EC:1.6.5.3 - FACTA Search

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Query: EC:1.6.5.3 (complex I)
8,901 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The effect of acute respiratory hypoxia in rats on mitochondrial respiration, adenine nucleotides and some amino acids of the heart was studied. The decrease in the total (ATP + ADP + AMP) and exchangeable (ATP + ADP) adenine nucleotide pool of the mitochondria was accompanied by a pronounced loss of state 3 respiration with glutamate plus malate and a slight decrease with succinate plus rothenone. The uncoupled respiration of mitochondria with glutamate and malate was decreased in the same degree as in the absence of 2,4-dinitrophenol. State 4 respiration with substrates of both types was unaffected by hypoxia. These data point to a hypoxia-induced impairment of complex I of the respiratory chain. The decrease of tissue and mitochondrial glutamate was accompanied by the elevation of alanine content in the heart and an increase in intramitochondrial aspartate. The ADP-stimulated respiration of mitochondria was correlated with mitochondrial glutamate and ATP as well as with exchangeable adenine nucleotide pools during hypoxia. The experimental results suggest that mitochondrial dysfunction induced by hypoxia may also be attributed to the low level of mitochondrial glutamate.
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PMID:[Relation between glutamate and adenine nucleotide levels of heart mitochondria during hypoxia]. 359 88

The effect of asphyxia and subsequent resumption of respiration on the content of adenine nucleotides and some amino acids in heart tissue and mitochondria, as well as respiration of heart mitochondria was studied in rats. The depression of cardiac contractile function during asphyxia showed a better correlation with losses in mitochondrial adenine nucleotides (ATP + ADP + AMP) than those in cardiac tissue. The decrease in the heart work index was accompanied by a decrease in state 3 respiration with glutamate and malate as well as uncoupled respiration with these substrates. This did not occur with succinate. Nonphosphorylating (state 4) respiratory rates and ADP/O ratios were slightly affected by asphyxia, when respiratory substrates of both types were used. The decreased level of glutamic acid in the tissue and mitochondria of asphyxic hearts was simultaneously observed with a significant increase of alanine in cardiac tissue and of aspartic acid in the mitochondria. The losses of intramitochondrial ATP and respiratory activity with NAD-dependent substrates during asphyxia were associated with a reduction of glutamic acid level in mitochondria. The recovery of cardiac function during resumption of respiration was related to the restoration of mitochondrial respiration supported by glutamate and malate, as well as to the restoration of mitochondrial adenine nucleotides and glutamic acid. The results suggest that the depression of cardiac function caused by acute respiratory hypoxia may be attributed to impairment of electron transport, particularly in complex I of the respiratory chain and changes in metabolism of glutamic acid.
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PMID:The relationship between the cardiac contractile function, adenine nucleotides and amino acids of cardiac tissue and mitochondria at acute respiratory hypoxia. 361 64

The effect of acute hypoxia on adenine nucleotides, glutamate, aspartate, alanine and respiration of heart mitochondria was studied in rats. The losses of intramitochondrial adenine nucleotides (ATP+ADP+AMP) during hypoxia were related to depression of state 3 respiration supported by glutamate and malate, as well as decrease in uncoupled respiration. Hypoxia had less prominent effect on succinate-dependent state 3 respiration. Non-phosphorylating (state 4) respiratory rates and ADP/O ratios were slightly affected by oxygen deprivation. Glutamate fall in tissue and mitochondria of hypoxic hearts was concomitant with significant increase in tissue alanine and mitochondrial aspartate. The losses of intramitochondrial ATP and respiratory activity with NAD-dependent substrates during hypoxia were related to a decrease in mitochondrial glutamate. The results suggest that hypoxia-induced impairment of complex I of respiratory chain and a loss of glutamate from the matrix may limit energy-producing capacity of heart mitochondria.
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PMID:Adenine nucleotides, glutamate and respiratory function of heart mitochondria during acute hypoxia. 375 8

Mitochondrial dysfunction in ischemic liver has been demonstrated to be due to decrease in the intramitochondrial level of ATP and the subsequent disruption of the proton barrier of the inner membrane (Watanabe, F., Hashimoto, T. and Tagawa, K. (1985) J. Biochem. 97, 1229-1234). In this study, another injury process, impairment of the electron-transfer system, which occurred during reoxygenation of ischemic liver, was studied during reperfusion of cold preserved liver and during cold incubation of isolated rat-liver mitochondria. The sites of the respiratory chain that were sensitive to peroxidative damage were ubiquinone-cytochrome c oxidoreductase and NADH-ubiquinone oxidoreductase. These enzymic activities decreased with increase in lipid peroxidation. Incubation of submitochondrial particles with t-butyl hydroperoxide or with an NADPH-dependent peroxidation system decreased the enzymic activities of the electron-transport system. These data strongly suggested that lipid peroxidation during reoxygenation of ischemic liver impaired the electron-transfer system. Thus, mitochondria of ischemic liver suffer from two different types of injury: increase in proton permeability during anoxia, and decrease in enzymic activities of the electron-transport system during reoxygenation.
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PMID:Peroxidative injury of the mitochondrial respiratory chain during reperfusion of hypothermic rat liver. 380 61

An animal model for the human condition of mitochondrial myopathy has been established and characterized physiologically and biochemically. The NADH: coenzyme Q reductase inhibitor diphenyleneiodonium [Bloxham (1979) Biochem. Soc. Trans. 7, 103-106] was either infused acutely in vivo into rat hind limb or injected chronically into rats. Both modes of delivery resulted in a reduced muscle oxidative capacity and increased fatigue. Analysis of muscle metabolites by h.p.l.c. and 31P-n.m.r. indicated that ATP concentrations were similar to control values during periods of stimulation and these were maintained by the phosphocreatine pool. During the recovery period after muscle stimulation in the experimental animals the muscle pH remained depressed and the rate of phosphocreatine synthesis was markedly delayed as compared with controls. Factors thought to be involved in the fatigue response are discussed in relation to this model.
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PMID:Experimentally induced defects of mitochondrial metabolism in rat skeletal muscle. Biological effects of the NADH: coenzyme Q reductase inhibitor diphenyleneiodonium. 392 66

Submitochondrial particles prepared from liver and skeletal muscle of control and iron-deficient rats were examined for cytochrome content and for both energy-independent and energy-conserving functions. Liver submitochondrial particles appear quite resistant to iron deficiency with cytochrome content and electron-transferring or energy-conserving functions maintained at a level of 85% or better of normal. Iron-deficient skeletal muscle submitochondrial particles, in contrast, have decreased cytochrome content and only 15-20% of the normal capacity for oxidation through either complex I (NADH dehydrogenase) or complex II (succinate dehydrogenase). Energy-linked reactions which involve substrate oxidation/reduction (succinate----NAD+ reversed electron flow and succinate-driven energy-dependent transhydrogenation) are likewise markedly decreased, while ATP-driven energy-dependent transhydrogenation and mitochondrial ATPase are normal. Our data support the concept that iron deficiency leads to decreased electron-carrying capacity of iron-containing mitochondrial enzymes, with skeletal muscle being much more susceptible than liver, but that the mitochondria are otherwise normal with regard to energy conservation.
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PMID:Effect of iron deficiency on energy conservation in rat liver and skeletal muscle submitochondrial particles. 405 63

1. The reconstitution of oxidase activity in cell-free extracts of a mutant of Escherichia coli K12Ymel, that require 5-aminolaevulinic acid for growth on non-fermentable carbon sources, is described. 2. The reconstitution is dependent on haematin or a haem extract from a prototrophic strain of E. coli, and the product of the reaction has been identified as NADH-reducible cytochrome b. 3. The requirement for haematin cannot be replaced by four other porphyrins. Coproporphyrin III does not inhibit the haematin-dependent reconstitution, mesoporphyrin IX and protoporphyrin IX apparently compete with haematin for a binding site on the cytochrome apoprotein(s) and deuteroporphyrin IX binds to cytochrome apoprotein(s) and cannot be subsequently replaced by haematin. 4. The properties of electron-transport particles from cell-free extracts of the mutant strain, grown aerobically in the presence or absence of 5-aminolaevulinic acid, are described. In the absence of 5-aminolaevulinic acid no detectable cytochromes are produced, and oxidase activities are lowered but there is no apparent effect on the activities of the NADH dehydrogenase and d-lactate dehydrogenase. 5. The reconstitution of oxidase activity by electron-transport particles from cells grown in the absence of 5-aminolaevulinic acid requires ATP and haematin, and the product of the reaction was identified as NADH-reducible cytochrome b. 6. It is concluded that the cytochrome apoproteins are synthesized and incorporated into the cytoplasmic membrane of E. coli in the absence of haem synthesis. The subsequent reconstitution of functional cytochrome(s) requires protohaem, but the nature of the side chain on the 2 and 4 positions of the porphyrin appears to be important.
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PMID:The reconstitution of oxidase activity in membranes derived from a 5-aminolaevulinic acid-requiring mutant of Escherichia coli. 415 Jun 52

1. With reference to the post-operative dysfunction of the liver observed after halothane anaesthesia, the effects of the anaesthetic on some metabolic functions were studied in the isolated perfused rat liver. Oxygen uptake, glycolysis, gluconeogenesis and urea synthesis were affected by halothane at a concentration (2.5% of the gas phase) within the range used in clinical anaesthesia. 2. At this concentration of halothane uptake of oxygen was inhibited in livers from both fed and starved rats. 3. In livers from fed rats there was a 16-fold increase in lactate production. This was accompanied by a fivefold decrease in the tissue content of 2-oxoglutarate and a more than twofold decrease in citrate. The calculated [free NAD(+)]/[free NADH] ratio in both cytoplasm and mitochondria was lower in the halothane-exposed livers than in controls. 4. In livers of starved rats the rate of gluconeogenesis from lactate was decreased by halothane to 30% of the control rate. 5. Halothane inhibited gluconeogenesis from alanine and propionate to the same extent as from lactate, whereas glucose formation from dihydroxyacetone, glycerol, fructose and sorbitol was relatively unaffected. 6. During gluconeogenesis from 10mm-lactate the tissue content of ATP was decreased by 50%, glutamate by 50% and 2-oxoglutarate was decreased eightfold in the halothane-exposed livers. 7. Halothane decreased urea synthesis in the presence of 10mm-NH(4)Cl and 2mm-ornithine to 15% of the control rate. 8. The inhibitions of gluconeogenesis and urea synthesis were completely abolished within 15min of withdrawal of the anaesthetic. 9. The stimulation of uptake of oxygen brought about by the addition of lactate or precursors of urea was abolished by halothane. 10. Effects on gluconeogenesis similar to those of halothane occurred in livers exposed to the anaesthetic methoxyflurane, although normal rates were not restored on withdrawal of the drug. Other anaesthetic agents tested (ketamine-HCl and trichloroethylene) decreased gluconeogenesis to 66% of the control rate. 11. The inhibitory effects of halothane are consistent with an interference at the stage of the NADH dehydrogenase of the electron-transport chain.
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PMID:The effects of halothane (2-bromo-2-chloro-1,1,1-trifluoroethane) on glycolysis and biosynthetic processes of the isolated perfused rat liver. 434 8

The maximum Gibbs free energies of reverse electron transfer from succinate to NAD+ and from cytochrome c to fumarate driven by ATP hydrolysis in submitochondrial particles from beef heart were measured as a function of the Gibbs free energy of ATP hydrolysis. The ratio of the energies delta G'redox/delta G'ATP was 1.40 from succinate to NAD+ and 0.89 from cytochrome c to succinate. The ratio, equivalent to a thermodynamic P/2e-ratio, was dependent on whether the electrochemical proton gradient was primarily a membrane potential or a pH gradient for the cytochrome c to fumarate reaction. The results are consistent with H+/ATP = 3 for F1 ATPase, H+/2e- = 4 for NADH-CoQ reductase, and H+(matrix)/2e- = 2 for succinate-cytochrome c reductase.
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PMID:Energetics of ATP-driven reverse electron transfer from cytochrome c to fumarate and from succinate to NAD in submitochondrial particles. 608 93

1. The midpoint potentials of the various iron-sulphur centres in Site I were determined at different pH values by the technique of redox potentiometry. An interesting feature is the pH-dependence of Centre N-2, the highest potential component of the NADH dehydrogenase segment of the respiratory chain. 2. The apparent midpoint potentials of Centre N-2 (NADH dehydrogenase) and S-1 (succinate dehydrogenase) and their pH-dependence was also determined by using the succinate/fumarate couple. Again Centre N-2 is pH-dependent in midpoint potential, and Centre S-1 is not. The results obtained by titrating with the succinate/fumarate couple are in quantitative agreement with those obtained for these centres by redox potentiometry. 3. Oxidation-reduction titrations of iron-sulphur centres with the couple NADH/NAD+ and an analogue APADH/APAD+ in the presence of rotenone gave results substantially different from those obtained by redox potentiometry; these differences may be due to the mechanism of action of NADH dehydrogenase and its specific interaction with NADH. 5. The addition of ATP to an NAD+/NADH-poised system induces an uncoupler-sensitive oxidation of Centre N-4.
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PMID:An analysis of some thermodynamic properties of iron-sulphur centres in site I of mitochondria. 624 37

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