Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.6.5.3 (complex I)
 8,901 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nitrite, once thought to be an inert biomarker of NO formation, is now recognized as an endocrine storage pool of bioactive NO. While nitrite mediates a number of hypoxic responses, one of its most robust effects is its ability to confer cytoprotection after ischemia/reperfusion in a number of organs and models. The mechanism of this cytoprotection appears to be mediated at the level of the mitochondrion. Here we review the studies demonstrating that nitrite is cytoprotective in the heart and describe the mechanism of this cytoprotection, which involves the post-translational modification of complex I leading to the modulation of mitochondrial reactive oxygen species generation at reperfusion. The mechanism of nitrite-dependent cytoprotection will be compared to other cytoprotective agents including NO and ischemic preconditioning.
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PMID:Nitrite mediates cytoprotection after ischemia/reperfusion by modulating mitochondrial function. 1924 36

Here we report effect of ischemia-reperfusion on mitochondrial Ca2+ uptake and activity of complexes I and IV in rat hippocampus. By performing 4-vessel occlusion model of global brain ischemia, we observed that 15 min ischemia led to significant decrease of mitochondrial capacity to accumulate Ca2+ to 80.8% of control whereas rate of Ca2+ uptake was not significantly changed. Reperfusion did not significantly change mitochondrial Ca2+ transport. Ischemia induced progressive inhibition of complex I, affecting final electron transfer to decylubiquinone. Minimal activity of complex I was observed 24 h after ischemia (63% of control). Inhibition of complex IV activity to 80.6% of control was observed 1 h after ischemia. To explain the discrepancy between impact of ischemia on rate of Ca2+ uptake and activities of both complexes, we performed titration experiments to study relationship between inhibition of particular complex and generation of mitochondrial transmembrane potential (DeltaPsi(m)). Generation of a threshold curves showed that complex I and IV activities must be decreased by approximately 40, and 60%, respectively, before significant decline in DeltaPsi(m) was documented. Thus, mitochondrial Ca2+ uptake was not significantly affected by ischemia-reperfusion, apparently due to excess capacity of the complexes I and IV. Inhibition of complex I is favourable of reactive oxygen species (ROS) generation. Maximal oxidative modification of membrane proteins was documented 1 h after ischemia. Although enhanced formation of ROS might contribute to neuronal injury, depressed activities of complex I and IV together with unaltered rate of Ca2+ uptake are conditions favourable of initiation of other cell degenerative pathways like opening of mitochondrial permeability transition pore or apoptosis initiation, and might represent important mechanism of ischemic damage to neurones.
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PMID:Mitochondrial calcium transport and mitochondrial dysfunction after global brain ischemia in rat hippocampus. 1925 83

The reversible S-nitrosation and inhibition of mitochondrial complex I is a potential mechanism of cardioprotection, recruited by ischemic preconditioning (IPC), S-nitrosothiols, and nitrite. Previously, to exploit this mechanism, the mitochondrial S-nitrosating agent S-nitroso-2-mercaptopropionyl glycine (SNO-MPG) was developed, and protected perfused hearts and isolated cardiomyocytes against ischemia-reperfusion (IR) injury. In the present study, the murine left anterior descending coronary artery (LAD) occlusion model of IR injury was employed, to determine the protective efficacy of SNO-MPG in vivo. Intraperitoneal administration of 1 mg/kg SNO-MPG, 30 min prior to occlusion, significantly reduced myocardial infarction and improved EKG parameters, following 30 min occlusion plus 2 or 24 h reperfusion. SNO-MPG protected to the same degree as IPC, and notably was also protective when administered at reperfusion. Cardioprotection was accompanied by increased mitochondrial protein S-nitrosothiol content, and inhibition of complex I, both of which were reversed after 2 h reperfusion. Finally, hearts from mice harboring a heterozygous mutation in the complex I NDUSF4 subunit were refractory to protection by either SNO-MPG or IPC, suggesting that a fully functional complex I, capable of reversible inhibition is critical for cardioprotection. Overall, these results are consistent with a role for mitochondrial S-nitrosation and complex I inhibition in the cardioprotective mechanism of IPC and SNO-MPG in vivo.
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PMID:In vivo cardioprotection by S-nitroso-2-mercaptopropionyl glycine. 1933 6

Mitochondrial dysfunction contributes to myocardial injury during ischemia and reperfusion. Ischemia damages the mitochondrial electron transport chain. Therapeutic intervention during early reperfusion decreases cardiac injury, which suggests that myocardial injury can be attenuated even though mitochondria were already damaged during the preceding ischemia. Our previous study shows that amobarbital given only before ischemia prevents ischemic damage to the electron transport chain and decreases infarct size measured during reperfusion in Langendorff-perfused Fischer 344 rat hearts. In the current study, amobarbital was given at the onset of reperfusion to test whether the blockade of proximal electron transport only during early reperfusion can decrease myocardial injury. Amobarbital administrated during early reperfusion decreased infarct size compared with untreated hearts, which suggests that the modulation of electron transport during early reperfusion attenuates myocardial injury. The increased generation of reactive oxygen species (ROS) contributes to injury. We tested whether the blockade of proximal electron transport prevents ROS release from the mitochondria that sustained ischemic damage. The blockade of the proximal electron transport chain at complex I attenuates maximal ROS generation from ischemia-damaged mitochondria. Thus, the modulation of oxidative function during reperfusion provides a translationally relevant opportunity to prevent a portion of the mitochondrial-dependent injury. The cardiac protection by amobarbital given during reperfusion may result from decreased ROS generation from the electron transport chain.
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PMID:Reversible blockade of electron transport with amobarbital at the onset of reperfusion attenuates cardiac injury. 1937 83

Dietary nitrate, found in abundance in green vegetables, can be converted to the cytoprotective molecule nitrite by oral bacteria, suggesting that nitrate and nitrite may represent active cardioprotective constituents of the Mediterranean diet. We therefore tested the hypothesis that dietary nitrate and nitrite levels modulate tissue damage and ischemic gene expression in a mouse liver ischemia-reperfusion model. We found that stomach content, plasma, heart, and liver nitrite levels were significantly reduced after dietary nitrate and nitrite depletion and could be restored to normal levels with nitrite supplementation in water. Remarkably, we confirmed that basal nitrite levels significantly reduced liver injury after ischemia-reperfusion. Consistent with an effect of nitrite on the posttranslational modification of complex I of the mitochondrial electron transport chain, the severity of liver infarction was inversely proportional to complex I activity after nitrite repletion in the diet. The transcriptional response of dietary nitrite after ischemia was more robust than after normoxia, suggesting a hypoxic potentiation of nitrite-dependent transcriptional signaling. Our studies indicate that normal dietary nitrate and nitrite levels modulate ischemic stress responses and hypoxic gene expression programs, supporting the hypothesis that dietary nitrate and nitrite are cytoprotective components of the diet.
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PMID:Dietary nitrate and nitrite modulate blood and organ nitrite and the cellular ischemic stress response. 1946 64

Nitric oxide (NO(*)) competitively inhibits oxygen consumption by mitochondria at cytochrome c oxidase and S-nitrosates thiol proteins. We developed mitochondria-targeted S-nitrosothiols (MitoSNOs) that selectively modulate and protect mitochondrial function. The exemplar MitoSNO1, produced by covalently linking an S-nitrosothiol to the lipophilic triphenylphosphonium cation, was rapidly and extensively accumulated within mitochondria, driven by the membrane potential, where it generated NO(*) and S-nitrosated thiol proteins. MitoSNO1-induced NO(*) production reversibly inhibited respiration at cytochrome c oxidase and increased extracellular oxygen concentration under hypoxic conditions. MitoSNO1 also caused vasorelaxation due to its NO(*) generation. Infusion of MitoSNO1 during reperfusion was protective against heart ischemia-reperfusion injury, consistent with a functional modification of mitochondrial proteins, such as complex I, following S-nitrosation. These results support the idea that selectively targeting NO(*) donors to mitochondria is an effective strategy to reversibly modulate respiration and to protect mitochondria against ischemia-reperfusion injury.
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PMID:A mitochondria-targeted S-nitrosothiol modulates respiration, nitrosates thiols, and protects against ischemia-reperfusion injury. 1952 54

During cardiac arrest (CA), myocardial perfusion is solely dependent on cardiopulmonary resuscitation (CPR) although closed-chest compressions only provide about 10-20% of normal myocardial perfusion. The study was conducted in a whole animal CPR model to determine whether CPR-generated oxygen delivery preserves or worsens mitochondrial function. Male Sprague-Dawley rats (400-450 g) were randomly divided into four groups: (1) BL (instrumentation only, no cardiac arrest), (2) CA(15) (15 min cardiac arrest without CPR), (3) CA(25) (25 min cardiac arrest without CPR) and (4) CPR (15 min cardiac arrest, followed by 10 min CPR). The differences between groups were evaluated by measuring mitochondrial respiration, electron transport chain (ETC) complex activities and mitochondrial ultrastructure by transmission electron microscopy (TEM). The CA(25) group had the greatest impairment of mitochondrial respiration and ETC complex activities (I-III). In contrast, the CPR group was not different from the CA(15) group regarding all measures of mitochondrial function. Complex I was more susceptible to ischemic injury than the other complexes and was the major determinant of mitochondrial dysfunction. Observations of mitochondrial ultrastructure by TEM were compatible with the biochemical results. The findings suggest that, despite low blood flow and oxygen delivery, CPR is able to preserve heart mitochondrial function and viability during ongoing global ischemia. Preservation of complex I activity and mitochondrial function during cardiac arrest may be an important mechanism underlying the beneficial effects of CPR which have been shown in clinical studies.
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PMID:Preservation of mitochondrial function with cardiopulmonary resuscitation in prolonged cardiac arrest in rats. 1975 39

Various stressful conditions such as ischemia in cold cardioplegic solutions and reperfusion occur during heart transplantation. Since ATP production is essential for the maintenance of contractile activity, mitochondrial function may be a mediator of ischemia and ischemia/reperfusion (I/R) injury. We aimed at testing the ability of two distinct cardioplegic solutions, Celsior (Cs) and Histidine Buffer (HBS), to protect rat heart mitochondria (HM) function during ischemia alone or ischemia followed by reperfusion. A standard Krebs-Henseleit solution (KH) was used as "negative" control. Male and Female Wistar rats were divided into control (Ctrl), reperfusion control (Ctrl_R), ischemia and I/R groups. Ischemia and I/R were divided into three subgroups depending on the cardioplegic solution used (Cs, HBS or KH) and subjected to 4-or 6-h ischemia alone or followed by reperfusion. HM respiration and transmembrane electric potential (Deltapsi) were measured with oxygen and TPP(+)-selective electrodes, respectively. Mitochondrial electron microscopy and detection of protein carbonyl groups content were also performed. After ischemic heart preservation, mitochondrial respiration and Deltapsi were not significantly affected except for the respiratory control ratio (RCR). After I/R, state 3 respiration, RCR and Deltapsi were decreased, especially in HM from male and for complex I substrates (CxI). HM preserved in HBS had less membrane disruption, segregation or disintegration. We conclude that (a) female HM were less sensitive to I/R, (b) CxI was particularly affected by I/R, (c) two cardioplegic solutions tested act in different mitochondrial targets preventing mitochondrial collapse.
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PMID:Mitochondrial preservation in Celsior versus histidine buffer solution during cardiac ischemia and reperfusion. 1975 1

Oxidative stress is deeply involved in various brain diseases, including neurodegenerative diseases, stroke, and ischemia/reperfusion injury. Mitochondria are thought to be the target and source of oxidative stress. We investigated the role of mitochondria in oxidative stress-induced necrotic neuronal cell death in a neuroblastoma cell line and a mouse model of middle cerebral artery occlusion. The exogenous administration of hydrogen peroxide was used to study the role of oxidative stress on neuronal cell survival and mitochondrial function in vitro. Hydrogen peroxide induced non-apoptotic neuronal cell death in a c-Jun N-terminal kinase- and poly(ADP-ribosyl) polymerase-dependent manner. Unexpectedly, hydrogen peroxide treatment induced transient hyperpolarization of the mitochondrial membrane potential and a subsequent delayed burst of endogenous reactive oxygen species (ROS). The inhibition of mitochondrial hyperpolarization by diphenylene iodonium or rotenone, potent inhibitors of mitochondrial respiratory chain complex I, resulted in reduced ROS production and subsequent neuronal cell death in vitro and in vivo. The inhibition of mitochondrial hyperpolarization can protect neuronal cells from oxidative stress-induced necrotic cell death, suggesting a novel method of therapeutic intervention in oxidative stress-induced neurological disease.
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PMID:Oxidative stress-induced necrotic cell death via mitochondira-dependent burst of reactive oxygen species. 1980 58

Since the anti-epileptic drug Zonisamide (ZNS) seems to exert beneficial effects in Parkinson's (PD) disease, we have investigated the electrophysiological effects of ZNS in a rat corticostriatal slice preparation. ZNS affected neither the resting membrane potential nor the input resistance of the putative striatal spiny neurons. In contrast, this drug depressed in a dose-dependent manner the current-evoked repetitive firing discharge with a EC(50) value of 16.38 microM. ZNS also reduced the amplitude of glutamatergic excitatory postsynaptic potentials (EPSPs) with a EC(50) value of 32.5 microM. Reduced activity of the mitochondrial respiratory chain, particularly complex I and II, is implicated in the pathophysiology of PD and Huntington's (HD) diseases, respectively. Thus, ZNS was also tested in two different in vitro neurotoxic models obtained by acutely exposing corticostriatal slices either to rotenone, a selective inhibitor of mitochondrial complex I, or to 3-nitropropionic acid (3-NP), an inhibitor of complex II. Additionally, we also investigated the effect of ZNS in an in vitro model of brain ischemia. Interestingly, low concentrations of ZNS (0.3, 1, 3 and 10 microM) significantly reduced the rotenone-induced toxicity protecting striatal slices from the irreversible loss of corticostriatal field potential (FP) amplitude via a GABA-mediated mechanism. Conversely, this drug showed no protection against 3-NP and ischemia-induced toxicity. Our data indicate that relatively high doses of ZNS are required to decrease striatal neuronal excitability while low concentrations of this drug are sufficient to protect striatum against mitochondrial impairment suggesting its possible use in the therapy of basal ganglia neurodegenerative diseases.
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PMID:Electrophysiological actions of zonisamide on striatal neurons: Selective neuroprotection against complex I mitochondrial dysfunction. 2045 Sep 11


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