The identification and structural characterization of C7orf24 as gamma-glutamyl cyclotransferase. An essential enzyme in the gamma-glutamyl cycle

The hypothetical protein C7orf24 has been implicated as a cancer marker with a potential role in cell proliferation. We have identified C7orf24 as gamma-glutamyl cyclotransferase (GGCT) that catalyzes the formation of 5-oxoproline (pyroglutamic acid) from gamma-glutamyl dipeptides and potentially plays a significant role in glutathione homeostasis. In the present study we have identified the first cDNA clones encoding a gamma-glutamyl cyclotransferase. The GGCT gene is located on chromosome 7p14-15 and consists of four exons that span 8 kb. The primary sequence is 188 amino acids in length and is unlike any protein of known function. We crystallized functional recombinant gamma-glutamyl cyclotransferase and determined its structure at 1.7 A resolution. The enzyme is a dimer of 20,994-Da subunits. The topology of GGCT is unrelated to other enzymes associated with cyclotransferase-like activity. The fold was originally classified as "BtrG-like," a small family that only includes structures of hypothetical proteins from Mus musculus, Escherichia coli, Pyrococcus horikoshii, and Arabidopsis thaliana. Since this is the first member of this family with a defined function, we propose to refer to this structure as the gamma-glutamyl cyclotransferase fold. We have identified a potential active site pocket that contains a highly conserved glutamic acid (Glu(98)) and propose that it acts as a general acid/base in the reaction mechanism. Mutation of Glu(98) to Ala or Gln completely inactivates the enzyme without altering the overall fold.     

A spectrophotometric method for the determination of gamma-glutamyl cyclotransferase with alanine dehydrogenase in the presence of anthglutin

gamma-Glutamyl cyclotransferase activity is assayed in tissues by a colorimetric method using gamma-glutamyl alanine as a substrate coupled with alanine dehydrogenase from B. sphericus, to measure the formation of NADH. In order to avoid interference by the reaction catalyzed by gamma-glutamyl transpeptidase, anthglutin, a specific inhibitor of the transpeptidase was included in the reaction mixture. The Km value of rat kidney gamma-glutamyl cyclotransferase with respect to gamma-glutamyl alanine appeared to be the same when determined by either the colorimetric or the radiometric method. This assay presents a reliable alternative to the use of radiolabeled substrate and is used for the assay of gamma-glutamyl cyclotransferase in a variety of physiological and experimental samples.     

L-gamma-(Threo-beta-methyl)glutamyl-L-alpha-aminobutyrate, a selective substrate of alpha-glutamyl cyclotransferase

L-gamma(Threo-beta-methyl)glutamyl-L-alpha-aminobutyrate was was prepared and found to be an excellent substrate of gamma-glutamyl cyclotransferase; in contrast to gamma-glutamyl-glutamine and other good substrates of cyclotransferase, the new substrate is not acted upon by gamma-glutamyl transpeptidase. gamma-Glutamyl cyclotransferase converts the new substrate to alpha-aminobutyrate and 3-methyl-5-oxoproline; the latter compound is not a substrate of 5-oxoprolinase. These properties of L-gamma-(threo-beta-methyl)glutamyl-L-alpha-aminobutyrate facilitate its use in selectively determining cyclotransferase activity in biological materials that have transpeptidase activity. Thus, the new substrate was used here for the determination of the cyclotransferase activity of homogenates of various mouse tissues. The new substrate was also used to examine gamma-glutamyl cyclotransferase activity in vivo; thus, the rate of respiratory 14CO2 formation after administration of L-gamma-(threo-beta-methyl)glutamyl-L-alpha-amino[14C]butyrate to mice provides a valid measure of cyclotransferase activity. beta-Aminoglutaryl-L-alpha-aminobutyrate is a competitive inhibitor of cyclotransferase (apparent Ki, 0.6 mM). Administration of beta-amino-glutaryl-L-alpha-aminobutyrate to mice out only decreased the level of 5-oxoproline in the kidney of control mice, but also of mice in which kidney 5-oxoproline levels were increased by administration of methionine. Administration of beta-aminoglutaryl-L-alpha-aminobutyrate to mice decreased the in vivo metabolism of L-(threo-beta-methyl)glutamyl-L-alpha-amino[14C]butyrate as indicated by a marked decrease in the rate of respiratory 14CO2 formation. The findings indicate that gamma-glutamyl cyclo-transferase is a major in vivo catalyst for the formation of 5-oxoproline.     

gamma-Glutamyl cyclotransferase from rat kidney. Sulfhydryl groups and isolation of a stable form of the enzyme.

gamma-Glutamyl cyclotransferase, highly purified from rat kidney, contains several readily accessible sulfhydryl groups whose modification appears to be associated with the appearance of multiple enzyme forms as determined by isoelectric focusing and ion exchange chromatography. The enzyme was obtained in a 1000-fold purified and apparently homogeneous form by a procedures involving treatment with dithiothreitol followed by chromatography on thiol-Sepharose. The enzyme was also isolated in a highly active, apparently homogeneous, and stable form after reduction and treatment with iodoacetamide. The amino acid compositions and other properties of the two forms of the enzyme were very similar. Studies on the activity of the enzyme toward a variety of gamma-glutamyl amino acids and di-gamma-glutamyl amino acids showed that the enzyme is much more active toward certain di-gamma-glutamyl amino acids than toward the corresponding gamma-glutamyl amino acids; thus, the preferred substrates have the general structure gamma-Glu-gamma-Glu-NH-R in which the nature of the R moiety has relatively little effect on activity.     

Renal glutamine utilization: glycylglycine stimulation of gamma-glutamyltransferase

Glycylglycine stimulation of renal glutamine utilization was studied on the homogenate, subcellular and purified enzyme level. The results clearly establish the existence of two glutamine utilizing pathways, the mitochondrial dependent L-glutamine amidohydrolase (PDG) and a second, extramitochondrial pathway. In contrast to the mitochondrial pathway which produces stoichiometric amounts of ammonia and glutamate, this second pathway hydrolyzes glutamine to produce ammonia and transfers the gamma-glutamyl moiety, producing gamma-glutamyl peptides. In the crude systems, containing cyclotransferase, the gamma-glutamyl moiety appears mainly as 5-oxoproline; however, in the enzyme preparation, purified 112-fold, gamma-glutamyl peptides (transpeptidation) and a small amount of glutamate (hydrolysis) appear. D-Glutamine was also hydrolyzed, in contrast to the stereospecific PDG, but at less than one-half the rate of the L-isomer. The molecular weight of this extramitochondrial D- and L-glutamine utilizing enzyme was estimated by gel filtration on a Sephadex G-200 column and found to be approximately 70 000. Based on product formation, molecular weight estimation and copurification with the activity responsible for p-nitroanilide release from gamma-glutamyl-p-nitroanilide, we conclude that this reaction is catalyzed by gamma-glutamyltranspeptidase. Glycylglycine stimulated this enzyme to produce more ammonia while decreasing the appearance of glutamate; in contrast, the mitochondrial glutaminase was unaffected by glycylglycine. This extramitochondrial glutamine utilizing pathway can make a significant contribution to in vivo renal ammoniagenesis.     

Formation of N epsilon-(gamma-glutamyl)-lysine isodipeptide in Chinese-hamster ovary cells.

N epsilon-(gamma-Glutamyl)-lysine isodipeptide was detected in a protein-free fraction of Chinese-hamster ovary cells and their culture fluid by using radioactive lysine as a tracer. The identity of the isodipeptide was established by its separation on ion-exchange chromatography, analysis by h.p.l.c. after derivatization, recovery of lysine after acidic hydrolysis or after cleavage by a specific enzyme, namely gamma-glutamylamine cyclotransferase. The amount of isodipeptide was raised (460 pmol/10(7) cells and 61 pmol/ml of culture fluid were observed as highest values) as the cell density increased. Effects of inhibitors of intracellular protein degradation have shown that the isodipeptide derives from cross-linking N epsilon-(gamma-glutamyl)-lysine bonds formed by tissue transglutaminase. Estimated half-life values of cross-linked proteins were about 3 h. gamma-Glutamylamine cyclotransferase, which may split the isodipeptide formed during the continuous turnover of cross-linked proteins, was also found in Chinese-hamster ovary cells. Isodipeptide may have been accumulated when either its generated amount is beyond the capacity of gamma-glutamylamine cyclotransferase or it is generated in cell compartments where this enzyme is not present.     

Does a modified gamma-glutamyl cycle exist in human erythrocytes (author's transl)]

The first step in the biosynthesis of glutathione is the formation of gamma-glutamyl-cysteine by the enzyme glutamyl-cysteine synthetase. Since this enzyme is not specific for cysteine, different gamma-glutamylamino acids may be formed in vivo which represent potential substrates for the enzymes gamma-glutamylcyclotransferase; in this way 5-oxo-L-proline and free amino acid are formed. We investigated in membrane-free hemolysate the competition between the biosynthesis of glutathione or ophthalmic acid and the degradation of gamma-glutamyl peptides by measuring the formation of 5-oxoproline. The endogenous rate of 5-oxoproline production was 0.13 muM/min. This increased to 2muM/min after addition of 2-aminobutyrate, and to 10muM/min after addition of glutamate and 2-aminobutyrate to hemolysate. Addition of cysteine resulted in an increased oxoproline production only under conditions where glutamyl-cysteine accumulated. In addition, it was shown that for glutamyl-2-aminobutyrate the degradation to 5-oxoproline is faster than the utilization for the tripeptide synthesis. This was not the case for glutamyl-cysteine. Since membrane-free hemolysate (which lacks gamma-glutamyltransferase) is able to produce 5-oxoproline starting from glutamate, it is concluded that this 5-oxoprolinent amino acid transport via a modified gamma-glutamyl cycle.     

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.     

Gamma-glutamyl hydrolase conjugase). Purification and properties of the bovine hepatic enzyme.

Bovine hepatic gamma-glutamyl hydrolase (conjugase) has been purified to homogeneity. A feature of the purification procedure was the use of high affinity macromolecular polyanion enzyme inhibitors which formed tight complexes with the enzyme altering its solubility, gel filtration, and ion exchange properties. The enzyme, which cleaves the gamma-glutamyl bonds of pteroylpolyglutamates, has a molecular weight of 108,000. It is a glycoprotein with an acid pH optimum, properties consistent with its lysosomal localization. Zinc is essential for enzyme stability. The presence of highly reactive sulfhydryl groups was evident from the extreme sensitivity to oxidizing agents and organomercurials. Very little thermal denaturation occurs below 65 degrees, but the enzyme is extremely sensitive to 0uffer anions, in keeping with the polyanionic nature of the substrate. In order to study the mechanism of action of the enzyme, a wide range of pteroylpolyglutamates, N-t-Boc polyglutamates and free polyglutamates were synthesized containing L-[U-14C]glutamic acid residues in different positions. Two pteroyltriglutamate derivatives were also synthesized in which an alpha bond replaced one of the two available gamma bonds. Time course studies of the products of the action of conjugase on these various substrates enabled us to draw the following conclusions about the enzyme: (a) peptide bond cleavage occurred only at gamma-glutamyl bonds and the presence of a COOH-terminal gamma bond was essential for enzyme action; (b) bond cleavage occurred with equal facility at internal points of the peptide chain and the enzyme should therefore be more appropriately classified as an acid hydrolase; (c) longer chain gamma-glutamyl peptides were preferentially attacked by the enzyme, the cleavage of diglutamyl peptides being extremely slow; and (d) cleavage of gamma bonds was independent of the NH2-terminal pteroyl moiety. Studies with polyanions such as the glycosaminoglycans and dextran sulfate supported the concept that the polyanion structure of the substrate was a major factor in substrate-active site interaction.     

Human kidney gamma-glutamyl transpeptidase. Catalytic properties, subunit structure, and localization of the gamma-glutamyl binding site on the light subunit.

Human kidney gamma-glutamyl transpeptidase has been purified by a procedure involving Lubrol extraction, acetone precipitation, treatment with bromelain, and column chromatography on DEAE-cellulose and Sephadex G-150. The final preparation is a glycoprotein (molecular weight of approximately 84,000) composed of two nonidentical glycopeptides (molecular weights of 62,000 and 22,000). The isozymic forms, separable by isoelectric focusing, have different contents of sialic acid. The utilization of L-glutamine (which is both a gamma-glutamyl donor and acceptor) is stimulated about 3-fold by maleate in contrast to 10-fold stimulation of glutamine utilization by the rat kidney enzyme. The gamma-glutamyl analogs, 6-diazo-5-oxo-L-norleucine (DON) and L-azaserine inactivate the human kidney enzyme with respect to its transpeptidase and hydrolase activities. Inactivation is prevented by gamma-glutamyl substrates (but not by acceptor substrates) and is accelerated by maleate. [14C]DON reacts covalently and stoichiometrically at the gamma-glutamyl site, which was localized to the light subunit of the enzyme. The light subunit of human transpeptidase closely resembles that of rat kidney enzyme in having the gamma-glutamyl binding site, and similar molecular weight and amino acid composition. The heavy subunits of the two enzymes are markedly different in both molecular weight and amino acid content; this may account for differences observed in acceptor amino acid specificity and in the magnitude of the maleate effect.     

Partial purification and some properties of gamma-glutamyl transpeptidase from human bile.

1. Gamma-Glutamyl transpepetidase ((5-glutamyl)-peptide: amino acid 5-glutamyltransferase, EC 2.3.2.2) from human bile has been partially purified using protamine sulphate treatment, DEAE-cellulose chromatography and Sephadex G-200 filtration. The procedure resulted in 150-fold increase in specific acitivity with a 37% yield. 2. The partially purified enzyme showed a single zone of enzyme activity by polyacrylamide gel electrophoresis and eluted in the inner volume of Sephadex G-200. 3. The enzyme had a pH optimum of 8.1 and Km of 1.52 mM using gamma-glutamyl p-nitroanilide as substrate. 4. The effects of cations and different gamma-glutamyl acceptors on the activity of the enzyme are reported. 5. As bile gamma-glutamyl transpeptidase appears to be soluble in the absence of detergents, it is suggested that bile may prove to be a useful source for further studies of the kinetic properties and physiological role of human gamma-glutamyl transpeptidase.     

Spectrophotometric assays for L-lysine alpha-oxidase and gamma-glutamylamine cyclotransferase

A new assay for l-lysine alpha-oxidase is described. In this assay, the oxidized product generated from l-lysine is reacted with semicarbazide to form alpha-keto-epsilon-aminocaproate semicarbazone. Formation of the alpha-keto acid semicarbazone is continuously monitored spectrophotometrically at 248 nm (epsilon 10,160 +/- 240 M(-1) cm(-1)). The method was adapted to provide a new assay for gamma-glutamylamine cyclotransferase. This enzyme catalyzes the conversion of many l-gamma-glutamylamines to 5-oxo-l-proline and free amine. A biologically important substrate is N(epsilon)-(gamma-l-glutamyl)-l-lysine, which is converted to 5-oxo-l-proline and l-lysine by the action of gamma-glutamylamine cyclotransferase. The l-lysine generated from N(epsilon)-(gamma-l-glutamyl)-l-lysine in an endpoint assay is converted to alpha-keto epsilon-aminocaproate semicarbazone in the presence of semicarbazide, excess l-lysine alpha-oxidase, and catalase. The methods were applied to the determination of gamma-glutamylamine cyclotransferase activity of partially purified preparations of the bovine kidney enzyme and to detect gamma-glutamylamine cyclotransferase activity in rat kidney and liver homogenates.     

Studies of human kidney gamma-glutamyl transpeptidase. Purification and structural, kinetic and immunological properties.

gamma-Glutamyl transpeptidase, present in various mammalian tissues, transfers the gamma-glutamyl moiety of glutathione to a variety of acceptor amino acids and peptides. This enzyme has been purified from human kidney cortex about 740-fold to a specific activity of 200 units/mg of protein. The purification steps involved incubation of the homogenate at 37 degrees followed by centrifugation and extraction of the sediment with 0.1 M Tris-HCl buffer, pH 8.0, containing 1% sodium deoxycholate; batchwise absorption on DEAE-cellulose; DEAE-cellulose (DE52) column chromatography; Sephadex G-200 gel filtration; and affinity chromatography using concanavalin A insolubilized on beaded Agarose. Detergents were used throughout the purification of the enzyme. The purified enzyme separated into three protein bands, all of which had enzyme activity, on polyacrylamide disc electrophoresis in the presence of Triton X-100. The enzyme has an apparent molecular weight of about 90,000 as shown by Sephadex G-200 gel filtration, and appears to be a tetramer with subunits of molecular weights of about 21,000. The Km for gamma-glutamyl transpeptidase using the artificial substrate, gamma-glutamyl-p-nitroanilide, with glycylglycine as the acceptor amino acid was found to be about 0.8 mM. The optimum pH for the enzyme activity is 8.2 and the isoelectric point is 4.5. Both GSH and GSSG competitively inhibited the activity of gamma-glutamyl transpeptidase when gamma-glutamyl-p-nitroanilide was used as the substrate. Treatment of the purified enzyme with papain has no effect on the enzyme activity or mobility on polyacrylamide disc electrophoresis. The purified gamma-glutamyl transpeptidase had no phosphate-independent glutaminase activity. The ratio of gamma-glutamyl transpeptidase to phosphate-independent glutaminase changed significantly through the initial steps of gamma-glutamyl transpeptidase purification. These studies indicate that the transpeptidase and phosphate-independent glutaminase activities are not exhibited by the same protein in human kidney.     

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.     

A novel mechanism for group translocation: substrate-product reutilization by gamma-glutamyl transpeptidase in peptide and amino acid transport.

Gamma-glutamyl transpeptidase (gamma-GTP) is suggested to act as a carrier in the group translocation of oligopeptides and possibly some amino acids across cellular membranes. It is proposed that the process may involve the repetitive transfer of gamma-glutamyl groups to acceptor peptides which are being translocated from the exterior of the cell to its interior. After group translocation of the peptides has occurred with concomitant formation of gamma-glutamyl peptide products, it is suggested that the products might then be utilized as substrate for the enzyme in order to permit the translocation of other peptides from the exterior. The system is economical and requires only that it be primed with an appropriate source of gamma-glutamyl peptides, such as glutathione. In contrast to most group translocation systems previously described, substrate-product reutilization by gamma-GTP would not be expected to accumulate peptides against a concentration gradient. Mechanisms for maintaining low intracellular concentrations of the translocated peptides are described. Studies on acceptor substrate specificity of gamma-GTP from bovine choroid plexus and rat kidney show some glycyl peptides are much better substrates than free amino acids in accord with the proposal that gamma-GTP might be primarily involved in peptide translocation. Both kinetic and topological evidence support the suggestion that repetitive transfer of gamma-glutamyl moieties by gamma-GTP could occur during group translocation of peptides and possibly some amino acids.     

PARTIAL PURIFICATION AND KINETICS OF γ-GLUTAMYL TRANSPEPTIDASE FROM BOVINE CHOROID PLEXUS

Abstract— γ-Glutamyl transpeptidase from bovine choroid plexus has been shown to be a membrane-bound enzyme. Partial purification of the enzyme has been accomplished using detergent extraction and ammonium sulfate fractionation. Important determinants of enzymatic activity with acceptor substrates included chain length, stereoisomerism, and amino acid composition of the acceptors. L-Methionine was the best amino acid substrate and its corresponding peptides L-methionylmethionine and L-methionyl-L-serine were also good γ-glutamyl acceptors. L-Alanine and glycine were poor acceptor substrates; whereas, some peptides containing these amino acids were excellent substrates. Glycylglycine was significantly more effective as a γ-glutamyl acceptor than glycine, triglycine, or tetraglycine. L-Alanylglycine was a superior acceptor to glycine, L-alanine, or L-alanylglycylglycine, while the D-isomer of alanylglycine was only minimally effective as an acceptor substrate. In general glycyl peptides were the best acceptor substrates examined. Our findings that γ-glutamyl transpeptidase could catalyze the transfer of γ-glutamyl groups to glycylglycyl-L-alanine and L-alanylglycylglycine are of special interest, since few examples of tripeptide acceptors for the enzyme have been found. It is suggested that γ-glutamyl transpeptidase might play a role in the inactivation and/or transport of biologically active peptides.     

Purification and properties of gamma-glutamylcyclotransferase from human erythrocytes.

1. GAMMA-Glutamylcyclotransferase was purified 10000-fold from human erythrocytes. 2. The purification steps involved fractionation with (NH4)(2)SO(4) and chromatography on Sephadex G-75, DEAE-cellulose and hydroxyapatite. The purified enzyme was found to be homogeneous on density-gradient polyacrylamide-gel electrophoresis. 3. The maximum reaction rate was observed at pH9.0 and the apparent Km value for gamma-glutamyl-L-alanine was 2.2mM. 4. The molecular weight (25250) of the purified enzyme agreed well with the value (25500) in fresh haemolysates, indicating no apparent structural modification of the enzyme during purification. However, rapid processing of the blood through the initial (NH4)(2)SO(4) and Sephadex-chromatography steps was required to prevent formation of a high-molecular-weight aggregate with substantially lower specific activity. 5. gamma-Glutamylcyclotransferase catalyses the formation of 5-oxoproline from gamma-glutamyl dipeptides. The role of this enzyme in erythrocytes is of particular interest, because gamma-glutamyl-L-cysteine serves as a substrate for both gamma-glutamylcyclotransferase and glutathione synthetase. Thus the cyclotransferase could modulate glutathione synthesis.     

Activation of transglutaminase and production of protein-bound gamma-glutamylhistamine in stimulated mouse mast cells

The identification of transglutaminase in the growth-factor-dependent mouse mast cell line PT18 was accomplished through its characteristic catalytic properties (specificity, calcium dependency, and inhibition by iodoacetamide); and by both immunoprecipitation and Western blot analysis using affinity purified antibody. The enzymatic activity in these cells increased in association with the release of histamine from the cells induced by an IgE-dependent mechanism or by exposure to the ionophores A23187 or Br-x537A. The increase in transglutaminase activity was paralleled by a marked increase in the level of protein-bound gamma-glutamylhistamine, determined in radiolabeled form in mast cells that were either metabolically labeled with [3H]histidine or incubated with [3H]histamine before degranulation. The highest level of bound gamma-glutamylhistamine was found in the immunologically stimulated cells. Enzymatic activity and the gamma-glutamyl derivative were associated primarily with the cells, both before and after stimulation. Separation of gamma-glutamylhistamine in a proteolytic digest of these cells was carried out using a combination of ion exchange chromatography and high performance liquid chromatography. The gamma-glutamyl compound was identified and quantitated through the enzymatic production of histamine with the use of gamma-glutamylamine cyclotransferase, an enzyme specific for the disassembly of gamma-glutamylamines.     

The donor specificity and kinetics of the hydrolysis reaction of gamma-glutamyltransferase

The donor specificity of the hydrolytic reaction of gamma-glutamyltransferase [5-glutamyl)-peptide:amino-acid 5-glutamyltransferase, EC 2.3.2.2) has been studied by the use of specifically synthesised gamma-glutamyl substrates. It was found that a wide variety of gamma-glutamylated adducts were hydrolysed by the enzyme. The structure of the adduct was relatively unimportant for donor specificity and the enzyme appears to 'recognise' the gamma-glutamyl portion of the donor molecule. In particular the alpha-amino group and the free proton of the gamma-peptide bond appear to be essential for donor activity. The Vmax of hydrolysis increased proportionally to the electron-withdrawing capacity of the adduct moiety. The rate of formation of gamma-glutamyl-enzyme intermediate was therefore dependent upon the structure of the adduct of the gamma-glutamyl donor. The results suggest that the enzyme shows little specificity beyond that for gamma-glutamyl amides and there is therefore no reason to postulate the presence of a specific glutathione-binding site.     

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.