UMLS:C0003129 - FACTA Search

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Query: UMLS:C0003129 (Anoxia)
551 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Effects of glucose concentration and anoxia upon the metabolite concentrations and rates of glycolysis and respiration have been investigated in the perfused liver of the fetal guinea pig. In most cases the metabolite concentrations in the perfused liver were similar to those observed in vivo. Between 50 days and term there was a fall in the respiratory rate and in the concentration of ATP and fructose 1,6-diphosphate and an increase in the concentration of glutamate, glycogen and glucose. Reducing the medium glucose concentration from 10 mM to 1 mM or 0.1 mM depressed lactate production and the concentration of most of the phosphorylated intermediates (except 6-phosphogluconate) in the liver of the 50-day fetus. This indicates a fall in glycolytic rate which is not in accord with the known kinetic properties of hexokinase in the fetal liver. Anoxia increased lactate production by, and the concentrations of, the hexose phosphates ADP and AMP in the 50-day to term fetal liver, while the concentration of ribulose 5-phosphate, ATP and some triose phosphates fell. These results are consistent with an activation of glycolysis, particularly at phosphofructokinase and of a reduction in pentose phosphate pathway activity, particularly at 6-phosphogluconate dehydrogenase. The calculated cytosolic NAD+/NADH ratio for the perfused liver was similar to that measured in vivo and evidence is presented to suggest that the dihydroxyacetone phosphate/glycerol 3-phosphate ratio gives a better indication of cytosolic redox than the lactate/pyruvate ratio. The present observations indicate that phosphofructokinase hexokinase and possibly pyruvate kinase control the glycolytic rate and that glyceraldehyde-3-phosphate dehydrogenase is at equilibrium in the perfused liver of the fetal guinea pig.
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PMID:Some effects of glucose concentration and anoxia on glycolysis and metabolite concentrations in the perfused liver of fetal guinea pig. 2 74

Cellular high-energy phosphate levels and 42K exchange were studied in isolated, interventricular rabbit septa at 28 degrees C. Septa were perfused with a modified Tyrode solution that contained glucose as the metabolic substrate. Anoxia was induced by switching to solution equilibrated with N2-CO2 gas. Potassium lost during anoxia by increased efflux from the cells was measured by 42K. Whole tissue levels of ATP, ADP, phosphocreatine, and total creatine were determined. The effects of 20-min anoxic stresses were evaluated in each of four groups of septa: 1) control (perfused with regular solution and paced at 42 excitations/min; 2) E-C uncoupled (by perfusing with solution containing 50 micron Ca2+); 3) quiescent (spontaneous contraction rate less than 1/min); and 4) perfused with high glucose solution (20 mM). Compared to the control group, only quiescence significantly decreased the potassium loss during anoxia; the cellular energetic state was well maintained during stress by both E-C uncoupling and quiescence. The results indicate that the increase in potassium efflux during brief anoxic stress is largely excitation dependent and can be dissociated from contraction and cellular energetic state.
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PMID:Dissociation of energetic state and potassium loss from anoxic myocardium. 72 75

In isolated perfused rabbit hearts, coronary vasodilation, produced by reduced oxygen tension seems to be independent of myocardial prostaglandin biosynthesis. a) Anoxia (N2: CO2 95: 5 %) produced coronary vasodilation without causing prostaglandin-like substance (PLS) biosynthesis and release; b) the decrease in coronary resistance during hypoxia (N2:02:CO2 - 80:15:5 %) was sustained during myocardial perfusion with the low oxygen media despite the transitory nature of its PLS release; and c) indomathacin, which abolished basal or ADP stimulated myocardial PLS release, did not abolish the coronary vasodilation produced by ischemia, hypoxia, or anoxia.
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PMID:Relationship between oxygen tension, coronary vasodilation and prostaglandin biosynthesis in the isolated rabbit heart. 113 23

The glycolytic enzymes glycogen phosphorylase, phosphofructokinase (PFK), and pyruvate kinase (PK) were assessed in liver, heart, red muscle, and white muscle of aerobic and 5-h anoxic turtles (Pseudemys scripta) for changes in total activity and kinetic parameters. Anoxia induced statistically significant changes in these glycolytic enzymes in each of the four organs assayed. Compared with normoxic controls, anoxic liver showed a 3.3-fold increase in glycogen phosphorylase activity, a 1.5-fold increase in the PFK I50 value for citrate (concentration that inhibits initial activity by 50%), a 1.5-fold increase in the PFK Michaelis constant (Km) value for fructose 6-phosphate (P), and an increased maximal activity of PK. Anoxic heart muscle showed a 2.6-fold decrease in glycogen phosphorylase activity and, for PFK, a 1.7-fold decrease in the Km value for ATP and a twofold increase in the I50 value for citrate. In anoxic white muscle, PFK showed a fivefold lower Km value for fructose-6-P and a threefold lower activator concentration producing half-maximal activation (A50) for potassium phosphate than the aerobic enzyme form. Changes in anoxic white muscle PK included a twofold increase in the Km value for ADP and a 1.7-fold decrease in the I50 value for alanine. In red muscle, anoxia affected only the Km value for ATP, which was 50% higher than the value for the aerobic enzyme form. Fructose 2,6-diphosphate (P2) levels also decreased in heart muscle and increased in red and white muscle during anoxia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Regulation of glycolytic enzymes during anoxia in the turtle Pseudemys scripta. 252 74

Isometric twitch tension of ventricular preparations stimulated at 0.2 Hz fell over 30 min of anoxia by a fraction decreasing in the order rainbow trout, cod, eel, and freshwater turtle. Drops in the estimated cytoplasmic energy state were related to larger tension losses for trout than for the other species, possibly due to larger changes in free phosphate. Anoxic energy degradation was slower for turtle than for the other species. Anoxia combined with glycolytic inhibition (1 mmol/l iodoacetate) enhanced the decrease in twitch tension for a drop in energy state and enlarged the increase in ADP/ATP relative to that in creatine/phosphocreatine to an extent inversely related to the creatine kinase activity. Furthermore, it increased resting tension to an extent possibly related to myosin-adenosinetriphosphatase (ATPase) activity and lowered the content of phosphorylated adenylates in trout and turtle myocardium. The results indicate that species differences in performance of the metabolically challenged myocardium depend on energy-degrading processes, e.g., myosin-ATPase activity, phosphate release, creatine kinase activity, and efflux/degradation of ADP and AMP, and that glycolysis offers protection due to its cytoplasmic localization.
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PMID:Cardiac force and high-energy phosphates under metabolic inhibition in four ectothermic vertebrates. 889 86

Rat liver mitochondria were exposed to extramitochondrial free calcium between 0 and 5 microM and/or 5 minutes of anoxia followed by 10 minutes of reoxygenation. At concentrations higher than 4 microM, the membrane potential collapsed indicating the permeability transition of the mitochondrial membrane. Anoxia-reoxygenation shifted this transition to lower calcium concentrations. Anoxia-reoxygenation alone resulted in the decrease of ADP stimulated respiration down to about 40% of its initial value. Between 1 and 2 microM, a protective effect in terms of respiration and oxidative protein modification was found. It is concluded that calcium may suppress the formation of reactive oxygen species during anoxia-reoxygenation before permeability transition occurs.
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PMID:Micromolar calcium prevents isolated rat liver mitochondria from anoxia-reoxygenation injury. 931 80

Anoxia/reoxygenation injury of isolated rat liver mitochondria was investigated. During anoxia of up to 60 min, the membrane potential was largely preserved and mitochondrial swelling was not observed. Reoxygenation of anoxic mitochondria rapidly caused swelling, cyclosporin A-sensitive Ca2+ efflux, [14C]sucrose trapping, and loss of the membrane potential along with increased generation of reactive oxygen intermediates (ROI). Although pretreatment with catalase and superoxide dismutase completely abolished reoxygenation-induced generation of ROI, mitochondrial damage was not prevented, as indicated by swelling, loss of the membrane potential, a decrease of the ATP content, and cyclosporin A-sensitive Ca2+ efflux. However, addition of the immunosuppressant cyclosporin A or addition of ADP completely prevented the mitochondrial damage induced by reoxygenation. The same protective effect was noted when Ca2+ cycling was prevented, either by chelating Ca2+ with EGTA or by inhibiting Ca2+ reuptake with ruthenium red. These findings indicate that mitochondrial anoxia/reoxygenation injury is caused by the cyclosporin A-sensitive and Ca2+-dependent membrane permeability transition. In contrast, reoxygenation injury does not appear to be triggered by the enhanced production of ROI.
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PMID:Reoxygenation-induced mitochondrial damage is caused by the Ca2+-dependent mitochondrial inner membrane permeability transition. 965 18

The present study investigated the protective effects of Ginkgo biloba extract (EGb 761) on rat liver mitochondrial damage induced by in vitro anoxia/reoxygenation. Anoxia/reoxygenation was known to impair respiratory activities and mitochondrial oxidative phosphorylation efficiency. ADP/O (2.57 +/- 0.11) decreased after anoxia/reoxygenation (1.75 +/- 0.09, p < .01), as well as state 3 and uncoupled respiration (-20%, p < .01), but state 4 respiration increased (p < .01). EGb 761 (50-200 microg/ml) had no effect on mitochondrial functions before anoxia, but had a specific dose-dependent protective effect after anoxia/reoxygenation. When mitochondria were incubated with 200 microg/ml EGb 761, they showed an increase in ADP/O (2.09 +/- 0.14, p < .05) and a decrease in state 4 respiration (-22%) after anoxia/reoxygenation. In EPR spin-trapping measurement, EGb 761 decreased the EPR signal of superoxide anion produced during reoxygenation. In conclusion, EGb 761 specially protects mitochondrial ATP synthesis against anoxia/reoxygenation injury by scavenging the superoxide anion generated by mitochondria.
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PMID:EGb 761 protects liver mitochondria against injury induced by in vitro anoxia/reoxygenation. 1049 Feb 80

We evaluated the effects of freezing, dehydration and anoxia stresses on muscle PP-1 activity in the freeze-tolerant amphibian, Rana sylvatica. In addition, PP-1 catalytic subunit (PP-1c) was purified to homogeneity to assess the biochemical properties of the enzyme from a freeze-tolerant vertebrate. Freezing stimulated a rise in the amount of active PP-1 (70% above the control) at 20 min post-nucleation. With longer freezing (1-12 h), the amount of active enzyme returned to control levels, and the amount of total PP-1 fell, decreasing by up to 43%. This decline in total PP-1 kept the % active at a high value throughout the freeze. Anoxia exposure (12 h) reduced the active PP-1 by 60%, but had no effect on total PP-1 activity. Neither dehydration nor rehydration had any significant effect on the amounts of either total or active PP-1. PP-1 activity associated with the myofibril fraction increased, while activity associated with the glycogen pellet decreased in response to freezing and dehydration, but not anoxia. Purified frog PP-1c showed a variety of properties that are typical of the enzyme from other sources. In addition, the enzyme was strongly inhibited by AMP and weakly by ADP and ATP; the physiological relevance of inhibition by nucleotides remains to be determined. Overall, the results suggest an important role for PP-1 in signal transduction in the skeletal muscle of freeze-tolerant amphibians.
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PMID:Protein phosphatase type-1 from skeletal muscle of the freeze-tolerant wood frog. 1174 55

The role of ATP in anoxic activation of ATP-sensitive K+ (KATP) channels was studied in dorsal vagal neurons of mouse brainstem slices. In the whole-cell configuration, cyanide-induced chemical anoxia evoked within 10 s a 300-pA outward current that gave rise to a hyperpolarization of 24 mV. These responses were mimicked by nitrogen-aerated saline, rotenone or diazoxide and abolished by tolbutamide. The cyanide-induced hyperpolarization was due to activation of 70 pS K(ATP) channels that were half-maximally blocked by 5 microM internal ATP. Dialyzing the cells with either 1, 20 or 0 mM ATP did not, however, affect the time to onset, the kinetics or the magnitude of the cyanide-induced hyperpolarization. Impairment of ATP consumption by ouabain, vanadate or reduced temperature had no effect either. Thus, anoxia-induced activation of these KATP channels cannot be explained by a fall of cellular ATP or a concomitant rise of ADP. Anoxia-related changes of the actin cytoskeleton or the composition of the plasma membrane are also not likely to be involved, as cytochalasin D did not affect the cyanide-evoked hyperpolarization and phosphatidylinositol 4,5-bisphosphate failed to decrease the ATP sensitivity of single KATP channels. Finally, because of a lack of effects of reduced/oxidized glutathione and the oxidase blocker diphenyliodonium on the cyanide-induced hyperpolarization, cellular redox state does not appear to be involved. Our results indicate that despite a high sensitivity to ATP in excised patches, anoxic activation of KATP channels is independent of cellular ATP. Rather the ATP block seems to be removed as a consequence of impaired mitochondrial function.
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PMID:ATP-independent anoxic activation of ATP-sensitive K+ channels in dorsal vagal neurons of juvenile mice in situ. 1180 67

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