Some properties of mitochondrial glutathione.

1. The presence of GSH in rat liver mitochondria is confirmed. GSH diffuses from the suspended particles in the presence of phosphate but respiratory inhibitors inhibit the diffusion. 2. GSH is oxidised in situ by oxidants including t-butyl hydroperoxide. The products formed include GSSG and GSS-protein mixed disulphides. The oxidation occurs at lower oxidant concentrations if phosphate or oxaloacetate are also present. Respiratory inhibitors abolish their effect. 3. With phosphate, the GSSG produced is found chiefly outside the mitochondria whereas with oxaloacetate, it is found chiefly inside. 4. The GSSG formed by the oxidation is reduced by Krebs-cycle acids with the exception of the ketoacids. Exogenous GSSG is reduced by these substrates only after lysis. Intact particles, however, catalyse the reduction of GSSG by either NADH2 or NADPH2.     

Glutathione oxidation and activation of pentose phosphate cycle during hydroperoxide metabolism. A comparison of livers from fed and fasted rats

Perfusion of livers from fed and fasted rats with 0.07--0.1 mM t-butyl hydroperoxide for 15 min decreased the levels of reduced glutathione (GSH) by 1.5 mumol/g liver in both nutritional states. Glutathione disulfide (GSSG) was increased by 70 and 140 nmol/g liver and glutathione mixed disulfides enhanced by 45 and 150 nmol/g liver in livers from fed and fasted animals, respectively. The ratio of GSH/GSSG was decreased from 243 to 58 in fed animals, and from 122 to 8 in fasted animals. The increase of GSSG and the mixed disulfides was nearly parallel until an apparently critical low GSH content of 1.5 mumol/g was reached. Only in livers from fasted rats 14CO2-production from [1-14C]glucose was stimulated upon t-butyl hydroperoxide infusion at the employed rates. Flux of glucose through pentose phosphate cycle rose from 8 to 12% of glucose utilization via glycolysis, whereas in livers from fed animals this portion remained unchanged at 8% Dithio-erythritol reversed pentose phosphate cycle activity as well as GSSG and protein-bound glutathione contents to the original levels. In livers from fasted rats the activity of glucose-6-phosphate dehydrogenase was increased by 34% by t-butyl hydroperoxide infusion.     

Glutathione disulfide reduction in tumor mitochondria after t-butyl hydroperoxide treatment.

Treatment of isolated mitochondria from rat hepatoma tumor cells (AS-30D) with the oxidant, t-butyl hydroperoxide (tBuOOH, 1 or 5 mumol/ml) resulted in the oxidation of glutathione (GSH to GSSG) and the formation of protein-glutathione mixed disulfides (ProSSG). The GSSG was retained inside of the hepatoma mitochondria. In the presence of ADP+succinate (5 or 10 mM), or ketoglutarate (10 mM) or malate (5 mM), the GSSG was reduced to GSH, but the amount of ProSSG stayed constant. With saline or ADP+glutamate (10 mM)/malate (0.1 mm) no reduction of GSSG to GSH occurred. The presence of antimycin (5 micrograms/ml) with ADP+succinate inhibited reduction. At a concentration of 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU, 0.5 mM) which inhibited a major portion of the glutathione reductase activity, the reduction of GSSG to replenish GSH was also inhibited. NADPH may play a critical role as well, for the addition of 2.4 mM NADPH to permeabilized hepatoma mitochondria fostered the reduction of GSSG after tBuOOH treatment. Therefore, hepatoma mitochondria possess a glutathione reductase-dependent system to reduce GSSG to GSH. The reaction only occurs with actively respiring mitochondria.     

Relation between glutathione redox changes and biliary excretion of taurocholate in perfused rat liver

The influence of the intracellular glutathione status on bile acid excretion was studied in the perfused rat liver. Perturbation of the thiol redox state by short term additions of diamide (100 microM) or hydrogen peroxide (250 microM) or t-butyl hydroperoxide (250 microM) led to a reversible inhibition of biliary taurocholate release without affecting hepatic uptake; inhibition amounted to 45% for diamide and 90% for the hydroperoxides. Concomitantly, the bile acid accumulated intracellularly. Bile flow increased from 1.3 to 2.0 microliters X min-1 X g liver-1 upon infusion of taurocholate (10 microM); the latter value was suppressed to 1.2 microliters X min-1 X g liver-1 by the addition of t-butyl hydroperoxide (250 microM). Similarly, the hepatic disposition of another bile constituent, bilirubin, was suppressed by 70% upon addition of hydrogen peroxide. While the addition of hydrogen peroxide inhibited also the endogenous release of bile acids almost completely, endogenous bile flow was much less affected, decreasing from 1.3 to 1.0 microliters X min-1 X g liver-1. Measurement of [14C]erythritol clearance showed bile/perfusate ratios of about unity both in the absence and presence of hydrogen peroxide, suggesting canalicular origin of the bile under both conditions. In livers from Se-deficient rats low in Se-GSH peroxidase (less than 5% of controls), hydrogen peroxide inhibited taurocholate transport substantially less, providing evidence for the involvement of glutathione in mediating the inhibition observed in normal livers. The percentage inhibition of taurocholate release and intracellular glutathione disulfide (GSSG) content were closely correlated. The addition of t-butyl hydroperoxide caused a several-fold increase of biliary GSSG release, whereas biliary GSH release was even decreased. The results establish a role of glutathione in canalicular taurocholate disposition.     

Adaptation of subcellular glutathione detoxification system to stress conditions in choline-deficient diet induced rat fatty liver

The response of fatty liver to stress conditions (t-butyl hydroperoxide [t-BH] or 36 h of fasting) was investigated by assessing intracellular glutathione (GSH) compartmentation and redox status, GSH peroxidase (GSH-Px) and reductase (GSSG-Rx) activities, lipid peroxidation (TBARs) and serum ALT levels in rats on a choline-deficient diet. Baseline cytosolic GSH was similar between fatty and normal livers, while the mitochondrial GSH content was significantly lower in fatty livers. With the except of cytosolic GSH-Px activity, steatosis was associated with significantly higher GSH-related enzymes activities. Liver TBARs and serum ALT levels were also higher. Administration of t-BH significantly decreased the concentration of cytosolic GSH, increased GSSG levels in all the compartments, and increased TBARs levels in cytosol and mitochondria and serum ALT; all these alterations were more marked in rats with fatty liver. Fasting decreased the concentration of GSH in all the compartments both in normal and fatty livers, increased GSSG, TBARs and ALT levels, and decreased by 50% the activities of GSH-related enzymes. Administration of diethylmaleimide (DEM) resulted in cytosolic and microsomal GSH pool depletion. Administration of t-BH to DEM-treated rats further affected cytosolic GSH and enhanced ALT levels, whereas the application of fasting to GSH depleted rats mainly altered the mitochondrial GSH system, especially in fatty livers. This study shows that fatty livers have a weak compensation of hepatic GSH regulation, which fails under stress conditions, thus increasing the fatty liver's susceptibility to oxidative damage. Differences emerge among subcellular compartments which point to differential adaptation of these organelles to fatty degeneration.     

Effects of t-butyl hydroperoxide on NADPH, glutathione, and the respiratory burst of rat alveolar macrophages

The effects of t-butyl hydroperoxide on glutathione and NADPH and the respiratory burst (an NADPH-dependent function) in rat alveolar macrophages was investigated. Alveolar macrophages were exposed for 15 min to t-butyl hydroperoxide in the presence or absence of added glucose. Cells were then assayed for concanavalin A-stimulated O2 production or for NADPH, NADP, reduced glutathione, glutathione disulfide, glutathione released into the medium and glutathione mixed disulfides. Exposure of rat alveolar macrophages to 1 X 10(-5) M t-butyl hydroperoxide causes a loss of concanavalin A-stimulated superoxide production (the respiratory burst) that can be prevented or reversed by added glucose. Cells incubated without glucose had a higher oxidation state of the NADPH/NADP couple than cells incubated with glucose. With t-butyl hydroperoxide, NADP rose to almost 100% of the NADP + NADPH pool; however, addition of glucose prevented this alteration of the NADPH oxidation state. Cells exposed to 1 X 10(-5) M t-butyl hydroperoxide in the absence of glucose showed a significant increase in the percentage GSSG in the GSH + GSSG pool and increased glutathione mixed disulfides. These changes in glutathione distribution could also be prevented or reversed by glucose. With 1 X 10(-4) M t-butyl hydroperoxide, changes in glutathione oxidation were not prevented by glucose and cells were irreversibly damaged. We conclude that drastic alteration of the NADPH/NADP ratio does not itself reflect toxicity and that significant alteration of glutathione distribution can also be tolerated; however, when oxidative stress exceeds the ability of glucose to prevent alterations in oxidation state, irreversible damage to cell function and structure may occur.     

Retention of oxidized glutathione by isolated rat liver mitochondria during hydroperoxide treatment

The addition of tert-butyl hydroperoxide (t-BuOOH) to isolated mitochondria resulted in oxidation of approximately 80% of the mitochondrial reduced glutathione (GSH) independently of the dose of t-BuOOH (1-5 mM). Concomitant with the oxidation of GSH inside the mitochondria was the formation of GSH-protein mixed disulfides (protein-SSG), with approximately 1% of the mitochondrial protein thiols involved. A dose-dependent rate of GSH recovery was observed, via the reduction of oxidized GSH (GSSG) and a slower reduction of protein-SSG. Although t-BuOOH administration affected the respiratory control ratio, the mitochondria remained coupled and loss of the matrix enzyme, citrate synthase, was not increased over the control and was less than 3% over 60 min. A slow loss of GSH out of the coupled non-treated mitochondria was not increased by t-BuOOH treatment, in fact, a dose-dependent drop of GSH levels occurred in the medium. However, no GSSG was found outside the mitochondria, indicating the necessary involvement of enzymes in the t-BuOOH-induced conversion of GSH to GSSG. The absence of GSSG in the medium also suggests that, unlike the plasma membrane, the mitochondrial membranes do not have the ability to export GSSG as a response to oxidative stress. Our results demonstrate the inability of mitochondria to export GSSG during oxidative stress and may explain the protective role of mitochondrial GSH in cytotoxicity.     

The role of glutathione in the retention of Ca2+ by liver mitochondria

Concentrations of rhein and nitrofurantoin in the micromolar range induce Ca2+ release and the development of increased inner membrane permeability in liver mitochondria. Both compounds inhibit the mitochondrial glutathione reductase causing a depletion of GSH and an accumulation of GSSG in energized mitochondria. Under these conditions, the compounds also alter the oxidation state of pyridine nucleotides, NADH becoming oxidized while NADPH remains reduced. Using rhein or nitrofurantoin, together with t-butyl-hydroperoxide and beta-hydroxybutyrate, it is possible to selectively alter the NAD/NADH, the NADP/NADPH, and the GSSG/GSH ratios and to determine the effect of these different states on the ability of Ca2+ to produce a permeable inner membrane. No correlation between pyridine nucleotide ratios and sensitivity to Ca2+ was observed. Mitochondria are stable to Ca2+ when the GSH content is high, but become permeable when Ca2+ is present and GSH is converted to GSSG. It is proposed that the GSSG/GSH ratio, by controlling the reduction state of critical sulfhydryl groups, regulates lysophospholipid acyltransferase activity and, therefore, the ability of mitochondria to remain impermeable upon activation of the intramitochondrial Ca2+ requiring phospholipase A2.     

Mitochondria from distinct tissues are differently affected by 17β-estradiol and tamoxifen

This study was aimed to analyse and compare the bioenergetics and oxidative status of mitochondria isolated from liver, heart and brain of ovariectomized rat females treated with 17β-estradiol (E2) and/or tamoxifen (TAM). E2 and/or TAM did not alter significantly the respiratory chain of the three types of mitochondria. However, TAM significantly decreased the phosphorylation efficiency of liver mitochondria while E2 significantly decreased the phosphorylation efficiency of heart mitochondria. E2 also significantly decreased the capacity of heart and liver mitochondria to accumulate Ca(2+) this effect being attenuated in liver mitochondria isolated from E2+TAM-treated rat females. TAM treatment increased the ratio of glutathione to glutathione disulfide (GSH/GSSG) of liver mitochondria. Brain mitochondria from TAM- and E2+TAM-treated females showed a significantly lower GSH/GSSG ratio. However, heart mitochondria from TAM- and E2+TAM-treated females presented a significant decrease in GSSG and an increase in GSH/GSSG ratio. Thiobarbituric acid reactive substances levels were significantly decreased in liver mitochondria isolated from E2+TAM-treated females. Finally, E2 and/or TAM treatment significantly decreased the levels of hydrogen peroxide produced by brain mitochondria energized with glutamate/malate. These results indicate that E2 and/or TAM have tissue-specific effects suggesting that TAM and hormonal replacement therapies may have some side effects that should be carefully considered.     

Kinetics of hydroperoxide degradation by NADP-glutathione system in mitochondria

Hydroperoxide decomposition by the NADP-glutathione system in rat liver mitochondria was analyzed. Mitochondria were found to contain high concentrations of the reduced form of glutathione (GSH) (4.32 +/- 0.50 nmol/mg) and NADPH (4.74 +/- 0.64 nmol/mg), and high activities of glutathione peroxidase and reductase. In the initial phase of the reaction, the rate of hydroperoxide decomposition was proportional to both the GSH level and the activity of GSH peroxidase. However, in the later steady state, the step of NADP reduction was rate-limiting, and the overall reaction rate was independent of the initial concentration of GSH, and activities of glutathione peroxidase and reductase. Some GSH was released from mitochondria during incubation, but the rate of the decomposition could be simply expressed as kappa [GSH]/2, where kappa is the first-order rate constant of the peroxidase and [GSH] is the intramitochondrial level of GSH in the steady state. The rate of the reaction in the steady state was also dependent on the NADPH level, its reciprocal being linearly correlated with [NADPH]-1. The rate of decomposition of hydroperoxide was influenced by the respiratory state. During state 3 respiration, the rate was greatly depressed, but was still considered to exceed by far the rate of physiological generation of hydroperoxide.     

Useful agents for the study of glutathione metabolism in erythrocytes. Organic hydroperoxides

t-Butyl hydroperoxide and cumene hydroperoxide, both known to be substrates for glutathione peroxidase, were used to oxidize erythrocyte GSH. Addition of concentrations of hydroperoxides equimolar with respect to GSH in the erythrocytes or whole blood quantitatively oxidizes GSH in the erythrocytes with a half-time of 4.5s at 37 degrees C and about three times as long at 4 degrees C. In the presence of glucose, normal erythrocytes regenerate all the GSH in about 25min. However, glucose 6-phosphate dehydrogenase-deficient erythrocytes failed to regenerate GSH. Treatment of erythrocytes with hydroperoxides does not affect erythrocyte survival in rabbits. Oxidation of erythrocyte GSH with equimolar concentrations of hydroperoxides does not lead to formation of mixed disulphides of haemoglobin and GSH. The hydroperoxides do not affect erythrocyte glycolytic and hexose monophosphate-shunt-pathway enzymes. Previous studies on transport of GSSG from erythrocytes were confirmed by using t-butyl hydroperoxide to oxidize erythrocyte GSH.     

Effect of t-butyl hydroperoxide on Ca2+ movement in PC12 pheochromocytoma cells

The effect of the oxidant t-butyl hydroperoxide on intracellular free levels of Ca2+ ([Ca2+]i) in PC12 pheochromocytoma cells was examined by using fura-2 as a fluorescent dye. t-Butyl hydroperoxide induced an increase in [Ca2+]i in a concentration-dependent fashion between 50-250 microM with an EC50 of 100 microM. The [Ca2+]i signal consisted of a slow rise and a sustained phase. The response was decreased by 65% by removal of extracellular Ca2+. In Ca(2+)-free medium, pretreatment with 1 microM thapsigargin (an endoplasmic reticulum Ca2+ pump inhibitor) abolished 150 microM t-butyl hydroperoxide-induced [Ca2+]i increase, and conversely, pretreatment with t-butyl hydroperoxide abrogated thapsigargin-induced [Ca2+]i increase. The 150 microM t-butyl hydroperoxide-induced [Ca2+]i increase in Ca2+ medium was reduced by 42 +/- 5% by pretreatment with 0.1 microM nicardipine but not by 10 microM verapamil, nifedipine, nimodipine or diltiazem, or by 50 microM La3+ or Ni2+. Pretreatment with 10 microM t-butyl hydroperoxide for 40 min did not affect 10 microM ATP-induced [Ca2+]i increase. Together, the results show that t-butyl hydroperoxide induced significant [Ca2+]i increase in PC12 cells by causing store Ca2+ release from the thapsigargin-sensitive endoplasmic reticulum pool in an inositol 1,4,5-trisphosphate-independent manner and by inducing Ca2+ influx via a nicardipine-sensitive pathway.     

Changes in oxygen consumption induced by t-butyl hydroperoxide in perfused rat liver. Effect of free-radical scavengers.

The addition of t-butyl hydroperoxide to perfused rat liver elicited a biphasic effect on hepatic respiration. A rapid fall in liver oxygen consumption was initially observed, followed by a recovery phase leading to respiratory rates higher than the initial steady-state values of oxygen uptake. This overshoot in hepatic oxygen uptake was abolished by free-radical scavengers such as (+)-cyanidanol-3 or butylated hydroxyanisole at concentrations that did not alter mitochondrial respiration. (+)-Cyanidanol-3 was also able to facilitate the recovery of respiration, the diminution in the calculated rate of hydroperoxide utilization and the decrease in liver GSH content produced by two consecutive pulses of t-butyl hydroperoxide. It is suggested that the t-butyl hydroperoxide-induced overshoot in liver respiration is related to increased utilization of oxygen for lipid peroxidation as a consequence of free radicals produced in the scission of the hydroperoxide by cellular haemoproteins.     

Energy-linked cardiac transport system for glutathione disulfide

The relationship between the rate of glutathione disulfide (GSSG) export and the energy state was studied in isolated perfused rat heart. The intracellular GSSG level was maintained at saturation for transport (7.5 nmol GSSG X min-1 X g heart-1) by continuous perfusion with 20 microM t-butyl hydroperoxide. GSSG release was substantially restricted upon the addition of inhibitors of mitochondrial respiration such as KCN, antimycin A or rotenone. In contrast, no effect was observed on GSSG release during potassium-induced cardiac arrest, although changes in oxygen consumption and coronary flow were similar to those observed with KCN. The dependence of the GSSG transport rate on the cytosolic free ATP/ADP ratio reveals that GSSG transport is half-maximal at (ATP/ADP)free approximately equal to 10. The capacity of GSSG transport was unchanged by infusion of epinephrine, norepinephrine or dibutyryl cyclic AMP.     

Peroxidative injury of the mitochondrial respiratory chain during reperfusion of hypothermic rat liver

Mitochondrial dysfunction in ischemic liver has been demonstrated to be due to decrease in the intramitochondrial level of ATP and the subsequent disruption of the proton barrier of the inner membrane (Watanabe, F., Hashimoto, T. and Tagawa, K. (1985) J. Biochem. 97, 1229-1234). In this study, another injury process, impairment of the electron-transfer system, which occurred during reoxygenation of ischemic liver, was studied during reperfusion of cold preserved liver and during cold incubation of isolated rat-liver mitochondria. The sites of the respiratory chain that were sensitive to peroxidative damage were ubiquinone-cytochrome c oxidoreductase and NADH-ubiquinone oxidoreductase. These enzymic activities decreased with increase in lipid peroxidation. Incubation of submitochondrial particles with t-butyl hydroperoxide or with an NADPH-dependent peroxidation system decreased the enzymic activities of the electron-transport system. These data strongly suggested that lipid peroxidation during reoxygenation of ischemic liver impaired the electron-transfer system. Thus, mitochondria of ischemic liver suffer from two different types of injury: increase in proton permeability during anoxia, and decrease in enzymic activities of the electron-transport system during reoxygenation.     

Inactivation of 2-oxoglutarate dehydrogenase in rat liver mitochondria by its substrate and t-butyl hydroperoxide

Ketoacid oxidation in rat liver mitochondria was very sensitive to t-butyl hydroperoxide (t-BuOOH). Furthermore, 2-oxoglutarate and pyruvate each enhanced t-BuOOH-induced oxidative stresses of mitochondria, such as oxidation of pyridine nucleotides and GSH, inhibition of respiration with the other NAD-linked substrates, and peroxidation of mitochondrial lipids. We provide evidence that the t-BuOOH and ketoacid-induced effects are due to the failure of supply of NADH by 2-oxoglutarate dehydrogenase, and report the inactivation of the dehydrogenase in mitochondria by simultaneous addition of 2-oxoglutarate and t-BuOOH. Using the purified enzyme, we confirmed that t-BuOOH-induced inactivation of 2-oxoglutarate dehydrogenase was enhanced by its substrate and thiamine pyrophosphate protected the dehydrogenase from the inactivation. In contrast, succinate-dependent oxidation of mitochondria was not only scarcely affected by t-BuOOH, but also succinate protected against inactivation of 2-oxoglutarate dehydrogenase by t-BuOOH in mitochondria.     

On-column preconcentration of glutathione and glutathione disulfide using pH-mediated base stacking for the analysis of microdialysis samples by capillary electrophoresis

Capillary electrophoresis (CE) has become a useful analytical tool for the analysis of microdialysis samples. However, CE with UV detection (CE-UV) does not provide detection limits sufficient to quantify glutathione (GSH) and glutathione disulfide (GSSG) in biological samples such as liver microdialysates, because of the small optical path length in the capillary. To overcome this limitation, an on-column preconcentration technique, pH-mediated base stacking, was used in this study to improve the sensitivity of CE-UV. This stacking technique allowed large volumes of high ionic strength sample injection without deterioration of the separation efficiency and resolution. A 26-fold increase in sensitivity was achieved for both GSH and GSSG using the pH-mediated base stacking, relative to normal injection without stacking. The limit of detection for GSH and GSSG was found to be 0.75 microM (S/N=6) and 0.25 microM (S/N=6), respectively. The developed method was used to analyze GSH and GSSG in liver microdialysates of anesthetized Sprague Dawley male rats. The basal concentrations of GSH and GSSG in the liver microdialysates of male rats were found to be 4.73+/-2.08 microM (n=7) and 5.52+/-3.66 microM (n=7), respectively.     

Regulation of mitochondrial glutathione redox status and protein glutathionylation by respiratory substrates

Brain and liver mitochondria isolated by a discontinuous Percoll gradient show an oxidized redox environment, which is reflected by low GSH levels and high GSSG levels and significant glutathionylation of mitochondrial proteins as well as by low NAD(P)H/NAD(P) values. The redox potential of brain mitochondria isolated by a discontinuous Percoll gradient method was calculated to be -171 mV based on GSH and GSSG concentrations. Immunoblotting and LC/MS/MS analysis revealed that succinyl-CoA transferase and ATP synthase (F(1) complex, α-subunit) were extensively glutathionylated; S-glutathionylation of these proteins resulted in a substantial decrease of activity. Supplementation of mitochondria with complex I or complex II respiratory substrates (malate/glutamate or succinate, respectively) increased NADH and NADPH levels, resulting in the restoration of GSH levels through reduction of GSSG and deglutathionylation of mitochondrial proteins. Under these conditions, the redox potential of brain mitochondria was calculated to be -291 mV. Supplementation of mitochondria with respiratory substrates prevented GSSG formation and, consequently, ATP synthase glutathionylation in response to H(2)O(2) challenges. ATP synthase appears to be the major mitochondrial protein that becomes glutathionylated under oxidative stress conditions. Glutathionylation of mitochondrial proteins is a major consequence of oxidative stress, and respiratory substrates are key regulators of mitochondrial redox status (as reflected by thiol/disulfide exchange) by maintaining mitochondrial NADPH levels.     

Antioxidant capacity of desferrioxamine in biological systems

The antioxidant capacity of desferrioxamine (DF) was investigated in three biological systems. The addition of DF to rat brain homogenates undergoing autoxidation elicited a concentration dependent inhibition of both oxygen uptake and chemiluminescence, with a median inhibitory concentration (IC50) of 0.52 microM. In this system, Fe3+-induced light emission was completely abolished at a DF/Fe3+ molar ratio of 0.6. In rat erythrocyte suspensions supplemented with t-butyl hydroperoxide, DF lengthened the induction period and decreased the rate of oxygen consumption, with an IC50 of 300 microM. Infusion of increasing concentrations of DF to the perfused rat liver elicited a progressive decrease in the rate of oxygen consumption, with no alterations in the mitochondrial respiration. This DF-sensitive respiration has a maximal value of 200 nmol/g of liver/min, with a half-maximal rate at 120 microM DF. These results indicate that DF behaves as an efficient antioxidant either under basal conditions or in chemically-induced oxidative stress, through Fe3+ chelating and/or free-radical scavenging effects.     

Hydroperoxide-metabolizing systems in rat liver.

1. Metabolism of added hydroperoxides was studied in hemoglobin-free perfused rat liver and in isolated rat hepatocytes as well as microsomal and mitochondrial fractions. 2. Perfused liver is capable of removing organic hydroperoxides [cumene and tert-butyl hydroperoxide] at rates up to 3--4 mumol X min-1 X gram liver-1. Concomitantly, there is a release of glutathione disulfide (GSSG) into the extracellular space in a relationship approx. linear with hydroperoxide infusion rates. About 30 nmol GSSG are released per mumol hydroperoxide added per min per gram liver. GSSG release is interpreted to indicate GSH peroxidase activity. 3. GSSG release is observed also with added H2O2. At rates of H2O2 infusion of about 1.5 mumol X min-1 X gram liver-1 a maximum of GSSG release is attained which, however, can be increased by inhibition of catalase with 3-amino-1,2,4-aminotriazole. 4. A contribution of the endoplasmic reticulum in addition to glutathione peroxidase in organic hydroperoxide removal is demonstrated (a) by comparison of perfused livers from untreated and phenobarbital-pretreated rats and (b) in isolated microsomal fractions, and a possible involvement of reactive iron species (e.g. cytochrome P-450-linked peroxidase activity) is discussed. 5. Hydroperoxide addition to microsomes leads to rapid and substantial lipid peroxidation as evidenced by formation of thiobarbituric-acid-reactive material (presumably malondialdehyde) and by O2 uptake. Like in other types of induction of lipid peroxidation, malondialdehyde/O2 ratios of 1/20 are observed. Cumene hydroperoxide (0.6 mM) gives rise to 4-fold higher rates of malondialdehyde formation than tert-butyl hydroperoxide (1 mM). Ethylenediamine tetraacetate does not inhibit this type of lipid peroxidation. 6. Lipid peroxidation in isolated hepatocytes upon hydroperoxide addition is much lower than in isolated microsomes or mitochondria, consistent with the presence of effective hydroperoxide-reducing systems. However, when NADPH is oxidized to the maximal extent as evidenced by dual-wavelength spectrophotometry, lipid peroxidation occurs at large amounts. 7. A dependence of hydroperoxide removal rates upon flux through the pentose phosphate pathway is suggested by a stimulatory effect of glucose in hepatocytes from fasted rats and by an increased rate of 14CO2 release from [1-14C]glucose during hydroperoxide metabolism in perfused liver.