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Query: UMLS:C0011849 (
diabetes
)
277,896
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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.
...
PMID:Alteration of the apparent Ki of carnitine palmitoyltransferase for malonyl-CoA by the diabetic state and reversal by insulin. 389 56
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.
...
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
Intact mitochondria and inverted submitochondrial vesicles were prepared from the liver of fed, starved (48 h) and streptozotocin-diabetic rats in order to characterize
carnitine palmitoyltransferase
kinetics and malonyl-CoA sensitivity in situ. In intact mitochondria, both starved and diabetic rats exhibited increased Vmax., increased Km for palmitoyl-CoA, and decreased sensitivity to malonyl-CoA inhibition. Inverted submitochondrial vesicles also showed increased Vmax. with starvation and
diabetes
, with no change in Km for either palmitoyl-CoA or carnitine. Inverted vesicles were uniformly less sensitive to malonyl-CoA regardless of treatment, and
diabetes
resulted in a further decrease in sensitivity. In part, differences in the response of
carnitine palmitoyltransferase
to starvation and
diabetes
may reside in differences in the membrane environment, as observed with Arrhenius plots, and the relation of enzyme activity and membrane fluidity. In all cases, whether rats were fed, starved or diabetic, and whether intact or inverted vesicles were examined, increasing membrane fluidity was associated with increasing activity. Malonyl-CoA was found to produce a decrease in intact mitochondrial membrane fluidity in the fed state, particularly at pH 7.0 or less. No effect was observed in intact mitochondria from starved or diabetic rats, or in inverted vesicles from any of the treatment groups. Through its effect on membrane fluidity, malonyl-CoA could regulate
carnitine palmitoyltransferase
activity on both surfaces of the inner membrane through an interaction with only the outer surface.
...
PMID:Hepatic mitochondrial inner membrane properties and carnitine palmitoyltransferase A and B. Effect of diabetes and starvation. 409 1
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.
...
PMID:The regulation of ketogenesis. 612 45
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.
...
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.
...
PMID:Diabetes and proteolysis: effects on carnitine palmitoyltransferase-I and malonyl-CoA binding. 763 57
CBL/57 strain db/db mice exhibit type II (noninsulin-dependent)
diabetes
. The affected mice are markedly hyperinsulinemic, hyperglycemic, and hypercholesterolemic, and their serum K+ levels are decreased. The brains of the diabetic mice are significantly smaller than those of their lean, control littermates, but the protein concentration is normal. The low brain weight is accompanied by a loss of major fatty acid components within the whole brain, nerve endings, and mitochondrial membranes. Cholesterol levels are low in whole brain but are not significantly different from normal in the synaptosomal membranes. The phospholipid concentration is significantly decreased in whole brain homogenates, crude synaptosomal membranes, and crude mitochondrial membranes of the diabetic mice. In addition, the specific activities of membrane-bound synaptosomal acetylcholinesterase, Na+,K(+)-ATPase, and Mg(2+)-ATPase are decreased in crude synaptosomal membranes of the diabetic mice. The specific activities of
carnitine palmitoyltransferase I
and carnitine acetyltransferase are significantly increased in the crude mitochondrial fraction isolated from the brains of the type II diabetic mice, whereas the specific activity of pyruvate dehydrogenase complex is decreased. The specific activities of two other mitochondrial enzymes--monoamine oxidase B and citrate synthase--and a cytosolic enzyme--lactate dehydrogenase--are unaltered. The ability to synthesize cyclic AMP is markedly decreased in the brains of the diabetic mice. The concentrations of carnitine and of the amino acids, glutamate, aspartate, glutamine, and serine are unaltered, whereas glycine levels are significantly elevated in the brains of the db/db mice. The data suggest that in vivo the brains of the diabetic mice exhibit a decreased capacity for glucose oxidation and increased capacity for fatty acid oxidation. This hypothesis is supported by the finding that cerebral mitochondria isolated from the db/db mice oxidize [1-14C]palmitate to 14CO2 at a rate almost twice that of control mitochondria. The present findings emphasize the potentially serious alteration of brain metabolism in uncontrolled type II
diabetes
.
...
PMID:Lipid metabolism and membrane composition are altered in the brains of type II diabetic mice. 772 1
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.
...
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.
...
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.
...
PMID:Mitochondrial diseases. 795 50
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