The dynamics of cysteine, glutathione and their disulphides in astrocyte culture medium

Glutathione (GSH) plays an important neuroprotective role, and its synthesis depends on the amount of available cysteine (CSH) in the cells. Various kinds of evidence suggest that astrocytes can provide CSH or GSH to neurons, but the delivery mechanism of the thiol-compounds has not been elucidated. In this study, the dynamics of CSH, GSH and their disulphides in astrocyte culture medium were investigated by following the time-course of concentration changes and by computer simulation and curve fitting to experimental data using a mathematical model. The model consists of seven reactions and three transports, which are grouped into four categories: autoxidation of thiols into disulphides, thiol-disulphide exchange and reactions of thiols with medium components, as well as the cellular influx and efflux of thiols and disulphides. The obtained results are interpreted that cystine (CSSC) after entering astrocyte is reduced to CSH, most of which is released to medium and autoxidized to CSSC. The efflux of GSH was estimated to be considerably slower than that of CSH, and most of the excreted GSH is converted to cysteine-glutathione disulphide principally through the thiol-disulphide exchange. The results seem to indicate that astrocytes provide neurons mainly with CSH, rather than GSH, as the antioxidant material for neuroprotection.     

Ultrasound-Induced Formation of S-Nitrosoglutathione and S-Nitrosocysteine in Aerobic Aqueous Solutions of Glutathione and Cysteine

S-Nitrosocompounds are formed when aqueous solutions of cysteine or glutathione are exposed to ultrasound (880 kHz) in air. The yield of the S-nitrosocompounds was as high as 10% for glutathione and 4% for cysteine of the initial thiol concentrations (from 0.1 to 10 mM) in the aqueous solutions. In addition to the formation of S-nitrosocompounds, thiol oxidation to disulfide forms was observed. After the oxidation of over 70% of the sulfhydryl groups, formation of peroxide compounds as well as cysteic acid derivatives was recorded. The formation of the peroxide compounds and peroxide radicals in the ultrasound field reduced the yield of S-nitrosocompounds. S-Nitrosocompounds were not formed when exposing low-molecular-weight thiols to ultrasound in atmospheres of N₂ or CO. In neutral solutions, ultrasound-exposed cysteine or glutathione released NO due to spontaneous degradation of the S-nitrosocompounds. N₂O₃, produced due to the spontaneous degradation of the S-nitrosocompounds in air, nitrosylated sulfhydryl groups of glutathione manifested in the appearance of new absorption bands at 330 and 540 nm. The nitrogen compounds formed in an ultrasound field modified the sulfhydryl groups of apohemoglobin and serum albumin. The main target for ultrasound-generated oxygen free radicals were cystine residues oxidized to cysteic acid residues.     

Dynamics of sulfur amino acids in mammalian brain: assessment of the astrocytic-neuronal cysteine interaction by a mathematical hybrid model

A mathematically hybrid model was used to analyze three mechanisms by which cysteine could be produced in the brain to be used as preferential substrate in the synthesis of neuronal glutathione. In that way, the fluxes of sulfur-compounds at the brain-blood barrier were integrated with their transport in astrocytes and neurons, and with their metabolism in astrocytes. We concluded that cysteine, in contrast with its precursor cystine, would not be taken up from the blood at the blood-brain barrier, but instead it must be lost continuously from astrocytes. Cysteine efflux is produced because the uptake of cystine in astrocytes is much greater than their cysteine demand to synthesize glutathione, hypotaurine and taurine. Once in the interstitial parenchyma, cysteine would be taken for the neurons, as backwardly by the endothelial cells. Remarkably, a close sulfur-macro balance can be maintained only if the surplus of the produced cysteine is transferred from the endothelial cells to the blood together with significant amounts of other sulfur-compounds, probably taurine and hypotaurine. In addition, the results obtained shown that alternative mechanisms of cysteine generation (i.e., nonenzymatic-thiol-disulfide exchange reaction, enzymatic cleavage of the glutathione effluxed from astrocytes) are not quantitatively significant under physiological conditions, in situ.     

Maintenance of Neuronal Glutathione by Glial Cells

Abstract— Glutathione levels in neurons and gllal cells were investigated in a neuronal-glial coculture and in separate cultures. Brain cell suspensions obtained from cerebral hemispheres of fetal rats were cultured, and after 5 days the glutathione content of this cell population, consisting mainly of neurons and astroglial cells, was 23.0 nmol/mg of cell protein, with a significantly high content in glial cells (28.0 nmol/mg of protein) in comparison with neurons (18.8 nmol/mg of protein). When the neurons and glial cells were separated and recultured in fresh medium, neu-ronal glutathione rapidly decreased, whereas glial glutathione remained unchanged. Cysteine is a rate-limiting precursor for glutathione synthesis, and its level was also decreased in neurons, but not in glial cells. Cysteine was taken up rapidly by both neurons and glial cells, but cys-tine was taken up only by glial cells. This accounts for the rapid decrease of glutathione in the cultured neurons, because the culture medium contains cystine, but not cys-teine. It was also found that the cultured glial cells released cysteine into the medium. These results suggest that neurons maintain their glutathione level by taking up cysteine provided by glial cells.     

Turnover and functions of glutathione studied with isolated hepatic and renal cells

Suspensions of freshly isolated rat hepatocytes and renal tubular cells contain high levels of reduced glutathione (GSH), which exhibits half-lives of 3-5 and 0.7-1 h, respectively. In both cells types the availability of intracellular cysteine is rate limiting for GSH biosynthesis. In hepatocytes, methionine is actively converted to cysteine via the cystathionine pathway, and hepatic glutathione biosynthesis is stimulated by the presence of methionine in the medium. In contrast, extracellular cystine can support renal glutathione synthesis; several disulfides, including cystine, are rapidly taken up by renal cells (but not by hepatocytes) and are reduced to the corresponding thiols via a GSH-linked reaction sequence catalyzed by thiol transferase and glutathione reductase (NAD(P)H). During incubation, hepatocytes release both GSH and glutathione disulfide (GSSG) into the medium; the rate of GSSG efflux is markedly enhanced during hydroperoxide metabolism by glutathione peroxidase. This may lead to GSH depletion and cell injury; the latter seems to be initiated by a perturbation of cellular calcium homeostasis occurring in the glutathione-depleted state. In contrast to hepatocytes, renal cells metabolize extracellular glutathione and glutathione S-conjugates formed during drug biotransformation to the component amino acids and N-acetyl-cysteine S-conjugates, respectively. In addition, renal cells contain a thiol oxidase acting on extracellular GSH and several other thiols. In conclusion, our findings with isolated cells mimic the physiological situation characterized by hepatic synthesis and renal degradation of plasma glutathione and glutathione S-conjugates, and elucidate some of the underlying biochemical mechanisms.     

Macrophages regulate intracellular glutathione levels of lymphocytes. Evidence for an immunoregulatory role of cysteine

Macrophages consume cystine and generate approximately equivalent amounts of acid-soluble thiol. Stimulation of macrophages with bacterial lipopolysaccharide (LPS) or tumor necrosis factor (TNF) strongly augments the amount of thiol released into the culture supernatant. Cysteine constitutes most of the acid-soluble thiol. The intracellular glutathione level and the DNA synthesis activity in mitogenically stimulated lymphocytes are strongly increased by either exogenously added cysteine, or (syngeneic) macrophages. This cysteine dependency is observed even in the presence of relatively high extracellular cystine concentration as they occur in the blood plasma. The extracellular cysteine concentration also has a strong influence on the intracellular glutathione concentration, viability, and DNA synthesis of cycling T cell clones. Moreover, the cysteine concentration in the culture medium on Day 3 and Day 4 of a 5-day allogeneic mixed lymphocyte culture (i.e., in the late phase of incubation) has a strong influence on the generation of cytotoxic T cell activity, indicating that regulatory effects of cysteine are not restricted to the early phase of the blastogenic response. The inhibitory effect of cysteine starvation on the DNA synthesis of the T cell clones and on the activation of cytotoxic T lymphocytes can be explained essentially by the depletion of intracellular glutathione, since similar effects are observed after treatment with buthionine sulfoximine (BSO), a specific inhibitor of the glutathione biosynthesis. BSO has practically no influence, however, on the N alpha-benzyloxycarbonyl Ne-t-butyloxycarbonyl-L-lysine-thiobenzyl-ester (BLT)-esterase activity and hemolytic activity of the cell lysates from cytotoxic T cells against sheep red blood cells (perforin activity). Taken together, our experiments indicate that cysteine has a regulatory role in the immune system analogous to the hormone-like lymphokines and cytokines. It is released by macrophages at a variable and regulated rate and regulates immunologically relevant functions of lymphocytes in the vicinity.     

Cystine lyase: β-cystathionase from turnip roots

Cystine lyase (EC 4.4.1.-) was purified 277-fold by a combination of ammonium sulfate precipitation, chromatography on calcium phosphate and DEAE-cellulose with a 6% recovery. The MW as measured by gel filtration on Biogel p-300 was ca 150 000. The enzyme catalysed the pyridoxal phosphate-dependent degradation of cystine to pyruvate, ammonia and cysteine persulfide. Cysteine persulfide normally degraded spontaneously to elemental sulfur and cysteine, that further reacted to yield cystine and H₂S. Pyridoxal phosphate stabilized the enzyme. The K_m value for cystine was 0.94 mM. The enzyme was insensitive to thiol reagents but was inhibited by some thiols (which may have reduced the cystine). Cystine lyase degraded many compounds having the L-α-amino propionic acid group with a thioether or disulfide linkage attached to the β-carbon but was inactive towards D-configuration at the α-carbon or L-homocystine. The cystine lyase was also a β-cystathionase as indicated by (1) a constant ratio of β-cystathionase activity to cystine lyase activity throughout a 277-fold purification, (2) the inhibition of cystine lyase activity by cystathionine and inhibition of β-cystathionase activity by cystine and (3) similarity in sensitivity to heat, cyanide and hydroxylamine. Using DL-cystathionine as substrate, the K_m value was 4 mM.     

Distribution of oxidized and reduced forms of glutathione and cysteine in rat plasma

The distribution of the glutathionyl moiety between reduced and oxidized forms in rat plasma was markedly different than that for the cysteinyl moiety. Most of the glutathionyl moiety was present as mixed disulfides with cysteine and protein whereas most of the cysteinyl moiety was present as cystine. Seventy percent of total glutathione equivalents was bound to proteins in disulfide linkage. The distribution of glutathione equivalents in the acid-soluble fraction was 28.0% as glutathione, 9.5% as glutathione disulfide, and 62.6% as the mixed disulfide with the cysteinyl moiety. In contrast, 23% of total cysteine equivalents was protein-bound. The distribution of cysteine equivalents in the acid-soluble fraction was 5.9% as cysteine, 83.1% as cystine, and 10.8% as the mixed disulfide with the glutathionyl moiety. A first-order decline in glutathione occurred upon in vitro incubation of plasma and was due to increased formation of mixed disulfides of glutathione with cysteine and protein. This indicates that plasma thiols and disulfides are not at equilibrium, but are in a steady-state maintained in part by transport of these compounds between tissues during the inter-organ phase of their metabolism. The large amounts of protein-bound glutathione and cysteine provide substantial buffering which must be considered in analysis of transient changes in glutathione and cysteine. In addition, this buffering may protect against transient thiol-disulfide redox changes which could affect the structure and activity of plasma and plasma membrane proteins.     

Screening of Thiol Compounds: Depolarization-Induced Release of Glutathione and Cysteine from Rat Brain Slices

Superfusates from rat brain slices were screened for thiol compounds after derivatization with monobromobimane by reversed-phase HPLC. Only glutathione and cysteine were detected. The Ca(2+)-dependent release of these compounds from slices of different regions of rat brain was investigated, applying a highly sensitive and reproducible quantification method, based on reduction of superfusates with dithiothreitol, reaction of thiols with iodoacetic acid, precolumn derivatization with o-phthalaldehyde reagent solution, and analysis with reversed-phase HPLC. This methodology allowed determination of reduced and total thiols in aliquots of the same superfusates. Mostly reduced glutathione and cysteine were released upon K+ depolarization and the Ca2+ dependency suggests that they originate from a neuronal compartment. The GSH release was most prominent in the mesodiencephalon, cortex, hippocampus, and striatum and lowest in the pons-medulla and cerebellum. This underscores a physiologically significant role for glutathione in CNS neurotransmission.     

Sulfhydryl oxidase from egg white. A facile catalyst for disulfide bond formation in proteins and peptides.

Both metalloprotein and flavin-linked sulfhydryl oxidases catalyze the oxidation of thiols to disulfides with the reduction of oxygen to hydrogen peroxide. Despite earlier suggestions for a role in protein disulfide bond formation, these enzymes have received comparatively little general attention. Chicken egg white sulfhydryl oxidase utilizes an internal redox-active cystine bridge and a FAD moiety in the oxidation of a range of small molecular weight thiols such as glutathione, cysteine, and dithiothreitol. The oxidase is shown here to exhibit a high catalytic activity toward a range of reduced peptides and proteins including insulin A and B chains, lysozyme, ovalbumin, riboflavin-binding protein, and RNase. Catalytic efficiencies are up to 100-fold higher than for reduced glutathione, with typical K(m) values of about 110-330 microM/protein thiol, compared with 20 mM for glutathione. RNase activity is not significantly recovered when the cysteine residues are rapidly oxidized by sulfhydryl oxidase, but activity is efficiently restored when protein disulfide isomerase is also present. Sulfhydryl oxidase can also oxidize reduced protein disulfide isomerase directly. These data show that sulfhydryl oxidase and protein disulfide isomerase can cooperate in vitro in the generation and rearrangement of native disulfide pairings. A possible role for the oxidase in the protein secretory pathway in vivo is discussed.     

Prediction of reversibly oxidized protein cysteine thiols using protein structure properties

Protein cysteine thiols can be divided into four groups based on their reactivities: those that form permanent structural disulfide bonds, those that coordinate with metals, those that remain in the reduced state, and those that are susceptible to reversible oxidation. Physicochemical parameters of oxidation-susceptible protein thiols were organized into a database named the Balanced Oxidation Susceptible Cysteine Thiol Database (BALOSCTdb). BALOSCTdb contains 161 cysteine thiols that undergo reversible oxidation and 161 cysteine thiols that are not susceptible to oxidation. Each cysteine was represented by a set of 12 parameters, one of which was a label (1/0) to indicate whether its thiol moiety is susceptible to oxidation. A computer program (the C4.5 decision tree classifier re-implemented as the J48 classifier) segregated cysteines into oxidation-susceptible and oxidation-non-susceptible classes. The classifier selected three parameters critical for prediction of thiol oxidation susceptibility: (1) distance to the nearest cysteine sulfur atom, (2) solvent accessibility, and (3) pKa. The classifier was optimized to correctly predict 136 of the 161 cysteine thiols susceptible to oxidation. Leave-one-out cross-validation analysis showed that the percent of correctly classified cysteines was 80.1% and that 16.1% of the oxidation-susceptible cysteine thiols were incorrectly classified. The algorithm developed from these parameters, named the Cysteine Oxidation Prediction Algorithm (COPA), is presented here. COPA prediction of oxidation-susceptible sites can be utilized to locate protein cysteines susceptible to redox-mediated regulation and identify possible enzyme catalytic sites with reactive cysteine thiols.     

The export of glutathione from human diploid cells in culture.

The export of glutathione from cultured human diploid fibroblasts into the surrounding medium was found by isotopic labeling experiments using [35S]cystine and by enzymatic measurements. The major part of the glutathione exported from the cells was found in normal culture medium as mixed disulfide of glutathione and cysteine. Radioactivity of 35S, mostly derived from cellular glutathione, was mainly located in glutathione moiety, not in cysteine moiety, of the mixed disulfide. Export of free glutathione was found when cystine-free medium was used. It was, therefore, concluded that mixed disulfide of glutathione and cysteine was formed in the medium by exported glutathione and medium cystine via sulfhydryl-disulfide exchange reaction. Amount of total glutathione exported from the cells was measured by enzymatic method and it was found that more than 10% of normal cellular glutathione was exported within 2 h. Apparent concentration of glutathione in the medium after a day of culture reached 3 to 4 micrometer, which was comparable to that observed in normal plasma by the same enzymatic method.     

Growth-associated modifications of low-molecular-weight thiols and protein sulfhydryls in human bronchial fibroblasts

The thiol redox status of cultured human bronchial fibroblasts has been characterized at various growth conditions using thiol-reactive monobromobimane, with or without the combination of dithiotreitol, a strong reducing agent. This procedure has enabled measurement of the cellular content of reduced glutathione (GSH), total glutathione equivalents, cysteine, total cysteine equivalents, protein sulfhydryls, protein disulfides, and mixed disulfides. Passage of cells with trypsin perturbs the cellular thiol homeostasis and causes a 50% decrease in the GSH content, whereas the total cysteine content is subsequently increased severalfold during cell attachment. During subsequent culture, transient severalfold increased levels of GSH, protein-bound thiols, and protein disulfides are reached, whereas the total cysteine content gradually declines. These changes in the redox balance of both low-molecular-weight thiols and protein-bound thiols correlate with cell proliferation and mostly precede the major growth phase. When the onset of proliferation is inhibited by maintenance of cells in medium containing decreased amounts of serum, the GSH content remains significantly increased. Subsequent stimulation of growth by addition of serum results in decreased GSH levels at the onset of proliferation. In thiol-depleted medium, proliferation is also inhibited, whereas GSH levels are increased to a lesser extent than in complete medium. Exposure to buthionine sulfoximine inhibits growth, prevents GSH synthesis, and results in accumulation of total cysteine, protein-bound cysteine, and protein disulfides. For extracellular cystine, variable rates of cellular uptake correlate with the initial increase in the total cysteine content observed following subculture and with the GSH peak that precedes active proliferation. The results strongly suggest that specific fluctuations in the cellular redox balance of both free low-molecular-weight thiols and protein sulfhydryls are involved in growth regulation of normal human fibroblasts.     

Exogenous cysteine and cystine promote cell proliferation in CaCo-2 cells

Abstract. Previous studies have shown that intracellular glutathione, a ubiquitous intracellular thiol, is related to cell proliferation and that cysteine or its disulphide form, cystine, also induces cell proliferation. Cysteine is a thiol containing amino acid and a rate-limiting precursor of glutathione. Therefore, it is still unresolved as to whether the proliferative effect of cysteine or cystine is entirely mediated by a change in the intracellular glutathione status. The objective of this study was to delineate the relationship among cysteine/cystine (thereafter referred to as cyst(e)ine), intracellular glutathione and cell proliferation in the human colon cancer CaCo-2 cell line. CaCo-2 cells were cultured in cyst(e)ine-free Dulbecco's Modified Eagle Medium without serum, and treated with 200 µ m cysteine and/or 200–400 µ m cystine for 24 h. In the presence of DL-buthionine-[S, R]-sulfoximine (BSO), a glutathione synthesis inhibitor, exogenously administered cyst(e)ine did not change the intracellular glutathione content, but increased the intracellular cysteine as well as cystine level. Addition of exogenous cyst(e)ine following 5 m m BSO treatment significantly increased cell proliferation as measured by ³H-thymidine incorporation and protein content. Cell cycle analyses revealed that cyst(e)ine promoted cell progression from the G₁ phase to the S phase. Correspondingly, cyst(e)ine treatment induced expression of cyclin D1 and phosphorylation of retinoblastoma protein (Rb). In conclusion, these data indicate that both cysteine and cystine have proliferative effects in CaCo-2 cells independent of an increase in intracellular glutathione. Induction of cyclin D1, phosphorylation of Rb, and subsequent facilitation of G₁-to-S phase transition were involved in the proliferative effect of exogenous cyst(e)ine.     

Low concentrations of acid-soluble thiol (cysteine) in the blood plasma of HIV-1-infected patients

Blood plasma samples from HIV-1-infected persons contain elevated glutamate concentrations up to 6-fold the normal level and relatively low concentrations of acid-soluble thiol (i.e. decreased cysteine concentrations). The intracellular glutathione concentration in peripheral blood-mononuclear cells (PBMC) and monocytes from HIV antibody-positive persons are also significantly decreased. Therapy with azidothymidine (AZT) causes a substantial recovery of the plasma thiol levels; but glutamate levels remain significantly elevated and intracellular glutathione levels remain low. Cell culture experiments with approximately physiological amino-acid concentrations revealed that variations of the extracellular cysteine concentration have a strong influence on the intracellular glutathione level and the rate of DNA synthesis [( 3H]thymidine incorporation) in T cell clones and human and murine lymphocyte preparations even in the presence of several-fold higher cystine and methionine concentrations. Cysteine cannot be replaced by a corresponding increase of the extracellular cystine or methionine concentration. These experiments suggest strongly that the low cysteine concentration in the plasma of HIV-infected persons may play a role in the pathogenetic mechanism of the acquired immunodeficiency syndrome.     

Neuroprotective immunity: T cell-derived glutamate endows astrocytes with a neuroprotective phenotype

A well-controlled T cell response to CNS injury may result in increased neuronal survival. However, the precise mechanism of T cell-induced neuroprotection is unknown. In this study, we report the unexpected finding that during culture of T cells, high levels of glutamate accumulate, which are efficiently cleared if T cells are cocultured with astrocytes. The T cell-derived glutamate elicits in turn, the release of neuroprotective thiols (cysteine, glutathione, and cysteinyl-glycine) and lactate from astrocytes. Media obtained from astrocytes conditioned in the presence of T cells reduce neuronal apoptosis induced by oxidative stress in primary neuronal cultures from 48 +/- 14 to 9 +/- 4% (p < 0.001). Inhibition of glutamate-dependent signaling during astrocyte-T cell cocultivation by a glutamate uptake inhibitor, l-aspartic acid beta-hydroxamate, abolishes this neuroprotective effect. The ability of astrocytes to clear extracellular glutamate is impaired under conditions of oxidative stress. We demonstrate that T cells, via secreted cytokines, restore glutamate clearance capacity of astrocytes under oxidative conditions. Furthermore, under normoxic conditions, glutamate-buffering capacity of astrocytes is increased upon cocultivation with T cells. It is known that, following CNS injury, astrocytes can respond with beneficial or destructive effects on neurons. However, the context and signaling mechanisms for this dual astrocytic response are unknown. Our results implicate T cells as potential determinants of the context that elicits a protective role for astrocytes in the damaged CNS.     

Regulation of glutathione levels in mouse spleen lymphocytes by transport of cysteine

Cysteine and cystine transport activities of resting and activated mouse spleen lymphocytes were characterized in order to examine the contributions of cysteine and cystine to intracellular glutathione contents. Following stimulation with lipopolysaccharide, the lymphocytes markedly increased their capacity to transport cysteine. The uptake of cysteine was mediated mainly by the ASC system (Na+-dependent neutral amino acid transport system especially reactive with alanine, serine, and cysteine). On the other hand, both the resting and the activated lymphocytes had extremely low cystine transport activities. Because of the instability of cysteine, the culture media usually contained cystine but not cysteine. Therefore, both the resting and the activated lymphocytes rapidly decreased their glutathione contents owing to their poor capacities to take up cystine. The effects of freshly added cysteine on the cellular glutathione contents were examined in the presence of bathocuproinedisulfonate, a nontoxic copper-specific chelator that inhibits autoxidation of cysteine. Cysteine added at 25-400 microM only partially prevented the rapid decrease of the glutathione contents in fresh resting lymphocytes. In the lipopolysaccharide-activated cells, however, cysteine enhanced the cellular glutathione contents in a dose-dependent manner. These results indicate that the enhanced activity of the ASC system increases the level of intracellular glutathione in the presence of cysteine.     

S-METHYLTHIO-CYSTEINE AND CYSTAMINE ARE POTENT STIMULATORS OF THIOL PRODUCTION AND GLUTATHIONE SYNTHESIS

The effects of methylthio-cysteine disulfide (MT-Cy) and cystamine (CAM) on the thiol production and glutathione content of a human T cell line (CEM-SS) have been investigated. MT-Cy per se and CAM in the presence of cystine greatly enhanced thiol production and glutathione content of cells while cystine alone exerted no or slight influence in the first hours. The MT-Cy- or CAM-induced extracellular SH-generation was observed both in a complete nutrient medium and even more in SH-free D-PBS. The acid-soluble thiol level and glutathione content of cells elevated markedly (up to 5–6 fold in two hours) when incubating cells in complete medium. Inhibition of glutathione synthesis by DL-buthionine (S,R)-sulfoximine did not alter the MT-Cy- or CAM-induced extracellular thiol production indicating that glutathione synthesis is not involved in this effect. The results suggest that MT-Cy easily enters the cells thus accelerating the thiol cycle in SH-poor medium while CAM promotes cystine uptake into the cells. Phenylalanine and leucine inhibited both MT-Cy- and CAM-dependent thiol production in D-PBS most effectively suggesting the involvement of the L membrane transport system in these effects. © 1998 Elsevier Science Inc.     

Cystine Uptake and Glutathione Level in Fetal Brain Cells in Primary Culture and in Suspension

Abstract— The glutathione level and the factors affecting this level were investigated in fetal rat brain cells in a primary culture. Early in the culture, the glutathione level of the brain cells decreased, but after 5 h it began to increase. This increase was not observed in a cystine-free medium and was prevented by excess glutamate. Cystine was taken up in freshly isolated brain cell suspensions, and its rate increased during the culture. The cystine uptake was mediated by a Na⁺-independent, glutamate-sensitive route previously found in various types of cells and designated as system x⁻_c. The uptake of cystine is a crucial factor in maintaining the glutathione level of the cells under culture, because it provides cysteine for the cells for glutathione synthesis. Cysteine was undetectable in the medium before the culture, but it appeared, though at a very low level, when the brain cells were cultured there. The source of this cysteine was the cystine in the medium. Presumably the decrease in the glutathione level of the cells in the early stage of the culture resulted from the fact that the medium did not contain cysteine. The enhancement of the cystine uptake during culture may constitute a protective mechanism against the oxidative stress to which the cultured cells are exposed. Regulation of the glutathione level in fetal brain cells in vivo by the transport of cystine and cysteine is discussed.