Gamma-glutamyl-glutathione. Natural occurrence and enzymology

The natural occurrence of gamma-glutamyl-glutathione (gamma-glutamyl-gamma-glutamylcysteinylglycine) in bile was established by analytical and chromatographic studies on the isolated and chemically synthesized materials. Evidence that it is formed in kidney was obtained. The origin of gamma-glutamyl-glutathione was explored through studies on the interaction of glutathione with gamma-glutamyl transpeptidase. When purified gamma-glutamyl transpeptidase was incubated with various concentrations (4 microM-50 mM) of glutathione, the initial rates of formation of gamma-glutamyl-glutathione were substantial at all concentrations of glutathione studied and were greater than the rates of formation of glutamate at physiological levels of glutathione (1-10 mM). The findings indicate that gamma-glutamyl transpeptidase catalyzes transpeptidation in vivo. That gamma-glutamyl-glutathione is formed in vivo and that it is a significant product of the reaction between glutathione and gamma-glutamyl transpeptidase under physiological conditions suggest that this polyanionic tetrapeptide may have a physiological role. gamma-Glutamyl-glutathione is not a substrate of glutathione reductase or of glutathione S-transferase, but it is a substrate of gamma-glutamyl-cyclotransferase. That gamma-glutamyl-glutathione has an additional negative charge as compared to glutathione suggests that it may be more effective than glutathione in forming complexes with certain metal ions and other cations.     

Distribution and some properties of the glutathione S-transferase and gamma-glutamyl transpeptidase activities of rainbow trout

1. Gills, kidney, intestinal caeca and liver of trout have glutathione S-transferase activity with 1-chloro-2,4-dinitrobenzene (200 500 nmol/min/mg protein), and reduced glutathione (0.5 2.0 mmol/kg tissue). 2. Only kidney and intestinal caeca have substantial gamma-glutamyl transpeptidase activity with gamma-glutamyl-rho-nitroanilide (2-9 nmol/min/mg protein). 3. Renal gamma-glutamyl transpeptidase is membrane-bound and has similar kinetic properties to its mammalian counterparts. 4. The data are consistent with the presence of a mercapturic acid pathway in trout.     

Effects of inhibition of cystathionase activity on glutathione and metallothionein levels in the adult rat.

The effects of alterations in sulfur metabolism on hepatic and renal metallothionein and glutathione metabolism were studied in the adult rat using inhibition of two enzymes of these pathways, hepatic cystathionase and renal gamma-glutamyl transpeptidase. Rats were fed a diet containing both methionine (0.66%) and cystine (0.20%) for 1 week before receiving three consecutive daily intraperitoneal injections of propargylglycine, a selective cystathionase inhibitor, at various doses (2.5-375 mumol/kg). When hepatic cystathionase was inhibited greater than 90% (greater than or equal to 50 mumol propargylglycine/kg), renal and hepatic metallothionein and hepatic glutathione were unaltered except at the highest dose. On the other hand, renal glutathione was increased two-fold with a concomitant decrease in renal gamma-glutamyl transpeptidase activity (50% of control). In another experiment, when renal gamma-glutamyl transpeptidase was inhibited greater than 90% with three consecutive daily injections of acivicin, a selective gamma-glutamyl transpeptidase inhibitor (10 mg/kg IP), renal glutathione content was unaltered while hepatic glutathione was decreased. Renal and hepatic metallothionein were not changed. Thus, the cysteine pools for metallothionein and glutathione appear unrelated under the present experimental conditions. In addition, following either proparglyglycine or acivicin injections, renal and hepatic glutathione pools appear to be altered differently. These results suggest that renal glutathione may be preferentially maintained even when hepatic glutathione is decreased.     

Effects of inhibition of cystathionase activity on glutathione and metallothionein levels in the adult rat

The effects of alterations in sulfur metabolism on hepatic and renal metallothionein and glutathione metabolism were studied in the adult rat using inhibition of two enzymes of these pathways, hepatic cystathionase and renal gamma-glutamyl transpeptidase. Rats were fed a diet containing both methionine (0.66%) and cystine (0.20%) for 1 week before receiving three consecutive daily intraperitoneal injections of propargylglycine, a selective cystathionase inhibitor, at various doses (2.5–375 μmol/kg). When hepatic cystathionase was inhibited greater than 90% (≥50 μmol propargylglycine/kg), renal and hepatic metallothionein and hepatic glutathione were unaltered except at the highest dose. On the other hand, renal glutathione was increased twofold with a concomitant decrease in renal gamma-glutamyl transpeptidase activity (50% of control). In another experiment, when renal gamma-glutamyl transpeptidase was inhibited greater than 90% with three consecutive daily injections of acivicin, a selective gamma-glutamyl transpeptidase inhibitor (10 mg/kg IP), renal glutathione content was unaltered while hepatic glutathione was decreased. Renal and hepatic metallothionein were not changed. Thus, the cysteine pools for metallothionein and glutathione appear unrelated under the present experimental conditions. In addition, following either propargylglycine or acivicin injections, renal and hepatic glutathione pools appear to be altered differently. These results suggest that renal glutathione may be preferentially maintained even when hepatic glutathione is decreased.     

Perturbation of hepatic glutathione level and glutathione-related enzyme activities by repeated administration of aminopyrine in rats

The influence of repeated administration of aminopyrine on the tissue glutathione level and related enzyme activities was investigated in rats. Reduced glutathione level in the liver was not changed after 5 days of treatment but a significant increase was seen after 15 days of aminopyrine treatment. Oxidized glutathione level was unaltered throughout the experiment. Repeated administration of aminopyrine for 5 days caused a marked increase in gamma-glutamyl transpeptidase activities in liver whole homogenates as well as in the nuclear fraction, but not in liver microsomes. These results suggest that gamma-glutamyl transpeptidase located in plasma membrane may be induced by repeated administration of aminopyrine for 5 days. The activities of cytosolic glutathione peroxidase, which modulates glutathione level, were also significantly increased by aminopyrine treatment. Under the same conditions, glutathione peroxidase activity with H2O2 as a substrate was unaltered, while a time-dependent increase in the activity was found when cumene hydroperoxide was used as a substrate, even after a single administration of aminopyrine. The intracellular cysteine level was increased accompanying the increased gamma-glutamyl transpeptidase activities. Therefore, induced gamma-glutamyl transpeptidase may play a role in the reclamation of extracellular oxidized glutathione.     

Intermediates of the gamma-glutamyl cycle in mouse tissues. Influence of administration of amino acids on pyrrolidone carboxylate and gamma-glutamyl amino acids.

GAMMA-Glutamyl transpeptidase, gamma-glutamyl cyclotransferase, L-pyrrolidone carboxylate hydrolase, gamma-glutamylcysteine synthetase and glutathione synthetase, the enzymes of the gamma-glutamyl cycle, were found in mouse brain, liver and kidney. The activity of L-pyrrolidone carboxylate hydrolase was many times lower than the activities of the other enzymes, and thus the conversion of L-pyrrolidone carboxylate to L-glutamate is likely to be the rate-limiting step of the cycle. The specificity of gamma-glutamyl cyclotransferase from mouse tissues was similar to that from rat tissues. The concentration of pyrrolidone carboxylate and gamma-glutamyl amino acids, intermediates of the gamma-glutamyl cycle, was determined by a gas chromatographic procedure coupled with electron capture detection. Administration of L-2-aminobutyrate, an amino acid that is utilized as substrate in the reaction catalyzed by gamma-glutamylcysteine synthetase, led to a large accumulation of gamma-glutamyl-2-aminobutyrate and pyrrolidone carboxylate in mouse tissues. L-Methionine-RS-sulfoximine, an inhibitor of gamma-glutamylcysteine synthetase, abolished the increase in concentration of pyrrolidone carboxylate. No accumulation of pyrrolidone carboxylate was observed after L-cysteine. The separate administration of several protein amino acids had little effect on the concentration of pyrrolidone carboxylate; however formation of small amounts of the corresponding gamma-glutamyl derivatives (e.g. gamma-glutamylmethionine and gamma-glutamylphenylalanine) was detected. These intermediates are probably formed by transpeptidation between glutathione and the corresponding amino acid, catalyzed by gamma-glutamyl transpeptidase. The concentration of pyrrolidone carboxylate increased significantly after administration of a mixture containing all protein amino acids, the highest increase occurring in the kidney. The results suggest that two separate pathways for the formation of gamma-glutamyl amino acids and pyrrolidone carboxylate exist in vivo. One of these results from the function of gamma-glutamylcysteine synthetase in glutathione synthesis. The other pathway involves the amino-acid-dependent degradation of glutathione, mediatedby gamma-glutamyl transpeptidase. Only very small amounts of free intermediates are apparently derived from the latter pathway, suggesting that the gamma-glutamyl amino acids formed in this pathway are either enzyme-bound or are directly hydrolyzed to glutamate and free amino acid.     

Decrease of intracellular cystine content in cystinotic fibroblasts by inhibitors of gamma-glutamyl transpeptidase

Cystine content of skin fibroblasts derived from patients with cystinosis was decreased by inhibitors of gamma-glutamyl transpeptidase, the initial enzyme in glutathione catabolism. The addition of maleate or the gamma-glutamyl hydrazone of alpha-ketobutyric acid to culture medium (1-20 mM) resulted in dose-dependent decreases of up to 55% on intracellular cystine content of cystinotic cells in 24 h. L-Serine in sodium borate buffer (40 mM each) produced similar results and further decreased cystine levels to 14% of cystinotic control values after 10 days incubation. Analysis of intracellular amino acids showed that, in general, other amino acids remained unchanged following serine-borate treatment. These results suggest that cystine storage in cystinotic tissues may be related to metabolism of glutathione.     

The apparent glutathione oxidase activity of gamma-glutamyl transpeptidase. Chemical mechanism

The apparent glutathione oxidase activity of gamma-glutamyl transpeptidase is due to nonenzymatic oxidation and transhydrogenation reactions of cysteinylglycine, an enzymatic product formed from glutathione by hydrolysis or autotranspeptidation. Since cysteinylglycine reacts with oxygen more rapidly than does glutathione, the rate of disulfide formation is increased and either cystinyl-bis-glycine or the mixed disulfide of cysteinylglycine and glutathione forms as an intermediate product. Nonenzymatic transhydrogenation reactions of these disulfides with glutathione yield glutathione disulfide and thus account for the apparent glutathione oxidase activity of gamma-glutamyl transpeptidase. A sensitive assay for glutathione oxidation is described, and it is shown that covalent inhibitors of gamma-glutamyl transpeptidase abolish the oxidase activity of the purified enzyme and of crude homogenates of mouse and rat kidney.     

Uptake and metabolism of glutamine in cultured kidney cells

The metabolism of glutamine was investigated in cultured rat kidney cells. Glutamine utilization and product formation were followed as a function of time at either 10 microM or 1 mM initial glutamine concentration. At 1 mM glutamine, glutamate and gamma-glutamylglutamate were the major products formed at the end of a 5-min incubation period; glutamate accounted for 46% while gamma-glutamylglutamate accounted for 33% of the glutamine utilized. With time, glutamate continued to accumulate while gamma-glutamyl peptide formation leveled off. The role of gamma-glutamyl transpeptidase was assessed by using hippurate, a physiological activator of gamma-glutamyl transpeptidase and acivicin, L-(alpha S,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid, an inhibitor of gamma-glutamyl transpeptidase. Hippurate, 4 mM, increased the utilization of glutamine and the formation of glutamate, gamma-glutamyl peptides and ammonia. Exposure of cells to acivicin resulted in 98% inhibition of gamma-glutamyl transpeptidase without effecting phosphate-dependent glutaminase activity. Acivicin inhibition resulted in a decreased utilization of glutamine and product formation as compared to control; 5-oxoproline appearance fell 70%. The fractional distribution of glutamine carbon and nitrogen into its metabolic products in control, hippurate and acivicin-treated cells showed no change at the end of 60 min. The data provide evidence that gamma-glutamyl transpeptidase utilizes glutamine and forms gamma-glutamyl peptides in cultured kidney cells.     

Enhanced gamma-glutamyl transpeptidase expression and superoxide production in Mpv17-/- glomerulosclerosis mice.

Recently, gamma-glutamyl transpeptidase, which initiates cleavage of extracellular glutathione, has been shown to promote oxidative damage to cells. Here we examined a murine disease model of glomerulosclerosis, involving loss of the Mpv17 gene coding for a peroxisomal protein. In Mpv17-/- cells, enzyme activity and mRNA expression (examined by quantitative RT-PCR) of membrane-bound gamma-glutamyl transpeptidase were increased, while plasma glutathione peroxidase and superoxide dismutase levels were lowered. Superoxide anion production in these cells was increased as documented by electron spin resonance spectroscopy. In the presence of Mn(III)tetrakis(4-benzoic acid)porphyrin, the activities of gamma-glutamyl transpeptidase and plasma glutathione peroxidase were unchanged, suggesting a relationship between enzyme expression and the amount of reactive oxygen species. Inhibition of gamma-glutamyl transpeptidase by acivicin reverted the lowered plasma glutathione peroxidase and superoxide dismutase activities, indicating reciprocal control of gene expression for these enzymes.     

Variations in gamma-glutamyl transpeptidase glycosylation and kinetic parameters in cultured liver cells.

In rat hepatocytes; the tumorigenic rat liver cell line ARL-16; and the human hepatoma line, Hep G2, 50% of the total gamma-glutamyl transpeptidase (GGT) activity was bound by a Concanavalin-A Sepharose 4B column, calling for alpha-methylmannoside elution (Peak I). Non-binding GGT was distributed between a rapidly eluting Peak II and a slightly retained Peak III. The Km for gamma-glutamyl-p-nitroanalide for either hydrolysis or transpeptidation, or glutathione (GSH) transpeptidation did not vary with peak number or cell type. The GSH hydrolysis Km was essentially constant in Peak I and II GGT. Peak III GGT exhibited a lower Km for GSH hydrolysis with Hep G2 Peak III GGT being the lowest. Peak III GGT increased to 50% of the GGT activity in Hep G2 cells cultured with GSH as the sole cysteine source.     

Stimulation of intralysosomal proteolysis by cysteinyl-glycine, a product of the action of gamma-glutamyl transpeptidase on glutathione

The mechanism of the stimulatory effect of glutathione on proteolysis in mouse kidney lysosomes and a lack of an effect in lysosomes from the liver was investigated. The stimulation in kidney lysosomes was inhibited by serine plus borate, a reversibly inhibitor of gamma-glutamyl transpeptidase. Treatment of mouse kidney lysosome suspensions with L-(alpha S,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (acivicin), an irreversibly inhibitor of the transpeptidase, also inhibited the effect of glutathione, but this inhibition was completely relieved by washing and addition of freshly prepared kidney membranes or purified gamma-glutamyl transpeptidase to the incubation mixtures. Cysteinyl-glycine, a product of the action of gamma-glutamyl transpeptidase, stimulated proteolysis in acivicin-inhibited kidney lysosome preparations similarly to glutathione, and cysteine had no effect at equivalent concentrations. Glutathione also stimulated proteolysis in liver lysosomes in the presence of washed kidney membranes or gamma-glutamyl transpeptidase, but the effect was similar to that produced by equivalent concentrations of cysteine. These results suggest that the stimulatory effect of glutathione was mediated by the action of gamma-glutamyl transpeptidase present in contaminating cell membrane fragments in the lysosome preparations, and that glutathione does not take part in intralysosomal proteolysis. However, the possibility that cysteinyl-glycine is a physiological intralysosomal disulfide reductant in kidney lysosomes has not been excluded.     

gamma-Glutamyl amino acids. Transport and conversion to 5-oxoproline in the kidney

Transport of gamma-glutamyl amino acids, a step in the proposed glutathione-gamma-glutamyl transpeptidase-mediated amino acid transport pathway, was examined in mouse kidney. The transport of gamma-glutamyl amino acids was demonstrated in vitro in studies on kidney slices. Transport was followed by measuring uptake of 35S after incubation of the slices in media containing gamma-glutamyl methionine [35S]sulfone. The experimental complication associated with extracellular conversion of the gamma-glutamyl amino acid to amino acid and uptake of the latter by slices was overcome by using 5-oxoproline formation (catalyzed by intracellular gamma-glutamyl-cyclotransferase) as an indicator of gamma-glutamyl amino acid transport. This method was also successfully applied to studies on transport of gamma-glutamyl amino acids in vivo. Transport of gamma-glutamyl amino acids in vitro and in vivo is inhibited by several inhibitors of gamma-glutamyl transpeptidase and also by high extracellular levels of glutathione. This seems to explain urinary excretion of gamma-glutamylcystine by humans with gamma-glutamyl transpeptidase deficiency and by mice treated with inhibitors of this enzyme. Mice depleted of glutathione by treatment with buthionine sulfoximine (which inhibits glutathione synthesis) or by treatment with 2,6-dimethyl-2,5-heptadiene-4-one (which effectively interacts with tissue glutathione) exhibited significantly less transport of gamma-glutamyl amino acids than did untreated controls. The findings suggest that intracellular glutathione functions in transport of gamma-glutamyl amino acids. Evidence was also obtained for transport of gamma-glutamyl gamma-glutamylphenylalanine into kidney slices.     

Characterization of a glutathione metabolic mutant of Mycobacterium tuberculosis and its resistance to glutathione and nitrosoglutathione

Glutathione is a tripeptide and antioxidant, synthesized at high levels by cells during the production of reactive oxygen and nitrogen intermediates. Glutathione also serves as a carrier molecule for nitric oxide in the form of S-nitrosoglutathione. Previous studies from this laboratory have shown that glutathione and S-nitrosoglutathione are directly toxic to mycobacteria. Glutathione is not transported into the cells as a tripeptide. Extracellular glutathione is converted to a dipeptide due to the action of transpeptidase, and the dipeptide is then transported into the bacterial cells. The processing of glutathione and S-nitrosoglutathione is brought about by the action of the enzyme gamma-glutamyl transpeptidase. The function of gamma-glutamyl transpeptidase is to cleave glutathione and S-nitrosoglutathione to the dipeptide (Cys-Gly), which is then transported into the bacterium by the multicomponent ABC transporter dipeptide permease. We have created a mutant strain of Mycobacterium tuberculosis lacking this metabolic enzyme. We investigated the sensitivity of this strain to glutathione and S-nitrosoglutathione compared to that of the wild-type bacteria. In addition, we examined the role of glutathione and/or S-nitrosoglutathione in controlling the growth of intracellular M. tuberculosis inside mouse macrophages.     

Evidence that transpeptidation is a significant function of gamma-glutamyl transpeptidase

gamma-Glutamyl transpeptidase (purified from rat kidney) was incubated with glutathione and a mixture of amino acids that closely approximates the amino acid composition of blood plasma, and the relative extents of transpeptidation and hydrolysis were determined by quantitative measurement of the products formed (glutamate, cysteinylglycine, gamma-glutamyl amino acids). At pH 7.4, in the presence of 50 microM glutathione and the amino acid mixture, about 50% of the glutathione that was utilized participated in transpeptidation. Studies in which the formation of individual gamma-glutamyl amino acids was determined in the presence of glutathione and the amino acid mixture showed that L-cystine and L-glutamine are the most active amino acid acceptors, and that other neutral amino acids also participate in transpeptidation to a significant extent. These in vitro experiments are consistent with a number of other findings which indicate that transpeptidation is a significant physiological function of gamma-glutamyl transpeptidase.     

Ammonia production by IMR-90 fibroblast cultures: effects of ammonia on glutathione, gamma-glutamyl transpeptidase, lysosomal enzymes, and cell division

gamma-Glutamyl transpeptidase has multi-catalytic activities. It degrades glutathione and can produce ammonia from glutamine. The present study was designed to examine whether the decreased cell proliferation, cellular glutathione content and concurrent increase in ammonia production in senescent cells in culture are the result of increased gamma-glutamyl transpeptidase activity. We used IMR-90 fibroblast and 3T3 LI preadipocyte cultures. The cellular glutathione content depended upon cell proliferation and cell density. The glutathione content was higher in cells at logarithmic growth, and lower at stationary growth or post confluency; dead cells had no detectable glutathione by the method currently used. The glutathione content was minimal in "old" IMR-90 cells, regardless of cell density. On the other hand, an increase occurred in the unit number of molecules of bound 5-iodoacetoamidofluorescein, an active-site directed stoichiometric inhibitor of transpeptidase. That result corresponded favorably with the increased enzyme activity, suggesting that the number of enzyme molecules per cell was increased. The inhibition of ammonia production of the cultures by inhibition of gamma-glutamyl transpeptidase by 5-iodoacetoamidofluorescein and reversible inhibition of ammonia production by a serine-borate mixture were consistent with our postulate. Addition of NH4Cl (0.1 mM) to IMR-90 cultures caused increased activities of transpeptidase and some of the lysosomal enzymes; concurrently, the amount of cellular glutathione and the number of cell divisions decreased. This suggests that the increased ammonia production presumably resulting from glutaminase activity of the observed increase of transpeptidase may profoundly affect certain cellular functions.     

Modulating effect of cystamine and unsaturated fatty acids on gamma-glutamyl transpeptidase: Relation to cellular oxidative status

Summary Cell surface gamma-glutamyl transpeptidese activity in cultured neoplastic astrocytes was significantly increased upon treatment of the cells with the hepatoprotective disulfide, cystamine. The cystamine effect was sensitive to cycloheximide and could be significantly depressed by exogenous glutathione. Surface gamma-glutamyl transpeptidase activity was also modulated by the presence in the culture medium of the unsaturated fatty acids, linoleic acid and arachidonic acid. Metabolism of the fatty acids via the cyclooxygenase pathway was not a prerequisite for their modulation of the glycoprotein ectoenzyme. Lipoxygenase, however, was found to potentiate the unsaturated fatty acid effect in neoplastic astrocytes. Lipoxygenase is reported to catalyze the conversion of unsaturated fatty acids to their corresponding peroxides. The data indicate an oxidative influence on the control of gamma-glutamyl transpeptidase activity.     

Glutathione and glutathione-related enzymes in busulfan treated rat lens

Glutathione (GSH) and GSH-related enzymes, glutathione reductase (GR), gamma-glutamyl cysteine synthetase (gamma-GCS), gamma-glutamyl transpeptidase (gamma-GTP), glutathione S-transferase (GST) and adenosine triphosphatase (ATPase) enzymes were analysed to study the effect of busulfan on the defence mechanisms of the lens. All these enzymes were found to increase significantly except GSH which showed only 7.9% increase as compared to controls in precataractous stage. These results affirm that busulfan is capable of evoking a response from the enzymes involved in the various pathways of GSH enabling the lens to prolong its clarity. The cataractous lenses showed significant decrease in all these parameters. Here, the impairment of the defense mechanism (GST, GR) and the total ATPase may be attributed to the cumulative action of the drug which can react with -SH groups of these enzymes, ultimately causing opacification.     

Glutathione and gamma-glutamyl transpeptidase in the adult female rat brain after intraventricular injection of LHRH and somatostatin

Glutathione content and glutamyl transpeptidase activity in different regions of adult female rat brain were determined at 10 and 30 min following intraventricular injection of LHRH and somatostatin. Hypothalamic glutathione levels were significantly elevated at 10 and 30 min after a single injection of a 0.1 micrograms dose of LHRH. On the contrary, glutathione levels significantly decreased in the hypothalamus, cerebral cortex and cerebellum at 10 and 30 min after 0.5 or 1 microgram dose. However, significant decrease in brain stem glutathione was evident at 30 min after 0.5 microgram and 10 min after the 1 microgram dose. Somatostatin at doses of 0.5 microgram and 1 microgram significantly decreased glutathione levels in all four brain regions both at 10 and 30 min following injection into the 3rd ventricle. Gamma-glutamyl transpeptidase activity in the hypothalamus and cerebral cortex was significantly elevated after intraventricular injection of LHRH. However, a significant increase in gamma-glutamyl transpeptidase activity in cerebellum and brain stem was seen only with 0.5 and 1 micrograms doses of LHRH. Somatostatin also significantly increased gamma-glutamyl transpeptidase activity in hypothalamus, cerebral cortex, brain stem and cerebellum. The decrease in glutathione levels with corresponding increase in gamma-glutamyl transpeptidase activity after intraventricular administration of LHRH and somatostatin suggests a possible interaction between glutathione and hypothalamic peptides.     

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.