Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Adenine nucleotides and respiration were assayed with rat kidney mitochondria depleted of adenine nucleotides by pyrophosphate treatment and by normothermic ischemia, respectively, with the aim of identifying net uptake of ATP as well as elucidating the contribution of adenine nucleotide loss to the ischemic impairment of oxidative phosphorylation. Treatment of rat kidney mitochondria with pyrophosphate caused a loss of adenine nucleotides as well as a decrease of state 3 respiration. After incubation of pyrophosphate-treated mitochondria with ATP, Mg2+ and phosphate, the content of adenine nucleotides increased. We propose that kidney mitochondria possess a mechanism for net uptake of ATP. Restoration of a normal content of matrix adenine nucleotides was related to full recovery of the rate of state 3 respiration. A hyperbolic relationship between the matrix content of adenine nucleotides and the rate of state 3 respiration was observed. Mitochondria isolated from kidneys exposed to normothermic ischemia were characterized by a decrease in the content of adenine nucleotides as well as in state 3 respiration. Incubation of ischemic mitochondria with ATP, Mg2+ and phosphate restored the content of adenine nucleotides to values measured in freshly-isolated mitochondria. State 3 respiration of ischemic mitochondria reloaded with ATP recovered only partially. The rate of state 3 respiration increased by ATP-reloading approached that of uncoupler-stimulated respiration measured with ischemic mitochondria. These findings suggest that the decrease of matrix adenine nucleotides contributes to the impairment of ischemic mitochondria as well as underlining the occurrence of additional molecular changes of respiratory chain limiting the oxidative phosphorylation.
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PMID:The contribution of adenine nucleotide loss to ischemia-induced impairment of rat kidney cortex mitochondria. 130 55

Skeletal muscle ischemia results in energy depletion and intracellular acidosis. Reperfusion is associated with impaired adenine nucleotide resynthesis, edema formation, and myocyte necrosis. The purpose of these studies was to define the time course of cellular injury and adenine nucleotide depletion and resynthesis in postischemic skeletal muscle during prolonged reperfusion in vivo. The isolated canine gracilis muscle model was used. After 5 h of ischemia, muscles were reperfused for either 1 or 48 h. Lactate and creatine phosphokinase (CPK) release during reperfusion was calculated from arteriovenous differences and blood flow. Adenine nucleotides, nucleosides, bases, and creatine phosphate were quantified by high-performance liquid chromatography, and muscle necrosis was assessed by nitroblue tetrazolium staining. Reperfusion resulted in a rapid release of lactate, which paralleled the increase in blood flow, and a delayed but prolonged release of CPK. Edema formation and muscle necrosis increased between 1 and 48 h of reperfusion (P less than 0.05). Recovery of energy stores during reperfusion was related to the extent of postischemic necrosis, which correlated with the extent of nucleotide dephosphorylation during ischemia (r = 0.88, P less than 0.001). These results suggest that both adenine nucleotide resynthesis and myocyte necrosis, which are protracted processes in reperfusing skeletal muscle, are related to the extent of nucleotide dephosphorylation during ischemia.
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PMID:Prolonged adenine nucleotide resynthesis and reperfusion injury in postischemic skeletal muscle. 159 Apr 58

The quantification of adenine nucleotides released from the heart is hampered by their rapid dephosphorylation to adenosine in the extracellular space catalyzed by highly active ectonucleotidases. To determine the total release of adenine nucleotides from isolated Langendorff-perfused guinea pig hearts, ecto 5'-nucleotidase was effectively blocked by infusion of alpha, beta-methylene-ADP (AOPCP, 50 microM). Adenine nucleotides were measured in the coronary venous effluent by the luciferin-luciferase method after enzymatic rephosphorylation to ATP. In hearts perfused at a constant flow rate (10 ml/min) with normoxic buffer (95% O2, 5% CO2) the release +/- SEM of adenine nucleotides and adenosine was 0.06 +/- 0.01 (n = 11) and 0.04 +/- 0.01 (n = 13) nmol/min. In the presence of AOPCP, the release of adenine nucleotides increased to 0.43 +/- 0.04 nmol/min (n = 9; p less than 0.05), whereas adenosine remained unchanged. Hypoxic perfusion (10% O2, 85% N2, 5% CO2) caused a threefold increase in adenine nucleotide release but a 40-fold increase in adenosine. In contrast, global ischemia (30 seconds) caused adenine nucleotide and adenosine release to rise to similar values of 1.06 +/- 0.10 and 0.80 +/- 0.14 nmol/min (n = 9). Stimulation of hearts with isoproterenol (4 nM) likewise increased the release of adenine nucleotides (0.50 +/- 0.04 nmol/min) and adenosine (0.87 +/- 0.21 nmol/min) (n = 6). To determine the cellular source of adenine nucleotides released from the heart, the coronary endothelial adenine nucleotide pool was selectively prelabeled by [3H]adenosine. Global ischemia increased the specific radioactivity of released adenine nucleotides by 57%. The findings indicate that 1) adenine nucleotides and adenosine are released at the same order of magnitude from the well-oxygenated heart; 2) beta-adrenergic stimulation and ischemia stimulate the release of adenine nucleotides and adenosine, both purines reaching vasoactive concentrations in the effluent perfusate; 3) during hypoxic perfusion only the release of adenosine is greatly enhanced; and 4) the coronary endothelium preferentially contributes to the ischemia-induced adenine nucleotide release.
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PMID:Adenine nucleotide release from isolated perfused guinea pig hearts and extracellular formation of adenosine. 174 67

Using Langendorff rat hearts, we tested whether 1. adenosine as a cardioplegic agent, and 2. inosine administered during reperfusion could prevent and treat ischemic injury, respectively. For cardioplegic arrest (37 degrees C), buffer supplemented with 20 mM K+ (K), K + 1 mM adenosine (KA), or none (Control, C), was infused for 3 min at 3 ml/min. Arrest time was 260 +/- 16 s (C), 22 +/- 4 s (K) and 10 +/- 2 s (KA, p less than 0.02 vs K). During 20 min total ischemia, resting tension increased only in C, and remained elevated after 20 min reperfusion. In treated hearts resting tension rose somewhat and returned to baseline. Developed tension: heart rate (g/min) after reperfusion was superior with KA:C (3,180 +/- 830), K (4,380 +/- 390), and KA (6,250 +/- 740, p less than 0.05 vs. K.). Our electrophysiological studies suggest that adenosine increases K(+)-permeability and thereby arrests the sinus node. It did not affect high-energy phosphates. We also tested whether inosine could regenerate nucleotides. We perfused hearts with buffer containing glucose +/- pyruvate. After 15 min no-flow, hearts were reperfused for 45 min with 20 microM inosine and 0.5 mM ribose. Adenine nucleotide levels tended to recover better in the purine-treated groups. Inosine decrease the ATP/ADT ratio by 15% (p less than 0.05) and increased the IMP level 2 times (p less than 0.01) whom pyruvate was absent. It increased the effluent adenosine concentration 6 times (p less than 0.005). Inosine administration +/- pyruvate did not affect function recovery, heart rate or coronary flow. Thus adenosine as adjunct to K(+)-cardioplegia shortened arrest time, and was also beneficial for post-ischemic recovery. Inosine given during reperfusion failed to improve heart function. Both treatments hardly affected cardiac adenine nucleotide levels.
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PMID:Prevention and treatment of ischemic injury with nucleosides. 202 58

Reports on enhanced nucleotide regeneration by purines during reperfusion are conflicting. We have, therefore, evaluated the effects of inosine or adenine, administered after ischemia, on adenine nucleotide levels and function in isolated rat hearts. The hearts were perfused with a Tyrode solution, containing 10 mM D-glucose, with or without 5 mM pyruvate. After 15 minutes without flow, the hearts were reperfused for 45 minutes with 20 microM purine and 0.5 mM D-ribose. Adenine nucleotide levels tended to recover better in the purine-treated groups. The purines decreased the ATP/ADP ratio by 10-15% (p less than 0.05) if pyruvate was absent. The IMP level in the inosine/glucose group exceeded that in all other groups by a factor of two (p less than 0.001). Inosine increased the adenosine concentration in the effluent sixfold (p less than 0.005). The hypoxanthine concentration rose up to four times following adenine treatment (p less than 0.05). The administration of purine, with or without pyruvate, did not affect mechanical recovery, heart rate or coronary flow. We conclude that inosine and adenine failed to improve cardiac function and hardly affected nucleotide levels in the reperfused heart.
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PMID:Effects of inosine and adenine on nucleotide levels in the post-ischemic rat heart, perfused with and without pyruvate. 210 91

The lower extremity may be exposed to prolonged periods of ischemia, resulting in depletion of intracellular energy stores in the affected skeletal muscle. The role of adenine nucleotide reduction and failure of resynthesis on reperfusion in determining the extent of muscle necrosis was investigated in this study, in addition to the possible beneficial effects of the addition of exogenous adenosine triphosphate-magnesium chloride during early reperfusion. The isolated paired canine gracilis muscle model was used. After 4 hours of normothermic ischemia in group I, a perfusate Krebs-Henseleit solution plus the gradual reintroduction of oxygenated blood flow was compared to standard reperfusion. In group II, a similar infusion protocol was used, with the addition of 2 mmol/L adenosine triphosphate-magnesium chloride and compared to normal reperfusion. Adenosine triphosphate-magnesium chloride resulted in the salvage of skeletal muscle, 57% +/- 12% versus 44% +/- 14% (p less than 0.05, n = 6 pairs). Reperfusion with the solution alone increased the resulting necrosis (42% +/- 13% vs 60% +/- 20%, n = 6 pairs). Adenine nucleotide stores were not increased, but oxygen consumption was increased by magnesium chloride-adenosine triphosphate (p less than 0.05, analysis of variance [ANOVA]). A clear relationship was demonstrated between the fall in energy stores, as measured by a change in energy charge potential from preischemia to end ischemia levels, and the extent of resulting necrosis (p less than 0.01). In summary, the addition of 2 mmol/L to an infusion of Krebs-Henseleit solution during reperfusion results in significant salvage of skeletal muscle.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Exogenous magnesium chloride-adenosine triphosphate administration during reperfusion reduces the extent of necrosis in previously ischemic skeletal muscle. 231 33

Isolated adult rat myocytes were used to develop an in vitro model of myocardial ischemia. Freshly isolated myocytes were spun into a cell pellet to limit extracellular volume. Excess supernatant was removed and the pellet was covered with mineral oil and incubated in a temperature controlled water bath. After various periods of incubation, cells were analyzed for adenine nucleotide levels, lactate accumulation, rate of cell death, and cell morphology. Adenine nucleotide profiles after 60 min incubation at 37 degrees C showed marked depletion of adenosine triphosphate (ATP) and large increases in adenosine monophosphate (AMP), adenosine, inosine, and lactate and no significant difference in levels of inosine monophosphate. These results are consistent with ischemic conditions. Reduction of the incubation temperature to 34 and 30 degrees C slowed the rate of cell squaring and the onset of cell death. Resuspension of ischemic cells after 30, 45, 60 and 90 min incubation in hypotonic buffer (170 mosmol) to induce acute cell swelling caused an increase in the number of non-viable cells at each time point. Control cells and ischemic cells incubated less than 30 min did not show increases in non-viable cells when subjected to hypotonic swelling. Morphological analysis revealed that isolated myocytes respond to ischemia in a heterogeneous fashion and exhibit changes at both light and electron microscopic levels similar to those seen in other ischemic models. These results indicate that pelleted isolated adult rat myocytes may be a useful in vitro model to study myocardial ischemic cells injury.
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PMID:An in vitro model of myocardial ischemia utilizing isolated adult rat myocytes. 232 36

Unilateral ischemia in the right cerebral hemisphere of the rat was induced by ligation of the right common carotid artery coupled with controlled hemorrhage to produce hypotension (25 +/- 8 mm/Hg). Where indicated after 30 min of ischemia, the withdrawn blood was reinfused to restore arterial pressure to normal. Mitochondria isolated from the ipsilateral hemisphere after 30 min of ischemia showed significantly lower respiratory rates than the organelles isolated from the contralateral side. Oxidation of NAD(+)-linked substrates was more sensitive to inhibition in ischemia (30%) than was of ferrocytochrome c (12%), succinate oxidation being intermediate. The activities of membrane-bound dehydrogenases (both NADH and succinate-linked) were also significantly lowered. Ischemia did not affect the cytochrome content of mitochondria. Respiratory activity (NAD(+)-linked) of mitochondria isolated from the ipsilateral hemisphere was twice as sensitive to inhibition by fatty acid as was of preparations from the contralateral side. Mitochondria isolated from cerebral cortex after 90 min of post-ischemic reperfusion showed no significant improvement in the rate of substrate oxidation. Adenine nucleotide translocase activity and energy-dependent Ca2+ uptake, both of which decreased significantly in mitochondria isolated from the ischemic brain, showed little recovery, on reperfusion. These observations suggested the strong possibility that the deleterious effects of ischemia on mitochondrial respiratory function might be mediated by free fatty acids that are known to accumulate in large amounts in ischemic tissues. The pattern of inhibition of ATPase activity was consistent with this view.
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PMID:Influence of cerebral ischemia and post-ischemic reperfusion on mitochondrial oxidative phosphorylation. 234 84

The purpose of this study was to assess how brief periods of intermittent reperfusion (IR) imposed during a renal ischemic insult affect adenine nucleotide/catabolite concentrations, oxidant stress, and the severity of ischemic acute renal failure (IARF). Rats were subjected to 35 minutes of renal pedicle occlusion with or without brief IR periods (total less than or equal to 3 minutes). Adenine nucleotides and their catabolites were measured at the end of ischemia and at 30 minutes of the recovery period. Oxidant stress in the recovery phase was assessed by non-protein-bound sulfhydryl and malondialdehyde (MDA) concentrations. The severity of IARF was quantified at 24 hours by degrees of azotemia and histologic damage. Although IR had no significant impact on end-ischemic ATP concentrations, it did induce profound adenine nucleotide catabolite depletion; the sum of adenosine, inosine, inosine monophosphate, hypoxanthine, and xanthine fell by 78%, compared with control ischemia values (p less than 0.001). The pattern of IR affected the degree of catabolite depletion: dividing a single 3-minute IR period into two 1 1/2-minute segments increased catabolite loss by 45% without affecting adenine nucleotide content. Although adenine nucleotide catabolites can be resynthesized to ATP, IR did not worsen postischemic adenine nucleotide recovery. IR augmented postischemic sulfhydryl depletion by 8% (p less than 0.02). However, lipid peroxidation (as assessed by MDA) did not result and the severity of IARF was not adversely affected.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Brief intermittent reperfusion during renal ischemia: effects on adenine nucleotides, oxidant stress, and the severity of renal failure. 234 58

Adenine nucleotide metabolism is greatly altered by myocardial anoxia or ischemia, both of which induce depletion of ATP and of the total adenine nucleotide pool. The depletion occurs at variable rates depending upon the nature of the model and the severity and conditions of the injury. In ischemia, the decrease in both ATP and the adenine nucleotide pool is due to an inadequate rate of production of high-energy phosphate relative to the demand of the heart for energy. In the process of capturing the high-energy phosphate of ADP, AMP is produced via myokinase and is degraded to nucleosides and ultimately to bases. In the early phase of ischemia, ADO and INO are the chief metabolites produced. A small quantity of XAN and large quantities of HX accumulate with time until eventually HX replaces INO as the principal metabolite of the pool. The biology of myocardial ischemic cell damage in the dog heart is summarized with respect to the depletion of ATP and total adenine nucleotide pool. Myocytes can survive with about 25% of the ATP of control tissue but exhibit a variety of defects that persist for minutes to days. At the onset of irreversibility, the dead tissue invariably exhibits virtually no ATP and a 65% or greater depletion in the total adenine nucleotide pool. It is not known whether these changes in ATP and the pool are directly or indirectly related to the development of irreversibility. In any event, the transition to cell death appears to be gradual.
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PMID:Nucleotide metabolism and cellular damage in myocardial ischemia. 258 8


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