Inactivation of bacterial glutamine synthetase by ADP-ribosylation

Glutamine synthetase from Escherichia coli was inactivated by chemical modification with arginine-specific reagents (Colanduoni, J. A., and Villafranca, J. J. (1985) Biochem. Biophys. Res. Commun. 126, 412-418). E. coli glutamine synthetase was also a substrate for an erythrocyte NAD:arginine ADP-ribosyltransferase. Transfer of one ADP-ribosyl group/subunit of glutamine synthetase caused loss of both biosynthetic and gamma-glutamyltransferase activity. The ADP-ribose moiety was enzymatically removed by an erythrocyte ADP-ribosylarginine hydrolase, resulting in return of function. The site of ADP-ribosylation was arginine 172, determined by isolation of the ADP-ribosylated tryptic peptide. Arginine 172 lies in a central loop that extends into the core formed by the 12 subunits of the native enzyme. The central loop is important in anchoring subunits together to yield the spatial orientation required for catalytic activity. ADP-ribosylation may thus inactivate glutamine synthetase by disrupting the normal subunit alignment. Enzyme-catalyzed ADP-ribosylation may provide a simple, specific technique to probe the role of arginine residues in the structure and function of proteins.     

Inactivation of pea seed glutamine synthetase by the toxin, tabtoxinine-beta-lactam

Glutamine synthetase of plants is the physiological target of tabtoxinine-beta-lactam, a toxin produced by several disease-causing pathovars of Pseudomonas syringae. This toxin, a unique amino acid, is an active site-directed, irreversible inhibitor of glutamine synthetase from pea. ATP is required for inactivation. Neither ADP, AMP, nor adenosine 5'-(beta,gamma-methylene)triphosphate (AMP-PCP) supports inactivation. Adenyl-5'-yl imidophosphate (AMP-PNP) is slowly hydrolyzed by glutamine synthetase to produce adenyl-5'-yl phosphoramidate (AMP-PN) and inorganic phosphate as identified by 31P NMR spectroscopic analysis. AMP-PNP also supports a slow inactivation of glutamine synthetase by tabtoxinine-beta-lactam. These data are consistent with gamma-phosphate transfer being involved in the inactivation. Completely inactivated glutamine synthetase has 0.9 mumol of toxin bound/mumol of subunit. One mumol of ATP is bound per mumol of subunit of glutamine synthetase in the absence of either the toxin or another active site-directed inhibitor, methionine sulfoximine; whereas, a 2nd mumol of either [alpha- or gamma-32P]ATP is bound per mumol of subunit when glutamine synthetase is incubated in the presence of either toxin or methionine sulfoximine until all enzyme activity is lost. These data suggest that the gamma-phosphate hydrolyzed from ATP during inactivation remains with the enzyme-inhibitor complex, as well as the ADP. The open chain form, tabtoxinine, was neither a reversible nor an irreversible inhibitor of glutamine synthetase, suggesting that the beta-lactam ring is necessary for inhibition. The inactivation of glutamine synthetase with tabtoxinine-beta-lactam is pseudo-first-order when done in buffer containing 15% (v/v) ethylene glycol. The rate constant for this reaction is 3 X 10(-2) S-1, and the Ki for the toxin is 1 mM. Removal of the ethylene glycol from the buffer allows the reaction to proceed in a non-first-order manner with the apparent rate constant decreasing with time. As the enzyme is inactivated in these conditions, the binding affinity for the toxin appears to decrease, while the Km observed for glutamate does not change.     

Inactivation of Escherichia coli glutamine synthetase by thiourea trioxide

Incubation of Escherichia coli glutamine synthetase with thiourea trioxide resulted in partial inactivation of the enzyme. This reagent specifically modifies lysine residues to form homoarginine. By amino acid analysis 2.3 ± 0.3 residues of homoarginine are produced per enzyme subunit after treatment with thiourea trioxide. Previously we determined that thiourea dioxide totally inactivated glutamine synthetase and modified both lysine and histidine residues (J. Colanduoni and J. J. Villafranca (1985) J. Biol. Chem. 260, 15,042–15,050). Thiourea trioxide reacted with the same lysine residues of glutamine synthetase as thiourea dioxide. The K_m values for the thiourea trioxide modified enzyme were determined and are 210 ± 30 μm and 10 ± 1 mm for ATP and glutamate, respectively. Both values are about threefold higher than for native enzyme assayed under the same conditions. Fluorescence titrations of native and thiourea trioxide labeled enzyme showed that ATP binding was virtually unchanged by the modification while glutamate and methionine sulfoximine bound about twofold more weakly to the modified enzyme.     

Inactivation of Bacillus subtilis glutamine synthetase by metal-catalyzed oxidation.

Instability of Bacillus subtilis glutamine synthetase in crude extracts was attributed to site-specific oxidation by a mixed-function oxidation, and not to limited proteolysis by intracellular serine proteases (ISP). The crude extract from B. subtilis KN2, which is deficient in three intracellular proteases, inactivated glutamine synthetase similarly to the wild-type strain extract. To understand the structural basis of the functional change, oxidative modification of B. subtilis glutamine synthetase was studied utilizing a model system consisting of ascorbate, oxygen, and iron salts. The inactivation reaction appeared to be first order with respect to the concentration of unmodified enzyme. The loss of catalytic activity was proportional to the weakening of subunit interactions. B. subtilis glutamine synthetase was protected from oxidative modification by either 5 mM Mn2+ or 5 mM Mn2+ plus 5 mM ATP, but not by Mg2+. The CD-spectra and electron microscopic data showed that oxidative modification induced relatively subtle changes in the dodecameric enzyme molecules, but did not denature the protein. These limited changes are consistent with a site-specific free radical mechanism occurring at the metal binding site of the enzyme. Analytical data of the inactivated enzyme showed that loss of catalytic activity occurred faster than the appearance of carbonyl groups in amino acid side chains of the protein. In B. subtilis glutamine synthetase, the catalytic activity was highly sensitive to minute deviations of conformation in the dodecameric molecules and these subtle changes in the molecules could be regarded as markers for susceptibility to proteolysis.     

Inactivation of human gamma-glutamylcysteine synthetase by cystamine. Demonstration and quantification of enzyme-ligand complexes.

Human erythrocyte gamma-glutamylcysteine synthetase is inactivated by the disulfide cystamine (2,2'-dithiobis-(ethylamine)) at pH 8.2 with a rate constant of 1020 min-1 mM-1. Magnesium ion and various combinations of substrates and products confer differing degrees of protection against cystamine inactivation, thus allowing the detection and quantification of certain enzyme-ligand interactions. By measuring inactivation rates as a function of ligand concentrations in incomplete reaction mixtures, we have obtained evidence for the following complexes: enzyme . Mg2+; enzyme . Mg2+ . MgATP2-; enzyme . Mg2+ . L-glutamate; enzyme . Mg2+ . MgATP2- . L-glutamate; enzyme . Mg2+ . L-gamma-glutamyl-L-alpha-aminobutyrate. The data also imply the existence of enzyme . (Mg2+)2 . MgATP2- . L-glutamate and several enzyme forms resulting from the weak binding to L-alpha-aminobutyrate. The methods used permit the calculation of cystamine inactivation rates for most of these enzyme forms and also give values for the equilibrium constants describing their formation.     

Inactivation of glutamine synthetase by adenylylation in intact cells of E. coli

Summary The adenine pool of a purineless mutant of E. coli was radioactively labelled by short incubation with ¹⁴C-adenine.The glutamine synthetase was inactivated in vivo by incubation of the cell suspension with 2x10^-3 M NH₄ ⁺ for 2 min. The inactivated glutamine synthetase was extracted from the cells and purified 20-fold.Incubation of the purified glutamine synthetase with phosphodiesterase regenerated the biosynthetic activity of the enzyme paralleled by the liberation of ¹⁴C-adenine and ¹⁴C-adenosine. ¹⁴C-adenine and ¹⁴C-adenosine were also obtained when inactivated glutamine synthetase, prepared in vitro by use of ¹⁴C-ATP and purified adenylylating enzyme, was incubated with phosphodiesterase under the same conditions.The similar liberation of adenine derivatives by phosphodiesterase from glutamine synthetase inactivated in a cell-free system as well as in intact cells, demonstrates that in both cases the inactivation consists in an adenylylation of the enzyme.     

Inactivation of glutamine synthetase by a purified rabbit liver microsomal cytochrome P-450 system

Several mixed-function oxidation systems catalyze inactivation of Escherichia coli glutamine synthetase and other key metabolic enzymes. In the presence of NADPH and molecular oxygen, highly purified preparations of cytochrome P-450 reductase and cytochrome P-450 (isozyme 2) from rabbit liver microsomes catalyze enzyme inactivation. The inactivation reaction is stimulated by Fe(III) or Cu(II) and is inhibited by catalase, Mn(II), Zn(II), histidine, and the metal chelators o-phenanthroline and EDTA. The inactivation of glutamine synthetase is highly specific and involves the oxidative modification of a histidine in each glutamine synthetase subunit and the generation of a carbonyl derivative of the protein which forms a stable hydrazone when treated with 2,4-dinitrophenylhydrazine. We have proposed that the mixed-function oxidation system (the cytochrome P-450 system) produces Fe(II) and H2O2 which react at the metal binding site on the glutamine synthetase to generate an activated oxygen species which oxidizes a nearby susceptible histidine. This thesis is supported by the fact that (a) Mn(II) and Zn(II) inhibit inactivation and also interfere with the reduction of Fe(III) to Fe(II) by the P-450 system; (b) Fe(II) and H2O2 (anaerobically), in the absence of a P-450 system, catalyze glutamine synthetase inactivation; (c) inactivation is inhibited by catalase; and (d) hexobarbital, which stimulates the rate of H2O2 production by the P-450 system, stimulates the rate of glutamine synthetase inactivation. Moreover, inactivation of glutamine synthetase by the P-450 system does not require complex formation because inactivation occurs when the P-450 components and the glutamine synthetase are separated by a semipermeable membrane. Also, if endogenous catalase is inhibited by azide, rabbit liver microsomes catalyze the inactivation of glutamine synthetase.     

Different nitrogen sources modulate activity but not expression of glutamine synthetase in arbuscular mycorrhizal fungi

Glutamine synthetase (GS) is a central enzyme of nitrogen metabolism that allows assimilation of nitrogen and biosynthesis of glutamine. We isolated the cDNA encoding GS from two arbuscular mycorrhizal fungi, Glomus mosseae (GmGln1) and Glomus intraradices (GiGln1). The deduced protein orthologues have a high degree of similarity (92%) with each other as well as with GSs from other fungi. GmGln1 was constitutively expressed during all stages of the fungal life cycle, i.e., spore germination, intraradical and extraradical mycelium. Feeding experiments with different nitrogen sources did not induce any change in the mRNA level of both genes independent of the symbiotic status of the fungus. However, GS activity of extraradical hypahe in G. intraradices was considerably modulated in response to different nitrogen sources. Thus, in a N re-supplementation time-course experiment, GS activity responded quickly to addition of nitrate, ammonium or glutamine. Re-feeding with ammonium produced a general increase in GS activity when compared with hyphae grown in nitrate as a sole N source.     

Inducers of gamma-glutamylcysteine synthetase and their effects on glutathione synthetase expression

Synthesis of GSH occurs via two enzymatic steps, the first is catalyzed by gamma-glutamylcysteine synthetase (GCS) and the second is catalyzed by GSH synthetase (GS). A heavy (HS) and light subunit (LS) make up GCS; regulation of both subunits have been well characterized, whereas regulation of GS is largely unknown. In this study, we examined the effects of treatments known to influence the gene expression of GCS subunits on GS expression. Insulin and hydrocortisone treatment of rat hepatocytes or ethanol-feeding of rats for 9 weeks, which increased the expression of GCS-HS only, had no influence on GS expression. However, two-thirds partial hepatectomy in rats which increased the expression of GCS-HS only, also increased GS expression. Treatment of hepatocytes or rats with diethyl maleate, buthionine sulfoximine, tert-butylhydroquinone, or thioacetamide, which increased the expression of both GCS subunits, increased the expression of GS. The GSH synthesis capacity increased 50-100% by treatments that increased only the GCS-HS expression, whereas it increased 161-200% by treatments that increased both GCS-HS and GS expression. Thioacetamide treatment of Chang cells increased cell GSH and GS expression by 50%, but had minimal influence on GCS subunits. Thus, GS induction can further increase the cell's GSH synthetic capacity and in some cells may be as important as GCS in determining the rate of GSH synthesis.     

Bovine lens gamma-glutamylcysteine synthetase. Inhibition by glutathione and adenine nucleotides

Steady-state kinetic analysis shows that glutathione binds reversibly to both Mg . enzyme and Mg . enzyme . L-glutamate forms of gamma-glutamylcysteine synthetase to form inactive complexes. The Ki values for binding to these two species of enzyme are 4 mM and 0.4 mM, respectively; those for S-methyl glutathione are 16 mM and 0.5 mM, respectively. These data suggest that glutathione is an important feedback inhibitor and contributes to the regulation of glutathione synthesis by modulating the synthesis rate of the precursor dipeptide. Adenosine 5'-diphosphate (5'ADP) is also an inhibitor and competes with both ATP and L-beta-chloroalanine for Mg . enzyme . L-glutamate and Mg . enzyme . L-glutamylphosphate, respectively. Under physiological conditions in the lens, 5' ADP competes effectively with L-cysteine for Mg . enzyme . L-glutamylphosphate, owing to the low concentration of L-cysteine, and less effectively with ATP for Mg . enzyme . L-glutamate, because of a high concentration of ATP.     

Biochemical and biophysical characterization of Leishmania donovani gamma-glutamylcysteine synthetase

γ-glutamylcysteine synthetase (Gcs) is a vital enzyme catalyzing the first and rate limiting step in the trypanothione biosynthesis pathway, the ATP-dependent ligation of L-Glutamate and L-Cysteine to form gamma-glutamylcysteine. The Trypanothione biosynthesis pathway is unique metabolic pathway essential for trypanosomatid survival rendering Gcs as a potential drug target. Here we report the cloning, expression, purification and characterization of L. donovani Gcs. Three other constructs of Gcs (GcsN, GcsC and GcsT) were designed on the basis of S. cerevisiae and E. coli Gcs crystal structures. The study shows Gcs possesses ATPase activity even in the absence of substrates L-glutamate and L-Cysteine. Divalent ions however plays an indispensable role in LdGcs ATPase activity. Isothermal titration calorimetry and fluorescence studies illustrates that L. donovani Gcs binds substrate in order ATP >L-glutamate>L-cysteine with Glu 92 and Arg 498 involved in ATP hydrolysis and Glu 92, Glu 55 and Arg 498 involved in glutamate binding. Homology modeling and molecular dynamic simulation studies provided the structural rationale of LdGcs catalytic activity and emphasized on the possibility of involvement of three Mg²⁺ ions along with Glutamates 52, 55, 92, 99, Met 322, Gln 328, Tyr 397, Lys 483, Arg 494 and Arg 498 in the catalytic function of L. donovani Gcs.     

Inactivation of skeletal glycogen synthetase by diethylpyrocarbonate

Glycogen synthetase from skeletal muscle is rapidly inactivated by DEPC. In the presence of the substrate UDPG only 50% of the enzyme activity is lost. The concomitant addition of both UDPG and the allosteric activator glucose-6-phosphate almost completely prevents the inactivation by DEPC. Since glucose-6-phosphate alone does not prevent the inactivation by DEPC, it is concluded that it is effective through a potentiation of the effects of UDPG, possibly through a conformational change of the enzyme.     

Substrate binding determinants of Trypanosoma brucei gamma-glutamylcysteine synthetase

gamma-Glutamylcysteine synthetase (gamma-GCS) catalyzes the ATP-dependent ligation of L-Glu and L-Cys, which is the first step in de novo biosynthesis of the tripeptide glutathione. Recently it was demonstrated that gamma-GCS is a structural homologue of glutamine synthetase (GS), providing the basis to build a model for the gamma-GCS active site [Abbott et al. (2001) J. Biol. Chem. 276, 42099-42107]. Substrate binding determinants in the active site of gamma-GCS have been identified and characterized in the enzyme from the parasitic protozoa Trypanosoma brucei using this model as a guide for site-directed mutagenesis. R366 and R491 were identified as key determinants of L-Glu binding. Mutation of R366 to Ala increases the K(d) for L-Glu by 160-fold and eliminates the positive cooperativity observed for the binding of L-Glu and ATP to the wild-type enzyme, based on a rapid equilibrium random mechanism of substrate binding. Unlike the wild-type enzyme, the R366A mutant enzyme was able to form product using the substrate analogue gamma-aminobutyric acid, suggesting that R366 interacts with the alpha-carboxylate of L-Glu. Mutation of R491 to Ala decreased k(cat) for ATP hydrolysis by 70-fold; however, dipeptide product was only formed in 5% of these turnovers. These data suggest that R491 stabilizes the phosphorylated gamma-carboxylate of L-Glu during nucleophilic attack by the L-Cys to form the dipeptide product. T323, R474, and R487 were predicted to be ATP binding determinants. Mutation of each of these residues to Ala increased the apparent K(m) for ATP by 20-100-fold while having only modest effects on k(cat) or the apparent K(m)'s for the other substrates. Finally, mutation of R179, a conserved residue that is present in gamma-GCS, but not in GS, increased the apparent K(m) for both L-Cys and L-Glu.