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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Propionyl-L-carnitine, unlike L-carnitine, is known to improve myocardial function and metabolism altered during the course of ischemia-reperfusion. In this study, the effect of propionyl-L-carnitine has been compared with that of propionate and carnitine on the performance of rat hearts perfused with a glucose-containing medium either under normoxia, ischemia, or postischemic reperfusion. In the postischemic phase, contractile parameters were partially restored both in the control and in the propionate plus carnitine-treated hearts, were markedly impaired by propionate, and were fully recovered by propionyl-L-carnitine. In addition, propionyl-L-carnitine, but not propionate, reduced the functional decay of mitochondria prepared from the ischemic hearts. Even in normoxic conditions propionate, unlike propionyl-L-carnitine, caused a drastic reduction of free CoA and L-carnitine. The concomitant increase in lactate production and decrease in ATP content might be explained by the inhibition of pyruvate dehydrogenase caused by the accumulation of propionyl-CoA. Indeed, when pyruvate was the only oxidizable substrate, propionate induced a gradual decrease in developed pressure, which was largely prevented by L-carnitine. The protective effect of propionyl-L-carnitine may be a consequence of the anaplerotic utilization of propionate in the presence of an optimal amount of ATP and free L-carnitine.
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PMID:Contrasting effects of propionate and propionyl-L-carnitine on energy-linked processes in ischemic hearts. 806 96

Ischemia of the heart is accompanied by the tissue accumulation of long-chain fatty acids and their metabolic derivatives such as beta-hydroxy fatty acids and fatty acyl-CoA and acyl-L-carnitine esters. These substances might be detrimental for proper myocardial function. Previously, it has been suggested that intracellular lipid binding proteins like cytoplasmic fatty acid-binding protein (FABP) and acyl-CoA binding protein (ACBP) may bind these accumulating fatty acyl moieties to prevent their elevated levels from potentially harmful actions. In addition, the suggestion has been made that the abundantly present FABP may scavenge free radicals which are generated during reperfusion of the ischemic heart. However, these protective actions are challenged by the continuous physico-chemical partition of fatty acyl moieties between FABP and membrane structures and by the rapid release of FABP from ischemic and reperfused cardiac muscle. Careful evaluation of the available literature data reveals that at present no definite conclusion can be drawn about the potential protective effect of FABP on the ischemic and reperfused heart.
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PMID:Significance of cytoplasmic fatty acid-binding protein for the ischemic heart. 823 60

We have previously demonstrated that ischemic injury results in the loss of peroxisomal functions (e.g., inhibition of catalase activity and fatty-acid beta-oxidation activity). To understand the molecular mechanism leading to the loss of peroxisomal beta-oxidation in ischemic tissue, we examined the levels of individual enzyme activities and proteins of the peroxisomal beta-oxidation system and overall fatty-acid oxidation in peroxisomes isolated from kidney exposed to ischemia-reperfusion injury. The peroxisomal beta-oxidation decreased with an increase in time of ischemic injury (53% and 43% of the control in kidneys exposed to 60 and 90 min ischemia, respectively). In vivo inactivation of catalase with aminotriazole and exposure of isolated peroxisomes to H2O2 resulted in inhibition of peroxisomal beta-oxidation system suggesting that this enzyme system is labile to excessive H2O2 produced during ischemic injury. The enzyme activities of lignoceroyl-CoA ligase, acyl-CoA oxidase, bifunctional enzymes and acyl-CoA thiolase (individual peroxisomal beta-oxidation enzymes) after 90 min of ischemia were 87, 80, 87 and 85% of the control, respectively. This decrease in enzyme activities was more pronounced following reperfusion (28, 11, 23 and 35% of the control, respectively). Immunoblot analysis of these enzymes indicated that the major loss of these enzyme activities during ischemia was due to their inactivation, whereas during reperfusion, proteolysis also contributed toward the observed loss of these activities. In summary, these results demonstrated that loss of peroxisomal beta-oxidation in ischemia-reperfusion injury was due to inactivation and proteolysis of beta-oxidation enzymes. Acyl-CoA oxidase was more sensitive to ischemia-reperfusion injury compared to other enzymes, and the overall loss of peroxisomal beta-oxidation may be a reflection of the loss of acyl-CoA oxidase activity, a rate-limiting enzyme.
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PMID:Alterations of peroxisomal function in ischemia-reperfusion injury of rat kidney. 839 63

The effects of hypothermic ischemia utilizing Euro-Collins flush on renal tissue long-chain activated fatty acid content was studied in dogs. Also, the ability of the simple amino acid glycine to complex these acyl thioesters was also investigated. Renal inner cortex was found to contain (in increasing amounts) myristoyl-, palmitoleoyl-, palmitoyl-, arachidonyl-, and oleoyl-coenzyme A throughout the 3 days of cold ischemia. Although the amounts of individual long-chain acyl-CoA compounds varied considerably, the concentrations were not found to differ significantly with increasing ischemia times. The presence of 5 mM of glycine in the flush also did not influence the amount or species of long-chain acyl-CoA esters in renal tissue during cold ischemia. Ischemic renal tissue content of most long-chain acyl-CoA compounds was reduced by about 50% when the tissue underwent in vitro reperfusion with 37 degrees C O2-saturated media. Glycine included in the flush storage solution did not alter acyl-CoA levels in tissue undergoing hypothermic ischemia and short-term in vitro reperfusion with O2-saturated buffer. In conclusion, long-chain acyl-CoA thioesters are present during hypothermic renal ischemia and the levels of most of these species are reduced during in vitro reperfusion after ischemia. The quality and production mass of these metabolites appears to be unaltered by progressive hypothermic ischemia times. Finally, the protective effects of glycine in this model of renal organ preservation injury are not associated with reductions of renal tissue long-chain activated fatty acids.
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PMID:Long-chain acyl-coenzyme A thioesters and renal hypothermic ischemic injury: effects of glycine flush. 844 Jan 27

Although accounting for 2% of body weight, brain has one of the greatest metabolic rates compared with other organs and systems. The energy metabolic consum is expended mainly in the maintenance of ionic gradient, essential to neuronal activity. Brain receives energy substrates from circulation, with interference of blood brain barrier (BBB). Glucose is the main substrate and has a metabolic rate so high as 150 g/day (0.7 mM/G/min). At cellular level, metabolism of glucose seems to be controlled by phosphofructokynase. If the cellular level were high enough, manose and other products like fructose 1,6 biphosphate, pyruvate, lactate and acetate can be used in the place of glucose. Lactate, when oxyded, consums at least 21% of the cerebral needs of O2. In ischemia and inflammatory infections, brain tissue produces lactate instead of use it. Ketone bodies reduce cerebral needs of glucose; in view of the disturbances that occur in cerebral production of succinyl CoA and guanosine 3 phosphate (GTP), they must be considered as complementary substrate but not as an alternative one. Although they can be metabolized, there are no evidences that brain could produce energy from systemic free fatty acids, even when hypoglicemia is present. Ethanol and glycerol are considered only at experimental level. Brain uptake of aminoacids occur better for long chain aminoacids, specially valine. The aminoacids that are synthetised in the brain (aspartate, gluconate and alanine) show the lower absortion rates. All aminoacids should be oxided to CO2 and H2O. Even when glucose consum is reduced to 30%, aminoacid accounts for only 10% of the energetic expenditure of the brain. To maintain cerebral glucose and oxygen supply to the brain, blood flow must be at least 800 ml/min. The regulation of supply and consumption of energy substrate by the brain is changed in few situations. Among them, are included the oxidation of lactate immediately before milk diet early in development and utilization of ketone bodies at the beginning of lactation. This review includes a brief discussion about the relevance of glucose as the main energy substrate for cerebral tissue in different ages and ischemia or hypoxia.
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PMID:[Control of supply and use of energy substrates in the encephalon]. 858 33

The purposes of this study were to: (1) assess myocardial pyruvate dehydrogenase (PDH) activity and substrate exchange under well-perfused and ischemic conditions; (2) determine the metabolic effects of an intra-coronary infusion of the PDH activator, dichloroacetate (DCA); and (3) measure the effects of ischemia and DCA on malonyl CoA levels. Experiments were performed in anesthetised open-chest swine under non-ischemic conditions, followed by 40 min with a 60% reduction in left anterior descending coronary artery (LAD) blood flow. Myocardial needle biopsies for measurement of PDH activity were taken after an intracoronary infusion of either saline or DCA (1 mM in LAD blood) under aerobic conditions, and after 37 min of ischemia. Pyruvate dehydrogenase activity was measured with and without maximal activation by swine PDH phosphatase. Malonyl CoA and acetyl CoA were measured after 40 min of LAD ischemia in myocardium from the ischemic DCA- or saline-treated LAD bed, and the non-ischemic untreated left circumflex coronary artery (CFX) perfusion bed. Net glucose, lactate and free fatty acid (FFA) uptakes were measured across the LAD perfusion bed throughout the study. Dichloroacetate treatment increased the amount of active dephosphorylated PDH to 88% of the total activity under aerobic conditions, compared to 55% with saline (P < 0.01). Ischemia did not significantly change PDH activation state in either group. Acetyl CoA and malonyl CoA contents were significantly elevated in ischemic DCA-treated myocardium compared to saline-treated ischemic myocardium. Dichloroacetate treatment significantly lowered rates of myocardial FFA uptake under both aerobic and ischemic conditions, but did not effect glucose uptake or lactate exchange. Free fatty acid uptake was negatively correlated to malonyl CoA levels (r = -0.68) during ischemia. It is proposed that the inhibition of FFA uptake observed with DCA in ischemic myocardium is due to malonyl CoA inhibition of carnitine palmitoyl transferase I.
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PMID:Pyruvate dehydrogenase activity and malonyl CoA levels in normal and ischemic swine myocardium: effects of dichloroacetate. 876 30

Studies were performed to test the influence of propionate as a competing myocardial substrate on acetate and palmitate metabolism in reperfused pig hearts after an exposure of mild-to-moderate regional ischemia. Experiments were conducted in intact, working pig hearts (n = 10) using an extracorporeal coronary perfusion technique. Half the animals received 2 mM propionate selectively into the anterior descending (LAD) perfusate. Perfusion conditions in the LAD circulation were divided into three intervals: an aerobic, preischemic period (0-20 min); an ischemic period affected by a 60% reduction in LAD flow (20-60 min); and an aerobic, postischemic period (60-100 min). Steady-state infusions of (1(-14)C) acetate and [9, 10(-3)H] palmitate were begun at 60 min perfusion to monitor metabolism during reperfusion. Propionate had no effect on oxidation of acetate except for a slight delay in CO2 appearance. Propionate significantly suppressed oxidation of long-chain fatty acids (-38 delta %, P < 0.018), which was not explained by a selective scavenging of CoA units or carnitine by propionate, which might otherwise enhance fatty acid activation, transfer, or oxidation. Propionate by indirect estimates had no apparent effect on glucose metabolism. Propionate-treated hearts, despite shifts in substrate preference, were not further compromised in energy metabolism as levels of creatine phosphate and adenine nucleotides were comparable to control hearts. Recovery of regional mechanical function was also comparable between groups but incompletely, with respect to preischemic performance, compatible with myocardial stunning. The data show in reperfused myocardium that propionate is capable of altering the preferred use of fatty acids, but that anaplerotic entry of carbon units during this reperfusion interval was sufficient to prevent a selective imbalance of energy metabolism or deficit in mechanical recovery.
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PMID:Anaplerotic effects of propionate on oxidations of acetate and long-chain fatty acids. 876 74

In this review, evidence is summarized for the production of PAF in brain, in response to stimulation associated with pathology. As well, there is a growing literature on the duality of actions of this lipid autocoid upon nervous tissue, indicated by extracellular and intracellular actions and binding sites for PAF in brain. The metabolic routes to PAF can be divided into the de novo and remodelling pathways of synthesis. The de novo route consists of 1-alkyl glycerophosphate acetyltransferase, and the subsequent actions of distinct phosphohydrolase and cholinephosphotransferase activities. This acetyltransferase can be activated by phosphorylation, and inhibited by MgATP and fatty acyl CoA thioesters, inhibitions which have particular relevance to brain ischemia. There is also evidence that the cholinephosphotransferase is controlled by phosphorylation, and regulated by levels of CDP-choline. The remodelling pathway to PAF relies upon the actions of phospholipase A2 or CoA-independent transacylases to generate the 1-alkyl glycerophosphorylcholine, as substrate for a distinct acetyltransferase. Following stimulation, rising intracellular calcium may trigger arachidonate selective cytosolic phospholipase activity which leads to increased PAF synthesis. The 1-alkyl glycerophosphocholine acetyltransferase activity is quite small in brain in comparison with the de novo acetyltransferase activity, and is also controlled by phosphorylation. Evidence has been presented for the actions of both pathways in brain, in response to biologically relevant stimulation pertinent to the disease state.
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PMID:Enzymes of platelet activating factor synthesis in brain. 878 21

The mammalian heart is normally well oxygenated and anaerobic glycolysis is extremely rare except for the production of extra ATP during extreme exercise like a marathon race. Anaerobic glycolysis plays a role when there is a serious impairment in coronary blood flow such as during heart attack and open heart surgery. The control of glycolysis in ischemic myocardial tissue appears to be extremely complex. During aerobic glycolysis, phosphofructokinase is the most important regulatory enzyme that controls the energy requirements of the cell. Under anaerobic conditions, however, glyceraldehyde-3-phosphate dehydrogenase becomes the key enzyme because it responds promptly to any changes in the essential supply of co-factors for oxidation. The conversion of pyruvate to acetyl CoA (aerobic metabolism) involves a series of chain reactions primarily catalyzed by pyruvate dehydrogenase complex which is situated at the cross roads between both aerobic and anaerobic glycolysis. It is important to remember that substrate utilization is carefully controlled by substrate availability. During aerobic metabolism, control mechanisms using fatty acids, lactate and glucose as energy substrates regulate the rate of ATP production according to energy demand. This precise mechanism is upset during ischemia and post-ischemic reperfusion for reasons discussed in this review. The demand for ATP can no longer be met by its supply because of severely reduced anaerobic glycolysis and significantly inhibited beta-oxidation of fatty acids. The impairment of bioenergetics is discussed in the context of several diseases such as cardiomyopathy, heart failure, diabetes, arrhythmias, cardiac surgery, heart-lung transplantation, and also in aging and oxidative stress. The regulation of energy metabolism in preconditioned heart is also discussed. Finally, methods used to preserve energy in ischemic myocardium are summarized and quantitation of the high-energy phosphates is discussed. This review challenges scientists to discover drugs which will stimulate energy supply during myocardial ischemia.
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PMID:Bioenergetics, ischemic contracture and reperfusion injury. 880 94

The activities of enzymes in platelet activating factor (PAF) biosynthetic pathways were analyzed in hippocampal and cerebral cortical regions of normal and ischemic gerbil brain to assess changes in enzyme activities and potential modulators that could explain the accentuated production of PAF seen in ischemia. Global forebrain ischemia was produced by bilateral carotid artery ligation, and the effectiveness of the ligation was shown by free fatty acid release and ATP depletion. Specific activities of 1-alkyl-2-acetyl-sn-glycerol (AAG) choline phosphotransferase, 1-alkyl-sn-glycero-3-phosphate (AGP) acetyl transferase, and 1-alkyl-sn-glycero-3-phosphocholine (lyso PAF) acetyl transferase in tissue homogenates were in the ratio 4:1:0.1, respectively. Sham-operated and ischemic or ischemic-reperfused tissues showed similar activities for individual enzymes, indicating that enzyme levels or activation states did not change in ischemic or reperfused tissues. However, small metabolites (relevant to ischemia) added to the in vitro assays did modify enzyme activities. Physiological concentrations of MgATP severely inhibited AGP acetyl transferase activity, and this resulted in the ratio of AGP acyl transferase to AGP acetyl transferase activities changing from 48:1 in the presence of 2.5 mM MgATP to 6:1 in the absence of MgATP. This suggests that falling ATP levels in cerebral ischemia may promote the de novo pathway of PAF biosynthesis by releasing inhibition of AGP acetyl transferase. Lyso PAF acetyl transferase was much less active than AGP acetyl transferase and was also inhibited by MgATP. AAG choline phosphotransferase was not inhibited by MgATP but was inhibited by calcium. However the superior specific activity of the choline phosphotransferase in comparison with the AGP acetyl transferase suggested that the lowered choline phosphotransferase activity in the presence of rising intracellular calcium would not seriously compromise the synthesis of PAF by the de novo route. Both acetyl transferase enzymes were also inhibited by oleoyl CoA.
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PMID:Activities of enzymes in platelet activating factor biosynthetic pathways in the gerbil model of cerebral ischemia. 888 40


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