Overexpression of catalase in the mitochondrial or cytosolic compartment increases sensitivity of HepG2 cells to tumor necrosis factor-alpha-induced apoptosis

The sensitivity of HepG2 cells overexpressing catalase in either the cytosolic or mitochondrial compartment to tumor necrosis factor-alpha (TNF-alpha) and cycloheximide was studied. Cells overexpressing catalase in the cytosol (C33 cells) and especially in mitochondria (mC5 cells) were more sensitive to TNF-alpha-induced apoptosis than were control cells (Hp cells). The activities of caspase-3 and -8 were increased by TNF-alpha, with the highest activities found in mC5 cells. Sodium azide, an inhibitor of catalase, reduced the increased sensitivity of mC5 and C33 cells to TNF-alpha to the level of toxicity found with control Hp cells. Azide also decreased the elevated caspase-3 activity of mC5 cells. A pan-caspase inhibitor prevented the TNF-alpha-induced apoptosis and toxicity produced by catalase overexpression. Addition of H(2)O(2) prevented TNF-alpha-induced apoptosis and caspase activation, an effect prevented by simultaneous addition of catalase. TNF-alpha plus cycloheximide increased ATP levels, with higher levels in C33 and mC5 cells compared with Hp cells. TNF-alpha did not produce apoptosis in mC5 cells maintained in a low energy state. TNF-alpha signaling was not altered by the overexpression of catalase, as activation of nuclear factor kappaB and AP-1 by TNF-alpha was similar in the three cell lines. These results suggest that catalase, overexpressed in the cytosolic or especially the mitochondrial compartment, potentiates TNF-alpha-induced apoptosis and activation of caspases by removal of H(2)O(2).     

Adenovirus-mediated overexpression of catalase in the cytosolic or mitochondrial compartment protects against cytochrome P450 2E1-dependent toxicity in HepG2 cells

Cytochrome P450 2E1 (CYP2E1) is an effective producer of reactive oxygen species such as superoxide radical and hydrogen peroxide, which may contribute to the development of alcohol liver disease or cytotoxicity. To investigate the protective role of catalase against CYP2E1-dependent cytotoxicity, E47 cells, a transfected HepG2 cell line overexpressing CYP2E1, were infected with adenoviral vectors containing human catalase cDNA (AdCat) and catalase cDNA with a mitochondrial leader sequence (AdmCat). Forty-eight hours after infection with AdCat or AdmCat at a multiplicity of infection of 100, intracellular catalase protein was increased >2-fold compared with uninfected E47 cells and E47 cells infected with empty adenoviral vector (AdNull) as determined by Western blotting and catalase activity measurements. Overexpression of catalase in the cytosol (AdCat) and in mitochondria (AdmCat) was confirmed by confocal microscopy. Cell death caused by arachidonic acid plus iron was considerably suppressed in both AdCat- and AdmCat-infected E47 cells as determined by assays of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide absorbance, lactate dehydrogenase release, and morphology changes. AdCat- and AdmCat-infected cells were also more resistant to the loss of mitochondrial membrane potential and to the increase in lipid peroxidation induced by arachidonic acid and iron. This study indicates that catalase in the cytosol and catalase in mitochondria are capable of protecting HepG2 cells expressing CYP2E1 against cytotoxicity induced by oxidants that promote lipid peroxidation and suggests the possibility that such agents may be useful in protecting against the development of alcohol liver injury.     

Mitochondrial catalase and oxidative injury

Mitochondria dysfunction induced by reactive oxygen species (ROS) is related to many human diseases and aging. In physiological conditions, the mitochondrial respiratory chain is the major source of ROS. ROS could be reduced by intracellular antioxidant enzymes including superoxide dismutase, glutathione peroxidase and catalase as well as some antioxidant molecules like glutathione and vitamin E. However, in pathological conditions, these antioxidants are often unable to deal with the large amount of ROS produced. This inefficiency of antioxidants is even more serious in mitochondria, because mitochondria in most cells lack catalase. Therefore, the excessive production of hydrogen peroxide in mitochondria will damage lipid, proteins and mDNA, which can then cause cells to die of necrosis or apoptosis. In order to study the important role of mitochondrial catalase in protecting cells from oxidative injury, a HepG2 cell line overexpressing catalase in mitochondria was developed by stable transfection of a plasmid containing catalase cDNA linked with a mitochondria leader sequence which would encode a signal peptide to lead catalase into the mitochondria. Mitochondria catalase was shown to protect cells from oxidative injury induced by hydrogen peroxide and antimycin A. However, it increased the sensitivity of cells to tumor necrosis factor-alpha-induced apoptosis by changing the redox-oxidative status in the mitochondria. Therefore, the antioxidative effectiveness of catalase when expressed in the mitochondrial compartment is dependent upon the oxidant and the locus of ROS production.     

Bcl-2 family proteins regulate mitochondrial reactive oxygen production and protect against oxidative stress

Bcl-2 family proteins protect against a variety of forms of cell death, including acute oxidative stress. Previous studies have shown that overexpression of the antiapoptotic protein Bcl-2 increases cellular redox capacity. Here we report that cell lines transfected with Bcl-2 paradoxically exhibit increased rates of mitochondrial H(2)O(2) generation. Using isolated mitochondria, we determined that increased H(2)O(2) release results from the oxidation of reduced nicotinamide adenine dinucleotide-linked substrates. Antiapoptotic Bcl-2 family proteins Bcl-xL and Mcl-1 also increase mitochondrial H(2)O(2) release when overexpressed. Chronic exposure of cells to low levels of the mitochondrial uncoupler carbonyl cyanide 4-(triflouromethoxy)phenylhydrazone reduced the rate of H(2)O(2) production by Bcl-xL overexpressing cells, resulting in a decreased ability to remove exogenous H(2)O(2) and enhanced cell death under conditions of acute oxidative stress. Our results indicate that chronic and mild elevations in H(2)O(2) release from Bcl-2, Bcl-xL, and Mcl-1 overexpressing mitochondria lead to enhanced cellular antioxidant defense and protection against death caused by acute oxidative stress.     

Mitochondrial or cytosolic catalase reverses the MnSOD-dependent inhibition of proliferation by enhancing respiratory chain activity, net ATP production, and decreasing the steady state levels of H(2)O(2)

Manganese superoxide dismutase (MnSOD) overexpression has been shown to reverse the malignant phenotype in a variety of tumor cell lines. The inhibition of proliferation and reversal of the malignant phenotype has been attributed to an increase in H(2)O(2) production as a result of the dismutation reaction. However, direct evidence in support of this hypothesis has not been forthcoming. To evaluate the contribution of H(2)O(2) in the regulation of cell growth in response to MnSOD overexpression, control and MnSOD-overexpressing HT-1080 fibrosarcoma cells were transfected with constructs that direct catalase to either the mitochondrial or cytosolic compartments. Overexpression of catalase in either compartment reversed the proliferative and clonogenic inhibition associated with MnSOD overexpression, blocked the increase in the steady state levels of H(2)O(2) as measured by flow cytometric analysis of 2', 7'-dichlorofluorescein diacetate, and increased protection from the cytotoxicity of H(2)O(2). In addition, mitochondrial or cytosolic catalase enhances respiration through complex I and II in both control and MnSOD overexpressing cell lines and reverses a MnSOD-dependent decrease in net ATP production. Thus, catalase reverses the proliferative inhibition associated with MnSOD overexpression and may also play an important role in metabolic regulation.     

Mitochondrial oxidative burst involved in apoptotic response in oats

Apoptotic cell response in oats is induced by victorin, a host-selective toxin secreted by Cochliobolus victoriae and thought to exert toxicity by inhibiting mitochondrial glycine decarboxylase (GDC) in Pc-2/Vb oats. We examined the role of mitochondria, especially the organelle-derived production of reactive oxygen species (ROS), in the induction of apoptotic cell death. Cytofluorimetric analysis showed that victorin caused mitochondrial deltaPsim breakdown and mitochondrial oxidative burst. Ultrastructural analysis using a cytochemical assay based on the reaction of H2O2 with CeCl3 detected H2O2 eruption at permeability transition pore-like sites on the mitochondrial membrane in oat cells treated with victorin. ROS generation preceded the apoptotic cell responses seen in chromatin condensation and DNA laddering. Both aminoacetonitrile (a specific GDC inhibitor) and antimycin A (a mitochondrial complex III inhibitor) also induced mitochondrial H2O2 eruption, and led to the apoptotic response in oat cells. ROS scavengers such as N-acetyl-l-cysteine and catalase suppressed the mitochondrial oxidative burst and delayed chromatin condensation and DNA laddering in the victorin- or antimycin A-treated leaves. These findings indicate possible involvement of mitochondria, especially mitochondrial-derived ROS generation, as an important regulator in controlling apoptotic cell death in oats.     

Overexpression of CYP2E1 in mitochondria sensitizes HepG2 cells to the toxicity caused by depletion of glutathione

Induction of CYP2E1 by ethanol is one mechanism by which ethanol causes oxidative stress and alcohol liver disease. Although CYP2E1 is predominantly found in the endoplasmic reticulum, it is also located in rat hepatic mitochondria. In the current study, chronic alcohol consumption induced rat hepatic mitochondrial CYP2E1. To study the role of mitochondrial targeted CYP2E1 in generating oxidative stress and causing damage to mitochondria, HepG2 lines overexpressing CYP2E1 in mitochondria (mE10 and mE27 cells) were established by transfecting a plasmid containing human CYP2E1 cDNA lacking the hydrophobic endoplasmic reticulum targeting signal sequence into HepG2 cells followed by G418 selection. A 40-kDa catalytically active NH2-terminally truncated form of CYP2E1 (mtCYP2E1) was detected in the mitochondrial compartment in these cells by Western blot analysis. Cell death caused by depletion of GSH by buthionine sulfoximine (BSO) was increased in mE10 and mE27 cells as compared with cells transfected with empty vector (pCI-neo). Antioxidants were able to abolish the loss of cell viability. Increased levels of reactive oxygen species and mitochondrial 3-nitrotyrosine and 4-hydroxynonenal protein adducts and decreased mitochondrial aconitase activity and mitochondrial membrane potential were observed in mE10 and mE27 cells treated with BSO. The mitochondrial membrane stabilizer, cyclosporine A, was also able to protect these cells from BSO toxicity. These results revealed that CYP2E1 in the mitochondrial compartment could induce oxidative stress in the mitochondria, damage mitochondria membrane potential, and cause a loss of cell viability. The accumulation of CYP2E1 in hepatic mitochondria induced by ethanol consumption might play an important role in alcohol liver disease.     

Voltage-dependent anion channels control the release of the superoxide anion from mitochondria to cytosol

Several reactions in biological systems contribute to maintain the steady-state concentrations of superoxide anion (O(2)*-) and hydrogen peroxide (H(2)O(2)). The electron transfer chain of mitochondria is a well documented source of H(2)O(2); however, the release of O(2)*- from mitochondria into cytosol has not been unequivocally established. This study was aimed at validating mitochondria as sources of cytosolic O(2)*-, elucidating the mechanisms underlying the release of O(2)*- from mitochondria into cytosol, and assessing the role of outer membrane voltage-dependent anion channels (VDACs) in this process. Isolated rat heart mitochondria supplemented with complex I or II substrates generate an EPR signal ascribed to O(2)*-. Inhibition of the signal in a concentration-dependent manner by both manganese-superoxide dismutase and cytochrome c proteins that cannot cross the mitochondrial membrane supports the extramitochondrial location of the spin adduct. Basal rates of O(2)*- release from mitochondria were estimated at approximately 0.04 nmol/min/mg protein, a value increased approximately 8-fold by the complex III inhibitor, antimycin A. These estimates, obtained by quantitative spin-trapping EPR, were confirmed by fluorescence techniques, mainly hydroethidine oxidation and horseradish peroxidase-based p-hydroxyphylacetate dimerization. Inhibitors of VDAC, 4'-diisothiocyano-2,2'-disulfonic acid stilbene (DIDS), and dextran sulfate (in a voltage-dependent manner) inhibited O(2)*- production from mitochondria by approximately 55%, thus suggesting that a large portion of O(2)*- exited mitochondria via these channels. These findings are discussed in terms of competitive decay pathways for O(2)*- in the intermembrane space and cytosol as well as the implications of these processes for modulating cell signaling pathways in these compartments.     

Novel localization of OCTN1, an organic cation/carnitine transporter, to mammalian mitochondria

Carnitine is a zwitterion essential for the beta-oxidation of fatty acids. We report novel localization of the organic cation/carnitine transporter, OCTN1, to mitochondria. We made GFP- and RFP-human OCTN1 cDNA constructs and showed expression of hOCTN1 in several transfected mammalian cell lines. Immunostaining of GFP-hOCTN1 transfected cells with different intracellular markers and confocal fluorescent microscopy demonstrated mitochondrial expression of OCTN1. There was striking co-localization of an RFP-hOCTN1 fusion protein and a mitochondrial-GFP marker construct in transfected MEF-3T3 and no co-localization of GFP-hOCTN1 in transfected human skin fibroblasts with other intracellular markers. L-[(3)H]Carnitine uptake in freshly isolated mitochondria of GFP-hOCTN1 transfected HepG2 demonstrated a K(m) of 422 microM and Western blot with an anti-GFP antibody identified the expected GFP-hOCTN1 fusion protein (90 kDa). We showed endogenous expression of native OCTN1 in HepG2 mitochondria with anti-GST-hOCTN1 antibody. Further, we definitively confirmed intact L-[(3)H]carnitine uptake (K(m) 1324 microM), solely attributable to OCTN1, in isolated mitochondria of mutant human skin fibroblasts having <1% of carnitine acylcarnitine translocase activity (alternate mitochondrial carnitine transporter). This mitochondrial localization was confirmed by TEM of murine heart incubated with highly specific rabbit anti-GST-hOCTN1 antibody and immunogold labeled goat anti-rabbit antibody. This suggests an important yet different role for OCTN1 from other OCTN family members in intracellular carnitine homeostasis.     

Toxicity by pyruvate in HepG2 cells depleted of glutathione: role of mitochondria.

Several studies have shown that pyruvate can scavenge H(2)O(2) and protect from H(2)O(2)-mediated cell injury. Mitochondria are critical participants in the control of apoptotic and necrotic cell death. Mitochondrial GSH plays an important role in the maintenance of cell functions and viability by metabolism of oxygen free radicals generated by the respiratory chain. Since loss of GSH, especially mitochondrial GSH, is associated with increased production of reactive oxygen species and cell toxicity, the ability of pyruvate to protect against these actions was evaluated. Adding pyruvate to HepG2 cells depleted of GSH by treatment with l-buthionine sulfoximine (BSO) surprisingly caused loss of viability after 24 and 48 h of incubation. Anoxia, treatment with antioxidants, and infection with cytosolic catalase, and interestingly, catalase expressed in the mitochondrial compartment were able to rescue the HepG2 cells from this pyruvate plus BSO injury, suggesting a key role for H(2)O(2), and lipid peroxides as mediators in the cytotoxicity. This toxicity and cell death observed was linked to damage to the mitochondria as evidenced by the increased lipid peroxidation in total homogenate and mitochondrial fraction, loss of mitochondrial membrane potential, and a decrease in protein-sulfhydryl groups. The type of cell death observed under these conditions was a mixture of apoptosis and necrosis. These results suggest that the protective ability of pyruvate against oxidant damage requires a functional GSH pool, especially in the mitochondrial compartment, and that in the absence of GSH, pyruvate increases cell injury by damaging the mitochondria, presumably as a consequence of enhanced electron flow and reactive oxygen production by the respiratory chain.     

Expression of human catalase in acatalasemic murine SV-B2 cells confers protection from oxidative damage

Reactive oxygen species have been implicated in aerobic organisms as causative agents in damage to DNA, proteins, and lipids. Catalase is a major enzyme in the defense against such oxidant damage. To determine whether increased catalase expression confers greater resistance to oxidant stress, a eukaryotic expression vector harboring a human catalase cDNA clone was constructed. Acatalasemic murine fibroblasts were then co-transfected with the catalase expression vector and pSV2-neo, and successfully transfected cells were identified by their ability to grow in the presence of geneticin. Clones that contained integrated copies of the catalase expression vector were identified by Polymerase Chain Reaction (PCR) analysis. Stably transfected geneticin-resistant cell lines that overexpressed catalase in potentially positive cell lines were confirmed by catalase enzyme assays. To examine the physiological relevance of catalase overexpression, cells were exposed to oxidant stresses (hydrogen peroxide and hyperoxia), and survival rates were determined. Results demonstrated a significant resistance to oxidative stress in cells overexpressing catalase when compared to controls. These transfected cell lines will provide important models for further evaluation of the role of catalase in protecting cells against the toxic effects of oxygen-derived free radicals and their derivatives.     

Myxothiazol induces H(2)O(2) production from mitochondrial respiratory chain

Interruption of electron flow at the quinone-reducing center (Q(i)) of complex III of the mitochondrial respiratory chain results in superoxide production. Unstable semiquinone bound in quinol-oxidizing center (Q(o)) of complex III is thought to be the sole source of electrons for oxygen reduction; however, the unambiguous evidence is lacking. We investigated the effects of complex III inhibitors antimycin, myxothiazol, and stigmatellin on generation of H(2)O(2) in rat heart and brain mitochondria. In the absence of antimycin A, myxothiazol stimulated H(2)O(2) production by mitochondria oxidizing malate, succinate, or alpha-glycerophosphate. Stigmatellin inhibited H(2)O(2) production induced by myxothiazol. Myxothiazol-induced H(2)O(2) production was dependent on the succinate/fumarate ratio but in a manner different from H(2)O(2) generation induced by antimycin A. We conclude that myxothiazol-induced H(2)O(2) originates from a site located in the complex III Q(o) center but different from the site of H(2)O(2) production inducible by antimycin A.     

Mitochondrial localization of catalase provides optimal protection from H2O2-induced cell death in lung epithelial cells

Reactive oxygen species (ROS) can cause cell injury and death via mitochondrial-dependent pathways, and supplementation with antioxidants has been shown to ameliorate these processes. The c-Jun NH(2)-terminal kinase (JNK) pathway has been shown to play a critical role in ROS-induced cell death. To determine if targeting catalase (CAT) to the mitochondria provides better protection than cytosolic expression against H(2)O(2)-induced injury, the following two approaches were taken: 1) adenoviral-mediated transduction was performed using cytosolic (CCAT) or mitochondrial (MCAT) CAT cDNAs and 2) stable cell lines were generated overexpressing CAT in mitochondria (n = 3). Cells were exposed to 250 microM H(2)O(2), and cell survival, mitochondrial function, cytochrome c release, and JNK activity were analyzed. Although all viral transduced cells had a transient twofold increase in CAT activity, MCAT cells had significantly higher survival rates, the best mitochondrial function, and lowest JNK activity compared with CCAT and LacZ controls. The improved protection with MCAT was observed in primary type II lung epithelial cells and in transformed lung epithelial cells. In the three stable cell lines, cell survival directly correlated with extent of mitochondrial localization (r = 0.60572, P < 0.05) and not overall CAT activity (r = -0.45501, P < 0.05). Data indicate that targeting of antioxidants directly to the mitochondria is more effective in protecting lung epithelial cells against ROS-induced injury. This has important implications in antioxidant supplementation trials to prevent ROS-induced lung injury in critically ill patients.     

Mitochondrial O2*- and H2O2 mediate glucose deprivation-induced stress in human cancer cells

The hypothesis that glucose deprivation-induced cytotoxicity in transformed human cells is mediated by mitochondrial O2*- and H2O2 was first tested by exposing glucose-deprived SV40-transformed human fibroblasts (GM00637G) to electron transport chain blockers (ETCBs) known to increase mitochondrial O2*- and H2O2 production (antimycin A (AntA), myxothiazol (Myx), or rotenone (Rot)). Glucose deprivation (2-8 h) in the presence of ETCBs enhanced parameters indicative of oxidative stress (i.e. GSSG and steady-state levels of oxygen-centered radicals) as well as cytotoxicity. Glucose deprivation in the presence of AntA also significantly enhanced cytotoxicity and parameters indicative of oxidative stress in several different human cancer cell lines (PC-3, DU145, MDA-MB231, and HT-29). In addition, human osteosarcoma cells lacking functional mitochondrial electron transport chains (rho0) were resistant to glucose deprivation-induced cytotoxicity and oxidative stress in the presence of AntA. In the absence of ETCBs, aminotriazole-mediated inactivation of catalase in PC-3 cells demonstrated increases in intracellular steady-state levels of H2O2 during glucose deprivation. Finally, in the absence of ETCBs, overexpression of manganese containing superoxide dismutase and/or mitochondrial targeted catalase using adenoviral vectors significantly protected PC-3 cells from toxicity and oxidative stress induced by glucose deprivation with expression of both enzymes providing greater protection than was seen with either alone. Overall, these findings strongly support the hypothesis that mitochondrial O2*- and H2O2 significantly contribute to glucose deprivation-induced cytotoxicity and metabolic oxidative stress in human cancer cells.     

Spatiotemporal autophagic degradation of oxidatively damaged organelles after photodynamic stress is amplified by mitochondrial reactive oxygen species

Although reactive oxygen species (ROS) have been reported to evoke different autophagic pathways, how ROS or their secondary products modulate the selective clearance of oxidatively damaged organelles is less explored. To investigate the signaling role of ROS and the impact of their compartmentalization in autophagy pathways, we used murine fibrosarcoma L929 cells overexpressing different antioxidant enzymes targeted to the cytosol or mitochondria and subjected them to photodynamic (PD) stress with the endoplasmic reticulum (ER)-associated photosensitizer hypericin. We show that following apical ROS-mediated damage to the ER, predominantly cells overexpressing mitochondria-associated glutathione peroxidase 4 (GPX4) and manganese superoxide dismutase (SOD2) displayed attenuated kinetics of autophagosome formation and overall cell death, as detected by computerized time-lapse microscopy. Consistent with a primary ER photodamage, kinetics and colocalization studies revealed that photogenerated ROS induced an initial reticulophagy, followed by morphological changes in the mitochondrial network that preceded clearance of mitochondria by mitophagy. Overexpression of cytosolic and mitochondria-associated GPX4 retained the tubular mitochondrial network in response to PD stress and concomitantly blocked the progression toward mitophagy. Preventing the formation of phospholipid hydroperoxides and H 2O 2 in the cytosol as well as in the mitochondria significantly reduced cardiolipin peroxidation and apoptosis. All together, these results show that in response to apical ER photodamage ROS propagate to mitochondria, which in turn amplify ROS production, thereby contributing to two antagonizing processes, mitophagy and apoptosis.     

Critical role of mitochondrial glutathione in the survival of hepatocytes during hypoxia

Hypoxia is known to stimulate reactive oxygen species (ROS) generation. Because reduced glutathione (GSH) is compartmentalized in cytosol and mitochondria, we examined the specific role of mitochondrial GSH (mGSH) in the survival of hepatocytes during hypoxia (5% O2). 5% O2 stimulated ROS in HepG2 cells and cultured rat hepatocytes. Mitochondrial complex I and II inhibitors prevented this effect, whereas inhibition of nitric oxide synthesis with Nomega-nitro-L-arginine methyl ester hydrochloride or the peroxynitrite scavenger uric acid did not. Depletion of GSH stores in both cytosol and mitochondria enhanced the susceptibility of HepG2 cells or primary rat hepatocytes to 5% O2 exposure. However, this sensitization was abrogated by preventing mitochondrial ROS generation by complex I and II inhibition. Moreover, selective mGSH depletion by (R,S)-3-hydroxy-4-pentenoate that spared cytosol GSH levels sensitized rat hepatocytes to hypoxia because of enhanced ROS generation. GSH restoration by GSH ethyl ester or by blocking mitochondrial electron flow at complex I and II rescued (R,S)-3-hydroxy-4-pentenoate-treated hepatocytes to hypoxia-induced cell death. Thus, mGSH controls the survival of hepatocytes during hypoxia through the regulation of mitochondrial generation of oxidative stress.     

Bcl-2 prevents loss of mitochondria in CCCP-induced apoptosis

Bcl-2 family proteins regulate apoptosis at the level of mitochondria. To examine the mechanism of Bcl-2 function, we investigated the effects of the protonophore carbonyl cyanide m-chlorophenyl hydrazone (CCCP) on two hematopoietic cell lines and Bcl-2 overexpressing transfectants. CCCP directly interferes with mitochondrial function and induces apoptosis. We show that Bcl-2 inhibits apoptosis and that the antiapoptotic effect of Bcl-2 takes place upstream of caspase activation and nuclear changes associated with apoptosis, since these were markedly inhibited in cells overexpressing Bcl-2. Bcl-2 does not prevent the decrease in mitochondrial membrane potential nor the alterations in cellular ATP content induced by CCCP in FL5.12 and Jurkat cells. A higher number of mitochondria was observed in untreated Bcl-2 transfected cells compared to parental cells, as shown by electron microscopy. Exposure to CCCP induced a dramatic decrease in the number of mitochondria and severely disrupted mitochondrial ultrastructure, with apparent swelling and loss of cristae in parental cells. Bcl-2 clearly diminished the disruption of mitochondrial structure and preserved a higher number of mitochondria. These data suggest that CCCP induces apoptosis by structural disruption of mitochondria and that Bcl-2 prevents apoptosis and mitochondrial degeneration by preserving mitochondrial integrity.     

Effect of training on H(2)O(2) release by mitochondria from rat skeletal muscle

In this study, oxygen consumption and H(2)O(2) release rate by succinate or pyruvate/malate supplemented mitochondria isolated from skeletal muscle of trained and untrained rats were investigated. The overall mitochondrial antioxidant capacity and the effect of preincubation of mitochondria with GDP, an inhibitor of uncoupling proteins UCP1 and UCP2, on both succinate-supported H(2)O(2) release and membrane potential were also determined. The results indicate that training does not affect mitochondrial oxygen consumption with both complex-I- and complex II-linked substrates. Succinate-supported H(2)O(2) release was lower in trained than in untrained rats both in State 4 and State 3. Even the antimycin A-stimulated release was lower in trained rats. When pyruvate/malate were used as substrates, H(2)O(2) release rate was lower in trained rats only in the presence of antimycin A. The increase of mitochondrial protein content (determined by the ratio between cytochrome oxidase activities in homogenates and mitochondria) in trained muscle was such that the succinate-supported H(2)O(2) release per g of tissue was not significantly different in trained and untrained rats, while that supported by pyruvate/malate was higher in trained than in untrained animals. The lack of training-induced changes in overall antioxidant capacity of mitochondria indicates that the decrease in mitochondrial H(2)O(2) release cannot be attributed to a greater capacity of mitochondria to scavenge the reactive oxygen intermediates derived from univalent O(2) reduction by respiratory chain components. In contrast, the above decrease seems to depend on the drop induced by training in mitochondrial membrane potential. These training effects are not due to an increased level of mitochondrial uncoupling protein, because in the presence of GDP the increase in both membrane potential and H(2)O(2) release was greater in untrained than in trained rats.     

The impact of oxidative stress on Arabidopsis mitochondria

Treatment of Arabidopsis cell culture for 16 h with H2O2, menadione or antimycin A induced an oxidative stress decreasing growth rate and increasing DCF fluorescence and lipid peroxidation products. Treated cells remained viable and maintained significant respiratory rates. Mitochondrial integrity was maintained, but accumulation of alternative oxidase and decreased abundance of lipoic acid-containing components during several of the treatments indicated oxidative stress. Analysis of the treatments was undertaken by IEF/SDS-PAGE, comparison of protein spot abundances and tandem mass spectrometry. A set of 25 protein spots increased >3-fold in H2O2/menadione treatments, a subset of these increased in antimycin A-treated samples. A set of 10 protein spots decreased significantly during stress treatments. A specific set of mitochondrial proteins were degraded by stress treatments. These damaged components included subunits of ATP synthase, complex I, succinyl CoA ligase, aconitase, and pyruvate and 2-oxoglutarate dehydrogenase complexes. Nine increased proteins represented products of different genes not found in control mitochondria. One is directly involved in antioxidant defense, a mitochondrial thioredoxin-dependent peroxidase, while another, a thioredoxin reductase-dependent protein disulphide isomerase, is required for protein disulfide redox homeostasis. Several others are generally considered to be extramitochondrial but are clearly present in a highly purified mitochondrial fraction used in this study and are known to play roles in stress response. Using H2O2 as a model stress, further work revealed that this treatment induced a protease activity in isolated mitochondria, putatively responsible for the degradation of oxidatively damaged mitochondrial proteins and that O2 consumption by mitochondria was significantly decreased by H2O2 treatment.     

Formation of hydrogen peroxide in the mitochondria of skeletal muscles

The generation of H2O2 in skeletal muscle mitochondria during the oxidation of NAD-dependent substrates and succinate is initiated by antimycin A but not by rotenone, which points to H2O2 formation at the respiratory chain site between the rotenone and antimycin blocks. The O2-/H2O2 ratio for alpha-ketoglutarate and succinate oxidation is approximately 1.4, which suggests that in skeletal muscle mitochondria H2O2 is predominantly formed via the superoxide radical generation. Heart and skeletal muscle mitochondria appeared to have the similar values of Vmax for H2O2 production; the catalase activity in skeletal muscle mitochondria is much lower.