UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Saponin-permeabilization (30 micrograms/ml) of the platelet plasma membrane, which enables access of added compounds to mitochondrial overt carnitine palmitoyltransferase (CPT I), was applied to allow the rapid determination of CPT I activity in situ. The effects of diabetes and short-term incubation with insulin in vitro on the kinetic parameters and malonyl-CoA sensitivity of CPT I were also studied in rat platelets. CPT I exhibited ordinary Michaelis-Menten kinetics when platelets were incubated with palmitoyl-CoA. Malonyl-CoA showed an I50 (concentration giving 50% inhibition of CPT activity) of 0.92 +/- 0.11 microM in permeabilized platelets. Platelets obtained from diabetic rats (induced by streptozotocin injection) exhibited an increased Vmax and I50 for malonyl-CoA, and an unaltered Km for palmitoyl-CoA. In contrast, preincubation of platelets prepared from both fed control rats and diabetic rats with insulin (100 and 150 microU/ml) led to a decrease in enzyme activity when assayed with 75 microM palmitoyl-CoA and 0.5 mM L-carnitine as substrates. These in vivo and in vitro results suggested that insulin directly modulated rat platelet CPT I activity, as it does in the liver.
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PMID:Characterization of overt carnitine palmitoyltransferase in rat platelets; involvement of insulin on its regulation. 185 44

Carnitine palmitoyltransferase (CPT total) activity and synthesis increase in states where the insulin/glucagon ratio is low, such as starvation and diabetes [Brady & Brady (1987) Biochem. J. 246, 641-646]. However, the effect of glucagon and insulin on CPT synthesis is unknown. The present experiments were designed to determine the effect of glucagon, cAMP [8-(chlorophenylthio) cyclic AMP], and insulin + cAMP on CPT transcription and mRNA amounts over time after injection. The CPT protein that was purified, used to generate antibody, and cloned in these studies was the 68 kDa mitochondrial protein described previously [Brady & Brady (1987) Biochem. J. 246, 641-646; Brady, Feng & Brady (1988) J. Nutr. 118, 1128-1136; Brady & Brady (1989) Diabetes 38, in the press]. Saline-injected control rats exhibited a 2-fold increase in hepatic CPT transcription rate and CPT mRNA over the 5 h experiment from 09:00 to 14:00 h. The effect was most probably due to the fasting state of the rats during the day. Glucagon injection caused an 8-fold increase in transcription rate by 90 min and a 4-fold increase in CPT mRNA by 90-120 min. The cAMP effect had reached a peak by the first time point taken (15 min). Transcription rate was increased 4-fold and CPT mRNA was increased 3-fold at this time. The combination of cAMP + insulin injection did not produce any significant increase in transcription rate or CPT mRNA over the saline-injected controls. CPT mRNA and transcription rate showed a clear dose-response to glucagon injection from 0 to 150 micrograms/100 g body wt. Total CPT activity and immunoreactive CPT were not increased during these experiments. The data indicate that glucagon and insulin interact in control of transcription rate and amount of CPT mRNA, but that increases in CPT immunoreactive protein and activity are temporally delayed. This lag probably relates to the half-life of the CPT protein in vivo, which has been estimated as 2-7 days.
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PMID:Regulation of carnitine palmitoyltransferase in vivo by glucagon and insulin. 254 60

The effect of fatty acids and the carnitine palmitoyltransferase I (CPT I) inhibitor, Etomoxir, on myocardial glucose oxidation in diabetes was studied. 14CO2 production from 11 mM [14C]glucose was measured in control or 6-week streptozotocin-diabetic isolated working rat hearts perfused with or without 1.2 mM palmitate (bound to 3% albumin). In control hearts, addition of palmitate to the buffer resulted in a marked reduction (13-fold) in glucose oxidation rates. Glucose oxidation in diabetic rat hearts perfused with palmitate was almost abolished. Even though glucose oxidation rates were low, exogenous palmitate oxidation rates, measured as 14CO2 production from [14C]palmitate, were not increased in diabetic versus control hearts. Addition of the CPT 1 inhibitor, Etomoxir (1.10(-6) M), resulted in a doubling of glucose oxidation rates in both control and diabetic rat hearts, in the presence or absence of palmitate. The effects of Etomoxir on glucose oxidation could not be explained by reduced exogenous palmitate oxidation or decreased levels of citrate. Cardiac function, as measured by the heart rate x peak systolic pressure product, was reduced in diabetic rat hearts. Etomoxir significantly increased heart function in palmitate-perfused hearts from both control and diabetic rats. These data suggest that fatty acids contribute to decreased glucose oxidation and cardiac function in diabetic rat hearts. These effects of fatty acids can be partially reversed with the CPT 1 inhibitor, Etomoxir.
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PMID:Glucose oxidation rates in fatty acid-perfused isolated working hearts from diabetic rats. 280 76

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

The oral hypoglycemic agent, methyl 2-tetradecylglycidate (Me-TDGA), which inhibits in vitro mitochondrial carnitine palmitoyl transferase A (CPT-A) was used to study the relationship of CPT inhibition to changes in ketonemia and glycemia in normal and diabetic rats. After oral administration of Me-TDGA, the CPT activity of isolated rat liver mitochondria was substantially reduced with only the presumed outer enzyme fraction CPT-A released by digitonin treatment showing reduced activity. Mitochondrial fatty acyl-CoA synthetase was not inhibited. Oral doses of 0.1-2.5 mg/kg Me-TDGA produced both a dose-dependent lowering of plasma ketones and an inhibition of liver CPT. With single doses in excess of 2.5 mg/kg, po, heart and skeletal muscle CPT were also consistently inhibited. The effect on the liver enzyme persisted for at least 48 hr following 1 mg/kg, po, while the effect on ketones disappeared by 36 hr. The degree of inhibition of liver CPT produced by Me-TDGA was not altered by diabetes or the dietary state. At low doses (0.05-0.25 mg/kg, po), the most sensitive parameter was inhibition of hepatic CPT. Both plasma ketones and CPT were lowered with doses 10-fold less (0.1 mg/kg) than were required for blood glucose lowering, thus making Me-TDGA the most potent hypoketonemic compound known. In conclusion, inhibition of liver beta-oxidation at the stage of CPT-A by Me-TDGA can explain the potent hypoketonemic effects of this compound in fasted normal and diabetic rats. Higher acute doses are needed for both inhibition of muscle CPT and lowering of blood glucose.
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PMID:Inhibition of mitochondrial carnitine palmitoyl transferase A in vivo with methyl 2-tetradecylglycidate (methyl palmoxirate) and its relationship to ketonemia and glycemia. 396 83

The regulation of hepatic mitochondrial carnitine palmitoyltransferase-I (CPT-I) was studied in rats during starvation and insulin-dependent diabetes and in rat H4IIE cells. The Vmax. for CPT-I in hepatic mitochondrial outer membranes isolated from starved and diabetic rats increased 2- and 3-fold respectively over fed control values with no change in Km values for substrates. Regulation of malonyl-CoA sensitivity of CPT-I in isolated mitochondrial outer membranes was indicated by an 8-fold increase in Ki during starvation and by a 50-fold increase in Ki in the diabetic state. Peroxisomal and microsomal CPT also had decreased sensitivity to inhibition by malonyl-CoA during starvation. CPT-I mRNA abundance was 7.5 times greater in livers of 48-h-starved rats and 14.6 times greater in livers of insulin-dependent diabetic rats compared with livers of fed rats. In H4IIE cells, insulin increased CPT-I sensitivity to inhibition by malonyl-CoA in 4 h, and sensitivity continued to increase up to 24 h after insulin addition. CPT-I mRNA levels in H4IIE cells were decreased by insulin after 4 h and continued to decrease so that at 24 h there was a 10-fold difference. The half-life of CPT-I mRNA was 4 h in the presence of actinomycin D or with actinomycin D plus insulin. These results suggest that insulin regulates CPT-I by inhibiting transcription of the CPT-I gene.
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PMID:Insulin regulates enzyme activity, malonyl-CoA sensitivity and mRNA abundance of hepatic carnitine palmitoyltransferase-I. 757 18

Malonyl-CoA binding and malonyl-CoA inhibition of carnitine palmitoyltransferase-I (CPT-I) were measured in hepatic mitochondria from normal and diabetic rats and in protease-treated mitochondria from fed rats to test the hypothesis that proteolysis represents a mechanism by which diabetes produces changes in the sensitivity of CPT-I to inhibition by malonyl-CoA. As in diabetes, protease treatment increased the apparent Ki values for malonyl-CoA. Palmitoyl-CoA greatly diminished malonyl-CoA specific binding in the mitochondrial system being studied, suggesting strong competition at the malonyl-CoA binding site. Proteolysis decreased capacity for specific binding of malonyl-CoA by 60-80%, but it had no effect on binding affinity. In contrast, the decreased specific binding of malonyl-CoA seen in the diabetic state is accompanied by increased binding affinity. Furthermore, observed Kd values differed from Ki values by a factor of 10 or more, suggesting that measured Kd and Ki may represent different ligand-protein complexes. These data suggest that alterations in inhibition of CPT-I by malonyl-CoA occurring in the diabetic state may involve mechanisms other than simple proteolytic removal of malonyl-CoA binding sites.
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PMID:Diabetes and proteolysis: effects on carnitine palmitoyltransferase-I and malonyl-CoA binding. 763 57

The incidence of mortality from cardiovascular diseases in higher in diabetic patients. The cause of this accelerated cardiovascular disease is multifactorial and, although atherosclerotic cardiovascular disease in association with well-defined risk factors has an influence on morbidity and mortality in diabetics, myocardial cell dysfunction independent of vascular defects have also been defined. We postulate that these adverse cardiac effects could presumably result as a consequence of the following sequence of events. Major abnormalities in myocardial carbohydrate and lipid metabolism occur as a result of insulin deficiency. These changes are closely linked to the accumulation of various acylcarnitine and coenzyme derivatives. Abnormally high amounts of metabolic intermediates could cause disturbances in calcium homeostasis either directly or indirectly through structural and functional subcellular membrane alterations. Over time, chronic abnormalities such as reduced myosin ATPase activity, decreased ability of the sarcoplasmic reticulum to take up calcium as well as depression of other membrane enzymes such as Na(+)-K+ ATPase and Ca(2+)-ATPase leads to changes in calcium homeostasis and eventually to cardiac dysfunction. More importantly from the point of view of pharmacological intervention, during the initial stages, acute disturbances in both the glucose and FFA oxidative pathways may provide the initial biochemical lesion from which further events ensue. Thus therapies which target these metabolic aberrations in the heart during the early stages of diabetes, in effect, can potentially delay or impede the progression of more permanent sequelae which could ensue from otherwise uncontrolled derangements in cardiac metabolism. There is little dispute that an attempt should be made to lower raised plasma triglyceride and FFA levels. This would decrease the heart's reliance on fatty acids and, hence, overcome the fatty acid inhibition of myocardial glucose utilization. In this regard, the likely application of fatty acid oxidation inhibitors (CPT inhibitors, beta-oxidation inhibitors, sequestration of mitochondrial CoA) is also apparent.
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PMID:Myocardial substrate metabolism: implications for diabetic cardiomyopathy. 776 Mar 40

The selective inhibition of individual carnitine acyltransferases may be useful in the therapy of diabetes and heart disease. Aminocarnitine (3) is a weak competitive inhibitor (K(i) = 4.0 mM) for carnitine acetyltransferase (CAT), although the N-acetyl derivative 4 is about 165 times more potent (K(i) = 0.024 mM) than 3. Compound 3 is also a potent competitive inhibitor for carnitine palmitoyltransferases 1 and 2 (CPT-1 and CPT-2) (IC50 for CPT-2 = 805 nM). We synthesized 3-amino-5,5-dimethylhexanoic acid (7) and its N-acetyl derivative (8) as isosteric analogs of 3 and 4 that lack the quaternary ammonium positive charge. Like 3 and 4, compounds 7 and 8 were competitive inhibitors of CAT with significantly different potencies, but in this case, 8 (K(i) = 25 mM) was 10 times less potent than 7 (K(i) = 2.5 mM). R-(-)-7 and S-(+)-7 were stereoselective inhibitors of CAT (K(i) = 1.9 and 9.2 mM, respectively). Racemic 7 was a weak competitive inhibitor of CPT-2 (K(i) = 20 mM) and had no effect on CPT-1. These results are consistent with differences among the carnitine-binding sites on carnitine acyl-transferases that may be useful in selective inhibitor design. Furthermore, the data suggest that the quaternary ammonium positive charge of carnitine may be important for the proper orientation of carnitine and its analogs in the binding site.
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PMID:3-Amino-5,5-dimethylhexanoic acid. Synthesis, resolution, and effects on carnitine acyltransferases. 793 52

Mitochondrial diseases are heterogeneous and characterized by a primary defect of the mitochondrial energy output. Genetic defects of mitochondrial energy enzymes may be due to either nuclear DNA gene mutations or mitochondrial DNA (mtDNA) mutations. Among hereditary defects of nuclear-encoded mitochondrial enzymes, carnitine palmitoyltransferase II (CPT-II) deficiency and pyruvate dehydrogenase complex (PDHC) deficiency are of major interest to the neurologist. Several mutations in the CPT-II gene as well as in the X-linked E1 alpha subunit gene of PDHC have been reported and associated with different clinical phenotypes. mtDNA-related syndromes include mitochondrial encephalomyopathies (e.g. MELAS, MERRF, NARP, MIMyCa, etc.), 'pure' encephalopathies (e.g. LHON) and a few syndromes involving only non-neurological systems (e.g. Pearson's pancreas-bone marrow syndrome or diabetes mellitus). Three kinds of molecular lesions have been identified in mtDNA-related disorders: point mutations of protein-encoding mtDNA genes (mit- mutations), point mutations of mtDNA-tRNA genes (syn- mutations) and large-scale rearrangements of mtDNA (rho- mutations). Point mutations (mit- and syn+) are usually maternally inherited, while single large-scale mtDNA rearrangements are usually sporadic. Furthermore, mendelian traits leading to either qualitative or quantitative abnormalities of mtDNA (i.e. multiple mtDNA deletions and tissue-specific mtDNA depletion, respectively) are the first examples of genetic dysfunction of nuclear-mitochondrial communication. In most cases, the molecular detection of the known defects of mtDNA can be carried out by non-invasive techniques, thus making it an easy and relatively inexpensive procedure in the differential diagnosis of the mitochondrial disorders, a rapidly expanding area of clinical neurology.
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PMID:Mitochondrial diseases. 795 50

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