Cooperative binding of gamma-glutamyl substrate to human glutathione synthetase.

Human glutathione synthetase is responsible for catalyzing the final step in glutathione biosynthesis. It is a homodimer with a monomer subunit MW of 52 kDa. Kinetic analysis reveals a departure from linearity of the Lineweaver-Burk double reciprocal plot for the binding of gamma-glutamyl substrate, indicating cooperative binding. The measured apparent K(m) values for gamma-glutamyl-alpha-aminobutyrate (an analog of gamma-glutamyl-alpha-aminobutyrate) are 63 and 164 microM, respectively. Neither ATP (K(m) of 248 microM) nor glycine (K(m) of 452 microM) exhibits such cooperative binding behavior. Although ATP is proposed to play a key role in the sequential binding of gamma-glutamyl substrate to the enzyme, the cooperative binding of the gamma-glutamyl substrate is not affected by alterations of ATP concentration. Quantitative analysis of the kinetic results for gamma-glutamyl substrate binding gives a Hill coefficient (h) of 0.75, indicating negative cooperativity. Our studies, for the first time, show that human glutathione synthetase is an allosteric enzyme with cooperative binding for gamma-glutamyl substrate.     

Aspartate 458 of human glutathione synthetase is important for cooperativity and active site structure

Human glutathione synthetase (hGS) catalyzes the second ATP-dependent step in the biosynthesis of glutathione (GSH) and is negatively cooperative to the γ-glutamyl substrate. The hGS active site is composed of three highly conserved catalytic loops, notably the alanine rich A-loop. Experimental and computational investigations of the impact of mutation of Asp458 are reported, and thus the role of this A-loop residue on hGS structure, activity, negativity cooperativity and stability is defined. Several Asp458 hGS mutants (D458A, D458N and D458R) were constructed using site-directed mutagenesis and their activities determined (10%, 15% and 7% of wild-type hGS, respectively). The Michaelis–Menten constant (K_m) was determined for all three substrates (glycine, GAB and ATP): glycine K_m increased by 30–115-fold, GAB K_m decreased by 8–17-fold, and the ATP K_m was unchanged. All Asp458 mutants display a change in cooperativity from negative cooperativity to non-cooperative. All mutants show similar stability as compared to wild-type hGS, as determined by differential scanning calorimetry. The findings indicate that Asp458 is essential for hGS catalysis and that it impacts the allostery of hGS.     

Catalytic and regulatory site composition of yeast AMP deaminase by comparative binding and rate studies. Resolution of the cooperative mechanism

Yeast AMP deaminase is allosterically activated by ATP and MgATP and inhibited by GTP and PO4. The tetrameric enzyme binds 2 mol each of ATP, GTP, and PO4/subunit with Kd values of 8.4 +/- 4.0, 4.1 +/- 0.6, and 169 +/- 12 microM, respectively. At 0.7 M KCl, ATP binds to the enzyme, but no longer activates. Titration with coformycin 5'-monophosphate, a slow, tight-binding inhibitor, indicates a single catalytic site/subunit. ATP and GTP bind at regulatory sites distinct from the catalytic site and their binding is mutually exclusive. Inorganic phosphate competes poorly with ATP for the ATP sites (Kd = 20.1 +/- 4.1 mM). However, near-saturating ATP reduces the moles of phosphate bound per subunit to 1 PO4, which binds with a Kd = 275 +/- 22 microM. In the presence of ATP, PO4 cannot effectively compete with ATP for the nucleotide triphosphate sites. The PO4 which binds in the presence of ATP is competitive with AMP at the catalytic site since the Kd equals the kinetic inhibition constant for PO4. Initial reaction rate curves are a cooperative function of AMP concentration and activation by ATP is also cooperative. However, no cooperativity is observed in the binding of any of the regulator ligands and ATP binding and kinetic activation by ATP is independent of substrate analog concentration. Cooperativity in initial rate curves results, therefore, from altered rate constants for product formation from each (enzyme.substrate)n species and not from cooperative substrate binding. The traditional cooperative binding models of allosteric regulation do not apply to yeast AMP deaminase, which regulates catalytic activity by kinetic control of product formation. The data are used to estimate the rates of AMP hydrolysis under reported metabolite concentrations in yeast.     

The kinetic mechanism of rat kidney gamma-glutamylcysteine synthetase.

A detailed kinetic investigation was made of the binding mechanism of gamma-glutamylcysteine synthetase purified from rat kidney. The results of initial rate and inhibition studies are consistent with a partially random mechanism in which ATP is the obligatory first substrate and both amino acids bind in a random order to the enzyme-ATP complex. Formation of the enzyme-substrate quaternary complex is necessary prior to release of products. This mechanism is consistent with previous binding studies with the enzyme and while it does not rule out participation of enzyme-bound gamma-glutamyl phosphate as an intermediate in catalysis, such an intermediate cannot be a discrete covalent complex.     

Investigation of the mechanism of phosphinothricin inactivation of Escherichia coli glutamine synthetase using rapid quench kinetic technique.

A number of slow tight-binding inhibitors are known for glutamine synthetase that resemble the geometry of the tetrahedral intermediate formed during the enzyme-catalyzed condensation of gamma-glutamyl phosphate and ammonia. One of these inhibitors, phosphinothricin [L-2-amino-4-(hydroxymethyl-phosphinyl)butanoic acid], has been investigated by rapid kinetic methods. Phosphinothricin not only exhibits the kinetic properties of a slow tight-binding inhibitor but also undergoes phosphorylation during the course of the ATP-dependent inactivation. The acid lability of phosphinothricin phosphate enabled investigation of the kinetics of glutamine synthetase inactivation using rapid quench kinetic techniques. The rate-limiting step in the inhibition reaction is the binding of inhibitor (0.004-0.014 microM-1 s-1) and/or a conformational change associated with binding, which is several orders of magnitude slower than the binding of ATP. The association rate of phosphinothricin depends on which metal ion is bound to the enzyme (Mn2+ or Mg2+). With Mn2+ bound to glutamine synthetase the rate of association and the phosphorylation rate are faster than when Mg2+ is bound. The data are interpreted with use of a model in which the binding of a substrate analogue with a tetrahedral moiety enhances the phosphorylation rate of the reaction intermediate; however, the initial binding interaction is retarded because the enzyme has to bind a molecule that has a "transition-state" geometry rather than a ground-state substrate structure. During the course of the inactivation, progressively slower rates for binding and phosphoryl transfer were observed, indicating communication between active sites.     

Kinetic mechanism of glutathione synthetase from Arabidopsis thaliana

Glutathione synthetase (GS) catalyzes the ATP-dependent formation of the ubiquitous peptide glutathione from gamma-glutamylcysteine and glycine. The bacterial and eukaryotic GS form two distinct families lacking amino acid sequence homology. Moreover, the detailed kinetic mechanism of the bacterial and the eukaryotic GS remains unclear. Here we have overexpressed Arabidopsis thaliana GS (AtGS) in an Escherichia coli expression system and purified the recombinant enzyme for biochemical characterization. AtGS is functional as a homodimeric protein with steady-state kinetic properties similar to those of other eukaryotic GS. The kinetic mechanism of AtGS was investigated using initial velocity methods and product inhibition studies. The best fit of the observed data was to the equation for a random Ter-reactant mechanism in which dependencies between the binding of some substrate pairs were preferred. The binding of either ATP or gamma-glutamylcysteine increased the binding affinity of AtGS for the other substrate by 10-fold. Likewise, the binding of ATP or glycine increased binding affinity for the other ligand by 3.5-fold. In contrast, binding of either glycine or gamma-glutamylcysteine causes a 6.7-fold decrease in binding affinity for the second molecule. Product inhibition studies suggest that ADP is the last product released from the enzyme. Overall, these observations are consistent with a random Ter-reactant mechanism for the eukaryotic GS in which the binding order of certain substrates is kinetically preferred for catalysis.     

alpha-Aminomethylglutarate, a beta-amino analog of glutamate that interacts with glutamine synthetase and the enzymes that catalyze glutathione synthesis.

The glutamate analog, alpha-aminomethylglutaric acid, was synthetized by Michael addition of ammonia to 2-methylene glutaronitrile followed by hydrolysis of the intermediate alpha-aminomethylglutaryl nitrile; the analog cyclizes readily on heating to 2-piperidone-5-carboxylic acid. Sheep brain glutamine synthetase utilizes one isomer of DL-alpha-aminomethylglutarate at about 10% of the rate with L-glutamate. gamma-Glutamylcysteine synthetase uses both isomers of DL-alpha-aminomethylglutarate, preferentially acting on the same isomer used by glutamine synthetase. gamma-(alpha-Aminomethyl)glutaryl-alpha-aminobutyrate, prepared enzymatically with gamma-glutamylcysteine synthetase, was found to be a substrate and an inhibitor of glutathione synthetase. alpha-Aminomethylglutarate does not inhibit gamma-glutamyl cyclotransferase and gamma-glutamyl transpeptidase appreciably. When alpha-aminomethylglutarate was administered to mice, there were substantial decreases in the levels of glutamine, glutathione, glutamate, and glycine in the kidney, and of glutamine and glutamate in the liver, indicating that this glutamate analog is effective as an inhibitor of glutamine and glutathione synthesis in vivo, and suggesting that it may also inhibit other enzymes.     

Studies of the mechanism of glutamine synthetase utilizing pH-dependent behavior in catalysis and binding

The pKa values of enzyme groups of Escherichia coli glutamine synthetase which affect catalysis and/or substrate binding were determined by measuring the pH dependence of Vmax and V/K. Analysis of these data revealed that two enzyme groups are required for catalysis with apparent pKa values of approximately 7.1 and 8.2. The binding of ATP is essentially independent of pH in the range studied while the substrate ammonia must be deprotonated for the catalytic reaction. Using methylamine and hydroxylamine in place of ammonia, the pKa value of the deprotonated amine substrate as expressed in the V/K profiles was shifted to a lower pKa value for hydroxylamine and a higher pKa value for methylamine. These data indicate that the amine substrate must be deprotonated for binding. Hydroxylamine is at least as good a substrate as ammonia judged by the kinetic parameters whereas methylamine is a poor substrate as expressed in both the V and V/K values. Glutamate binding was determined by monitoring fluorescence changes of the enzyme and the data indicate that a protonated residue (pKa = 8.3 +/- 0.2) is required for glutamate binding. Chemical modification by reductive methylation with HCHO indicated that the group involved in glutamate binding most likely is a lysine residue. In addition, the Ki value for the transition state analog, L-3-amino-3-carboxy-propanesulfonamide was measured as a function of pH and the results indicate that an enzyme residue must be protonated (pKa = 8.2 +/- 0.1) to assist in binding. A mechanism for the reaction catalyzed by glutamine synthetase is proposed from the kinetic data acquired herein. A salt bridge is formed between the gamma-phosphate group of ATP and an enzyme group prior to attack by the gamma-carboxyl of glutamate on ATP to form gamma-glutamyl phosphate. The amine substrate subsequently attacks gamma-glutamyl phosphate resulting in formation of the tetrahedral adduct before phosphate release. A base on the enzyme assists in the deprotonation of ammonia during its attack on gamma-glutamyl phosphate or after the protonated carbinol amine is formed. Based on the kinetic data with the three amine substrates, catalysis is not rate-limiting through the pH range 6-9.     

Studies in the enzymology of glutathione metabolism in human erythrocytes

Spectrophotometric assay methods are described for glutathione synthetase, gamma-glutamylcysteine synthetase and gamma-glutamyl transpeptidase of erythrocytes. The contents of these enzymes in normal human erythrocytes are reported. Erythrocyte glutathione synthetase is inhibited by ADP; this inhibition is competitive with respect to ATP. gamma-Glutamylcysteine synthetase is subject to feedback inhibition by GSH, and is also inhibited by NADH, and to a lesser extent by NAD(+) and NADPH. This enzyme is irreversibly inactivated by cysteamine.     

Dual binding sites for translocation catalysis by Escherichia coli glutathionylspermidine synthetase

Most organisms use glutathione to regulate intracellular thiol redox balance and protect against oxidative stress; protozoa, however, utilize trypanothione for this purpose. Trypanothione biosynthesis requires ATP-dependent conjugation of glutathione (GSH) to the two terminal amino groups of spermidine by glutathionylspermidine synthetase (GspS) and trypanothione synthetase (TryS), which are considered as drug targets. GspS catalyzes the penultimate step of the biosynthesis-amide bond formation between spermidine and the glycine carboxylate of GSH. We report herein five crystal structures of Escherichia coli GspS in complex with substrate, product or inhibitor. The C-terminal of GspS belongs to the ATP-grasp superfamily with a similar fold to the human glutathione synthetase. GSH is likely phosphorylated at one of two GSH-binding sites to form an acylphosphate intermediate that then translocates to the other site for subsequent nucleophilic addition of spermidine. We also identify essential amino acids involved in the catalysis. Our results constitute the first structural information on the biochemical features of parasite homologs (including TryS) that underlie their broad specificity for polyamines.     

Fluorometric studies of aza-epsilon-adenylylated glutamine synthetase from Escherichia coli

Glutamine synthetase in Escherichia coli is regulated by adenylation and deadenylation reactions. The adenylation reaction converts the divalent cation requirement of the enzyme from Mg2+ to Mn2+. Previously, the catalytic action of unadenylated glutamine synthetase was elucidated by monitoring the intrinsic tryptophan fluorescence change accompanying substrate binding. However, due to the lack of changes in the tryptophan fluorescence, a similar study could not be done with the adenylated enzyme. In this study, therefore, an extrinsic fluor is introduced into the adenylated glutamine synthetase by adenylating the enzyme with 2-aza-1,N6-ethenoadenosine triphosphate, a fluorescent analog of ATP. The modified enzyme (aza-epsilon-glutamine synthetase) exhibits catalytic and kinetic properties similar to those of the naturally adenylated enzyme. The results of fluorometric studies on this aza-epsilon-glutamine synthetase indicated that L-glutamate and ATP bind to both Mn2+ and Mg2+ forms of the enzyme in a random order, but only the Mn2+ form is capable of forming a highly reactive enzyme-bound intermediate which is a prerequisite for the reaction with NH4+ to form products. The extrinsic fluorescence changes are also used to determine the binding constants of various substrates and inhibitors of both the biosynthetic and gamma-glutamyl transfer reactions.     

Influence of Chlorella powder intake during swimming stress in mice

Glutathione (GSH) is present in all mammalian tissues and plays a crucial role in many cellular processes. The second and final step in the synthesis involves the formation of GSH from gamma-glutamylcysteine (γ-GC) and glycine and is catalyzed by glutathione synthetase (GS). GS deficiency is a rare autosomal recessive disorder, and is present in patients with a range of phenotypes, from mild hemolytic anemia and metabolic acidosis to severe neurologic disorders or even death in infancy. The substrate for GS, γ-GC, has been suggested as playing a protective role, by substituting for GSH as an antioxidant in GS deficient patients. To examine the role of GS and GSH metabolites in development, we generated mice deficient in GSH by targeted disruption of the GS gene (Gss). Homozygous mice died before embryonic day (E) 7.5, but heterozygous mice survived with no distinct phenotype. GS protein levels and enzyme activity, as well as GSH metabolites, were investigated in multiple tissues. Protein levels and enzyme activity of GS in heterozygous mice were diminished by 50%, while GSH levels remained intact. γ-GC could not be detected in any investigated tissue. These data demonstrate that GSH is essential for mammalian development, and GSH synthesis via GS is an indispensable pathway for survival.     

Interaction of glutathione analogues with Hydra attenuata gamma-glutamyltransferase.

gamma-Glutamyltransferase activity was studied in extracts of the cnidarian Hydra attenuata. The binding of gamma-glutamyl peptide analogues to the enzyme was studied by observing their effects on heat denaturation and their inhibition of p-nitroaniline release from gamma-glutamyl p-nitroanilide. Neither position-1 analogues, in which the gamma-glutamyl moiety was changed to a beta-aspartyl (beta-Asp-Abu-Gly) or an alpha-glutamyl (Glu-Abu-Gly) linkage, nor glutamate protected the enzyme against inactivation at 58 degrees C. GSH (reduced glutathione), gamma-Glu-Abu-Gly and gamma-Glu-Met on the other hand did prevent heat denaturation. GSH and analogues of GSH were competitive inhibitors of p-nitroaniline release, but those analogues in which glycine was replaced by 2-aminoisobutyrate, phenylalanine, leucine or tyrosine had Ki values that were approximately five times those of analogues with the cysteine residue replaced.     

The dependence of flux,sensitivity and response of the flux on the concentrations of substrate and modifiers for cooperative enzymes

The sensitivity (change of flux per unit change in the concentration of substrate) and response (change of flux per unit change in the concentration of modifier) are studied for a two-site Adair model in which cooperativity arises from both binding and catalytic interactions. For positive cooperativity, the sensitivity is weakly dependent on the Hill coefficient for the binding case, but can increase without limit for the catalytic case. Negatively cooperative enzymes (binding only) give very large sensitivities compared with positively or non-interacting systems, but the sensitivity rapidly decreases as the saturation increases above 25%. Modifiers greatly enhance the sensitivity; large changes in flux can be obtained for small changes in the concentrations of substrates and modifiers. In general, increasing the degree of kinetic cooperativity decreases the degree of binding cooperativity; selective pressure to maximize the sensitivity and response of allosteric enzymes may act to optimize cooperativity of binding modifiers and kinetic cooperativity of substrate turnover. The initial velocity equations including modifiers can be extended to bi-substrate, cooperative kinetics. The kinetics of methanol dehydrogenase are discussed.     

Studies on the activity and activation of rat liver microsomal glutathione transferase with a series of glutathione analogues

The substrate specificity of rat liver microsomal glutathione transferase toward glutathione has been examined in a systematic manner. Out of a glycyl-modified and eight gamma-glutamyl-modified glutathione analogues, it was found that four (glutaryl-L-Cys-Gly, alpha-L-Glu-L-Cys-Gly, alpha-D-Glu-L-Cys-Gly, and gamma-L-Glu-L-Cys-beta-Ala) function as substrates. The kinetic parameters for three of these substrates (the alpha-D-Glu-L-Cys-Gly analogue gave very low activity) were compared with those of GSH with both unactivated and the N-ethylmaleimide-activated microsomal glutathione transferase. The alpha-L-Glu-L-Cys-Gly analogue is similar to GSH in that it has a higher kcat (6.9 versus 0.6 s-1) value with the activated enzyme compared with the unactivated enzyme but displays a high Km (6 versus 11 mM) with both forms. Glutaryl-L-Cys-Gly, in contrast, exhibited a similar kcat (8.9 versus 6.7 s-1) with the N-ethylmaleimide-treated enzyme but retains a higher Km value (50 versus 15 mM). Thus, the alpha-amino group of the glutamyl residue in GSH is important for the activity of the activated microsomal glutathione transferase. These observations were quantitated by analyzing the changes in the Gibbs free energy of binding calculated from the changes in kcat/Km values, comparing the analogues to GSH and each other. It is estimated that the binding energy of the alpha-amino group of the glutamyl residue in GSH contributes 9.7 kJ/mol to catalysis by the activated enzyme, whereas the corresponding value for the unactivated enzyme is 3.2 kJ/mol. The importance of the acidic functions in glutathione is also evident as shown by the lack of activity with 4-aminobutyric acid-L-Cys-Gly and the low kcat/Km values with gamma-L-Glu-L-Cys-beta-Ala (0.03 and 0.01 mM-1s-1 for unactivated and activated enzyme, respectively). Utilization of binding energy from a correctly positioned carboxyl group in the glycine residue (10 and 17 kJ/mol for unactivated and activated enzyme, respectively) therefore also appears to be required for optimal activity and activation. A conformational change in the microsomal glutathione transferase upon treatment with N-ethylmaleimide or trypsin, which allows utilization of binding energy from the alpha-amino group of GSH as well as the glycine carboxyl in catalysis, is suggested to account for at least part of the activation of the enzyme.     

Temperature adaptation of glutathione S-transferase P1-1. A case for homotropic regulation of substrate binding.

Human glutathione S-transferase P1-1 (GST P1-1) is a homodimeric enzyme expressed in several organs as well as in the upper layers of epidermis, playing a role against carcinogenic and toxic compounds. A sophisticated mechanism of temperature adaptation has been developed by this enzyme. In fact, above 35 degrees C, glutathione (GSH) binding to GST P1-1 displays positive cooperativity, whereas negative cooperativity occurs below 25 degrees C. This binding mechanism minimizes changes of GSH affinity for GST P1-1 because of temperature fluctuation. This is a likely advantage for epithelial skin cells, which are naturally exposed to temperature variation and, incidentally, to carcinogenic compounds, always needing efficient detoxifying systems. As a whole, GST P1-1 represents the first enzyme which displays a temperature-dependent homotropic regulation of substrate (e.g. GSH) binding.     

Glutathione synthetase promotes the reduction of arsenate via arsenolysis of glutathione

The environmentally prevalent arsenate (As(V)) undergoes reduction in the body to the much more toxic arsenite (As(III)). Phosphorolytic enzymes and ATP synthase can promote the reduction As(V) by converting it into arsenylated products in which the pentavalent arsenic is more reducible by glutathione (GSH) to As(III) than in inorganic As(V). Glutathione synthetase (GS) can catalyze the arsenolysis of GSH (γ-Glu-Cys-Gly) yielding two arsenylated products, i.e. γ-Glu-Cys-arsenate and ADP-arsenate. Thus, GS may also promote the reduction of As(V) by GSH. This hypothesis was tested with human recombinant GS, a Mg(2+) dependent enzyme. GS markedly increased As(III) formation when incubated with As(V), GSH, Mg(2+) and ADP, but not when GSH, Mg(2+) or ADP were separately omitted. Phosphate, a substrate competitive with As(V) in the arsenolysis of GSH, as well as the products of GSH arsenolysis or their analogs, e.g. glycine and γ-Glu-aminobutyrate, decreased As(V) reduction. Replacement of ADP with ATP or an analog that cannot be phosphorylated or arsenylated abolished As(V) reduction, indicating that GS-supported As(V) reduction requires formation of ADP-arsenate. In the presence of ADP, however, ATP (but not its metabolically inert analog) tripled As(V) reduction because ATP permits GS to remove the arsenolysis inhibitory glycine and γ-Glu-Cys by converting them into GSH. GS failed to promote As(V) reduction when GSH was replaced with ophthalmic acid, a GSH analog substrate of GS containing no SH group (although ophthalmic acid did undergo GS-catalyzed arsenolysis), indicating that the SH group of GSH is important for As(V) reduction. Our findings support the conclusion that GS promotes reduction of As(V) by catalyzing the arsenolysis of GSH, thus producing ADP-arsenate, which upon being released from the enzyme is readily reduced by GSH to As(III).     

Incorporation of labelled glycine into reduced glutathione of intact human erythrocytes by enzyme-catalysed exchange. A nuclear-magnetic-resonance study.

1H, 2H and 15N n.m.r. spectroscopy was used to monitor the incorporation of free glycine into the glycine residue of reduced glutathione (GSH) in suspensions of intact human erythrocytes. The following results were obtained. (i) By using 1H spin-echo n.m.r. the exchange reaction between [2H5]glycine and the protonated glycine residue of GSH was studied at various [2H5]glycine concentrations, thus enabling the calculation of an apparent Michaelis constant (Km) and maximal velocity (Vmax.) for the process. (ii) The reaction is catalysed by glutathione synthetase and proceeds most rapidly in the absence of glucose, which is the main physiological energy source of the erythrocyte. (iii) 15N n.m.r. spectroscopy, with a one-pulse sequence, and 2H n.m.r. spectroscopy, with an inversion recovery method, enabled demonstration of the incorporation of labelled glycine into an intra-erythrocyte peptide, consistent with incorporation into GSH. (iv) The exchange reaction, although inhibited by glucose, appeared not to be dependent on low ATP or 2,3-bisphosphoglycerate concentrations.     

Analysis of glutathione-enhanced differentiation by microfilariae of Onchocerca lienalis (Filarioidea: Onchocercidae) in vitro

Reduced glutathione (GSH), but not its oxidized form (GSSG), stimulated development of Onchocerca lienalis microfilariae to the late first-larval stage in vitro. The degree and frequency of development was dose-related with a peak of activity at 15 mM, a concentration that is similar to known intracellular levels of GSH. To determine the mode(s) of action of this multifunctional compound, other reducing agents (L-cysteine, dithiothreitol), cysteine delivery agents (N-acetyl-L-cysteine, L-thiazolidine-4-carboxylic acid, L-2-oxothiazolidine-4-carboxylic acid), cysteine analogues (S-methyl-L-cysteine, D-glucose-L-cysteine, cysteine ethyl ester), free-component amino acids of GSH (glutamic acid, cysteine, and glycine), a specific metabolic inhibitor of gamma-glutamyl synthetase (buthionine sulfoximine), and an inhibitor of gamma-glutamyl transpeptidase (gamma-glutamyl glutamic acid) were also tested at concentrations of 0.01-50 mM in this system. N-acetyl-L-cysteine at 1-5 mM and D-glucose-L-cysteine at 2.5-10 mM significantly enhanced development. In contrast to those worms maintained in GSH-supplemented medium, microfilariae exposed to GSH for only the first 24 hr showed no enhancement by day 7 in culture. Neither buthionine sulfoximine nor gamma-glutamyl glutamic acid at 0.01-35 mM inhibited the effects of 15 mM GSH or 1 mM N-acetyl-L-cysteine. Results indicate that GSH or other cysteine analogues possessing a free sulfhydryl group must be present in the extranematodal environment to support microfilarial differentiation in vitro.     

Elevated erythrocyte glutathione associated with elevated substrate in high- and low-glutathione sheep.

Erythrocyte glutathione concentration increases dramatically in sheep when they become anemic. To determine the mechanism of this change in glutathione control, we measured the enzymes and substrates necessary for glutathione control, we measured the enzymes and substrates necessary for glutathione synthesis after acute blood loss in both low- (gamma-glutamylcysteine synthetase deficient) and high-glutathione sheep. Erythrocyte glutamate, ATP, and glycine increased dramatically in all sheep. Erythrocyte gamma-glutamylcysteine synthetase increased slowly and seemed unrelated to changes in glutathione. Erythrocyte glutathione synthetase and cysteine and plasma cysteine, glutamate and glycine did not change significantly. Apparently substrate concentrations may be important in regulating erythrocyte glutathione levels.