Effect of low flow ischemia-reperfusion injury on liver function

The release of liver enzymes is typically used to assess tissue damage following ischemia-reperfusion. The present study was designed to determine the impact of ischemia-reperfusion on liver function and compare these findings with enzyme release. Isolated, perfused rat livers were subjected to low flow ischemia followed by reperfusion. Alterations in liver function were determined by comparing rates of oxygen consumption, gluconeogenesis, ureagenesis, and ketogenesis before and after ischemia. Lactate dehydrogenase (LDH) and purine nucleoside phosphorylase (PNP) activities in effluent perfusate were used as markers of parenchymal and endothelial cell injury, respectively. Trypan blue staining was used to localize necrosis. Total glutathione (GSH + GSSG) and oxidized glutathione (GSSG) were measured in the perfusate as indicators of intracellular oxidative stress. LDH activity was increased 2-fold during reperfusion compared to livers kept normoxic for the same time period whereas PNP activity was elevated 5-fold under comparable conditions. Rates of oxygen consumption, gluconeogenesis, and ureagenesis were unchanged after ischemia, but ketogenesis was decreased 40% following 90 min ischemia. During reperfusion, the efflux rates of total glutathione and GSSG were unchanged from pre-ischemic values. Significant midzonal staining of hepatocyte nuclei was observed following ischemia-reperfusion, whereas normoxic livers had only scattered staining of individual cells. Reperfusion of ischemic liver caused release of hepatic enzymes and midzonal cell death, however, several major liver functions were unaffected under these experimental conditions. These data indicate that there were negligible changes in liver function in this model of ischemia and reperfusion despite substantial enzyme release from the liver and midzonal cell death.     

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.     

Influence of selenium deficiency on glutathione disulfide metabolism in isolated perfused rat heart

Selenium deficiency causes a fall in rat cardiac glutathione peroxidase activity. As a consequence, isolated perfused selenium-deficient heart does not release increased amounts of GSSG when hydroperoxide is infused. However, the total amount of glutathione measured as intracellular GSH, intracellular GSSG and GSSG released from the heart when hydroperoxide is infused does not equal the total glutathione measured in these pools in untreated hearts (Xia, Y., Hill, K.E. and Burk, R.F. (1985) J. Nutr. 115, 733-742). GSSG can react with protein sulfhydryl groups to form glutathione-protein mixed disulfides (PrS-SG). PrS-SG were measured in perfused selenium-deficient and control hearts infused with t-butylhydroperoxide and were found to account for the previously unmeasured glutathione. The ability of the selenium-deficient heart to transport GSSG was also examined. GSSG was produced non-enzymatically by infusing diamide. The diamide-treated selenium-deficient heart formed GSSG and released it at the same rate as similarly-treated control heart. Thus although selenium deficiency decreases GSSG formation by glutathione peroxidase, it does not affect cardiac GSSG transport.     

Hypoxic damage generates reactive oxygen species in isolated perfused rat liver

The aim of the present study was to investigate the possible role of reactive oxygen species in the pathogenesis of hypoxic damage in isolated perfused rat liver. One hour of hypoxia caused severe cell damage (lactate dehydrogenase release of greater than 12,000 mU/min/g liver wt) and total irreversible cholestasis which was accompanied by a loss of cellular ATP and a marked decrease in lactate efflux. Tissue glutathione disulfide (GSSG) content and GSSG efflux as a measure of hepatic reactive oxygen formation was less than 1% of total glutathione before and during hypoxia. Upon reoxygenation, however, hepatic GSSG content increased sharply to about twice the control values and GSSG efflux increased several-fold to around 3-4 nmol GSH-equivalents/min/g. The release of lactate dehydrogenase decreased upon reoxygenation and tissue ATP content recovered partially. When livers were reoxygenated at an earlier time interval than 1 hr of hypoxia, i.e., before the onset of damage, no enhanced GSSG formation was observed. The results demonstrate that hypoxic damage is a prerequisite to reactive oxygen formation during the subsequent reoxygenation period. Thus, reactive oxygen species appear unlikely to play a crucial role in the pathogenesis of hypoxic liver damage in the hemoglobin-free, isolated perfused liver model.     

Role of catalase in metabolism of hydrogen peroxide by the perfused rat heart

Cardiac metabolism of H2O2 was studied by determining the concentration dependence for H2O2-stimulated release of GSSG, an indicator for flux through the glutathione peroxidase pathway, in perfused heart preparations. Treatment of rats with aminotriazole in vivo inhibited heart catalase by 83% and shifted the dose-response curve for GSSG release toward lower H2O2 concentrations. In aminotriazole-treated rats, 50 microM H2O2 elicited a maximal rate of GSSG release (about 5 nmol GSSG/min per g heart), whereas 200 microM H2O2 was necessary for obtaining a similar rate of GSSG release in control rat hearts. The results show that catalase, although present at low levels of activity in the heart compared to other organs, functions as a major route for detoxication of H2O2 in the myocardium.     

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.     

Effects of anisotonicity on pentose-phosphate pathway,oxidized glutathione release and t-butylhydroperoxide-induced oxidative stress in the perfused liver of air-breathing catfish,<Emphasis Type="Italic">Clarias batrachus</Emphasis>

Both hypotonic exposure (185 mOsmol/l) and infusion of glutamine plus glycine (2 mmol/l each) along with the isotonic medium caused a significant increase of¹⁴CO₂ production from [1-¹⁴C]glucose by 110 and 70%, respectively, from the basal level of 18.4 ± 1.2 nmol/g liver/min from the perfused liver ofClarias batrachus. Conversely, hypertonic exposure (345 mOsmol/l) caused significant decrease of¹⁴CO₂ production from [1-¹⁴C]glucose by 34%.¹⁴CO₂ production from [6-¹⁴C]glucose was largely unaffected by anisotonicity. The steady-state release of oxidized glutathione (GSSG) into bile was 1.18 ±0.09 nmol/g liver/min, which was reduced significantly by 36% and 34%, respectively, during hypotonic exposure and amino acid-induced cell swelling, and increased by 34% during hypertonic exposure. The effects of anisotonicity on¹⁴CO₂ production from [1-¹⁴C]glucose and biliary GSSG release were also observed in the presence of t-butylhydroperoxide (50 (Amol/1). The oxidative stress-induced cell injury, caused due to infusion of t-butylhydroperoxide, was measured as the amount of lactate dehydrogenase (LDH) leakage into the effluent from the perfused liver; this was found to be affected by anisotonicity. Hypotonic exposure caused significant decrease of LDH release and hypertonic exposure caused significant increase of LDH release from the perfused liver. The data suggest that hypotonically-induced as well as amino acid-induced cell swelling stimulates flux through the pentose-phosphate pathway and decreases loss of GSSG under condition of mild oxidative stress; hypotonically swollen cells are less prone to hydroperoxide-induced LDH release than hypertonically shrunken cells, thus suggesting that cell swelling may exert beneficial effects during early stages of oxidative cell injury probably due to swelling-induced alterations in hepatic metabolism.     

Protective effect of propionyl-L-carnitine against ischaemia and reperfusion-damage

Summary Reperfusion of isolated rabbit heart after 60 min of ischaemia resulted in poor recovery of mechanical function, release of reduced (GSH) and oxidized glutathione (GSSG), reduction of tissue GSH/GSSG ratio and shift of cellular thiol redox state toward oxidation, suggesting the occurrence of oxidative stress. Pretreatment of the isolated heart with propionyl-L-carnitine (10^–7M) improved the functional recovery of the myocardium, reduced GSH and GSSG release and attenuated the accumulation of tissue GSSG. This effect was specific for propionyl-L-carnitine as L-carnitine and propionyl acid did not modify myocardial damage.     

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.     

Detection of oxidized and reduced glutathione with a recycling postcolumn reaction

A rapid, sensitive, and selective method for the quantitation of both oxidized (GSSG) and reduced (GSH) glutathione in biological materials is described. Oxidized and reduced glutathione are resolved by anion-exchange high-performance liquid chromatography and detected with an in-line, recycling postcolumn reaction. The recycling reaction specifically amplifies the response to oxidized and reduced glutathione 20-100 times over that obtained with a stoichiometric reaction, permitting the detection of 2 pmol glutathione. Oxidized and reduced glutathione levels were measured in rat liver and in dog heart mitochondria. Special precautions are necessary to avoid artifacts which lead to either underestimation or overestimation of GSSG levels. GSH/GSSG ratios of approximately 100-300 were observed in samples prepared from rapidly frozen rat liver. Somewhat higher GSH/GSSG ratios were observed in isolated dog heart mitochondria.     

Effect of anisotonic cell-volume modulation on glutathione-S-conjugate release, t-butylhydroperoxide metabolism and the pentose-phosphate shunt in perfused rat liver.

1. Addition of 1-chloro-2,4-dinitrobenzene to isolated perfused rat liver results in the rapid formation of its glutathione-S-conjugate [S-(2,4-dinitrophenyl)glutathione], which is released into both, bile and effluent perfusate. Anisotonic perfusion did not affect total S-conjugate formation, but release of the S-conjugate into the perfusate was increased (decreased) following hypertonic (hypotonic) exposure at the expense of excretion into bile. Stimulation of S-conjugate release into the perfusate following hypertonic exposure paralleled the time course of volume-regulatory net K+ uptake. 2. Basal steady-state release of oxidized glutathione (GSSG) into bile was 1.30 +/- 0.12 nmol.g-1.min-1 (n = 18) during normotonic (305 mOsmol/l) perfusion and was 3.8 +/- 0.3 nmol.g-1.min-1 in the presence of t-butylhydroperoxide (50 mumol/l). Hypotonic exposure (225 mOsmol/1) lowered both, basal and t-butylhydroperoxide (50 mumol/l)-stimulated GSSG release into bile by 35% and 20%, respectively, whereas hypertonic exposure (385 mOsmol/l) increased. Anisotonic exposure was without effect on t-butylhydroperoxide removal by the liver. GSSG release into bile also decreased by 33% upon liver-cell swelling due to addition of glutamine plus glycine (2 mmol/l, each). 3. Hypotonic exposure led to a persistent stimulation 14CO2 production from [1-14C]glucose by about 80%, whereas 14CO2 production from [6-14C]glucose increased by only 10%. Conversely, hypertonic exposure inhibited 14CO2 production from [1-14C]glucose by about 40%, whereas 14CO2 production from [6-14C]glucose was unaffected. The effect of anisotonicity on 14CO2 production from [1-14C]glucose was also observed in presence of t-butylhydroperoxide (50 mumol/l), which increased 14CO2 production from [1-14C]glucose by about 40%. 4. t-Butylhydroperoxide (50 mumol/l) was without significant effect on volume-regulatory K+ fluxes following exposure to hypotonic (225 mOsmol/l) or hypertonic (385 mOsmol/l) perfusate. Lactate dehydrogenase release from perfused rat liver under the influence of t-butylhydroperoxide was increased by hypertonic exposure compared to hypotonic perfusions. 5. The data suggest that hypotonic cell swelling stimulates flux through the pentose-phosphate pathway and diminishes loss of GSSG under conditions of mild oxidative stress. Hypotonically swollen cells are less prone to hydroperoxide-induced lactate dehydrogenase release than hypertonically shrunken cells. Hypertonic cell shrinkage stimulates the excretion of glutathione-S-conjugates into the sinusoidal circulation at the expense of biliary secretion.     

Dietary supplementation with cysteine prodrugs selectively restores tissue glutathione levels and redox status in protein-malnourished mice(1)

Protein malnutrition (PM) is a major health problem in the world. PM compromises antioxidant defense in the body. In particular, PM decreases tissue glutathione (GSH) levels. A high protein diet was found to restore tissue GSH levels in animal studies, however it is not recommended for the early phase of PM rehabilitation. Therefore, using dietary supplementation to restore tissue GSH without giving a high protein diet may be an adjunct therapy that helps improve antioxidant status during the early rehabilitation of PM. In this study, we systematically compared the efficacy of dietary supplementation of four cysteine prodrugs: N-acetylcysteine, L-2-oxo-4-thiazolidine-carboxylate, methionine, and GSH, on tissue GSH in mice fed a protein-deficient (0.5%) diet. Results showed that dietary supplementation of cysteine prodrugs to PM mice restored GSH levels in liver, lung, heart and spleen, but not in colon. GSH and GSSG levels in brain and kidney were not affected by cysteine prodrug or PM. Supplementation also restored the redox status in liver and heart (based on GSH/GSSG), and in liver and spleen (based on GSSG/2GSH reduction potential). This suggests that the restoration of GSH levels and redox status by cysteine prodrugs are tissue-specific, and that the two indicators of redox status are not always interchangeable. However, all four prodrugs exhibited similar GSH-enhancing capacities, showing no prodrug-specificity as seen in cell culture studies. In conclusion, this study provided information that may be useful in a clinical setting where a short-term oral supplementation of cysteine prodrugs is necessary for the early rehabilitation of PM patients.     

Blood Glutathione as an Index of Radiation-Induced Oxidative Stress in Mice and Humans

The effect of x-rays on GSH and GSSG levels in blood was studied in mice and humans. An HPLC method that we recently developed was applied to accurately determine GSSG levels in blood. The glutathione redox status (GSH/GSSG) decreases after irradiation. This effect is mainly due to an increase in GSSG levels. Mice received single fraction radiotherapy, at total doses of 1.0 to 7.0 Gy. Changes in GSSG in mouse blood can be detected 10 min after irradiation and last for 6 h within a range of 2.0–7.0 Gy. The highest levels of GSSG (20.1 ± 2.9 ), a 4.7-fold increase as compared with controls) in mouse blood are found 2 h after radiation exposure (5 Gy). Breast and lung cancer patients received fractionated radiotherapy at total doses of 50.0 or 60.0 Gy, respectively. GSH/GSSG also decreases in humans in a dose–response fashion. Two reasons may explain the radiation-induced increase in blood GSSG: (a) the reaction of GSH with radiation-induced free radicals resulting in the formation of thyl radicals that react to produce GSSG; and (b) an increase of GSSG release from different organs (e.g., the liver) into the blood. Our results indicate that the glutathione redox ratio in blood can be used as an index of radiation-induced oxidative stress. © 1997 Elsevier Science Inc.     

Properties of glutathione release observed during reduction of organic hydroperoxide, demethylation of aminopyrine and oxidation of some substances in perfused rat liver, and their implications for the physiological function of catalase.

The enhanced reduction of t-butyl hydroperoxide by glutathione peroxidase is accompanied by a decrease in the cellular concentration of both glutathione and NADPH in isolated liver cells, resulting in the release of GSSG (oxidized glutathione) from the perfused rat liver. This phenomenon, first reported by H. Sies, C. Gerstenecker, H. Menzel & L. Flohé (1972) (FEBS Lett. 27, 171-175), can be observed under a variety of conditions, not only with the acceleration of the glutathione peroxidase reaction by organic peroxides, but also during the oxidation of glycollate and benzylamine, during demethylation of aminopyrine in the liver of the phenobarbital-pretreated rat and during oxidation of uric acid in the liver of the starved rat pretreated with 3-amino-1,2,4-triazole. The rate of release of GSSG is altered markedly by changes in the metabolic conditions which affect the rate of hepatic NADPH generation. Thus, regardless of whether achieved by enhanced oxidation of glutathione by glutathione peroxidase or by oxidation of NADPH through other metabolic pathways, an increase in the cellular concentration of GSSG appears to facilitate its release. It has been found that, in addition to the hexose monophosphate shunt, the mitochondrial NADH-NADP+ transhydrogenase reaction plays an important role in supplying reducing equivalents to the glutathione peroxidase reaction and in maintaining the cellular oxidation-reduction state of the nicotinamide nucleotides. Spectrophotometric analysis of the steady-state concentration of the catalase-H2O2 intermediate with simultaneous measurement of the rate of release of GSSG leads to the conclusion that intracellular compartmentation of catalase in the peroxisomes and glutathione peroxidase in the cytosol and mitochondria distinguishes the reactivities of these enzymes one from the other, and facilitates their effective cooperation in hydroperoxide metabolism in the liver.     

A Comparison Between Different Methods for the Determination of Reduced and Oxidized Glutathione in Mammalian Tissues

In this study, three rapid assay techniques for the determination of glutathione, one enzymatic, one flu-orometric and one newly patented colorimetric method, were compared by measuring reduced (GSH) and oxidized (GSSG) glutathione in guinea-pig heart and liver. The HPLC technique was used as a standard, since it is considered the most reliable assay method. In heart, all methods measured the same levels of GSH (about 1 µmole/g wet tissue), whereas in liver the fluorometric assay gave GSH levels about half as high as those measured by the other methods (about 3 vs. 7 µmoles/g wet tissue). Conversely, the fluorometric assay grossly overestimated GSSG concentration (by 5 to 8 times) in both heart and liver. These results confirm previous doubts about the use of the fluorometric technique for GSSC determination in mammalian tissues and also raise some questions about its use for the measurement of GSH in liver. In this tissue, the GSH concentration determined by the fluorometric method was shown to be inversely correlated with the size of the sample, suggesting the presence of some quenching material.     

External GSSG enhances intracellular glutathione level in isolated cardiac myocytes

The addition of external GSSG at concentrations in the range 50-500 microM produces in isolated adult rat heart myocytes an increase of GSH level and only a slight increase of GSSG level. On the contrary, external GSH at the above same indicated concentrations did not change the cell glutathione pool. The pretreatment of the cells with diethylamaleate depleted the myocytes of glutathione and enhanced the GSSG-induced replenishment effect on GSH level. On the contrary, the addition of GSH did not increase the concentration of cell glutathione. The level of cell GSH in diethylmaleate-treated myocytes was not increased after 30 min of incubation with cysteine, or acetylcysteine. The GSSG induced-stimulation on GSH level was not inhibited by buthionine sulfoximine, an inhibitor of glutathione synthesis. On the contrary, this stimulatory effect was inhibited by N, N-bis(2-chloroethyl)-N-nitrosourea, an inhibitor of glutathione reductase, or partially, by the remotion of glucose from the incubation medium. These results support the idea that the isolated adult rat heart myocytes are able to utilize external GSSG in order to increase the intracellular glutathione pool, probably through the reduction of the imported GSSG to GSH.     

Inhibition of biliary taurocholate excretion during menadione metabolism in perfused rat liver

In perfused rat liver menadione elicits substantial oxidation in both the NADPH and GSH redox systems. Biliary excretion of GSSG is increased several-fold. Menadione derivatives appear in the bile predominantly as the menadione-S-glutathione conjugate, thiodione (60%), or as conjugates derived therefrom (17%). About 10% appear as menadione glucuronides. The excretion of taurocholate into bile is strongly inhibited upon menadione infusion. The inhibition of taurocholate excretion is small in livers with a low content of Se-GSH-peroxidase and in glutathione-depleted livers. In these livers intracellular GSSG and biliary GSSG release remain at low values, although menadione still imposes oxidative stress as indicated by an oxidation of intracellular NADPH. Under anoxic conditions menadione has little influence on both the NADPH and GSH redox systems and also on biliary taurocholate excretion. The amount of thiodione released into bile is similar to that found under normoxia, whereas the amount of glucuronidated products almost doubled. We conclude (a) that intracellular formation of GSSG by menadione occurs via the generation of hydrogen peroxide; (b) that the inhibition of biliary taurocholate excretion by menadione is related to the increased formation of glutathione disulfide; and (c) that menadione derivatives show little, if any, contribution to the inhibition of taurocholate excretion.     

Increases in tumor necrosis factor-alpha in response to thyroid hormone-induced liver oxidative stress in the rat

Thyroid hormone-induced calorigenesis contributes to liver oxidative stress and promotes an increased respiratory burst activity in Kupffer cells, which could conceivably increase the expression of redox-sensitive genes, including those coding for cytokines. Our aim was to test the hypothesis that L-3,3',5-triiodothyronine (T3)-induced liver oxidative stress would markedly increase the production of TNF-alpha by Kupffer cells and its release into the circulation. Sprague-Dawley rats receive a single dose of 0.1 mg T3/kg or vehicle (controls) and determinations of liver O2 consumption, serum TNF-alpha, rectal temperature, and serum T3 levels, were carried out at different times after treatment. Hepatic content of total reduced glutathione (GSH) and biliary glutathione disulfide (GSSG) efflux were measured as indices of oxidative stress. In some studies, prior to T3 injection animals were administered either (i) the Kupffer cell inactivator gadolinium chloride (GdCl3), (ii) the antioxidants alpha-tocopherol and N-acetyl-L-cysteine (NAC), or (iii) an antisense oligonucleotide against TNF-alpha (ASO TJU-2755). T3 elicited an 80-fold increase in the serum levels of TNF-alpha at 22h after treatment, which coincided with the onset of thyroid calorigenesis. Pretreatment with GdCl3, alpha-tocopherol, NAC, and ASO TJU-2755 virtually abolished this effect and markedly reduced T3-induced liver GSH depletion and the increases in biliary GSSG efflux. It is concluded that the hyperthyroid state in the rat increases the circulating levels of TNF-alpha by actions exerted at the Kupffer cell level and these are related to the oxidative stress status established in the liver by thyroid calorigenesis.     

Effects of dopamine on the glutathione metabolism of cultured astroglial cells: implications for Parkinson's disease

To investigate the effects of dopamine (DA) on the release of glutathione (GSH) from astrocytes, we used astroglia-rich primary cultures from the brains of newborn rats. In the absence of DA, GSH accumulated in the medium of these cultures with a constant rate. In contrast, during incubation of the cells with 50 micro m DA extracellular GSH was not detectable anymore. This disappearance of extracellular GSH was prevented by superoxide dismutase, indicating that DA does not affect GSH release but rather reacts with the released GSH in a superoxide-dependent reaction. Incubation of astroglial cultures with 0.5 and 1 mm DA established almost constant extracellular concentrations of H2O2 of 5 microm and 15 microm, respectively. Under these conditions astroglial cultures release glutathione disulphide (GSSG). This GSSG export was blocked by catalase and by MK571, an inhibitor of the multidrug resistance protein 1. The effects of DA on the extracellular accumulations of GSH and GSSG were not modulated by inhibitors of DA receptors, DA transport, and monoamine oxidases. The other catecholamines adrenaline and noradrenaline showed similar effects on the accumulation of GSH and GSSG in the medium compared with those obtained for DA. In conclusion, the data presented demonstrate that DA affects astroglial GSH metabolism by two mechanisms: (i) directly by chemical reaction with extracellular GSH, and (ii) indirectly by generation of hydrogen peroxide that leads to the efflux of GSSG from astroglial cells. These observations are discussed in the context of the brain's GSH metabolism in Parkinson's disease.     

Glutathione pathways in the brain

The antioxidant glutathione (GSH) is essential for the cellular detoxification of reactive oxygen species in brain cells. A compromised GSH system in the brain has been connected with the oxidative stress occuring in neurological diseases. Recent data demonstrate that besides intracellular functions GSH has also important extracellular functions in brain. In this respect astrocytes appear to play a key role in the GSH metabolism of the brain, since astroglial GSH export is essential for providing GSH precursors to neurons. Of the different brain cell types studied in vitro only astrocytes release substantial amounts of GSH. In addition, during oxidative stress astrocytes efficiently export glutathione disulfide (GSSG). The multidrug resistance protein 1 participates in both the export of GSH and GSSG from astrocytes. This review focuses on recent results on the export of GSH and GSSG from brain cells as well as on the functions of extracellular GSH in the brain. In addition, implications of disturbed GSH pathways in brain for neurodegenerative diseases will be discussed.