Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.3.5.1 (succinate dehydrogenase)
 8,177 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nucleoside analogues can induce mitochondrial dysfunction leading to severe clinical syndromes. Lamivudine, a new nucleoside analogue, is an active inhibitor of hepatitis B viral replication without apparent clinical toxicity. To assess subclinical mitochondrial toxicity, we studied the morphology and function of the mitochondrial system in 15 patients treated with lamivudine. Morphology was investigated by routine histological evaluation and electron-microscopic studies of mitochondria in liver biopsy specimens. Mitochondrial function was assessed by 2-keto[1-14C] isocaproic acid decarboxylation (KICA breath test) and by measuring the activity in liver biopsy specimens of the mitochondrial enzymes encoded by nuclear and mitochondrial DNA (mt-DNA) (complex I and IV) as well as a mitochondrial and a cytosolic enzyme both encoded by nuclear DNA only (complex II and lactic dehydrogenase [LDH]). All 15 patients underwent a liver biopsy before treatment and a KICA breath test before and during treatment; 13 agreed to undergo a repeat liver biopsy during lamivudine treatment. Liver tissue with no or minimal fibrotic changes from 7 patients treated for 6 months with lamivudine was suitable for assessment of the mitochondrial enzyme activity. We observed no signs of toxicity by routine histological or electron-microscopic evaluation. KICA breath tests revealed no differences in either peak exhalation or the area under the curve from 0 to 60 minutes between healthy controls (3.0% and 19.3%), untreated patients with chronic hepatitis B (3.4% and 19.3%), and patients treated with lamivudine (3.1% and 20.6%). The activities of the mt-DNA-encoded enzymes remained normal after lamivudine therapy. Unexpectedly a significant decrease in the activity of nuclear-DNA-encoded enzymes in patients with chronic hepatitis B in comparison with normal controls was found. The mean activity of complex II dropped from 45.3 to 20.0 micromol x min(-1), that of lactic dehydrogenase from 106 to 44 micromol x min(-1) (Wilcoxon rank sum; P < .05). In conclusion, no subclinical signs of mitochondrial toxicity resulting from lamivudine therapy for 6 months were observed.
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PMID:Effect of lamivudine on morphology and function of mitochondria in patients with chronic hepatitis B. 921 72

Correcting action of vitamin E and it's short chain derivative on the activity of some mitochondria electron transport chain enzymes were investigated on models of acute and chronic toxic hepatitis. Inhibition of NADH- and succinate-cytochrome c oxidoreductase complexes activity was established in short term action of xenobiotics. Treatment of rats with CCl4 during 60 days lowered activity of NADH-cytochrome c oxidoreductase complex and significantly increased activity of succinate-cytochrome c oxidoreductase complex and succinate dehydrogenase. Obviously, as a result of long term influence of hepatotoxic agents switching over in rat mitochondria electron transport from NAD-dependent way of substrate oxidation to succinate-dependent way took place. This event could be a part of the body adaptation mechanisms. Vitamin E and its short chain analogue corrected activities of investigated enzymes of mitochondria liver in the animals with acute and chronic hepatitis.
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PMID:[Correction of the activity of certain enzymes in the rat liver mitochondrial electron transport chain by derivatives of alpha-tocopheryl acetate in toxic damage to the liver]. 1079 Oct 53

Hepatic oncocytes with abundant granular, eosinophilic cytoplasm due to mitochondrial hyperplasia are seen in various chronic liver diseases, particularly chronic hepatitis and cirrhosis. Increased mitochondria in oncocytes are thought to be a compensatory mechanism for deficiencies in the hepatocellular respiratory chain, although the pathogenesis of these deficiencies has been uncertain. We selected seven cases of cirrhosis (six with oncocytes, one without) for the following analysis: histoenzymatic and immunohistochemical staining of several mitochondrial DNA (mtDNA)- and nuclear DNA (nDNA)-encoded respiratory chain enzymes; immunostaining using antibodies against double-strand-DNA (anti-DNA) and against Ki-67 (a cell proliferation marker); and Southern blot analysis for mtDNA and nDNA. Eighty percent of oncocytes showed histoenzymatic and immunohistochemical deficiencies of cytochrome c oxidase and the mtDNA-encoded subunit I of complex IV, with preserved expression of nDNA-encoded succinate dehydrogenase and the iron-sulfur subunit of complex III (FeS). Cytoplasmic (but not nuclear) anti-DNA staining was partially or completely absent in approximately 50% of oncocytes. Three cases with oncocytes studied by Southern blot showed mtDNA reductions of 66%, 71%, and 85%. In conclusion, hepatic oncocytes demonstrate significant deficiencies of mtDNA and mtDNA-encoded respiratory chain enzymes. We propose that mtDNA depletion plays an important role in hepatocellular oncocytic transformation.
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PMID:Mitochondrial DNA dysfunction in oncocytic hepatocytes. 1470 2

Hepatitis C infection causes a state of chronic oxidative stress, which may contribute to fibrosis and carcinogenesis in the liver. Previous studies have shown that expression of the HCV core protein in hepatoma cells depolarized mitochondria and increased reactive oxygen species (ROS) production, but the mechanisms of these effects are unknown. In this study we examined the properties of liver mitochondria from transgenic mice expressing HCV core protein, and from normal liver mitochondria incubated with recombinant core protein. Liver mitochondria from transgenic mice expressing the HCV proteins core, E1 and E2 demonstrated oxidation of the glutathione pool and a decrease in NADPH content. In addition, there was reduced activity of electron transport complex I, and increased ROS production from complex I substrates. There were no abnormalities observed in complex II or complex III function. Incubation of control mitochondria in vitro with recombinant core protein also caused glutathione oxidation, selective complex I inhibition, and increased ROS production. Proteinase K digestion of either transgenic mitochondria or control mitochondria incubated with core protein showed that core protein associates strongly with mitochondria, remains associated with the outer membrane, and is not taken up across the outer membrane. Core protein also increased Ca(2+) uptake into isolated mitochondria. These results suggest that interaction of core protein with mitochondria and subsequent oxidation of the glutathione pool and complex I inhibition may be an important cause of the oxidative stress seen in chronic hepatitis C.
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PMID:Hepatitis C virus core protein inhibits mitochondrial electron transport and increases reactive oxygen species (ROS) production. 1615 Jul 32

Mitochondria play a central role in cellular energy metabolism. Oxidative phosphorylation occurs in the electron transport system of the inner mitochondrial membrane. Cytochrome aa3, b and c1 are encoded by mitochondrial DNA whereas cytochrome c is encoded by the nuclear gene, and these mitochondrial-DNA dependent cytochromes are decreased and electron transport at complex II, III and IV is disturbed in liver carcinomas and during carcinogenesis. The more the decreased cytochrome and oxidase activity are seen, the more significant is the increase in reactive oxygen species (ROS) production. ROS produced in mitochondria may be the main cause of nuclear-gene mutation in carcinogenesis. The mitochondrial dysfunction and overproduction of ROS plays a key role in progression of chronic hepatitis C and ethanol-induced liver injury. Ethanol also causes bacterial translocation in the intestine and the resulting lipopolysaccharides (LPS) activates Kupffer cells to produce pro-inflammatory cytokines. We suspect that non-alcoholic steatohepatitis (NASH) also is the result of increased ROS production in Kupffer cells and hepatocytes.
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PMID:Central role of mitochondria in metabolic regulation of liver pathophysiology. 1756 55