Some Kinetic Properties of Bacillus subtilis Glutamine Synthetase

Nitrogen assimilation in denitrifier Bacillus azotoformans LMG 9581T

Until recently, it has not been generally known that some bacteria can contain the gene inventory for both denitrification and dissimilatory nitrate (NO₃^-)/nitrite (NO₂^-) reduction to ammonium (NH₄⁺) (DNRA). Detailed studies of these microorganisms could shed light on the differentiating environmental drivers of both processes without interference of organism-specific variation. Genome analysis of Bacillus azotoformans LMG 9581^T shows a remarkable redundancy of dissimilatory nitrogen reduction, with multiple copies of each denitrification gene as well as DNRA genes nrfAH, but a reduced capacity for nitrogen assimilation, with no nas operon nor amtB gene. Here, we explored nitrogen assimilation in detail using growth experiments in media with different organic and inorganic nitrogen sources at different concentrations. Monitoring of growth, NO₃^- NO₂^-, NH₄⁺ concentration and N₂O production revealed that B. azotoformans LMG 9581^T could not grow with NH₄⁺ as sole nitrogen source and confirmed the hypothesis of reduced nitrogen assimilation pathways. However, NH₄⁺ could be assimilated and contributed up to 50% of biomass if yeast extract was also provided. NH₄⁺ also had a significant but concentration-dependent influence on growth rate. The mechanisms behind these observations remain to be resolved but hypotheses for this deficiency in nitrogen assimilation are discussed. In addition, in all growth conditions tested a denitrification phenotype was observed, with all supplied NO₃^- converted to nitrous oxide (N₂O).

Structures of the Bacillus subtilis glutamine synthetase dodecamer reveal large intersubunit catalytic conformational changes linked to a unique feedback inhibition mechanism

Glutamine synthetase (GS), which catalyzes the production of glutamine, plays essential roles in nitrogen metabolism. There are two main bacterial GS isoenzymes, GSI-α and GSI-β. GSI-α enzymes, which have not been structurally characterized, are uniquely feedback-inhibited by Gln. To gain insight into GSI-α function, we performed biochemical and cellular studies and obtained structures for all GSI-α catalytic and regulatory states. GSI-α forms a massive 600-kDa dodecameric machine. Unlike other characterized GS, the Bacillus subtilis enzyme undergoes dramatic intersubunit conformational alterations during formation of the transition state. Remarkably, these changes are required for active site construction. Feedback inhibition arises from a hydrogen bond network between Gln, the catalytic glutamate, and the GSI-α-specific residue, Arg(62), from an adjacent subunit. Notably, Arg(62) must be ejected for proper active site reorganization. Consistent with these findings, an R62A mutation abrogates Gln feedback inhibition but does not affect catalysis. Thus, these data reveal a heretofore unseen restructuring of an enzyme active site that is coupled with an isoenzyme-specific regulatory mechanism. This GSI-α-specific regulatory network could be exploited for inhibitor design against Gram-positive pathogens.

Transcription factor TnrA inhibits the biosynthetic activity of glutamine synthetase in Bacillus subtilis

The Bacillus subtilis glutamine synthetase (GS) plays a dual role in cell metabolism by functioning as catalyst and regulator. GS catalyses the ATP-dependent synthesis of glutamine from glutamate and ammonium. Under nitrogen-rich conditions, GS becomes feedback-inhibited by high intracellular glutamine levels and then binds transcription factors GlnR and TnrA, which control the genes of nitrogen assimilation. While GS-bound TnrA is no longer able to interact with DNA, GlnR-DNA binding is shown to be stimulated by GS complex formation. In this paper we show a new physiological feature of the interaction between glutamine synthetase and TnrA. The transcription factor TnrA inhibits the biosynthetic activity of glutamine synthetase in vivo and in vitro, while the GlnR protein does not affect the activity of the enzyme.

Artifact versus reality--how astrocytes contribute to synaptic events

The neuronal doctrine, developed a century ago regards neuronal networks as the sole substrate of higher brain function. Recent advances in glial physiology have promoted an alternative hypothesis, which places information processing in the brain into integrated neuronal-glial networks utilizing both binary (neuronal action potentials) and analogue (diffusional propagation of second messengers/metabolites through gap junctions or transmitters through the interstitial space) signal encoding. It has been proposed that the feed-forward and feed-back communication between these two types of neural cells, which underlies information transfer and processing, is accomplished by the release of neurotransmitters from neuronal terminals as well as from astroglial processes. Understanding of this subject, however, remains incomplete and important questions and controversies require resolution. Here we propose that the primary function of perisynaptic glial processes is to create an "astroglial cradle" that shields the synapse from a multitude of extrasynaptic signaling events and provides for multifaceted support and long-term plasticity of synaptic contacts through variety of mechanisms, which may not necessarily involve the release of "glio" transmitters.

A mathematical model for examining growth and sporulation processes of Bacillus subtilis

A mathematical model for the growth process of the bacterium Bacillus subtilis is described. The model is a highly structured one. The driving motivation for development of the model and explicit accounting of major interactions of metabolic networks in the model is related to our eventual goal that the model will be used in the analysis of complex biological patterns. Bacillus subtilis was chosen in our study due to the interesting sporulation process that these cells undergo in response to adverse environmental conditions including nutrient limitation. Sporulation process in B. subtilis represents a primordial prototype of cellular differentiation in higher cellular systems. Thus a model for the B. subtilis growth process should prove extremely useful for understanding questions of developmental biology. The model is capable of simulating the transition between the exponential and stationary phase of growth in a batch culture. Since during the transition period the growth process and the metabolism become decoupled and many transient processes are taking place, such predictions are a severe test for the validity of any model. A strategy to examine the leading hypothesis on B. subtills sporulation implementing GTP as a component which signals sporulation initiation is described.

A feedback-resistant mutant of Bacillus subtilis glutamine synthetase with pleiotropic defects in nitrogen-regulated gene expression

The Bacillus subtilis TnrA transcription factor regulates gene expression during nitrogen-limited growth. When cells are grown with excess nitrogen, feedback-inhibited glutamine synthetase forms a protein-protein complex with TnrA and prevents TnrA from binding to DNA. A mutation in glutamine synthetase with a phenylalanine replacement at the Ser-186 residue (S186F) was isolated by screening for B. subtilis mutants with constitutive TnrA activity. Although S186F glutamine synthetase has kinetic properties that are similar to the wild-type protein, the S186F enzyme is resistant to feedback inhibition by glutamine and AMP. Ligand binding experiments revealed that the S186F protein had a lower affinity for glutamine and AMP than the wild-type enzyme. S186F glutamine synthetase was defective in its ability to block DNA binding by TnrA in vitro. The properties of the feedback-resistant S186F mutant support the model in which the feedback-inhibited form of glutamine synthetase regulates TnrA activity in vivo.

The global transcriptional response of Bacillus subtilis to manganese involves the MntR, Fur, TnrA and sigmaB regulons

We have used DNA microarrays to monitor the global transcriptional response of Bacillus subtilis to changes in manganese availability. Mn(II) leads to the MntR-dependent repression of both the mntH and mntABCD operons encoding Mn(II) uptake systems. Mn(II) also represses the Fur regulon. This repression is unlikely to be a direct effect of Mn(II) on Fur as repression is sensitive to 2,2'-dipyridyl, an iron-selective chelator. We suggest that elevated Mn(II) displaces iron from cellular-binding sites and the resulting rise in free iron levels leads to repression of the Fur regulon. Many of the genes induced by Mn(II) are activated by sigmaB or TnrA. Both of these regulators are controlled by Mn(II)-dependent enzymes. Induction of the sigmaB-dependent general stress response by Mn(II) is largely dependent on RsbU, a Mn(II)-dependent phosphatase that dephosphorylates RsbV, ultimately leading to release of active sigmaB from its antisigma, RsbW. The activity of TnrA is inhibited when it forms an inactive complex with feedback-inhibited glutamine synthetase. Elevated Mn(II) reduces the sensitivity of glutamine synthetase to feedback inhibitors, and we suggest that this leads to the observed increase in TnrA activity. In sum, three distinct mechanisms can account for most of the transcriptional effects elicited by manganese: (i) direct binding of Mn(II) to metalloregulators such as MntR, (ii) perturbation of cellular iron pools leading to increased Fur activity and (iii) altered activity of Mn(II)-dependent enzymes that regulate the activity of sigmaB and TnrA.

Mutations in Bacillus subtilis glutamine synthetase that block its interaction with transcription factor TnrA

In Bacillus subtilis, the activity of the nitrogen regulatory factor TnrA is regulated through a protein- protein interaction with glutamine synthetase. During growth with excess nitrogen, the feedback-inhibited form of glutamine synthetase binds to TnrA and blocks DNA binding by TnrA. Missense mutations in glutamine synthetase that constitutively express the TnrA-regulated amtB gene were characterized. Four mutant proteins were purified and shown to be defective in their ability to inhibit the in vitro DNA-binding activity of TnrA. Two of the mutant proteins exhibited enzymatic properties similar to those of wild-type glutamine synthetase. A model of B. subtilis glutamine synthetase was derived from a crystal structure of the Salmonella typhimurium enzyme. Using this model, all the mutated amino acid residues were found to be located close to the glutamate entrance of the active site. These results are consistent with the glutamine synthetase protein playing a direct role in regulating TnrA activity.

Bacillus subtilis glutamine synthetase controls gene expression through a protein-protein interaction with transcription factor TnrA

Bacillus subtilis TnrA, a global regulator of transcription, responds to nitrogen availability, but the specific signal to which it responds has been elusive. Genetic studies indicate that glutamine synthetase is required for the regulation of TnrA activity in vivo. We report here that the feedback-inhibited form of glutamine synthetase directly interacts with TnrA and blocks the DNA binding activity of TnrA. Mutations in the tnrA gene (tnrA(C)) that allow constitutive high level expression of tnrA-activated genes were isolated and characterized. Feedback-inhibited glutamine synthetase had a significantly reduced ability to block the in vitro DNA binding by three of the TnrA(C) proteins. Thus, glutamine synthetase, an enzyme of central metabolism, directly interacts with and regulates the DNA binding activity of TnrA.

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.

Purification and properties of glutamine synthetase from Nocardia asteroides

Glutamine synthetase (GS, EC 6.3.1.2) from Nocardia asteroides was purified to homogeneity by ammonium sulfate precipitation, Sephadex G-150, and DEAE-Sepharose chromatography. The native molecular weight of the purified enzyme was determined to be 720 kDa. SDS-PAGE analysis of the purified preparation revealed a single band corresponding to 59 kDa, indicating the possible presence of 12 identical subunits. The divalent cations Mn2+ and Mg2+ were found to be essential for optimal transferase and biosynthetic activity, respectively. The optimal pH and temperature for both activities of the enzyme were found to be 7.2 and 50 degrees C. Amino acids such as L-alanine, glycine, and aspartate inhibited the GS activity. The Km values for the substrates of the biosynthetic reaction ATP, glutamate, and ammonium chloride were found to be 400 microM, 7.7 mM, and 200 microM, respectively. Addition of ammonium chloride to the nitrogen-limited culture resulted in a decrease of GS transferase and biosynthetic activities. Phosphodiesterase treatment of the extract from ammonia-shocked cultures showed an increase in GS transferase activity. The results indicate the possible regulation of GS by covalent modification.

Structure of the Escherichia coli signal transducing protein PII

BACKGROUND

In Gram-negative proteobacteria, the nitrogen level in the cell is reflected by the uridylylation status of a key signal transducing protein, PII. PII modulates the activity of glutamine synthetase (GS) through its interaction with adenylyl transferase and it represses the expression of GS by acting in concert with nitrogen regulatory protein II.

RESULTS

The three-dimensional structure of the Escherichia coli PII trimer has been determined at 2.7 A resolution. PII shows a low level of structural similarity to a broad family of alpha/beta proteins and contains a double beta alpha beta motif. The PII trimer contains three beta-sheets, each of which is composed of strands from each of the three monomers. These are surrounded by six alpha-helices.

CONCLUSIONS

The structure of PII suggests potential regions of interaction with other proteins and serves as an initial step in understanding its signal transducing role in nitrogen regulation.

The femC locus of Staphylococcus aureus required for methicillin resistance includes the glutamine synthetase operon

Tn551 insertional inactivation of femC is known to reduce methicillin resistance levels in methicillin-resistant and -susceptible Staphylococcus aureus. By use of cotransductional crosses, femC was mapped close to thrB on the SmaI-A fragment of the S. aureus NCTC 8325 chromosome. The Tn551 insertion femC::omega 2005 was found to interrupt an open reading frame coding for a putative protein of 121 amino acids which is highly similar to the glutamine synthetase repressors (GlnR) of Bacillus spp. Downstream of femC, an open reading frame highly similar to Bacillus sp. glutamine synthetases (GlnA) was found. Northern (RNA) blots probed with putative glnR or glnA fragments revealed that 1.7- and 1.9-kb transcripts characteristic of wild-type cells were replaced by less abundant 7.0- and 7.2-kb transcripts in the femC::omega 2005 mutant. Total glutamine synthetase activity was also decreased in the mutant strain; the addition of glutamine to defined media restored the wild-type methicillin resistance phenotype of the femC mutant. This result suggests that the omega 2005 insertion in glnR has a polar effect on glnA and that glnR and glnA are transcribed together as an operon. These results suggest that the loss of wild-type levels of glutamine synthetase and the consequent decrease in glutamine availability cause a decreased level of methicillin resistance.

The nitrogen-regulated Bacillus subtilis nrgAB operon encodes a membrane protein and a protein highly similar to the Escherichia coli glnB-encoded PII protein

Expression of beta-galactosidase encoded by the nrg-29::Tn917-lacZ insertion increases 4,000-fold during nitrogen-limited growth (M.R. Atkinson and S. H. Fisher, J. Bacteriol. 173:23-27, 1991). The chromosomal DNA adjacent to the nrg-29::Tn917-lacZ insertion was cloned and sequenced. Analysis of the resulting nucleotide sequence revealed that the Tn917-lacZ transposon was inserted into the first gene of a dicistronic operon, nrgAB. The nrgA gene encodes a 43-kDa hydrophobic protein that is likely to be an integral membrane protein. The nrgB gene encodes a 13-kDa protein that has significant sequence similarity with the Escherichia coli glnB-encoded PII protein. Primer extension analysis revealed that the nrgAB operon is transcribed from a single promoter. The nucleotide sequence of this promoter has significant similarity with the -10 region, but not the -35 region, of the consensus sequence for Bacillus subtilis sigma A-dependent promoters.

Recent developments on the regulation and structure of glutamine synthetase enzymes from selected bacterial groups

The structure of glutamine synthetase (GS) enzymes from diverse bacterial groups fall into three distinct classes. GSI is the typical bacterial GS, GSII is similar to the eukaryotic GS and is found together with GSI in plant symbionts and Streptomyces, while GSIII has been found in two unrelated anaerobic rumen bacteria. In most cases, the structural gene for GS enzyme is regulated in response to nitrogen. However, different regulatory mechanisms, to ensure optimal utilization of nitrogen substrates, control the GS enzyme in each class.

Altered regulation of the glnRA operon in a Bacillus subtilis mutant that produces methionine sulfoximine-tolerant glutamine synthetase

A Bacillus subtilis mutant that produced glutamine synthetase (GS) with altered sensitivity to DL-methionine sulfoximine was isolated. The mutation, designated glnA33, was due to a T.A-to-C.G transition, changing valine to alanine at codon 190 within the active-site C domain. Altered regulation was observed for GS activity and antigen and mRNA levels in a B. subtilis glnA33 strain. The mutant enzyme was 28-fold less sensitive to DL-methionine sulfoximine and had a 13.0-fold-higher Km for hydroxylamine and a 4.8-fold-higher Km for glutamate than wild-type GS did.

Synthesis of collagenase by the phytopathogenic bacterium Corynebacterium rathayii

The collagenase-producing bacterium tentatively called Empedobacter collagenolyticum was recently identified as Corynebacterium rathayii. Production of collagenase was studied in different media containing peptones or peptides of known sequences. A hexapeptide, Pro-Ala-Gly-Pro-Pro-Gly, is an inducer almost as good as collagen.

Molecular cloning, sequencing, and expression of the glutamine synthetase II (glnII) gene from the actinomycete root nodule symbiont Frankia sp. strain CpI1

In common with other plant symbionts, Frankia spp., the actinomycete N2-fixing symbionts of certain nonleguminous woody plants, synthesize two glutamine synthetases, GSI and GSII. DNA encoding the Bradyrhizobium japonicum gene for GSII (glnII) hybridized to DNA from three Frankia strains. B. japonicum glnII was used as a probe to clone the glnII gene from a size-selected KpnI library of Frankia strain CpI1 DNA. The region corresponding to the Frankia sp. strain CpI1 glnII gene was sequenced, and the amino acid sequence was compared with that of the GS gene from the pea and glnII from B. japonicum. The Frankia glnII gene product has a high degree of similarity with both GSII from B. japonicum and GS from pea, although the sequence was about equally similar to both the bacterial and eucaryotic proteins. The Frankia glnII gene was also capable of complementing an Escherichia coli delta glnA mutant when transcribed from the vector lac promoter, but not when transcribed from the Frankia promoter. GSII produced in E. coli was heat labile, like the enzyme produced in Frankia sp. strain CpI1 but unlike the wild-type E. coli enzyme.

Purification and properties of glutamine synthetases from the cyanobacteria Synechocystis sp. strain PCC 6803 and Calothrix sp. strain PCC 7601

Glutamine synthetases (GSs) from two cyanobacteria, one unicellular (Synechocystis sp. strain PCC 6803) and the other filamentous (Calothrix sp. strain PCC 7601 [Fremyella diplosiphon]), were purified to homogeneity. The biosynthetic activities of both enzymes were strongly inhibited by ADP, indicating that the energy charge of the cell might regulate the GS activity. Both cyanobacteria exhibited an ammonium-mediated repression of GS synthesis. In addition, the Synechocystis sp. showed an inactivation of GS promoted by ammonium that had not been demonstrated previously in cyanobacteria.

Regulation of glutamine synthesis by glycine and serine in Neurospora crassa

The biosynthetic activities of the polypeptide subunits alpha and beta of glutamine synthetase (GS) were inhibited in vitro by glycine and serine. These amino acids inhibited the growth of a mutant strain with partial GS activity when grown on glutamate as the nitrogen source and also blocked the synthesis of the glutamine in vivo, thus demonstrating the inhibitory effect on GS activity in vivo. Glycine and serine lowered the intracellular glutamine pool and regulated GS beta synthesis. A preferential induction of synthesis of the GS beta polypeptide was observed when either of these amino acids was present in the medium. On this basis, we obtained a glycine-sensitive mutant which showed a structural alteration of the GS beta polypeptide. The double regulatory effect of either glycine or serine on glutamine synthesis may be considered an example of the regulation of glutamine synthesis by alpha-amino nitrogen. It may be a mechanism that regulates the assimilation of ammonium into glutamate versus glutamine.

Purification and regulation of glutamine synthetase in a collagenolytic Vibrio alginolyticus strain

Glutamine synthetase (EC 6.3.1.2) has been purified from a collagenolytic Vibrio alginolyticus strain. The apparent molecular weight of the glutamine synthetase subunit was approximately 62,000. This indicates a particle weight for the undissociated enzyme of 744,000, assuming the enzyme is the typical dodecamer. The glutamine synthetase enzyme had a sedimentation coefficient of 25.9 S and seems to be regulated by adenylylation and deadenylylation. The pH profiles assayed by the gamma-glutamyltransferase method were similar for NH4-shocked and unshocked cell extracts and isoactivity point was not obtained from these curves. The optimum pH for purified and crude cell extracts was 7.9. Cell-free glutamine synthetase was inhibited by some amino acids and AMP. The transferase activity of glutamine synthetase from mid-exponential phase cells varied greatly depending on the sources of nitrogen or carbon in the growth medium. Glutamine synthetase level was regulated by nitrogen catabolite repression by (NH4)2SO4 and glutamine, but cells grown in the presence of proline, leucine, isoleucine, tryptophan, histidine, glutamic acid, glycine and arginine had enhanced levels of transferase activity. Glutamine synthetase was not subject to glucose, sucrose, fructose, glycerol or maltose catabolite repression and these sugars had the opposite effect and markedly enhanced glutamine synthetase activity.

Glutamine synthetase gene of Bacillus subtilis

The glutamine synthetase gene (glnA) of Bacillus subtilis was purified from a library of B. subtilis DNA cloned in phage lambda. By mapping the locations of previously identified mutations in the glnA locus it was possible to correlate the genetic and physical maps. Mutations known to affect expression of the glnA gene and other genes were mapped within the coding region for glutamine synthetase, as determined by measuring the sizes of truncated, immunologically cross-reacting polypeptides coded for by various sub-cloned regions of the glnA gene. When the entire B. subtilis glnA gene was present on a plasmid it was capable of directing synthesis in Escherichia coli of B. subtilis glutamine synthetase as judged by enzymatic activity, antigenicity, and ability to allow growth of a glutamine auxotroph. By use of the cloned B. subtilis glnA gene as a hybridization probe, it was shown that the known variability of glutamine synthetase specific activity during growth in various nitrogen sources is fully accounted for by changes in glnA mRNA levels.

Covalent modification of bacterial glutamine synthetase: physiological significance

Stadtman, Holzer and their colleagues (reviewed in Stadtman and Ginsburg 1974) demonstrated that the enzyme glutamine synthetase (GS) [(L-glutamate: ammonia ligase (ADP-forming), EC 6.3.1.2] is covalently modified by adenylylation in a variety of bacterial genera and that the modification is reversible. These studies further indicated that adenylylated GS is the less active form in vitro. To assess the physiological significance of adenylylation of GS we have determined the growth defects of mutant strains (glnE) of S. typhimurium that are unable to modify GS and we have determined the basis for these growth defects. The glnE strains, which lack GS adenylyl transferase activity (ATP: [L-glutamate: ammonia ligase (ADP-forming)] adenylyltransferase, EC 2.7.7.42), show a large growth defect specifically upon shift from a nitrogen-limited growth medium to medium containing excess ammonium (NH4+). The growth defect appears to be due to very high catalytic activity of GS after shift, which lowers the intracellular glutamate pool to approximately 10% that under preshift conditions. Consistent with this view, recovery of a rapid growth rate on NH4+ is accompanied by an increase in the glutamate pool. The glnE strains have normal ATP pools after shift. They synthesize very large amounts of glutamine and excrete glutamine into the medium, but excess glutamine does not seem to inhibit growth. We hypothesize that a major function for adenylylation of bacterial GS is to protect the cellular glutamate pool upon shift to NH4+ -excess conditions and thereby to allow rapid growth.

Expression of the Bacillus subtilis glutamine synthetase gene in Escherichia coli

The structural gene for glutamine synthetase (glnA) in Bacillus subtilis ( glnAB ) cloned in the lambda vector phage Charon 4A was used to transduce a lysogenic glutamine auxotrophic Escherichia coli strain to prototrophy. The defective E. coli gene ( glnAE ) was still present in the transductant since it could be transduced. In addition, curing of the prototroph resulted in the restoration of glutamine auxotrophy. Proteins in crude extracts of the transductant were examined by a "Western blotting" procedure for the presence of B. subtilis or E. coli glutamine synthetase antigen; only the former was detected. Growth of the strain in media without glutamine was not curtailed even when the bacteriophage lambda pL and pRM promoters were hyperrepressed . The specific activities and patterns of derepression of glutamine synthetase in the transductant were similar to those of B. subtilis, with no evidence for adenylylation. The information necessary for regulation of glnAB must be closely linked to the gene and appears to function in E. coli.

Bacillus subtilis glutamine synthetase mutants pleiotropically altered in glucose catabolite repression

Strain SF22, a glutamine-requiring (Gln-) mutant of Bacillus subtilis SMY, is likely to have a mutation in the structural gene for glutamine synthetase, since this strain synthesized 22 to 55% as much glutamine synthetase antigen as did wild-type cells in a 10-min period but had less than 3% of wild-type glutamine synthetase enzymatic activity. The expression of several genes subject to glucose catabolite repression was altered in the Gln- mutant. The induced levels of alpha-glucosidase, histidase, and aconitase were 3.5- to 4-fold higher in SF22 cells than in wild-type cells grown in glucose-glutamine medium, and citrate synthase levels were 8-fold higher in the Gln- mutant than in wild-type cells. The relief of glucose catabolite repression in the Gln- mutant may result from poor utilization of glucose. Examination of the intracellular metabolite pools of cells grown in glucose-glutamine medium showed that the glucose-6-phosphate pool was 2.5-fold lower, the pyruvate pool was 4-fold lower, and the 2-ketoglutarate pool was 2.5-fold lower in the Gln- cells than they were in wild-type cells. Intracellular levels of glutamine were sixfold higher in the Gln- mutant than in wild-type cells. Measurements of enzymes involved in glutamine transport and utilization showed that the elevated pools of glutamine in the Gln- mutant resulted from a threefold increase in glutamine permease and a fivefold decrease in glutamate synthase. The pleiotropic effect of the gln-22 mutation on the expression of several genes suggests that either the glutamine synthetase protein or its enzymatic product, glutamine, is involved in the regulation of several metabolic pathways in B. subtilis.

Ammonia utilization by a proposed bacterial pathogen in human periodontal disease, Capnocytophaga ochracea

Capnocytophaga ochracea strain 25 was originally isolated from a patient with severe juvenile periodontitis. An NAD-specific glutamate dehydrogenase (GDH) (EC 1.4.1.2.) was found in cell-free extracts from this organism. The NADH-dependent reductive, or ammonia-assimilating activity (NADH-GDH), of the enzyme was 8-10-fold higher than its NAD-dependent oxidative, or ammonia-releasing activity (NAD-GDH), suggesting that the primary physiological role of the GDH is ammonia-fixing. Capnocytophaga ochracea GDH was purified approximately 39-fold by a rapid, single-step purification procedure using DEAE-cellulose (DE52) ion-exchange column chromatography which gave 90 per cent recovery of total enzyme units. Paper chromatography of an NADH-GDH assay mixture containing the partially purified enzyme showed that glutamate was, indeed, a product of the ammonia-assimilating reaction. The pH optimum for the NAD-GDH reaction was 9.0; that for the NADH-GDH reaction was 7.5. Although a number of mono- and divalent cations were tested, none had a large effect on either NAD-GDH or NADH-GDH activity. The NAD-GDH reaction showed a hyperbolic kinetic response to glutamate and NAD and the Km values for glutamate and NAD were 2.44 and 0.083 mM respectively. The kinetic response of the NADH-GDH reaction to NADH, alpha-ketoglutarate and ammonium chloride also obeyed Michaelis-Menten kinetics and their respective Km values were 0.069, 1.44 and 3.33 mM. Of a number of biologically-active compounds tested for their ability to modulate GDH activity, only ADP and NAD exerted much effect. The NADH-GDH activity showed a negative hyperbolic kinetic response to both ADP and NAD and Dixon plot-analysis of the NAD and ADP saturation data gave Ki values for ADP and NAD of 4.0 and 0.46 mM respectively. Both NAD and ADP appeared to exert their negative effects on NADH-GDH activity by completely inhibiting the binding of the reduced coenzyme, NADH, to the enzyme.

Regulation of glutamine synthetase activity and synthesis in free-living and symbiotic Anabaena spp

Regulation of the synthesis and activity of glutamine synthetase (GS) in the cyanobacterium Anabaena sp. strain 7120 was studied by determining GS transferase activity and GS antigen concentration under a variety of conditions. Extracts prepared from cells growing exponentially on a medium supplemented with combined nitrogen had a GS activity of 17 mumol of gamma-glutamyl transferase activity per min per mg of protein at 37 degrees C. This activity doubled in 12 h after transfer of cells to a nitrogen-free medium, corresponding to the time required for heterocyst differentiation and the start of nitrogen fixation. Addition of NH3 to a culture 11 h after an inducing transfer immediately blocked the increase in GS activity. In the Enterobacteriaceae, addition of NH3 after induction results in the covalent modification of GS by adenylylation. The GS of Anabaena is not adenylylated by such a protocol, as shown by the resistance of the transferase activity of the enzyme to inhibition by Mg2+ and by the failure of the enzyme to incorporate 32P after NH3 upshift. Methionine sulfoximine inhibited Anabaena GS activity rapidly and irreversibly in vivo. After the addition of methionine sulfoximine to Anabaena, the level of GS antigen neither increased nor decreased, indicating that Glutamine cannot be the only small molecule capable of regulating GS synthesis. Methionine sulfoximine permitted heterocyst differentiation and nitrogenase induction to escape repression by NH3. Nitrogen-fixing cultures treated with methionine sulfoximine excreted NH3. The fern Azolla caroliniana contains an Anabaena species living in symbiotic association. The Anabaena species carries out nitrogen fixation sufficient to satisfy all of the combined nitrogen requirements of the host fern. Experiments by other workers have shown that the activity of GS in the symbiont is significantly lower than the activity of GS in free-living Anabaena. Using a sensitive radioimmune assay and a normalization procedure based on the content of diaminopimelic acid, a component unique to the symbiont, we found that the level of GS antigen in the symbiont was about 5% of the level in free-living Anabaena cells. Thus, the host fern appears to repress synthesis of Anabaena GS in the symbiotic association.

Properties of the Bacillus licheniformis A5 glutamine synthetase purified from cells grown in the presence of ammonia or nitrate

The glutamine synthetase from Bacillus licheniformis A5 was purified by using a combination of polyethylene glycol precipitation and chromatography on Bio-Gel A 1.5m. The resulting preparation was judged to be homogeneous by the criteria of polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, equilibrium analytical ultracentrifugation, and electron microscopic analysis. The enzyme is a dodecamer with a molecular weight of approximately 616,000, and its subunit molecular weight is 51,000. Under optimal assay conditions (pH 6.6, 37 degrees C) apparent Km values for glutamate, ammonia, and manganese.adenosine 5'-triphosphate (1:1 ratio) were 3.6, 0.4, and 0.9 mM, respectively. Glutamine synthetase activity was inhibited approximately 50% by the addition of 5 mM glutamine, alanine, glycine, serine, alpha-ketoglutarate, carbamyl phosphate, adenosine 5'-diphosphate, or inosine 5'-triphosphate to the standard glutamine synthetase assay system, whereas 5 mM adenosine 5'-monophosphate or pyrophosphate caused approximately 90% inhibition of enzyme activity. Phosphorylribosyl pyrophosphate at 5 mM enhanced activity approximately 60%. We were unable to detect any physical or kinetic differences in the properties of the enzyme when it was purified from cells grown in the presence of ammonia or nitrate as sole nitrogen source. The data indicate that B. licheniformis A5 contains one species of glutamine synthetase whose catalytic activity is not regulated by a covalent modification system.

Effect of glutamine on enzymes of nitrogen metabolism in Bacillus subtilis

An earlier study of the regulation of glutamate synthase (GOGAT) in Bacillus subtilis (Deshpande et al., Bichem. Biophys. Res. Commun. 95:55--60, 1980) revealed an inverse relationship between the specific activity of this essential ammonia-assimilatory enzyme and the intracellular pool of glutamine: GOGAT activity decreased when the internal glutamine concentration reached or exceeded 2.5 mM. This finding prompted the present investigation of the intracellular events linking glutamine formation to the regulation of GOGAT. A growing culture of B. subtilis was shifted from glutamate plus NH+4 medium (high GOGAT activity) to glutamate medium (low GOGAT activity). At various times after the shift, the intracellular concentrations of aspartate, glutamate, glutamine, alanine, and NH+4 and the activities of GOGAT and glutamine synthetase (GS) were measured. After 30 min, the only significant pool level change was an eightfold increase in glutamine, which paralleled a 2- to 3-fold increase in GS activity. Approximately 15 min after the glutamine pool reached its peak, GOGAT activity began to decrease and eventually declined 2.5-fold. In contrast, when B. subtilis was shifted from glutamate medium to glutamate plus NH+4 medium, there was a 1- to 2-h lag before the glutamine pool and GS activity approached a steady state. As a result, GOGAT activity was low until the concentration of glutamine dropped below 2.5 mM. We propose that glutamine is an important regulatory element in the control of GOGAT activity and that one form of GOGAT regulation involves enzyme inactivation. In addition, these results indicate that glutamine is neither a corepressor nor a feedback inhibitor of GS.

Characterization of a pyridine nucleotide-nonspecific glutamate dehydrogenase from Bacteroides thetaiotaomicron

An oxidized nicotinamide adenine dinucleotide phosphate/oxidized nicotinamide adenine dinucleotide (NADP+/NAD+) nonspecific L-glutamate dehydrogenase from Bacteroides thetaiotaomicron was purified 40-fold (NADP+ or NAD+ activity) over crude cell extract by heat treatment, (NH4)2SO2 fractionation, diethylaminoethyl-cellulose, Bio-Gel A 1.5m, and hydroxylapatite chromatography. Both NADP+- and NAD+-dependent activities coeluted from all chromatographic treatments. Moreover, a constant ratio of NADP+/NAD+ specific activities was demonstrated at each purification step. Both activities also comigrated in 6% nondenaturing polyacrylamide gels. Affinity chromatography of the 40-fold-purified enzyme using Procion RED HE-3B gave a preparation containing both NADP+- and NAD+-linked activities which showed a single protein band of 48,5000 molecular weight after sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis. The dual pyridine nucleotide nature of the enzyme was most readily apparent in the oxidative direction. Reductively, the enzyme was 30-fold more active with reduced NADP than with reduced NAD. Nonlinear concave 1/V versus 1/S plots were observed for reduced NADP and NH4Cl. Salts (0.1 M) stimulated the NADP+-linked reaction, inhibited the NAD+-linked reaction, and had little effect on the reduced NADP-dependent reaction. The stimulatory effect of salts (NADP+) was nonspecific, regardless of the anion or cation, whereas the degree of NAD+-linked inhibition decreased in the order to I- greater than Br- greater than Cl- greater than F-. Both NADP+ and NAD+ glutamate dehydrogenase activities were also detected in cell extracts from representative strains of other bacteroides deoxyribonucleic acid homology groups.

Selection of Bacillus subtilis mutants impaired in ammonia assimilation

The selection of Bacillus subtilis mutants capable of using D-histidine to fulfill a requirement for L-histidine resulted in mutants with either no glutamate synthase activity or increased amounts of an altered glutamine synthetase.

Effects of amino acids, adenine nucleotides and inorganic pyrophosphate on glutamine synthetase from Anabaena cylindrica

Glutamine synthetase (L-glutamate:ammonia ligase (ADP-forming), EC 6.3.1.2) from Anabaena cylindrica was inhibited by alanine, glycine, serine and aspartate. The effects of alanine and serine were uncompetitive with respect to glutamate, while those of glycine and asparatate were uncompetitive with respect to glutamate, while those of glycine and aspartate were non-competitive and mixed type respectively. Different pairs of amino acids and their various combinations caused a cumulative inhibition of the enzyme activity. Glutamine synthetase was also inhibited by ADP and AMP and both nucleotides affected the enzyme competitively with respect to ATP and non-competitively for glutamate. Inorganic pyrophosphate, between 2 and 3 mM, produced a very pronounced inhibiton of enzyme activity. The inhibition by PPi was uncompetitive for ATP. Various combinations of the adenine nucleotides, PPi and Pi exerted a cumulative inhibitory effect on the enzyme activity, as did the amino acids, in different combinations with either adenine nucleotides, PPi or Pi. The effects of the adenine nucleotides and the amino acids were more pronounced at higher concentrations of ammonia. Except for serine similar responses of these effectors were obtained with increasing concentrations of Mg2+. It is proposed that changes in the free concentrations of Mg2+ are important in energy-dependent regulation of the enzyme activity in this alga.