Reactive Oxygen Species Production by Forward and Reverse Electron Fluxes in the Mitochondrial Respiratory Chain

Selivanov, Vitaly A.; Votyakova, Tatyana V.; Pivtoraiko, Violetta N.; Zeak, Jennifer A.; Сухомлин, Татьяна Анатольевна; Trucco, Massimo; Roca, Josep; Cascante, Marta

doi:10.1371/journal.pcbi.1001115

Cited by 138 publications

(148 citation statements)

References 44 publications

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“…They are unique organelles, accounting for about 85%-90% of oxygen consumed by the cell. The incomplete processing of oxygen and/or release of free electron in the mitochondria results in the production of reactive oxygen species (ROS) [2] . ROS released by the mitochondrial respiratory chain are a family of active molecules containing free radicals and are involved in the modulation of biological cell functions.…”

Section: Introductionmentioning

confidence: 99%

African eggplant (Solanum anguivi Lam.) fruit with bioactive polyphenolic compounds exerts in vitro antioxidant properties and inhibits Ca2+-induced mitochondrial swelling

Elekofehinti

Kamdem

Bolingon

et al. 2013

Asian Pacific Journal of Tropical Biomedicine

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Section: Introductionmentioning

confidence: 99%

African eggplant (Solanum anguivi Lam.) fruit with bioactive polyphenolic compounds exerts in vitro antioxidant properties and inhibits Ca2+-induced mitochondrial swelling

Elekofehinti

Kamdem

Bolingon

et al. 2013

Asian Pacific Journal of Tropical Biomedicine

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“…The potential values from −320 mV (for NADH) to −36 mV (for ubiquinone) correspond to Complex I, whereas the E 1/2 of DTBBQ (E 1/2 = −260 mV) corresponds to the potential of the NADH: ubiquinone reductase initial site, while the E 1/2 of juglone (E 1/2 = −99 mV) is close to the Q-reduction site of Complex I. It is known that rotenone interrupts electron transfer in Complex I, which causes a decrease of ROS generation by Complex III and an increase of ROS generation by Complex I (3,12,30,32,33,48,54). Then, the ROS production by quinones, which are reduced in ETC before rotenone binding site of Complex I, would increase after Complex I inhibition and, vice versa, the ROS production by quinones, which are reduced at the Complex I ubiquinonebinding site that is located higher than the rotenone-binding site in ETC would be suppressed during rotenone treatment.…”

Section: Discussionmentioning

confidence: 99%

Redox regulation of mitochondrial functional activity by quinones

et al. 2016

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Quinones are among the rare compounds successfully used as therapeutic agents to correct mitochondrial diseases and as specific regulators of mitochondrial function within cells. The aim of the present study was to elucidate the redox-dependent effects of quinones on mitochondrial function. The functional parameters [respiratory activity, membrane potential, and reactive oxygen species (ROS) generation] of isolated rat liver mitochondria and mitochondria in intact cells were measured in the presence of eight exogenously applied quinones that differ in lipophilicity and one-electron reduction potential. The quinones affected the respiratory parameters of mitochondria, and dissipated the mitochondrial membrane potential as well as influenced (either decreased or enhanced) ROS generation, and restored the electron flow during electron transport chain inhibition. The stimulation of ROS production by juglone and 2,5-di-tert-butyl-1,4-benzoquinone was accompanied by a decrease in the acceptor control and respiration control ratios, dissipation of the mitochondrial membrane potential and induction of the reverse electron flow under succinate oxidation in isolated mitochondria. Menadione and 2,3,5-trimethyl-1,4-benzoquinone, which decreased the mitochondrial ROS generation, did not affect the mitochondrial potential and, vice versa, were capable of restoring electron transport during Complex I inhibition. In intact C6 cells, all the quinones, except for coenzyme Q 10 , decreased the mitochondrial membrane potential. Juglone, 1,4-benzoquinone, and menadione showed the most pronounced effects. These findings indicate that quinones with the reduction potential values E 1/2 in the range from −99 to −260 mV were effective redox regulators of mitochondrial electron transport.

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“…For instance, inhibition of the electron transport chain and accompanying alterations in ROS production during hypoxia, especially, if it is followed by reoxygenation can initiate ROS-related cellular hypoxia-reoxygenation injury [7]. Selivanov and colleagues [8,9] discovered recently bistability in operation of the respiratory chain and showed computationally that bistability can be a reason of a drastic increase in ROS production during anoxia-reoxygenation. Computational analysis of bistability and an increase in ROS production during anoxia-reoxygenation was made [8,9] with the help of the rule-based model on the assumption that electron transfer between any redox pair of carriers does not depend on the redox state of the remaining electron carriers in the respiratory chain.…”

Section: Introductionmentioning

confidence: 99%

“…Selivanov and colleagues [8,9] discovered recently bistability in operation of the respiratory chain and showed computationally that bistability can be a reason of a drastic increase in ROS production during anoxia-reoxygenation. Computational analysis of bistability and an increase in ROS production during anoxia-reoxygenation was made [8,9] with the help of the rule-based model on the assumption that electron transfer between any redox pair of carriers does not depend on the redox state of the remaining electron carriers in the respiratory chain. Using this simplifying suggestion and describing explicitly the electron transfer between any two transporters that involves a few tens of reactions for the entire respiratory chain, authors were able to develop algorithms (rules) to automatically construct an implicit computational model consisting of a few hundreds differential equations and computing the probability (concentration) of all possible micro-states in Complexes I and III of the respiratory chain.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Компьютерный Анализ Гистерезиса И Бистабильности В Дыхательной Цепи Митохондрий

Маркевич,

Markevich

2014

Math.Biol.Bioinf.

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Abstract. Quantitative analysis of bistability in operation of the respiratory chain was performed with the help a computational mechanistic model developed by us earlier. This study included numerical solving of a system of algebraic equations according to steady states in a system of differential equations comprising the computational model and analysis of a wide spectrum of steady-state solutions in the model. Detailed quantitative analysis of the mechanisms of appearance of hysteresis in steady-state characteristics that accords with bistability and conditions of availability of bistability in the entire respiratory chain during oxidation of NADH, succinate and NADH+succinate was carried out. It was shown that although hysteresis and bistability in respiratory chain operation during oxidation of NADH and succinate has the same kinetic mechanism, namely an apparent substrate inhibition of QH2 oxidation at the Qo-site of Complex III, conditions of bistability arising in respiratory chain fueled by succinate alone differ from those during oxidation of NADH or NADH + succinate because of a different QH2-dependence of the QH2 generation rate by Complex II and Complex I. The most important factors which affect occurrence of bistability in the respiratory chain during oxidation of NADH and NADH + succinate are the rates of NADH reduction in the matrix and the total concentration of Complex I [CI] and ubiquinone [Q]tot in the inner membrane. A high rate of NADH reduction and a high ratio [CI]/[Q]tot are condition that would favorable for hysteresis and bistability. The mechanism of a drastic increase in ROS production due to bistable switches in the respiratory chain during hypoxia-reoxygenation suggested earlier by Selivanov and colleagues was analyzed. A computational simulation of hypoxia-reoxygentaion under condition of existence of bistability shows a considerable increase in the rate of ROS production if hypoxia induces a switch of the respiratory chain to the reduced steady state. However, no changes occur in the ROS production rate during reoxygenation following hypoxia compared to the initial state if the membrane potential drops during hypoxia keeping a high rate of respiration and oxidized steady state of the respiratory chain. This implies that additional mechanisms of a considerable increase in ROS production during hypoxia-reoxygentaion which initiate ROS-related cellular hypoxiareoxygenation injury should be.

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Reactive Oxygen Species Production by Forward and Reverse Electron Fluxes in the Mitochondrial Respiratory Chain

Cited by 138 publications

References 44 publications

African eggplant (Solanum anguivi Lam.) fruit with bioactive polyphenolic compounds exerts in vitro antioxidant properties and inhibits Ca2+-induced mitochondrial swelling

African eggplant (Solanum anguivi Lam.) fruit with bioactive polyphenolic compounds exerts in vitro antioxidant properties and inhibits Ca2+-induced mitochondrial swelling

Redox regulation of mitochondrial functional activity by quinones

Компьютерный Анализ Гистерезиса И Бистабильности В Дыхательной Цепи Митохондрий

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