Plasma membrane redox system protects cells against oxidative stress

Abstract

Aerobic organisms have developed defensive systems to survive in the presence of oxygen and its highly reactive species (ROS). The cellular mechanisms of protection against oxidative injury include: (i) specific enzymes, such as catalase, glutathione peroxidase and superoxide dismutase; (ii) small hydrophilic molecules, such as ascorbate, glutathione and uric acid; and (iii) hydrophobic agents, such as ubiquinone and α-tocopherol in membranes.¹ Among these, coenzyme Q (CoQ) is the only lipid-soluble antioxidant that can be synthesized in all organisms so far studied.     

Permeability of inner mitochondrial membrane and oxidative stress

The mechanism of increase in the inner membrane permeability induced by Ca2+ plus Pi, diamide and hydroperoxides has been analyzed. (1) The permeability increase is antagonized by oligomycin and favoured by atractyloside. The promoting effect of atractyloside is strongly reduced if the mitochondria are simultaneously treated with oligomycin. (2) Addition of the free-radical scavenger, butylhydroxytoluene, results in a complete protection of the membrane with respect to the permeability increase. (3) Although membrane damage and depression of the GSH concentration are often associated, there is no direct correlation between extent of membrane damage and concentration of reduced glutathione. Abolition of the permeability increase by butylhydroxytoluene or by oligomycin is not accompanied by maintenance of a high GSH concentration in the presence of diamide or hydroperoxides. The membrane damage induced by Ca2+ plus Pi is not accompanied by a depression of the GSH concentration. (4) It is proposed that a variety of processes causing an increased permeability of the inner mitochondrial membrane merge into some ultimate common steps involving the action of oxygen radicals.     

DAPK2 regulates oxidative stress in cancer cells by preserving mitochondrial function

Death-associated protein kinase (DAPK) 2 is a serine/threonine kinase that belongs to the DAPK family. Although it shows significant structural differences from DAPK1, the founding member of this protein family, DAPK2 is also thought to be a putative tumour suppressor. Like DAPK1, it has been implicated in programmed cell death, the regulation of autophagy and diverse developmental processes. In contrast to DAPK1, however, few mechanistic studies have been carried out on DAPK2 and the majority of these have made use of tagged DAPK2, which almost invariably leads to overexpression of the protein. As a consequence, physiological roles of this kinase are still poorly understood. Using two genetically distinct cancer cell lines as models, we have identified a new role for DAPK2 in the regulation of mitochondrial integrity. RNA interference-mediated depletion of DAPK2 leads to fundamental metabolic changes, including significantly decreased rate of oxidative phosphorylation in combination with overall destabilised mitochondrial membrane potential. This phenotype is further corroborated by an increase in the production of mitochondrial superoxide anions and increased oxidative stress. This then leads to the activation of classical stress-activated kinases such as ERK, JNK and p38, which is observed on DAPK2 genetic ablation. Interestingly, the generation of oxidative stress is further enhanced on overexpression of a kinase-dead DAPK2 mutant indicating that it is the kinase domain of DAPK2 that is important to maintain mitochondrial integrity and, by inference, for cellular metabolism.Death-associated protein kinase (DAPK) 2 shares a high level of homology within its kinase domain with the other two DAPK family members, DAPK1 (DAPk) and DAPK3 (ZIPK/DLK). Since the identification of DAPK1 by Kimchi and co-workers¹ numerous studies have shown that DAPK1 functions as a tumour suppressor, is linked to key events in autophagy and is involved in mitochondrial maintenance² and metabolism.³ DAPK2, which was characterised in 1999,⁴ is significantly smaller than DAPK1, and it lacks ankyrin repeats, the cytoskeletal binding domain and the death domain, all of which are part of DAPK1''s unique structure.¹ Several functions have been ascribed to DAPK2 and they often coincide with those of DAPK1. Like DAPK1, DAPK2 is also involved in the formation of autophagic vesicles,^{5, 6} modulation of receptor induced cell death^{7, 8, 9} and several modes of intrinsic apoptotic cell death.⁶ While epigenetic silencing of DAPK1 has been reported in many different human cancers,^{10, 11} DAPK2 appears to be silenced mainly in haematological disorders,¹² although it has been shown to modulate TRAIL-induced apoptosis in several cancer cell lines of non-haematological origin.⁹ Most approaches used for studying the role of DAPK2 used tagged DAPK2 and it is, therefore, still unclear whether these functions are also carried out by the native protein, expressed at much lower, endogenous, levels.DAPK1 has been shown to regulate mitochondrial integrity and to modulate the mitochondrial membrane potential² but, to the best of our knowledge, no work has been carried out in this respect with regard to DAPK2. Since DAPK1 and DAPK2 appear to share many functions and both are thought to reside, at least partially, in the mitochondria, we hypothesised that DAPK2 depletion regulated mitochondrial metabolism. Mitochondrial dysfunction is characterised by the induction of reactive oxygen species (ROS) in the cell.¹³ Ultimately, dysfunctional mitochondria can no longer be powerhouses of use to the cell and are, therefore, targeted for degradation. Alternatively, their membranes can depolarise leading to the release of cytochrome c, an early apoptotic process.¹⁴ Using two distinct cancer cell types, namely U2OS osteosarcoma and A549 non-small cell lung cancer cells,^{9, 15} we show that DAPK2 depletion increases the levels of intracellular ROS, leads to mitochondrial depolarisation and impairs mitochondrial metabolism. DAPK2 thus exerts metabolic and mitochondria-regulating functions, which have not been described to date and that can explain why it is downregulated in haematological malignancies,^{12, 16, 17} and involved in modulating death-inducing signalling in solid tumours.⁹     

Raloxifene attenuates oxidative stress and preserves mitochondrial function in astrocytic cells upon glucose deprivation

Oxidative stress and mitochondrial dysfunction induced by metabolic insults are both hallmarks of various neurological disorders, whereby neuronal cells are severely affected by decreased glucose supply to the brain. Likely injured, astrocytes are important for neuronal homeostasis and therapeutic strategies should be directed towards improving astrocytic functions to improve brain's outcome. In the present study, we aimed to assess the actions of raloxifene, a selective estrogen receptor modulator in astrocytic cells under glucose deprivation. Our findings indicated that pretreatment with 1 µM raloxifene results in an increase in cell viability and attenuated nuclei fragmentation. Raloxifene's actions also rely on the reduction of oxidative stress and preservation of mitochondrial function in glucose-deprived astrocytic cells, suggesting the possible direct effects of this compound on mitochondria. In conclusion, our results demonstrate that raloxifene's protective actions might be mediated in part by astrocytes in the setting of a metabolic insult.     

Comparative studies of oxidative stress and mitochondrial function in aging

The oxidative stress theory and its correlate the mitochondrial theory of aging are among the most studied and widely accepted of all hypotheses of the mechanism of aging. To date, most of the supporting evidence for these theories has come from investigations using common model organisms such as Caenorhabditis elegans, Drosophila melanogaster, and laboratory rodents. However, comparative data from a wide range of endotherms provide equivocal support as to whether oxidative stress is merely a correlate, rather than a determinant, of species' maximum lifespan. The great majority of studies in this area have been devoted to the relationship between reactive oxygen species and maximal longevity in young adult organisms, with little emphasis on mitochondrial respiratory efficiency, age-related alterations in mitochondrial physiology or oxidative damage. The advantage of studying a broader spectrum of species is the broad range of virtually every biological phenotype/trait, such as lifespan, body weight and metabolic rate. Here we summarize the results from a number of comparative studies in an effort to correlate oxidant production and oxidative damage among many species with their maximal lifespan and briefly discuss the pitfalls and limitations. Based on current information, it is not possible to accept or dispute the oxidative stress theory of aging, nor can we exclude the possibility that private mechanisms might offer an explanation for the longevity of exceptionally long-lived animal models. Thus, there is need for more thorough and controlled investigations with more unconventional animal models for a deeper understanding of the role of oxidative stress in longevity.     

Oxidative stress, mitochondrial function, and acute glutamate excitotoxicity in cultured cerebellar granule cells

On exposure to glutamate, cultured rat cerebellar granule cells undergo a delayed Ca2+ deregulation (DCD), which precedes and predicts cell death. We have previously shown that mitochondria control the sensitivity of the neurons to DCD. Mitochondrial depolarization by rotenone/oligomycin before glutamate addition is strongly neuroprotective, and the indication is therefore that mitochondrial Ca2+ loading leads to a delayed loss of bioenergetic function culminating in DCD and cell death. In this report it is shown that superoxide (O2.-) generation in intact cells, monitored by oxidation of hydroethidine to ethidium, was enhanced by glutamate only when mitochondria were polarized. Production of superoxide was higher in the subset of cells undergoing DCD. In the presence of rotenone and oligomycin, addition of glutamate did not result in increased superoxide generation. Menadione-generated superoxide enhances the DCD of cells exposed to glutamate; in contrast, glutamate-induced DCD was potently inhibited by the presence of the cell-permeant antioxidant manganese(III) tetrakis(4-benzoic acid) porphyrin. An inverse correlation is observed between the cytoplasmic free Ca2+ maintained in individual cells in the presence of glutamate and the ability of these cells to restore basal Ca2+ when NMDA receptors are inhibited and mitochondrial Ca2+ is released. It is concluded that mitochondrial Ca2+ accumulation and reactive oxygen species each contribute to DCD, probably related to damage to a process controlling Ca2+ efflux from the cell.     

Sex-dependent differences in aged rat brain mitochondrial function and oxidative stress

Females show lower incidences of several neurodegenerative diseases related to oxidative stress and mitochondrial dysfunction than males. In addition, female rats show more differentiated mitochondria than males in several tissues. The aim of this work was to investigate the existence of sex-dependent differences in brain mitochondrial bioenergetics and oxidative balance in aged rats. Results showed that aged female rat brain had a lower mitochondria content than aged male brain but with a greater differentiation degree given the higher mitochondrial protein content and mitochondrial complex activities in females. Female rat brain also showed a better oxidative balance than that of males, reflected by the fact that higher mitochondrial respiratory chain function is accompanied by a similar ROS production and greater antioxidant enzyme activities, which could be responsible for the lesser oxidative damage observed in proteins and lipids in this sex. Interestingly, levels of UCP4 and UCP5--proteins related to a decrease in ROS production--were also higher in females. In conclusion, aged female rat brain had more differentiated mitochondria than male brain and showed a better control of oxidative stress balance, which could be due, in part, to the neuroprotective effect of UCPs.     

Relationship between oxidative stress and mitochondrial function in the post-conditioned heart

The pathways activated by post-conditioning may converge on the mitochondria, in particular on the mitochondrial permeability transition pore. We sought to characterize the inhibition status of the mitochondrial permeability transition early after the post-conditioning maneuver and before long reperfusion was established. We observed that post-conditioning maneuvers applied to isolated rat hearts, after a prolonged ischemia and before reperfusion, promoted cardiac mechanical function recovery and maintained mitochondrial integrity. These effects were evaluated by mitochondrial swelling, calcium transport, and NAD⁺ content measurements; the improvements were established before restoring a long lasting reperfusion period. Mitochondrial integrity was associated with a diminution in oxidative stress, since carbonylation of proteins was prevented and aconitase activity was preserved in the post-conditioned hearts, implying that ROS might mediate mitochondrial dysfunction and mPTP opening. In addition, we found that cytochrome release was significantly abolished in the post-conditioned heart, in contrast with conventionally reperfused hearts.     

Plasma membrane RNase activity in mammalian cells

Plasma membranes isolated from eight different tissues from either man, rat, mouse or rabbit and from tissue culture were shown to inhibit protein synthesis in a cell-free system. From all membranal extracts an RNase endonuclease activity could be isolated which split rRNΔ. In contrast, the polyribosomal structure of rabbit reticulocytes was unaffected, showing that 9S mRNA was not destroyed under these conditions. The Triton X-100 membranal extracts blocked protein synthesis in the elongation stage and all resembled very closely the previously described RNase M activity [2]. A hypothesis is put forward, suggesting that newly formed ribosomes migrate in the cytoplasm while accomplishing protein synthesis. After being engaged in a series of such rounds of protein synthesis they meet with the plasma membrane and are inactivated by the RNase endonucleolytic splitting of their ribosomal RNA (rRNA). It is suggested that this is a mechanism common to all eukaryotic cells.     

Role of oxidative stress in the ammonia-induced mitochondrial permeability transition in cultured astrocytes

Ammonia is a neurotoxin that has been strongly implicated in the pathogenesis of hepatic encephalopathy (HE) and other neurological disorders, and astrocytes are thought to be the principal target of ammonia toxicity. While the precise mechanisms of ammonia neurotoxicity remain to be more clearly defined, altered bioenergetics and oxidative stress appear to be critical factors in its pathogenesis. It has recently been demonstrated that pathophysiological concentrations of ammonia induce the mitochondrial permeability transition (MPT) in cultured astrocytes, a process associated with mitochondrial dysfunction, and frequently caused by oxidative stress. This study investigated the potential role of oxidative stress in the induction of the MPT by ammonia. Accordingly, the effect of various antioxidants on the induction of the MPT by ammonia in cultured astrocytes was examined. Astrocytes were subjected to NH4Cl (5 mM) treatment for 2 days with or without various antioxidants. The MPT was assessed by quantitative fluorescence imaging for the mitochondrial membrane potential (DeltaPsim), employing the potentiometric dye TMRE; by changes in mitochondrial calcein fluorescence and by 2-deoxyglucose-6-phosphate (2-DG-6-P) changes in mitochondrial permeability. Astrocytes treated with ammonia significantly dissipated the DeltaPsim, which was blocked by the MPT inhibitor, cyclosporin A, caused a decrease in mitochondrial calcein fluorescence and increased 2-DG-6-P permeability into mitochondria. All of these findings are consistent with induction of the MPT. Pretreatment with SOD, catalase, desferroxamine, Vitamin E, PBN and the nitric oxide synthase inhibitor, N(G)-nitro-L-arginine methyl ester (L-NAME), completely blocked the ammonia-induced MPT. These data provide strong evidence that oxidative stress is involved in the induction of the MPT by ammonia, and suggest that oxidative stress and the subsequent induction of the MPT contribute to the pathogenesis of HE and other hyperammonemic disorders.     

DJ-1 regulation of mitochondrial function and autophagy through oxidative stress

The dysregulation of mitochondrial function has been implicated in the pathogenesis of Parkinson disease.

Mutations in the parkin, PINK1 and DJ-1 genes all result in recessive parkinsonism. Although the protein products of these genes have not been fully characterized, it has been established that all three contribute to the maintenance of mitochondrial function. PINK1 and parkin act in a common pathway to regulate the selective autophagic removal of depolarized mitochondria, but the relationship between DJ-1 and PINK1- and/or parkin-mediated effects on mitochondria and autophagy is less clear. We have shown that loss of DJ-1 leads to mitochondrial phenotypes including reduced membrane potential, increased fragmentation and accumulation of autophagic markers. Supplementing DJ-1-deficient cells with glutathione reverses both mitochondrial and autophagic changes suggesting that DJ-1 may act to maintain mitochondrial function during oxidative stress and thereby alter mitochondrial dynamics and autophagy indirectly.     

DJ-1 regulation of mitochondrial function and autophagy through oxidative stress

The dysregulation of mitochondrial function has been implicated in the pathogenesis of Parkinson disease. Mutations in the parkin, PINK1 and DJ-1 genes all result in recessive parkinsonism. Although the protein products of these genes have not been fully characterized, it has been established that all three contribute to the maintenance of mitochondrial function. PINK1 and parkin act in a common pathway to regulate the selective autophagic removal of depolarized mitochondria, but the relationship between DJ-1 and PINK1- and/or parkin-mediated effects on mitochondria and autophagy is less clear. We have shown that loss of DJ-1 leads to mitochondrial phenotypes including reduced membrane potential, increased fragmentation and accumulation of autophagic markers. Supplementing DJ-1-deficient cells with glutathione reverses both mitochondrial and autophagic changes suggesting that DJ-1 may act to maintain mitochondrial function during oxidative stress and thereby alter mitochondrial dynamics and autophagy indirectly.     

Enterocyte mitochondrial dysfunction due to oxidative stress

The endogenous production of H2O2 in isolated rat intestinal mitochondria and oxidant induced damage to mitochondria were examined. There was an appreciable amount of H2O2 production in presence of succinate, glutamate and pyruvate, while the presence of rotenone with succinate further increased production. Superoxide generated by the X-XO system induced membrane permeability transition (MPT), calcium influx, lipid peroxidation and changes in membrane fluidity in mitochondria. A decreased mitochondrial ATPase activity and uncoupling of respiration was also observed. Spermine inhibited swelling induced by X-XO and also blocked the calcium influx and reversed the membrane fluidity changes.     

Plasma membrane Ca-ATPases: Targets of oxidative stress in brain aging and neurodegeneration

The plasma membrane Ca(2+)-ATPase (PMCA) pumps play an important role in the maintenance of precise levels of intracellular Ca(2+) [Ca(2+)](i), essential to the functioning of neurons. In this article, we review evidence showing age-related changes of the PMCAs in synaptic plasma membranes (SPMs). PMCA activity and protein levels in SPMs diminish progressively with increasing age. The PMCAs are very sensitive to oxidative stress and undergo functional and structural changes when exposed to oxidants of physiological relevance. The major signatures of oxidative modification in the PMCAs are rapid inactivation, conformational changes, aggregation, internalization from the plasma membrane and proteolytic degradation. PMCA proteolysis appears to be mediated by both calpains and caspases. The predominance of one proteolytic pathway vs the other, the ensuing pattern of PMCA degradation and its consequence on pump activity depends largely on the type of insult, its intensity and duration. Experimental reduction of PMCA expression not only alters the dynamics of cellular Ca(2+) handling but also has a myriad of downstream consequences on various aspects of cell function, indicating a broad role of these pumps. Age- and oxidation-related down-regulation of the PMCAs may play an important role in compromised neuronal function in the aging brain and its several-fold increased susceptibility to neurodegenerative disorders such as Alzheimer's disease, Parkinson's disease, and stroke. Therapeutic approaches that protect the PMCAs and stabilize [Ca(2+)](i) homeostasis may be capable of slowing and/or preventing neuronal degeneration. The PMCAs are therefore emerging as a new class of drug targets for therapeutic interventions in various chronic degenerative disorders.     

Enhancement of oxidative damage to cultured cells and Caenorhabditis elegans by mitochondrial electron transport inhibitors

The mechanisms that lead to mitochondrial damage under oxidative stress conditions were examined in primary and cultured cells as well as in the nematode Caenorhabditis elegans (C. elegans) treated simultaneously with electron transport inhibitors and oxygen gas. Oxygen loading enhanced the damage of PC 12 cells by thenoyltrifluoroacetone (TTFA, a complex II inhibitor), but did not by rotenone (a complex I inhibitor), antimycin (a complex III inhibitor), and sodium azide (a complex IV inhibitor). In primary hepatocytes, the enhancement was observed with the addition of sodium azide and rotenone, but not by TTFA or antimycin. In the nematode, only rotenone and TTFA enhanced the sensitivity under hyperoxia. These results demonstrate that highly specific inhibitors of electron transport can induce oxygen hypersensitivity in cell levels such as PC 12 cells and primary hepatocytes, and animal level of C. elegans. In addition the cell damage is different dependent on cell type and organism.     

Role of oxidative stress in alterations of mitochondrial function in ischemic-reperfused hearts

To study the mechanisms of mitochondrial dysfunction due to ischemia-reperfusion (I/R) injury, rat hearts were subjected to 20 or 30 min of global ischemia followed by 30 min of reperfusion. After recording both left ventricular developed pressure (LVDP) and end-diastolic pressure (LVEDP) to monitor the status of cardiac performance, mitochondria from these hearts were isolated to determine respiratory and oxidative phosphorylation activities. Although hearts subjected to 20 min of ischemia failed to generate LVDP and showed a marked increase in LVEDP, no changes in mitochondrial respiration and phosphorylation were observed. Reperfusion of 20-min ischemic hearts depressed mitochondrial function significantly but recovered LVDP completely and lowered the elevated LVEDP. On the other hand, depressed LVDP and elevated LVEDP in 30-min ischemic hearts were associated with depressions in both mitochondrial respiration and oxidative phosphorylation. Reperfusion of 30-min ischemic hearts elevated LVEDP, attenuated LVDP, and decreased mitochondrial state 3 and uncoupled respiration, respiratory control index, ADP-to-O ratio, as well as oxidative phosphorylation rate. Alterations of cardiac performance and mitochondrial function in I/R hearts were attenuated or prevented by pretreatment with oxyradical scavenging mixture (superoxide dismutase and catalase) or antioxidants [N-acetyl-L-cysteine or N-(2-mercaptopropionyl)-glycine]. Furthermore, alterations in cardiac performance and mitochondrial function due to I/R were simulated by an oxyradical-generating system (xanthine plus xanthine oxidase) and an oxidant (H(2)O(2)) either upon perfusing the heart or upon incubation with mitochondria. These results support the view that oxidative stress plays an important role in inducing changes in cardiac performance and mitochondrial function due to I/R.     

Continuous exposure to l-arginine induces oxidative stress and physiological tolerance in cultured human endothelial cells

The therapeutic benefits of L-arginine (ARG) supplementation in humans, often clearly observed in short-term studies, are not evident after long-term use. The mechanisms for the development of ARG tolerance are not known and cannot be readily examined in humans. We have developed a sensitive in vitro model using a low glucose/low arginine culture medium to study the mechanisms of ARG action and tolerance using two different human endothelial cells, i.e., Ea.hy926 and human umbilical venous endothelial cells. Cultured cells were incubated with different concentrations of ARG and other agents to monitor their effects on endothelial nitric oxide synthase (eNOS) expression and function, as well as glucose and superoxide (O2(·-) ) accumulation. Short-term (2 h) exposure to at least 50 μM ARG moderately increased eNOS activity and intracellular glucose (p < 0.05), with no change in eNOS mRNA or protein expression. In contrast, 7-day continuous ARG exposure suppressed eNOS expression and activity. This was accompanied by increase in glucose and O2(·-) accumulation. Co-incubation with 100 μM ascorbic acid, 300 U/ml polyethylene glycol-superoxide dismutase (PEG-SOD), 100 μM L-lysine or 30 μM 5-chloro-2-(N-2,5-dichlorobenenesulfonamido)-benzoxazole (a fructose-1,6-bisphosphatase inhibitor) prevented the occurrence of cellular ARG tolerance. Short-term co-incubation of ARG with PEG-SOD improved cellular nitrite accumulation without altering cellular ARG uptake. These studies suggest that ARG-induced oxidative stress may be a primary causative factor for the development of cellular ARG tolerance.     

Glycolytic and oxidative metabolism in relation to retinal function

Measurements of lactate production and ATP concentration in superfused rat retinas were compared with extracellular photoreceptor potentials (Fast PIII). The effect of glucose concentration, oxygen tension, metabolic inhibition, and light were studied. Optimal conditions were achieved with 5-20 mM glucose and oxygen. The isolated retina had a high rate of lactate production and maintained the ATP content of a freshly excised retina, and Fast PIII potentials were similar to in vivo recordings. Small (less than 10%) decreases in aerobic and anaerobic lactate production were observed after illumination of dark-adapted retinas. There were no significant differences in ATP content in dark- and light-adapted retinas. In glucose-free medium, lactate production ceased, and the amplitude of Fast PIII and the level of ATP declined, but the rates of decline were slower in oxygen than in nitrogen. ATP levels were reduced and the amplitude of Fast PIII decreased when respiration was inhibited, and these changes were dependent on glucose concentration. Neither glycolysis alone nor Krebs cycle activity alone maintained the superfused rat retina at an optimal level. Retinal lactate production and utilization of ATP were inhibited by ouabain. Mannose but not galactose or fructose produced lactate and maintained ATP content and Fast PIII. Iodoacetate blocked lactate production and Fast PIII and depleted the retina of ATP. Pyruvate, lactate, and glutamine maintained ATP content and Fast PIII reasonably well (greater than 50%) in the absence of glucose, even in the presence of iodoacetate. addition of glucose, mannose, or 2-deoxyglucose to medium containing pyruvate and iodoacetate abolished Fast PIII and depleted the retina of its ATP. It is suggested that the deleterious effects of these three sugars depend upon their cellular uptake and phosphorylation during the blockade of glycolysis by iodoacetate.