Evidence for lumenal and antilumenal localization of gamma-glutamyltranspeptidase in rat kidney

Gamma-Glutamyl-p-nitroanilide (γ-GpNA) utilization was studied using the isolated rat kidney perfused with 1.5 mM γ-glutamyl-p-nitroanilide and 8 mM glycylglycine (glygly). In the absence of glygly, autotransfer products, γ-glu-γ-glu-p-NA appeared in the perfusate while glutamate, the hydrolytic product, appeats in the urine. In the presence of glygly, p-nitroaniline (p-NA) formation was stimulated 3-fold with the appearance of γ-gluglygly as the major product in both the perfusate and urine. Under conditions of single pass perfusion, 89 percent of the γ-glutamyl-p-nitroanilide utilization occurs on the antilumenal border and only 11 percent on the lumenal border; ureter ligation reduced glomerular filtration 90 percent but does not significantly reduce utilization. However, reducing the perfusate flow rate of the antilumenal side to that of the lumenal results in a utilization rate which is approximately one-third that of the lumenal, suggesting that the lumenal border enzyme is at least 3 times in excess of the antilumenal border enzyme.     

Phosphate-independent glutaminase from rat kidney. Partial purification and identity with gamma-glutamyltranspeptidase.

Phosphate-independent glutaminase can be quantitatively solubilized from a microsomal preparation of rat kidney by treatment with papain. Subsequent gel filtration and chromatography on quaternary aminoethyl (QAE)-Sephadex and hydroxylapatite yield a 200-fold purified preparation of this glutaminase. The purified enzyme also hydrolyzes gamma-glutamylhydroxamate and exhibits substrate inhibition at high concentrations of either glutamine or gamma-glutamyhydroxamate, which is partially relieved by increasing concentrations of maleate. Rat kidney phosphate-independent glutaminase reaction is catalyzed by the same enzyme which catalyzes the gamma-glutamyltranspeptidase reaction. The ratio of glutaminase to transpeptidase activities remained constant throughout a 200-fold purification of this enzyme. The observation that the phosphate0independent glutaminase and gamma-glutamyltranspeptidase activities exhibit coincident mobilities during electrophoresis, both before and after extensive treatment with neuraminidase, strongly suggests that both reactions are catalyzed by the same enzyme. This conclusion is strengthened by the observation that maleate and various amino acids have reciprocal effects on the two activities. Maleate increases glutaminase activity and blocks transpeptidation, whereas amino acids activate the transpeptidase but inhibit glutaminase activity. In contrast, the addition of both maleate and alanine resulted in a strong inhibition of both activities. Both activities exhibit a similar distribution in the various regions of the kidney. Recovery of maximal activities in the outer stripe region of the medulla is consistent with previous quantitative microanalysis which indicated that this glutaminase activity is localized primarily in the proximal straight tubule cells. The glutaminase and transpeptidase activities have different pH optima. Examination of the product specificity suggests that decreasing pH also promotes glutaminase activity and that below pH 6.0, this enzyme functions strictly as a glutaminase. Because of the localization of this activity on the brush border membrane, these resuts are consistent with the possibility that the physiological conditions induced by metabolic acidosis could convert this enzyme from a broad specificity transpeptidase to a glutaminase. Therefore, this enzyme could contribute to the increased renal synthesis of ammonia from glutamine which is observed during metabolic acidosis.     

Kinetic studies of rat kidney gamma-glutamyltranspeptidase deacylation reveal a general base-catalyzed mechanism

The enzyme gamma-glutamyltranspeptidase (GGT) is critical to cellular detoxification and leukotriene biosynthesis processes, as well as amino acid transport in kidneys. GGT has also been implicated in many important physiological disorders, including Parkinson's disease and inhibition of apoptosis. It binds glutathione as a donor substrate and initially forms a gamma-glutamyl-enzyme complex that can then react with a water molecule or an acceptor substrate (usually an amino acid or a dipeptide) to form glutamate or a product containing a new gamma-glutamyl-isopeptide bond, respectively, thus regenerating the free enzyme. Despite its important role in human physiology, the mechanisms of the reactions catalyzed by GGT are not well-known, particularly with respect to the deacylation step. We have synthesized a series of methionine amide derivatives whose alpha-ammonium groups have different pK(a) values. By using these compounds as acceptor substrates for GGT, we have constructed a Br?nsted plot and obtained a good correlation for log(k(norm)(cat,b)/K(b)) versus pK(a)(NH+) with a slope beta(nuc) of 0.84, consistent with a rate-limiting nucleophilic attack of the substrate amine on the acyl-enzyme intermediate. Isotope effect studies have shown that there is a proton in flight at the transition state, consistent with concerted deprotonation of the nucleophilic amine effected by an unidentified general base. A bell-shaped pH-rate profile has also been obtained for the deacylation step, reflecting the pK(a) values of the acceptor substrate (and/or that of a general base residue) and of a putative general acid that may be necessary for reprotonation of the active site nucleophile upon regeneration of the free enzyme. These data allow us to propose for the first time a detailed mechanism for this important step of the GGT-mediated reaction and to speculate about the origin of its acceptor substrate specificity.     

Biochemical and immunologic studies on the native and deglycosylated forms of gamma-glutamyltranspeptidase of rat kidney

We have deglycosylated the enzyme gamma-glutamyl transpeptidase by treatment of the protein with anhydrous hydrofluoric acid at 0 degree C. After deglycosylation, the heavy and light subunits showed a molecular weight of 43 and 23 Kd respectively. Whereas the antiserum against the native enzyme recognized both proteins, the antiserum against the deglycosylated enzyme failed to recognize the native enzyme, indicating that some of the determinants of the native enzyme are masked by the carbohydrate moiety.     

Difference in the sugar chains of two subunits and of isozymic forms of rat kidney gamma-glutamyltranspeptidase

A comparative study by gel-permeation chromatographic analysis of oligosaccharides released from the heavy and the light subunits of rat kidney gamma-glutamyltranspeptidase has revealed that high-mannose-type sugar chains are found only in the heavy subunit, and the nonsialylated and nonfucosylated biantennary complex-type sugar chains are included only in the light subunit. By the same analysis of the oligosaccharide fractions obtained from four isozymic forms of rat kidney gamma-glutamyltranspeptidase, it was found that all these enzymes contain 2 mol of neutral sugar chains but different numbers of acidic sugar chains. The total numbers of sialic acid residues showed a reciprocal relationship to the isoelectric point of each isozymic form, and an increase of 1 mol of sialic acid residue corresponds to a decrease of 0.5 in the value of the isoelectric point.     

Structures of sugar chains of human kidney gamma-glutamyltranspeptidase

gamma-Glutamyltranspeptidase purified from human kidneys contains 4-5 asparagine-linked sugar chains in each molecule. The sugar chains were released from the polypeptide portion of the enzyme by hydrazinolysis as oligosaccharides and separated by paper electrophoresis into one neutral and two acidic fractions. By sequential exoglycosidase digestion and methylation analysis, the neutral fraction, which comprised 69% of total oligosaccharides, was shown to be a mixture of bisected bi- and triantennary complex-type sugar chains with and without a fucose on the proximal N-acetylglucosamine residue and with Gal beta 1----4GlcNAc and/or Gal beta 1----4(Fuc alpha 1----3)GlcNAc groups in their outer chain moieties. The acidic oligosaccharide fractions were mixtures of mono- and disialyl derivatives of bisected triantennary complex-type oligosaccharides with Gal beta 1----4GlcNAc and/or Gal beta 1----4(Fuc alpha 1----3)GlcNAc group in their outer chain moieties. Some of the outer chains of the acidic oligosaccharides were considered to be sialylated X-antigenic structures.     

Immunocytochemical localization of gamma-glutamyltranspeptidase during fetal development of mouse kidney

In the fully developed kidney, gamma-glutamyltranspeptidase is localized predominantly to the apical plasma membrane of the proximal tubules. The appearance of this activity during murine fetal nephrogenesis was quantitated using a sensitive fluorometric assay, and development of membrane polarity was assessed by immunocytochemistry. Specific activity of the transpeptidase in 13-day fetal kidney was approximately 1 mU/mg protein. Between 13-21 days of gestation, total transpeptidase activity increased 7500-fold, whereas specific activity increased 50-fold. At 13 days of gestation, gamma-glutamyltranspeptidase immunoreactivity is localized to the apical surfaces of developing renal vesicles and the proximal segment of the S-shaped tubules. The organized cell structures have tight tubular junctions but lack a well-defined brush-border membrane. By 15 days of gestation, immunostaining of the apical surface of developing proximal segments is more prominent, and slight reactivity of the basolateral membrane is evident. By 17 days of gestation, the kidney is organized into discrete zones. The large increase in gamma-glutamyltranspeptidase activity correlates with the appearance of increased immunostaining of the developing brush-border membranes of the proximal tubules contained in the inner cortex. A very similar although somewhat delayed pattern of appearance of transpeptidase activity and immunostaining was observed in metanephric organ culture. Induction of proximal tubular cyst formation had no effect on the increase in transpeptidase activity that occurred during organotypic nephrogenesis.     

Characterization and physiological function of rat renal gamma-glutamyltranspeptidase.

Rat renal gamma-glutamyltranspeptidase is an intrinsic membrane glycoprotein. The larger of its two subunits is apparently folded into two distinguishable domains which are separated by a protease-sensitive sequence of amino acids. Membrane binding of gamma-glutamyltranspeptidase results from the hydrophobic interaction of the nonpolar domain of the amphipathic subunit with the lipid bilayer. Localization of at least a portion of the gamma-glutamyl binding site on the smaller subunit limits the active site of the enzyme to one side of the membrane. Within the kidney, the enzyme is primarily associated with the luminal surface of the brush border membrane of the proximal straight tubule. Comparison of the kinetic properties of gamma-glutamyltranspeptidase with the pH and the substrates available within the tubular fluid suggests that the physiologically significant reaction catalyzed by the transpeptidase is the hydrolysis of glutathione and its S-derivatives. The glutathionemia and glutathionuria observed in a patient who lacks detectable gamma-glutamyltranspeptidase activity and in mice following specific inhibition of transpeptidase, support the hypothesis that the enzyme plays a major role in glutathione catabolism. It now appears that the activities attributed to the gamma-glutamyl cycle do not participate in amino acid transport, but instead constitute three separate metabolic pathways; the intracellular synthesis of glutathione, the intracellular degradation of gamma-glutamyl peptides and the extracellular hydrolysis of glutathione. The finding that various cells release reduced and oxidized glutathione indicates that glutathione turnover may be a process of intracellular synthesis, excretion and extracellular degradation.     

Biosynthesis and degradation of mammalian glycosphingolipids

Glycolipids are a large and heterogeneous family of sphingolipids that form complex patterns on eukaryotic cell surfaces. This molecular diversity is generated by only a few enzymes and is a paradigm of naturally occurring combinatorial synthesis. We report on the biosynthetic principles leading to this large molecular diversity and focus on sialic acid-containing glycolipids of the ganglio-series. These glycolipids are particularly concentrated in the plasma membrane of neuronal cells. Their de novo synthesis starts with the formation of the membrane anchor, ceramide, at the endoplasmic reticulum (ER) and is continued by glycosyltransferases of the Golgi complex. Recent findings from genetically engineered mice are discussed. The constitutive degradation of glycosphingolipids (GSLs) occurs in the acidic compartments, the endosomes and the lysosomes. Here, water-soluble glycosidases sequentially cleave off the terminal carbohydrate residues from glycolipids. For glycolipid substrates with short oligosaccharide chains, the additional presence of membrane-active sphingolipid activator proteins (SAPs) is required. A considerable part of our current knowledge about glycolipid degradation is derived from a class of human diseases, the sphingolipidoses, which are caused by inherited defects within this pathway. A new post-translational modification is the attachment of glycolipids to proteins of the human skin.     

The activity of gamma-glutamyltranspeptidase in regenerating rat liver

gamma-Glutamyltranspeptidase is expressed at low levels in the liver of the male Fischer 344 rat where it exhibits 15-fold purification and 33% recovery in isolated plasma membranes. While the activity of the enzyme is unaltered in regenerating liver 24 h after partial hepatectomy, it increases steadily thereafter over a period of one week. Seven days after partial hepatectomy the enzyme is maximally activated: 5.6-fold in liver homogenates and 5.3-fold in isolated liver plasma membranes. The enzyme declines in activity over the next fourteen days and is expressed at normal levels three weeks after partial hepatectomy. These results demonstrate that the activity of gamma-glutamyltranspeptidase increases in regenerating liver but that the increase is out of phase with the proliferative response.     

Biosynthesis of dimethyl selenide from sodium selenite in rat liver and kidney cell-free systems

A pathway for the synthesis of dimethyl seledine from sodium selenite was studied in rat liver and kidney fractions under anaerobic conditions in the presence of GSH, a NADPH-generating system, and S-adenosylmethionine. Chromatography of liver or kidney soluble fraction on Sephadex G-75 yielded a Fraction C (30 000 molecular weight) which synthesized dimethyl selenide, but at a low rate. Addition of proteins eluting at the void volume (Fraction A) to Fraction C restored full activity. Fractionation of Fraction A on DEAE-cellulose revealed that its ability to stimulate Fraction C was associated with two fractions, one containing glutathione reductase and the other a NADPH-dependent disulfide reductase. It was concluded that Fraction C contains a methyltransferase acting on small amounts of hydrogen selenide produced non-enzymically by the reaction of selenite with GSH, and that stimulation by Fraction A results partly from the NADPH-linked formation of hydrogen selenide catalyzed by glutathione reductase present in Fraction A. Washed liver microsomal fraction incubated with selenite plus 20 mM GSH also synthesized dimethyl selenide, but addition of soluble fraction stimulated activity. A synergistic effect was obtained when liver soluble fraction was added to microsomal fraction in the presence of a physiological level of GSH (2 mM), whereas at 20 mM GSH the effect was merely additive. The microsomal component of the liver system was labile, had maximal activity around pH 7.5, and was exceedingly sensitive to NaAsO₂ (93% inhibition by 10^?6 M arsenite in the presence of a 20 000-fold excess of GSH). The microsomal activity apparently results from a Se-methyltransferase, possibly a dithiol protein, that methylates hydrogen selenide produced enzymically by the soluble fraction or non-enzymically when a sufficiently high concentration of GSH is used.     

Processing of the propeptide form of rat renal gamma-glutamyltranspeptidase

The biosynthesis of rat renal gamma-glutamyltranspeptidase (EC 2.3.2.2) was studied by sodium dodecyl sulfate gel electrophoresis and fluorography of specific immunoprecipitates obtained at varying times' postinjection with [35S]methionine. At 20 min postinjection 3 endo-beta-N-acetylglucosaminidase H-sensitive bands were observed representing the propeptide (Mr 75 000) large subunit (Mr 49 500) and small subunit (Mr 29 000) of transpeptidase. The alterations in Mr are consistent with removal of 6 N-linked coreoligosaccharides from the propeptide; 4 from the large subunit and 2 from the small subunit. All 3 bands became more diffuse and less endoglycosidase H-sensitive by 40 min and completely resistant by 60 min postinjection. At 20 h postinjection no propeptide remained. Thus, the primary propeptide cleavage reaction occurs prior to the loss of endoglycosidase H sensitivity while about 30% of the propeptide is processed along with the heterodimer and cleaved at a later time.     

Biosynthesis of dimethyl selenide from sodium selenite in rat liver and kidney cell-free systems.

A pathway for the synthesis of dimethyl selenide from sodium selenite was studied in rat liver and kidney fractions under anaerobic conditions in the presence of GSH, a NADPH-generating system, and S-adenosylmethionine. Chromatography of liver or kidney soluble fraction on Sephadex G-75 yielded a Fraction C (30,000 molecular weight) which synthesized dimethyl selenide, but at a low rate. Addition of proteins eluting at the void volume (Fraction A) to Fraction C restored full activity. Fractionation of Fraction A on DEAE-cellulose revealed that its ability to stimulate Fraction C was associated with two fractions, one containing glutathione reductase and the other a NADPH-dependent disulfide reductase. It was concluded that Fraction C contains a methyltransferase acting on small amounts of hydrogen selenide produced non-enzymically by the reaction of selenite with GSH, and that stimulation by Fraction A results partly from the NADPH-linked formation of hydrogen selenide catalyzed by glutathione reductase present in Fraction A. Washed liver microsomal fraction incubated with selenite plus 20 mM GSH also synthesized dimethyl selenide, but addition of soluble fraction stimulated activity. A synergistic effect was obtained when liver soluble fraction was added to microsomal fraction in the presence of a physiological level of GSH (2 mM), whereas at 20 mM GSH the effect was merely additive. The microsomal component of the liver system was labile, had maximal activity around pH 7.5, and was exceedingly sensitive to NaAsO2 (93% inhibition by 10(-6) M arsenite in the presence of a 20,000-fold excess of GSH). The microsomal activity apparently results from a Se-methyltransferase, possibly a dithiol protein, that methylates hydrogen selenide produced enzymically by the soluble fraction or non-enzymically when a sufficiently high concentration of GSH is used.     

The binding and degradation of 125I-labelled insulin by rat kidney brush-border membranes

• 1.1. The interaction of insulin with purified brush-border membranes from rat kidney was studied with the use of [¹²⁵I]insulin.
• 2.2. The specific binding of insulin by brush-borders could be demonstrated, and was time- and temperature-dependent.
• 3.3. [¹²⁵I]insulin was displaced by unlabelled insulin. A₁-B₂₉ dodecoyl insulin and insulin A- and B-chains in proportion to their relative bioactivity.
• 4.4. Brush-border membranes showed high insulin-degrading activity with an apparent K_m of 2.2 μM.
• 5.5. A number of proteinase inhibitors were effective in inhibiting insulin degradation but the greatest degree of inhibition was achieved by the use of thiol-blocking reagents.
• 6.6. No evidence was obtained for the involvement of the enzyme glutathione-insulin transhydrogenase.

     

Biosynthesis and degradation of the endocannabinoid 2-arachidonoylglycerol

2-Arachidonoylglycerol (2-AG) is a monoacylglycerol (MAG) molecule containing an esterified arachidonic acid chain at sn-2 position of the glycerol backbone. Together with structurally similar N-arachidonoylethanolamine (anandamide), 2-AG has been extensively studied as an endogenous ligand of cannabinoid receptors (an endocannabinoid) in brain and other mammalian tissues. Accumulating evidence demonstrates that the endocannabinoid system, including the central-type cannabinoid receptor CB1 and 2-AG, is responsible for synaptic retrograde signaling in the central nervous system. As 2-AG is rapidly formed from membrane phospholipids on cellular stimuli and degraded to arachidonic acid and glycerol, the enzymes catalyzing its biosynthesis and degradation are believed to play crucial roles in the regulation of its tissue levels. The major biosynthetic pathway appears to consist of sequential hydrolyses of inositol phospholipids via diacylglycerol (DAG) by β-type phospholipase C and DAG lipase, while MAG lipase is a principal enzyme in the degradation. In this short review, we will briefly outline rapid advances in enzymological research on the biosynthetic and degradative pathways of 2-AG.