Involvement of iron and iron-catalyzed free radical production in ethanol metabolism and toxicity

Lipoperoxidation, a degradative process of membranous polyunsaturated fatty acids, has been suggested to represent an important mechanism in the pathogenesis of ethanol toxicity on the liver and possibly also on the brain. Catalysis by transition metals, especially iron, is involved in the biosynthesis of free radicals contributing to lipid peroxidation. Although the exact nature of the redox-active iron implicated in this catalysis is still unknown, it has been well established that lipid peroxidation can be prevented in vitro by iron chelators such as desferrioxamine. Deprivation of redox-active iron through desferrioxamine inhibits by about 50% the microsomal oxidation of ethanol in vitro and reduces very significantly in vivo the overall ethanol elimination rate in rats. Administration of desferrioxamine together with ethanol also reduces the ethanol-induced disturbances in the antioxidant defense mechanisms of the hepatocyte. It also reduces in mice both the severity of physical dependence on ethanol and lethality following the acute administration of a narcotic dose of ethanol. Chronic overloading of rats with iron results, on the opposite, in an increased rate of ethanol elimination, although alcohol dehydrogenase and catalase activities are reduced and cytochrome P-450 depleted in the liver of such iron-overloaded animals. The magnitude of the ethanol-induced increase in lipid peroxidation and decrease in the major membranous antioxidant, alpha-tocopherol, is exacerbated in iron-overloaded rats. Several disturbances of iron metabolism have been reported in human alcoholics. Their contribution to ethanol toxicity appears very likely in the case of hepatic siderosis associated with alcohol abuse. Ethanol could however disturb iron metabolism even in the absence of gross abnormalities of the total iron stores. It is suggested that ethanol intoxication could increase cellular redox-active iron, thus contributing to an enhanced steady-state concentration of reactive-free radicals. This oxidative stress would lead to lipoperoxidative damage and cellular injury.     

Metabolism of hepatic and plasma triglycerides in rabbits given ethanol or ethionine

The formation and transport of hepatic triglyceride fatty acids (TGFA) were studied after intravenous administration of palmitate-1-(14)C or palmitate-9,10-(3)H in rabbits pretreated with ethanol or ethionine. Administration of ethanol produced significant hypertriglyceridemia without consistent accumulation of hepatic fat. The isotopic studies suggest that plasma free fatty acids were the major precursors of TGFA in d < 1.006 lipoproteins and that fatty acids synthesized in the liver were not the source of the hypertriglyceridemia in the ethanol-treated animals. Administration of ethionine resulted in an increased concentration of TGFA in the liver, a decreased level of TGFA in d < 1.006 lipoproteins and a very low specific activity in this plasma fraction. These findings suggest that the development of fatty liver after administration of ethionine is in part accompanied by impaired release of TGFA from the liver.     

Sonochemical free radical formation in aqueous solutions

The phenomena of stable and transient acoustic cavitation in liquids exposed to ultrasound are briefly explained. The role of micronuclei, resonant bubble size, and rectified diffusion in the initiation of transient cavitation is reviewed. In aqueous solutions transient cavitation initially generates hydrogen atoms and hydroxyl radicals that may recombine to form hydrogen and H2O2 or may react with solutes in the gas phase, at the gas-liquid boundary, or in the bulk of the solution. The analogies and differences between sonochemistry and ionizing radiation chemistry are explored. The use of spin trapping and electron spin resonance to conclusively identify hydrogen atoms and hydroxyl radicals and to detect cavitation produced by continuous wave and by pulsed ultrasound is described in detail.     

Mitochondrial free radical production and cell signaling

Mitochondria were classically recognized as the organelles that produce the energy required to drive the endergonic processes of cell life, but now they are considered as the most important cellular source of free radicals, as the main target for free radical regulatory and toxic actions, and as the source of signaling molecules that command cell cycle, proliferation and apoptosis. The progress in the knowledge of mitochondrial functions in the last decades is reviewed. The mitochondrial production of the primary free radicals superoxide anion (O(2)(-)) and nitric oxide (NO), as well as of the termination products H(2)O(2) (hydrogen peroxide) and peroxynitrite (ONOO(-)), is described. A network of intramitochondrial antioxidants consisting of the enzymes Mn-superoxide dismutase and glutathione peroxidase and of the reductants NADH(2), ubiquinol and reduced glutathione, is operative in minimizing the potentially harmful effects of O(2)(-), NO, H(2)O(2) and ONOO(-). Nitric oxide and H(2)O(2) participate in cell signaling, through narrow concentration ranges that signal for opposite cellular situations, i.e., proliferation or apoptosis. A mechanism involving mitogen-activated protein kinases is described. The role of mitochondria in apoptosis is well established through the mitochondrion-dependent pathways of cell death, that includes increased NO production, loss of membrane potential, appearance of dysfunctional mitochondria, cytochrome c release and opening of the voltage-dependent anion channel of the outer membrane.     

Tannic acid inhibits in vitro iron-dependent free radical formation

The antioxidant activity of tannic acid (TA), a plant polyphenol claimed to possess antimutagenic and anticarcinogenic activities, was studied by monitoring (i) 2-deoxyribose degradation (a technique for OH detection), (ii) ascorbate oxidation, (iii) ascorbate radical formation (determined by EPR analysis) and (iv) oxygen uptake induced by the system, which comprised Fe(III) complexes (EDTA, nitrilotriacetic acid (NTA) or citrate as co-chelators), ascorbate and oxygen. TA removes Fe(III) from the co-chelators (in the case of EDTA, this removal is slower than with NTA or citrate), forming an iron-TA complex less capable of oxidizing ascorbate into ascorbate radical or mediating 2-deoxyribose degradation. The effectiveness of TA against 2-deoxyribose degradation, ascorbate oxidation and ascorbate radical formation was substantially higher in the presence of iron-NTA (or iron-citrate) than with iron-EDTA, which is consistent with the known formation constants of the iron complexes with the co-chelators. Oxygen uptake and 2-deoxyribose degradation induced by Fe(II) autoxidation were also inhibited by TA. These results indicate that TA inhibits OH formation induced by Fe(III)/ascorbate/O(2) mainly by arresting Fe(III)-induced ascorbate oxidation and Fe(II) autoxidation (which generates Fe(II) and H(2)O(2), respectively), thus limiting the production of Fenton reagents and OH formation. We also hypothesize that the Fe(II) complex with TA exhibits an OH trapping activity, which explains the effect of TA on the Fenton reaction.     

Comparative toxicity of alkyl-1,4-naphthoquinones in rats: Relationship to free radical production in vitro

2-Methyl-1,4-naphthoquinone causes haemolysis in vivo. This toxic effect is believed to result from oxidative damage to erythrocytes by “active oxygen” species formed via one-electron reduction of the naphthoquinone by oxyhaemoglobin. In the present investigation, seven 2-alkyl-1,4-naphthoquinones have been studied with regard to their haemolytic activity in rats, their ability to cause oxidative damage in erythrocytes in vitro, and their reactivity toward oxyhaemoglobin. A close correlation was observed between the in vivo and in vitro parameters, suggesting that the proposed mechanism of toxicity of 2-methyl-1,4-naphthoquinone is correct and is also applicable to other alkylnaphthoquinones.     

Ascorbyl free radical and dehydroascorbate formation in rat liver endoplasmic reticulum

The mechanism of ascorbate oxidation was studied in rat liver microsomes. A continuous consumption of the added ascorbate was observed, which was accompanied with a prompt appearance of ascorbyl free radical and dehydroascorbate. Microsomes sustained steady-state level of ascorbyl free radical and dehydroascorbate till ascorbate was present in the medium. Ascorbyl free radical formation was diminished when microsomes had been pretreated with heat or trypsine. It was also decreased by addition of quercetin, econazole or metal chelators, including the copper specific neocuproine. Enzymatic (superoxide dismutase, catalase) and nonenzymatic (dimethyl sulfoxide, mannitol) antioxidants did not modify the microsomal production of ascorbyl free radical. Investigation of the subcellular distribution of ascorbate oxidation showed that the microsomal fraction of liver had the highest activity. The decrease of ascorbate oxidation after protease treatment and the negligible increase upon permeabilization of microsomal vesicles showed that a membrane protein is responsible for the activity, which is exposed to the outer surface of the endoplasmic reticulum. The results indicate the presence of a primary enzymatic ascorbate oxidation in rat liver endoplasmic reticulum which is able to generate dehydroascorbate, an important source of the oxidizing environment in the endoplasmic reticulum.     

The involvement of ethanol in the free radical reaction of 6-hydroxydopamine

ESR spin trapping technique was used to detect and analyze free radical formation. When 6-hydroxydomine (6-OHDA) was incubated alone or in the presence of a free radical generating system (H₂O₂ and FeSO₄), hydroxyl free radicals were observed in a concentration-dependent manner. Glutathione was found to be the most effective scavenger of the ESR signal when compared with vitamin E or Mannitol. The addition of ethanol resulted in the formation of the pure hydroxyethyl free radicals. The amount of hydroxyethyl free radicals in the system was dependent upon the concentration of ethanol and the formation of hydroxyethyl free radicals correlated well with the extent of lipid peroxidation and the loss of enzymic activity of the membrane-bound (Na⁺, K⁺)-ATPase. We suggest that in the biological system ethanol may potentiate the neurotoxicity of 6-OHDA with the formation of hydroxyethyl free radicals, which are longer-lived and far more damaging to membranes that the hydroxyl radicals. These data lead us to further hypothesize that the neuronal degeneration caused by 6-OHDA and other compounds that generate free radicals could be potentiated in the presence of ethanol.     

Hydroxyl free radical production in iron-cysteine solutions and protection by zinc

Hydroxyl radicals (OH^?) can be formed on incubation of an oxygenated solution of ferrous sulphate and cysteine. This has been demonstrated by esr using the spin trap DMPO (5,5-dimethyl-1-pyrroline-1-oxide), catalase, and the radical scavengers ethanol and propan-2-ol. Hydroxyl radicals are not formed when excess zinc sulphate is present. These results provide support for the pro-oxidant action of iron and cysteine and a possible protective role for zinc.     

The participation of coenzyme Q in free radical production and antioxidation

Published experimental data pertaining to the participation of coenzyme Q as a site of free radical formation in the mitochondrial electron transfer chain and the conditions required for free radical production have been reviewed critically. The evidence suggests that a component from each of the mitochondrial NADH-coenzyme Q, succinate-coenzyme Q, and coenzyme QH₂-cytochrome c reductases (complexes I, II, and III, most likely a nonheme iron-sulfur protein of each complex, is involved in free radical formation. Although the semiquinone form of coenzyme Q may be formed during electron transport, its unpaired electron most likely serves to aid in the dismutation of superoxide radicals instead of participating in free radical formation. Results of studies with electron transfer chain inhibitors make the conclusion dubious that coenzyme Q is a major free radical generator under normal physiological conditions but may be involved in superoxide radical formation during ischemia and subsequent reperfusion. Experiments at various levels of organization including subcellular systems, intact animals, and human subjects in theclinical setting, support the view that coenzyme Q, mainly in its reduced state, may act as an antioxidant protecting a number of cellular membranes from free radical damage.     

Enhanced intraarticular free radical reactions in adjuvant arthritis rats

One of the reasons of rheumatoid arthritis (RA) development is widely recognized the relation of free radical reactions in tissue injuries. The aim of this study was to evaluate the location where in vivo free radical reactions was enhanced in adjuvant arthritis (AA) model rats using in vivo electron spin resonance (ESR)/nitroxyl spin probe technique. The signal decay after intravenous injection of spin probe was enhanced in AA than that in control and suppressed by the pre-treatment of dexamethasone (DXT). Interestingly, the decay in joint cavity occurred prior to paw swelling of AA and suppressed by a simultaneous injection of free radical scavengers, indicating that the enhancement of free radical reactions in joint cavity of AA rats. This technique would be useful tool to determine the location of the enhanced free radical reactions and evaluate the activity of antioxidant medicine with non-invasive real-time measurement.     

Enhanced intraarticular free radical reactions in adjuvant arthritis rats

One of the reasons of rheumatoid arthritis (RA) development is widely recognized the relation of free radical reactions in tissue injuries. The aim of this study was to evaluate the location where in vivo free radical reactions was enhanced in adjuvant arthritis (AA) model rats using in vivo electron spin resonance (ESR)/nitroxyl spin probe technique. The signal decay after intravenous injection of spin probe was enhanced in AA than that in control and suppressed by the pre-treatment of dexamethasone (DXT). Interestingly, the decay in joint cavity occurred prior to paw swelling of AA and suppressed by a simultaneous injection of free radical scavengers, indicating that the enhancement of free radical reactions in joint cavity of AA rats. This technique would be useful tool to determine the location of the enhanced free radical reactions and evaluate the activity of antioxidant medicine with non-invasive real-time measurement.     

Accelerated clearance of plasma triglycerides and free fatty acids in omega3-depleted rats.

The present study aims mainly at exploring the effects of a severe depletion in polyunsaturated long-chain omega3 fatty acids upon the fate of circulating lipids. The plasma concentration and fatty acid pattern of triglycerides, diglycerides, free fatty acids, and phospholipids were measured in omega3-depleted and control rats injected intravenously one hour before sacrifice with either saline, a control medium-chain triglyceride:olive oil emulsion or a medium-chain triglyceride:fish oil emulsion recently found to rapidly increase the phospholipid content of C20:5omega3 and C22:6omega3 in different cell types. The estimated fractional removal rate of the injected triglycerides and the clearance of free fatty acids from circulation were both higher in omega3-depleted rats than in control animals. The injection of the lipid emulsions apparently inhibited intracellular lipolysis, this being least pronounced in omega3-depleted rats. The increased clearance of circulating triglycerides and unesterified fatty acids in omega3-depleted rats may favor the cellular accumulation of lipids. In turn, such an accumulation and the lesser regulatory inhibition of tissular lipolysis may match the increased clearance of circulating unesterified fatty acids and, hence, account for the lack of any significant difference in plasma unesterified fatty acid concentration between these and control animals.     

Anti-CD11d antibody treatment reduces free radical formation and cell death in the injured spinal cord of rats

Treatment with a monoclonal antibody (mAb) against the CD11d subunit of the leukocyte integrin CD11d/CD18 after spinal cord injury (SCI) decreases intraspinal inflammation and oxidative damage, improving neurological function in rats. In this study we tested whether the anti-CD11d mAb treatment reduces intraspinal free radical formation and cell death after SCI. Using clip-compression SCI in rats, reactive oxygen species (ROS) generated in injured spinal cord were detected using 2',7'-dichlorofluorescin-diacetate and hydroethidine as fluorescent probes. ROS in the injured cord increased significantly after SCI; anti-CD11d mAb treatment significantly reduced this ROS formation. Immunohistochemistry and western blotting were employed to assess the effects of anti-CD11d mAb treatment on spinal cord expression of gp91Phox (a subunit of NADPH oxidase producing superoxide) on formation of 4-hydroxynonenal (HNE, indicating lipid peroxidation) and on expression of caspase-3. We also assessed effects on cell death, determined by cell morphology. The expression of gp91Phox, formation of HNE, and cell death increased after SCI. Anti-CD11d mAb treatment clearly attenuated these responses. In conclusion, anti-CD11d mAb treatment significantly reduces intraspinal free radical formation caused by infiltrating leukocytes after SCI, thereby reducing secondary cell death. These effects likely underlie tissue preservation and improved neurological function that result from the mAb treatment.     

Kinetics of anthracycline antibiotic free radical formation and reductive glycosidase activity

Adriamycin free radical anion concentrations have been correlated with production of 7-deoxyadriamycin aglycone in a reaction catalyzed by NADPH-cytochrome c reductase. The free radical species is detected by electron spin resonance (ESR) spectroscopy and quantified by double integrations. The 7-deoxyaglycone product is isolated by thin-layer chromatography (TLC) and quantified by fluorometry. As the concentration of adriamycin increases, a concomitant increase in aglycone and free radical levels occurs. These results as well as those with inhibitors Vitamin K₃, Vitamin E, and 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) point to an obligatory free radical intermediate in the metabolism of adriamycin. DMPO inhibits the reaction under aerobic conditions only, and shows no effect under anaerobiosis at the concentrations studied here. Vitamin E and aerobic DMPO act as free radical scavangers, while Vitamin K₃ competes for the reducing power of NADPH in the NADPH-cytochrome c reductase system.