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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 redox state of the carriers of electron-transport chain of cardiac mitochondria was studied in the conditions of normal perfusion, global
ischemia
and reoxygenation of the myocardial tissue. Experiments were performed on isolated rat hearts perfused at 37 degrees C by the "working heart" procedure. The EPR spectra of the freeze-clamped hearts were measured at 6-30 K. An analysis of the main values of g-tensor, line-shape, line-width and relaxation parameters of the components of low-temperature EPR spectra allowed to distinguish the signals from Fe-S centers of
NADH-CoQ reductase
and succinate-CoQ reductase, and the signals from free radical species of coenzyme Q and flavin coenzymes. The EPR spectra of hearts that were fixed during control perfusion and reperfusion contained predominantly the signal of oxidized S3 center of succinate-CoQ reductase. The free radical signal in these conditions was mainly due to ubisemiquinones. Besides the intensive signal of S3 center, the low-temperature EPR spectra contained also signals from different Fe-S centers paramagnetic in reduced state. The global
ischemia
of cardiac muscle caused essential reduction of the Fe-S clusters of the mitochondrial electron-transport chain. In ischemic condition the free radical EPR signal was mainly due to flavosemiquinones. The changes of the redox state of carriers of the mitochondrial respiratory chain correlated with the changes of the physiological parameters of cardiac muscle.
...
PMID:[Redox state of the electron-transport carriers in cardiac mitochondria: a study by the method of low-temperature EPR spectroscopy]. 949 Jan 10
We previously reported that cardiac reperfusion results in declines in mitochondrial NADH-linked respiration. The degree of inactivation increased with age and was paralleled by modification of protein by the lipid peroxidation product 4-hydroxy-2-nonenal. To gain insight into potential sites of oxidative damage, the present study was undertaken to identify specific mitochondrial protein(s) inactivated during
ischemia
and reperfusion and to determine which of these losses in activity are responsible for observed declines in mitochondrial respiration. Using a Langendorff rat heart perfusion protocol, we observed age-dependent inactivation of
complex I
during
ischemia
and complex IV and alpha-ketoglutarate dehydrogenase during reperfusion. Although losses in
complex I
and IV activities were found not to be of sufficient magnitude to cause declines in mitochondrial respiration, an age-related decrease in
complex I
activity during
ischemia
may predispose old animals to more severe oxidative damage during reperfusion. It was determined that inactivation of alpha-ketoglutarate dehydrogenase is responsible, in large part, for observed reperfusion-induced declines in NADH-linked respiration. alpha-Ketoglutarate dehydrogenase is highly susceptible to 4-hydroxy-2-nonenal inactivation in vitro. Thus, our results suggest a plausible mechanism for age-dependent, reperfusion-induced declines in mitochondrial function and identify alpha-ketoglutarate dehydrogenase as a likely site of free radical-mediated damage.
...
PMID:Declines in mitochondrial respiration during cardiac reperfusion: age-dependent inactivation of alpha-ketoglutarate dehydrogenase. 1035 73
Mitochondrial membrane potential (delta psi(m)) was determined in intact isolated nerve terminals using the membrane potential-sensitive probe JC-1. Oxidative stress induced by H2O2 (0.1-1 mM) caused only a minor decrease in delta psi(m). When
complex I
of the respiratory chain was inhibited by rotenone (2 microM), delta psi(m) was unaltered, but on subsequent addition of H2O2, delta psi(m) started to decrease and collapsed during incubation with 0.5 mM H2O2 for 12 min. The ATP level and [ATP]/[ADP] ratio were greatly reduced in the simultaneous presence of rotenone and H2O2. H2O2 also induced a marked reduction in delta psi(m) when added after oligomycin (10 microM), an inhibitor of F0F1-ATPase. H2O2 (0.1 or 0.5 mM) inhibited alpha-ketoglutarate dehydrogenase and decreased the steady-state NAD(P)H level in nerve terminals. It is concluded that there are at least two factors that determine delta psi(m) in the presence of H2O2: (a) The NADH level reduced owing to inhibition of alpha-ketoglutarate dehydrogenase is insufficient to ensure an optimal rate of respiration, which is reflected in a fall of delta psi(m) when the F0F1-ATPase is not functional. (b) The greatly reduced ATP level in the presence of rotenone and H2O2 prevents maintenance of delta psi(m) by F0F1-ATPase. The results indicate that to maintain delta psi(m) in the nerve terminal during H2O2-induced oxidative stress, both
complex I
and F0F1-ATPase must be functional. Collapse of delta psi(m) could be a critical event in neuronal injury in
ischemia
or Parkinson's disease when H2O2 is generated in excess and
complex I
of the respiratory chain is simultaneously impaired.
...
PMID:Depolarization of in situ mitochondria due to hydrogen peroxide-induced oxidative stress in nerve terminals: inhibition of alpha-ketoglutarate dehydrogenase. 1038 74
Mitochondria alteration is an early event in
ischemia
-induced damage, and its prevention improves tissue survival upon reperfusion. Adenine translocase and
complex I
activities are rapidly affected by
ischemia
. Ginkgo biloba extract demonstrates anti-ischemic properties attributable to the terpenoid fraction, mainly due to the presence of bilobalide. The mechanism of the protection afforded by bilobalide is not yet known. In this work, the effects of bilobalide on mitochondrial respiration were investigated. Mitochondria isolated from rats treated with bilobalide (2 to 8 mg/kg) showed a dose-dependent increase in the respiratory control ratio, due to a lower oxygen consumption during state 4. Bilobalide also decreased the sensitivity of oxygen consumption to inhibition of
complex I
by Amytal or to inhibition of complex III by antimycin A or myxothiazol. There was no protection of complexes IV and V. It also increased the activity of
complex I
but not of adenine translocase. Similar effects were also obtained in vitro when control mitochondria were preincubated for 1 hr with 0.8 microg/mL bilobalide. Treatment of the rats with 8 mg/kg bilobalide also prevented the
ischemia
-induced decrease in state 3 of the mitochondrial respiration and thus the decrease in RCR. The protective effect of bilobalide on cellular ATP content observed under ischemic conditions can be correlated with the above observations. By protecting
complex I
and III activities, bilobalide allows mitochondria to maintain their respiratory activity under ischemic conditions as long as some oxygen is present, thus delaying the onset of
ischemia
-induced damage. This mechanism provides a possible explanation for the anti-ischemic properties of bilobalide and of Ginkgo biloba extract in therapeutic interventions.
...
PMID:Protection of mitochondrial respiration activity by bilobalide. 1040 24
Kidney proximal tubule cells developed severe energy deficits during hypoxia/reoxygenation not attributable to cellular disruption, lack of purine precursors, the mitochondrial permeability transition, or loss of cytochrome c. Reoxygenated cells showed decreased respiration with
complex I
substrates, but minimal or no impairment with electron donors at complexes II and IV. This was accompanied by diminished mitochondrial membrane potential (DeltaPsi(m)). The energy deficit, respiratory inhibition, and loss of DeltaPsi(m) were strongly ameliorated by provision of alpha-ketoglutarate plus aspartate (alphaKG/ASP) supplements during either hypoxia or only during reoxygenation. Measurements of (13)C-labeled metabolites in [3-(13)C]aspartate-treated cells indicated the operation of anaerobic pathways of alphaKG/ASP metabolism to generate ATP, yielding succinate as end product. Anaerobic metabolism of alphaKG/ASP also mitigated the loss of DeltaPsi(m) that occurred during hypoxia before reoxygenation. Rotenone, but not antimycin or oligomycin, prevented this effect, indicating that electron transport in
complex I
, rather than F(1)F(0)-ATPase activity, had been responsible for maintenance of DeltaPsi(m) by the substrates. Thus, tubule cells subjected to hypoxia/reoxygenation can have persistent energy deficits associated with
complex I
dysfunction for substantial periods of time before onset of the mitochondrial permeability transition and/or loss of cytochrome c. The lesion can be prevented or reversed by citric acid cycle metabolites that anaerobically generate ATP by intramitochondrial substrate-level phosphorylation and maintain DeltaPsi(m) via electron transport in
complex I
. Utilization of these anaerobic pathways of mitochondrial energy metabolism known to be present in other mammalian tissues may provide strategies to limit mitochondrial dysfunction and allow cellular repair before the onset of irreversible injury by
ischemia
or hypoxia.
...
PMID:Mitochondrial dysfunction during hypoxia/reoxygenation and its correction by anaerobic metabolism of citric acid cycle intermediates. 1071 1
Although it is considered that L-Glutamine (L-Gln) supplementation improves gut morphology and survival in animal models such as radiation and drug-induced enterocolitis, the mechanisms underlying are far from being established. Recently, Gln has been reported to give protection against stress in in vitro intestinal epithelial cell lines through the induction of heat shock proteins (HSPs). This study is designed to examine whether L-Gln may induce cytoprotective molecules such as heme oxygenase-1/HSP32 (HO-1) and reduced glutathione (GSH) in in vivo intestinal tissues, and to clarify whether these molecules may play a role in warm
ischemia
and reperfusion (I/R) injury. We measured the releases of serotonin and tumor necrosis factor-alpha (TNF-alpha), and graft survival as viability assays following reperfusion of warm ischemically injured intestinal grafts. The substantial expression of HO-1 after L-Gln administration was observed in villous epithelial cells, crypts and muscular layers, and peaked at 6 h, while that of the control group pretreated with lactated Ringer (LR) solution was observed throughout tissues to be slightly similar to those of fresh untreated tissues. Tissue GSH contents slightly increased 24 h after administration and were less reduced through the periods of I/R than those of the LR group. Releases of serotonin and TNF-alpha in L-Gln group were attenuated during the brief periods of warm
ischemia
, compared with those in the LR group. A significant graft survival rate was also observed between both groups (6/6 of L-Gln group vs. 1/6 of LR group; p < 0.05). In conclusion, the protective effects of L-Gln in small intestines against warm I/R injury were considered to be in part mediated by up-regulation of molecules such as HO-1 and GSH via cellular antioxidant activity. Thus, L-Gln pretreatment may represent an innovative approach to the prevention of
complex I
/R injury.
...
PMID:[L-glutamine-induced heme oxygenase-1 protects small intestine from warm ischemia and reperfusion injury in the rat]. 1123 9
Hyperthermic stress is known to protect against myocardial dysfunction after
ischemia
-reperfusion injury. It is unclear however, what energetic mechanisms are affected by the molecular adaptation to heat stress. We hypothesized that mild hyperthermic stress can increase mitochondrial respiratory enzyme activity, affording protection to mitochondrial energetics during prolonged cardiac preservation for transplantation. Rat hearts were excised after heat-stress or sham treatment and subjected to cold cardioplegic arrest and
ischemia
followed by reperfusion in an ex vivo perfusion system. Cardiac function, mitochondrial respiratory, and complex activities were assessed before and after
ischemia
. Heat shock protein (Hsp 32, 60, and 72) expression was increased in heat-stressed hearts. This was associated with increased mitochondrial complex activities in heat-stress versus sham-treated groups for
complex I
-V. During reperfusion, higher complex activities and respiratory control ratios were observed in heat-stressed versus sham-treated groups. Recovery of ventricular function was improved in heat-stressed hearts. Furthermore, mitochondria in reperfused heat-stressed myocardium exhibited intact membranes with packed, parallel, lamellar cristae, whereas in sham-treated myocardium, mitochondria were severely disrupted. This study provides the first evidence of heat-stress-mediated enhancement of mitochondrial energetic capacity. This is associated with increased tolerance to
ischemia
-reperfusion injury. Protection by heat stress against myocardial dysfunction may be partially due to enhancement of mitochondrial energetics.
...
PMID:Heat stress contributes to the enhancement of cardiac mitochondrial complex activity. 1133 80
We investigated the effects of
ischemia
duration on the functional response of mitochondria to reperfusion and its relationship with changes in mitochondrial susceptibility to oxidative stress. Mitochondria were isolated from hearts perfused by the Langendorff technique immediately after different periods of global
ischemia
or reperfusion following such
ischemia
periods. Rates of O2 consumption and H2O2 release with
complex I
- and complex II-linked substrates, lipid peroxidation, overall antioxidant capacity, capacity to remove H2O2, and susceptibility to oxidative stress were determined. The effects of
ischemia
on some parameters were time dependent so that the changes were greater after 45 than after 20 min of
ischemia
, or were significantly different to the nonischemic control only after 45 min of
ischemia
. Thus, succinate-supported state 3 respiration exhibited a significant decrease after 20 min of
ischemia
and a greater decrease after 45 min, while pyruvate malate-supported respiration showed a significant decrease only after 45 min of
ischemia
, indicating an
ischemia
-induced early inhibition of complex II and a late inhibition of
complex I
. Furthermore, both succinate and pyruvate malate-supported H2O2 release showed significant increases only after 45 min of
ischemia
. Similarly, whole antioxidant capacity significantly increased and susceptibility to oxidants significantly decreased after 45 min of
ischemia
. Such changes were likely due to the accumulation of reducing equivalents, which are able to remove peroxides and maintain thiols in a reduced state. This condition, which protects mitochondria against oxidants, increases mitochondrial production of oxyradicals and oxidative damage during reperfusion. This could explain the smaller functional recovery of the tissue and the further decline of the mitochondrial function after reperfusion following the longer period of oxygen deprivation.
...
PMID:Effects of myocardial ischemia and reperfusion on mitochondrial function and susceptibility to oxidative stress. 1169 31
Biochemical cascades initiated by oxidative stress and excitotoxic intracellular calcium rises are thought to converge on mitochondrial dysfunction. We investigated the contribution of mitochondrial dysfunction to free radical (FR) overproduction in rat CA1 pyramidal neurons of organotypic slices subjected to a hypoxic-hypoglycemic insult.
Ischemia
-induced FR generation was decreased by the mitochondrial
complex I
blocker, rotenone, indicating that mitochondria are the principal source of ischemic FR production. Measurements of mitochondrial calcium with the mitochondrial calcium probe dihydroRhod-2, revealed that FR production during and after the anoxic episode correlates with the accumulation of mitochondrial calcium. However, the mitochondrial calcium uptake inhibitor Ru360 did not prevent FR generation during
ischemia
and attenuated it to some degree during reoxygenation. On the other hand, the mitochondrial permeability transition blocker cyclosporinA (CsA) completely arrested both ischemic FR generation and mitochondrial calcium overload, and prevented deterioration of neuronal intrinsic membrane properties. CsA had no effect on the accumulation of intracellular calcium during
ischemia
-reperfusion. Nicotinamide, a blocker of NAD+ hydrolysis, reproduced the CsA effects on FR generation, mitochondrial calcium accumulation and cytoplasmic calcium increases. These observations suggest that a major determinant of ischemic FR generation in pyramidal neurons is the uncoupling of the mitochondrial respiratory chain, which may be associated with the mitochondrial permeability transition.
...
PMID:Dynamics of intracellular calcium and free radical production during ischemia in pyramidal neurons. 1170
The aim of this study was to investigate the influence of reactive oxygen species (ROS) on the activity of
complex I
and on the cardiolipin content in bovine heart submitochondrial particles (SMP). ROS were generated through the use of xanthine/xanthine oxidase (X/XO) system. Treatment of SMP with X/XO resulted in a large production of superoxide anion, detected by acetylated cytochrome c method, which was blocked by superoxide dismutase (SOD). Exposure of SMP to ROS generation resulted in a marked loss of
complex I
activity and to parallel loss of mitochondrial cardiolipin content. Both these effects were completely abolished by SOD+catalase. Exogenous added cardiolipin was able to almost completely restore the ROS-induced loss of
complex I
activity. No restoration was obtained with other major phospholipid components of the mitochondrial membrane such as phosphatidylcholine and phosphatidylethanolamine, nor with peroxidized cardiolipin. These results demonstrate that ROS affect the mitochondrial
complex I
activity via oxidative damage of cardiolipin which is required for the functioning of this multisubunit enzyme complex. These results may prove useful in probing molecular mechanisms of ROS-induced peroxidative damage to mitochondria, which have been proposed to contribute to those pathophysiological conditions characterized by an increase in the basal production of reactive oxygen species such as aging,
ischemia
/reperfusion and chronic degenerative diseases.
...
PMID:Reactive oxygen species affect mitochondrial electron transport complex I activity through oxidative cardiolipin damage. 1194 69
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