EC:1.6.5.3 - FACTA Search

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)

Measurement of the effect of drugs on the in vivo rates of synthesis of rabbit liver organelle bound proteins were measured following individual treatments with the inducers phenobarbital, 3-methylcholanthrene and PCB (a mixture of polychlorinated biphenyls) and the inhibitors, cycloheximide, aflatoxin B1, chloramphenicol and actinomycin D. Following their isolation from a homogenate containing the combined livers of 14C-leucine injected experimental animals and 3H-leucine injected control animals, purified fractions of the following proteins were prepared: microsomal cytochrome b5, cytochrome P-450, NADH-cytochrome b5 reductase, NADPH-cytochrome P-450 reductase and proteolipids, outer mitochondrial membrane cytochrome b5, NADH-cytochrome b5 reductase and proteolipids, inner mitochondrial membrane cytochrome c, NADH dehydrogenase and proteolipids, intermitochondrial membrane cytochrome b5 and circulating serum albumin. The effect of a drug was examined by measuring the 14C/3H ratio of leucine incorporation of each fraction; ratios which differed markedly from a control value of 1 represented actual changes in the relative rates of protein synthesis. Increased rates of synthesis of cytochrome P-450 and its reductase, intermitochondrial membrane cytochrome b5 and all three proteolipid fractions resulted from each inducer treatment. Treatments with 3-methylcholanthrene and PCB also increased the rate of synthesis of cytochrome b5 and its reductase in both the microsome and outer mitochondrial membrane. In addition, the PCB treatment increased the rates of synthesis of cytochrome c and NADH-dehydrogenase. The rates of synthesis of cytochromes, reductases and of circulating serum albumin were inhibited following treatments with cycloheximide, aflatoxin B1 and actinomycin D. Actinomycin D appeared to inhibit the release of newly synthesized albumin into the bloodstream while chloramphenicol treatment appeared to inhibit the incorporation of cytochrome c into the mitochondria. After 20 hours of treatment with inhibitors, the inhibitory effect of actinomycin D and cycloheximide were still apparent while the rates of protein synt;esis in chloramphenicol and aflatoxin B1 treated animals increased to levels above the controls. The incorporation of radioactively labeled leucine into the proteolipids of the microsomal, and the outer and inner mitochondrial membranes were inhibited following the treatment with actinomycin D and stimulated following the treatment with cycloheximide.
...
PMID:Effect of a single dose of inducers and inhibitors on the rate of synthesis of cytochromes and reductases in liver organelles. 11 59

Semliki Forest virus inhibits phosphatidylethanolamine biosynthesis in baby hamster kidney-21 cells 6 h after infection. Viral infection reduced the incorporation of [1,2-14C]-ethanolamine into intact cells by approximately 50%. A similar reduction in the activity of the ethanolaminephosphotransferase (EC 2.7.8.1) was also observed. The apparent Km for CDPethanolamine was 60 muM for the microsomal enzymes from infected or mock-infected cells. In addition, exogenous diglyceride only stimulated by 1.5-fold the ethanolaminephosphotransferase from virus- or mock-infected cells, whereas the same diglyceride preparations stimulated the cholinephosphotransferase (EC 2.7.8.2) from baby hamster kidney cells by sixfold. Generation of endogenous diglyceride by pretreatment of the microsomes with phospholipase C (EC 3.1.4.3) stimulated the activity of the cholinephosphotransferase but not the ethanolaminephosphotranferase. Semliki Forest virus does not inhibit all microsomal enzymes, since the activities of NADH- K3Fe(CN)6 reductase and NADH dehydrogenase (EC 1.6.99.3) were not affected. The ethanolaminephosphotransferase from virus- and mock-infected cells showed similar profiles of activity as a function of temperature; this result and other studies suggest that that membranous environment of the ethanolaminephosphotransferase was not significantly modified by the virus.
...
PMID:Inhibition of phosphatidylethanolamine biosynthesis in baby hamster kidney-21 cells infected with Semliki Forest virus. 17 Oct 43

Mitochondria and microsomes from whole rat testis, seminiferous tubules and Leydig cells were investigated with respect to their capacity to generate superoxide anion. In addition, lipid peroxidation by whole testis mitochondria and microsomes was measured. In the presence of NADH and various respiratory inhibitors all three mitochondrial preparations catalyzed the formation of superoxide anion at a rate of 0.27-1.67 nmol/min.mg. This formation was concluded to be confined mainly to the NADH dehydrogenase region of the respiratory chain. Addition of NADPH to whole testis or Leydig cell mitochondria, but not tubule mitochondria, caused an additional formation of superoxide anion, which was unrelated to the respiratory chain, accelerated several-fold by menadione, and presumably catalyzed by NADPH-cytochrome c reductase and cytochrome P-450. Microsomes isolated from whole testis, seminiferous tubules, and Leydig cells generated superoxide anion at rates between 0.19 and 0.44 nmol/min.mg. These rates were also strongly stimulated by menadione. It is likely that both NADPH-cytochrome c reductase and cytochrome P-450 were involved in the microsomal generation of superoxide. Free radical scavengers of various types inhibited both the mitochondrial and microsomal formation of superoxide anion. Lipid peroxidation in whole testis essentially paralleled superoxide anion generation. However, the rate of mitochondrial lipid peroxidation was twice that of the microsomal rate. It is concluded that seminiferous tubules and Leydig cells generate superoxide anion at different rates and by different mechanisms. Together with cytochrome P-450-dependent hydroxylases, e.g., BP and DMBA hydroxylases, this superoxide generation may reflect a potential for cell-specific peroxidative damage in the testis.
...
PMID:Generation of superoxide anion and lipid peroxidation in different cell types and subcellular fractions from rat testis. 284 Jul 54

Results of comparative studies on stimulation of the rates of cofactor consumption, superoxide generation and hydrogen peroxide production by mitoxantrone (Novantrone; dihydroxyanthracenedione; MXN), ametantrone (AM), doxorubicin (DOX) and daunorubicin (DNR) in the presence of NADPH-cytochrome P-450 reductase, NADH dehydrogenase, or rabbit hepatic microsomes have been reported. MXN and AM were substantially less effective in stimulating the rate of cofactor oxidation, superoxide formation or hydrogen peroxide production relative to the anthracyclines. In the presence of P-450 reductase, the rate of NADPH oxidation or superoxide generation produced by 100 microM MXN or AM was only 15% and 2% respectively of that produced by 100 microM anthracycline. The effects of MXN and AM on lipid peroxidation in hepatic microsomes, cardiac sarcosomes and cardiac mitochondria were determined and compared with those produced by ADM. MXN and AM at 50 microM inhibited the basal rate of NADPH-dependent rabbit liver microsomal lipid peroxidation by 50%; in contrast, DOX enhanced the rate of hepatic microsomal lipid peroxidation by 2- and 2.5-fold at 100 and 200 microM, respectively. Rabbit cardiac sarcosomal NADPH-dependent lipid peroxidation was inhibited completely at 100 microM anthracenedione. NADH-dependent lipid peroxidation in cardiac mitochondria was diminished by 50 microM MXN and AM, whereas 50 microM DOX produced a 2-fold stimulation in lipid peroxidation. The anthracenediones also effectively inhibited DOX-stimulated lipid peroxidation with 50% inhibition occurring at 4 microM (MXN) and 6 microM (AM). Moreover, both MXN and AM potently inhibited iron (100 microM)-stimulated lipid peroxidation in rabbit hepatic microsomes with 80% inhibition produced by 15 microM anthracenedione.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Mitoxantrone: propensity for free radical formation and lipid peroxidation--implications for cardiotoxicity. 299 Nov 63

We report the identification of an NADH-dependent haem-degrading system in ox heart mitochondria. The activity was localized to the mitochondrial inner membrane, specifically associated with complex I (NADH:ubiquinone oxidoreductase). The mitochondrial NADH-dependent haem-degradation activity was highly effective and displayed a rate nearly 60% higher than that of the microsomal activity. The following observations suggested the enzymic nature of the activity: (i) haem degradation by complex I did not proceed upon exposure to elevated temperature and extremes of pH; (ii) it displayed substrate specificity; (iii) it was inhibited by a substrate analogue; and (iv) it showed a cofactor requirement. Moreover, the activity was distinctly different from the ascorbate-mediated haem-degradation activity. Also, complex I differed from the microsomal NADPH:cytochrome c (P-450) reductase inasmuch as the formation of an effective interaction with the microsomal haem oxygenase could not be detected. Addition of purified haem oxygenase to complex I neither influenced the rate of haem degradation nor resulted in the formation of biliverdin IX alpha. In contrast, addition of haem oxygenase to NADPH:cytochrome c (P-450) reductase enhanced the rate of haem degradation by nearly 8-fold, and more than 60% of the degraded haem could be accounted for as biliverdin IX alpha. The haem-degrading activity of complex I appeared to involve the activity of H2O2, as the reaction was inhibited by nearly 90% by catalase, and propentdyopents were detected as reaction products. Intact haemoproteins such as cytochrome c and myoglobin were not effective substrates. However, the haem undecapeptide of cytochrome c was degraded at a rate equal to that observed for haem. Haematohaem was degraded at a rate 50% lower than that observed for haem. It is suggested that the NADH-dependent haem-degradation system may have a biological role in the regulation of the concentration of respiratory haemoproteins and the disposition of the aberrant forms of the mitochondrial haemoproteins.
...
PMID:Characterization of an NADH-dependent haem-degrading system in ox heart mitochondria. 312 Jun 97

6-Chloro-1,2,3-benzothiadiazole (6-Cl-BTD) is an effective inhibitor of NADH oxidase (site I) but not of succinate oxidase in beef heart submitochondrial particles. For NADH oxidase activity maximal inhibition (80-85%) was achieved at 0.75mM 6-Cl-BTD. A similar level of inhibition was also observed (half maximal inhibitory concentration 0.5mM) towards NADH-duroquinone reductase; NADH-juglone reductase was slightly inhibited (23%) at 0.5mM 6-Cl-BTD while NADH-ferricyanide reductase was unaffected. The data suggest that 6-Cl-BTD interacts with an electron transport site on the oxygen side of NADH dehydrogenase and inhibitory studies with 6-Cl-BTD and rotenone indicate that it might correspond with one of the two sites affected by rotenone. The substituted 1,2,3-benzothiadiazoles (BTDs) are perhaps best known for their activity as inhibitors of cytochrome P-450-mediated mixed-function oxidation (MFO). In vitro, the BTDs are potent inhibitors of MFO activities in microsomes from mammalian liver and insect tissues and they have been demonstrated to inhibit aminopyrine metabolism in perfused rat liver. In vivo, they reportedly prolong hexobarbital sleeping time in mice, inhibit the irreversible binding of labeled trichloro-ethylene to microsomal protein and effectively enhance the toxicity (synergize) of pyrethrin, organophosphorus-containing and carbamate insecticides to insects.
...
PMID:The locus of inhibition of NADH oxidation by benzothiadiazoles in beef heart submitochondrial particles. 370 93

1. Paraquat and diquat produce only a slight increase in the oxygen uptake of rat liver mitochondria, and it is likely that they do not penetrate the mitochondrial membrane. 2. In mitochondrial fragments inhibited by antimycin A or by Amytal, both substances stimulate oxygen uptake with NADH or beta-hydroxybutyrate as substrate but not with succinate. The NADH dehydrogenase of the respiratory chain appears to be involved, at a site only partially inhibited by Amytal. 3. An NADPH oxidase activity is stimulated in rat liver microsomes by diquat, and to a smaller extent by paraquat; diquat also causes an NADH oxidase activity to develop. The effect is not inhibited by carbon monoxide or p-chloromercuribenzoate, and it is probable that a flavoprotein is involved by a mechanism not requiring thiol groups. 4. One molecule of oxygen can oxidize two molecules of NADPH in the stimulated microsomal system, the hydrogen peroxide produced being broken down by a catalase activity in the microsomes. 5. Diquat can stimulate NADH oxidase and NADPH oxidase activity in the postmicrosomal soluble fraction; the enzyme involved may be DT-diaphorase. 6. The mechanism of these reactions and their significance in relation to the toxicity of the dipyridilium compounds are discussed.
...
PMID:The action of paraquat and diquat on the respiration of liver cell fractions. 438 31

1. Rat liver mitochondria were separated on the basis of their sedimentation coefficients in an iso-osmotic gradient of Ficoll-sucrose by rate zonal centrifugation. The fractions (33, each of 40ml) were collected in order of decreasing density. Fractions were analysed by spectral analysis to determine any differences in the concentrations of the cytochromes and by enzyme analyses to ascertain any differences in the activities of NADH dehydrogenase, succinate dehydrogenase and alpha-glycerophosphate dehydrogenase. 2. When plotted as% of the highest specific concentration, the contents of cytochrome a+a(3) and cytochrome c+c(1) were constant in all fractions but cytochrome b was only 65% of its maximal concentration in fraction 7 and increased with subsequent fractions. As a result, the cytochrome b/cytochrome a+a(3) ratio almost doubled between fractions 7 and 25 whereas the cytochrome c+c(1)/cytochrome a+a(3) ratio was unchanged. 3. Expression of the dehydrogenase activities as% of highest specific activity showed the following for fractions 6-26: NADH dehydrogenase activity remained fairly constant in all fractions; succinate dehydrogenase activity was 62% in fraction 6 and increased steadily to its maximum in fraction 18 and then decreased; the activity of alpha-glycerophosphate dehydrogenase was only 53% in fraction 6 and increased slowly to its peak in fractions 22 and 24. 4. These differences did not result from damaged or fragmented mitochondria or from microsomal contamination. 5. These results demonstrate that isolated liver mitochondria are biochemically heterogeneous. The importance of using a system for separating biochemically different mitochondria in studies of mitochondrial biogenesis is discussed.
...
PMID:Biochemical heterogeneity of rat liver mitochondria separated by rate zonal centrifugation. 467 5

The reduction and the potential autoxidation of quinoid compounds may be viewed as taking place in three cell compartments. In microsomal fractions (endoplasmic reticulum) one-electron reduction by NAPDH-cytochrome P450 reductase leads to the formation of semiquinones which rapidly react with oxygen to form the parent quinone and superoxide anions. The formation of superoxide through this futile cycle leads ultimately to other damaging species (H2O2 and .OH). A similar futile cycle in mitochondria involves NADH dehydrogenase. In this instance, mitochondria initiation of such a cycle with quinones results not only in the formation of toxic radical species but also in the diversion of electrons from phosphorylating pathways. The consequent diminution of cellular ATP may have as important a consequence with respect to the toxicity of quinones as the generation of radicals. Finally, cytosolic DT diaphorase, which carries out a two-electron reduction of quinones to more stable hydroquinones, may compete with the one-electron systems and participate in the detoxification of quinones by supplying hydroquinones for conjugation reactions. The extent of quinone-induced damage may thus vary from cell to cell depending on the integration of these pathways.
...
PMID:Futile redox cycling: implications for oxygen radical toxicity. 631 61

Both respiratory-competent and respiratory-deficient yeast cells reduce external ferricyanide. The reduction is stimulated by ethanol and inhibited by the alcohol dehydrogenase inhibitor, pyrazole. The reduction of ferricyanide is not inhibited by inhibitors of mitochondrial or microsomal ferricyanide reduction. Cells in exponential-phase growth show a much higher rate of ferricyanide reduction. The reduction of ferricyanide is accompanied by increased release of protons by the yeast cells. We propose that the ferricyanide reduction is carried out by a transmembrane NADH dehydrogenase.
...
PMID:Transmembrane ferricyanide reduction by cells of the yeast Saccharomyces cerevisiae. 704 21

1 2 3 Next >>