Effect of Adriamycin on superoxide radical generation in isolated heart mitochondria

The influence of Adriamycin (doxorubicin) on the rate of superoxide radical formation in isolated rat heart mitochondria was studied by EPR with the Tiron spin trap not penetrating the mitochondrial inner membrane. Adriamycin at 10–150 μM considerably enhanced superoxide generation in the presence of succinate (substrate of the respiratory chain complex II) and glutamate/malate (complex I substrate) when electron transfer was blocked in complex III with antimycin A. Such effects may partly account for the known cardiotoxicity of this antitumor drug.     

Lucigenin-derived chemiluminescence in intact isolated mitochondria

There are many data both in favor and against the use of lucigenin as a probe for superoxide anion (SA) in mitochondria, cells, and simple enzymatic systems. In the present work high concentrations (50-400 M) of lucigenin were used for continuous recording of rapid and reversible changes in the SA level in intact isolated mitochondria. The SA level in the presence of lucigenin rapidly and reversibly changed during the transition of the mitochondria from one functional state to another: under conditions of ATP synthesis from ADP and P_i, of Ca²⁺ accumulation, and of reverse electron transfer. Induction of a Ca²⁺,cyclosporin A-sensitive pore in mitochondria completely suppressed the lucigenin-derived chemiluminescence (LDC). The electron transfer in the Q-cycle of the respiratory chain complex III and high electric potential difference across the inner membrane of mitochondria were obligatory conditions for generation of a SA-dependent chemiluminescent signal. Based on our own and literature data, a scheme of LDC generation is suggested. The origin of superoxide anion detected in intact mitochondria with lucigenin is discussed.     

Mitochondria as the target for mildronate's protective effects in azidothymidine (AZT)-induced toxicity of isolated rat liver mitochondria

Previously mildronate, an aza-butyrobetaine derivative, was shown to be a cytoprotective drug, through its mechanism of action of inhibition of carnitine palmitoyltransferase-1, thus protecting mitochondria from long-chain fatty acid accumulation and subsequent damage. Recently in an azidothymidine (AZT)-induced cardiotoxicity model in vivo (in mice), we have found mildronate's ability of protecting heart tissue from nuclear factor kappaB abnormal expression. Preliminary data also demonstrate cerebro- and hepatoprotecting properties of mildronate in AZT-toxicity models. We suggest that mildronate may target its action predominantly to mitochondria. The present study in isolated rat liver mitochondria was designed to clarify mitochondrial targets for mildronate by using AZT as a model compound. The aim of this study was to investigate: (1) whether mildronate may protect mitochondria from AZT-induced toxicity; and (2) which is the most critical target in mitochondrial processes that is responsible for mildronate's regulatory action. The results showed that mildronate protected mitochondria from AZT-induced damage predominantly at the level of complex I, mainly by reducing hydrogen peroxide generation. Significant protection of AZT-caused inhibition of uncoupled respiration, ADP to oxygen ratio, and transmembrane potential were also observed. Mildronate per se had no effect on the bioenergetics, oxidative stress, or permeability transition of rat liver mitochondria. Since mitochondrial complex I is the first enzyme of the respiratory electron transport chain and its damage is considered to be responsible for different mitochondrial diseases, we may account for mildronate's effectiveness in the prevention of pathologies associated with mitochondrial dysfunctions.     

Effects of tamoxifen on the electron transport chain of isolated rat liver mitochondria

Tamoxifen (and 4-hydroxytamoxifen), a nonsteroidal triphenylethylene antiestrogenic drug widely used in the treatment of breast cancer, interacts strongly with the respiratory chain of isolated rat liver mitochondria. The drug acts as both an uncoupling agent and a powerful inhibitor of electron transport. Tamoxifen brings about a collapse of the membrane potential. Enzymatic assays and spectroscopic studies indicate that tamoxifen inhibits electron transfer in the respiratory chain at the levels of complex III (ubiquinol–cytochrome-c reductase) and, to a lesser extent, of complex IV (cytochrome-c oxidase). The activities can be restored by the addition of diphosphatidylglycerol, a phospholipid implicated in the functioning of the respiratory chain complexes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Direct measurement of oscillatory generation of superoxide anions by single phagocytes

Phagocytic cells such as neutrophils generate superoxide anions (O₂⁻) within phagocytic vacuoles for killing and digesting microorganisms. Here we report the simultaneous observation of morphological changes and O₂⁻ generation in single phagocytic cells during phagocytosis. Point stimulation of a cell by contact with an opsonized microelectrode at the cell surface induced significant deformation to engulf the electrode, and also induced the O₂⁻ generation which was measured by the electrode. Periodic fluctuations in the magnitude of the O₂⁻ generation were observed in the time course. These oscillations may be caused by metabolic regulation of the formation of NADPH, which is the substrate for the O₂⁻ generation.     

Mitochondrial functional impairment with aging is exaggerated in isolated mitochondria compared to permeabilized myofibers

Mitochondria regulate cellular bioenergetics and apoptosis and have been implicated in aging. However, it remains unclear whether age‐related loss of muscle mass, known as sarcopenia, is associated with abnormal mitochondrial function. Two technically different approaches have mainly been used to measure mitochondrial function: isolated mitochondria and permeabilized myofiber bundles, but the reliability of these measures in the context of sarcopenia has not been systematically assessed before. A key difference between these approaches is that contrary to isolated mitochondria, permeabilized bundles contain the totality of fiber mitochondria where normal mitochondrial morphology and intracellular interactions are preserved. Using the gastrocnemius muscle from young adult and senescent rats, we show marked effects of aging on three primary indices of mitochondrial function (respiration, H₂O₂ emission, sensitivity of permeability transition pore to Ca²⁺) when measured in isolated mitochondria, but to a much lesser degree when measured in permeabilized bundles. Our results clearly demonstrate that mitochondrial isolation procedures typically employed to study aged muscles expose functional impairments not seen in situ. We conclude that aging is associated with more modest changes in mitochondrial function in sarcopenic muscle than suggested previously from isolated organelle studies.     

The effect of superoxide generation on the ability of mitochondria to take up and retain Ca2+

When heart or liver mitochondria are exposed to superoxide radicals generated from xanthine + xanthine oxidase their ability to take up and to retain Ca2+ is impaired. The rate of oxidation of pyruvate + malate as substrates is diminished and the appearance of thiol groups when the mitochondria are supplied with these substrates is abolished. These inhibitory effects are offset if respiration is supported by succinate in presence of rotenone provided that a substrate (beta-hydroxybutyrate) is provided to maintain the reduction of NADH. The data agree with the thesis that a generation of thiol groups is essential to maintain membrane integrity and that the generation depends on provision of reduced NAD(P)H.     

Palmitate oxidation by the mitochondria from volume-overloaded rat hearts

In this work, an attempt was made to identify the reasons of impaired long-chain fatty acid utilization that waspreviously described in volume-overloaded rat hearts. The most significant data are the following: (1) The slowing down of long-chain fatty acid oxidation in severely hypertrophied hearts cannot be related to a feedback inhibition of carnitine palmitoyltransferase I from an excessive stimulation of glucose oxidation since, because of decreased tissue levels of L-carnitine, glucose oxidation also declines in volume-overloaded hearts. (2) While, in control hearts, the estimated intracellular concentrations of free carnitine are in the range of the respective K_m of mitochondrial CPT I, a kinetic limitation of this enzyme could occur in hypertrophied hearts due to a 40% decrease in free carnitine. (3) However, the impaired palmitate oxidation persists upon the isolation of the mitochondria from these hearts even in presence of saturating concentrations of L-carnitine. In contrast, the rates of the conversion of both palmitoyl-CoA and palmitoylcarnitine into acetyl-CoA are unchanged. (4) The kinetic analyses of palmitoyl-CoA synthase and carnitine palmitoyltransferase I reactions do not reveal any differences between the two mitochondrial populations studied. On the other hand, the conversion of palmitate into palmitoylcarnitine proves to be substrate inhibited already at physiological concentrations of exogenous palmitate. The data presented in this work demonstrate that, during the development of a severe cardiac hypertrophy, a fragilization of the mitochondrial outer membrane may occur. The functional integrity of this membrane seems to be further deteriorated by increasing concentrations of free fatty acids which gives rise to an impaired functional cooperation between palmitoyl-CoA synthase and carnitine palmitoyltransferase I. In intact myocardium, the utilization of the generated in situ palmitoyl-CoA can be further slowed down by decreased intracellular concentrations of free carnitine.     

Research on mitochondria and aging, 2006-2007

This review focuses on some of the 'hot topics' that fall under the general heading 'mitochondria and aging'. For each selected topic, we highlight recent publications that have either addressed specific problems within the field or presented novel findings of interest regarding the links between mitochondria and aging. These include studies on the structure of complex I and the mechanisms of superoxide production by this complex; work showing a novel site of hydrogen peroxide production within mitochondria that is modulated by caloric restriction; explorations of the relationship between the rate of evolution of mitochondrial DNA and lifespan; a demonstration that mitochondrial DNA mutations do not limit lifespan in mice; and investigations of the effects of mitochondrial fission on aging. We also list other relevant articles of interest and suggest some key challenges for the field in the near future.     

Targeting mitochondria by anthelmintic drug atovaquone sensitizes renal cell carcinoma to chemotherapy and immunotherapy

Targeting mitochondria respiration is an effective therapeutic strategy in renal cell carcinoma (RCC). Atovaquone is a FDA‐approved antibiotic but is also known as a mitochondrial inhibitor. We found that atovaquone inhibited proliferation and induced apoptosis of RCC cells. Mechanistically, atovaquone inhibits mitochondrial respiration in a concentration‐dependent and time‐dependent manner, via targeting mitochondrial respiratory complex III. Although increased glycolysis was observed in atovaquone‐treated cells, atovaquone decreased ATP levels. As a consequence of mitochondrial respiration inhibition, reactive oxygen species levels were increased by atovaquone. The complete rescue of atovaquone's effects by an antioxidant suggests the important role of oxidative stress in the action of atovaquone in RCC. Importantly, atovaquone enhanced the in vitro and in vivo efficacy of 5‐fluorouracil (5‐FU) and interferon‐α (IFN‐α). Our preclinical findings suggest that atovaquone is a useful addition for RCC treatment. Our work also further demonstrates that RCC is more dependent on mitochondrial respiration than glycolysis.     

Prohibitin involvement in the generation of mitochondrial superoxide at complex I in human sperm

Prohibitin (PHB), a major mitochondrial membrane protein, has been shown earlier in our laboratoryto regulate sperm motility via an alteration in mitochondrial membrane potential (MMP) in infertile men with poor sperm quality. To test if PHB expression is associated with sperm mitochondrial superoxide (mROS) levels, here we examined sperm mROS levels, high MMP and lipid peroxidation in infertile men with poor sperm motility (asthenospermia, A) and/or low sperm concentrations (oligoasthenospermia, OA). The diaphorase‐type activity of sperm mitochondrial complex I (MCI) and PHB expression were also determined. We demonstrate that mROS and lipid peroxidation levels are significantly higher in sperm from A and OA subjects than in normospermic subjects, whereas high MMP and PHB expression are significantly lower. A positive correlation between mROS and lipid peroxidation and a negative correlation of mROS with PHB expression, high MMP, and sperm motility were found in these subjects. The finding of similar diaphorase‐type activity levels of sperm MCI in the three groups studied suggests that the catalytic subunits of MCI in the matrix arm may produce mROS on its own. There may be a dysfunction of electron transport at MCI associated with decreased expression of PHB in sperm with poor quality. We conclude that mROS level is increased and associated with decreased PHB expression, and it may regulate sperm motility via increases in low MMP and lipid peroxidation. This is the first report on the involvement of PHB in human sperm motility loss associated with increased generation of mROS at MCI.     

Association of Cu,Zn-type superoxide dismutase with mitochondria and peroxisomes

The subcellular localization of Cu,Zn-type superoxide dismutase (Cu,Zn-SOD) was investigated in rat tissues and cultured human fibroblasts. Subcellular fractionation, Nycodenz gradient centrifugation, and immunoblot analysis using specific antibodies showed that Cu,Zn-SOD was localized in cytosol, mitochondria, and peroxisomes of rat liver and brain. Treatment of highly purified mitochondria from rat liver with either Chaps or Triton X-100 released the bound Cu,Zn-SOD into supernatant fraction. Depolarization of mitochondria by inorganic phosphate and Ca(2+) released both Cu,Zn-SOD and cytochrome c from mitochondria. Digitonin also released Cu,Zn-SOD but not cytochrome c from mitochondria. Confocal immunofluorescence microscopy revealed that anti-Cu,Zn-SOD antibody in cultured human fibroblasts was found to colocalize with antibodies to Mn-SOD and PMP-70, markers of mitochondria and peroxisomes, respectively. Incubation of human Cu,Zn-SOD with purified mitochondria resulted in their association. These results indicate that Cu,Zn-SOD associates with mitochondria and peroxisomes in various cell types such as those in brain, liver, and skin.     

Calcium- and ADP-Magnesium-induced respiratory uncoupling in isolated cardiac mitochondria: Influence of cycolsporin A

This study was designed to determine the effect of calcium and ADP-Mg on the oxidative phosphorylation in isolated cardiac mitochondria. The influence of cyclosporin A was also evaluated. The mitochondria were extracted from rat ventricles. Their oxidative phosphorylations were determined in two respiration media with different free Ca²⁺ concentrations. Respiration was determined with palmitoylcarnitine and either ADP- or ADP-Mg. With elevated free Ca²⁺concentrations and ADP-Mg, the transition state III to state IV respiration did not occurred. The ADP:O ratio was reduced. The phenomenon was not observed in the other experimental conditions (low free Ca²⁺ concentration with either ADP^- or ADP-Mg or elevated free Ca²⁺ concentration with ADP^-). Uncoupling was allied with a constant AMP production, which maintained an elevated ADP level in the respiration medium and prevented the return to state IV respiration. It was also observed in a respiration medium devoid of free Ca²⁺ when the mitochondria were pre-loaded with Ca²⁺. Uncoupling was inhibited by cyclosporin A. Furthermore, the Krebs cycle intermediates released from¹⁴C-palmitoylcarnitine oxidation revealed that succinate was increased by elevated free Ca²⁺ and ADP-Mg. Succinate is a FAD-linked substrate with low respiration efficiency. Its accumulation could account for the decreased ADP:O ratio. The Ca²⁺- and ADP-Mg-induced uncoupling might be partly responsible for the mechanical abnormalities observed during low-flow ischemia. (Mol Cell Biochem 000: 000-000, 1999)     

The quantitative measurement of H2O2 generation in isolated mitochondria

Adequate methods to measure the rate of mitochondrial oxygen radical generation are needed since oxygen radicals are involved in many pathologies. A fluorometric method appropriate to measure the rate of generation of H₂O₂ in intact mitochondria is described. Just after isolation of functional mitochondria from fresh tissues, rates of generation of H₂O₂ are kinetically measured by fluorometry in the presence of homovanillic acid and horseradish peroxidase. The method is specific for H₂O₂ and is sensitive enough to assay mitochondrial H₂O₂ generation in the presence of respiratory substrate without inhibitors of the respiratory chain. Simultaneous measurement of mitochondrial oxygen consumption allows calculation of the free radical leak: the percentage of electrons out of sequence which reduce oxygen to oxygen radicals along the mitochondrial respiratory chain instead of reducing oxygen to water at the terminal cytochrome oxidase. The method shows instantaneous response to H₂O₂. This makes it appropriate to study the quick effects of different inhibitors and modulators on the rate of mitochondrial oxygen radical production. Its application to the localization of the sites where caloric restriction decreases mitochondrial oxygen radical generation in heart mitochondria is described.     

Cu/Zn superoxide dismutase in yeast mitochondria - a general phenomenon

Fermentative and respiratory yeast strains of genera Saccharomyces, Kluyveromyces, Pichia, Candida and Hansenula have been investigated for mitochondrial localization of Cu/Zn superoxide dismutase (SOD). Pure mitochondrial fractions were obtained and the specific activities of Cu/Zn and Mn SODs were measured in comparison with those in the corresponding cell-free extracts. The Cu/Zn SOD: Mn SOD ratio in mitochondria and crude extracts was calculated and was considered a specific characteristic of all tested strains. Electrophoretical visualization of SOD patterns provided evidence for possible migration of cytosolic Cu/Zn SOD to mitochondria. The characteristic Cu/Zn SOD profile in mitochondria of all tested strains suggested its ubiquity within the fermentative and respiratory yeasts.     

In vivo real-time measurement of superoxide anion radical with a novel electrochemical sensor

The dynamics of superoxide anion (O₂⁻) in vivo remain to be clarified because no appropriate method exists to directly and continuously monitor and evaluate O₂⁻ in vivo. Here, we establish an in vivo method using a novel electrochemical O₂⁻ sensor. O₂⁻ generated is measured as a current and evaluated as a quantified partial value of electricity (Q_part), which is calculated by integration of the difference between the baseline and the actual reacted current. The accuracy and efficacy of this method were confirmed by dose-dependent O₂⁻ generation in xanthine–xanthine oxidase in vitro in phosphate-buffered saline and human blood. It was then applied to endotoxemic rats in vivo. O₂⁻ current began to increase 1 h after lipopolysaccharide, and Q_part increased significantly for 6 h in endotoxemic rats, in comparison to sham-treated rats. These values were attenuated by superoxide dismutase. The generation and attenuation of O₂⁻ were indirectly confirmed by plasma lipid peroxidation with malondialdehyde, endothelial injury with soluble intercellular adhesion molecule-1, and microcirculatory dysfunction. This is a novel method for measuring O₂⁻ in vivo and could be used to monitor and treat the pathophysiology caused by excessive O₂⁻ generation in animals and humans.     

Enhanced hydrogen peroxide generation accompanies the beneficial bioenergetic effects of methylene blue in isolated brain mitochondria

The redox dye methylene blue (MB) is proven to have beneficial effects in various models of neurodegenerative diseases. Here we investigated the effects of MB (100 nM, 300 nM, and 1 μM) on key bioenergetic parameters and on H₂O₂ production/elimination in isolated guinea pig brain mitochondria under normal as well as respiration-impaired conditions. As measured by high-resolution Oxygraph the rate of resting oxygen consumption was increased, but the ADP-stimulated respiration was unaffected by MB with any of the substrates (glutamate malate, succinate, or α-glycerophosphate) used for supporting mitochondrial respiration. In mitochondria treated with inhibitors of complex I or complex III MB moderately but significantly increased the rate of ATP production, restored ΔΨ_m, and increased the rate of Ca²⁺ uptake. The effects of MB are consistent with transferring electrons from upstream components of the electron transport chain to cytochrome c, which is energetically favorable when the flow of electrons in the respiratory chain is compromised. On the other hand, MB significantly increased the production of H₂O₂ measured by Amplex UltraRed fluorimetry under all conditions, in resting, ATP-synthesizing, and respiration-impaired mitochondria, with each substrate combination supporting respiration. Furthermore, it also decreased the elimination of H₂O₂. Generation of H₂O₂ without superoxide formation, observed in the presence of MB, is interpreted as a result of reduction of molecular oxygen to H₂O₂ by the reduced MB. The elevated generation and impaired elimination of H₂O₂ should be considered for the overall oxidative state of mitochondria treated with MB.     

Coevolution Predicts Direct Interactions between mtDNA-Encoded and nDNA-Encoded Subunits of Oxidative Phosphorylation Complex I

Despite years of research, the structure of the largest mammalian oxidative phosphorylation (OXPHOS) complex, NADH-ubiquinone oxidoreductase (complex I), and the interactions among its 45 subunits are not fully understood. Since complex I harbors subunits encoded by mitochondrial DNA (mtDNA) and nuclear DNA (nDNA) genomes, with the former evolving ∼ 10 times faster than the latter, tight cytonuclear coevolution is expected and observed. Recently, we identified three nDNA-encoded complex I subunits that underwent accelerated amino acid replacement, suggesting their adjustment to the elevated mtDNA rate of change. Hence, they constitute excellent candidates for binding mtDNA-encoded subunits.Here, we further disentangle the network of physical cytonuclear interactions within complex I by analyzing subunits coevolution. Firstly, relying on the bioinformatic analysis of 10 protein complexes possessing solved structures, we show that signals of coevolution identified physically interacting subunits with nearly 90% accuracy, thus lending support to our approach. When applying this approach to cytonuclear interaction within complex I, we predict that the ‘rate-accelerated’ nDNA-encoded subunits of complex I, NDUFC2 and NDUFA1, likely interact with the mtDNA-encoded subunits ND5/ND4 and ND5/ND4/ND1, respectively. Furthermore, we predicted interactions among mtDNA-encoded complex I subunits. Using the yeast two-hybrid system, we experimentally confirmed the predicted interactions of human NDUFC2 with ND4, the interactions of human NDUFA1 with ND1 and ND4, and the lack of interaction of NDUFC2 with ND3 and NDUFA1, thus providing a proof of concept for our approach.Our study shows, for the first time, evidence for direct interactions between nDNA-encoded and mtDNA-encoded subunits of human OXPHOS complex I and paves the path towards deciphering subunit interactions within complexes lacking three-dimensional structures. Our subunit-interactions-predicting method, ComplexCorr, is available at http://webclu.bio.wzw.tum.de/complexcorr.     

Infra-red thermography revealed a role for mitochondria in pre-symptomatic cooling during harpin-induced hypersensitive response

The establishment of Erwinia amylovora harpin-induced hypersensitive response (HR) in Nicotiana sylvestris was followed by infra-red thermography (IRT). Three to four hours after elicitation, the temperature decreased in the harpin-infiltrated zone associated to stomatal opening. The marked drop in temperature which reached 2 degrees C and preceded necrosis symptoms for several hours, is thus likely caused by higher transpiration. Neither of these effects was observed in a respiratory mutant, affected in complex I structure and function and over-expressing alternative oxidase, indicating that they are directly or indirectly mediated by mitochondrial function. However, as the HR establishment was similar in both wild type and mutant, cell death was either uncorrelated with the observed epidermal changes or occurred by a different signalling pathway in the two genotypes. IRT revealed a novel aspect of plant-pathogen interactions and could be applied to screen for mutants affected in elicitor signalling and/or for respiratory mutants.