Respiratory oscillations in yeast: mitochondrial reactive oxygen species,apoptosis and time; a hypothesis

Oscillatory metabolic activities occur more widely than is generally realised; detectability requires observation over extended times of single yeast cells or synchrony of individuals to provide a coherent population. Where oscillations in intracellular metabolite concentrations are observed, the phenomenon has been ascribed to sloppy control, energetic optimisation, signalling, temporal compartmentation of incompatible reactions, or timekeeping functions. Here we emphasise the consequences of respiratory oscillations as a source of mitochondrially generated reactive O(2) metabolites. Temporal co-ordination of intracellular activities necessitates a time base. This is provided by an ultradian clock, and one result of its long-term operation is cyclic energisation of mitochondria, and thereby the generation of deleterious free radical species. Our hypothesis is that unrepaired cellular constituents and components (especially mitochondria) eventually lead to cellular senescence and apoptosis when a finite number of respiratory cycles has occurred.     

Salinomycin-induced apoptosis of human prostate cancer cells due to accumulated reactive oxygen species and mitochondrial membrane depolarization

The anticancer activity of salinomycin has evoked excitement due to its recent identification as a selective inhibitor of breast cancer stem cells (CSCs) and its ability to reduce tumor growth and metastasis in vivo. In prostate cancer, similar to other cancer types, CSCs and/or progenitor cancer cells are believed to drive tumor recurrence and tumor growth. Thus salinomycin can potentially interfere with the end-stage progression of hormone-indifferent and chemotherapy-resistant prostate cancer. Androgen-responsive (LNCaP) and androgen-refractive (PC-3, DU-145) human prostate cancer cells showed dose- and time-dependent reduced viability upon salinomycin treatment; non-malignant RWPE-1 prostate cells were relatively less sensitive to drug-induced lethality. Salinomycin triggered apoptosis of PC-3 cells by elevating the intracellular ROS level, which was accompanied by decreased mitochondrial membrane potential, translocation of Bax protein to mitochondria, cytochrome c release to the cytoplasm, activation of the caspase-3 and cleavage of PARP-1, a caspase-3 substrate. Expression of the survival protein Bcl-2 declined. Pretreatment of PC-3 cells with the antioxidant N-acetylcysteine prevented escalation of oxidative stress, dissipation of the membrane polarity of mitochondria and changes in downstream molecular events. These results are the first to link elevated oxidative stress and mitochondrial membrane depolarization to salinomycin-mediated apoptosis of prostate cancer cells.     

Decavanadate induces mitochondrial membrane depolarization and inhibits oxygen consumption

Decavanadate induced rat liver mitochondrial depolarization at very low concentrations, half-depolarization with 39 nM decavanadate, while it was needed a 130-fold higher concentration of monomeric vanadate (5 microM) to induce the same effect. Decavanadate also inhibits mitochondrial repolarization induced by reduced glutathione in vitro, with an inhibition constant of 1 microM, whereas no effect was observed up to 100 microM of monomeric vanadate. The oxygen consumption by mitochondria is also inhibited by lower decavanadate than monomeric vanadate concentrations, i.e. 50% inhibition is attained with 99 M decavanadate and 10 microM monomeric vanadate. Thus, decavanadate is stronger as mitochondrial depolarization agent than as inhibitor of mitochondrial oxygen consumption. Up to 5 microM, decavanadate does not alter mitochondrial NADH levels nor inhibit neither F(O)F(1)-ATPase nor cytochrome c oxidase activity, but it induces changes in the redox steady-state of mitochondrial b-type cytochromes (complex III). NMR spectra showed that decameric vanadate is the predominant vanadate species in decavanadate solutions. It is concluded that decavanadate is much more potent mitochondrial depolarization agent and a more potent inhibitor of mitochondrial oxygen consumption than monomeric vanadate, pointing out the importance to take into account the contribution of higher oligomeric species of vanadium for the biological effects of vanadate solutions.     

Gliotoxin induces apoptosis in cultured macrophages via production of reactive oxygen species and cytochrome c release without mitochondrial depolarization

The cytotoxicity and its underlying mechanisms induced by gliotoxin (GT), an immunosuppressive agent, in macrophages are poorly understood. We report here that GT induced a rapid apoptosis (DNA fragmentation and hypodiploid nuclei obtained within 4 hrs of treatment) in murine macrophages PU5-1.8 in a dose-dependent and cell cycle-independent manner. The GT-induced apoptosis was suppressed by z-Asp, z-VAD-fmk and antioxidants suggesting that production of reactive oxygen species (ROS) and activation of caspases were important in this process. Also, release of cytochrome c from mitochondria was found to be an early event (within 1 hr) after addition of GT (250 ng/ml) and its presence in the cytosol was sufficient to elicit apoptosis. Interestingly, the release of cytochrome c was not accompanied by a reduction in the mitochondrial membrane potential (ψ_m) as determined by several ψ_m-sensitive fluorescent indicators. Taken together, our results indicate that GT is a potent apoptotic agent in PU5-1.8 cells and the loss of ψ_m is not a universal early marker for apoptosis.     

Redox signaling (cross-talk) from and to mitochondria involves mitochondrial pores and reactive oxygen species

This review highlights the important role of redox signaling between mitochondria and NADPH oxidases. Besides the definition and general importance of redox signaling, the cross-talk between mitochondrial and Nox-derived reactive oxygen species (ROS) is discussed on the basis of 4 different examples. In the first model, angiotensin-II is discussed as a trigger for NADPH oxidase activation with subsequent ROS-dependent opening of mitochondrial ATP-sensitive potassium channels leading to depolarization of mitochondrial membrane potential followed by mitochondrial ROS formation and respiratory dysfunction. This concept was supported by observations that ethidium bromide-induced mitochondrial damage suppressed angiotensin-II-dependent increase in Nox1 and oxidative stress. In another example hypoxia was used as a stimulator of mitochondrial ROS formation and by using pharmacological and genetic inhibitors, a role of mitochondrial ROS for the induction of NADPH oxidase via PKC? was demonstrated. The third model was based on cell death by serum withdrawal that promotes the production of ROS in human 293T cells by stimulating both the mitochondria and Nox1. By superior molecular biological methods the authors showed that mitochondria were responsible for the fast onset of ROS formation followed by a slower but long-lasting oxidative stress condition based on the activation of an NADPH oxidase (Nox1) in response to the fast mitochondrial ROS formation. Finally, a cross-talk between mitochondria and NADPH oxidases (Nox2) was shown in nitroglycerin-induced tolerance involving the mitochondrial permeability transition pore and ATP-sensitive potassium channels. The use of these redox signaling pathways as pharmacological targets is briefly discussed.     

Determination of mitochondrial reactive oxygen species: methodological aspects

The generation of Reactive Oxygen Species (ROS) as by-products in mitochondria Electron Transport Chain (ETC) has long been admitted as the cost of aerobic energy metabolism with oxidative damages as consequence. The purpose of this methodological review is to present some of the most widespread methods of ROS generation and to underline the limitations as well as some problems, identified with some experiments as examples, in the interpretation of such results. There is now no doubt that besides their pejorative role, ROS are involved in a variety of cellular processes for the continuous adaptation of the cell to its environment. Because ROS metabolism is a complex area (low production, instability of species, efficient antioxidant defense system, several places of production…) bias, variances and limitations in ROS measurements must be recognized in order to avoid artefactual conclusions, and especially to improve our understanding of physiological and pathophysiological mechanisms of such phenomenon.     

线粒体电子传递链电子漏的化学发光测定

本实验用差速离心法分离正常大鼠肝脏和心肌线粒体 ,以lucigenin (探测超氧阴离子 )与luminol (探测过氧化氢 )为探剂 ,用化学发光法测定METC电子漏的生成。在反应体系中加入外源底物 ,其发光强度明显高于空白对照 (体系中无线粒体 )。在肝线粒体体系中 ,无论是lucigenin还是luminol诱发的发光 ,琥珀酸底物引起的发光强均要高于丙酮酸 /苹果酸引起的发光强度。在心肌线粒体 luminol体系中也有与肝线粒体相似的结果 ,在心肌线粒体 lucigenin体系中 ,加入外源底物丙酮酸 /苹果酸诱发的发光强度高于琥珀酸诱发的发光强度     

Stimulus-induced downregulation of root water transport involves reactive oxygen species-activated cell signalling and plasma membrane intrinsic protein internalization

The water uptake capacity of plant roots (i.e. their hydraulic conductivity, Lp(r)) is determined in large part by aquaporins of the plasma membrane intrinsic protein (PIP) subfamily. In the present work, we investigated two stimuli, salicylic acid (SA) and salt, because of their ability to induce an accumulation of reactive oxygen species (ROS) and an inhibition of Lp(r) concomitantly in the roots of Arabidopsis plants. The inhibition of Lp(r) by SA was partially counteracted by preventing the accumulation of hydrogen peroxide (H(2)O(2)) with exogenous catalase. In addition, exogenous H(2)O(2) was able to reduce Lp(r) by up to 90% in <15 min. Based on the lack of effects of H(2)O(2) on the activity of individual aquaporins in Xenopus oocytes, and on a pharmacological dissection of the action of H(2)O(2) on Lp(r), we propose that ROS do not gate Arabidopsis root aquaporins through a direct oxidative mechanism, but rather act through cell signalling mechanisms. Expression in transgenic roots of PIP-GFP fusions and immunogold labelling indicated that external H(2)O(2) enhanced, in <15 min, the accumulation of PIPs in intracellular structures tentatively identified as vesicles and small vacuoles. Exposure of roots to SA or salt also induced an intracellular accumulation of the PIP-GFP fusion proteins, and these effects were fully counteracted by co-treatment with exogenous catalase. In conclusion, the present work identifies SA as a novel regulator of aquaporins, and delineates an ROS-dependent signalling pathway in the roots of Arabidopsis. Several abiotic and biotic stress-related stimuli potentially share this path, which involves an H(2)O(2)-induced internalization of PIPs, to downregulate root water transport.     

Role of mitochondrial superoxide dismutase in contraction-induced generation of reactive oxygen species in skeletal muscle extracellular space

Contractions of skeletal muscles produce increases in concentrations of superoxide anions and activity of hydroxyl radicals in the extracellular space. The sources of these reactive oxygen species are not clear. We tested the hypothesis that, after a demanding isometric contraction protocol, the major source of superoxide and hydroxyl radical activity in the extracellular space of muscles is mitochondrial generation of superoxide anions and that, with a reduction in MnSOD activity, concentration of superoxide anions in the extracellular space is unchanged but concentration of hydroxyl radicals is decreased. For gastrocnemius muscles from adult (6–8 mo old) wild-type (Sod2^+/+) mice and knockout mice heterozygous for the MnSOD gene (Sod2^+/-), concentrations of superoxide anions and hydroxyl radical activity were measured in the extracellular space by microdialysis. A 15-min protocol of 180 isometric contractions induced a rapid, equivalent increase in reduction of cytochrome c as an index of superoxide anion concentrations in the extracellular space of Sod2^+/+ and Sod2^+/- mice, whereas hydroxyl radical activity measured by formation of 2,3-dihydroxybenzoate from salicylate increased only in the extracellular space of muscles of Sod2^+/+ mice. The lack of a difference in increase in superoxide anion concentration in the extracellular space of Sod2^+/+ and Sod2^+/- mice after the contraction protocol supported the hypothesis that superoxide anions were not directly derived from mitochondria. In contrast, the data obtained suggest that the increase in hydroxyl radical concentration in the extracellular space of muscles from wild-type mice after the contraction protocol most likely results from degradation of hydrogen peroxide generated by MnSOD activity. hydroxyl radicals; microdialysis     

植物线粒体、活性氧与信号转导

活性氧(ROS)的产生是需氧代谢不可避免的结果。在植物细胞中,线粒体电子传递链(ETC)的复合物Ⅰ和Ⅱ是ROS产生的主要的部位。交替氧化酶和可能的内源鱼藤酮不敏感的NADH脱氢酶通过保持ETc的相对氧化状态限制线粒体产生ROS。线粒体基质中的抗氧化酶系统与小分子量的抗氧化剂一道起ROS的解毒作用。ROS除了引起细胞的伤害外,在植物中还能够作为一种普遍存在的信号分子起作用。在低浓度时,ROS能诱导防御基因的表达和引起适应反应;在高浓度时,引起细胞死亡。一氧化氮是植物合成和释放的一种气体,也可作为信号分子调节植物的生长和发育。     

利用荧光探针直接测定线粒体活性氧的形成

目的与方法：根据荧光探针－还原型二氯荧光素（2‘,7‘-dichlorodihydrofluorescin,DCFH)可与活性氧（reactive oxygen species,ROS)反应生成荧光物一氧化型二氯荧光素（2‘,7‘-dichlorofluorecin,DCF)的原理,设计了利用荧光分光光度计直接定量检测线粒体活性氧生成并可观察在各种实验条件下线粒体活性氧产生动态变化的方法。结果与结论：线粒体在态4呼吸状态下,DCF的荧光强度随时间呈线性增加,表明活性氧以恒定速率产生。将荧光强度随时间变化的数据点拟合,线性回归直线斜率与活性氧产生的速率呈正比,测定中加入叠氮钠和丙二酸可分别使线粒体活性氧产生增加和减少。DCF荧光强度增加速率与线粒体浓度在一定范围内呈线性关系。复管实验表明重复性良好。     

Studies elucidating the mechanisms of calcium induced mitochondrial depolarization in individual isolated brain mitochondria

Among other mitochondrial functions, energy production and Ca²⁺ uptake are crucial for maintaining neuronal viability. Both of these functions are critically dependent on mitochondrial membrane potential (ΔΨ_m). Mitochondrial Ca²⁺ overload causing a dissipation of ΔΨ_m is a key component of several neuronal pathologies. However, the mechanism of Ca²⁺-induced depolarization in neuronal mitochondria remains unclear. Typically, ΔΨ_m has been evaluated as a single overall estimate from all mitochondria present in a given cell or tissue. However, recent data showed that the population of mitochondria isolated from tissues is not homogeneous, and averaged parameters from the whole population do not necessarily reflect the processes taking place in a single organelle. This review summarizes our recent studies of Ca²⁺-induced depolarization in individual mitochondria isolated from rat forebrain and immobilized to coverslips. Fluorescence imaging techniques and potentiometric fluorescent dyes were effectively used to study ΔΨ_m changes. The data have shown that Ca²⁺ triggers ΔΨ_m oscillations in brain mitochondria followed by a complete depolarization. Further investigation of this phenomenon led us to suggest that Ca²⁺-induced ΔΨ_m oscillations can represent an intermediate unstable state that may lead to irreversible mitochondrial dysfunction. Therefore, further study of this phenomenon would help to understand what causes the irreversible damage of mitochondria during cytosolic/mitochondrial Ca²⁺ overload. Here we discuss the effects of different modulators of the mitochondrial permeability transition pore on Ca²⁺-induced depolarization in brain mitochondria and in liver mitochondria, where the mechanism of Ca²⁺-depolarization is better understood. A comparison of these effects in brain and liver mitochondria led us to conclude that Ca²⁺ can induce reversible “low conductance” permeability transition in brain mitochondria, the phenomenon which requires a transient conformational change of the adenine nucleotide translocator from a specific transporter to a non-specific pore. The article is published in the original.     

Curcumin inhibits apoptosis by regulating intracellular calcium release,reactive oxygen species and mitochondrial depolarization levels in SH-SY5Y neuronal cells

Neurological diseases such as Alzheimer’s and Parkinson’s diseases are incurable progressive neurological disorders caused by the degeneration of neuronal cells and characterized by motor and non-motor symptoms. Curcumin, a turmeric product, is an anti-inflammatory agent and an effective reactive oxygen and nitrogen species scavenging molecule. Hydrogen peroxide (H₂O₂) is the main source of oxidative stress, which is claimed to be the major source of neurological disorders. Hence, in this study we aimed to investigate the effect of curcumin on Ca²⁺ signaling, oxidative stress parameters, mitochondrial depolarization levels and caspase-3 and -9 activities that are induced by the H₂O₂ model of oxidative stress in SH-SY5Y neuronal cells. SH-SY5Y neuronal cells were divided into four groups namely, the control, curcumin, H₂O₂, and curcumin?+?H₂O₂ groups. The dose and duration of curcumin and H₂O₂ were determined from published data. The cells in the curcumin, H₂O₂, and curcumin?+?H₂O₂ groups were incubated for 24?h with 5?µM curcumin and 100?µM H₂O₂. Lipid peroxidation and cytosolic free Ca²⁺ concentrations were higher in the H₂O₂ group than in the control group; however, their levels were lower in the curcumin and curcumin?+?H₂O₂ groups than in the H₂O₂ group alone. Reduced glutathione (GSH) and glutathione peroxidase (GSH-Px) values were lower in the H₂O₂ group although they were higher in the curcumin and curcumin?+?H₂O₂ groups than in the H₂O₂ group. Caspase-3 activity was lower in the curcumin group than in the H₂O₂ group. In conclusion, curcumin strongly induced modulator effects on oxidative stress, intracellular Ca²⁺ levels, and the caspase-3 and -9 values in an experimental oxidative stress model in SH-SY5Y cells.     

Mitochondria: omega-3 in the route of mitochondrial reactive oxygen species

Mitochondria are the main organelles that produce reactive oxygen species (ROS). Overproduction of ROS induces oxidative damage to macromolecules, including lipids, and can damage cellular membrane structure and functions. Mitochondria, the main target of ROS-induced damage, are equipped with a network of antioxidants that control ROS production. Dietary intake of omega-3 polyunsaturated fatty acids (ω3PUFAs) and consequently the increase in ω3PUFA content of membrane lipids may be disadvantageous to the health because ROS-induced oxidative peroxidation of ω3PUFAs within membrane phospholipids can lead to the formation of toxic products. Mitochondrial control of lipid peroxidation is one of the mechanisms that protect cell against oxidative damage. This review discusses the role of mitochondria in ROS generation and the mechanisms by which it regulates ROS production. The susceptibility to peroxidation of PUFAs by ROS raises the question of the adverse effects of ω3PUFA dietary supplementation on embryonic development and prenatal developmental outcomes.     

Dopamine modifies oxygen consumption and mitochondrial membrane potential in striatal mitochondria

Dopamine is a neurotransmitter that has been related to mitochondrial dysfunction. In this study, striatal intact mitochondria and submitochondrial membranes were incubated with different dopamine concentrations, and changes on mitochondrial function, hydrogen peroxide, and nitric oxide production were evaluated. A 35% decrease in state 3 oxygen uptake (active respiration state) was found after 1 mM dopamine incubation. In addition, mitochondrial respiratory control significantly decreased, indicating mitochondrial dysfunction. High dopamine concentrations induced mitochondrial depolarization. Also, evaluation of hydrogen peroxide production by intact striatal mitochondria showed a significant increase after 0.5 and 1 mM dopamine incubation. Incubation with 0.5 and 1 mM dopamine increased nitric oxide production in submitochondrial membranes by 28 and 49%, respectively, as compared with control values. This study provides evidence that high dopamine concentrations induce striatal mitochondrial dysfunction through a decrease in mitochondrial respiratory control and loss of membrane potential, probably mediated by free radical production.     

Roles of mitochondrial fragmentation and reactive oxygen species in mitochondrial dysfunction and myocardial insulin resistance

Purpose

Evidence suggests an association between aberrant mitochondrial dynamics and cardiac diseases. Because myocardial metabolic deficiency caused by insulin resistance plays a crucial role in heart disease, we investigated the role of dynamin-related protein-1 (DRP1; a mitochondrial fission protein) in the pathogenesis of myocardial insulin resistance.

Methods and Results

DRP1-expressing H9c2 myocytes, which had fragmented mitochondria with mitochondrial membrane potential (ΔΨ_m) depolarization, exhibited attenuated insulin signaling and 2-deoxy-d-glucose (2-DG) uptake, indicating insulin resistance. Treatment of the DRP1-expressing myocytes with Mn(III)tetrakis(1-methyl-4-pyridyl)porphyrin pentachloride (TMPyP) significantly improved insulin resistance and mitochondrial dysfunction. When myocytes were exposed to hydrogen peroxide (H₂O₂), they increased DRP1 expression and mitochondrial fragmentation, resulting in ΔΨ_m depolarization and insulin resistance. When DRP1 was suppressed by siRNA, H₂O₂-induced mitochondrial dysfunction and insulin resistance were restored. Our results suggest that a mutual enhancement between DRP1 and reactive oxygen species could induce mitochondrial dysfunction and myocardial insulin resistance. In palmitate-induced insulin-resistant myocytes, neither DRP1-suppression nor TMPyP restored the ΔΨ_m depolarization and impaired 2-DG uptake, however they improved insulin signaling.

Conclusions

A mutual enhancement between DRP1 and ROS could promote mitochondrial dysfunction and inhibition of insulin signal transduction. However, other mechanisms, including lipid metabolite-induced mitochondrial dysfunction, may be involved in palmitate-induced insulin resistance.     

Detection and manipulation of mitochondrial reactive oxygen species in mammalian cells

Reactive oxygen species (ROS) are formed upon incomplete reduction of molecular oxygen (O₂) as an inevitable consequence of mitochondrial metabolism. Because ROS can damage biomolecules, cells contain elaborate antioxidant defense systems to prevent oxidative stress. In addition to their damaging effect, ROS can also operate as intracellular signaling molecules. Given the fact that mitochondrial ROS appear to be only generated at specific sites and that particular ROS species display a unique chemistry and have specific molecular targets, mitochondria-derived ROS might constitute local regulatory signals. The latter would allow individual mitochondria to auto-regulate their metabolism, shape and motility, enabling them to respond autonomously to the metabolic requirements of the cell. In this review we first summarize how mitochondrial ROS can be generated and removed in the living cell. Then we discuss experimental strategies for (local) detection of ROS by combining chemical or proteinaceous reporter molecules with quantitative live cell microscopy. Finally, approaches involving targeted pro- and antioxidants are presented, which allow the local manipulation of ROS levels.     

Role of mitochondria and reactive oxygen species in dendritic cell differentiation and functions

Dendritic cells (DC) are potent antigen-presenting cells capable of inducing T and B responses and immune tolerance. We have characterized some aspects of energy metabolism accompanying the differentiation process of human monocytes into DC. Compared to precursor monocytes, DC exhibited a much larger number of mitochondria and consistently (i) a higher endogenous respiratory activity and (ii) a more than sixfold increase in ATP content and an even larger increase in the activity of the mitochondrial marker enzyme citrate synthase. The presence in the culture medium of rotenone, an inhibitor of the respiratory chain Complex I, prevented the increase in mitochondrial number and ATP level, without affecting cell viability. Rotenone inhibited DC differentiation, as revealed by the observation that the expression of CD1a, which is a specific surface marker of DC differentiation, was strongly reduced. Cells cultured in the presence of rotenone displayed a lower content of growth factor-induced, mitochondrially generated, hydrogen peroxide. A similar drop in ROS was observed upon addition of catalase, which caused functional effects similar to those produced by rotenone treatment. These results suggest that ROS play a crucial role in DC differentiation and that mitochondria are an important source of ROS in this process.