Antioxidant protection against oxidant-induced damage in cultured gastric mucosal cells

Evaluation of ischemia-reperfusion liver injury by near-infrared spectroscopy in an experimental swine model: the effect of desferoxamine

INTRODUCTION

Ischemia-reperfusion (I-R) injury has long been regarded a primary factor for the physiological dysfunction that can occur following major liver resection performed under vascular control. The aim of our study was to assess the effect of treatment with desferoxamine (DFO), a potent antioxidative agent, monitoring the I-R injury on a porcine model of major hepatectomy.

MATERIALS AND METHODS

Twelve female pigs were allocated to control (n = 6) and DFO groups (n = 6) and underwent 30 min of liver ischemia, during which a ≥30% hepatectomy was performed, followed by six hours of postoperative monitoring. The DFO group animals were preconditioned with a continuous iv solution of DFO to a total dose of 100 mg/kg during their postoperative period. Liver remnants (≈70% of initial liver volume) were evaluated by means of infrared spectroscopy, serum lactate measurement of the systemic, portal and hepatic vein blood, and by immunohistochemical assessment of apoptosis in consecutive liver biopsies.

RESULTS

DFO group demonstrated considerably faster restoration of tissue oxygenation (92.33% vs. 80%, p < .05) and serum lactate values (1.23 mmol/l vs. 2.27 mmol/l, p < .05). Moreover, apoptosis as estimated by TUNEL and caspase-3 staining was significantly lower in the DFO group (0.06% vs. 1.17% and 1.17% vs. 2%, respectively, p < .05). The severity of the I-R injury showed a linear correlation to the restoration of tissue oxygenation, as estimated by infrared-spectroscopy (r(2) = 0.81, p < .01).

CONCLUSION

Iron chelation with DFO appears to attenuate I-R injury of the liver remnant following hepatectomy, as reflected by faster restoration of tissue oxygenation and lower apoptotic activity.

Eupatilin inhibits H(2)O(2)-induced apoptotic cell death through inhibition of mitogen-activated protein kinases and nuclear factor-kappaB

Eupatilin (5,7-dihydroxy-3',4',6-trimethoxyflavone), an extract from Artemisia asiatica Nakai, is a flavonoid of pharmacologically active ingredients. Eupatilin is known to possess anti-cancer, anti-inflammatory, and anti-oxidative activity. Recently, eupatilin has been reported to be effective in producing gastric mucosal as an anti-gastritis agents. However, the mechanism of protective action is still unknown. We studied cytoprotective actions of eupatilin on H(2)O(2)-induced cell death and its possible mechanisms of action in human gastric (AGS) cells. Eupatilin dose-dependently inhibited H(2)O(2)-induced apoptosis as indicated by co-staining with Annexin V and propidium iodide. Hydrogen peroxide provoked phosphorylation of extracellular regulated kinase (ERK) and c-Jun NH(2)-terminal kinase (JNK), and activation of nuclear factor-kappaB (NF-kappaB). On the contrary, eupatilin decreased H(2)O(2)-induced activation of ERK, JNK and NF-kappaB. In addition, treatment of specific inhibitors for ERK, JNK, and NF-kappaB attenuated H(2)O(2)-induced apoptosis. Co-treatment of inhibitors and eupatilin was more effective in decreasing H(2)O(2)-induced apoptosis. Taken together, we suggest that eupatilin inhibits H(2)O(2)-induced apoptosis through the inhibition ERK, JNK, and NF-kappaB.

Spermine and spermidine mediate protection against oxidative damage caused by hydrogen peroxide

The polyamines spermidine and spermine have been hypothesized to possess different functions in the protection of DNA from reactive oxygen species. The growth and survival of mouse fibroblasts unable to synthesize spermine were compared to their normal counterparts in their native and polyamine-depleted states in response to oxidative stress. The results of these studies suggest that when present at normal or supraphysiological concentrations, either spermidine or spermine can protect cells from reactive oxygen species. However, when polyamine pools are pharmacologically manipulated to produce cells with low levels of predominately spermine or spermidine, spermine appears to be more effective. Importantly, when cells are depleted of both glutathione and endogenous polyamines, they exhibit increased sensitivity to hydrogen peroxide as compared to glutathione depletion alone, suggesting that polyamines not only play a role in protecting cells from oxidative stress but this role is distinct from that played by glutathione.

Indomethacin inactivates gastric peroxidase to induce reactive-oxygen-mediated gastric mucosal injury and curcumin protects it by preventing peroxidase inactivation and scavenging reactive oxygen

We have investigated the mechanism of indomethacin-induced gastric ulcer caused by reactive oxygen species (ROS) and the gastroprotective effect of curcumin thereon. Curcumin dose-dependently blocks indomethacin-induced gastric lesions, showing 82% protection at 25 mg/kg. Indomethacin-induced oxidative damage by ROS as shown by increased lipid peroxidation and thiol depletion is almost completely blocked by curcumin. Indomethacin causes nearly fivefold increase in hydroxyl radical (()OH) and significant inactivation of gastric mucosal peroxidase to elevate endogenous H(2)O(2) and H(2)O(2)-derived ()OH, which is prevented by curcumin. In vitro studies indicate that indomethacin inactivates peroxidase irreversibly only in presence of H(2)O(2) by acting as a suicidal substrate. 5,5-Dimethyl-pyrroline-N-oxide (DMPO) protects the peroxidase, indicating involvement of indomethacin radical in the inactivation. Indomethacin radical was also detected in the peroxidase-indomethacin-H(2)O(2) system as DMPO adduct (a(N) = 15 G, a(beta)(H) = 16 G) by electron spin resonance spectroscopy. Curcumin protects the peroxidase in a concentration-dependent manner and consumes H(2)O(2) for its oxidation as a suitable substrate of the peroxidase, thereby blocking indomethacin oxidation. Curcumin can also scavenge ()OH in vitro. We suggest that curcumin protects gastric damage by efficient removal of H(2)O(2) and H(2)O(2) -derived ()OH by preventing peroxidase inactivation by indomethacin.

Mechanism of vitamin C inhibition of cell death induced by oxidative stress in glutathione-depleted HL-60 cells

Vitamin C is a well known antioxidant whose precise role in protecting cells from oxidative challenge is uncertain. In vitro results have been confounded by pro-oxidant effects of ascorbic acid and an overlapping role of glutathione. We used HL-60 cells as a model to determine the precise and independent role of vitamin C in cellular protection against cell death induced by oxidative stress. HL-60 cells do not depend on glutathione to transport or reduce dehydroascorbic acid. Depletion of glutathione rendered the HL-60 cells highly sensitive to cell death induced by H2O2, an effect that was not mediated by changes in the activities of glutathione reductase, glutathione peroxidase, catalase, or superoxide dismutase. The increased sensitivity to oxidative stress was largely reversed when glutathione-depleted cells were preloaded with ascorbic acid by exposure to dehydroascorbic acid. Resistance to H2O2 treatment in cells loaded with vitamin C was accompanied by intracellular consumption of ascorbic acid, generation of dehydroascorbic acid, and a decrease in the cellular content of reactive oxygen species. Some of the dehydroascorbic acid generated was exported out of the cells via the glucose transporters. Our data indicate that vitamin C is an important independent antioxidant in protecting cells against death from oxidative stress.

Protection against oxidative injury and permeability alteration in cultured alveolar epithelium by transferrin-catalase conjugate

The successful prevention of hydrogen peroxide-induced alveolar permeability alterations and cell injury by transferrin-catalase conjugate is described in this study. Permeability alterations and cell injury were induced in cultured alveolar epithelial monolayers by hydrogen peroxide. Transepithelial transport of a permeability marker, [14C] mannitol, and cellular nuclear fluorescence of a membrane integrity indicator, propidium iodide, were used to quantitate epithelial permeability and damage respectively. Hydrogen peroxide (0.1 - 10 mM) induced a dose-dependent increase in both alveolar permeability and cellular damage; however, the oxidant effect on monolayer permeability did not require prior cell damage. Electron spin resonance measurements using the spin trap 5,5-dimethyl-l-pyrroline-N-oxide indicated the formation of hydroxyl radicals in hydrogen peroxide-treated cells. Chelation of the cellular pool of iron by deferoxamine inhibited radical formation and helped protect the cells from oxidative changes. Prior treatment of the cells with catalase (0.1 U-10 U/ml) had minimal protective effects on cell injury and permeability alterations. In contrast, transferrin-catalase conjugate, at the same concentration range, exhibited much improved protective effects on the cells in response to oxidant stress. This enhanced protection was found to correlate well with an increase in cellular uptake of the enzyme conjugate via the transferrin receptor endocytosis pathway. Effective protection by the enzyme conjugate was shown to require both the antioxidant enzyme moiety and the cognate moiety for the cell surface receptor. These findings indicate the potential therapeutic merit of transferrin-catalase conjugate for the treatment of pathological processes in the lung, whenever oxidative stress is involved.

In vitro cell injury by oxidized low density lipoprotein involves lipid hydroperoxide-induced formation of alkoxyl, lipid, and peroxyl radicals

Mounting evidence supports current theories linking lipoprotein oxidation to atherosclerosis. We sought the cellular biochemical mechanism by which oxidized LDL inflicts cell injury. Inhibitors of candidate pathways of cell death were used to treat human fibroblast target cells exposed to oxidized LDL.. Ebselen, which degrades lipid hydroperoxides, inhibited oxidized LDL toxicity, consistent with our recent report that 7 beta-hydroperoxycholesterol (7 beta-OOH chol) is the major cytotoxin of oxidized LDL. Intracellular chelation of metal ions inhibited, while preloading cells with iron enhanced, toxicity, Inhibition of oxidized LDL and 7 beta-OOH chol toxicity by 2-keto-4-thiolmethyl butyric acid, a putative alkoxyl radical scavenger and by vitamin E, probucol and diphenylphenylenediamine, putative scavengers of peroxyl radicals was consistent with the involvement of these radicals in the lethal sequence. Cell death was thus postulated to occur due to lipid peroxidation via a sequence involving lipid hydroperoxide-induced, iron-mediated formation of alkoxyl, lipid, and peroxyl radicals. Pathways involving other reactive oxygen species, new protein synthesis, or altered cholesterol metabolism were considered less likely, since putative inhibitors failed to lessen toxicity. Understanding the mechanism of cell injury by oxidized LDL and its toxic moiety, 7 beta-OOH chol, may indicate specific interventions in the cell injury believed to accompany vascular lesion development.