Evidence for the gamma-glutamyl cycle in yeast.

Many previous studies have shown that yeast contains high concentrations of glutathione and enzymes needed for its synthesis. We report here that yeast also contains γ-glutamyl transpeptidase, γ-glutamyl cyclotransferase, dipeptidase, and 5-oxoprolinase activities, suggesting that the γ-glutamyl cycle may be operative in yeast. The presence of the cycle enzymes in yeast offers a simple free-cell system which can probably be adapted to studies on the function of this cycle.     

Transport of the large-neutral amino acids by the gamma-glutamyl cycle: a proposal.

The γ-glutamyl cycle has been proposed by Meister (1973) as one possible mechanism for the mediation of amino acid transport. The high energy requirement of the pathway, the very low specificity of γ-glutamyl transpeptidase and the inability to account for trans membrane stimulation of amino acid entry are but three criticisms of this hypothesis. It is proposed that the various objections can be overcome by postulating that the soluble form of γ-glutamyl transpeptidase transfers the γ-glutamyl moiety from gluthathione to glutamine (in the case of brain) and that the membrane sequestered form of this enzyme catalyzes the exchange of the γ-glutamyl group between γ-glutamyl glutamine and an entering neutral amino acid. The released glutamine leaves the cell. The γ-glutamyl amino acid then passes into the cytoplasm where it is acted upon by either γ-glutamyl cyclotransferase or the soluble γ-glutamyl transpeptidase which transfers the γ-glutamyl group to another molecule of glutamine. It is postulated that access to the membrane-bound enzyme is dependent on the relative lipophilia of the entering large-neutral amino acids. The available data support this mechanism. By regeneration of γ-glutamyl glutamine, a low expenditure of energy is required for the transport process. Specificity of transpeptidation is attained by the constraints of access to the membrane bound enzyme site.     

Localization of gamma-glutamyl transpeptidase in the retinal pigment epithelium and visual receptor cells.

The activities of γ-glutamyl transpeptidase and other enzymes of the γ-glutamyl cycle, a series of reactions that catalyzes the synthesis and utilization of glutathione, were studied in the rabbit retina. Histochemical studies demonstrated that γ-glutamyl transpeptidase is localized in the visual receptor cells and the retinal pigment epithelium. Rat and mouse retinas revealed similar localizations of transpeptidase. These findings are in accord with the view that γ-glutamyl transpeptidase is involved in the transport of amino acids between the retinal pigment epithelium and the avascular visual receptor cells.     

ENZYMES OF THE γ-GLUTAMYL CYCLE IN THE CHOROID PLEXUS AND BRAIN

—The presence of enzymes of the γ-glutamyl cycle in the bovine and rabbit brain and choroid plexus is described. The activities of γ-glutamyl transpeptidase, γ-glutamyl cyclotransferase and γ-glutamyl-cysteine synthetase in the choroid plexus were found to be higher than in the brain. The activity of γ-glutamyl transpeptidase in the choroid plexus was many times higher than the activity of the other enzymes. Brain and choroid plexus γ-glutamyl transpeptidase were activated by Na⁺ and K⁺. Both brain and choroid plexus showed only a very limited capacity to metabolize [¹⁴C]5-oxoproline to ¹⁴CO₂.     

Significance of γ-glutamyl transpeptidase and thiols in amino acid uptake by rat pancreatic islets: Studies with glutamine and leucine

The importance of γ-glutamyl transpeptidase, the key enzyme of the γ-glutamyl cycle and of thiols for the uptake of amino acids into rat pancreatic islets was investigated. Both serine–borate, an inhibitor of γ-glutamy transpeptidase, and serine which does not inhibit this enzyme, but probabaly is a competitive inhibitor of amino acid uptake, inhibited of glutamine. The inhibitory effect of serine-borate was not greater than that of serine alone. The uptake of glutamine was not affected by either GSH (reduced glutathione) or diamide (a thiol oxidant). Niether substances affected the uptake of leucine. The results indicate that the uptake of glutamine by rat pancreatic islets is not dependent on the functioning of γ-glutamyl transpeptidase and that thiols are not important for the uptake of the amino acids glutamine and leucine.     

gamma-Glutamyl transpeptidase in Hydra littoralis.

$\text{Hydra}$$\text{littoralis}$ exhibits high γ-glutamyl transpeptidase activity, i.e., about 12% of the activity (determined with glutathione) of rat kidney. Histochemical studies show that the enzyme is located mainly in the gastric and sub-hypostome regions; the enzyme is also present in the tentacles and basal disc. These results and the presence of other enzymes of the γ-glutamyl cycle suggest that the cycle plays a role in the metabolism of glutathione in hydras and that γ-glutamyl transpeptidase may function in their digestive and absorptive processes and possibly also in the behavioral response to glutathione.     

Glutathione is a physiologic reservoir of neuronal glutamate

Glutamate, the principal excitatory neurotransmitter of the brain, participates in a multitude of physiologic and pathologic processes, including learning and memory. Glutathione, a tripeptide composed of the amino acids glutamate, cysteine, and glycine, serves important cofactor roles in antioxidant defense and drug detoxification, but glutathione deficits occur in multiple neuropsychiatric disorders. Glutathione synthesis and metabolism are governed by a cycle of enzymes, the γ-glutamyl cycle, which can achieve intracellular glutathione concentrations of 1–10 mM. Because of the considerable quantity of brain glutathione and its rapid turnover, we hypothesized that glutathione may serve as a reservoir of neural glutamate. We quantified glutamate in HT22 hippocampal neurons, PC12 cells and primary cortical neurons after treatment with molecular inhibitors targeting three different enzymes of the glutathione metabolic cycle. Inhibiting 5-oxoprolinase and γ-glutamyl transferase, enzymes that liberate glutamate from glutathione, leads to decreases in glutamate. In contrast, inhibition of γ-glutamyl cysteine ligase, which uses glutamate to synthesize glutathione, results in substantial glutamate accumulation. Increased glutamate levels following inhibition of glutathione synthesis temporally precede later effects upon oxidative stress.     

Determination of pyrrolidone carboxylate and gamma-glutamyl amino acids by gas chromatography.

Gas chromatographic methods for the quantitation of pyrrolidone carboxylate and γ-glutamyl amino acids are described. These intermediates of the γ-glutamyl cycle were separated by ion exchange chromatography and converted to their N-acyl-ester derivatives in a reaction with a mixture of 2,2,3,3,3-pentafluoro-1-propanol and pentafluoropropionic anhydride. The derivatives have excellent electron capture properties thus making possible their determination even in small amounts of material of biological origin. The method was applied for the determination of concentrations of pyrrolidone carboxylate in human urine and cerebrospinal fluid, and in the brain, liver, and kidney of the mouse. It was also used to demonstrate the formation in mouse tissues of several γ-glutamyl derivatives of amino acids after administration of the corresponding free amino acid.     

N-terminal [Glu]3 moiety of γ-glutamyl peptides contributes largely to the activation of human calcium-sensing receptor,a kokumi receptor

ABSTRACT

γ-glutamyl peptides have been suggested to impart kokumi properties to foods by activating human calcium-sensing receptor (hCaSR). In this study, the relationship between γ-glutamyl peptide structure and hCaSR activity was systematically analyzed using γ-[Glu]_(n=0-4)-α-[Glu]_(n=0-3)-Tyr. Our results suggest that N-terminal [Glu]₃ moiety is very important for hCaSR activities of γ-glutamyl peptides.     

Glutathione metabolism in Escherichia coli

Glutathione is the most abundant low-molecular-weight thiol compound in aerobic bacterial cells. Although its biosynthetic pathway in Escherichia coli is known, its degradative pathway is not clear. We have studied its degradative pathway using E. coli K-12 as a model bacterium. Glutathione synthesized during the exponential phase of growth is excreted into the medium. During the stationary phase, extra cellular glutathione penetrates into the periplasm where its γ-glutamyl residue is cleaved off by γ-glutamyltranspeptidase localized in the periplasm. The released cysteinylglycine is taken up into the cytoplasm through peptide transport systems and the peptide linkage of cysteinylglycine is cooperatively cleaved by enzymes with cysteinylglycinase activity. The resultant cysteine and glycine are used as cysteine and glycine sources, respectively. This cycle acts as a salvage system for cysteine (glycine) in the cells. γ-Glutamyltranspeptidase, the key enzyme of this cycle, was studied extensively not only from a physiological point of view, but also with the aim of applying this enzyme as a catalyst for the synthesis of useful γ-glutamyl compounds.     

Pathways of glutathione degradation in the yeast Saccharomyces cerevisiae

The degradation of glutathione (GSH) in the yeast Saccharomyces cerevisiae appears to be mediated only by γ-glutamyltranspeptidase and cysteinylglycine dipeptidase. Other enzymes of the γ-glutamyl cycle, γ-glutamyl cyclotransferase and 5-oxo-l-prolinase, are not present in the yeast. In vivo transpeptidation was shown in the presence of a high intracellular level of γ-glutamyltranspeptidase, but only when the de-repressing nitrogen source was a suitable acceptor of the transferase reaction. In contrast, when the de-repressing source was not an acceptor of the transferase reaction (e.g. urea), only glutamate was detected. Intracellular GSH is virtually inert when the level of γ-glutamyltranspeptidase is low. Possible roles for in vivo transpeptidation are discussed.     

Diversity of γ- glutamyl peptides and oligosaccharides,the “kokumi” taste enhancers,in seeds from soybean mini core collections

Soybeans (Glycine max (L,) Merr,) contain γ-glutamyl peptides and oligosaccharides, and these components play an important role in imparting the “kokumi” taste to foods. To gain insight into the genetic diversities and molecular mechanisms of accumulation of γ-glutamyl peptides and oligosaccharides in soybean, we measured the contents of these components using the Japan and World mini core collections. Similar to other previously reported traits, wide variations were detected among the accessions in the core collections with respect to the content of γ-glutamyl peptides and oligosaccharides. We found a positive relationship between the content of γ-glutamyl tyrosine and γ-glutamyl phenylalanine and between the content of raffinose and stachyose. Furthermore, there were unique accessions that included high levels of γ-glutamyl peptides and oligosaccharides. These accessions may be helpful in understanding the accumulation mechanism of γ-glutamyl peptides and oligosaccharides and to increase the “kokumi” taste components in soybean by performing a genetic analysis.     

棉酚对大鼠肾脏γ-谷氨酰转肽酶动力学的影响

本文应用动力学分析观察了棉酚对大鼠肾脏γ-谷氨酰转肽酶(γ-GT)的抑制作用。实验结果证实了棉酚在体外是大鼠肾脏γ-GT的抑制剂,而且抑制常数远小于r-GT的天然抑制剂——马尿酸。在不同浓度的棉酚作用下,改变双底物浓度,测定其活力并应用Lineweaver-Burk双倒数作图法,测得棉酚在两种底物情况下,对γ-GT的抑制作用均呈非竞争性抑制。     

Laboratory evolution of glutathione biosynthesis reveals natural compensatory pathways

The first and highly conserved step in glutathione (GSH) biosynthesis is formation of γ-glutamyl cysteine by the enzyme glutamate-cysteine ligase (GshA). However, bioinformatic analysis revealed that many prokaryotic species that encode GSH-dependent proteins lack the gene for this enzyme. To understand how bacteria cope without gshA, we isolated Escherichia coli ΔgshA multigenic suppressors that accumulated physiological levels of GSH. Mutations in both proB and proA, the first two genes in L-proline biosynthesis, provided a new pathway for γ-glutamyl cysteine formation via the selective interception of ProB-bound γ-glutamyl phosphate by amino acid thiols, likely through an S-to-N acyl shift mechanism. Bioinformatic analysis suggested that the L-proline biosynthetic pathway may have a second role in γ-glutamyl cysteine formation in prokaryotes. Also, we showed that this mechanism could be exploited to generate cytoplasmic redox buffers bioorthogonal to GSH.     

Isolation from bovine brain of a fraction containing capillaries and a fraction containing membrane fragments of the choroid plexus

Combined differential and density gradient centrifugation was used for the isolation of a capillary-rich fraction from the cerebral cortex and a brush border containing fraction from the bovine choroid plexus. The activities of γ-glutamyl transpeptidase and several other marker enzymes were monitored during the fractionation procedure. Electron microscopic examination showed a membrane-rich fraction in the choroid plexus high in γ-glutamyl transpeptidase and 5'-nucleotidase activities. From the brain cortex, a capillary-rich fraction was obtained which was high in γ-glutamyl transpeptidase and alkaline phosphatase activities. A histochemical examination showed γ-glutamyl transpeptidase activity localized in the capillary walls.     

A general method for characterizing naturally occurring folate compounds, illustrated by characterizing Torula yeast (Candida utilis) folates

A method previously found suitable for the chromatographic separation and identification of simpler folates has been extended and found suitable for separating and characterizing all the complex polyglutamyl folyl derivatives occurring naturally. Folates were characterized employing the combined use of analytical DEAE-cellulose chromatography, folylpoly-γ-glutamyl carboxypeptidase digestion, and differential microbiological growth response studies. An observed relation between the log phosphate concentration of the eluting buffer and the number of γ-glutamyl residues in successive pteroylpoly-γ-glutamyl derivatives provides a simple tool for a rapid and accurate identification of folate compounds from their elution profile. Twelve folate compunds present in Torula yeast (Candida utilis) were characterized employing this method; 80% of the total folates appeared to be pteroylpolyglutamates. The method characterizes not only the number of γ-glutamyl residues but also the state of reduction of the pteridine ring and the nature of the 1-C substituents attached.     

Hydrolysis and transfer reactions catalyzed by gamma-glutamyl transpeptidase; evidence for separate substrate sites and for high affinity of L-cystine.

γ-Glutamyl transpeptidase was studied with L- and D-γ-glutamyl-p-nitroanilide as γ-glutamyl donors. No autotranspeptidation occurred with the D-γ-glutamyl donor or when the L-γ-glutamyl donor was used at concentrations lower than 10 μM. The K_m values for hydrolysis were 5 and 31 μM for the L- and D-γ-glutamyl donors, respectively; the corresponding V_max values were identical. The γ-glutamyl donor site of the enzyme thus exhibits low stereospecificity (but high affinity), while the acceptor site exhibits absolute L-specificity. The K_m value for L-cystine as acceptor is very low (30 μM); the same value was obtained with L- and D-γ-glutamyl donors. The data are consistent with a ping pong mechanism and the existence of separate donor and acceptor enzyme sites. The present findings thus extend the usefulness of γ-glutamyl-p-nitro-anilide as a substrate in probing the catalytic behavior of this enzyme.     

Inhibition of muscle actomyosin ATPase activity by mitochondrial ATPase inhibitor.

Ascites hepatoma cell line AH-130 was tested for the ability to transport various amino acids and glutathione before and after γ-glutamyl transpeptidase of the cells was affinity-labeled and inactivated by 6-diazo-5-oxo-L-norleucine, a glutamine analog. The rate of uptake of alanine, glycine, leucine and glutamine by the cells remained unchanged after γ-glutamyl transpeptidase was inactivated by this affinity label. This indicated that γ-glutamyl transpeptidase of the cell was not involved in the transport process of these amino acids tested. The uptake of glutathione was also tested before and after affinity labeling the enzyme. The total amount of the radioactivity incorporated into the cells was not significantly affected by the enzyme inactivation. However, the relative amount of incorporated intact glutathione was found to be slightly but significantly increased after membraneous γ-glutamyl transpeptidase was inactivated by the affinity label, while that of component amino acid, glycine, was found to decrease. This indicated that glutathione was taken up by the cell in its intact form as well as in degraded forms into its component amino acids, and γ-glutamyl transpeptidase in the ascites tumor cell AH-130 seemed to be involved in the metabolic process via the latter system.     

Gamma-glutamyl transpeptidase of rat seminal vesicles; effect of orchidectomy and hormone administration on the transpeptidase in relation to its possible role in secretory activity.

γ-Glutamyl transpeptidase was prepared from rat seminal vesicles by two methods and was found to be similar to rat kidney γ-glutamyl transpeptidase with respect to substrate specificity, stimulation of “glutaminase” activity by maleate, and apparent molecular weight. Histochemical studies demonstrated that γ-glutamyl transpeptidase is concentrated in the secretory epithelium of the seminal vesicle. Like the epithelium itself, the enzyme responds to the presence or absence of testosterone. The content and specific activities of γ-glutamyl transpeptidase and γ-glutamyl cyclotransferase in rat seminal vesicles are low in orchidectomized animals, an effect which is reversed by administration of testosterone but accentuated by estradiol administration. These enzymes may be involved in the secretory functions of the seminal vesicles.     

Direct evidence for inter-organ transport of glutathione and that the non-filtration renal mechanism for glutathione utilization involves γ-glutamyl transpeptidase

A direct examination of the inter-organ cycle of glutathione metabolism was made by determining glutathione levels in plasma obtained from various blood vessels of the rat. High levels of GSH were found in hepatic vein plasma, relative to arterial and systemic venous levels, reflecting translocation of GSH from the liver to the plasma. Renal vein plasma has a level that is 20% of arterial plasma indicating that the kidney removes glutathione from plasma not only by glomerular filtration (which can account for 20–30% of the glutathione removed), but also by a non-filtration mechanism. Inhibitors of γ-glutamyl transpeptidase decrease the fraction of glutathione removed by the kidney to a value approaching that filtered, indicating that the non-filtration mechanism involves γ-glutamyl transpeptidase.