Studies on the unique presence of an N-acetylgalactosamine residue in the carbohydrate moieties of human follicle-stimulating hormone

The effect of cystine starvation on the transport system of cystine and glutamate was examined in cultures of human diploid fibroblasts. The 2-min uptake of cystine and glutamate increased progressively after a lag of 6 h of cystine starvation. There was approx. 2-3-fold increase, and the increased rate of uptake was accompanied by an increase in the Vmax and unchanged Km. The cystine starvation-induced enhancement appeared specific for the uptake of cystine and glutamate. Actinomycin D or cycloheximide completely blocked the time-related increase in th uptake. Depletion of glutamate did not lead to the enhanced uptake, whereas depletion of glycine and serine caused as much increase in the uptake as depletion of cystine did. The intracellular pool of glutathione was extremely reduced by depletion of cystine, or of glycine and serine, but to a far less extent by depletion of glutamate. The results indicate that te transport system for cystine and glutamate appears to undergo adaptive regulation. It is suggested that glutathione may function as a regulatory signal to this transport system.     

Intrabiliary glutathione hydrolysis. A source of glutamate in bile

High concentrations of glutathione (GSH) and two of its constituent amino acids, glutamate and glycine, are normally found in rat bile. To examine the role of intrabiliary GSH hydrolysis as a source of these amino acids, as well as of cystine in bile, the biliary excretion of GSH and free amino acids was measured in normal male Sprague-Dawley rats; in animals given either phenol 3,6-dibromphthalein disulfonate or diethyl maleate, inhibitors of GSH secretion into bile; and after a retrograde intrabiliary infusion of (alpha S, 5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (AT-125), an irreversible inhibitor of gamma-glutamyl transferase activity. Total concentration of amino acids in normal rat bile ranged from 4 to 7 mM and was more than double the concentration in plasma (2-3 mM). Although most amino acids were detected in bile, glutamate and glycine were the most prevalent (1.2 and 1.0 mM, respectively), followed by the branched chain amino acids valine and leucine. The administration of phenol 3,6-dibromphthalein disulfonate (180 mumol/kg, intravenous), or of diethyl maleate (1 mmol/kg, intraperitoneal), resulted in a marked decrease in the biliary excretion of GSH, as well as a decrease in the excretion of glutamate, cystine, and glycine; however, the effects of these agents were not specific for the amino acid constituents of GSH. Following retrograde intrabiliary infusion of AT-125 (10 mumol/kg), there was an immediate and sustained doubling in the rate of biliary excretion of both GSH and glutathione disulfide and a marked decrease in the rate of excretion of glutamate. Varying the dose of AT-125 (0-20 mumol/kg) resulted in an inverse linear relation between hepatic gamma-glutamyl transferase activity and the biliary excretion of intact GSH. These findings suggest that most, if not all, of the free glutamate in excreted bile is formed from the intrabiliary hydrolysis of GSH. Prior to hydrolysis within the biliary tree, substantial concentrations of GSH must be transported from liver cells into bile; minimal canalicular concentrations of this tripeptide are estimated at 5 mM.     

Adaptive enhancement of cystine and glutamate uptake in human diploid fibroblasts in culture

The effect of cystine starvation on the transport system of cystine and glutamate was examined in cultures of human diploid fibroblasts. The 2-min uptake of cystine and glutamate increased progressively after a lag of 6 h of cystine starvation. There was approx. 2–3-fold increase, and the increased rate of uptake was accompanied by an increase in the V_max and unchanged K_m. The cystine starvation-induced enhancement appeared specific for the uptake of cystine and glutamate. Actinomycin D or cycloheximide completely blocked the time-related increase in the uptake. Depletion of glutamate did not lead to the enhanced uptake, whereas depletion of glycine and serine caused as much increase in the uptake as depletion of cystine did. The intracellular pool of glutathione was extremely reduced by depletion of cystine, or of glycine and serine, but to a far less extent by depletion of glutamate. The results indicate that the transport system for cystine and glutamate appears to undergo adaptive regulation. It is suggested that glutathione may function as a regulatory signal to this transport system.     

Induction of cystine transport in bovine pulmonary artery endothelial cells by sodium arsenite.

Sodium arsenite is one of a number of agents reported to induce a 30-34 kDa 'stress' protein in cells. Other agents which induce this stress protein, including diethyl maleate (DEM) and H2O2, have also been reported to be inducers of cystine transport in fibroblasts, macrophages, endothelial cells and other cell types. We have determined that micromolar levels of sodium arsenite increase cystine transport in bovine pulmonary artery endothelial cells (BPAEC), resulting in increases in intracellular glutathione (GSH). The increase in cystine transport appears to be due to stimulation of the synthesis of a protein analogous to the xc- transport system, a sodium-independent system specific for cystine and glutamate. We have determined that this stimulation is maximal between 8-16 h after addition of sodium arsenite and is inhibited by exogenous GSH. Others have reported that synthesis of the 30-34 kDa stress protein is maximal between 2-4 h and returns to baseline by 6-10 h. We conclude that cystine transport may be considered a 'secondary' stress response and is likely to be modulated by sulfhydryl-reactive agents.     

The inhibitory effect of glutamate on the growth of a murine hybridoma is caused by competitive inhibition of the x- C transport system required for cystine utilization

Glutamic acid was found to be growth inhibitory to a murinelymphocyte hybridoma in a concentration-dependent manner from 3to 12 mM glutamate. At 12 mM glutamate there was a 70% decreasein the specific growth rate of the cells. Attempts to alleviateinhibition or adapt cells to growth in glutamate-based mediawere unsuccessful. It is proposed that elevated glutamate levelsimpair adequate uptake of cystine, a critical amino acid for thesynthesis of glutathione. Glutathione is required by cells toprevent intracellular oxidative stress. The measured rate ofuptake of U-¹⁴C L-cystine into the cells was found to havethe following parameters: K_m = 0.87 mM, V_max = 0.9nmole/mg cell protein per min. The uptake was sodiumindependent and resembled the previously described x^- _ctransport system, with elevated glutamate levels causingextensive inhibition. Glutamate at a concentration of 1.4 mMcaused a 50% decrease in cystine uptake from the serum-freegrowth medium. Glutamate was taken up from the external medium(K_m = 20 mM and V_max = 12.5 nmole/mg cell protein permin) by the same transport system in a stereo specific, sodiumindependent manner. Of the amino acids examined, it was foundthat cystine and homocysteic acid were the most extensiveinhibitors of glutamate uptake and that inhibition was competitive. Metabolic profiles of the cells grown in culturescontaining enhanced glutamate levels revealed an overallincrease in net production of alanine, serine, asparagine andaspartate. A substantially increased specific consumption ofglutamate was accompanied by a decreased consumption of cystine,valine and phenylalanine.The combined kinetic and metabolic results indicate thatglutamate and cystine are taken up by the anionic transportsystem x^- _c. The increasing levels of glutamate in themedium result in a decreased transport of cystine by this systemdue to competitive inhibition by glutamate.     

Effect of cellular glutathione depletion on cadmium-induced cytotoxicity in human lung carcinoma cells

The effect of glutathione depletion on cellular toxicity of cadmium was investigated in a subpopulation (T27) of human lung carcinoma A549 cells with coordinately high glutathione levels and Cd⁺⁺-resistance. Cellular glutathione levels were depleted by exposing the cells to diethyl maleate or buthionine sulfoximine. Depletion was dose-dependent. Exposure of the cells to 0.5 mM diethyl maleate for 4 hours or to 10 mM buthionine sulfoximine for 8 hours eliminated the threshold for Cd⁺⁺ cytotoxic effect and deccreased the LD_50S. Cells that were pretreated with 0.5 mM diethyl maleate or 10 mM buthionine sulfoximine and then exposed to these same concentrations of diethyl maleate or buthionine sulfoximine during the subsequent assay for colony forming efficiency produced no colonies, reflecting an enhanced sensitivity to these agents at low cell density. Diethyl maleate was found to be more cytotoxic than buthionine sulfoximine. Synergistic cytotoxic effects were observed in the response of diethyl maleate pretreated cells exposed to Cd⁺⁺. Thus the results demostrated that depletion of most cellular glutathione in A549-T27 cells prior to Cd⁺⁺ exposure sensitizes them to the agent's cytotoxic effects. Glutathione thus may be involved in modulating the early cellular Cd⁺⁺ cytotoxic response. Comparison of reduced glutathione levels and of Cd⁺⁺ cytotoxic responses in buthionine sulfoximine-treated A549-T27 cells with those levels in other, untreated normal and tumor-derived cells suggests that the higher level of glutathione in A549-T27 is not the sole determinant of its higher level of Cd⁺⁺ resistance.Abbreviations BSO DL-buthionine-(R,S)-sulfoximine - DEM diethyl maleate - DMSO dimethyl sulfoxide - GSH reduced glutathione - MT metallothionein     

Characterization of cystine uptake in cultured astrocytes

Glutathione is involved in the maintenance of the structural and functional integrity of membrane proteins, in protection against free radicals and oxidative stress, and in the detoxification of xenobiotics. The cellular uptake of cystine is the rate limiting step in the biosynthesis of glutathione. The precise mechanism for such uptake is not clear as some reports indicate that the uptake occurs through a glutamate-cystine antiporter (system X(c)(-)), whereas, others suggest that it is taken up by the glutamate transporter (system X(AG)). Our studies in cultured astrocytes derived from neonatal rats showed that glutamate, D- and L-aspartate inhibited cystine uptake; that factors that increased intracellular glutamate levels, which would have enhanced the activity of the antiporter, did not stimulate cystine uptake; that the uptake was sodium dependent and partially chloride dependent; that the b(o,+) and ASC systems, which have been shown to carry cystine in some cells, did not mediate cystine uptake in astrocytes; that glutamate uptake blockers such as L-aspartate-beta-hydroxamate (AbetaH) and L-trans-pyrrolidine-2,4-dicarboxylate (PDC), as well as cystine uptake inhibitor L-alpha-aminoadipate (AAA) potently reduced cystine uptake. Additionally, deferoxamine (100 microM) as well as ammonium chloride (5 mM), both of which inhibit glutamate uptake, also inhibited cystine uptake. Taken together, our findings indicate that astrocytes take up cystine through a similar, if not identical, system used to take up glutamate. Interference of cystine uptake by astrocytes through the glutamate transport system may have profound effects on the redox state and the structural and functional integrity of the CNS.     

Nitric oxide production by cultured aortic endothelial cells in response to thiol depletion and replenishment

The requirements and influence of thiols on the production of nitric oxide (NO) were examined in cultured porcine aortic endothelial cells. NO production was diminished when cells were pretreated with thiol-depleting agents (IC50: N-ethylmaleimide, 30 microM; 1-chloro-2,4-dinitrobenzene, 200 microM; diamide, 1.5 mM; diethyl maleate, 20 mM). The depletion of glutathione (45-99% loss at the various IC50 values) and protein thiols (3-25% loss at IC50) showed no consistent relationship to decreased NO production. The effects of the agents on NO production were not linked to altered sensitivity to the stimulant (calcium ionophore A23187; maximal effect at 10 microM), but roughly paralleled the appearance of cell damage (17-44% lactate dehydrogenase release at IC50). The decrease in NO production due to 1-chloro-2,4-dinitrobenzene was partially reversed by cysteine, dithioerythritol, and dihydrolipoate, whereas cystine partially reversed the decrease due to diamide or diethyl maleate. On the other hand, several thiols diminished NO production in control cells. Overall, alterations of NO production did not parallel the depletion or replenishment of either glutathione, protein thiol, or soluble thiol pools, and so the results argue against hypotheses that cellular thiols are either substrates or necessary cofactors in the pathway of NO synthesis in endothelial cells.     

Glutamate toxicity in a neuronal cell line involves inhibition of cystine transport leading to oxidative stress

Glutamate binds to both excitatory neurotransmitter binding sites and a Cl(-)-dependent, quisqualate- and cystine-inhibited transport site on brain neurons. The neuroblastoma-primary retina hybrid cells (N18-RE-105) are susceptible to glutamate-induced cytotoxicity. The Cl(-)-dependent transport site to which glutamate and quisqualate (but not kainate or NMDA) bind has a higher affinity for cystine than for glutamate. Lowering cystine concentrations in the cell culture medium results in cytotoxicity similar to that induced by glutamate addition in its morphology, kinetics, and Ca2+ dependence. Glutamate-induced cytotoxicity is directly proportional to its ability to inhibit cystine uptake. Exposure to glutamate (or lowered cystine) causes a decrease in glutathione levels and an accumulation of intracellular peroxides. Like N18-RE-105 cells, primary rat hippocampal neurons (but not glia) in culture degenerate in medium with lowered cystine concentration. Thus, glutamate-induced cytotoxicity in N18-RE-105 cells is due to inhibition of cystine uptake, resulting in lowered glutathione levels leading to oxidative stress and cell death.     

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.     

Spindle disturbances in mammalian cells. IV. The action of some glutathione-specific agents in V79 Chinese hamster cells, changes in levels of free sulfhydryls and ATP, c-mitosis and effects on DNA metabolism

The glutathione-specific agents diamide, diethyl maleate and 1-chloro-2,4-dinitrobenzene were found to induce a low frequency of c-mitosis (15%) at non-toxic concentrations concomitant with a 30-40% decrease of non-protein sulfhydryls. The frequency of c-mitosis did not increase further with increased concentrations until non-protein sulfhydryl levels were obtained suggesting depletion of reduced glutathione. The observed shape of the concentration-response curve for c-mitosis is particular to these 3 agents and caffeine among 22 different compounds being tested under comparable conditions. This suggests a similar mechanism of action and from what is known about caffeine this mechanism probably involves an impaired control of cytoplasmic free Ca2+. It is speculated that this impairment with the glutathione-specific agents is primarily due to depletion of a particular pool of reduced glutathione. Tertiary butylhydroperoxide which is a substrate for glutathione peroxidase(s) also causes c-mitosis when there is no significant decrease of non-protein sulfhydryls. The c-mitotic response was found to be biphasic with maintained control levels at an intermediate concentration. The humps in the concentration-response curve for c-mitosis appeared coincident with a mitogenic response (G1----S). Since the latter type of effect most probably is Ca2+ dependent and since the spindle is sensitive to Ca2+ it is tentatively suggested that the c-mitotic effect of tertiary butylhydroperoxide is due to an increase of cytoplasmic Ca2+. Measurements performed imply that an increase of glutathione disulfide (diamide) is more inhibitory to uptake and incorporation of thymidine than a decrease of reduced glutathione per se (diethyl maleate). This difference is probably due to secondary effects on pertinent protein sulfhydryls with diamide, one possible target being the ribonucleotide reductase. All compounds were found to cause an increase of ATP with some of the applied concentrations. The results with diethyl maleate suggest that an increase of ATP is favored by an attack on mitochondrial reduced glutathione. The possible analogy between this effect and an increase of ATP and Ap4A in bacteria during oxidative stress is considered.     

Transport of L-[14C]cystine and L-[14C]cysteine by subtypes of high affinity glutamate transporters over-expressed in HEK cells

Transport of L-cystine across the cell membrane is essential for synthesis of the major cellular antioxidant, glutathione (gamma-glutamylcysteinylglycine). In this study, uptake of L-[14C]cystine by three of the high affinity sodium-dependent mammalian glutamate transporters (GLT1, GLAST and EAAC1) individually expressed in HEK cells has been determined. All three transporters display saturable uptake of L-[14C]cystine with Michaelis affinity (K(m)) constants in the range of 20-110 microM. L-glutamate and L-homocysteate are potent inhibitors of sodium-dependent L-[14C]cystine uptake in HEK(GLAST), HEK(GLT1) and HEK(EAAC1) cells. Reduction of L-[14C]cystine to L-[14C]cysteine in the presence of 1mM cysteinylglycine increases the uptake rate in HEK(GLT1), HEK(GLAST) and HEK(EAAC1) cells, but only a small proportion (<10%) of L-[14C]cysteine uptake in HEK(GLT1) and HEK(GLAST) cells occurs by the high affinity glutamate transporters. The majority (>90%) of L-[14C]cysteine transport in these cells is mediated by the ASC transport system. In HEK(EAAC1) cells, on the other hand, L-[14C]cysteine is transported equally by the ASC and EAAC1 transporters. L-homocysteine inhibits L-[14C]cysteine transport in both HEK(GLAST) and HEK(GLT1) cells, but not in HEK(EAAC1) cells. It is concluded that the quantity of L-[14C]cyst(e)ine taken up by individual high affinity sodium-dependent glutamate transporters is determined both by the extracellular concentration of amino acids, such as glutamate and homocysteine, and by the extracellular redox potential, which will control the oxidation state of L-cystine.     

The oxidative stress-inducible cystine/glutamate antiporter, system x c ? : cystine supplier and beyond

The oxidative stress-inducible cystine/glutamate exchange system, system x_c⁻, transports one molecule of cystine, the oxidized form of cysteine, into cells and thereby releases one molecule of glutamate into the extracellular space. It consists of two protein components, the 4F2 heavy chain, necessary for membrane location of the heterodimer, and the xCT protein, responsible for transport activity. Previously, system x_c⁻ has been regarded to be a mere supplier of cysteine to cells for the synthesis of proteins and the antioxidant glutathione (GSH). In that sense, oxygen, electrophilic agents, and bacterial lipopolysaccharide trigger xCT expression to accommodate with increased oxidative stress by stimulating GSH biosynthesis. However, emerging evidence established that system x_c⁻ may act on its own as a GSH-independent redox system by sustaining a redox cycle over the plasma membrane. Hallmarks of this cycle are cystine uptake, intracellular reduction to cysteine and secretion of the surplus of cysteine into the extracellular space. Consequently, increased levels of extracellular cysteine provide a reducing microenvironment required for proper cell signaling and communication, e.g. as already shown for the mechanism of T cell activation. By contrast, the enhanced release of glutamate in exchange with cystine may trigger neurodegeneration due to glutamate-induced cytotoxic processes. This review aims to provide a comprehensive picture from the early days of system x_c⁻ research up to now.     

Adaptive responses to peroxynitrite: increased glutathione levels and cystine uptake in vascular cells

We and others recentlydemonstrated increased glutathione levels, stimulated cystine uptake,and induced -glutamylcysteinyl synthase (-GCS) invascular cells exposed to nitric oxide donors. Here we report theeffects of peroxynitrite on glutathione levels and cystine uptake.Treatment of bovine aortic endothelial and smooth muscle cells with3-morpholinosydnonimine (SIN-1), a peroxynitrite donor, resulted intransient depletion of glutathione followed by a prolonged increasebeginning at 8-9 h. Concentration-dependent increases inglutathione of up to sixfold occurred 16-18 h after 0.05-2.5mM SIN-1. Responses to SIN-1 were inhibited by copper-zinc superoxidedismutases and manganese(III)tetrakis(1-methyl-4-pyridyl)porphyrin pentachloride, providing evidence for peroxynitrite involvement. Because glutathione synthesis is regulated by amino acid availability, we also studied cystine uptake. SIN-1 treatment resulted in a prolongedincrease in cystine uptake beginning at 6-9 h. Increases incystine uptake after SIN-1 were blocked by inhibitors of protein andRNA synthesis, by extracellular glutamate but not by extracellular sodium. These studies suggest induction of thex_c pathway of amino acid uptake. A closecorrelation over time was observed for increases in cystine uptake andglutathione levels. In summary, vascular cells respond to chronicperoxynitrite exposure with adaptive increases in cellular glutathioneand cystine transport.

     

Immature cortical neurons are uniquely sensitive to glutamate toxicity by inhibition of cystine uptake

Using the N18-RE-105 neuroblastoma X retina cell line, we previously described Ca2(+)-dependent quisqualate-type glutamate toxicity caused by the inhibition of high-affinity cystine uptake, leading to glutathione depletion and accumulation of cellular oxidants. We now demonstrate that primary cultures of rat cortical neurons (E17; 24-72 h in culture), but not glia, also degenerate when exposed to culture medium with reduced cystine or containing competitive inhibitors of cystine uptake, including glutamate. At this developmental stage, neurotoxicity did not occur as a consequence of continuous exposure to glutamate receptor subtype agonists, N-methyl-D-aspartate, kainate, or 2(RS)-amino-3-hydroxy-5-methyl-4-isoxazolepropionate. However, those that inhibited neuronal cystine uptake--quisqualate, glutamate, homocysteate, beta-N-oxalyl-L-alpha,beta-diaminopropionic acid, and ibotenate--were neurotoxic. Toxicity related to quisqualate did not correlate with the development of quisqualate-stimulated phosphatidylinositol turnover. The toxic potencies of glutamate, quisqualate, and homocysteate were inversely proportional to the concentration of cystine in the medium, suggesting that they competitively inhibit cystine uptake. Autoradiographic analysis of the cellular localization of L-[35S]cystine uptake indicated that embryonic neurons have a high-affinity transport system that is sensitive to quisqualate, whereas non-neuronal cells in the same cultures have a low-affinity system that is insensitive to quisqualate but potently blocked by D-aspartate and glutamate. Exposure to glutamate or homocysteate resulted in a time-dependent depletion of the cellular antioxidant glutathione. The centrally acting antioxidant idebenone and alpha-tocopherol completely blocked the neurotoxicity resulting from glutamate exposure. We propose that competitive inhibition of cystine transport and reduction of extracellular cystine levels result in neuronal cell death due to accumulation of cellular oxidants.     

Uptake of Glutamate and Cystine in C-6 Glioma Cells and in Cultured Astrocytes

The uptake of glutamate in rat glioma C-6 cells and cultured astrocytes derived from rat cerebral hemispheres was found to be mediated by a Na(+)-dependent and a Na(+)-independent system. The Na(+)-dependent system was inhibited by aspartate and was consistent with the commonly occurring system designated system X-AG. The Na(+)-independent system was inhibited by cystine and was consistent with system x-c described in various types of cells in the periphery. It was also found that quisqualate selectively and competitively interfered with the Na(+)-independent glutamate uptake. In C-6 cells, the glutamate uptake via systems X-AG and x-c accounted for approximately 35% and 55% of the total uptake, respectively, at 0.05 mM glutamate. In cultured astrocytes, the glutamate uptake via system X-AG was very potent, whereas the uptake via system xc- was relatively weak and its contribution to the total uptake of glutamate seemed almost negligible. However, in both C-6 cells and astrocytes, system xc- was necessary for the uptake of cystine, another substrate of system xc-. Cystine in the culture medium was an essential precursor of glutathione, and the inhibition of the cystine uptake by excess glutamate as a competitor led to a severe deficiency in glutathione, followed by cell degeneration.     

The glutathione content of retinal Müller (glial) cells: effect of pathological conditions

Maintenance of isolated retinal Müller (glial) cells in glutamate-free solutions over 7 h causes a significant loss of their initial glutathione content; this loss is largely prevented by the blockade of glutamine synthesis using methionine sulfoximine (5 mM). Anoxia does not reduce the glutathione content of Müller cells when glucose (11 mM), glutamate and cystine (0.1 mM each) are present. In contrast, simulation of total ischemia (i.e., anoxia plus removal of glucose) decreases the glutathione levels dramatically, even in the presence of glutamate and cystine. Less severe effects are caused by high extracellular K+ (40 mM). Reactive oxygen species are generated in the retina under various conditions, such as anoxia, ischemia, and reperfusion. One of the crucial substances protecting the retina against reactive oxygen species is glutathione, a tripeptide constituted of glutamate, cysteine and glycine. It was recently shown that glutathione can be synthesized in retinal Müller glial cells and that glutamate is the rate-limiting substance. In this study, glutathione levels were determined in acutely isolated guinea-pig Müller cells using the glutathione-sensitive fluorescent dye monochlorobimane. The purpose was to find out how the glial glutathione content is affected by anoxia/ischemia and accompanying pathophysiological events such as depolarization of the cell membrane. Our results further strengthen the view that glutamate is rate-limiting for the glutathione synthesis in glial cells. During glutamate deficiency, as caused by e.g., impaired glutamate uptake, this amino acid is preferentially delivered to the glutamate-glutamine pathway, at the expense of glutathione. This mechanism may contribute to the finding that total ischemia (but not anoxia) causes a depletion of glial glutathione. In situ depletion may be accelerated by the ischemia-induced increase of extracellular K+, decreasing the driving force for glutamate uptake. The ischemia-induced lack of glutathione is particularly fatal considering the increased production of reactive oxygen species under this condition. Therefore the therapeutic application of exogenous free radical scavengers is greatly recommended.     

Unique characteristics of rat spleen lymphocyte, L1210 lymphoma and HeLa cells in glutathione biosynthesis from sulfur-containing amino acids

Suspensions of rat spleen lymphocyte, murine L1210 lymphoma and HeLa cells were partially depleted of glutathione (GSH) with diethyl maleate and allowed to utilize either [35S]methionine, [35S]cystine or [35S]-cysteine for GSH synthesis. Lymphocytes preferentially utilized cysteine, compared to cystine, at a ratio of about 30 to 1, which was not related to differences in the extent of amino acid uptake. Only HeLa cells displayed a slight utilization of methionine via the cystathionine pathway for cysteine and GSH biosynthesis. HeLa and L1210 cells readily utilized either cystine or cysteine for GSH synthesis. The three cell types accumulated detectable levels of intracellular cysteine glutathione mixed disulfide when incubated in a medium containing a high concentration of cystine. Various enzyme activities were measured including gamma-glutamyl transpeptidase, GSH S-transferase and gamma-cystathionase. These results support the concept of a dynamic interorgan relationship of GSH to plasma cyst(e)ine that may have importance for growth of various cell types in vivo.     

Role of proton dissociation in the transport of cystine and glutamate in human diploid fibroblasts in culture

The effect of extracellular pH on the transport interaction of cystine and glutamate in cultured human diploid cells was examined over the pH range of 5.8-8.0. The initial rates of uptake of cystine increased with an increase in pH and glutamate potently inhibited the cystine uptake independently of pH. The uptake of glutamate was almost invariable within the pH range, but it was inhibited by cystine in a pH-dependent manner; the inhibition increased with an increase in pH. Regardless of pH, the uptake of cystine and glutamate was strongly inhibited by alpha-aminoadipate, alpha-aminopimelate, and homocysteate. From the pK values of cystine and other amino acids, it is suggested that cystine is transported in the same ionic form as is glutamate.