Studies onAspergillus niger glutamine synthetase: Regulation of enzyme levels by nitrogen sources and identification of active site residues

The specific activity of glutamine synthetase (L-glutamate: ammonia ligase, EC 6.3.1.2) in surface grownAspergillus niger was increased 3–5 fold when grown on L-glutamate or potassium nitrate, compared to the activity obtained on ammonium chloride. The levels of glutamine synthetase was regulated by the availability of nitrogen source like NH ₄ ⁺ , and further, the enzyme is repressed by increasing concentrations of NH ₄ ⁺ . In contrast to other micro-organisms, theAspergillus niger enzyme was neither specifically inactivated by NH ₄ ⁺ or L-glutamine nor regulated by covalent modification. Glutamine synthetase fromAspergillus niger was purified to homogenity. The native enzyme is octameric with a molecular weight of 385,000±25,000. The enzyme also catalyses Mn²⁺ or Mg²⁺-dependent synthetase and Mn²⁺-dependent transferase activity. Aspergillusniger glutamine synthetase was completely inactivated by two mol of phenyl-glyoxal and one mol of N-ethylmaleimide with second order rate constants of 3.8 M^-1 min^-1 and 760 M^-1 min^-1 respectively. Ligands like Mg. ATP, Mg. ADP, Mg. AMP, L-glutamate NH ₄ ⁺ , Mn²⁺ protected the enzyme against inactivation. The pattern of inactivation and protection afforded by different ligands against N-ethylamaleimide and phenylglyoxal was remarkably similar. These results suggest that metal ATP complex acts as a substrate and interacts with an arginine ressidue at the active site. Further, the metal ion and the free nucleotide probably interact at other sites on the enzyme affecting the catalytic activity.     

In vivo regulation of glutamine synthetase by ammonium in the cyanobacterium Anabaena L-31

In cell-free preparations of NH₄⁺-grown cultures of the cyanobacterium Anabaena L-31 the glutamine synthetase activity is only half as much as in N₂-grown cultures. Using a procedure which enables quantitative purification of the enzyme to homogeneity it has been shown that the decrease in the enzyme activity is caused by NH₄⁺-mediated repression. Glutamine synthetase activity in both N₂-grown and NH₄⁺-grown Anabaena remains stable for more than 24 h in the presence of chloramphenicol suggesting low enzyme turnover and an enzyme half-life greater than the generation time (16–18 h) of the cyanobacterium. In N₂-grown cultures, a drastic decrease in the enzyme activity by exogenous NH₄⁺ can be discerned when fresh protein synthesis is prevented by chloramphenicol. The enzyme purified from such cultures has K_m values for NH₄⁺, glutamate Mg²⁺, and ATP similar to those observed for the enzyme from N₂- and NH₄⁺-grown Anabaena, but shows depression in V for all the substrates, leading to drastic decrease in specific activity. The modified enzyme also shows a sharper thermal denaturation profile. These results indicate that NH₄⁺-mediated modification to a less active form may be a means of regulation of glutamine synthetase in N₂-fixing cultures of Anabaena.     

Cascade control of E. coli glutamine synthetase. II. Metabolite regulation of the enzymes in the cascade.

Enzymes and regulatory proteins involved in the cascade control of glutamine synthetase activity of Escherichia coli have been separated from one another and the effects of numerous metabolites on each step in the cascade have been determined. The adenylyl transferase (ATase) -catalyzed adenylylation of glutamine synthetase, which requires the presence of the unmodified form of the regulatory protein PII is enhanced by glutamine and is inhibited by either α-ketoglutarate (α-KG) or the uridylylated form (PII·UMP) of the regulatory protein. PII·UMP and α-KG act synergistically to inhibit this activity. In contrast, the PII·UMP-dependent, ATase-catalyzed deadenylylation of glutamine synthetase requires α-KG and ATP and is inhibited by glutamine or PII and synergistically by glutamine plus PII. The capacity of uridylyl transferase (UTase) to catalyze the uridylylation of PII is dependent on the presence of α-KG and ATP and is inhibited by glutamine. The deuridylylation of PII·UMP by the uridylyl removing enzyme (UR) is enhanced by glutamine but is unaffected by α-KG. However, CMP, UMP, and CoA all inhibit activity at 10^?6m. High concentrations of ATase inhibit both UR and UTase activities, presumably by binding the regulatory protein. Of more than 50 substances that alter the activity of at least one enzyme in the cascade, only α-KG and glutamine affect the activity at every step. This accounts for the observation that glutamine synthetase activity in vivo is very sensitive to the intracellular ratio of α-KG to glutamine.     

Metabolite regulation of the state of adenylylation of glutamine synthetase

When glutamine synthetase is incubated in a mixture containing adenylyltrans-ferase, the regulatory protein (P_II) and several effectors, including ATP, UTP, P_i, α-ketoglutarate, glutamine, and Mg²⁺ and/or Mn²⁺, it ultimately assumes a constant state of adenylylation. The final state of adenylylation (i.e., the number of adenylylated subunits per mole of enzyme) can vary from 0 to 12 and is specified by the concentrations and ratios of the various effectors and by the extent of uridylylation of P_II (i.e., the P_IIA:P_IID ratio). Under otherwise identical conditions, increasing the concentrations of either UTP, P_i, α-ketoglutarate, Mn²⁺, or P_IID decreases the state of adenylylation finally reached, whereas increasing the concentrations of either glutamine, ATP, or Pua increases the final state of adenylylation. The final state of adenylylation is independent of the concentrations of glutamine synthetase, adenylyltransferase, and P_II (but not of the P_IIA:P_IIDratio), and also of the initial average state of adenylylation of glutamine synthetase. Various lines of evidence show that the final state of adenylylation represents a dynamic steady state in which the rates of adenylylation and deadenylylation of glutamine synthetase are equal. It is concluded that the regulation of glutamine synthetase activity by the adenylylation mechanism utilizes a significant amount of ATP energy, but this amount is less than 0.1% that utilized directly by the glutamine synthetase in the synthesis of glutamine.     

Zinc-induced paracrystalline aggregation of glutamine synthetase

The unique capacity of glutamine synthetase to form highly insoluble paracrystalline aggregates in the presence of Zn²⁺ and Mg²⁺ mixtures is the basis of a new simple procedure for the isolation of the enzyme from crude extracts of Escherichia coli. Under optimal conditions (pH 5.85, 25 °C, 1.5 mm ZnSO₄ and 50 MgCl₂ over 95% of the enzyme is precipitated from crude extracts; differential extraction of the precipitate with dilute buffer (pH 7.0) containing 2.5 mm MgCl₂ leads to high yields of almost pure glutamine synthetase. Polyacrylamide gel electrophoresis of the purified enzyme shows it to consist of one major protein and two minor protein components, all of which exhibit glutamine synthetase activity. The major component appears to be identical with the enzyme previously isolated by the older more tedious procedure of Woolfolk et al. (1966). The γ-glutamyl transferase activity of enzyme isolated by the new procedure is the same as that isolated by the older method, but its biosynthetic activity is 25–35% lower. In all other respects examined (i.e., divalent ion specificity, pH optimum, apparent K_m values for substrates, susceptibility to feedback inhibition and physical properties) enzymes prepared by the old and the new procedures are indistinguishable. From studies with pure glutamine synthetase isolated by either procedure, it has been established that paracrystalline aggregation does not occur until 9–10 equivs of Zn²⁺ are bound per mole of enzyme. The high specificity of Zn²⁺ in inducing enzyme aggregation, suggests that its binding provokes a unique conformational state of the enzyme. This is supported by the fact that addition of Zn²⁺ to relaxed (divalent cation free) enzyme elicits a change in the ultraviolet spectrum of the enzyme that is qualitatively different from that caused by either Mg²⁺ or Mn²⁺. Moreover, in contrast to Mg²⁺, the binding of Zn²⁺ decreases the fluorescence associated with the binding of 2-p-toludinyl-naphthalene-6-sulfonic acid to the enzyme, suggesting that Zn²⁺ binding is accompanied by a decrease in the number of exposed hydrophobic regions on the enzyme.     

Purification and properties of glutamine synthetase from the plant cytosol fraction of lupin nodules

Glutamine synthetase from the plant cytosol fraction of lupin nodules was purified 89-fold to apparent homogeneity. The enzyme molecule is composed of eight subunits of M_r 44,700 ± 10%. Kinetic analysis indicates that the reaction mechanism is sequential and there is some evidence that Mg-ATP is the first substrate to bind to the enzyme. Michaelis constants for each substrate using the ammonium-dependent biosynthetic reaction are as follows: ATP, 0.24 mm; l-glutamate, 4.0–4.2 mm; ammonium, 0.16 mm. Using an hydroxamate-forming biosynthetic reaction the K_m ATP is 1.1 mm but the K_m for l-glutamate is not altered. The effect of pH on the K_m for ammonium indicates that NH₃ rather than NH₄⁺ may be the true substrate. At 10 mm Mg²⁺, the pH optimum of the enzyme is between 7.5 and 8, but increasing Mg²⁺ concentrations produce progressively more acidic optima while lower Mg²⁺ concentrations raise the pH optimum. The rate-response curve for Mg²⁺ is sigmoidal becoming bell-shaped in alkaline conditions. The enzyme is inhibited by l-Asp (K_i, 1.4 mm) and less markedly by l-Gln and l-Asn. Inhibition by ADP and AMP is strong, both nucleotides exhibiting K_i values around 0.3 mM. Investigations of the probable physiological conditions within the nodule plant cytosol indicate that in situ glutamine synthetase has an activity greater than that required to support the efflux of amino acid nitrogen from the nodule. A possible role for glutamine synthetase in the control of nodule ammonium assimilation is suggested.     

Inhibition of Escherichia coli glutamine synthetase by phosphinothricin

The inhibition of Escherichia coli glutamine synthetase by phosphinothricin [2-amino-4-(methylphosphinyl)butanoic acid] has been studied. This amino acid was observed to function as an active site directed inhibitor exhibiting time-dependent inhibition of glutamine synthetase in the presence of ATP or adenylylimidodiphosphate (AMPPNP) but not adenylyl(β,γ-methylene) diphosphonate (AMPPCP). The inactivation was observed to be pseudo-first order. Phosphinothricin was also found to inhibit the enzyme reversibly under initial rate conditions and was competitive with respect to glutamate with K_1S = 18 ± 3 μm. The inactive enzyme inhibitor complex was found to contain approximately 11 molecules of ADP and of ³²P per dodecamer using [γ-³²P]ATP. Reactivation of the inactive enzyme complex was achieved by incubating the enzyme complex in 50 mm acetate (pH 4.4), 1 m KCl, and 0.40 m (NH₄)₂SO₄. ADP, phosphinothricin, and P_i were released upon reactivation.     

Regulation of glutamine synthetase adenylylation and deadenylylation by the enzymatic uridylylation and deuridylylation of the PII regulatory protein

Regulation of glutamine synthetase activity in Escherichia coli is mediated by covalent attachment and detachment of an adenylyl group to each subunit of the enzyme [Kingdon, H. S. et al., Proc. Nat. Acad. Sci., 58, 1703, (1967); Wulff, K. D. et al., Biochem. Biophys. Res. Commun.28, 740, (1967)]. Adenylylation and deadenylylation of the enzyme are both catalyzed by a single adenylyltransferase (ATase) whose activity is modulated by various metabolites and by a regulatory protein, P_II [Shapiro, B. M., Biochemistry; Anderson, W. B. et al., Proc. Nat. Acad. Sci.67, 1761 (1970)].The present study confirms preliminary results [Brown, M. S. et al., Proc. Nat. Acad. Sci.68, 2949 (1971)] showing that: (1) the regulatory protein (P_II) exists in two interconvertible forms, P_IIA and P_IID, which, respectively, stimulate adenylylation and deadenylylation activity of ATase; (2) conversion of P_IIA to P_IID requires the presence of UTP, 2-oxoglutarate, ATP, and either Mg²⁺ or Mn²⁺; (3) this conversion involves covalent attachment of a uridine derivative to P_IIA. It is further established that the covalently bound uridine derivative is UMP which is derived from UTP in a reaction catalyzed by a specific uridylyltransferase (UTase). Removal of the covalently bound UMP from P_IID is catalyzed by a separate enzyme, referred to as the uridylyl-removing enzyme (UR-enzyme). This enzyme has an obligatory requirement for Mn²⁺.Regulation of glutamine synthetase activity in E. coli is thus facilitated by a highly sophisticated cascade system of proteins, consisting of an ATase, the regulatory protein (P_II), UTase, and the UR-enzyme. The activities of these various components is rigorously controlled by various metabolites, including glutamine, 2-oxoglutarate, ATP, P_i, UTP, and the divalent cations, Mn²⁺ and Mg²⁺.     

Purification and properties of glutamine synthetase from spinach leaves

The chloroplastic glutamine synthetase of spinach leaves has been purified to homogeneity using affinity chromatography. This involves a tandem `reactive blue A-agarose' and `reactive red-A-agarose' as the final step in the procedure. This procedure results in a yield of 18 milligrams of pure glutamine synthetase per kilogram of starting material. The purity of our enzyme has been demonstrated on both one- and two-dimensional polyacrylamide gels.

Purified glutamine synthetase has a molecular weight of 360,000 daltons and consists of eight 44,000 dalton subunits. The K_m is 6.7 millimolar for glutamate, 1.8 millimolar for ATP (synthetase assay), and 37.6 millimolar for glutamine (transferase assay). The isoelectric point is 6.5 and the pH optima are 7.3 in the synthetase assay and 6.4 in the transferase assay. The irreversible, competitive inhibitors methionine sulfoxamine and phosphinothricin have K_i values of 0.1 millimolar and 6.1 micromolar, respectively. Amino acid analysis has been carried out and the results compared with published analyses for other isoforms of glutamine synthetase.

     

Purification and properties of Azotobacter vinelandii glutamine synthetase.

A procedure is described for the purification of glutamine synthetase from the nitrogen-fixing organism Azotobacter vinelandii. Electron micrographs of the enzyme reveal a dodecameric arrangement of its subunits in two superimposed hexagonal rings similar to the glutamine synthetase of Escherichia coli. Disc eleetrophoresis in the presence of sodium dodecyl sulfate and sedimentation studies show a subunit molecular weight of 56,500 and a sedimentation coefficient (s_20,w) of the native enzyme of 20.0 S. Like the E. coli enzyme, the glutamine synthetase of A. vinelandii is regulated by adenylylation/deadenylylation. This finding was derived from (a) studies on the effect of snake venom phosphodiesterase treatment on the catalytic and spectral properties of enzyme isolated from cells grown on a nitrogen-rich medium, (b) the identification of the AMP released by the phosphodiesterase by thin-layer chromatography, (c) the selective precipitation of adenylylated enzyme with antibodies directed against adenylylated bovine serum albumin, and (d) the in vitro incorporation of radioactivity from [¹⁴C]ATP into deadenylylated enzyme in the presence of either crude extract from A. vinelandii or partially purified adenylyl transferase from E. coli. The state of adenylylation appears to have a similar influence on the catalytic properties of A. vinelandii glutamine synthetase as on those of the E. coli enzyme, with the exception that the deadenylylated form of the A. vinelandii glutamine synthetase is almost inactive in the Mn-dependent transferase reaction.     

Purification and properties of asparagine synthetase from rat liver

Asparagine synthetase (L-aspartate: ammonia ligase (AMP-forming, EC 6.3.1.1) activity in rat liver increased when the animals were put on a low casein diet. The enzyme was purified about 280-fold from the supernatant of rat liver homogenate by a procedure comprising ammonium sulfate fractionation, DEAE-Sepharose column chromatography, and Sephadex G-100 gel filtration. The optimal pH of the enzyme was in the range 7.4–7.6 with glutamine as an amide donor. The molecular weight was estimated to be approximately 110 000 by gel filtration. Chloride ion was required for the enzyme activity. The apparent K_m values for L-aspartate, L-glutamine, ammonium chloride, ATP, and Cl⁻ were calculated to be 0.76, 4.3, 10, 0.14, and 1.7 mM, respectively. The activity was inhibited by l-asparagine, nucleoside triphosphates except ATP, and sulflhdryl reagents.It has been observed that the properties of asparagine synthetase from rat liver are not different from those of tumors such as Novikoff hepatoma and RADA 1.     

Anion regulation of lupin asparagine synthetase: Chloride activation of the glutamine-utilizing reactions

Small monovalent anions strongly activate glutamine-dependent asparagine synthesis and glutamine hydrolysis catalysed by highly purified asparagine synthetase (EC 6.3.5.4) from cotyledons of Lupinus luteus seedlings. Cl^? and Br^? are most effective, but F^?, I^?, NO₃^? and CN^? also stimulate both reactions. The synthetase reactions with NH₃, or NH₂OH are only slightly stimulated by Cl^? and Br^?, indicating that the anions selectively accelerate the reactions involving glutamine cleavage. In asparagine synthesis Cl^? is a competitive activator vs glutamine and a noncompetitive activator vs MGATP and aspartate. Addition of Cl^? changes the substrate saturation kinetics of glutamine from negatively cooperative to normal hyperbolic and causes a 50-fold increase in the affinity for glutamine. The inherent glutaminase activity of the enzyme is enhanced up to 30-fold by addition of Cl^?, MgATP and aspartate. Thus, ligands of the synthetase reaction act as allosteric activators of the glutaminase step in the enzyme mechanism.     

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.     

Nitrogen and ammonia assimilation in the cyanobacteria: regulation of glutamine synthetase.

Glutamine synthetase, the first enzyme of the ammonia assimilatory pathway, has been purified from Anabaena sp. CA by use of established procedures and by affinity chromatography as a final step. No adenylylation system controlling glutamine synthetase activity was found. The enzyme shows a marked specificity for Mg²⁺ in the biosynthetic assay and Mn²⁺ in the transferase assay. Under physiological conditions, Co²⁺ produces a large stimulatory effect on the Mg²⁺-dependent biosynthetic activity. The enzyme is inhibited by the feedback modifiers l-alanine, glycine, l-serine, l-aspartate, and 5′-AMP. Inhibition by l-serine and l-aspartate is linear, noncompetitive with respect to l-glutamate with apparent K_i values of 3 and 13 mm, respectively. Cumulative inhibition is seen with mixtures of l-serine, l-aspartate, and 5′-AMP. The results indicate that, in vivo, divalent cation availability and the presence of feedback inhibitors may play the dominant role in regulating glutamine synthetase activity and hence ammonia assimilation in nitrogen-fixing cyanobacteria.     

Regulation of nitrogen fixation. Nitrogenase-derepressed mutants of Klebsiella pneumoniae

1. A new procedure is described for selecting nitrogenase-derepressed mutants based on the method of Brenchley et al. (Brenchley, J. E., Prival, M. J. and Magasanik, B. (1973) J. Biol. Chem. 248, 6122–6128) for isolating histidase-constitutive mutants of a non-N₂-fixing bacterium.2. Nitrogenase levels of the new mutants in the presence of NH₄⁺ were as high as 100% of the nitrogenase activity detected in the absence of NH₄⁺.3. Biochemical characterization of these nitrogen fixation (nif) derepressed mutants reveals that they fall into three classes. Three mutants (strains SK-24, 28 and 29), requiring glutamate for growth, synthesize nitrogenase and glutamine synthetase constitutively (in the presence of NH₄⁺). A second class of mutants (strains SK-27 and 37) requiring glutamine for growth produces derepressed levels of nitrogenase activity and synthesized catalytically inactive glutamine synthetase protein, as determined immunologically. A third class of glutamine-requiring, nitrogenase-derepressed mutants (strain SK-25 and 26) synthesizes neither a catalytically active glutamine synthetase enzyme nor an immunologically cross-reactive glutamine synthetase protein.4. F-prime complementation analysis reveals that the mutant strains SK-25, 26, 27, 37 map in a segment of the Klebsiella chromosome corresponding to the region coding for glutamine synthetase. Since the mutant strains SK-27 and SK-37 produce inactive glutamine synthetase protein, it is concluded that these mutations map within the glutamine synthetase structural gene.     

Glutamine synthetase from Salmonella typhimurium: manganese(II), substrate, and inhibitor interaction with the unadenylylated enzyme.

Unadenylylated glutamine synthetase (EC 6.3.1.2) was isolated and purified to homogeneity from Salmonella typhimurium. The enzyme molecule is a symmetrical aggregate of 12 subunits arranged in two hexagonal layers, as is evident from electron micrographs. The subunit molecular weight of the enzyme was found to be approximately 50,000 by polyacrylamide gel electrophoresis in sodium dodecyl sulfate when compared to Escherichia coli glutamine synthetase and other protein standards. A long tube of glutamine synthetase was formed as a single-stranded coil resulting from incubation of the enzyme in a low ionic strength buffer. A study of Mn(II) binding to the unadenylylated enzyme at 25 °C was conducted as a function of pH. At pH 7.1 two classes of metal ion sites per subunit were found with K_D values of 3.7 × 10^?6 and 1.7 × 10^?4m, while at pH 6.8 these values were 1.1 × 10^?5 and 1.0 × 10^?4m, respectively. Only one set of binding sites was observed at pH 6.2 with a K_D value of 1.0 × 10^?4m. The metal ion binding sites were further investigated by monitoring proton relaxation rates (prr) and the epr spectrum of enzyme-bound Mn(II). The longitudinal prr of water protons at pH 7.1 indicate that protons interacting with enzyme-Mn(II) at the “tight” site (K_D = 3.7 × 10^?6) are de-enhanced (?_b1 = 0.42) and result from water protons beyond the inner coordination sphere. The second Mn(II) site has a value of ?_b2 = 35 for the binary enhancement, suggesting that this site probably has two to three rapidly exchanging water molecules in its coordination sphere. The epr spectrum of enzyme-bound Mn(II) at the “tight” site is isotropic and is dramatically sharpened by adding the substrate analog methionine sulfoximine. Subsequent addition of ATP or the ATP analog, AMP-PCP (adenylyl methylene diphosphate) produced anisotropic spectra that were similar, suggesting that both ATP and AMP-PCP bind similarly on the enzyme surface. However, a marked change in the Mn(II) environment from anisotropic to near cubic results from the addition of ADP to the quaternary enzyme-Mn(II)-sulfoximine- (AMP-PCP) complex, indicating that ADP displaces AMP-PCP. No change in the anisotropic spectrum due to the enzyme-Mn(II)-sulfoximine-ATP complex is seen by the addition of ADP. This experimental result supports the experimental findings of Ronzio and Meister [Proc. Nat. Acad. Sci. USA59, 164 (1968)], who established that ATP phosphorylates methionine sulfoximine, thereby producing an inactive enzyme. The allosteric effectors, AMP and Trp, have little effect on the epr spectrum of the complex formed from Mn(II), enzyme, sulfoximine, and ADP, suggesting the absence of direct coordination of AMP or Trp to the bound Mn(II). The prr and epr results reported herein with glutamine synthetase from S. typhimurium when compared to those seen for the enzyme from E. coli [Villafranca et al., Biochemistry15, 544 (1976)] demonstrate some similarities but also many substantial differences between the enzymes from these two bacterial sources.     

Human GMP synthetase

• 1.1. The specific activity of GMP synthetase was measured in several human tissues and found to be highest in cultured skin fibroblasts, followed by bone marrow, leukocytes, erythrocytes. placenta, and liver.
• 2.2. The enzyme from fibroblasts was purified approximately 50-fold by ammonium sulfate fractionation and gel filtration.
• 3.3. The K_m values were determined to be 4.9μM for XMP, 270μM for ATP. and 340 μM for glutamine.
• 4.4. Ammonium sulfate could replace glutamine as the amino donor but was much less efficient.
• 5.5. The enzyme was specific for ATP as the energy source.
• 6.6. Unlike the calf thymus enzyme, the human enzyme has no requirement for a reduced sulfhydryl compound.
• 7.7. Human GMP synthetase is inhibited by ATP, dATP, azaserine, and hydroxylamine.

     

Alteration of cyanobacterial glutamine synthetase activity in vivo in response to light and NH 4 +

Extractable glutamine synthetase activity of the cyanobacterium Anabaena cylindrica was reduced by approximately 50% when N₂-fixing cultures were treated with 10 mM NH ₄ ⁺ or were placed in darkness. The deactivated enzyme could be rapidly reactivated (within 5 min) by adding 40 mM 2-mercaptoethanol to the biosynthetic reaction mixture. The enzyme could also be reactivated in vivo by replacing the culture in light or by removing NH ₄ ⁺ . When the enzyme was deactivated by simultaneously adding NH ₄ ⁺ and placing the culture in darkness, reactivation occurred on reillumination and removal of NH ₄ ⁺ . The removal of NH ₄ ⁺ in darkness did not result in reactivation. On in vitro reactivation of glutamine synthetase from dark or NH ₄ ⁺ -treated cultures the maximum glutamine synthetase activity observed frequently exceeded that of glutamine synthetase extracted from untreated cultures. Anacystis nidulans showed a similar type of reversible dark deactivation to A. cylindrica but Plectonema boryanum and a Nostoc did not. With A. cylindrica, a direct positive correlation between the size of the intracellular pool of glutamate and biosynthetic glutamine synthetase activity occurred during light/dark shifts, and on treatment with NH ₄ ⁺ . The changes in activity of glutamine synthetase in A. cylindrica in response to light resemble in some respects the light modulation of enzymes of the oxidative and reductive pentose phosphate pathways noted in cyanobacteria by others.     

Glutamine synthetase regulation by energy charge in sunflower roots

Energy charge [(ATP) + ½ (ADP)]/[(ATP) + (ADP) + (AMP)] and glutamine synthetase activity (transferase reaction) of roots increase in a near congruent manner when decotyledonized sunflower plants (Helianthus annuus L. var. Mammoth Russian) are grown in nitrate for 9 days. Replacement of nitrate with ammonium for the final 2 days leads to a higher energy charge and increased enzyme activity. Similar correlations occur when nitrate plants are placed on a zero nitrogen regimen and when they are subjected to continuous darkness. A rank order correlation of 0.72 is obtained for all data. Control concepts such as adenylylation-deadenylylation and ammonium inhibition of enzyme synthesis are not supported by the data. Energy charge-enzyme activity plots support the view that glutamine synthetase of sunflower roots is subject to control by end products of glutamine metabolism. Alanine appears to exert a modulating effect on the regulation of glutamine synthetase by energy charge.     

Expression,purification, and characterization of recombinant mangrove glutamine synthetase

To expand our knowledge about the relationship of nitrogen use efficiency and glutamine synthetase (GS) activity in the mangrove plant, a cytosolic GS gene from Avicennia marina has been heterologously expressed in and purified from Escherichia coli. Synthesis of the mangrove GS enzyme in E. coli was demonstrated by functional genetic complementation of a GS deficient mutant. The subunit molecular mass of GSI was ~40 kDa. Optimal conditions for biosynthetic activity were found to be 35 °C at pH 7.5. The Mg²⁺-dependent biosynthetic activity was strongly inhibited by Ni²⁺, Zn²⁺, and Al³⁺, whereas was enhanced by Co²⁺. The apparent K _m values of AmGLN1 for the substrates in the biosynthetic assay were 3.15 mM for glutamate, and 2.54 mM for ATP, 2.80 mM for NH₄ ⁺ respectively. The low affinity kinetics of AmGLN1 apparently participates in glutamine synthesis under the ammonium excess conditions.