24 h of starvation also increased heart AMPK activity and Thr172 phosphorylation of AMPK alpha-subunits. Perfusion with insulin decreased both alpha-1 and alpha-2 AMPK activities and increased malonyl-CoA content. Palmitate prevented both of these effects. Perfusion with epinephrine decreased malonyl-CoA content without an effect on AMPK activity but prevented the activation of AMPK by palmitate. The concept is discussed that activation of AMPK by an unknown fatty acid-driven signalling process provides a mechanism for a 'feed-forward' activation of fatty acid oxidation.
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PMID:Covalent activation of heart AMP-activated protein kinase in response to physiological concentrations of long-chain fatty acids. 1515 11

We have previously proposed that changes in malonyl-CoA sensitivity of rat L-CPT1 (liver carnitine palmitoyltransferase 1) might occur through modulation of interactions between its cytosolic N- and C-terminal domains. By using a cross-linking strategy based on the trypsin-resistant folded state of L-CPT1, we have now shown the existence of such N-C (N- and C-terminal domain) intramolecular interactions both in wild-type L-CPT1 expressed in Saccharomyces cerevisiae and in the native L-CPT1 in fed rat liver mitochondria. These N-C intramolecular interactions were found to be either totally (48-h starvation) or partially abolished (streptozotocin-induced diabetes) in mitochondria isolated from animals in which the enzyme displays decreased malonyl-CoA sensitivity. Moreover, increasing the outer membrane fluidity of fed rat liver mitochondria with benzyl alcohol in vitro, which induced malonyl-CoA desensitization, attenuated the N-C interactions. This indicates that the changes in malonyl-CoA sensitivity of L-CPT1 observed in mitochondria from starved and diabetic rats, previously shown to be associated with altered membrane composition in vivo, are partly due to the disruption of N-C interactions. Finally, we show that mutations in the regulatory regions of the N-terminal domain affect the ability of the N terminus to interact physically with the C-terminal domain, irrespective of whether they increased [S24A (Ser24-->Ala)/Q30A] or abrogated (E3A) malonyl-CoA sensitivity. Moreover, we have identified the region immediately N-terminal to transmembrane domain 1 (residues 40-47) as being involved in the chemical N-C cross-linking. These observations provide the first demonstration by a physico-chemical method that L-CPT1 adopts different conformational states that differ in their degree of proximity between the cytosolic N-terminal and the C-terminal domains, and that this determines its degree of malonyl-CoA sensitivity depending on the physiological state.
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PMID:Demonstration of N- and C-terminal domain intramolecular interactions in rat liver carnitine palmitoyltransferase 1 that determine its degree of malonyl-CoA sensitivity. 1549 23

Acetyl-CoA carboxylase (ACC) plays a fundamental role in fatty acid metabolism. The reaction product, malonyl-CoA, is both an intermediate in the de novo synthesis of long-chain fatty acids and also a substrate for distinct fatty acyl-CoA elongation enzymes. In metazoans, which have evolved energy storage tissues to fuel locomotion and to survive periods of starvation, energy charge sensing at the level of the individual cell plays a role in fuel selection and metabolic orchestration between tissues. In mammals, and probably other metazoans, ACC forms a component of an energy sensor with malonyl-CoA, acting as a signal to reciprocally control the mitochondrial transport step of long-chain fatty acid oxidation through the inhibition of carnitine palmitoyltransferase I (CPT I). To reflect this pivotal role in cell function, ACC is subject to complex regulation. Higher metazoan evolution is associated with the duplication of an ancestral ACC gene, and with organismal complexity, there is an increasing diversity of transcripts from the ACC paraloges with the potential for the existence of several isozymes. This review focuses on the structure of ACC genes and the putative individual roles of their gene products in fatty acid metabolism, taking an evolutionary viewpoint provided by data in genome databases.
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PMID:Structure and regulation of acetyl-CoA carboxylase genes of metazoa. 1574 55

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