Rate Reactive Oxygen Species Research Articles

Exogenous insulin can reverse the effects of caloric restriction on mitochondria

It has been proposed that part of the anti-aging mechanism of caloric restriction (CR) involves a reduction in both the generation rate of reactive oxygen species (ROS) by mitochondria, and a reduction in peroxidizability of mitochondrial membranes. It was hypothesized that these effects may be due to upstream changes in hormonal status, since certain hormones (such as insulin) are stimulatory for ROS production, effect fatty acid composition, and are lowered by CR. To investigate this hypothesis, young male Brown–Norway rats on 55% CR (4 months duration) were subjected to insulin replacement by use of mini-osmotic pumps. ROS and free radical-induced malondialdehdye production were significantly lower in mitochondria from CR animals compared to those from fully fed, and these effects were reversed by insulin. It is concluded that the beneficial changes induced by CR, as seen at the mitochondrion, may in part be downstream effects of alterations in hormonal signalling.

A “mitochondrial cascade hypothesis” for sporadic Alzheimer's disease

Alzheimer's disease (AD) includes etiologically heterogenous disorders characterized by senile or presenile dementia, extracellular amyloid protein aggregations containing an insoluble amyloid precursor protein derivative, and intracytoplasmic tau protein aggregations. Recent studies also show excess neuronal aneuploidy, programmed cell death (PCD), and mitochondrial dysfunction. The leading AD molecular paradigm, the “amyloid cascade hypothesis”, is based on studies of rare autosomal dominant variants and does not specify what initiates the common late-onset, sporadic form. We propose for late-onset, sporadic AD a “mitochondrial cascade hypothesis” that comprehensively reconciles seemingly disparate histopathologic and pathophysiologic features. In our model, the inherited, gene-determined make-up of an individual's electron transport chain sets basal rates of reactive oxygen species (ROS) production, which determines the pace at which acquired mitochondrial damage accumulates. Oxidative mitochondrial DNA, RNA, lipid, and protein damage amplifies ROS production and triggers three events: (1) a reset response in which cells respond to elevated ROS by generating the β-sheet protein, beta amyloid, which further perturbs mitochondrial function, (2) a removal response in which compromised cells are purged via PCD mechanisms, and (3) a replace response in which neuronal progenitors unsuccessfully attempt to re-enter the cell cycle, with resultant aneuploidy, tau phosphorylation, and neurofibrillary tangle formation. In addition to defining a role for aging in AD pathogenesis, the mitochondrial cascade hypothesis also allows and accounts for histopathologic overlap between the sporadic, late-onset and autosomal dominant, early onset forms of the disease.

Effect of caloric restriction on mitochondrial reactive oxygen species production and bioenergetics: reversal by insulin.

To gain insight into the antiaging mechanisms of caloric restriction (CR), mitochondria from liver tissue of male Brown Norway rats were used to study the effects of CR and insulin on mitochondrial reactive oxygen species production and bioenergetics. As assessed by hydrogen peroxide measurement, CR resulted in a decrease in the production rate of reactive oxygen species. This decrease was attributed to a decrease in protonmotive force in mitochondria from the CR animals. The decrease in protonmotive force resulted from an increase in proton leak activity and a concomitant decrease in substrate oxidation activity. Each of these effects of CR was reversed by subjecting CR animals to 2 wk of insulin treatment. To achieve continuous and stable insulin delivery, animals were placed under temporary halothane anesthesia and miniosmotic pumps were implanted subcutaneously. To gain further insight into how CR and insulin exerted its effects on mitochondrial bioenergetics, the effects of CR and insulin were quantified using modular metabolic control analysis. This analysis revealed that the effects of CR were transmitted through different reaction branches of the bioenergetic system, and insulin reversed the effects of CR by acting through the same branches. These results provide a plausible mechanism by which mitochondrial reactive oxygen species production is lowered by CR and a complete description of the effects of CR on mitochondrial bioenergetics. They also indicate that these changes may be due to lowered insulin concentrations and altered insulin signaling in the CR animal.

Increase in Mitochondrial Mass in Human Fibroblasts under Oxidative Stress and during Replicative Cell Senescence

Abnormal proliferation of mitochondria generally occurs in muscle of aged individuals and patients with mitochondrial myopathy. An increase in the mitochondrial DNA (mtDNA) copy number has also been observed in aging human tissues. However, the molecular mechanism underlying the increase in mitochondrial mass and mtDNA is still unclear. In a previous study, we demonstrated that sublethal levels of oxidative stress caused an increase in mitochondrial mass in human lung cells. In this communication, we report our recent findings that the mitochondrial mass in human lung fibroblasts (MRC-5) in a later proliferation stage is significantly increased compared to that in the early stages of proliferation. The extent of the increase in mitochondrial mass in the senescent cells was similar to that in cells in the early stages of proliferation that had been treated with low concentrations (≤180 µM) of hydrogen peroxide (H₂O₂). Moreover, we found that the rate of reactive oxygen species (ROS) production was higher in cells in the later proliferation stage compared to cells in the early proliferation stages. A similar phenomenon was also observed in cells in the early proliferation stages under low levels of oxidative stress. On the other hand, the mRNA levels of many nuclear DNA-encoded proteins involved in mitochondrial biogenesis, particularly nuclear respiratory factor-1, were found to increase in cells in later proliferation stages and in cells in early proliferation stages that had been treated with 180 µM H₂O₂. Interestingly, the increase in mitochondrial mass in the cells under oxidative stress could be repressed by treatment with cycloheximide or m-chlorocarbonyl cyanide phenylhydrazone but not by chloramphenicol. Furthermore, the mitochondrial mass of mtDNA-less ρ^o cells was also significantly increased by exposure to low concentrations (e.g. 180 µM) of H₂O₂. These results suggest that the increase in mitochondrial mass in replicative senescent cells may result from an increase in ROS production, and that it is dependent on both de novo synthesis of nuclear DNA-encoded proteins and their import into mitochondria, dictated by the membrane potential of mitochondria.

Increase in mitochondrial mass in human fibroblasts under oxidative stress and during replicative cell senescence.

Abnormal proliferation of mitochondria generally occurs in muscle of aged individuals and patients with mitochondrial myopathy. An increase in the mitochondrial DNA (mtDNA) copy number has also been observed in aging human tissues. However, the molecular mechanism underlying the increase in mitochondrial mass and mtDNA is still unclear. In a previous study, we demonstrated that sublethal levels of oxidative stress caused an increase in mitochondrial mass in human lung cells. In this communication, we report our recent findings that the mitochondrial mass in human lung fibroblasts (MRC-5) in a later proliferation stage is significantly increased compared to that in the early stages of proliferation. The extent of the increase in mitochondrial mass in the senescent cells was similar to that in cells in the early stages of proliferation that had been treated with low concentrations (< or = 180 microM) of hydrogen peroxide (H(2)O(2)). Moreover, we found that the rate of reactive oxygen species (ROS) production was higher in cells in the later proliferation stage compared to cells in the early proliferation stages. A similar phenomenon was also observed in cells in the early proliferation stages under low levels of oxidative stress. On the other hand, the mRNA levels of many nuclear DNA-encoded proteins involved in mitochondrial biogenesis, particularly nuclear respiratory factor-1, were found to increase in cells in later proliferation stages and in cells in early proliferation stages that had been treated with 180 microM H(2)O(2). Interestingly, the increase in mitochondrial mass in the cells under oxidative stress could be repressed by treatment with cycloheximide or m-chlorocarbonyl cyanide phenylhydrazone but not by chloramphenicol. Furthermore, the mitochondrial mass of mtDNA-less rho(o) cells was also significantly increased by exposure to low concentrations (e.g. 180 microM) of H(2)O(2). These results suggest that the increase in mitochondrial mass in replicative senescent cells may result from an increase in ROS production, and that it is dependent on both de novo synthesis of nuclear DNA-encoded proteins and their import into mitochondria, dictated by the membrane potential of mitochondria.

Inhibition of oxidative stress produced by plasma membrane NADH oxidase delays low-potassium-induced apoptosis of cerebellar granule cells.

From 1 to 3 h after the onset of cerebellar granule cells (CGC) apoptosis in a low-K+(5 mm KCl) medium there was a large decay of NADH and a 2.5-fold increase of the rate of reactive oxygen species (ROS) production (measured using CGC loaded with dichlorodihydrofluorescein). During the same time period, the ascorbate-dependent NADH oxidase activity, which accounted for more than 90% of both total NADH oxidase activity and NADH-dependent *O2- production of CGC lysates, increased 2.5- to threefold. The stimulation of the ascorbate-dependent NADH oxidase activity by oxidized cytochrome c, 2.5-fold at saturation with a K(0.5) of 4-5 microm cytochrome c, can at least partially explain this activation. The plasma membrane ascorbate-dependent NADH oxidase activity accounted for more than 70% of the total activity (both in terms of NADH oxidase and *O2- release) of CGC lysates. 4-Hydroxyquinazoline (4-HQ), which was found to block this apoptotic process, prevented the increase of ROS production. 4-HQ protection against cell viability loss and DNA fragmentation correlated with the inhibition by 4-HQ of the ascorbate-dependent NADH oxidase activity of CGC lysates, showing the same K(0.5)-value (4-5 mm 4-HQ). The efficient blockade of CGC apoptosis by addition of superoxide dismutase to the medium further supports the neurotoxic role of *O2- overproduction by the plasma membrane ascorbate-dependent NADH oxidase.

Glutathione depletion enforces the mitochondrial permeability transition and causes cell death in Bcl-2 overexpressing HL60 cells.

Bcl-2, a protein that blocks apoptosis by inhibiting the mitochondrial permeability transition (MPT) and release of cytochrome c appears to affect normal mitochondrial function by altering electron flow and increasing rates of reactive oxygen species (ROS) production. In this study, we show that glutathione (GSH) depletion induces ROS production and selective toxicity in HL60 cells that overexpress Bcl-2 compared with neomycin vector control cells. Toxicity was mediated by the MPT because it was blocked with the adenine nucleotide translocator (ANT) ligand bongkrekic acid and resulted in mitochondrial cytochrome c release, caspase 3 activation, and DNA fragmentation, indicating the involvement of an apoptotic pathway. Respiratory chain inhibitors stigmatellin and antimycin A, which inhibit Qo and Qi sites of respiratory chain complex III, respectively, blocked ROS production, preserved the redox state of protein thiols, and prevented cell death. These results indicate that in the absence of GSH, endogenous ROS generated at respiratory complex III induce MPT independently of Bcl-2. The results also suggest a new model for MPT in which the central pore protein ANT is regulated by adenine nucleotide and the activity of mitochondrial respiratory complex III.

Doxorubicin-induced persistent oxidative stress to cardiac myocytes

We recently reported a cardioselective and cumulative oxidation of cardiac mitochondrial DNA (mtDNA) following subchronic administration of doxorubicin to rats. The mtDNA adducts persist for up to 5 weeks after cessation of doxorubicin treatment. Since the evidence suggests that this persistence of mtDNA adducts cannot be attributed to a lack of repair and replication, we investigated whether it might reflect a long-lasting stimulation of free radical-mediated adduct formation. Male Sprague–Dawley rats received weekly s.c. injections of either doxorubicin (2 mg/kg) or an equivalent volume of saline. Cardiac myocytes isolated from rats following 6 weekly injections of doxorubicin expressed a much higher rate of reactive oxygen species (ROS) formation compared to saline controls. This higher rate of ROS formation persisted for 5 weeks following the last injection. Associated with this was a persistent depression of GSH in heart tissue, while protein-thiol content was not markedly altered. These data suggest that the accumulation and persistence of oxidized mtDNA may be due, not to the stability of the adducts, but to some as yet undefined toxic lesion that causes long-lasting stimulation of ROS generation by doxorubicin. This persistent generation of ROS may contribute to the cumulative and irreversible cardiotoxicity observed clinically with the drug.

Ibuprofen protects low density lipoproteins against oxidative modification

Oxidative modification of LDL by vascular cells has been proposed as the mechanism by which LDL become atherogenic. The effect of ibuprofen on LDL modification by copper ions, monocytes and endothelial cells was studied by measuring lipid peroxidation products. Ibuprofen inhibited LDL oxidation in a dose-dependent manner over a concentration range of 0.1 to 2.0 mM. Ibuprofen (2 mM, 100 μg/ml LDL) reduced the amount of lipid peroxides formed during 2 and 6 h incubation in the presence of copper ions by 52 and 28%, respectively. Weak free radical scavenging activity of ibuprofen was observed in the DPPH test. The protective effect of ibuprofen was more marked when oxidation was induced by monocytes or endothelial cells. Ibuprofen (1 mM, 100 μg/ml LDL) reduced the amount of lipid peroxides generated in LDL during monocyte-mediated oxidation by 40%. HUVEC-mediated oxidation of LDL in the absence and presence of Cu 2+ was reduced by 32 and 39%, respectively. More lipid peroxides appeared when endothelial cells were stimulated by IL-1β or TNFα and the inhibitory effect of ibuprofen in this case was more pronounced. Ibuprofen (1 mM, 100 μg/ml LDL) reduced the amount of lipid peroxides formed during incubation of LDL with IL-1β-stimulated HUVEC by 43%. The figures in the absence and presence of Cu 2+ for HUVEC stimulated with TNFα were 56 and 59%, respectively. To assess the possibility that ibuprofen acts by lowering the production rate of reactive oxygen species, the intracellular concentration of H 2O 2 was measured. Ibuprofen (1 mM) reduced intracellular production of hydrogen peroxide in PMA-stimulated mononuclear cells by 69%. When HUVEC were stimulated by IL-1β or TNFα the reduction was 62% and 66%, respectively.

Rapid Communication Interferon beta-1b inhibits reactive oxygen species production in peripheral blood monocytes of patients with relapsing-remitting multiple sclerosis

We studied the rate of reactive oxygen species (ROS) production by monocytes {ex vivo| in a cohort of healthy individuals, in a group of MS patients undergoing treatment with interferon beta-1b and another group of MS patients who refused treatment with interferon beta-1b. The rate of ROS production in healthy individuals was slightly lower than in non-treated MS patients. The lower rate of ROS production was obtained in monocytes of MS patients treated with interferon beta-1b. These results indicate that the treatment of relapsing-remitting MS patients with interferon beta-1b rendered the NADPH oxidase of the monocytes less sensitive to trigger reactive oxygen species (ROS).

Three weeks' exposure of rats to dearomatized white spirit modifies indices of oxidative stress in brain, kidney, and liver

The present study was undertaken in order to investigate whether dearomatized white spirit induces indices of oxidative stress in subcellular fractions of hemisphere, hippocampus, kidney and liver tissue of rats exposed to 0, 400 and 800 ppm 6 hr/day, 7 days a week for 3 weeks. The results show that white spirit is a strong in vivo inducer of oxidative stress in subcellular fractions of brain, kidney and liver. In the liver there was a statistically significant increase in the rate of reactive oxygen species (ROS) generation and a decrease in glutamine synthetase activity. In the kidney there was a statistically significant decrease in the rate of ROS generation. In the hemisphere there was a statistically significant increase in the level of reduced glutathione. In the hippocampus there was a statistically significant increase in the rate of ROS generation. However, in vitro addition of dearomatized white spirit had no effect on the rate of cerebrocortical P2 fraction ROS generation. The results suggest that cumulative oxidative damage may be an underlying mechanism of dearomatized white spirit-induced neurotoxicity and that various regions of the brain may respond differently.

Ethanol‐Induced Oxidative Stress and Nutritional Status

The ability of dietary ethanol, administered over a 10-day period, to elevate production rates of reactive oxygen species and to alter glutathione levels has been determined in both liver and cerebellum, a brain region known to be susceptible to ethanol-induced damage. Two groups of ethanol-consuming rats were used. One set of treated animals that received an all-liquid ethanol-containing diet experienced weight gain, and this gain was matched in a pair-fed control group. The other ethanol-treated group that had free access only to solid chow and water containing ethanol lost weight during the exposure period. The corresponding control group that received unlimited water and chow was allowed to gain weight normally. In animals that lost weight as a consequence of ethanol in the drinking water, evidence of oxidative stress was enhanced relative to that in animals receiving ethanol by way of the liquid diet. This latter set gained weight, despite higher blood ethanol levels than the group that lost weight. An excess prooxidant condition prevailed in the liver and cerebellum of the ethanol-dosed malnourished group. In the case of liver, this difference may relate to a greater lability of iron-containing proteins in the rats that experienced weight loss, leading to the appearance of low molecular weight iron in the cytosol.

Responses of vascular endothelial oxidant metabolism to lipopolysaccharide and tumor necrosis factor-α

Quantification of intracellular and extracellular levels and production rates of reactive oxygen species is crucial to understanding their contribution to tissue pathophysiology. We measured basal rates of oxidant production and the activity of xanthine oxidase, proposed to be a key source of O 2 − and H 2O 2, in endothelial cells. Then we examined the influence of tumor necrosis factor-α and lipopolysaccharide on endothelial cell oxidant metabolism, in response to the proposal that these inflammatory mediators initiate vascular injury in part by stimulating endothelial xanthine oxidase-mediated production of O 2 − and H 2O 2. We determined a basal intracellular H 2O 2 concentration of 32.8 ± 10.7 p m in cultured bovine aortic endothelial cells by kinetic analysis of aminotriazole-mediated inactivation of endogenous catalase. Catalase activity was 5.72 ± 1.61 U/mg cell protein and glutathione peroxidase activity was much lower, 8.13 ± 3.79 mU/ mg protein. Only 0.48 ± 0.18% of total glucose metabolism occurred via the pentose phosphate pathway. The rate of extracellular H 2O 2 release was 75 ± 12 pmol · min −1 · mg cell protein −1. Intracellular xanthine dehydrogenase/oxidase activity determined by pterin oxidation was 2.32 ± 0.75 μU/mg with 47.1 ± 11.7% in the oxidase form. Intracellular purine levels of 1.19 ±1.04 nmol hypoxanthine/mg protein, 0.13 ± 0.17 nmol xanthine/mg protein, and undetectable uric acid were consistent with a low activity of xanthine dehydrogenase/ oxidase. Exposure of endothelial cells to 1000 U/ml tumor necrosis factor (TNF) or 1 μg/ml lipopolysaccharide (LPS) for 1–12 h did not alter basal endothelial cell oxidant production or xanthine dehydrogenase/oxidase activity. These results do not support a casual role for H 2O 2 in the direct endothelial toxicity of TNF and LPS.

Deferoxamine inhibits methyl mercury-induced increases in reactive oxygen species formation in rat brain

It has been suggested that methyl mercury may express its neurotoxicity by way of iron-mediated oxidative damage. Therefore, the effect of deferoxamine, a potent iron-chelator, on methyl mercury-induced increases in reactive oxygen species formation was studied in rat brain. The generation rate of reactive oxygen species was estimated in crude synaptosomal fractions using the probes 2′,7′-dichlorofluorescin diacetate and dihydrorhodamine 123. The formation rate of the fluorescent oxidation products was used as the measure of reactive oxygen species generation. Seven days after a single injection of methyl mercury (5 mg/kg, ip), the formation rate of reactive oxygen species was significantly increased in the cerebellum. Pretreatment with deferoxamine (500 mg/kg, ip) completely prevented the methyl mercury-induced increase in cerebellar reactive oxygen species generation rates. The oxidative consequences of in vitro exposure to methyl mercury (20 μ m) were also inhibited by deferoxamine (100 μ m). The formation of the iron-saturated complex ferrioxamine was not affected by a 10-fold excess of methylmercuric chloride or mercuric chloride, suggesting that a deferoxamine-mercurial complex does not form. The findings in this study: (1) provide evidence that iron-catalyzed oxygen radical-producing reactions play a role in methyl mercury neurotoxicity, (2) demonstrate the potential of fluorescent probes as a measure of reactive oxygen species formation, and (3) provide support for iron-chelator therapy in protection against xenobiotic-induced oxidative damage.

Effects of toluene and its metabolites on cerebral reactive oxygen species generation

The effects of toluene on lipid peroxidation and rates of reactive oxygen species (ROS) formation have been studied in isolated systems and in vivo. The induction of reactive oxygen species was assayed using the probe 2',7'-dichlorofluorescin diacetate (DCFH-DA). Toluene exposure (1 g/kg, 1 hr, i.p.) did not stimulate cortical lipid peroxidation as evaluated by measurement of conjugated dienes. Exposure to toluene, however, both in vivo and in vitro, caused a significant elevation of ROS formation within cortical crude synaptosomal fractions (P2) and microsomal fractions (P3). The ROS-inducing properties of toluene were blocked in vivo in the presence of a mixed-function oxidase inhibitor, metyrapone. This suggested that a metabolite of toluene may catalyze reactive oxygen formation. Both benzyl alcohol and benzoic acid, in vitro, were found to have free radical quenching properties, while benzaldehyde exhibited significant induction of ROS generation. It appears that benzaldehyde is the metabolite responsible for the effect of toluene in accelerating reactive oxygen production within the nervous system. Benzaldehyde may also contribute to the overall neurotoxicity of toluene.