Inhibition of fatty acid-supported mitochondrial respiration by cyclosporine

We have shown that, in addition to inhibition of the succinate-supported energy pathway (5), CS inhibition of mitochondrial Complex II activity also limits fatty acid oxidation. These results are consistent with the participation of altered lipid metabolism in CS nephrotoxicity.     

Sites of inhibition of mitochondrial electron transport in macrophage- injured neoplastic cells

Previous work has shown that injury of neoplastic cells by cytotoxic macrophages (CM) in cell culture is accompanied by inhibition of mitochondrial respiration. We have investigated the nature of this inhibition by studying mitochondrial respiration in CM-injured leukemia L1210 cells permeabilized with digitonin. CM-induced injury affects the mitochondrial respiratory chain proper. Complex I (NADH-coenzyme Q reductase) and complex II (succinate-coenzyme Q reductase) are markedly inhibited. In addition a minor inhibition of cytochrome oxidase was found. Electron transport from alpha-glycerophosphate through the respiratory chain to oxygen is unaffected and permeabilized CM-injured L1210 cells oxidizing this substrate exhibit acceptor control. However, glycerophosphate shuttle activity was found not to occur within CM- injured or uninjured L1210 cells in culture hence, alpha- glycerophosphate is apparently unavailable for mitochondrial oxidation in the intact cell. It is concluded that the failure of respiration of intact neoplastic cells injured by CM is caused by the nearly complete inhibition of complexes I and II of the mitochondrial electron transport chain. The time courses of CM-induced electron transport inhibition and arrest of L1210 cell division are examined and the possible relationship between these phenomena is discussed.     

Inactivation of mitochondrial electron transport by photosensitization of a pheophorbide a derivative

We examined the damage to mitochondrial electron transport caused by photosensitization of a pheophorbide a derivative, DH-I-180-3, shown recently to induce necrosis of lung carcinoma cells with low dark toxicity. Confocal microscopy showed that DH-I-180-3 co-localized with dihydrorhodamine-123 suggesting that it mainly accumulates in mitochondria. The photosensitizer alone in the dark did not affect mitochondrial electron transport. Illumination of isolated mitochondria in the presence of DH-I-180-3 resulted in inhibition of both NADH- and succinate-dependent respiration. Measurement of the activity of each component of the electron transport chain revealed that Complex I and III were very susceptible to the treatment whereas Complex IV was resistant. We conclude that the photosensitizer is localized in mitochondria and, upon illumination, produces reactive oxygen species that inactivate Complexes I and III.     

Mitochondrial Adaptations to NaCl. Complex I Is Protected by Anti-Oxidants and Small Heat Shock Proteins, Whereas Complex II Is Protected by Proline and Betaine

High soil sodium (Na) is a common stress in natural and agricultural systems. Roots are usually the first tissues exposed to Na stress and Na stress-related impairment of mitochondrial function is likely to be particularly important in roots. However, neither the effects of NaCl on mitochondrial function, nor its protection by several potential adaptive mechanisms, have been well studied. This study investigated the effects of NaCl stress on maize (Zea mays) mitochondrial electron transport and its relative protection by osmoprotectants (proline, betaine, and sucrose), antioxidants (ascorbate, glutathione, and alpha-tocopherol), antioxidant enzymes (catalase and Cu/Zn-superoxide dismutase), and mitochondrial small heat shock proteins (sHsps). We demonstrate that Complex I electron transport is protected by antioxidants and sHsps, but not osmoprotectants, whereas Complex II is protected only by low concentrations of proline and betaine. These results indicate that NaCl stress damaged Complex I via oxidative stress and suggests that sHsps may protect Complex I as antioxidants, but NaCl damaged Complex II directly. This is the first study to demonstrate that NaCl stress differentially affects Complex I and II in plants and that protection of Complex I and II during NaCl stress is achieved by different mechanisms.     

Differential sensitivity to cadmium of key mitochondrial enzymes in the eastern oyster, Crassostrea virginica Gmelin (Bivalvia: Ostreidae)

Combined effects of cadmium (Cd) and temperature on key mitochondrial enzymes [including Complexes I-IV of electron transport chain and Krebs cycle enzymes citrate synthase (CS), and NAD- and NADP-dependent isocitrate dehydrogenases (NAD-IDH and NADP-IDH)] were studied in a marine ectotherm, Crassostrea virginica in order to better understand the mechanisms of Cd-induced impairment of mitochondrial function. Matrix enzymes including CS and isocitrate dehydrogenases were the most sensitive to Cd making Krebs cycle a likely candidate to explain Cd-induced impairment of mitochondrial substrate oxidation. CS and NAD-IDH had IC(50) of 26 and 65 microM at the acclimation temperature (15 degrees C) and 65 (CS) and 1.5 (NAD-IDH) microM at elevated temperature (25 degrees C), respectively. Mitochondrial NADP-IDH was the most sensitive to Cd with IC(50) of 14 and 3.4 microM at 15 degrees and 25 degrees C, respectively. Electron transport chain (ETC) complexes were significantly less sensitive to the direct effects of Cd with IC(50) ranging from 260 to >400 microM. Temperature increase led to a higher sensitivity of mitochondrial enzymes to the inhibitory effects of Cd as indicated by a decline in IC(50) with the exception of Complex III from gills and CS from gills and hepatopancreas. Cd exposure also resulted in a decrease in activation energy of mitochondrial enzymes suggesting that mitochondria from Cd-exposed oysters could exhibit reduced capacity to respond to temperature rise with an adequate increase in the substrate flux. These interactive effects of Cd and temperature on mitochondrial enzymes could negatively affect metabolic performance of oysters and possibly other ectotherms in polluted environments during temperature increase such as expected during the global climate change and/or tidal or seasonal warming in estuarine and coastal waters.     

The stability and activity of respiratory Complex II is cardiolipin-dependent

Respiratory Complex II of the mitochondrial inner membrane serves as a link between the tricarboxylic acid cycle and the electron transport chain. Complex II dysfunction has been implicated in a wide range of heritable mitochondrial diseases, including cancer, by a mechanism that likely involves the production of reactive oxygen species (ROS). Using Complex II enzymes reconstituted into nanoscale lipid bilayers (nanodiscs) with varying lipid composition, we demonstrate for the first time that the phospholipid environment, specifically the presence of cardiolipin, is critical for the assembly and enzymatic activity of the complex, as well as in the curtailment of ROS production.     

Crystal structure of mitochondrial respiratory membrane protein complex II

The mitochondrial respiratory Complex II or succinate:ubiquinone oxidoreductase (SQR) is an integral membrane protein complex in both the tricarboxylic acid cycle and aerobic respiration. Here we report the first crystal structure of Complex II from porcine heart at 2.4 A resolution and its complex structure with inhibitors 3-nitropropionate and 2-thenoyltrifluoroacetone (TTFA) at 3.5 A resolution. Complex II is comprised of two hydrophilic proteins, flavoprotein (Fp) and iron-sulfur protein (Ip), and two transmembrane proteins (CybL and CybS), as well as prosthetic groups required for electron transfer from succinate to ubiquinone. The structure correlates the protein environments around prosthetic groups with their unique midpoint redox potentials. Two ubiquinone binding sites are discussed and elucidated by TTFA binding. The Complex II structure provides a bona fide model for study of the mitochondrial respiratory system and human mitochondrial diseases related to mutations in this complex.     

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.     

Altered mitochondrial functioning induced by preoperative fasting may underlie protection against renal ischemia/reperfusion injury

We reported previously that the robust protection against renal ischemia/reperfusion (I/R) injury in mice by fasting was largely initiated before the induction of renal I/R. In addition, we found that preoperative fasting downregulated the gene expression levels of complexes I, IV, and V of the mitochondrial oxidative phosphorylation (OXPHOS) system, while it did not change those of complexes II and III. Hence, we now investigated the effect of 3 days of fasting on the functioning of renal mitochondria in order to better understand our previous findings. Fasting did not affect mitochondrial density. Surprisingly, fasting significantly increased the protein expression of complex II of the mitochondrial OXPHOS system by 19%. Complex II‐driven state 3 respiratory activity was significantly reduced by fasting (46%), which could be partially attributed to the significant decrease in the enzyme activity of complex II (16%). Fasting significantly inhibited Ca²⁺‐dependent mitochondrial permeability transition pore opening that is directly linked to protection against renal I/R injury. The inhibition of the mitochondrial permeability transition pore did not involve the expression of the voltage‐dependent anion channel by fasting. In conclusion, 3 days of fasting clearly induces the inhibition of complex II‐driven mitochondrial respiration state 3 in part by decreasing the amount of functional complex II, and inhibits mitochondrial permeability transition pore opening. This might be a relevant sequence of events that could contribute to the protection of the kidney against I/R injury. J. Cell. Biochem. 114: 230–237, 2012. © 2012 Wiley Periodicals, Inc.     

Arabidopsis PPR40 connects abiotic stress responses to mitochondrial electron transport

Oxidative respiration produces adenosine triphosphate through the mitochondrial electron transport system controlling the energy supply of plant cells. Here we describe a mitochondrial pentatricopeptide repeat (PPR) domain protein, PPR40, which provides a signaling link between mitochondrial electron transport and regulation of stress and hormonal responses in Arabidopsis (Arabidopsis thaliana). Insertion mutations inactivating PPR40 result in semidwarf growth habit and enhanced sensitivity to salt, abscisic acid, and oxidative stress. Genetic complementation by overexpression of PPR40 complementary DNA restores the ppr40 mutant phenotype to wild type. The PPR40 protein is localized in the mitochondria and found in association with Complex III of the electron transport system. In the ppr40-1 mutant the electron transport through Complex III is strongly reduced, whereas Complex IV is functional, indicating that PPR40 is important for the ubiqinol-cytochrome c oxidoreductase activity of Complex III. Enhanced stress sensitivity of the ppr40-1 mutant is accompanied by accumulation of reactive oxygen species, enhanced lipid peroxidation, higher superoxide dismutase activity, and altered activation of several stress-responsive genes including the alternative oxidase AOX1d. These results suggest a close link between regulation of oxidative respiration and environmental adaptation in Arabidopsis.     

Apoptotic death in Leishmania donovani promastigotes in response to respiratory chain inhibition: complex II inhibition results in increased pentamidine cytotoxicity

The biochemical changes consequent to respiratory chain inhibition and their relationship to cell death in Leishmania spp. remain elusive. Inhibitors of respiratory chain complexes I, II, and III were able to induce apoptotic death of the bloodstream form of Leishmania donovani. Complex I inhibition resulted in mitochondrial hyperpolarization that was preceded by increased superoxide production. Limitation of electron transport by thenoyltrifluoroacetone and antimycin A, inhibitors of complexes II and III, respectively, resulted in dissipation of mitochondrial membrane potential that was sensitive to cyclosporin A, a blocker of mitochondrial permeability transition pore. Further studies conducted with thenoyltrifluoroacetone showed maximal generation of hydrogen peroxide with a moderate elevation of superoxide levels. Complex III inhibition provoked superoxide generation only. Interference with complex II but not complexes I and III increased intracellular Ca(2+). A tight link between Ca(2+) and reactive oxygen species was demonstrated by antioxidant-induced diminution of the Ca(2+) increase. However, chelation of extracellular Ca(2+) could not abrogate the early increase of reactive oxygen species, providing evidence that Ca(2+) elevation was downstream to reactive oxygen species generation. Ca(2+) influx occurred through nonselective cation and L-type channels and Na(+)/Ca(2+) exchanger-like pathways. Antioxidants such as glutathione and Ca(2+) channel blockers reduced apoptotic death. This study provides a new possibility that concurrent inhibition of respiratory chain complex II with pentamidine administration increases cytotoxicity of the drug. This increased cytotoxicity was connected to a 4-fold elevation in intracellular Ca(2+) that was pooled only from intracellular sources. Therefore, inhibition of complexes I, II, and III leads to apoptosis and complex II inhibition in parallel with pentamidine administration-enhanced drug efficacy.     

Rapid purification and mass spectrometric characterization of mitochondrial NADH dehydrogenase (Complex I) from rodent brain and a dopaminergic neuronal cell line

Oxidative stress and mitochondrial dysfunction signify important biochemical events associated with the loss of dopaminergic neurons in Parkinson's disease (PD). Studies using in vitro and in vivo PD models or tissues from diseased patients have demonstrated a selective inhibition of mitochondrial NADH dehydrogenase (Complex I of the OXPHOS electron transport chain) that affects normal mitochondrial physiology leading to neuronal death. In an earlier study, we demonstrated that oxidative stress due to glutathione depletion in dopaminergic cells, a hallmark of PD, leads to Complex I inhibition via cysteine thiol oxidation (Jha et al. (2000) J. Biol. Chem. 275, 26096-26101). Complex I is a approximately 980-kDa multimeric enzyme spanning the inner mitochondrial membrane comprising at least 45 protein subunits. As a prerequisite to investigating modifications to Complex I using a rodent disease model for PD, we developed two independent rapid and mild isolation procedures based on sucrose gradient fractionation and immunoprecipitation to isolate Complex I from mouse brain and a cultured rat mesencephalic dopaminergic neuronal cell line. Both protocols are capable of purifying Complex I from small amounts of rodent tissue and cell cultures. Blue Native gel electrophoresis, one-dimensional and two-dimensional SDS-PAGE were employed to assess the purity and composition of isolated Complex I followed by extensive mass spectrometric characterization. Altogether, 41 of 45 rodent Complex I subunits achieved MS/MS sequence coverage. To our knowledge, this study provides the first detailed mass spectrometric analysis of neuronal Complex I proteins and provides a means to investigate the role of cysteine oxidation and other posttranslational modifications in pathologies associated with mitochondrial dysfunction.     

Mitochondrial Complex I superoxide production is attenuated by uncoupling

Complex I, i.e. proton-pumping NADH:quinone oxidoreductase, is an essential component of the mitochondrial respiratory chain but produces superoxide as a side-reaction. However, conditions for maximum superoxide production or its attenuation are not well understood. Unlike for Complex III, it has not been clear whether a Complex I-derived superoxide generation at forward electron transport is sensitive to membrane potential or protonmotive force. In order to investigate this, we used Amplex Red for H(2)O(2) monitoring, assessing the total mitochondrial superoxide production in isolated rat liver mitochondria respiring at state 4 as well as at state 3, namely with exclusive Complex I substrates or with Complex I substrates plus succinate. We have shown for the first time, that uncoupling diminishes rotenone-induced H(2)O(2) production also in state 3, while similar attenuation was observed in state 4. Moreover, we have found that 5-(N-ethyl-N-isopropyl) amiloride is a real inhibitor of Complex I H(+) pumping (IC(50) of 27 microM) without affecting respiration. It also partially prevented suppression by FCCP of rotenone-induced H(2)O(2) production with Complex I substrates alone (glutamate and malate), but nearly completely with Complexes I and II substrates. Sole 5-(N-ethyl-N-isopropyl) amiloride alone suppressed 20% and 30% of total H(2)O(2) production, respectively, under these conditions. Our data suggest that Complex I mitochondrial superoxide production can be attenuated by uncoupling, which means by acceleration of Complex I H(+) pumping due to the respiratory control. However, when this acceleration is prevented by 5-(N-ethyl-N-isopropyl) amiloride inhibition, no attenuation of superoxide production takes place.     

Mitochondrial Generation of Oxygen Radicals During Reoxygenation of Ischemic Tissues

Ischemia and reperfusion causes severe mitochondrial damage, including swelling and deposits of hyd-roxyapatite crystals in the mitochondrial matrix. These crystals are indicative of a massive influx of Ca²⁺ into the mitochondrial matrix occurring during reoxygenation. We have observed that mitochondria isolated from rat hearts after 90 minutes of anoxia followed by reoxygenation, show a specific inhibition in the electron transport chain between NADH dehydrogenase and ubiquinone in addition to becoming uncoupled (unable to generate ATP). This inhibition is associated with an increased H₂O₂ formation at the NADH dehydrogenase level in the presence of NADH dependent substrates. Control rat mitochondria exposed for 15 minutes to high Ca²⁺ (200 nmol/mg protein) also become uncoupled and electron transport inhibited between NADH dehydrogenase and ubiquinone. a lesion similar to that observed in post-ischem-ic mitochondria. This Ca²⁺ -dependent effect is time dependent and may be partially prevented by albumin, suggesting that it may be due to phospholipase A₂ activation. releasing fatty acids, leading to both inhibition of electron transport and uncoupling. Addition of arachidonic or linoleic acids to control rat heart mitochondria, inhibits electron transport between Complex I and III. These results are consistent with the following hypothesis: during ischemia, the intracellular energy content drops severely, affecting the cytoplasic concentration of ions such as Na⁺ and Ca²⁺. Upon reoxygenation, the mitochondrion is the only organelle capable of eliminating the excess cytoplasmic Ca²⁺ through an electrogenic process requiring oxygen (the low ATP concentration makes other ATP-dependent Ca^?' lransport systems non-operational). Ca²⁺-overload of mitochondria activates phospholipase A₂ releasing free fatty acids, leading to uncoupling and inhibition of the interactions between Complex I and III of the respiratory chain. As a consequence, the NADH-dehydrogenase becomes highly reduced, and transfers electrons directly to oxygen generating O₂.     

Caspase-mediated loss of mitochondrial function and generation of reactive oxygen species during apoptosis

During apoptosis, the permeabilization of the mitochondrial outer membrane allows the release of cytochrome c, which induces caspase activation to orchestrate the death of the cell. Mitochondria rapidly lose their transmembrane potential (Delta Psi m) and generate reactive oxygen species (ROS), both of which are likely to contribute to the dismantling of the cell. Here we show that both the rapid loss of Delta Psi m and the generation of ROS are due to the effects of activated caspases on mitochondrial electron transport complexes I and II. Caspase-3 disrupts oxygen consumption induced by complex I and II substrates but not that induced by electron transfer to complex IV. Similarly, Delta Psi m generated in the presence of complex I or II substrates is disrupted by caspase-3, and ROS are produced. Complex III activity measured by cytochrome c reduction remains intact after caspase-3 treatment. In apoptotic cells, electron transport and oxygen consumption that depends on complex I or II was disrupted in a caspase-dependent manner. Our results indicate that after cytochrome c release the activation of caspases feeds back on the permeabilized mitochondria to damage mitochondrial function (loss of Delta Psi m) and generate ROS through effects of caspases on complex I and II in the electron transport chain.     

The effect of glucagon on hepatic respiratory capacity

Data from numerous laboratories show that mitochondria isolated from livers treated acutely with glucagon have higher rates of state 3 respiration than control mitochondria. The purpose of the present study was to learn whether this phenomenon is an isolation artifact resulting from a stabilization of the mitochondrial membrane or whether it represents a real increase in the maximal respiratory capacity of liver cells due to glucagon treatment. Electron transport was measured through different spans of the electron transport chain by using ferricyanide as an alternate electron acceptor to O2. With isolated intact liver mitochondria, pretreatment with glucagon was found to cause an increase in electron flow, through both Complex I and Complex III, suggesting that the effect of glucagon was not specific for a single site in the electron transport chain. Using intact isolated hepatocytes, different results are obtained. Respiration was measured in isolated hepatocytes after quantitation of the hepatocyte mitochondrial content by assay of citrate synthase. Hepatocyte respiration could therefore be reported per mg of mitochondrial protein. By providing durohydroquinone to the cells, it was possible to measure electron flow from coenzyme Q to O2 in the absence of the physiological regulation of substrate supply. Likewise, the addition of carbonyl cyanide p-trifluoromethoxyphenylhydrazone released the in situ mitochondria from control by the cytosolic ATP/ADP ratio and it was possible to measure maximal electron flow rates through Complex III. In the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone, electron flow was higher in mitochondria in the cell than in isolated mitochondria. Glucagon caused no increase in mitochondrial respiration in situ either in the presence of the physiological substrates or in the presence of durohydroquinone. The data obtained do not support a role for the electron transport chain as a target of glucagon action in hepatocytes.     

Impact of diabetes-associated lipoproteins on oxygen consumption and mitochondrial enzymes in porcine aortic endothelial cells

Impairments in mitochondrial function have been proposed to play an important role in the pathogenesis of diabetes. Atherosclerotic coronary artery disease (CAD) is the leading cause of mortality in diabetic patients. Mitochondrial dysfunction and increased production of reactive oxygen species (ROS) are associated with diabetes and CAD. Elevated levels of glycated low density lipoproteins (glyLDL) and oxidized LDL (oxLDL) were detected in patients with diabetes. Our previous studies demonstrated that oxLDL and glyLDL increased the generation of ROS and altered the activities of antioxidant enzymes in vascular endothelial cells (EC). The present study examined the effects of glyLDL and oxLDL on mitochondrial respiration, membrane potential and the activities and proteins of key enzymes in mitochondrial electron transport chain (mETC) in cultured porcine aortic EC (PAEC). The results demonstrated that glyLDL or oxLDL significantly reduced oxygen consumption in Complex I, II/III and IV of mETC in PAEC compared to LDL or vehicle control using oxygraphy. Incubation with glyLDL or oxLDL significantly reduced mitochondrial membrane potential, the activities of mitochondrial ETC enzymes - NADH dehydrogenase (Complex I), succinate cytochrome c reductase (Complex II + III), ubiquinol cytochrome c reductase (Complex III), and cytochrome c oxidase (Complex IV) in PAEC compared to LDL or control. Treatment with oxLDL or glyLDL reduced the abundance of subunits of Complex I, ND1 and ND6 in PAEC. However, the effects of oxLDL on mitochondrial activity and proteins were not significantly different from glyLDL. The findings suggest that the glyLDL or oxLDL impairs mitochondrial respiration, as a result from the reduction of the abundance of several key enzymes in mitochondria of vascular EC, which potentially may lead to oxidative stress in vascular EC, and the development of diabetic vascular complications.     

Oxidative stress caused by blocking of mitochondrial complex I H(+) pumping as a link in aging/disease vicious cycle

Vulnerability of mitochondrial Complex I to oxidative stress determines an organism's lifespan, pace of aging, susceptibility to numerous diseases originating from oxidative stress and certain mitopathies. The mechanisms involved, however, are largely unknown. We used confocal microscopy and fluorescent probe MitoSOX to monitor superoxide production due to retarded forward electron transport in HEPG2 cell mitochondrial Complex I in situ. Matrix-released superoxide production, the un-dismuted surplus (J(m)) was low in glucose-cultivated cells, where an uncoupler (FCCP) reduced it to half. Rotenone caused a 5-fold J(m) increase (AC(50) 2 microM), which was attenuated by uncoupling, membrane potential (DeltaPsi(m)), and DeltapH-collapse, since addition of FCCP (IC(50) 55 nM), valinomycin, and nigericin prevented this increase. J(m) doubled after cultivation with galactose/glutamine (i.e. at obligatory oxidative phosphorylation). A hydrophobic amiloride that acts on the ND5 subunit and inhibits Complex I H(+) pumping enhanced J(m) and even countered the FCCP effect (AC(50) 0.3 microM). Consequently, we have revealed a new principle predicting that Complex I produces maximum superoxide only when both electron transport and H(+) pumping are retarded. H(+) pumping may be attenuated by high protonmotive force or inhibited by oxidative stress-related mutations of ND5 (ND2, ND4) subunit. We predict that in a vicious cycle, when oxidative stress leads to higher fraction of, e.g. mutated ND5 subunits, it will be accelerated more and more. Thus, inhibition of Complex I H(+) pumping, which leads to oxidative stress, appears to be a missing link in the theory of mitochondrial aging and in the etiology of diseases related to oxidative stress.     

Quantitative mapping of reversible mitochondrial Complex I cysteine oxidation in a Parkinson disease mouse model

Differential cysteine oxidation within mitochondrial Complex I has been quantified in an in vivo oxidative stress model of Parkinson disease. We developed a strategy that incorporates rapid and efficient immunoaffinity purification of Complex I followed by differential alkylation and quantitative detection using sensitive mass spectrometry techniques. This method allowed us to quantify the reversible cysteine oxidation status of 34 distinct cysteine residues out of a total 130 present in murine Complex I. Six Complex I cysteine residues were found to display an increase in oxidation relative to controls in brains from mice undergoing in vivo glutathione depletion. Three of these residues were found to reside within iron-sulfur clusters of Complex I, suggesting that their redox state may affect electron transport function.     

Complex III releases superoxide to both sides of the inner mitochondrial membrane

Mechanisms of mitochondrial superoxide formation remain poorly understood despite considerable medical interest in oxidative stress. Superoxide is produced from both Complexes I and III of the electron transport chain, and once in its anionic form it is too strongly charged to readily cross the inner mitochondrial membrane. Thus, superoxide production exhibits a distinct membrane sidedness or "topology." In the present work, using measurements of hydrogen peroxide (Amplex red) as well as superoxide (modified Cypridina luciferin analog and aconitase), we demonstrate that Complex I-dependent superoxide is exclusively released into the matrix and that no detectable levels escape from intact mitochondria. This finding fits well with the proposed site of electron leak at Complex I, namely the iron-sulfur clusters of the (matrix-protruding) hydrophilic arm. Our data on Complex III show direct extramitochondrial release of superoxide, but measurements of hydrogen peroxide production revealed that this could only account for approximately 50% of the total electron leak even in mitochondria lacking CuZn-superoxide dismutase. We posit that the remaining approximately 50% of the electron leak must be due to superoxide released to the matrix. Measurements of (mitochondrial matrix) aconitase inhibition, performed in the presence of exogenous superoxide dismutase and catalase, confirmed this hypothesis. Our data indicate that Complex III can release superoxide to both sides of the inner mitochondrial membrane. The locus of superoxide production in Complex III, the ubiquinol oxidation site, is situated immediately next to the intermembrane space. This explains extramitochondrial release of superoxide but raises the question of how superoxide could reach the matrix. We discuss two models explaining this result.