Mechanistic studies of glutamine synthetase from Escherichia coli. An integrated mechanism for biosynthesis, transferase, ATPase reaction.

The mechanism of biosynthetic, transferase, ATPase, and transphosphorylation reactions catalyzed by unadenylylated glutamine synthetase from E. coli was studied. Activation complex(es) involved in the biosynthetic reaction are produced in the presence of either Mg2+ or Mn2+ ; however, with the Mn2+-enzyme inhibition by the product, ADP, is so great that the overall forward biosynthetic reaction cannot be detected with the known assay methods. Binding studies show that substrates (except for NH3 and NH2OH which are not reported here) can bind to the enzyme in a random manner and that binding of the ATP-glutamate, ADP-Pi or ADP-arsenate pairs is strongly synergistic. Inhibition and binding studies show that the same binding site is utilized for glutamate and glutamine in biosynthetic and transferase reactions, respectively, and that a common nucleotide binding site is used for all reactions studied. Studies of the reverse biosynthetic reaction and results of fluorescent titration experiments suggest that both arsenate and orthophosphate bind at a site which overlaps the gamma-phosphate site of nucleoside triphosphate. In the reverse biosynthetic and transferase reactions, ATP serves as a substrate for the Mn2+-enzyme but not for the Mg2+-enzyme. The ATP supported transferase activity of Mn2+-enzyme is probably facilitated by the generation of ADP through ATP hydrolysis. When AMP was the only nucleotide substrate added, it was converted to ATP with concomitant formation of two equivalents of glutamate, under the reverse biosynthetic reaction conditions, and no ADP was detected. The reversibility of 180 transfer between orthophosphate and gamma-acyl group of glutamate was confirmed. ATPase activity of Mg2+ and Mn2+ unadenylylated enzymes is about the same. Both enzymes forms catalyze transphosphorylation reactions between various purine nucleoside triphosphates and nucleoside diphosphates under biosynthetic reaction conditions. The data are consistent with the hypothesis that a single active center is utilized for all reactions studied. Two stepwise mecanisms that could explain the results are discussed.     

Subunit interaction elicited by partial inactivation with L-methionine sulfoximine and ATP differently affects the biosynthetic and gamma-glutamyltransferase reactions catalyzed by yeast glutamine synthetase

Yeast glutamine synthetase can be irreversibly inactivated in the presence of L-methionine sulfoximine, ATP, and a divalent cation Mn2+ or Mg2+. Kinetic studies with partially inactivated enzymes show that inactivation of a given subunit in the octameric glutamine synthetase affects the activities of its neighboring subunit such that the rate of the inactivation as well as the gamma-glutamyltransferase activity of the noninactivated subunits decreases while their biosynthetic activity is enhanced. This outcome of subunit interaction is the same irrespective of whether Mn2+ or Mg2+ is used to fulfill the divalent cation requirement of glutamine synthetase for the inactivation reaction and the gamma-glutamyltransferase reaction. Although only Vmax is affected in the gamma-glutamyltransferase assay, both Km (glutamate) and Vmax are changed in the biosynthetic assay.     

o-Phosphotyrosyl glutamine synthetase: modification of the nucleotide ligation site of adenylylated glutamine synthetase

The nucleotide ligation site of adenylylated glutamine synthetase, which contains a unique tyrosyl residue linked through a phosphodiester bond to 5'-AMP, was studied by digestion with three hydrolytic enzymes. The products on micrococcal nuclease digestion were adenosine and o-phosphotyrosyl glutamine synthetase. The Km for this macromolecular substrate with the nuclease was 40 microM, at pH 8.9. The glutamine synthetase activity was not affected by deadenosylation with the nuclease, in contrast to SVPDE digestion, with which the glutamine synthetase activity was markedly increased. The Km for the native adenylylated glutamine synthetase with the SVPDE was 36 microM, i.e., similar to that for the nuclease. When the isolated o-phosphotyrosyl enzyme was incubated with alkaline phosphatase at pH 7.2, the glutamine synthetase activity rapidly increased to the same level as that of the SVPDE treated enzyme. Furthermore, kinetic properties of the o-phosphotyrosyl glutamine synthetase were compared with those of the adenylylated enzyme. The optimum pH, apparent Km for each of three substrates, glutamate, ATP, and NH3, and Vmax were in good agreement, as to either Mg2+- or Mn2+-dependent biosynthetic activity. From these results we can conclude that the regulation of glutamine synthetase activity simply requires the phosphorylation of the tyrosyl residue in each subunit, without recourse to adenylylation.     

Purification and properties of glutamine synthetase from the non-N2-fixing cyanobacterium Phormidium laminosum.

Soluble glutamine synthetase activity (L-glutamate:ammonia ligase, ADP forming, EC 6.3.1.2) was purified to electrophoretic homogeneity from the filamentous non-N2-fixing cyanobacterium Phormidium laminosum (OH-1-p.Cl1) by using conventional purification procedures in the absence of stabilizing ligands. The pure enzyme showed a specific activity of 152 mumol of gamma-glutamylhydroxamate formed.min-1 (transferase activity), which corresponded to 4.4 mumol of Pi released.min-1 (biosynthetic activity). The relative molecular mass of the native enzyme was 602 kilodaltons and was composed of 12 identically sized subunits of 52 kilodaltons. Biosynthetic activity required the presence of Mg2+ as an essential activator, although Co2+ and Zn2+ were partially effective. The kinetics of activation by Mg2+, Co2+, and Zn2+ were sigmoidal, and concentrations required for half-maximal activity were 18 mM (h = 2.2), 6.3 mM (h = 5.6), and 6.3 mM (h = 2.45), respectively. However, transferase activity required Mn2+ (Ka = 3.5 microM), Cu2+, Co2+, or Mg2+ being less effective. The substrate affinities calculated for L-Glu, ammonium, ATP, L-Gln, and hydroxylamine were 15, 0.4, 1.9 (h = 0.75), 14, and 4.1 mM, respectively. Optimal pH and temperature were 7.2 and 55 degrees C for biosynthetic activity and 7.5 and 45 degrees C for transferase activity. The biosynthetic reaction mechanism proceeded according to an ordered three-reactant system, the binding order being ammonium, L-Glu, and ATP. The presence of Mn2+ or Mg2+ drastically affected the thermostability of transferase and biosynthetic activities. Heat inactivation of biosynthetic activity in the presence of Mn2+ obeyed first-order kinetics, with an Ea of 76.8 kcal (ca. 321 kJ) mol-1. Gly, L-Asp, L-Ala, L-Ser and, with lower efficiency, L-Lys and L-Met, L-Lys, and L-Glu inhibited only transferase activity. No cumulative inhibition was observed when mixtures of amino acids were used. Biosynthetic activity was inhibited by AMP (Ki= 7 mM), ADP (Ki= 2.3 mM), p-hydroxymercuribenzoate (Ki= 25 microM), and L-methionine-D, L-sulfoximine (Ki= 2 microM). The enzyme was not activated in vitro by chemically reduced Anabaena thioredoxin. This is the first report of glutamine synthetase activity purified from a filamentous non-N2-fixing cyanobacterium.     

A novel reaction catalyzed by unadenylylated glutamine synthetase from Escherichia coli. AMP-dependent synthesis of pyrophosphate and L-Glutamate from orthophosphate and L-glutamine

The unadenylylated, manganese form of glutamine synthetase (L-glutamate: ammonia ligase (ADP forming), EC 6.3.1.2 from Escherichia coli catalyzes a novel, AMP-dependent (reversible) synthesis of pyrophosphate and L-glutamate from orthophosphate and L-glutamine: Formula (See Text). The hydrolysis of the L-glutamine amide bond is coupled to the stoichiometric synthesis of pyrophosphate, although as PPi accumulates, additional hydrolysis of L-glutamine occurs in a secondary reaction catalyzed by the [manganese x enzyme x AMP x PPi] complex. The synthesis of PPi probably occurs at the subunit catalytic site in the positions normally occupied by the beta, gamma-phosphates of ATP. To promote PPi synthesis, AMP apparently binds to the subunit catalytic site rather than to the allosteric inhibitor site; equilibrium binding results suggest that Pi directs the binding of AMP to the active site. In this reaction, Mg2+ will not substitute for Mn2+, and adenylylated glutamine synthetase is inactive. Pyrophosphate is synthesized by the unadenylylated, manganese enzyme at approximately 2% of the rate of that of ATP in the reverse biosynthetic reaction. If P1 is replaced by arsenate, the enzymatic rate of the AMP-supported hydrolysis of L-glutamine is 100-fold faster than is PPi synthesis and is one-half the rate of the ADP-supported, irreversible arsenolysis of L-glutamine. This latter activity also is supported by GMP and IMP, suggesting that the catalytic site of glutamine synthetase has a rather broad specificity for the nucleotide base. The reactions supported by AMP directly relate to the mechanism of glutamine synthetase catalysis.     

Adenine nucleotides as allosteric effectors of pea seed glutamine synthetase

The effects of adenine nucleotides on pea seed glutamine synthetase (EC 6.3.1.2) activity were examined as a part of our investigation of the regulation of this octameric plant enzyme. Saturation curves for glutamine synthetase activity versus ATP with ADP as the changing fixed inhibitor were not hyperbolic; greater apparent Vmax values were observed in the presence of added ADP than the Vmax observed in the absence of ADP. Hill plots of data with ADP present curved upward and crossed the plot with no added ADP. The stoichiometry of adenine nucleotide binding to glutamine synthetase was examined. Two molecules of [gamma-32P]ATP were bound per subunit in the presence of methionine sulfoximine. These ATP molecules were bound at an allosteric site and at the active site. One molecule of either [gamma-32P]ATP or [14C]ADP bound per subunit in the absence of methionine sulfoximine; this nucleotide was bound at an allosteric site. ADP and ATP compete for binding at the allosteric site, although ADP was preferred. ADP binding to the allosteric site proceeded in two kinetic phases. A Vmax value of 1.55 units/mg was measured for glutamine synthetase with one ADP tightly bound per enzyme subunit; a Vmax value of 0.8 unit/mg was measured for enzyme with no adenine nucleotide bound at the allosteric site. The enzyme activation caused by the binding of ADP to the allosteric sites was preceded by a lag phase, the length of which was dependent on the ADP concentration. Enzyme incubated in 10 mM ADP bound approximately 4 mol of ADP/mol of native enzyme before activation was observed; the activation was complete when 7-8 mol of ADP were bound per mol of the octameric, native enzyme. The Km for ATP (2 mM) was not changed by ADP binding to the allosteric sites. ADP was a simple competitive inhibitor (Ki = 0.05 mM) of ATP for glutamine synthetase with eight molecules of ADP tightly bound to the allosteric sites of the octamer. Binding of ATP to the allosteric sites led to marked inhibition.     

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.     

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.     

Affinity labeling of the active site of Escherichia coli glutamine synthetase by 5'-p-fluorosulfonylbenzoyladenosine

The interaction of Escherichia coli glutamine synthetase with the adenosine 5'-triphosphate analogue, 5'-p-fluorosulfonylbenzoyladenosine (5'-FSO2BzAdo), has been studied. This interaction results in the covalent attachment of the 5'-FSO2BzAdo to the enzyme with concomitant loss of catalytic activity. Although adenine nucleotides interact with glutamine synthetase at three distinct sites--a noncovalent AMP effector site, a regulatory site of covalent adenylylation, and the catalytic ATP/ADP binding site--our studies suggest that reaction with 5'-FSO2BzAdo occurs only at the active center. When glutamine synthetase was incubated with 5'-FSO2BzAdo, the decrease in catalytic activity obeyed pseudo-first order kinetics. The plot of the observed rate constant of inactivation versus the concentration of 5'-FSO2BzAdo was hyperbolic, consistent with reversible binding of the analogue to the enzyme prior to covalent attachment. Protection against inactivation was afforded by ATP and ADP; L-glutamate did not protect the enzyme against inactivation, but rather enhanced the rate of inactivation, consistent with the observations of others (Timmons, R. B., Rhee, S. G., Luterman, D. L., and Chock, P. B. (1974) Biochemistry 13, 4479-4485) that there is synergism in the binding of the two substrates to the enzyme. The incorporation of approximately 1.09 mol of the 5'-FSO2BzAdo/mol of glutamine synthetase subunit resulted in the total loss of enzymatic activity. The results suggest that 5'-FSO2BzAdo occupies the ATP binding site at the active center of glutamine synthetase and binds covalently to an amino acid residue nearby.     

Regulation of glutamine synthetase. VI. Interactions of inhibitors for Bacillus licheniformis glutamine synthetase

The relationships of five feedback inhibitors for the Bacillus licheniformis glutamine synthetase were investigated. The inhibitors were distinguishable by differences in their competitive relationship for the substrates of the enzyme. Mixtures of l-glutamine and adenosine-5'-monophosphate (AMP) or histidine and AMP caused synergistic inhibition of glutamine synthesis. Histidine, alanine, and glycine acted antagonistically toward the l-glutamine inhibition. Alanine acted antagonistically toward the glycine and histidine inhibitions. Independence of inhibitory action was observed with the other pairs of effectors. Possible mechanisms by which the inhibitors may interact to control glutamine synthesis are discussed. The low rate of catalysis of the glutamyl transfer reaction by the B. licheniformis glutamine synthetase can be attributed to the fact that l-glutamine serves both as a substrate and an inhibitor for the enzyme. Effectors which act antagonistically toward the l-glutamine inhibition stimulated glutamotransferase activity. The stimulation was not observed when d-glutamine was used as substrate for the glutamyl transfer reaction.     

北京棒状杆菌AS1.299谷氨酰胺合成酶活力调节的研究

北京棒状杆菌(Corynebacterium pekinense AS1.299)谷氨酰胺合成酶的转移酶活性依赖于Mn~(++),酶的生物合成酶活性依赖于Mg~(++),其他二价金属离子只能部分代替Mn~(++)和Mg~(++)的作用。Mn~(++)对ATP或ADP的克分子比对酶活力起调节作用。ATP、CTP,丙氨酸和甘氨酸对谷氨酰胺合成酶有较强的抑制作用;丝氨酸、谷氨酸和6-磷酸葡萄糖胺对酶活力的抑制作用分别是24,15和21％。效应物混合物对酶的作用被证明是累积性的抑制作用。     

Characterization of recombinant glutamine synthetase from the hyperthermophilic archaeon Pyrococcus sp. strain KOD1.

The glnA gene encoding glutamine synthetase was cloned from the hyperthermophilic archaeon Pyrococcus sp. strain KOD1, and its nucleotide sequence was determined. The glnA gene was expressed in Escherichia coli ME8459 (glnA mutant strain), and the protein was purified to homogeneity and shown to be functional in a dodecameric from (637,000 Da), exhibiting both transferase and synthetase activities. However, kinetic studies indicated that the enzyme possessed low biosynthetic activity, suggesting that the reaction was biased towards glutamate production. The optimum temperature for both activities was 60 degrees C, which was lower than the optimal growth temperature of KOD1. Recombinant KOD1 GlnA exhibited different optimum pHs depending on the reaction employed (pH 7.8 for the synthetase reaction and pH 7.2 for the transferase reaction). Of the various nucleoside triphosphates tested, GTP as well as ATP was involved in the synthetase reaction.     

Regulation of glutamine metabolism in Chlorella pyrenoidosa. Regulation of glutamine synthetase activity by adenylic system components]

A decrease of glutamine synthetase (E. C. 6.3.1.2.) activity was observed under the assimilation of ammonium nitrogen in Chlorella. At the same time a decrease of ATP content in Chlorella cells took place. The ATP content was 7-fold decreased, while ADP and AMP contents were 4-fold and 3-fold increased respectively, after 15 min. of Chlorella incubation on "ammonium" medium. Further incubation for 45 min, resulted in gradual increase of ATP content and in decrease of ADP and AMP contents. The value of energy charge in ammonium assimilating Chlorella cells sharply decreased for first 15 min. of incubation and then it normalized gradually. The experiments with glutamine synthetase preparation, isolated from ammonium assimilating cells, have shown that ADP and AMP are strong inhibitors of the enzyme in the presence of Mg2+, and only ADP produces the inhibitory effect in the presence of Mn2+. No enzyme reactivation was observed after the transfer of ammonium assimilating cells into nitrogen-free medium or nitrate medium, the enzyme activity increasing at the expense of enzyme protein synthesis denovo.     

Pea leaf glutamine synthetase: regulatory properties

Of a variety of purine and pyrimidine nucleotides tested, only ADP and 5'AMP significantly inhibited the Mg(2+)-dependent activity of pea leaf glutamine synthetase. They were less effective inhibitors where Mn(2+) replaced Mg(2+). They were competitive inhibitors with respect to ATP, with inhibition constant (Ki) values of 1.2 and 1.8 mm, respectively. The energy charge significantly affects the activity of glutamine synthetase, especially with Mg(2+). Of a variety of amino acids tested, l-histidine and l-ornithine were the most inhibitory, but significant inhibition was seen only where Mn(2+) was present. Both amino acids appeared to compete with l-glutamate, and the Ki values were 1.9 mm for l-histidine (pH 6.2) and 7.8 mm for l-ornithine (pH 6.2). l-Alanine, glycine, and l-serine caused slight inhibition (Mn(2+)-dependent activity) and were not competitive with ATP or l-glutamate.Carbamyl phosphate was an effective inhibitor only when Mn(2+) was present, and did not compete with substrates. Inorganic phosphate and pyrophosphate caused significant inhibition of the Mg(2+)-dependent activity.     

Regulation of Glutamine Synthetase II. Patterns of Feedback Inhibition in Microorganisms

The feedback inhibition of glutamine synthetase was investigated by use of partially purified enzyme preparations from Salmonella typhimurium, Micrococcus sodonensis, Pseudomonas fluorescens, Bacillus cereus, Bacillus licheniformis, Clostridium pasteurianum, Rhodospirillum rubrum, Neurospora crassa, Candida utilis, and Chlorella pyrenoidosa. Inhibition analyses indicated that the enzyme of each organism can be effectively regulated with mixtures of end products from the diverse pathways of glutamine metabolism. When tested individually, tryptophan, histidine, alanine, glycine, glutamine, 5'-adenylate (AMP), cytidine-5'-triphosphate, carbamyl phosphate, and glucosamine-6-phosphate gave limited inhibition. In most cases, the inhibitors were independent in their action, and cumulative degrees of inhibition were obtained with mixtures of these end products. In contrast, with the glutamine synthetases of the two Bacillus species, the simultaneous presence of AMP and histidine (or AMP and glutamine) gave inhibition greater than the sum of the amounts of inhibition caused by either inhibitor alone. Also, alanine and carbamyl phosphate acted synergistically to inhibit the enzyme from N. crassa. The remarkable similarity in the overall patterns of end-product inhibition observed with the enzymes from different sources indicates that these diverse organisms have evolved comparable mechanisms for the regulation of glutamine metabolism. Nevertheless, the enzymes from different sources do differ significantly in their physical and catalytic properties, as was demonstrated by dissimilarities in their purification behaviors, specificity for nucleotide substrate, ability to catalyze the glutamyl transfer reaction, and ability to utilize Mn(++) and Mg(++) as activators for the biosynthetic reaction.     

Rapid transfer of oxygens from inorganic phosphate to glutamine catalyzed by Escherichia coli glutamine synthetase.

Measurements are reported on certain isotopic fluxes during the net conversion of glutamine, ADP and Pi to glutamate, NH3, and ATP by Escherichia coli glutamine synthetase (adenylylated form, Mn2+ activated) in presence of a hexokinase/glucose trap to remove the ATP formed during the reaction. The results show that the transfer of oxygens from Pi to glutamine is the most rapid of the measured isotopic interchanges, over five oxygens from Pi being transferred to glutamine for each glutamate formed by net reaction. Under similar conditions, the oxygen transfer from Pi to glutamate, was stimulated somewhat by an increase in the glutamate concentration but inhibited by an increase in the ammonia concentration. The enzyme from brain or peas did not show the rapid transfer of 18O from Pi to glutamine shown by the E. coli enzyme. Deductions are also made from the data about the availability of the oxygens of gamma-carboxyl of bound glutamate for reaction. The most logical explanation of the results with the E. coli enzyme is that the gamma-carboxyl group of bound glutamate has sufficient rotational freedom so that under conditions of rapid substrate interconversion either carboxylate oxygen can participate in the reaction. The results with the pea enzyme are consistent with hindered rotation of the gamma-care additional findings make likely a relative order of certain catalytic steps for the E. coli enzyme as follows: ATP release less than NH3 release less than glutamate release less than substrate interconversion less than glutamine release and Pi release and glutamate release less than ADP release.     

Regulation of glutamine synthetase, aspartokinase, and total protein turnover in Klebsiella aerogenes

When suspensions of Klebsiella aerogenes are incubated in a nitrogen-free medium there is a gradual decrease in the levels of acid-precipitable protein and of aspartokinase III (lysine-sensitive) and aspartokinase I (threonine-sensitive) activities. In contrast, the level of glutamine synthetase increases slightly and then remains constant. Under these conditions, the glutamine synthetase and other proteins continue to be synthesized as judged by the incorporation of [14C]leucine into the acid-precipitable protein fraction and into protein precipitated by anti-glutamine synthetase antibodies, by the fact that growth-inhibiting concentrations of chloramphenicol also inhibit the incorporation of [14C]leucine into protein and into protein precipitated by anti-glutamine synthetase antibody, and by the fact that chloramphenicol leads to acceleration in the loss of aspartokinases I and III and promotes a net decrease in the level of glutamine synthetase and its cross-reactive protein. The loss of aspartokinases I and III in cell suspensions is stimulated by glucose and is inhibited by 2,4-dinitrophenol. Glucose also stimulates the loss of aspartokinases and glutamine synthetase in the presence of chloramphenicol. Cell-free extracts of K. aerogenes catalyze rapid inactivation of endogenous glutamine synthetase as well as exogenously added pure glutamine synthetase. This loss of glutamine synthetase is not associated with a loss of protein that cross-reacts with anti-glutamine synthetase antibodies. The inactivation of glutamine synthetase in extracts is not due to adenylylation. It is partially prevented by sulfhydryl reagents, Mn2+, antimycin A, 2,4-dinitrophenol, EDTA, anaerobiosis and by dialysis. Following 18 h dialysis, the capacity of extracts to catalyze inactivation of glutamine synthetase is lost but can be restored by the addition of Fe2+ (or Ni2+) together with ATP (or other nucleoside di- and triphosphates. After 40-60 h dialysis Fe3+ together with NADH (but not ATP) are required for glutamine synthetase inactivation. The results suggest that accelerated protein degradation in cells exposed to nitrogen-limited conditions reflects the differential destruction of some proteins, including aspartokinases I and III, in order to sustain the biosynthesis of others such as glutamine synthetase. The loss of glutamine synthetase activity in cell-free extracts is likely mediated in part by mixed-function oxidation systems and could represent a 'marking' step in protein turnover.     

Regulation and properties of glutamine synthetase purified from Bacillus cereus

The glutamine synthetase from Bacillus cereus IFO 3131 was purified to homogeneity. The enzyme is a dodecamer with a molecular weight of approximately 600,000, and its subunit molecular weight is 50,000. Both Mg2+ and Mn2+ activated the enzyme as to the biosynthesis of L-glutamine, but, unlike in the case of the E. coli enzyme, the Mg2+-dependent activity was stimulated by the addition of Mn2+. The highest activity was obtained when 20 mM Mg2+ and 0.5 mM Mn2+ were added to the assay mixture. For each set of optimal assay conditions, the apparent Km values for glutamate, ammonia and a divalent cation X ATP complex were 1.03, 0.34, and 0.40 mM (Mn2+: ATP = 1: 1); 14.0, 0.47, and 0.91 mM (Mg2+: ATP = 4: 1); and 9.09, 0.45, and 0.77 mM (Mg2+: Mn2+: ATP = 4: 0.2: 1), respectively. At each optimum pH, the Vmax values for these reactions were 6.1 (Mn2+-dependent), 7.4 (Mg2+-dependent), and 12.9 (Mg2+ plus Mn2+-dependent) mumoles per min per mg protein, respectively. Mg2+-dependent glutamine synthetase activity was inhibited by the addition of AMP or glutamine; however, this inhibitory effect was suppressed in the case of the Mg2+ plus Mn2+-dependent reaction. These results suggest that the activity of the B. cereus glutamine synthetase is regulated by both the intracellular concentration and the ratio of Mn2+/Mg2+ in vivo. Also in the present investigation, a potent glutamine synthetase inhibitor(s) was detected in crude extracts from B. cereus.     

Mg2+ is bound to glutamine synthetase extracted from bovine or ovine brain in the presence of L-methionine-S-sulfoximine phosphate

Purified glutamine synthetase from bovine or ovine brain had no tightly bound Mn2+. By extraction of bovine or ovine brain glutamine synthetase in the presence of L-Met-S-sulfoximine phosphate and ADP in metal ion-free water and 0.1 M KCl, only endogenously bound divalent cations were trapped on the enzyme. Enzyme complexes isolated by immunoprecipitation contained less than 0.05 Mn2+ and 1.5 +/- 0.2 Mg2+ per subunit. Without inactive complex formation, the enzyme immunoprecipitated from extracts contained undetectable Mn2+ (less than 0.01 eq per subunit) and 0.1-2.0 eq of Mg2+ per subunit. Direct binding measurements showed that the purified bovine brain enzyme contained two divalent cations bound at the active site of each subunit. Thus, although either Mg2+ or Mn2+ supports enzyme activity in vitro, Mg2+ rather than Mn2+ appears to be bound to brain glutamine synthetase in vivo.     

Catalytic cycle of the biosynthetic reaction catalyzed by adenylylated glutamine synthetase from Escherichia coli

The covalently attached AMP moiety of adenylylated glutamine synthetase from Escherichia coli has been replaced by its fluorescent analog, 2-aza-1,N6-etheno-AMP (aza-epsilon-AMP). The modified glutamine synthetase (aza-epsilon-GS) exhibits divalent cation requirement (Mn2+, rather than Mg2+), pH profile, Vmax, and Km similar to those of naturally adenylylated glutamine synthetase. Whereas naturally adenylylated glutamine synthetase exhibits only negligible fluorescence changes upon the binding of substrates, aza-epsilon-GS exhibits large fluorescence changes. The fluorescence changes have been used by means of a stopped flow technique to reveal the involvement of five fluorometrically distinct intermediates in the catalytic cycle for the biosynthesis of glutamine catalyzed by the adenylylated glutamine synthetase. The mechanism is very similar to that previously established for the unadenylylated enzyme, using intrinsic tryptophan fluorescence. Substrates bind via a rapid equilibrium random mechanism, but the reaction proceeds in a stepwise manner. The formation of an enzyme-bound intermediate (probably gamma-glutamyl phosphate + ADP) from ATP and L-glutamate is the rate-limiting step, with the subsequent reaction of the enzyme-bound intermediate occurring very rapidly. The success in elucidating this complex mechanism is due largely to the vastly different amplitudes of the fluorescence changes at the two excitation maxima (300 nm and 360 nm) of the aza-epsilon-AMP moiety which accompany the formation of the various intermediates.