Steady-state kinetics of the glutaminase reaction of CTP synthase from Lactococcus lactis. The role of the allosteric activator GTP incoupling between glutamine hydrolysis and CTP synthesis.

CTP synthase catalyzes the reaction glutamine + UTP + ATP --> glutamate + CTP + ADP + Pi. The rate of the reaction is greatly enhanced by the allosteric activator GTP. We have studied the glutaminase half-reaction of CTP synthase from Lactococcus lactis and its response to the allosteric activator GTP and nucleotides that bind to the active site. In contrast to what has been found for the Escherichia coli enzyme, GTP activation of the L. lactis enzyme did not result in similar kcat values for the glutaminase activity and glutamine hydrolysis coupled to CTP synthesis. GTP activation of the glutaminase reaction never reached the levels of GTP-activated CTP synthesis, not even when the active site was saturated with UTP and the nonhydrolyzeable ATP-binding analog adenosine 5'-[gamma-thio]triphosphate. Furthermore, under conditions where the rate of glutamine hydrolysis exceeded that of CTP synthesis, GTP would stimulate CTP synthesis. These results indicate that the L. lactis enzyme differs significantly from the E. coli enzyme. For the E. coli enzyme, activation by GTP was found to stimulate glutamine hydrolysis and CTP synthesis to the same extent, suggesting that the major function of GTP binding is to activate the chemical steps of glutamine hydrolysis. An alternative mechanism for the action of GTP on L. lactis CTP synthase is suggested. Here the binding of GTP to the allosteric site promotes coordination of the phosphorylation of UTP and hydrolysis of glutamine for optimal efficiency in CTP synthesis rather than just acting to increase the rate of glutamine hydrolysis itself.     

Lid L11 of the glutamine amidotransferase domain of CTP synthase mediates allosteric GTP activation of glutaminase activity

GTP is an allosteric activator of CTP synthase and acts to increase the k(cat) for the glutamine-dependent CTP synthesis reaction. GTP is suggested, in part, to optimally orient the oxy-anion hole for hydrolysis of glutamine that takes place in the glutamine amidotransferase class I (GATase) domain of CTP synthase. In the GATase domain of the recently published structures of the Escherichia coli and Thermus thermophilus CTP synthases a loop region immediately proceeding amino acid residues forming the oxy-anion hole and named lid L11 is shown for the latter enzyme to be flexible and change position depending on the presence or absence of glutamine in the glutamine binding site. Displacement or rearrangement of this loop may provide a means for the suggested role of allosteric activation by GTP to optimize the oxy-anion hole for glutamine hydrolysis. Arg359, Gly360 and Glu362 of the Lactococcus lactis enzyme are highly conserved residues in lid L11 and we have analyzed their possible role in GTP activation. Characterization of the mutant enzymes R359M, R359P, G360A and G360P indicated that both Arg359 and Gly360 are involved in the allosteric response to GTP binding whereas the E362Q enzyme behaved like wild-type enzyme. Apart from the G360A enzyme, the results from kinetic analysis of the enzymes altered at position 359 and 360 showed a 10- to 50-fold decrease in GTP activation of glutamine dependent CTP synthesis and concomitant four- to 10-fold increases in K(A) for GTP. The R359M, R359P and G360P also showed no GTP activation of the uncoupled glutaminase reaction whereas the G360A enzyme was about twofold more active than wild-type enzyme. The elevated K(A) for GTP and reduced GTP activation of CTP synthesis of the mutant enzymes are in agreement with a predicted interaction of bound GTP with lid L11 and indicate that the GTP activation of glutamine dependent CTP synthesis may be explained by structural rearrangements around the oxy-anion hole of the GATase domain.     

Substrate inhibition of Lactococcus lactis cytidine 5'-triphosphate synthase by ammonium chloride is enhanced by salt-dependent tetramer dissociation

Cytidine 5(')-triphosphate (CTP) synthase (EC 6.4.3.2) catalyzes the transfer of an amino group to the 4 position of uridine 5(')-triphosphate (UTP) to yield CTP. The reaction proceeds by activation of the base moiety of UTP by adenosine 5(')-triphosphate (ATP)-dependent phosphorylation. The activated intermediate reacts with NH(3) in the solution or is obtained by hydrolysis of glutamine. The Lactococcus lactis CTP synthase shows significant differences from the enzymes from Escherichia coli, yeast, and mammals. One is the apparent stability of the L. lactis CTP synthase tetramer in the absence of the nucleotides ATP and UTP. This condition causes the E. coli, yeast, and mammal enzymes to dissociate into dimers. However, the L. lactis CTP synthase shows substrate inhibition by NH(4)Cl that coincides with the range of NH(4)Cl concentrations that apparently dissociates tetrameric enzyme into dimers. Even though regular substrate inhibition was observed with NH(4)Cl when the ionic strength was held constant, a significant part of the inhibition could be shown to be due to the increase in ionic strength with increasing substrate concentration. Since the substrate inhibition by NH(4)Cl was relieved by increasing the equimolar ATP and UTP concentrations, it appeared that the substrate nucleotides stabilized the tetramer in a manner similar to that found in the absence of salt for other CTP synthases. In contrast to the suggested hydrophobic nature of the tetramer interactions in E. coli CTP synthase, the dissociation of the L. lactis CTP synthase tetramer in response to an increase in ionic strength suggests that the tetramer is stabilized by ionic interactions.     

Inhibition of E. coli CTP synthase by the "positive" allosteric effector GTP

Cytidine 5'-triphosphate (CTP) synthase catalyzes the ATP-dependent formation of CTP from UTP using either ammonia or l-glutamine as the source of nitrogen. When glutamine is the substrate, GTP is required as a positive allosteric effector to promote catalysis of glutamine hydrolysis. We show that at concentrations exceeding approximately 0.15 mM, GTP actually behaves as a negative allosteric effector of E. coli CTP synthase, inhibiting glutamine-dependent CTP formation. In addition, GTP inhibits NH(3)-dependent CTP formation in a concentration-dependent manner. However, GTP does not inhibit the enzyme's intrinsic glutaminase activity. Although the activation of CTP synthase by GTP does not display cooperative behavior, inhibition of both CTP synthase-catalyzed ammonia- and glutamine-dependent CTP synthesis by GTP do exhibit positive cooperativity. These results suggest that GTP binding affects CTP synthase catalysis in two ways: it activates enzyme-catalyzed glutamine hydrolysis and it inhibits the utilization of NH(3) as a substrate by the synthase domain.     

Alternative substrates for wild-type and L109A E. coli CTP synthases: kinetic evidence for a constricted ammonia tunnel.

Cytidine 5'-triphosphate (CTP) synthase catalyses the ATP-dependent formation of CTP from uridine 5'-triphosphate using either NH(3) or l-glutamine as the nitrogen source. The hydrolysis of glutamine is catalysed in the C-terminal glutamine amide transfer domain and the nascent NH(3) that is generated is transferred via an NH(3) tunnel [Endrizzi, J.A., Kim, H., Anderson, P.M. & Baldwin, E.P. (2004) Biochemistry43, 6447-6463] to the active site of the N-terminal synthase domain where the amination reaction occurs. Replacement of Leu109 by alanine in Escherichia coli CTP synthase causes an uncoupling of glutamine hydrolysis and glutamine-dependent CTP formation [Iyengar, A. & Bearne, S.L. (2003) Biochem. J.369, 497-507]. To test our hypothesis that L109A CTP synthase has a constricted or a leaky NH(3) tunnel, we examined the ability of wild-type and L109A CTP synthases to utilize NH(3), NH(2)OH, and NH(2)NH(2) as exogenous substrates, and as nascent substrates generated via the hydrolysis of glutamine, gamma-glutamyl hydroxamate, and gamma-glutamyl hydrazide, respectively. We show that the uncoupling of the hydrolysis of gamma-glutamyl hydroxamate and nascent NH(2)OH production from N(4)-hydroxy-CTP formation is more pronounced with the L109A enzyme, relative to the wild-type CTP synthase. These results suggest that the NH(3) tunnel of L109A, in the presence of bound allosteric effector guanosine 5'-triphosphate, is not leaky but contains a constriction that discriminates between NH(3) and NH(2)OH on the basis of size.     

Activation and coupling of the glutaminase and synthase reaction of glutamate synthase is mediated by E1013 of the ferredoxin-dependent enzyme, belonging to loop 4 of the synthase domain

Crystal structures of glutamate synthase suggested that a conserved glutamyl residue of the synthase domain (E1013 of Synechocystis sp. PCC 6803 ferredoxin-dependent glutamate synthase, FdGltS) may play a key role in activating glutamine binding and hydrolysis and ammonia transfer to the synthase site in this amidotransferase, in response to the ligation and redox state of the synthase site. The E1013D, N, and A, variants of FdGltS were overproduced in Escherichia coli cells, purified, and characterized. The amino acyl substitutions had no effect on the reactivity of the synthase site nor on the interaction with ferredoxin. On the contrary, a dramatic decrease of activity was observed with the D (approximately 100-fold), N and A (approximately 10,000-fold) variants, mainly due to an effect on the maximum velocity of the reaction. The E1013D variant showed coupling between glutamine hydrolysis at the glutaminase site and 2-oxoglutarate-dependent L-glutamate synthesis at the synthase site, but a sigmoid dependence of initial velocity on L-glutamine concentration. The E1013N variant exhibited hyperbolic kinetics, but the velocity of glutamine hydrolysis was twice that of glutamate synthesis from 2-oxoglutarate at the synthase site. These results are consistent with the proposed role of E1013 in signaling the presence of 2-oxoglutarate (and reducing equivalents) at the synthase site to the glutaminase site in order to activate it and to promote ammonia transfer to the synthase site through the ammonia tunnel. The sigmoid dependence of the initial velocity of the glutamate synthase reaction of the E1013D mutant on glutamine concentration provides evidence for a participation of glutamine in the activation of glutamate synthase during the catalytic cycle.     

Limited proteolysis of Escherichia coli cytidine 5'-triphosphate synthase. Identification of residues required for CTP formation and GTP-dependent activation of glutamine hydrolysis.

Cytidine 5'-triphosphate synthase catalyses the ATP-dependent formation of CTP from UTP using either ammonia or l-glutamine as the source of nitrogen. When glutamine is the substrate, GTP is required as an allosteric effector to promote catalysis. Limited trypsin-catalysed proteolysis, Edman degradation, and site-directed mutagenesis were used to identify peptide bonds C-terminal to three basic residues (Lys187, Arg429, and Lys432) of Escherichia coli CTP synthase that were highly susceptible to proteolysis. Lys187 is located at the CTP/UTP-binding site within the synthase domain, and cleavage at this site destroyed all synthase activity. Nucleotides protected the enzyme against proteolysis at Lys187 (CTP > ATP > UTP > GTP). The K187A mutant was resistant to proteolysis at this site, could not catalyse CTP formation, and exhibited low glutaminase activity that was enhanced slightly by GTP. K187A was able to form tetramers in the presence of UTP and ATP. Arg429 and Lys432 appear to reside in an exposed loop in the glutamine amide transfer (GAT) domain. Trypsin-catalyzed proteolysis occurred at Arg429 and Lys432 with a ratio of 2.6 : 1, and nucleotides did not protect these sites from cleavage. The R429A and R429A/K432A mutants exhibited reduced rates of trypsin-catalyzed proteolysis in the GAT domain and wild-type ability to catalyse NH3-dependent CTP formation. For these mutants, the values of kcat/Km and kcat for glutamine-dependent CTP formation were reduced approximately 20-fold and approximately 10-fold, respectively, relative to wild-type enzyme; however, the value of Km for glutamine was not significantly altered. Activation of the glutaminase activity of R429A by GTP was reduced 6-fold at saturating concentrations of GTP and the GTP binding affinity was reduced 10-fold. This suggests that Arg429 plays a role in both GTP-dependent activation and GTP binding.     

Assimilation of 13NH4+ by Azospirillum brasilense grown under nitrogen limitation and excess.

The specific activities of glutamine synthetase (GS) and glutamate synthase (GOGAT) were 4.2- and 2.2-fold higher, respectively, in cells of Azospirillum brasilense grown with N2 than with 43 mM NH4+ as the source of nitrogen. Conversely, the specific activity of glutamate dehydrogenase (GDH) was 2.7-fold higher in 43 mM NH4+-grown cells than in N2-grown cells. These results indicate that NH4+ could be assimilated and that glutamate could be formed by either the GS-GOGAT or GDH pathway or both, depending on the cellular concentration of NH4+. The routes of in vivo synthesis of glutamate were identified by using 13N as a metabolic tracer. The products of assimilation of 13NH4+ were, in order of decreasing radioactivity, glutamine, glutamate, and alanine. The formation of [13N]glutamine and [13N]glutamate by NH4+-grown cells was inhibited in the additional presence of methionine sulfoximine (an inhibitor of GS) and diazooxonorleucine (an inhibitor of GOGAT). Incorporation of 13N into glutamine, glutamate, and alanine decreased in parallel in the presence of carrier NH4+. These results imply that the GS-GOGAT pathway is the primary route of NH4+ assimilation by A. brasilense grown with excess or limiting nitrogen and that GDH has, at best, a minor role in the synthesis of glutamate.     

Modulation of nucleotide specificity of thermophilic F(o)F(1)-ATP Synthase by epsilon-subunit

The C-terminal two α-helices of the ε-subunit of thermophilic Bacillus F(o)F(1)-ATP synthase (TF(o)F(1)) adopt two conformations: an extended long arm ("up-state") and a retracted hairpin ("down-state"). As ATP becomes poor, ε changes the conformation from the down-state to the up-state and suppresses further ATP hydrolysis. Using TF(o)F(1) expressed in Escherichia coli, we compared TF(o)F(1) with up- and down-state ε in the NTP (ATP, GTP, UTP, and CTP) synthesis reactions. TF(o)F(1) with the up-state ε was achieved by inclusion of hexokinase in the assay and TF(o)F(1) with the down-state ε was represented by εΔc-TF(o)F(1), in which ε lacks C-terminal helices and hence cannot adopt the up-state under any conditions. The results indicate that TF(o)F(1) with the down-state ε synthesizes GTP at the same rate of ATP, whereas TF(o)F(1) with the up-state ε synthesizes GTP at a half-rate. Though rates are slow, TF(o)F(1) with the down-state ε even catalyzes UTP and CTP synthesis. Authentic TF(o)F(1) from Bacillus cells also synthesizes ATP and GTP at the same rate in the presence of adenosine 5'-(β,γ-imino)triphosphate (AMP-PNP), an ATP analogue that has been known to stabilize the down-state. NTP hydrolysis and NTP-driven proton pumping activity of εΔc-TF(o)F(1) suggests similar modulation of nucleotide specificity in NTP hydrolysis. Thus, depending on its conformation, ε-subunit modulates substrate specificity of TF(o)F(1).     

Thr-431 and Arg-433 are part of a conserved sequence motif of the glutamine amidotransferase domain of CTP synthases and are involved in GTP activation of the Lactococcus lactis enzyme

A conserved sequence motif within the class 1 glutamine amidotransferase (GATase) domain of CTP synthases was identified. The sequence motif in the Lactococcus lactis enzyme is (429)GGTLRLG(435). This motif was present only in CTP synthases and not in other enzymes that harbor the GATase domain. Therefore, it was speculated that this sequence was involved in GTP activation of CTP synthase. Other members of the GATase protein family are not activated allosterically by GTP. Residues Thr-431 and Arg-433 were changed by site directed mutagenesis to the sterically similar residues valine and methionine, respectively. The resulting enzymes, T431V and R433M, had both lost the ability for GTP to activate the uncoupled glutaminase activity and showed reduced GTP activation of the glutamine-dependent CTP synthesis reaction. The T431V enzyme had a similar activation constant, K(A), for GTP, but the activation was only 2-3-fold compared with 35-fold for the wild type enzyme. The R433M enzyme was found to have a 10-15-fold lower K(A) for GTP and a concomitant decrease in V(app). The activation by GTP of this enzyme was about 7-fold. The kinetic parameters for saturation with ATP, UTP, and NH(4)Cl were similar for wild type and mutant enzymes, except that the R433M enzyme only had half the V(app) of the wild type enzyme when NH(4)Cl was the amino donor. The mutant enzymes T431V and R433M apparently had not lost the ability to bind GTP, but the signal transmitted through the enzyme to the active sites upon binding of the allosteric effector was clearly disrupted in the mutant enzymes.     

Investigation of the mechanism of CTP synthetase using rapid quench and isotope partitioning methods

The UTP-dependent ATPase reaction and the glutamine-dependent overall reaction of Escherichia coli CTP synthetase have been studied by rapid quench and isotope partitioning kinetics. The effect of GTP, an allosteric effector, on the pre-steady-state kinetics of both reactions has also been examined. The time courses of the UTP-dependent ATPase reaction in the presence and absence of GTP are both characterized by a burst of acid-labile phosphate equivalent to 0.93 and 0.43 subunits, respectively. The time course of the glutamine-dependent reaction in the absence of GTP is also characterized by a burst of acid-labile phosphate corresponding to 0.8 subunit; however, in the presence of GTP, no burst was observed. These results along with positional isotope exchange experiments [von der Saal, W., Anderson, P. M., & Villafranca, J. J. (1985) J. Biol. Chem. 260, 14997] provide evidence that the mechanism of CTP formation involves phosphorylation of UTP followed by attack of NH3, and finally release of phosphate, producing CTP, ADP, and Pi. A kinetic model for the first stages of the enzymatic reaction was developed from the rapid quench data, and the internal equilibrium constant for the formation of the phosphorylated UTP intermediate was determined. The internal equilibrium constants for the UTP-dependent reaction in the presence and absence of GTP were found to be 1.1 and 18, respectively. By contrast, the internal equilibrium constant for the reaction in the presence of glutamine was 50. Thus, the presence of glutamine shifts the internal equilibrium constant to favor formation of the phosphorylated UTP intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of chlorophyll biosynthesis by mercury in excised etiolated maize leaf segments during greening: effect of 2-oxoglutarate

Mercury (0.01-1.0 mM) inhibited chlorophyll formation in greening maize leaf segments. However, supplementing incubation medium with 2-oxoglutarate, maintained substantially higher level of chlorophyll in absence of metal after an initial period of 8 hr. On preincubation of leaf segments with HgCl2, per cent inhibition of chlorophyll synthesis by metal was same in the presence and absence of 2-oxoglutarate. Supply of 2-oxoglutarate (0.1-10.0 mM) exerted concentration dependent effect on chlorophyll formation in absence or presence of metal. Increase in delta-amino levulinic acid dehydratase as well as NADH-glutamate synthase activity and decrease in NADH-glutamate dehydrogenase activity by 2-oxoglutarate in the presence of Hg suggested that glutamate for delta-amino levulinic acid synthesis could be made available from NH4+ assimilation via., glutamine synthetase/glutamate synthase pathway during mercury toxicity.     

Structural requirements for the activation of Escherichia coli CTP synthase by the allosteric effector GTP are stringent, but requirements for inhibition are lax

Cytidine 5'-triphosphate synthase catalyzes the ATP-dependent formation of CTP from UTP using either NH(3) or l-glutamine (Gln) as the source of nitrogen. GTP acts as an allosteric effector promoting Gln hydrolysis but inhibiting Gln-dependent CTP formation at concentrations of >0.15 mM and NH(3)-dependent CTP formation at all concentrations. A structure-activity study using a variety of GTP and guanosine analogues revealed that only a few GTP analogues were capable of activating Gln-dependent CTP formation to varying degrees: GTP approximately 6-thio-GTP > ITP approximately guanosine 5'-tetraphosphate > O(6)-methyl-GTP > 2'-deoxy-GTP. No activation was observed with guanosine, GMP, GDP, 2',3'-dideoxy-GTP, acycloguanosine, and acycloguanosine monophosphate, indicating that the 5'-triphosphate, 2'-OH, and 3'-OH are required for full activation. The 2-NH(2) group plays an important role in binding recognition, whereas substituents at the 6-position play an important role in activation. The presence of a 6-NH(2) group obviates activation, consistent with the inability of ATP to substitute for GTP. Nucleotide and nucleoside analogues of GTP and guanosine, respectively, all inhibited NH(3)- and Gln-dependent CTP formation (often in a cooperative manner) to a similar extent (IC(50) approximately 0.2-0.5 mM). This inhibition appeared to be due solely to the purine base and was relatively insensitive to the identity of the purine with the exception of inosine, ITP, and adenosine (IC(50) approximately 4-12 mM). 8-Oxoguanosine was the best inhibitor identified (IC(50) = 80 microM). Our findings suggest that modifying 2-aminopurine or 2-aminopurine riboside may serve as an effective strategy for developing cytidine 5'-triphosphate synthase inhibitors.     

“Pinching” the ammonia tunnel of CTP synthase unveils coordinated catalytic and allosteric-dependent control of ammonia passage

Molecular gates within enzymes often play important roles in synchronizing catalytic events. We explored the role of a gate in cytidine-5′-triphosphate synthase (CTPS) from Escherichia coli. This glutamine amidotransferase catalyzes the biosynthesis of CTP from UTP using either l-glutamine or exogenous NH₃ as a substrate. Glutamine is hydrolyzed in the glutaminase domain, with GTP acting as a positive allosteric effector, and the nascent NH₃ passes through a gate located at the end of a ~25-Å tunnel before entering the synthase domain where CTP is generated. Substitution of the gate residue Val 60 by Ala, Cys, Asp, Trp, or Phe using site-directed mutagenesis and subsequent kinetic analyses revealed that V60-substitution impacts glutaminase activity, nucleotide binding, salt-dependent inhibition, and inter-domain NH₃ transport. Surprisingly, the increase in steric bulk present in V60F perturbed the local structure consistent with “pinching” the tunnel, thereby revealing processes that synchronize the transfer of NH₃ from the glutaminase domain to the synthase domain. V60F had a slightly reduced coupling efficiency at maximal glutaminase activity that was ameliorated by slowing down the glutamine hydrolysis reaction, consistent with a “bottleneck” effect. The inability of V60F to use exogenous NH₃ was overcome in the presence of GTP, and more so if CTPS was covalently modified by 6-diazo-5-oxo-l-norleucine. Use of NH₂OH by V60F as an alternative bulkier substrate occurred most efficiently when it was concomitant with the glutaminase reaction. Thus, the glutaminase activity and GTP-dependent activation act in concert to open the NH₃ gate of CTPS to mediate inter-domain NH₃ transport.     

Crystal structure of Escherichia coli cytidine triphosphate synthetase, a nucleotide-regulated glutamine amidotransferase/ATP-dependent amidoligase fusion protein and homologue of anticancer and antiparasitic drug targets

Cytidine triphosphate synthetases (CTPSs) produce CTP from UTP and glutamine, and regulate intracellular CTP levels through interactions with the four ribonucleotide triphosphates. We solved the 2.3-A resolution crystal structure of Escherichia coli CTPS using Hg-MAD phasing. The structure reveals a nearly symmetric 222 tetramer, in which each bifunctional monomer contains a dethiobiotin synthetase-like amidoligase N-terminal domain and a Type 1 glutamine amidotransferase C-terminal domain. For each amidoligase active site, essential ATP- and UTP-binding surfaces are contributed by three monomers, suggesting that activity requires tetramer formation, and that a nucleotide-dependent dimer-tetramer equilibrium contributes to the observed positive cooperativity. A gated channel that spans 25 A between the glutamine hydrolysis and amidoligase active sites provides a path for ammonia diffusion. The channel is accessible to solvent at the base of a cleft adjoining the glutamine hydrolysis active site, providing an entry point for exogenous ammonia. Guanine nucleotide binding sites of structurally related GTPases superimpose on this cleft, providing insights into allosteric regulation by GTP. Mutations that confer nucleoside drug resistance and release CTP inhibition map to a pocket that neighbors the UTP-binding site and can accommodate a pyrimidine ring. Its location suggests that competitive feedback inhibition is affected via a distinct product/drug binding site that overlaps the substrate triphosphate binding site. Overall, the E. coli structure provides a framework for homology modeling of other CTPSs and structure-based design of anti-CTPS therapeutics.     

Synthesis of glutamine and glutamate by intact bundle-sheath cells of maize (Zea mays L.)

Intact bundle-sheath cells with functional plasmodesmata were isolated from leaves of Zea mays L. cv. Mutin, and the capacity of these cells to synthesize glutamine and glutamate was determined by simulating physiological substrate concentrations in the bathing medium. The results show that glutamine synthetase can operate at full rate in the presence of added 8 mM ATP. At lower concentrations of ATP a higher rate of glutamine synthesis was found in the light than in darkness. Glutamate-synthase activity, on the other hand, was strictly light dependent. It appears that in bundle-sheath cells of maize the nitrate-assimilatory capacities of glutamine synthetase (located mainly in the cytosol) and of glutamate synthase (located in the stroma) are high enough to meet the demands of whole maize leaves.Abbreviations Gln glutamine - Glu glutamate - GOGAT glutamate synthase - GS glutamine synthetase - 2-OG 2-oxoglutarate This work was supported by the Bundesminister für Forschung und Technologie (0319296A). We thank Mr. Bernd Raufeisen for the art work of Fig. 1.     

Some properties of glutamate dehydrogenase,glutamine synthetase and glutamate synthase from Corynebacterium callunae

Characteristics of the three major ammonia assimilatory enzymes, glutamate dehydrogenase (GDH), glutamine synthetase (GS) and glutamate synthase (GOGAT) in Corynebacterium callunae (NCIB 10338) were examined. The GDH of C. callunae specifically required NADPH and NADP⁺ as coenzymes in the amination and deamination reactions, respectively. This enzyme showed a marked specificity for -ketoglutarate and glutamate as substrates. The optimum pH was 7.2 for NADPH-GDH activity (amination) and 9.0 for NADP⁺-GDH activity (deamination). The results showed that NADPH-GDH and NADP⁺-GDH activities were controlled primarily by product inhibition and that the feedback effectors alanine and valine played a minor role in the control of NADPH-GDH activity. The transferase activity of GS was dependent on Mn⁺² while the biosynthetic activity of the enzyme was dependent on Mg²⁺ as essential activators. The pH optima for transferase and biosynthetic activities were 8.0 and 7.0, respectively. In the transfer reaction, the K _m values were 15.2 mM for glutamine, 1.46 mM for hydroxylamine, 3.5×10^-3 mM for ADP and 1.03 mM for arsenate. Feedback inhibition by alanine, glycine and serine was also found to play an important role in controlling GS activity. In addition, the enzyme activity was sensitive to ATP. The transferase activity of the enzyme was responsive to ionic strength as well as the specific monovalent cation present. GOGAT of C. callunae utilized either NADPH or NADH as coenzymes, although the latter was less effective. The enzyme specifically required -ketoglutarate and glutamine as substrates. In cells grown in a medium with glutamate as the nitrogen source, the optimum pH was 7.6 for NADPH-GOGAT activity and 6.8 for NADH-GOGAT activity. Findings showed that NADPH-GOGAT and NADH-GOGAT activities were controlled by product inhibition caused by NADP⁺ and NAD⁺, respectively, and that ATP also had an important role in the control of NADPH-GOGAT activity. Both activities of GOGAT were found to be inhibited by azaserine.Abbreviations GDH glutamate dehydrogenase - GOGAT glutamate synthase - GS glutamine synthetase     

The glutamine synthetase-glutamate synthase system in Rhodopseudomonas sphaeroides

The phototrophic purple bacterium Rhodopseudomonas sphaeroides, strain 2R, can assimilate ammonium by means of glutamine synthetase and glutamate synthase. A higher activity of glutamine synthetase is displayed by cells grown in the medium with glutamate or in the atmosphere of molecular nitrogen. The activity of glutamate synthase also rises when cells grow in the atmosphere of N2. However, in contrast to glutamine synthetase, the activity of glutamate synthase does not decrease in the presence of considerable NH4+ amounts. The glutamine synthetase of R. sphaeroides is modified by adenylylation/deadenylylation. In the presence of nitrogenase in R. sphaeroides, the glutamine synthetase is found mainly in the deadenylylation state. Methionine sulfone, an inhibitor of glutamine synthetase, partly restores the activity of nitrogenase in the presence of ammonium, and prevents adenylylation of glutamine synthetase.     

Regulation of glutamine synthetase in the blue-green alga Anabaena L-31

In N2-grown cultures of Anabaena L-31, in which protein synthesis was prevented by chloramphenicol, presence of NH+4 caused a drastic decrease of glutamine synthetase (L-glutamate:ammonia ligase (ADP-forming), EC 6.3.1.2) activity indicating NH+4-mediated inactivation or degradation of the enzyme. The half-life of glutamine synthetase was more than 24 h, whereas that of nitrogenase (reduced ferredoxin:dinitrogen oxidoreductase (ATP-hydrolysing), EC 1.18.2.1) was less than 4 h, suggesting that glutamine synthetase may not act as positive regulator of nitrogenase synthesis in Anabaena. Glutamine synthetase purified to homogeneity was subject to cumulative inhibition by alanine, serine and glycine. The amino acids, however, exhibited partial antagonism in this behaviour. Glyoxylate, an intermediate in photorespiration, virtually prevented the amino acid inhibition. Kinetic studies revealed inhibition of the enzyme activity by high Mg2+ concentration under limiting glutamate level and by high glutamate in limiting Mg2+. Maximum enzyme activity occurred when the ratio of glutamate to free Mg2+ was 0.5 to 1.0. The results demonstrate that the enzyme is subject to multiple regulation by various metabolites involved in nitrogen assimilation.     

The in vivo nitrogen isotope discrimination among organic plant compounds

The bulk delta 15 N-value of plant (leaf) biomass is determined by that of the inorganic primary nitrogen sources NO(3)(-), NH(4)(+) and N(2), and by isotope discriminations on their uptake or assimilation. NH(4)(+) from these is transferred into "organic N" mainly by the glutamine synthetase reaction. The involved kinetic nitrogen isotope effect does not become manifest, because the turnover is quantitative. From the product glutamine any further conversion proceeds in a "closed system", where kinetic isotope effects become only efficient in connection with metabolic branching. The central and most important corresponding process is the GOGAT-reaction, involved in the de novo nitrogen binding and in recycling processes like the phenylpropanoid biosynthesis and photorespiration. The reaction yields relatively 15N-depleted glutamate and remaining glutamine, source of 15N-enriched amide-N in heteroaromatic compounds. Glutamate provides nitrogen for all amino acids and some other compounds with different 15N-abundances. An isotope equilibration is not connected to transamination; the relative delta 15 N-value of individual amino acids is determined by their metabolic tasks. Relative to the bulk delta 15 N-value of the plant cell, proteins are generally 15N-enriched, secondary products like chlorophyll, lipids, amino sugars and alkaloids are depleted in 15N. Global delta 15 N-values and 15N-patterns of compounds with several N-atoms can be calculated from those of their precursors and isotope discriminations in their biosyntheses.