Physiological and biochemical analysis of the glutamine synthetase-impaired mutants of the nitrogen-fixing cyanobacteriumNostoc muscorum

Three types of glutamine synthetase (GS)-impaired mutants (gln) ofNostoc muscorum were isolated as ethylenediamine (EDA)-resistant phenotypes and characterized with respect to heterocyst development, nitrogen fixation, ammonium metabolism, photosynthetic characteristics, and glutamine synthetase activity. The criterion for categorizing the mutants was the extent of loss of GS activity (both in transferase and biosynthetic assays) compared with wild type; it was 70% in EDA-1, 30% in EDA-2, and more than 90% in EDA-3 strains. The level of nitrogenase activity in mutant strains was proportionate to heterocyst frequency and was found refractory to ammonium and EDA repression. In EDA-resistant strains, development of heterocysts and their spacing pattern remained unaffected and did not respond to treatment of amino acid analogues, drugs, and ammoniacal compounds which otherwise either stimulated or suppressed the number and altered the spacing pattern in wild type. A biphasic pattern of ammonium uptake indicating two transport systems was observed in all the strains except that the Km values for both high- and low-affinity systems were altered in mutant strains. In vivo treatment with MSX or EDA significantly inhibited the GS activity in wild type, whereas mutant strains did not respond to these treatments and were able to liberate NH ₄ ⁺ continuously into the medium without MSX treatment. During NH ₄ ⁺ uptake, percentage inhibition of O₂ evolution and changes in increase of fluorescence intensity were low in EDA strains compared with wild type. Assessment of GS protein with antibodies against GS and quantitative polyacrylamide gel electrophoresis (PAGE) suggested that loss in specific activity of GS per milligram of extractable protein in EDA mutants was owing to low production of GS-specific protein. SDS-PAGE of purified GS enzyme from all the strains revealed only one polypeptide band of molecular weight of about 51.28 kDa.     

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.     

Expression and purification of glutamine synthetase cloned from Bacteroides fragilis

A glutamine synthetase (GS) gene, glnA, from Bacteroides fragilis was cloned on a recombinant plasmid pJS139 which enabled Escherichia coli glnA deletion mutants to utilize (NH4)2SO4 as a sole source of nitrogen. DNA homology was not detected between the B. fragilis glnA gene and the E. coli glnA gene. The cloned B fragilis glnA gene was expressed from its own promoter and was subject to nitrogen repression in E. coli, but it was not able to activate histidase activity in an E. coli glnA ntrB ntrC deletion mutant containing the Klebsiella aerogenes hut operon. The GS produced by pJS139 in E. coli was purified; it had an apparent subunit Mr of approximately 75,000, which is larger than that of any other known bacterial GS. There was very slight antigenic cross-reactivity between antibodies to the purified cloned B. fragilis GS and the GS subunit of wild-type E. coli.     

Role of glutamine synthetase in nitrogen metabolite repression in Aspergillus nidulans

Glutamine synthetase (GS), EC 6.3.1.2, is a central enzyme in the assimilation of nitrogen and the biosynthesis of glutamine. We have isolated the Aspergillus nidulans glnA gene encoding GS and have shown that glnA encodes a highly expressed but not highly regulated mRNA. Inactivation of glnA results in an absolute glutamine requirement, indicating that GS is responsible for the synthesis of this essential amino acid. Even when supplemented with high levels of glutamine, strains lacking a functional glnA gene have an inhibited morphology, and a wide range of compounds have been shown to interfere with repair of the glutamine auxotrophy. Heterologous expression of the prokaryotic Anabaena glnA gene from the A. nidulans alcA promoter allowed full complementation of the A. nidulans glnADelta mutation. However, the A. nidulans fluG gene, which encodes a protein with similarity to prokaryotic GS, did not replace A. nidulans glnA function when similarly expressed. Our studies with the glnADelta mutant confirm that glutamine, and not GS, is the key effector of nitrogen metabolite repression. Additionally, ammonium and its immediate product glutamate may also act directly to signal nitrogen sufficiency.     

Differential Regulation of Nitrogen Metabolism in the Wild Type and the High-Light-Tolerant Mutant Cells of Anacystis nidulans

The glutamine synthetase activity in the wild type and high-light-tolerant mutant of Anacystis exhibited differential response to the increasing light intensity (2–40 W/m²). As evident from the results, the glutamine synthetase (GS) activity in the wild type is more dependent on respiration, whereas the GS enzyme in the mutant cells derived its carbon and energy from photosynthesis. Further, results revealed that the reduced GS activity in the wild-type cells under the high-light stress was accompanied by high aspartate amino transferase (AST/GOT) activity and low alanine amino transferase (ALT/GPT) activity. On the contrary, high GS activity in the mutant cells was accompanied by low AST/GOT enzyme activity and high ALT/GPT activity. It was inferred that mutant and wild-type cells adapt to the high-light stress by different mechanisms.     

Altered kinetic properties of tyrosine-183 to cysteine mutation in glutamine synthetase of anabaena variabilis strain SA1 is responsible for excretion of ammonium ion produced by nitrogenase

A L-methionine- D, L-sulfoximine-resistant mutant of the cyanobacterium Anabaena variabilis, strain SA1, excreted the ammonium ion generated from N(2) reduction. In order to determine the biochemical basis for the NH(4)(+)-excretion phenotype, glutamine synthetase (GS) was purified from both the parent strain SA0 and from the mutant. GS from strain SA0 (SA0-GS) had a pH optimum of 7.5, while the pH optimum for GS from strain SA1 (SA1-GS) was 6.8. SA1-GS required Mn(+2) for optimum activity, while SA0-GS was Mg(+2) dependent. SA0-GS had the following apparent K(m) values at pH 7.5: glutamate, 1.7 m M; NH(4)(+), 0.015 m M; ATP, 0.13 m M. The apparent K(m) for substrates was significantly higher for SA1-GS at its optimum pH (glutamate, 9.2 m M; NH(4)(+), 12.4 m M; ATP, 0.17 m M). The amino acids alanine, aspartate, cystine, glycine, and serine inhibited SA1-GS less severely than the SA0-GS. The nucleotide sequences of glnA (encoding glutamine synthetase) from strains SA0 and SA1 were identical except for a single nucleotide substitution that resulted in a Y183C mutation in SA1-GS. The kinetic properties of SA1-GS isolated from E. coli or Klebsiella oxytoca glnA mutants carrying the A. variabilis SA1 glnA gene were also similar to SA1-GS isolated from A. variabilis strain SA1. These results show that the NH(4)(+)-excretion phenotype of A. variabilis strain SA1 is a direct consequence of structural changes in SA1-GS induced by the Y183C mutation, which elevated the K(m) values for NH(4)(+) and glutamate, and thus limited the assimilation of NH(4)(+) generated by N(2) reduction. These properties and the altered divalent cation-mediated stability of A. variabilis SA1-GS demonstrate the importance of Y183 for NH(4)(+) binding and metal ion coordination.     

In vivo fluxes in the ammonium-assimilatory pathways in corynebacterium glutamicum studied by 15N nuclear magnetic resonance

Glutamate dehydrogenase (GDH) and glutamine synthetase (GS)-glutamine 2-oxoglutarate-aminotransferase (GOGAT) represent the two main pathways of ammonium assimilation in Corynebacterium glutamicum. In this study, the ammonium assimilating fluxes in vivo in the wild-type ATCC 13032 strain and its GDH mutant were quantitated in continuous cultures. To do this, the incorporation of 15N label from [15N]ammonium in glutamate and glutamine was monitored with a time resolution of about 10 min with in vivo 15N nuclear magnetic resonance (NMR) used in combination with a recently developed high-cell-density membrane-cyclone NMR bioreactor system. The data were used to tune a standard differential equation model of ammonium assimilation that comprised ammonia transmembrane diffusion, GDH, GS, GOGAT, and glutamine amidotransferases, as well as the anabolic incorporation of glutamate and glutamine into biomass. The results provided a detailed picture of the fluxes involved in ammonium assimilation in the two different C. glutamicum strains in vivo. In both strains, transmembrane equilibration of 100 mM [15N]ammonium took less than 2 min. In the wild type, an unexpectedly high fraction of 28% of the NH4+ was assimilated via the GS reaction in glutamine, while 72% were assimilated by the reversible GDH reaction via glutamate. GOGAT was inactive. The analysis identified glutamine as an important nitrogen donor in amidotransferase reactions. The experimentally determined amount of 28% of nitrogen assimilated via glutamine is close to a theoretical 21% calculated from the high peptidoglycan content of C. glutamicum. In the GDH mutant, glutamate was exclusively synthesized over the GS/GOGAT pathway. Its level was threefold reduced compared to the wild type.     

Glutamine Synthetase Regulation, Adenylylation State, and Strain Specificity Analyzed by Polyacrylamide Gel Electrophoresis

We used polyacrylamide gel electrophoresis to examine the regulation and adenylylation states of glutamine synthetases (GSs) from Escherichia coli (GS(E)) and Klebsiella aerogenes (GS(K)). In gels containing sodium dodecyl sulfate (SDS), we found that GS(K) had a mobility which differed significantly from that of GS(E). In addition, for both GS(K) and GS(E), adenylylated subunits (GS(K)-adenosine 5'-monophosphate [AMP] and GS(E)-AMP) had lesser mobilities in SDS gels than did the corresponding non-adenylylated subunits. The order of mobilities was GS(K)-AMP < GS(K) < GS(E)-AMP < GS(E). We were able to detect these mobility differences with purified and partially purified preparations of GS, crude cell extracts, and whole cell lysates. SDS gel electrophoresis thus provided a means of estimating the adenylylation state and the quantity of GS present independent of enzymatic activity measurements and of determining the strain origin. Using SDS gels, we showed that: (i) the constitutively produced GS in strains carrying the glnA4 allele was mostly adenylylated, (ii) the GS-like polypeptide produced by strains carrying the glnA51 allele was indistinguishable from wild-type GS(K), and (iii) strains carrying the glnA10 allele contained no polypeptide having the mobility of GS(K) or GS(K)-AMP. Using native polyacrylamide gels, we detected the increased amount of dodecameric GS present in cells grown under nitrogen limitation compared with cells grown under conditions of nitrogen excess. In native gels there was neither a significant difference in the mobilities of adenylylated and non-adenylylated GSs nor a GS-like protein in cells carrying the glnA10 allele.     

Involvement of the product of the glnF gene in the autogenous regulation of glutamine synthetase formation in Klebsiella aerogenes.

Mutations in a site, glnF, linked by P1-mediated transduction of argG on the chromosome of Klebsiella aerogenes, result in a requirement for glutamine. Mutants in this gene have in all media a level of glutamine synthetase (GS) corresponding to the level found in the wild-type strain grown in the medium producing the strongest repression of GS. The adenylylation and deadenylylation of GS in glnF mutants is normal. The glutamine requirement of glnF mutants could be suppressed by mutations in the structural gene for GS, glnA. These mutations result in altered regulation of GS synthesis, regardless of the presence or absence of the glnF mutation (GlnR phenotype). In GlnR mutants the GS level is higher than in the wild-type strain when the cells are cultured in strongly repressing medium, but lower than in the wild-type strain when cells are cultured in a derepressing medium. Heterozygous merodiploids carrying a normal glnA gene as well as a glnA gene responsible for the GlnR phenotype behave in every respect like merodiploids carrying two normal glnA genes. These results confirm autogenous regulation of GS synthesis and indicate that GS is both a repressor and an activator of GS synthesis. The mutation in glnA responsible for the GLnR phenotype has apparently resulted in the formation of a GS that is incompetent both as repressor and as activator of GS synthesis. According to this hypothesis, the product of the glnF gene is necessary for activation of the glnA gene by GS.     

Isolation of Klebsiella aerogenes mutants cis-dominant for glutamine synthetase expression

We have isolated three strains of Klebsiella aerogenes that failed to show repression of glutamine synthetase even when grown under the most repressing conditions for the wild-type strain. These mutant strains were selected as glutamine-independent derivatives of a strain that is merodiploid for the glnA region and contains a mutated glnF allele. The mutation responsible for the Gln+ phenotype in each strain was tightly linked to glnA, the structural gene for glutamine synthetase, and was dominant to the wild-type allele. These mutations are probably lesions in the control region of the glnA gene, since each mutation was cis-dominant for constitutive expression of the enzyme in hybrid merodiploid strains. Strains harboring this class of mutations were unable to produce a high level of glutamine synthetase unless they also contained an intact glnF gene, and unless cells were grown in derepressing medium. This study supports the idea that the glnA gene is regulated both positively and negatively, and that the deoxyribonucleic acid sites critical for positive control and negative control are functionally distinct.     

Establishment of a Highly Efficient Ammonia Secreting Mutant of Synechococcus sp. PCC 7942 and the Glutamine Synthetase Activity,Photosynthesis and Growth in Its Immobilized Cells

A recombinate plasmid pDC-ATGS was constructed, which contained the antisense fragment of glnA gene from Anabaena sp. PCC 7120 and transformed the unicellular cyanobactefium Synechococcus sp. PCC 7942. The foreign DNA was inserted into the site of glnA locus of the chromosome through the homologous recombination. By using neomyisin, a highly efficient ammonia secretion mutant was selected. After immobilized, the cells of the mutant within polyurethane (PU) foams, glutamine synthetase (GS) and NIt4+ secretory activity of GS, and its growth and photosynthesis were measured. It was shown that NH4+ secretion of the immobilized mutant was enhanced 156 folds which was much higher than that of free-living cells of the wild type. The activity of GS was decreased by 73.6%. Growth of the mutant was the same as that of the wild type. The activity of photosystem Ⅱ in the immobilized mutant cells increased by 44% with 77 K fluorescence spectrum measurement.     

Role of glutamine synthetase in phenazine antibiotic production by Pantoea agglomerans Eh1087

Pantoea agglomerans strain Eh1087 produces the phenazine antibiotic D-alanylgriseoluteic acid. A glutamine auxotroph harboring an insertion in a putative glnA gene was obtained by transposon-mutagenesis of Eh1087 that produced less D-alanylgriseoluteic acid than the parental strain (strain Eh7.1). Cosmids encoding the Eh1087 glnA were isolated by their ability to complement the mutant for prototrophy. The role of the Eh1087 glnA locus was functionally confirmed by complementation of an Escherichia coli glnA mutant. Analysis of the nucleotide and deduced amino acid sequences of the Eh1087 glnA gene indicated a high degree of similarity to the glnA genes and glutamine synthetase enzymes of other Enterobacteriaceae. Isotopic labelling experiments with 15N-labelled ammonium sulfate demonstrated that wild-type Eh1087 incorporated 15N into griseoluteic acid more readily than the glnA mutant Eh7.1. We conclude that the 2 nitrogens in the phenazine nucleus originate from glutamine and the intracellular glutamine synthesized by Eh1087 is a source of the phenazine nucleus nitrogens even in glutamine-rich environments.     

Rhizobium meliloti 1021 has three differentially regulated loci involved in glutamine biosynthesis, none of which is essential for symbiotic nitrogen fixation.

We have cloned and characterized three distinct Rhizobium meliloti loci involved in glutamine biosynthesis (glnA, glnII, and glnT). The glnA locus shares DNA homology with the glnA gene of Klebsiella pneumoniae, encodes a 55,000-dalton monomer subunit of the heat-stable glutamine synthetase (GS) protein (GSI), and complemented an Escherichia coli glnA mutation. The glnII locus shares DNA homology with the glnII gene of Bradyrhizobium japonicum and encodes a 36,000-dalton monomer subunit of the heat-labile GS protein (GSII). The glnT locus shares no DNA homology with either the glnA or glnII gene and complemented a glnA E. coli strain. The glnT locus codes for an operon encoding polypeptides of 57,000, 48,000, 35,000, 29,000, and 28,000 daltons. glnA and glnII insertion mutants were glutamine prototrophs, lacked the respective GS form (GSI or GSII), grew normally on different nitrogen sources (Asm+), and induced normal, nitrogen-fixing nodules on Medicago sativa plants (Nod+ Fix+). A glnA glnII double mutant was a glutamine auxotroph (Gln-), lacked both GSI and GSII forms, but nevertheless induced normal Fix+ nodules. glnT insertion mutants were prototrophs, contained both GSI and GSII forms, grew normally on different N sources, and induced normal Fix+ nodules. glnII and glnT, but not glnA, expression in R. meliloti was regulated by the nitrogen-regulatory genes ntrA and ntrC and was repressed by rich N sources such as ammonium and glutamine.     

Cloning and expression of the Thiobacillus ferrooxidans glutamine synthetase gene in Escherichia coli.

The glutamine synthetase (GS) gene glnA of Thiobacillus ferrooxidans was cloned on recombinant plasmid pMEB100 which enabled Escherichia coli glnA deletion mutants to utilize (NH4)2SO4 as the sole source of nitrogen. High levels of GS-specific activity were obtained in the E. coli glnA deletion mutants containing the T. ferrooxidans GS gene. The cloned T. ferrooxidans DNA fragment containing the glnA gene activated histidase activity in an E. coli glnA glnL glnG deletion mutant containing the Klebsiella aerogenes hut operon. Plasmid pMEB100 also enabled the E. coli glnA glnL glnG deletion mutant to utilize arginine or low levels of glutamine as the sole source of nitrogen. There was no detectable DNA homology between the T. ferrooxidans glnA gene and the E. coli glnA gene.     

Glutamine synthetase of Klebsiella aerogenes: genetic and physiological properties of mutants in the adenylylation system.

Mutations resulting in defects in the adenylylation system of glutamine synthetase (GS) affect the expression of glnA, the structural gene for GS. Mutants with lesions in glnB are glutamine auxotrophs and contain repressed levels of highly adenylylated GS. Glutamine-independent revertants of the glnB3 mutant have acquired an additional mutation at the glnE site. The glnE54 mutant is incapable of adenylylating GS and produces high levels of enzyme, even when ammonia is present in the growth medium. The fact that mutations in glnB and glnE simultaneously disturb both the normal adenylylation and repression patterns of GS in Klebsiella aerogenes indicates that the adenylylation system, or adenylylation state, of GS is critical for the regulation of synthesis of GS.     

Rhizobium sp. strain ORS571 ammonium assimilation and nitrogen fixation.

Among rhizobia studied, Rhizobium sp. strain ORS571 alone grew unambiguously on N2 as sole N source. In ORS571 , only the glutamine synthetase (GS)-glutamate synthase ( GOGAT ) pathway assimilated ammonium. However, ORS571 exhibited two unique physiological aspects of this pathway: ORS571 had only GS I, whereas all other Rhizobiaceae studied had both GS I and GS II, and both NADPH- and NADH-dependent GOGAT activities were present. ORS571 GS-affected and NADPH- GOGAT -affected mutant strains were defective in both ammonium assimilation (Asm-) and N2 fixation (Nif-) in culture and in planta ; NADH- GOGAT mutants were Asm- but Nif+. "Bacteroid" GS activity was essentially nil, suggesting symbiotic ammonium export. Physiological studies on effects of glutamine, ammonium, methionine sulfoximine, and diazo-oxo-norleucine on nitrogenase induction in culture implied a regulatory role for the intracellular glutamine pool.     

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.