EC:1.6.5.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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 objective of this study was to elucidate the mechanisms of mitochondrial H2O2 generation in mouse organs by determining the nature of their differences in substrate utilization, inhibitor sensitivity, and the site specificity affecting H2O2 production. Mitochondria were isolated from heart, brain, and kidney and the rate of H2O2 generation was measured using the FADH-linked substrates succinate and alpha-glycerophosphate as well as the NADH-linked substrates pyruvate/malate, beta-hydroxybutyrate, and glutamate. Respiratory inhibitors, antimycin and rotenone, were added singly and sequentially to each substrate-supported H2O2 generation reaction mixture to determine the mitochondrial site(s) of generation and the optimal condition(s) for maximal rates of generation. Succinate supported the highest rate of mitochondrial H2O2 generation. Moreover, it was the preferred substrate for the heart mitochondria. alpha-Glycerophosphate is a poor substrate for H2O2 generation in heart mitochondria. Inhibitor studies showed that heart mitochondria were the most sensitive and responsive to antimycin, while brain was the most sensitive to rotenone. A surprising finding was that NADH-linked substrate-supported H2O2 generation in kidney mitochondria was not responsive to rotenone. The contribution from each of the three sites (ubiquinone, NADH dehydrogenase, and alpha-glycerophosphate dehydrogenase) of mitochondrial H2O2 generation to the total was both substrate and organ dependent. Results indicate that assay conditions must be considered before comparisons of sites and rates of mitochondrial H2O2 generation among different organs can be made.
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PMID:Substrate and site specificity of hydrogen peroxide generation in mouse mitochondria. 946 28

A rapid method (about 1.5 h) for the isolation of intact functional mitochondria from neurons and astrocytes in primary culture is described. Mitochondria isolated by this method are metabolically active and tightly coupled as shown by respiratory control ratio values, which were about 4 with glutamate-malate as substrate. The activities of marker enzymes revealed the occurrence of a low degree of cytosolic (5%) or synaptosomal (5.5%) contamination in the mitochondrial fractions. In addition, the activity of citrate synthase was increased by 4 fold in both neuronal and astrocytic mitochondria with respect to values found in cell homogenates. These results confirm that the method affords mitochondrial preparations from cultured brain cells at suitable levels of purity and enrichment for the study of their mitochondrial function. Since mitochondrial damage has been associated with the pathogenesis of certain neurodegenerative diseases, such as Alzheimer's and Parkinson's diseases (P. Chagnon, C. Betard, Y. Robitaille, A. Cholette, D. Gauvreau, Distribution of brain cytochrome oxidase activity in various neurodegenerative disease, Neuroreport 6 (1995) 711-715 [6]; S.J. Kish, C. Bergeron, A. Rajput, S. Dozic, F. Mastrogiacomo, L. Chang, J.M. Wilson, L.M. DiStefano, J.N. Nobrega, Brain cytochrome oxidase in Alzheimer's disease, J. Neurochem. 59 (1992) 776-779 [10]; A.H.V. Schapira, J.M. Cooper, D. Dexter, J.B. Clark, P. Jenner, C.D. Marsden, Mitochondrial complex I deficiency in Parkinson's disease, J. Neurochem. 54 (1990) 823-827 [15]), the method described here shed light on the possible susceptibility of neuronal or astrocytic mitochondria to deleterious effects of these diseases.
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PMID:A rapid method for the isolation of metabolically active mitochondria from rat neurons and astrocytes in primary culture. 950 34

The NDI1 gene encoding rotenone-insensitive internal NADH-quinone oxidoreductase of Saccharomyces cerevisiae mitochondria was cotransfected into the complex I-deficient Chinese hamster CCL16-B2 cells. Stable NDI1-transfected cells were obtained by screening with antibiotic G418. The NDI1 gene was shown to be expressed in the transfected cells. The expressed Ndi1 enzyme was recognized to be localized to mitochondria by immunoblotting and confocal immunofluorescence microscopic analyses. Using digitonin-permeabilized cells, it was shown that the transfected cells, but not nontransfected control cells, exhibited the electron transfer activities with glutamate/malate as the respiratory substrate. The activities were inhibited by flavone, antimycin A, and KCN but not by rotenone. Added NADH did not serve as the substrate, suggesting that the expressed Ndi1 enzyme was located on the matrix side of the inner mitochondrial membranes. Furthermore, although nontransfected cells could not survive in a medium low in glucose (0.6 mM), which is a substrate of glycolysis, the NDI1-transfected cells were able to grow in the absence of added glucose. When glycolysis is slow, either at low glucose concentrations or in the presence of galactose, respiration is required for cells to survive. The mutant cells do not survive at low glucose or in galactose, but they can be rescued by Ndi1. These results indicated that the S. cerevisiae Ndi1 was expressed functionally in CCL16-B2 cells and catalyzed electron transfer from NADH in the matrix to ubiquinone-10 in the inner mitochondrial membranes. It is concluded that the NDI1 gene provides a potentially useful tool for gene therapy of mitochondrial diseases caused by complex I deficiency.
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PMID:Molecular remedy of complex I defects: rotenone-insensitive internal NADH-quinone oxidoreductase of Saccharomyces cerevisiae mitochondria restores the NADH oxidase activity of complex I-deficient mammalian cells. 968 52

Seven of the approximately 40 subunits of the mammalian respiratory NADH dehydrogenase (Complex I) are encoded in mitochondrial DNA (mtDNA). Their function is almost completely unknown. In this work, a novel selection scheme has led to the isolation of a mouse A9 cell derivative defective in NADH dehydrogenase activity. This cell line carries a near-homoplasmic frameshift mutation in the mtDNA gene for the ND6 subunit resulting in an almost complete absence of this polypeptide, while lacking any mutation in the other mtDNA-encoded subunits of the enzyme complex. Both the functional defect and the mutation were transferred with the mutant mitochondria into mtDNA-less (rho0) mouse LL/2-m21 cells, pointing to the pure mitochondrial genetic origin of the defect. A detailed biosynthetic and functional analysis of the original mutant and of the rho0 cell transformants revealed that the mutation causes a loss of assembly of the mtDNA-encoded subunits of the enzyme and, correspondingly, a reduction in malate/glutamate-dependent respiration in digitonin-permeabilized cells by approximately 90% and a decrease in NADH:Q1 oxidoreductase activity in mitochondrial extracts by approximately 99%. Furthermore, the ND6(-) cells, in contrast to the parental cells, completely fail to grow in a medium containing galactose instead of glucose, indicating a serious impairment in oxidative phosphorylation function. These observations provide the first evidence of the essential role of the ND6 subunit in the respiratory function of Complex I and give some insights into the pathogenic mechanism of the known disease-causing ND6 gene mutations.
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PMID:The mtDNA-encoded ND6 subunit of mitochondrial NADH dehydrogenase is essential for the assembly of the membrane arm and the respiratory function of the enzyme. 970 44

The objectives of the current study were to evaluate (1) the respiratory rates and enzyme activities of brain and muscle mitochondria from rats chronically treated with haloperidol, (2) the protective role of dopamine (DA) D-1 (SKF38393) and D-2 (quinpirole) receptor agonists, and (3) the effect of haloperidol on the mitochondrial DNA (mtDNA) and protein synthesis. Thirty male Sprague-Dawley rats were subdivided into the following five groups: controls, haloperidol, haloperidol plus SKF38393, haloperidol plus quinpirole, and haloperidol plus SKF38393 and quinpirole. We compared the respiratory rates and enzymatic activities of brain and muscle mitochondria from controls with other groups. We finally analyzed the mitochondrial protein synthesis and mtDNA alterations (deletions, point mutations, and depletion) in two rats from each group. In brain but not in muscle from haloperidol-treated rats, we found a decrease of oxygen consumption rates using glutamate plus malate (-68 +/- 35%, P < 0.05) and succinate (-78 +/- 20%, P < 0.05) as substrates as well as low complex I, II, and V activities (-35 +/- 15%, P < 0.05; -54 +/- 13%, P < 0.05; and -60 +/- 33%, P < 0.01; respectively). The administration of SKF38393 alone or together with quinpirole prevented most of haloperidol-induced effects, whereas the protective effects of quinpirole alone were lower. Brain mitochondrial protein synthesis was decreased in haloperidol-treated rats and was not prevented by SKF38393, quinpirole, or both. We did not find mtDNA abnormalities in brain or muscle mitochondria from haloperidol-treated rats. Chronic administration of haloperidol in rats is associated with a nonspecific deleterious effect in the activity of electron transport chain of brain, and this effect is only partially prevented by DA D-1 agonists. These results suggest that other mechanisms different from DA receptors pathway can contribute to the expression of behavioral supersensitivity.
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PMID:Biochemical and molecular effects of chronic haloperidol administration on brain and muscle mitochondria of rats. 971 Feb 67

The pathogenetic mechanism of the deafness-associated mitochondrial DNA (mtDNA) T7445C mutation has been investigated in several lymphoblastoid cell lines from members of a New Zealand pedigree exhibiting the mutation in homoplasmic form and from control individuals. We show here that the mutation flanks the 3' end of the tRNASer(UCN) gene sequence and affects the rate but not the sites of processing of the tRNA precursor. This causes an average reduction of approximately 70% in the tRNASer(UCN) level and a decrease of approximately 45% in protein synthesis rate in the cell lines analyzed. The data show a sharp threshold in the capacity of tRNASer(UCN) to support the wild-type protein synthesis rate, which corresponds to approximately 40% of the control level of this tRNA. Strikingly, a 7445 mutation-associated marked reduction has been observed in the level of the mRNA for the NADH dehydrogenase (complex I) ND6 subunit gene, which is located approximately 7 kbp upstream and is cotranscribed with the tRNASer(UCN) gene, with strong evidence pointing to a mechanistic link with the tRNA precursor processing defect. Such reduction significantly affects the rate of synthesis of the ND6 subunit and plays a determinant role in the deafness-associated respiratory phenotype of the mutant cell lines. In particular, it accounts for their specific, very significant decrease in glutamate- or malate-dependent O2 consumption. Furthermore, several homoplasmic mtDNA mutations affecting subunits of NADH dehydrogenase may play a synergistic role in the establishment of the respiratory phenotype of the mutant cells.
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PMID:The deafness-associated mitochondrial DNA mutation at position 7445, which affects tRNASer(UCN) precursor processing, has long-range effects on NADH dehydrogenase subunit ND6 gene expression. 974 4

Dopamine deficiency causes disinhibition and overactivity of the subthalamic nucleus (STN). Output neurons from the STN are excitatory and use glutamate as a neurotransmitter. They project to the external and internal segments of the globus pallidum (GPe and GPi), the substantia nigra pars reticulata (SNr), and the pedunculopontine nucleus (PPN). In addition, STN neurons provide excitatory innervation to dopaminergic (DA) neurons in the substantia nigra pars compacta (SNc) that contain glutamate receptors. Stimulation of the STN induces bursting activity in SNc dopaminergic neurons. This raises the possibility that the disinhibition of STN neurons that occurs as a result of a dopamine lesion might induce excitotoxic damage in target structures, including the SNc. In addition, the reduction in complex I activity found in the nigra in Parkinson's disease (PD) may cause mitochondrial dysfunction and make SNc dopaminergic neurons vulnerable to even physiologic concentrations of glutamate. We postulate that the dopamine loss that occurs in PD produces augmented STN activity which, in turn, causes further damage to vulnerable dopaminergic neurons, thereby creating a scenario for an increasing cycle of neuronal loss in the SNc. In addition, STN overactivity could, in theory, cause damage to the GPi, SNr, and PPN and thereby account for the development of parkinsonian features that do not respond to levodopa in patients with advanced disease. This hypothesis suggests that pharmacologic or surgical therapies that reduce STN neuronal overactivity or block glutamate receptors in the SNc and other target structures might be neuroprotective and might slow or halt the progression of neurodegeneration in PD.
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PMID:Subthalamic nucleus-mediated excitotoxicity in Parkinson's disease: a target for neuroprotection. 974 91

To evaluate the potential role of mitochondrial lactate dehydrogenase (LDH) in tissue lactate clearance and oxidation in vivo, isolated rat liver, cardiac, and skeletal muscle mitochondria were incubated with lactate, pyruvate, glutamate, and succinate. As well, alpha-cyano-4-hydroxycinnamate (CINN), a known monocarboxylate transport inhibitor, and oxamate, a known LDH inhibitor were used. Mitochondria readily oxidized pyruvate and lactate, with similar state 3 and 4 respiratory rates, respiratory control (state 3/state 4), and ADP/O ratios. With lactate or pyruvate as substrates, alpha-cyano-4-hydroxycinnamate blocked the respiratory response to added ADP, but the block was bypassed by addition of glutamate (complex I-linked) and succinate (complex II-linked) substrates. Oxamate increased pyruvate (approximately 10-40%), but blocked lactate oxidation. Gel electrophoresis and electron microscopy indicated LDH isoenzyme distribution patterns to display tissue specificity, but the LDH isoenzyme patterns in isolated mitochondria were distinct from those in surrounding cell compartments. In heart, LDH-1 (H4) was concentrated in mitochondria whereas LDH-5 (M4) was present in both mitochondria and surrounding cytosol and organelles. LDH-5 predominated in liver but was more abundant in mitochondria than elsewhere. Because lactate exceeds cytosolic pyruvate concentration by an order of magnitude, we conclude that lactate is the predominant monocarboxylate oxidized by mitochondria in vivo. Mammalian liver and striated muscle mitochondria can oxidize exogenous lactate because of an internal LDH pool that facilitates lactate oxidation.
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PMID:Role of mitochondrial lactate dehydrogenase and lactate oxidation in the intracellular lactate shuttle. 992 5

The generation of H2O2 by isolated pea stem mitochondria, oxidizing either malate plus glutamate or succinate, was examined. The level of H2O2 was almost one order of magnitude higher when mitochondria were energized by succinate. The succinate-dependent H2O2 formation was abolished by malonate, but unaffected by rotenone. The lack of effect of the latter suggests that pea mitochondria were working with a proton motive force below the threshold value required for reverse electron transfer. The activation by pyruvate of the alternative oxidase was reflected in an inhibition of H2O2 formation. This effect was stronger when pea mitochondria oxidized malate plus glutamate. Succinate-dependent H2O2 formation was ca. four times lower in Arum sp. mitochondria (known to have a high alternative oxidase) than in pea mitochondria. An uncoupler (FCCP) completely prevented succinate-dependent H2O2 generation, while it only partially (40-50%) inhibited that linked to malate plus glutamate. ADP plus inorganic phosphate (transition from state 4 to state 3) also inhibited the succinate-dependent H2O2 formation. Conversely, that dependent on malate plus glutamate oxidation was unaffected by low and stimulated by high concentrations of ADP. These results show that the main bulk of H2O2 is formed during substrate oxidation at the level of complex II and that this generation may be prevented by either dissipation of the electrochemical proton gradient (uncoupling and transition state 4-state 3), or preventing its formation (alternative oxidase). Conversely, H2O2 production, dependent on oxidation of complex I substrate, is mainly lowered by the activation of the alternative oxidase.
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PMID:Hydrogen peroxide generation by higher plant mitochondria oxidizing complex I or complex II substrates. 1037 Dec 18

The effect of carbon tetrachloride administration on liver mitochondrial function and the protective effect of an aqueous extract of Phyllanthus fraternus were studied in rats. The following changes were observed in mitochondria due to the administration of carbon tetrachloride. 1) A decrease in the rate of respiration, respiratory control ratio and P/O ratio using glutamate and malate or succinate as substrates. 2) A decrease in the activities of NADH dehydrogenase (35%), succinate dehydrogenase (76%) and cytochrome c oxidase (51%). The rate of electron transfer through site I, site II and site III was studied independently and found to be significantly decreased. 3) A decrease in the content of cytochrome aa3 (34%). 4) A significant decrease in the levels of phospholipids particularly cardiolipin and a significant increase in the lipid peroxide level was observed. The carbon tetrachloride induced toxicity may be partly due to the lipid peroxidation and partly due to the effect on protein synthesis. Administration of rats with an aqueous extract of P. fraternus prior to carbon tetrachloride administration showed significant protection on the carbon tetrachloride induced mitochondrial dysfunction on all the parameters studied.
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PMID:Protective effect of Phyllanthus fraternus against carbon tetrachloride-induced mitochondrial dysfunction. 1037 5

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