Effects of Insect-Growth-Regulatory Benzimidazole Derivatives on Cultured Integument of the Rice Stem Borer and Mitochondria from Rat Liver

The larvicidal activities of benzimidazole derivatives with a terpenoid side chain on the rice stem borer and the silkworm were compared with such in vitro activities as the growth inhibition of the cultured integument of the rice stem borer and the respiration inhibition of rat liver mitochondria. Each larvicidal activity is parallel with these in vitro activities. The comparisons of their activities with those of rotenone and diflubenzuron indicate that the benzimidazoles mainly acted as respiration inhibitors in their larvicidal activity as well as causing cuticular growth inhibition. The activity of 1-(3,7-dimethyl-7-ethoxy-2-octenyl)-2-methylbenzimidazole, the most potent compound tested as a respiration inhibitor, was found to be about 6-fold higher than that of rotenone. In the respiratory chain, the site between NADH and ubiquinone was blocked, indicating that the larvicidal benzimidazoles shared a mode of action with those of rotenone, piericidins, and ubicidines.     

The interaction of rubroskyrin, a modified bis-anthraquinone pigment fromPenicillium islandicum Sopp, with respiratory chain of liver mitochondria

Summary  Rubroskyrin, a modified bisanthraquinone pigment from an yellow rice moldPenicillium islandicum Sopp, was examined for its redox-interaction with the mitochondrial respiratory chain by using rat liver submitochondrial particles (SMP) and was compared with luteoskyrin and rugulosin. Rubroskyrin showed a redox interaction with the NAD-linked respiratory chain of SMP, promoting NADH oxidase in the presence of rotenone, a specific inhibitor to coupling site I of the respiratory chain. Rubroskyrin-mediated NADH oxidase was not inhibited by antimycin A and cyanide, inhibitors to coupling sites II and III, respectively, indicating a generation of an electron transport shunt from a rotenone-insensitive site of NADH dehydrogenase (complex I) to dissolved oxygen. An electrontransport shunt to cytochromec oxidase from complex I was also observed in the experiment with cytochromec and antimycin A. Rubroskyrin did not interact with succinate-linked respiratory chain. Such enzymatic redox response which generates electron transport shunt was not detected for luteoskyrin and rugulosin in the present study.     

Quinone dependent NADH dehydrogenation in mitochondria-like particles from Setaria digitata, a filarial parasite.

In the cattle filarial parasite, Setaria digitata, the mitochondria-like particles have been shown to possess site I associated oxidative phosphorylation and rotenone sensitive and insensitive pathways for the dehydrogenation of NADH. Quinone depleted mitochondria-like particles show a loss of activity of these NADH dehydrogenases and also a complete loss of fumarate reductase activity. Reconstitution with quinone restores both NADH linked oxygen uptake and fumarate reductase activity. Thus activities of complex I and fumarate reductase are linked to quinone. Hence an inhibitor at the level of quinone can simultaneously block both aerobic and anaerobic pathways which drive ATP production and may prove useful in the effective control of filariasis.     

A novel aerobic respiratory chain-linked NADH oxidase system in Zymomonas mobilis.

Membrane vesicles prepared from Zymomonas mobilis oxidized NADH exclusively, whereas deamino-NADH was little oxidized. In addition, the respiratory chain-linked NADH oxidase system exhibited only a single apparent Km value of approximately 66 microM for NADH. The NADH oxidase was highly sensitive to the respiratory chain inhibitor 2-heptyl-4-hydroxyquinoline-N-oxide. However, the NADH:quinone oxidoreductase was not sensitive to 2-heptyl-4-hydroxyquinoline-N-oxide and was highly resistant to another respiratory chain inhibitor, rotenone. Electron transfer from NADH to oxygen generated a proton electrochemical gradient (inside positive) in inside-out membrane vesicles. In contrast, electron transfer from NADH to ubiquinone-1 generated no electrochemical gradient. These findings indicate that Z. mobilis possesses only NADH:quinone oxidoreductase lacking the energy coupling site.     

The in vitro interaction of the carcinogens, 4-nitroquinoline-N-oxide and its metabolite 4-hydroxylaminoquinoline-N-oxide, with intact rat liver mitochondria.

The inhibition of rat liver mitochondrial respiration caused by rotenone, is relieved by the 2 carcinogens, 4-nitroquinoline-N-oxide (NQO) and its metabolite 4-hydroxylaminoquinoline-N-oxide (HAQO). Thus these agents cause reducing equivalents to circumvent the first coupling site of the respiratory chain. This is another example of the experimental confluence between oxidative phosphorylation and chemical carcinogenesis.     

Evidence that the blockade of mitochondrial respiration by the neurotoxin 1-methyl-4-phenylpyridinium (MPP+) involves binding at the same site as the respiratory inhibitor, rotenone

It has been postulated that 1-methyl-4-phenylpyridinium (MPP+) blocks mitochondrial respiration by combining at the same site as rotenone, a potent inhibitor of NADH oxidation in mitochondria, known to act at the junction of NADH dehydrogenase and coenzyme Q (CoQ). The present experiments show that MPP+ and two of its analogs indeed act in a concentration dependent manner to prevent the binding of [14C]-rotenone to submitochondrial particles (ETP) and significantly decrease the inhibition of electron transport caused by rotenone. It therefore appears that MPP+ binds at the same site as rotenone or an adjacent site, supporting the hypothesis that its neurotoxic action is due to the inhibition of mitochondrial respiration.     

Na+ is translocated at NADH:quinone oxidoreductase segment in the respiratory chain of Vibrio alginolyticus

The coupling site of the Na+ pump to the respiratory chain of Vibrio alginolyticus was examined using membrane fractions prepared from the wild type, Na+ pump-deficient mutants, and spontaneous revertant. NADH oxidase of the wild type and revertant specifically required NA+ for maximum activity, whereas Na+ was not essential for the NADH oxidase of mutants. Similar to the Na+ pump in whole cells, the Na+-dependent NADH oxidase in membranes had a pH optimum in the alkaline region. A respiratory inhibitor, 2-heptyl-4-hydroxyquinoline-N-oxide (HQNO), inhibited the Na+-dependent NADH oxidase but had little effect on the NA+-independent activity of mutant membranes. NADH:quinone oxidoreductase was found to be the Na+-dependent HQNO-sensitive site of the NADH oxidase. In the wild type cells, HQNO was also found to cause a strong inhibition of the Na+ pump with little effect on the overall H+ extrusion by respiration. The inhibition of the Na+ pump by HQNO was overcome by oxidized, but not reduced, N,N,N',N'-tetra-methyl-p-phenylenediamine (TMPD). In the presence of oxidised TMPD, the electron flow NADH to oxygen seemed to bypass the HQNO-sensitive site and energize the Na+ pump. From these results, it was concluded that the Na+ pump is coupled to the respiratory chain at the step of NADH:quinone oxidoreductase.     

Inhibition of NADH oxidation by 1-methyl-4-phenylpyridinium analogs as the basis for the prediction of the inhibitory potency of novel compounds

Inhibition of NADH dehydrogenase (Complex I) of the mitochondrial respiratory chain by 1-methyl-4-phenylpyridinium (MPP⁺) and its analogs results in dopaminergic cell death. In the present study, the inhibition of mitochondrial respiration and of NADH oxidation in inverted inner membrane preparations by the oxidation products of N-methyl-stilbazoles (N-methyl-styrylpyridiniums) are characterized. These nonflexible MPP⁺ analogs were found to be considerably more potent inhibitors than the corresponding MPP⁺ derivatives. The IC₅₀ values for these compounds and previously published figures for MPP⁺ analogs were then used to select a computer model based on structural parameters to predict the inhibitory potency of other compounds that react at the “rotenone site” in Complex I. A series of 12 novel inhibitors different in structure from the basic set were used to test the predictive capacity of the models selected. Despite major structural differences between the novel test compounds and the MPP⁺ and styrylpyridinium analogs on which the models were based, substantial agreement was found between the predicted and experimentally determined IC₅₀ values. The value of this technique lies in the potential for the prediction of the inhibitory potency of other drugs and toxins which block mitochondrial respiration by interacting at the rotenone sites. © 1996 John Wiley & Sons, Inc.     

The Effect of Respiratory Inhibitors on NADH, Succinate and Malate Oxidation in Corn Mitochondria

The effect of a series of respiratory inhibitors on the oxidation of NADH in state 4 and state 3 conditions was studied with corn shoot mitochondria. Comparisons were made using malate and succinate as substrates. The inhibitors, rotenone, amytal, antimycin A and cyanide, inhibited oxidation of NADH in state 3 but rotenone and amytal did not inhibit oxidation in state 4. The inhibition by antimycin A was partially overcome by the presence of cytochrome c. The results indicate the presence of alternative pathways available for NADH oxidation depending on the metabolic condition of the mitochondria. Under state 4 conditions, NADH oxidation bypasses the amytal and rotenone sensitive sites but under state 3 conditions a component of the NADH respiration appears to be oxidized by an internal pathway which is sensitive to these inhibitors. Still a third pathway for NADH oxidation is dependent on the addition of cytochrome c and is insensitive to antimycin A. Succinate oxidation was sensitive to cyanide and antimycin A under both state 4 and state 3 conditions as well as amytal and rotenone under state 3 conditions but was not inhibited by amytal and rotenone under state 4 conditions. Malate oxidation was inhibited by cyanide, rotenone and amytal under both state 4 and state 3 conditions. Antimycin A inhibited state 3 but did not appreciably alter state 4 rates of malate oxidation. With all substrates tested inhibition by antimycin A was greatly facilitated by preswelling the mitochondria for 10 min. This was interpreted to indicate that swelling increases the accessibility of antimycin A to the site of inhibition.     

Action of rotenone and related respiratory inhibitors on mammalian cell division. 1 Cell kinetics and biochemical aspects.

Inhibitors of mitochondrial respiration, phosphorylation inhibitors, and uncoupling agents have been reported to delay or inhibit mitosis in cultured mammalian cells. Although the molecular mechanism by which mitosis is delayed in the presence of most respiratory inhibitors presumably involves lowered ATP production for mitotic requirements, one respiratory inhibitor, rotenone, was determined to arrest mitosis by an unrelated mechanism. Cell cycle kinetics studies, oxygen consumption measurements, and viscosity assays indicate that rotenone arrests cultured mammalian cells in mitosis by inhibiting spindle microtubule assembly by a mechanism analogous with colchicine, Colecemid and related antimitotic drugs. Amytal, which blocks electron transport at the same site as does rotenone, failed to arrest cell progression at mitosis. Rotenone delayed cell progression in all phases of the cell cycle, apparently as a direct result of respiration inhibition. Thus, rotenone appears to exert a dual function on events of the cell cycle.     

Matrix NADH dehydrogenases of plant mitochondria and sites of quinone reduction by complex I.

In order to distinguish the pathways involved in the oxidation of matrix NADH in plant mitochondria, the oxidation of NADH and nicotinamide hypoxanthine dinucleotide (reduced form) was investigated in submitochondrial particles prepared from beetroot (Beta vulgaris L. cv. Derwent Globe) and soybeans (Glycine max L. cv. Bragg). Nicotinamide-hypoxanthine-dinucleotide(reduced form)-oxidase activity was more strongly inhibited by rotenone than the NADH-oxidase activity but both of the rotenone-inhibited activities could be stimulated by adding ubiquinone-1. The corresponding ubiquinone-1-reductase activities were inhibited by rotenone (to 69%) and further inhibited by N,N'-dicyclohexylcarbodiimide (to 79%), whilst the K3Fe(CN)6-reductase activities were not sensitive to either rotenone or N,N'-dicyclohexylcarbodiimide. Immunological analysis of mitochondrial proteins using an antiserum raised against purified beetroot complex I indicated very few differences between soybean and fresh and aged beetroot mitochondria, despite their varying sensitivities to rotenone. We confirm that there are two dehydrogenases capable of oxidising internal NADH and that only one of these, namely complex I, is inhibited by rotenone. Further, we conclude that complex I has two potential sites of quinone reduction, both sensitive to N,N'-dicyclohexycarbodiimide inhibition but only one of which is sensitive to rotenone inhibition.     

Respiratory control depression by tetraalkylammonium bromides in rat liver mitochondria.

Six different lipophilic (hydrophobic) organic cations, tetraethyl-, tetrapropyl, tetrabutyl-, tetrapentyl-, tetrahexyl-, and tetraheptylammonium bromide, depressed respiratory control in rat liver mitochondria. Evaluation of mitochondrial responses in terms of a quadratic equation in log P (an index of lipophilicity) indicated that the NADH dehydrogenase receptor site for inhibitor (diminution of control of glutamate, alpha-ketoglutarate, and beta-hydroxybutyrate respiration) was more lipophilic than receptor sites for flavin-linked substrates (reduction of control of succinate, choline and alpha-glycerophosphate respiration). The succinate dehydrogenase receptor site for inhibition by the tetraalkylammonium bromides was more hydrophillic (less lipophilic) than the choline or alpha-glycerophosphate dehydrogenase receptor sites. Depression of respiratory control may be a function of charge density and of lipophilicity at specific inner membranal sites and the susceptible site may differ for different respiratory substrates.     

Studies of the mitochondria from Eimeria tenella and inhibition of the electron transport by quinolone coccidiostats.

Intact but fragile mitochondria were isolated from unsporulated oocysts of Eimeria tenella. The mitochondria respired in response to succinate, malate plus pyruvate, and L-ascorbate at rates of 1.00, 0.40, and 0.25 mu1 O2/min/mg protein, respectively. Spectrophotometric analyses of the cytochromes in mitochondria and whole oocysts revealed b-type and o-type cytochromes, at roughly similar levels, but no cytochrome c could be detected. The mitochondrial respiration was inhibited by cyanide, azide, carbon monoxide, antimycin A, and 2-heptyl-4-hydroxyquinoline-N-oxide, but was relatively resistant to rotenone and amytal. The quinolone coccidiostats buquinolate, amquinate, methyl benzoquate, and decoquinate were identified as very powerful inhibitiors of succinate and malate plus pyruvate supported respiration in E. tenella mitochondria. None of these four drugs exhibited any inhibitory effect on chicken liver mitochondria. Only 3 pmol of the quinolones per mg mitochondrial protein was needed to achieve 50% inhibition. The inhibition could not be reversed by coenzymes Q6 or Q10. Since the quinolones did not affect L-ascorbate-supported respiration or the activities of submitochondrial succinate dehydrogenase and NADH dehydrogenase, the site of action of the quinolone coccidiostats was tentatively identified as probably near cytochrome b in E. tenella mitochondria. Mitochondria isolated from an E. tenella amquinate-resistant mutant were much less susceptible to quinolone coccidiostats; 50% inhibition was attained by 300 pmol of the drugs/mg mitochondrial protein. The results suggest that the mechanisms of action of quinolone coccidiostats is by inhibiting the cytochrome-mediated electron transport in the mitochondria of coccidia. 2-Hydroxynaphthoquinone coccidiostats were identified as inhibitors of mitochondrial respiration of both E. tenella and chicken liver. They inhibited submitochondrial succinate dehydrogenase and NADH dehydrogenase of E. tenella, and remained equally active against the mitochondrial function of E. tenella amquinolate-resistant mutant.     

UBIQUINONE REDOX STATUS IN BRAIN IN VITRO

—The redox status of ubiquinone (Q) as an index of mitochondrial respiratory chain activity in chopped telencephalon from the rat was investigated. With 12mm -glucose under aerobic conditions Q was 73% oxidized. Three mm -amytal and 2 μm -rotenone, inhibitors of mitochondrial NADH oxidation, resulted in Q being further oxidized by 14 and 16%, respectively. Thus, amytal and rotenone result in shifts in Q redox status of rat telencephalon slices in accord with the known site of action of these compounds in isolated mitochondria. However, under anaerobic conditions Q redox status shifted to 25% oxidized while incubation with 1 mm -NaCN resulted in a shift to only 58% oxidized. This discrepancy may result from concomitant inhibition in the supply of reducing equivalents to Q from substrate by NaCN or it may reflect a differential sensitivity of neuronal and glial mitochondria to NaCN. Evaluation of Q oxidation-reduction can be used to measure the effects of drugs and physiological perturbations on the redox status of the mitochondrial compartment of intact brain preparations.     

The locus of inhibition of NADH oxidation by benzothiadiazoles in beef heart submitochondrial particles

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.     

HQNO-sensitive NADH:quinone oxidoreductase of Bacillus cereus KCTC 3674

The enzymatic properties of NADH:quinone oxidoreductase were examined in Triton X-100 extracts of Bacillus cereus membranes by using the artificial electron acceptors ubiquinone-1 and menadione. Membranes were prepared from B. cereus KCTC 3674 grown aerobically on a complex medium and oxidized with NADH exclusively, whereas deamino-NADH was determined to be poorly oxidized. The NADH oxidase activity was lost completely by solubilization of the membranes with Triton X-100. However, by using the artificial electron acceptors ubiquinone-1 and menadione, NADH oxidation could be observed. The activities of NADH:ubiquinone-1 and NADH:menadione oxidoreductase were enhanced approximately 8-fold and 4-fold, respectively, from the Triton X-100 extracted membranes. The maximum activity of FAD-dependent NADH:ubiquinone-1 oxidoreductase was obtained at about pH 6.0 in the presence of 0.1M NaCl, while the maximum activity of FAD-dependent NADH:menadione oxidoreductase was obtained at about pH 8.0 in the presence of 0.1 M NaCl. The activities of the NADH:ubiquinone-1 and NADH:menadione oxidoreductase were very resistant to such respiratory chain inhibitors as rotenone, capsaicin, and AgNO(3), whereas these activities were sensitive to 2-heptyl-4-hydroxyquinoline-N-oxide (HQNO). Based on these results, we suggest that the aerobic respiratory chain-linked NADH oxidase system of B. cereus KCTC 3674 possesses an HQNO-sensitive NADH:quinone oxidoreductase that lacks an energy coupling site containing FAD as a cofactor.     

Interaction of positively charged ubiquinone analog (MitoQ10) with DT-diaphorase from liver mitochondria

Effects of the coenzyme Q analog (MitoQ₁₀) carrying a positively charged decyltetraphenylphosphonium group on functional activity of phosphorylating liver mitochondria were studied. Using inhibitory analysis it was found that at micromolar concentrations this quinone is reduced by NADH-dependent DT-diaphorase. Under conditions of malate oxidation, MitoQ₁₀ stimulates electron transfer from NADH to oxygen by shunting the block of rotenone-induced electron transport in Complex I. Steady-state mitochondrial respiration induced by rotenone and MitoQ₁₀ (1 μM), as well as K3 shunt are both blocked by the DT-diaphorase inhibitor dicumarol, the Complex III inhibitor myxothiazole, and the cytochrome oxidase inhibitor cyanide. The electron transport chain induced in liver mitochondria by MitoQ₁₀ in the presence of rotenone appears as follows: NADH → DT-diaphorase → MitoQ₁₀ → Complex III → Complex IV → O₂. Under conditions of malate (but not succinate) oxidation, MitoQ₁₀ and high concentrations of vitamin K3 induce in mitochondria cyanide-resistant respiration and opening of the nonspecific pore eventually resulting in inhibition of oxidative phosphorylation. It is concluded that MitoQ₁₀ should be regarded as an analog of hydrophilic quinones (vitamin K3, duroquinone, etc.) widely known as substrates for mitochondrial DT-diaphorase not interacting with CoQ₁₀ rather than as a natural CoQ₁₀ analog.     

Reye's syndrome: the effect of patient serum on mitochondrial respiration in vitro

Serum from patients with Reye's Syndrome stimulated state 4 respiration in isolated rat liver mitochondria. Inhibitors of specific mitochondrial functions were tested as potential antagonists of the stimulatory effect of RS serum. Oligomycin, ruthenium red, rotenone and antimycin A were all ineffective in preventing the increase in state 4 respiration, but KCN completely abolished all respiratory activity in the presence of RS serum. We conclude that the putative serum factor stimulates respiration by directly or indirectly interacting with the electron transport chain at a point beyond site II.     

Inhibition of respiratory complex I by 6-ketocholestanol: Relevance to recoupling action in mitochondria

6-Ketocholestanol (kCh) is known as a mitochondrial recoupler, i.e. it abolishes uncoupling of mitochondria by such potent agents as carbonyl cyanide m-chlorophenyl hydrazone (CCCP) and 3,5-di(tert-butyl)-4-hydroxybenzylidenemalononitril (SF6847) [Starkov et al., 1997]. Here, we report data on the kCh-induced inhibition of both NADH-oxidase and NADH-ubiquinone oxidoreductase activities of the respiratory complex I in bovine heart submitochondrial particles (SMP). Based on the absence of such inhibition with hexaammineruthenium (III) (HAR) as the complex I electron acceptor, the kCh effect could be associated with the ubiquinone-binding centre of this respiratory enzyme. In isolated rat liver mitochondria (RLM), kCh inhibited oxygen consumption with the glutamate/malate, substrates of NAD-linked dehydrogenases, while no inhibition of RLM respiration was observed with succinate, in agreement with the absence of the kCh effect on the succinate oxidase activity in SMP. Three kCh analogs (cholesterol, 6α-hydroxycholesterol, and 5α,6α-epoxycholesterol) exhibited no effect on the NADH oxidase activities in both SMP and RLM. Importantly, the kCh analogs were ineffective in the recoupling of RLM treated with CCCP or SF6847. Therefore, interaction of kCh with the complex I may be involved in the kCh-mediated mitochondrial recoupling.     

In vitro effects of acetaminophen metabolites and analogs on the respiration of mouse liver mitochondria

Acetaminophen, an analgesic and antipyretic, is toxic in overdose to liver and kidney. The effects on mitochondrial respiration of acetaminophen, its less toxic analog, 3-hydroxyacetanilide, and metabolites which arise from these compounds have been investigated. The parent compounds inhibited NADH-linked respiration reversibly, whereas the metabolites inhibit all mitochondrial respiration, apparently in the Complex III region of the respiratory chain. The quinone derivatives, 4-acetamido-o-benzoquinone and 2-acetamido-p-benzoquinone, are the best inhibitors, with the onset of inhibition dependent on active respiration, suggesting interaction of these compounds with oxidized components of the electron transport chain.