The effect of some tannins on trout erythrocytes exposed to oxidative stress

In order to gain more knowledge on the role of tannins as antioxidants, their ability to protect (Salmo irideus) erythrocytes against oxidative stress was investigated. Antioxidant activity of different tannins (tannic, gallic and ellagic acid) was evaluated by chemiluminescence (CL) techniques using lucigenin and luminol as chemiluminogenic probes for the superoxide radical generated by the xanthine/xanthine oxidase system and hydrogen peroxide, respectively. The superoxide-scavenging activity of these tannins was shown for all the compounds; however, it is not clear if this is due to their ability of scavenging the superoxide radical or to their inhibitory activity on xanthine oxidase. Tannic and ellagic acid showed a marked effect on the reduction of H2O2-luminol chemiluminescence. The influence of these tannins on the rate of hemolysis in stressed trout erythrocytes was investigated and the results indicate that tannic acid accelerates the hemolytic event while gallic and ellagic acid have no significant effect. The possible protective action of these compounds against oxidative DNA damage was assessed using the comet assay, a rapid and sensitive single-cell gel electrophoresis technique, used to detect primary DNA damage in individual cells. The results here reported show that tannins under study are capable at low concentrations of protecting DNA breakage, while at high concentrations they can be genotoxic.     

Effect of three diaryl tellurides, and an organoselenium compound in trout erythrocytes exposed to oxidative stress in vitro

Previous literature reports have demonstrated that nucleated trout erythrocytes in conditions of oxidative stress are subjected to DNA and membrane damage, and inactivation of glutathione peroxidase. The present study was undertaken to evaluate the ability of three diaryl tellurides and the organoselenium compound ebselen to protect trout (Salmo irideus) erythrocytes against oxidative stress, induced thermally and by a variation of pH. The antioxidant ability of these molecules was evaluated through chemiluminescence. Impairment of DNA was assessed using the comet assay, a rapid and sensitive single cell gel electrophoresis technique, used to detect primary DNA damage in individual cells. At low concentrations (<10 microM), all the compounds used presented a protective effect on DNA damage without altering the hemolysis rate. In higher concentrations, they accelerated the hemolysis rate and two of the diaryl tellurides were strongly genotoxic.     

Copper-specific damage in human erythrocytes exposed to oxidative stress

Ascorbate and complexes of Cu(II) and Fe(III) are capable of generating significant levels of oxygen free radicals. Exposure of erythrocytes to such oxidative stress leads to increased levels of methemoglobin and extensive changes in cell morphology. Cu(II) per mole is much more effective than Fe(III). However, isolated hemoglobin is oxidized more rapidly and completely by Fe(III)- than by Cu(II)-complexes. Both Fe(III) and Cu(II) are capable of inhibiting a number of the key enzymes of erythrocyte metabolism. The mechanism for the enhanced activity of Cu(II) has not been previously established. Using intact erythrocytes and hemolysates we demonstrate that Cu(II)-, but not Fe(III)-complexes in the presence of ascorbate block NADH-methemoglobin reductase. Complexes of Cu(II) alone are not inhibitory. The relative inability of Fe(III)-complexes and ascorbate to cause methemoglobin accumulation is not owing to Fe(III) association with the membrane, or its failure to enter the erythrocytes. The toxicity of Cu(II) and ascorbate appears to be a result of site-specific oxidative damage of erythrocyte NADH-methemoglobin reductase and the enzyme's subsequent inability to reduce the oxidized hemoglobin.     

Increase in vulnerability to oxidative damage in cholesterol-modified erythrocytes exposed to t-BuOOH

During the course of radical oxidation, cholesterol may exert seemingly contradictory effects. In order to gain a better understanding of the relationship between cholesterol levels and membrane susceptibility to oxidative damage induced by reactive oxygen species (ROS), here we analyze the integrity and structural stability of cholesterol-modified (enriched or depleted) and unmodified (control) erythrocytes exposed to tert-butyl hydroperoxide. The oxidant significantly increased ROS production, with almost complete oxidation of hemoglobin and a reduction in GSH content in the different erythrocyte groups at 2 mM concentration. These changes were accompanied by losses of cholesterol and total phospholipids, the main decreases being in phosphatidylethanolamine and phosphatidylcholine. The highest lipid loss was found in the cholesterol-depleted group. Fatty acid analyses revealed changes only in peroxidized cholesterol-modified erythrocytes, with decreases in linoleic and arachidonic acids. Fluorescence anisotropy studies showed an increase in the fluidity of the negatively charged surface of peroxidized control erythrocytes. Increased hemolysis and a positive correlation between cellular osmotic fragility and malondialdehyde contents were found in all peroxidized groups. These findings provide evidence that the modification of cholesterol levels in the erythrocyte membrane has provoking effects on peroxidation, with corresponding increases in oxidative damage in the treated cell, possibly as a consequence of lipid bilayer destabilization.     

Iron-mediated oxidative stress in erythrocytes.

Erythrocytes subjected extracellularly to iron-mediated oxidant stress undergo haemoglobin oxidation and membrane damage, which can be modulated by maintaining the energy requirements of the cells. The results presented here suggest that a balance exists between the oxidation state of the haemoglobin and the oxidative deterioration of the membrane lipids, which is dependent on the metabolic state of the erythrocytes. These findings have important implications for thalassaemic erythrocytes that may be exposed to excess plasma iron levels, in which excessive membrane-bound iron in the form of haemichromes is a characteristic feature and in which cellular ATP levels are lowered.     

Ebselen prevents mitochondrial ageing due to oxidative stress: in vitro study of fish erythrocytes

Nucleated trout erythrocytes under oxidative stress suffer DNA membrane damage and inactivation of glutathione peroxidase. In addition, oxidative damage increases with the age of the cell. In the present paper, we evaluate the effects of oxidative stress and ageing on mitochondrial functionality by means of transmission electron microscopy and cytofluorimetric determination of mitochondrial membrane potential and intracellular levels of reactive oxygen species. The protective activity of the antioxidant organoselenium compound ebselen, a mimic of glutathione peroxidase, is also evaluated. Ebselen prevents the drastic structural and functional changes in mitochondria in aged RBCs induced by oxidative stress. However, the antioxidant does not prevent swelling of the mitochondria.     

Effect of oxidative stress on membrane phospholipid and protein organization in human erythrocytes

Membrane phospholipid and protein organization was studied in intact human erythrocytes exposed to phenylhydrazine, an oxidative agent inducer. The evaluation of the membrane phospholipid and protein organization was carried out in terms of asymmetric distribution across the membrane bilayer for the phospholipids, and in terms of accessibility of cleavable sites present on the outer membrane surface for the proteins. Treatment of phenylhydrazine-exposed erythrocytes either with bee venom phospholipase A2 or with trinitrobenzenesulfonic acid indicated that phosphatidylserine (PS), which is the only phospholipid not formally present on the outer leaflet of the membrane, was translocated to the outer surface of the cell membrane. The extent of this phenomenon was directly proportional to the concentration of the oxidant having a peak value at 0.1 mM. Phosphatidylcholine and phosphatidylethanolamine conserved their original distribution across the erythrocyte membrane throughout the study. The oxidant, at a dose which did not induce any modification of the sodium dodecyl sulfate-polyacrylamide gel electrophoresis cytoskeleton membrane protein pattern, did not provoke any alteration of the membrane protein surface architecture, although the translocation of PS to the membrane outer leaflet in intact erythrocytes was present.     

Apoptosis and autophagy in photoreceptors exposed to oxidative stress

Studies on human and animal models of retinal dystrophy have suggested that apoptosis may be the common pathway of photoreceptor cell death. Autophagy, the major cellular degradation process in animal cells, is important in normal development and tissue remodeling, as well as under pathological conditions. Previously we provided evidence that genes, whose products are involved in apoptosis and autophagy, may be coexpressed in photoreceptors undergoing degeneration. Here, we investigated autophagy in oxidative stress-mediated cell death in photoreceptors, analyzing the light-damage mouse model and 661W photoreceptor cells challenged with H(2)O(2). In the in vivo model, we demonstrated a time-dependent increase in the number of TUNEL-positive cells, concomitant with the formation of autophagosomes. In vitro, oxidative stress increased mRNA levels of apoptotic and autophagic marker genes. H(2)O(2) treatment resulted in the accumulation of TUNEL-positive cells, the majority of which contain autophagosomes. To determine whether autophagy and apoptosis might precede each other or co-occur, we performed inhibitor studies. The autophagy inhibitor 3-methyladenine (3-MA), silencing RNA (siRNA) against two genes whose products are required for autophagy (autophagy-related (ATG) gene 5 and beclin 1), as well as the pan-caspase-3 inhibitor, Zvad-fmk, were both found to partially block cell death. Blocking autophagy also significantly decreased caspase-3 activity, whereas blocking apoptosis increased the formation of autophagosomes. The survival effects of 3?MA and zVAD-fmk were not additive; rather treatment with both inhibitors lead to increased cell death by necrosis. In summary, the study first suggests that autophagy participates in photoreceptor cell death possibly by initiating apoptosis. Second, it confirms that cells that normally die by apoptosis will execute cell death by necrosis if the normal pathway is blocked. And third, these results argue that the up-stream regulators of autophagy need to be identified as potential therapeutic targets in photoreceptor degeneration.     

Mitochondrial membrane potential in aging cells

Decreased mitochondrial membrane potential (DeltaPsi(M)) has been found in a variety of aging cell types from several mammalian species. The physiological significance and mechanisms of the decreased DeltaPsi(M) in aging are not well understood. This review considers the generation of DeltaPsi(M) and its role in ATP generation together with factors that modify DeltaPsi(M) with emphasis on mitochondrial membrane permeability, particularly the role of a multiprotein membrane megapore, the mitochondrial permeability transition pore complex (PTPC). Previous data showing decreased DeltaPsi(M) in aged cells is considered in relation to the methods available to estimate DeltaPsi(M). In the past the majority of studies used whole cell rhodamine 123 fluorescence to estimate DeltaPsi(M) in lymphocytes from mice or rats. Imaging of DeltaPsi(M) in living, in situ mitochondria using laser confocal scanning microscopy offers advantages over whole cell measurements or those from isolated mitochondria, particularly if several different potentiometric dyes are employed. Furthermore, high resolution imaging of the newer fixable potentiometric dyes allows immunocytochemistry for specific proteins and DeltaPsi(M) to be examined in the same cells or even the same mitochondria. We found that decreased DeltaPsi(M) in p53 overexpression-induced or naturally occurring senescence is associated with decreased responsiveness of the PTPC to agents that induce either its opening or closing. The decreased PTPC responsiveness seems to reflect, at least in part, decreased levels of a key PTPC protein, the adenine nucleotide translocase. We also consider the possible basis for decreased DeltaPsi(M) in fibroblasts from patients with Parkinson's disease, an age-related neurodegenerative disease. Finally, we speculate on the mechanisms and functional significance of decreased DeltaPsi(M) in aging.     

Mitochondrial membrane potential in cardiac myocytes

Mitochondria are involved in cellular functions that transcend the traditional role of these organelles as the energy factory of the cell. Their relative inaccessibility and the difficulties involved in attempts to study them in their natural environment -- the cytosol -- has delayed much of this understanding and they still have many secrets to yield. One of the relatively new fields in this respect is undoubtedly the analysis of mitochondrial membrane potential. The realization that its alteration may have important pathophysiological consequences has led to an increased interest in measuring this variable in a variety of biological settings, including cardiovascular diseases. Measurements of mitochondrial membrane potential tell us much about the role of mitochondria in normal cell function and in processes leading to cell death. However, we must be aware of the limitations of using isolated mitochondria, single cells and different fluorescent indicators.     

Mitochondrial matrix P53 sensitizes cells to oxidative stress

A mitochondrial matrix-specific p53 construct (termed p53-290) in HepG2 cells was utilized to determine the impact of p53 in the mitochondrial matrix following oxidative stress. H₂O₂ exposure reduced cellular proliferation similarly in both p53-290 and vector cells, and p53-290 cells demonstrating decreased cell viability at 1 mM H₂O₂ (~ 85% viable). Mitochondrial DNA (mtDNA) abundance was decreased in a dose-dependent manner in p53-290 cells while no change was observed in vector cells. Oximetric analysis revealed reduced maximal respiration and reserve capacity in p53-290 cells. Our results demonstrate that mitochondrial matrix p53 sensitizes cells to oxidative stress by reducing mtDNA abundance and mitochondrial function.     

Mitochondrial membrane potential and aging

The mitochondrial membrane potential (or protonmotive force) is the central bioenergetic parameter that controls respiratory rate, ATP synthesis and the generation of reactive oxygen species, and is itself controlled by electron transport and proton leaks. As a consequence of extensive research, there has emerged a consensus as to how these parameters integrate. Despite this consensus, the literature contains contradictory reports on the extent to which these parameters are modified in animal models of aging. This article critically examines the basis for a number of these reports.     

Mitochondrial permeability transition and oxidative stress

Mitochondrial permeability transition (MPT) is a non-selective inner membrane permeabilization that may precede necrotic and apoptotic cell death. Although this process has a specific inhibitor, cyclosporin A, little is known about the nature of the proteinaceous pore that results in MPT. Here, we review data indicating that MPT is not a consequence of the opening of a pre-formed pore, but the consequence of oxidative damage to pre-existing membrane proteins.     

Direct and continuous measurement of hydroperoxide-induced oxidative stress on the membrane of intact erythrocytes

Having minimized spectroscopic interference by hemoglobin (Hb), peroxidation processes in intact erythrocytes could be monitored in a continuous assay using the fluorescent polyunsaturated fatty acid, parinaric acid (PnA), as a peroxidation probe. Control experiments to establish the character of the method are described in detail. As a practical application, comparative studies were performed to monitor the response of normal and sickle Hb-containing human erythrocytes to oxidative stress in the PnA assay. After 10 min of incubation with 200 microM cumene hydroperoxide (cumOOH), peroxidation of PnA was found to be enhanced in erythrocytes from sickle cell disease patients (SS: 48 +/- 9% (n = 6) of initial amount had been peroxidized) compared to healthy controls (AA: 30 +/- 4% (n = 9)). PnA peroxidation in erythrocytes from sickle cell trait individuals (AS: 30 +/- 3% (n = 4)) was equal to that in control cells. The increased oxidation of PnA in sickle erythrocytes was accompanied by enhanced oxidation of Hb (metHb and hemichrome formation), indicating that sickle Hb mediates enhanced cumOOH-derived radical generation. It is concluded that PnA can be a useful tool in studying membrane peroxidation processes in intact normal and pathological erythrocytes.     

Mitochondrial accumulation under oxidative stress is due to defects in autophagy

Mitochondrial dynamics maintains normal mitochondrial function by degrading damaged mitochondria and generating newborn mitochondria. The accumulation of damaged mitochondria influences the intracellular environment by promoting mitochondrial dysfunction, and thus initiating a vicious cycle. Oxidative stress induces mitochondrial malfunction, which is involved in many cardiovascular diseases. However, the mechanism of mitochondrial accumulation in cardiac myoblasts remains unclear. We observed mitochondrial dysfunction and an increase in mitochondrial mass under the oxidative conditions produced by tert‐butyl hydroperoxide (tBHP) in cardiac myoblast H9c2 cells. However, in contrast to the increase in mitochondrial mass, mitochondrial DNA (mtDNA) decreased, suggesting that enhanced mitochondrial biogenesis may be not the primary cause of the mitochondrial accumulation. Therefore, we investigated changes in a number of proteins involved in autophagy. Beclin1, Atg12–Atg5 conjugate, Atg7 contents decreased but LC3‐II accumulated in tBHP‐treated H9c2 cells. Moreover, the capacity for acid hydrolysis decreased in H9c2 cells. We also demonstrated a decrease in DJ‐1 protein under the oxidative conditions that deregulate mitochondrial dynamics. These results reveal that autophagy became defective under oxidative stress. We therefore suggest that defects in autophagy mediate mitochondrial accumulation under these conditions. J. Cell. Biochem. 114: 212–219, 2012. © 2012 Wiley Periodicals, Inc.     

Acetaminophen protects human erythrocytes against oxidative stress

Acetaminophen protects human erythrocytes against various modes of oxidative stress. Protection against ozone-induced damage can be explained by a direct scavenging reaction between the drug and ozone. With t-butylhydroperoxide acetaminophen appeared to be an effective scavenger of radicals, generated in secondary reactions. The protection by acetaminophen against t-butylhydroperoxide- and hydrogen peroxide-induced lipid peroxidation and K+-leakage can be explained along these lines. In all cases the protective effect of acetaminophen was attended with covalent binding of acetaminophen to membrane proteins.     

Mitochondrial dysfunction and oxidative stress in diabetic wound

Diabetic wounds nowadays have become a major health challenge with the changes of the disease spectrum. Mitochondria are closely associated with stubborn nonhealing diabetic wounds for their vital role in energy metabolism, redox homeostasis, and signal transduction. There is significant mitochondrial dysfunction and oxidative stress in diabetic wounds. However, the contribution of mitochondrial dysfunction in oxidative stress induced nonhealing diabetic wound is still not fully understood. In this review, we will briefly summarize the current knowledge of the reported signaling pathways and therapeutic strategies involved in mitochondrial dysfunction in diabetic wounds. The findings provide further understanding of strategies that focus on mitochondria in diabetic wound treatment.