Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.6.99.5 (NADH dehydrogenase)
 2,135 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

It has been reported that N-methyl-beta-carbolinium analogues of the neurotoxic N-methyl-4-phenylpyridinium cation (MPP+) inhibit NADH-linked mitochondrial oxidations, as well as mitochondrial respiration on succinate nearly to the same extent [Fields, Albores, Neafsey and Collins (1992) Arch. Biochem. Biophys. 294, 539-544]. Those authors further claimed that MPP+ itself also blocks respiration through succinate dehydrogenase, in addition to its well-known effect on NADH dehydrogenase (Complex I), and concluded that both effects may contribute to the development of Parkinsonian symptoms. Since N-methyl-beta-carboliniums are thought to be endogenous metabolites, these findings, if verified, would have important implications on the etiology of idiopathic Parkinsonism. We have re-examined these observations, using mitochondria after full activation of succinate dehydrogenase, as well as submitochondrial particles, in which complexities due to membrane transport are not present. We report the following observations. (1) N-Methyl-beta-carboliniums inhibit mitochondrial respiration on NAD(+)-linked substrates in a time-dependent manner, and the inhibition is potentiated by the presence of tetraphenylboron anion (TPB-), as expected for positively charged compounds. (2) Unlike MPP+ itself, however, these compounds are uncouplers at higher concentrations, so that the effects seen in State 3 cannot be assigned exclusively to inhibition of NADH oxidation. (3) The effects on succinate oxidation in mitochondria, in which the full activity of the enzyme is expressed, are 1-1.5 orders of magnitude lower than on respiration via Complex I and are thus unlikely to contribute significantly to the neurotoxicity. (4) The effect of MPP+ on mitochondrial respiration via succinate dehydrogenase is trivial, in accord with previous reports from several laboratories, but contradicting the findings of Fields et al. (cited above). (5) In submitochondrial particles the inhibition of NADH oxidation (via the complete respiratory chain) has been confirmed, but it differs markedly from the action of MPP+ in two respects. First, the enhancement by TPB- is very small; secondly, the inhibition of NADH oxidation measured using ubiquinone (Q) analogues is far lower, suggesting that Complex I is not the only target. (6) In submitochondrial particles the inhibition of succinate oxidation by either O2 or Q analogues is incomplete, trivial or absent. (7) We thus conclude that we find no basis for assigning any potential biological effect of N-methyl-beta-carboliniums to the blockade of succinate oxidation.
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PMID:Is complex II involved in the inhibition of mitochondrial respiration by N-methyl-4-phenylpyridinium cation (MMP+) and N-methyl-beta-carbolines? 848 93

Effect of the polycation on oxidative phosphorylation in the rat liver mitochondria has been studied. Both oxygen uptake and coupled phosphorylation were progressively inhibited by increasing concentration of the polycation, as observed with NAD-linked substrates, succinate and ascorbate+TMPD which activates the terminal part of the respiratory chain. NADH oxidase, NADH dehydrogenase and cytochrome oxidase were strongly inhibited by the polycation, 80-90% of the activity being lost at an inhibitor concentration of 100 microM. Succinate oxidase and succinate dehydrogenase were inhibited 60-66% at 100 microM concentration of the polycation. The polycation inhibited the uncoupler 2,4-dinitrophenol stimulated ATPase activity both in presence and absence of Mg2+ ions. The polycation also inhibited salt-induced volume change.
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PMID:Inhibition of mitochondrial oxidative phosphorylation and its electron transport pathway by a polycation in vitro. 850 25

Studies were undertaken to investigate the principal actions underlying mercury-induced oxidative stress in the kidney. Mitochondria from kidneys of rats treated with HgCl2 (1.5 mg/kg i.p.) demonstrated a 2-fold increase in hydrogen peroxide (H2O2) formation for up to 6 hr following Hg(II) treatment using succinate as the electron transport chain substrate. No increase in H2O2 formation was observed when NAD-linked substrates (malate/glutamate) were used, suggesting that Hg(II) affects H2O2 formation principally at the ubiquinone-cytochrome b region of the mitochondrial respiratory chain in vivo. Together with increased H2O2 formation, mitochondrial glutathione (GSH) content was depleted by more than 50% following Hg(II) treatment, whereas formation of thiobarbiturate reactive substances (TBARS), indicative of mitochondrial lipid peroxidation, was increased by 68%. Studies in vivo revealed a significant concentration-related depolarization of the inner mitochondrial membrane following the addition of Hg(II) to mitochondria isolated from kidneys of untreated rats. This effect was accompanied by significantly increased H2O2 formation, GSH depletion and TBARS formation linked to both NADH dehydrogenase (rotenone-inhibited) and ubiquinone-cytochrome b (antimycin-inhibited) regions of the electron transport chain. Oxidation of pyridine nucleotides (NAD[P]H) was also observed in mitochondria incubated with Hg(II) in vitro. In further studies in vitro, the potential role of Ca2+ in Hg(II)-induced mitochondrial oxidative stress was investigated. Ca2+ alone (30-400 nmol/mg protein) produced no increase in H2O2 and only a slight increase in TBARS formation when incubated with kidney mitochondria isolated from untreated rats. However, Ca2+ significantly increased H2O2 and TBARS formation elicited by Hg(II) at the ubiquinone-cytochrome b region of the mitochondrial electron transport chain, whereas TBARS formation was decreased significantly when the Ca2+ uptake inhibitors, ruthenium red or [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (EGTA), were included with Hg(II) in the reaction mixtures. These findings support the view that Hg(II) causes depolarization of the mitochondrial inner membrane with consequent increased H2O2 formation. These events, coupled with Hg(II)-mediated GSH depletion and pyridine nucleotide oxidation, create an oxidant stress condition characterized by increased susceptibility of mitochondrial membranes to iron-dependent lipid peroxidation (TBARS formation). Since increased H2O2 formation, GSH depletion and lipid peroxidation were also observed in vivo following Hg(II) treatment, these events may underlie oxidative tissue damage caused by mercury compounds. Moreover, Hg(II)-induced alterations in mitochondrial Ca2+ homeostasis may exacerbate Hg(II)-induced oxidative stress in kidney cells.
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PMID:Studies on Hg(II)-induced H2O2 formation and oxidative stress in vivo and in vitro in rat kidney mitochondria. 851 85

There are multiple routes of NAD(P)H oxidation associated with the inner membrane of plant mitochondria. These are the phosphorylating NADH dehydrogenase, otherwise known as Complex I, and at least four other nonphosphorylating NAD(P)H dehydrogenases. Complex I has been isolated from beetroot, broad bean, and potato mitochondria. It has at least 32 polypeptides associated with it, contains FMN as its prosthetic group, and the purified enzyme is sensitive to inhibition by rotenone. In terms of subunit complexity it appears similar to the mammalian and fungal enzymes. Some polypeptides display antigenic similarity to subunits from Neurospora crassa but little cross-reactivity to antisera raised against some beef heart complex I subunits. Plant complex I contains eight mitochondrial encoded subunits with the remainder being nuclear-encoded. Two of these mitochondrial-encoded subunits, nad7 and nad9, show homology to corresponding nuclear-encoded subunits in Neurospora crassa (49 and 30 kDa, respectively) and beef heart CI (49 and 31 kDa, respectively), suggesting a marked difference between the assembly of CI from plants and the fungal and mammalian enzymes. As well as complex I, plant mitochondria contain several type-II NAD(P)H dehydrogenases which mediate rotenone-insensitive oxidation of cytosolic and matrix NADH. We have isolated three of these dehydrogenases from beetroot mitochondria which are similar to enzymes isolated from potato mitochondria. Two of these enzymes are single polypeptides (32 and 55 kDa) and appear similar to those found in maize mitochondria, which have been localized to the outside of the inner membrane. The third enzyme appears to be a dimer comprised of two identical 43-kDa subunits. It is this enzyme that we believe contributes to rotenone-insensitive oxidation of matrix NADH. In addition to this type-II dehydrogenases, several observations suggest the presence of a smaller form of CI present in plant mitochondria which is insensitive to rotenone inhibition. We propose that this represents the peripheral arm of CI in plant mitochondria and may participate in nonphosphorylating matrix NADH oxidation.
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PMID:Functional molecular aspects of the NADH dehydrogenases of plant mitochondria. 859 75

Studies on the effect of various Cd2+ concentrations on substrate oxidation by whole cells of cadmium-sensitive Staphylococcus aureus 17810S showed that oxidation of glutamate or pyruvate was highly sensitive to low Cd2+ concentrations (5 microM), whereas L-lactate oxidation was insensitive even to high Cd2+ concentrations (100 microM). Location of the cadmium-sensitive targets in the enzyme systems involved in oxidation of these substrates was studied in subcellular fractions prepared from cells pretreated with 5 or 100 microM Cd2+. Activities of the cytoplasmic 2-oxoglutarate dehydrogenase complex (ODHC)') and pyruvate dehydrogenase complex (PDHC) were strongly inhibited with 5 microM Cd2+, while with 100 microM Cd2+ the inhibition was almost complete. In contrast, activities of the cytoplasmic NAD-dependent glutamate dehydrogenase (NAD-GDH), the membrane-bound NADH dehydrogenase (NDH) and HQNO-sensitive NADH oxidase were not sensitive to 100 microM Cd2+. These data indicate that the accessible, cadmium-sensitive targets are located only in the cytoplasmic ODHC and PDHC. It is postulated that two vicinal dithiols present in ODHC and PDHC may be regarded as the primary cadmium-sensitive targets in the systems oxidizing glutamate or pyruvate. Since activities of the membrane-bound NAD-independent L-lactate dehydrogenase (iLDH) and HQNO-sensitive L-lactate oxidase were not affected by 100 microM Cd2+, this indicates that the L-lactate oxidizing system lacks the accessible, cadmium-sensitive targets. The mechanism of Cd2+ toxicity to energy conservation with glutamate, pyruvate or L-lactate in S. aureus is discussed.
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PMID:Cadmium-sensitive targets in the aerobic respiratory metabolism of Staphylococcus aureus. 895 92

Considerable quantitative variations in the competitive inhibition of NADH oxidase activity of bovine heart submitochondrial particles (SMP) by different samples of NAD- were observed. ADP-ribose (ADPR) was identified as the inhibitory contaminating substance responsible for variations in the inhibition observed. ADPR competitively inhibits NADH oxidation with Ki values (25 degrees C, pH 8.0) of 26 microM, 30 microM, and 180 microM for SMP, purified Complex I and three-subunit NADH dehydrogenase (FP), respectively. ADPR decreases NADH-induced flavin reduction and prolongs the cyclic bleaching of FP during aerobic oxidation of NADH. Ki for inhibition of the rotenone-sensitive NADH oxidase in SMP by ADPR does not depend on delta mu H+. The initial rate of the energy-dependent NAD+ reduction by succinate is insensitive to ADPR. The inhibitor increases the steady-state level of NAD+ reduction reached during aerobic succinate-supported reverse electron transfer catalyzed by tightly coupled SMP. The results obtained are consistent with the proposal on different nucleotide-binding sites operating in the direct and reverse reactions catalyzed by the mitochondrial NADH-ubiquinone reductase.
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PMID:A competitive inhibition of the mitochondrial NADH-ubiquinone oxidoreductase (complex I) by ADP-ribose. 923 Sep 20

Chlorophyll fluorescence measurements were performed on osmotically lysed potato chloroplasts in order to characterize the reactions involved in the dark reduction of photosynthetic inter-system chain electron carriers. Addition of NADH or NADPH to lysed chloroplasts increased the chlorophyll fluorescence level measured in the presence of a non-actinic light until reaching Fmax, thus indicating an increase in the redox state of the plastoquinone (PQ) pool. The fluorescence increase was more pronounced when the experiment was carried out under anaerobic conditions and was about 50% higher when NADH rather than NADPH was used as an electron donor. The NAD(P)H-PQ oxidoreductase reaction was inhibited by diphenylene iodonium, N-ethylmaleimide and dicoumarol, but insensitive to rotenone, antimycin A and piericidin A. By comparing the substrate specificity and the inhibitor sensitivity of this reaction to the properties of spinach ferredoxin-NADP+-reductase (FNR), we infer that FNR is not involved in the NAD(P)H-PQ oxidoreductase activity and conclude to the participation of rotenone-insensitive NAD(P)H-PQ oxidoreductase. By measuring light-dependent oxygen uptake in the presence of DCMU, methyl viologen and NADH or NADPH as an electron donors, the electron flow rate through the NAD(P)H-PQ oxidoreductase is estimated to about 160 nmol O2 min-1 mg-1 chlorophyll. The nature of this enzyme is discussed in relation to the existence of a thylakoidal NADH dehydrogenase complex encoded by plastidial ndh genes. Copyright 1998 Elsevier Science B.V.
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PMID:Reduction of the plastoquinone pool by exogenous NADH and NADPH in higher plant chloroplasts. Characterization of a NAD(P)H-plastoquinone oxidoreductase activity 952 46

Maintenance of a cytoplasmic redox balance is a necessity for sustained cellular metabolism. Glycerol formation is the only way by which Saccharomyces cerevisiae can maintain this balance under anaerobic conditions. Aerobically, on the other hand, several different redox adjustment mechanisms exist, one of these being the glycerol 3-phosphate (G3P) shuttle. We have studied the importance of this shuttle under aerobic conditions by comparing growth properties and glycerol formation of a wild-type strain with that of gut2 delta mutants, lacking the FAD-dependent glycerol 3-phosphate dehydrogenase, assuming that the consequent blocking of G3P oxidation is forcing the cells to produce glycerol from G3P. To impose different demands on the redox adjustment capability we used various carbon sources having different degrees of reduction. The results showed that the shuttle was used extensively with reduced substrate such as ethanol, whereas the more oxidized substrates lactate and pyruvate, did not provoke any activity of the shuttle. However, the absence of a functional G3P shuttle did not affect the growth rate or growth yield of the cells, not even during growth on ethanol. Presumably, there must be alternative systems for maintaining a cytoplasmic redox balance, e.g. the so-called external NADH dehydrogenase, located on the outer side of the inner mitochondrial membrane. By comparing the performance of the external NADH dehydrogenase and the G3P shuttle in isolated mitochondria, it was found that the former resulted in high respiratory rates but a comparably low P/O ratio of 1.2, whereas the shuttle gave low rates but a high P/O ratio of 1.7. Our results also demonstrated that of the two isoforms of NAD-dependent glycerol 3-phosphate dehydrogenase, only the enzyme encoded by GPD1 appeared important for the shuttle, since the enhanced glycerol production that occurs in a gut2 delta strain proved dependent on GPD1 but not on GPD2.
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PMID:The importance of the glycerol 3-phosphate shuttle during aerobic growth of Saccharomyces cerevisiae. 955 43

Isoniazid is the most widely used antituberculosis drug. Genetic studies in Mycobacterium smegmatis identified the inhA-encoded, NADH-dependent enoyl acyl carrier protein reductase as the primary target for this drug. A reactive form of isoniazid inhibits InhA by reacting with the NAD(H) cofactor bound to the enzyme active site forming a covalent adduct (isonicotinic acyl NADH) that is apt to bind with high affinity. Resistance can occur by increased expression of InhA or by mutations that lower the enzyme's affinity to NADH. Both of these resistance mechanisms are observed in 30% of clinical tuberculosis isolates. Mutation in katG, which encodes catalase peroxidase, is the most common source for resistance. Another mechanism for isoniazid resistance, in M. smegmatis, occurs by defects in NADH dehydrogenase (Ndh) of the respiratory chain. Genetic data indicated that ndh mutations confer resistance by lowering the rate of NADH oxidation and increasing the intracellular NADH/NAD+ ratio. An increased amount of NADH may prevent formation of isonicotinic acyl NADH or may promote displacement of the isonicotinic acyl NADH from InhA. While our studies have identified this mechanism in M. smegmatis, results reported in early literature lead us to believe that it can occur in Mycobacterium tuberculosis.
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PMID:Mechanisms for isoniazid action and resistance. 994 10

The oxidation of matrix and cytosolic NADH by isolated beetroot and wheat leaf mitochondria was investigated to determine whether the rotenone-insensitive NADH dehydrogenases of plant mitochondria were the products of nuclear or mitochondrial genes. After aging beetroot tissue (slicing and incubating in a CaSO4 solution), the induction of the level of matrix NADH oxidation in the presence of rotenone was greatly reduced in mitochondria isolated from tissue treated with cycloheximide, a nuclear protein synthesis inhibitor. This was also true for the oxidation of cytosolic NADH. Mitochondria isolated from chloramphenicol-treated tissue exhibited greatly increased levels of both matrix and external rotenone-insensitive NADH oxidation when compared to the increase due to the aging process alone. This increase was not accompanied by an increase in matrix NAD-linked substrate dehydrogenases such as malic enzyme nor intra-mitochondrial NAD levels. Possible explanations for this increase in rotenone-insensitive NADH oxidation are discussed. Based on these results we have concluded that the matrix facing rotenone-insensitive NADH dehydrogenase of plant mitochondria is encoded by a nuclear gene and synthesis of the protein occurs in the cytosol.
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PMID:The nuclear origin of the non-phosphorylating NADH dehydrogenases of plant mitochondria. 1041 91


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