Regulation of glutamine synthetase activity by adenylylation in the Gram-positive bacterium Streptomyces cattleya

Characterization of Rhodococcus sp. A5wh isolated from a high altitude Andean lake to unravel the survival strategy under lithium stress

Lithium (Li) is widely distributed in nature and has several industrial applications. The largest reserves of Li (over 85%) are in the so-called "triangle of lithium" that includes the Salar de Atacama in Chile, Salar de Uyuni in Bolivia and Salar del Hombre Muerto in Argentina. Recently, the use of microorganisms in metal recovery such as copper has increased; however, there is little information about the recovery of lithium. The strain Rhodococcus sp. A5_wh used in this work was previously isolated from Laguna Azul. The assays revealed that this strain was able to accumulate Li (39.52% of Li/g microbial cells in 180min) and that it was able to grow in its presence up to 1M. In order to understand the mechanisms implicated in Li tolerance, a proteomic approach was conducted. Comparative proteomic analyses of strain A5_wh exposed and unexposed to Li reveal that 17 spots were differentially expressed. The identification of proteins was performed by MALDI-TOF/MS, and the obtained results showed that proteins involved in stress response, transcription, translations, and metabolism were expressed under Li stress. This knowledge constitutes the first proteomic approach to elucidate the strategy followed by Rhodococcus to adapt to Li.

The actinorhizal root-nodule symbiont Frankia sp. strain CpI1 has two glutamine synthetases

Frankia sp. strain CpI1 has two glutamine synthetases. Glutamine synthetase I (GSI) is present during growth on ammonium or N(2) and is similar to classical prokaryotic glutamine synthetases. Gel-filtration chromatography gave a molecular weight estimate of about 680,000 for the GSI holoenzyme, and denaturing polyacrylamide gel electrophoresis yielded a subunit molecular weight of about 59,000, indicating that GSI is most likely a dodecamer. GSI is regulated by adenylylation, as shown by the presence of two spots on two-dimensional polyacrylamide gel electrophoresis and by its behavior during treatment with snake venom phosphodiesterase. GSII is derepressed during nitrogen starvation and accounts for about 95% of the glutamine synthetase activity in nitrogen-starved cells. It is heat-labile and has a subunit molecular weight of about 43,000. Frankia GSII is similar to GSII enzymes found in all but one member of the Rhizobiaceae analyzed to date. The presence of a second glutamine synthetase in Frankia lends support to the proposal that symbiotic organisms have unique modes of nitrogen nutrition but reopens questions about the origins and uniqueness of GSII genes in members of the Rhizobiaceae.

A complex role of Amycolatopsis mediterranei GlnR in nitrogen metabolism and related antibiotics production

Amycolatopsis, genus of a rare actinomycete, produces many clinically important antibiotics, such as rifamycin and vancomycin. Although GlnR of Amycolatopsis mediterranei is a direct activator of the glnA gene expression, the production of GlnR does not linearly correlate with the expression of glnA under different nitrogen conditions. Moreover, A. mediterranei GlnR apparently inhibits rifamycin biosynthesis in the absence of nitrate but is indispensable for the nitrate-stimulating effect for its production, which leads to the hyper-production of rifamycin. When glnR of A. mediterranei was introduced into its phylogenetically related organism, Streptomyces coelicolor, we found that GlnR widely participated in the host strain's secondary metabolism, resemblance to the phenotypes of a unique S. coelicolor glnR mutant, FS2. In contrast, absence or increment in copy number of the native S. coelicolor glnR did not result in a detectable pleiotrophic effect. We thus suggest that GlnR is a global regulator with a dual functional impact upon nitrogen metabolism and related antibiotics production.

Purification and properties of glutamine synthetase from Hydrogenobacter thermophilus TK-6

Hydrogenobacter thermophilus TK-6, a thermophilic and obligately chemoautotrophic bacterium, assimilates ammonium using glutamine synthetase (GS). GS was purified using three chromatography steps. The purified GS was found to belong to GS type I on the basis of its subunit composition and molecular weight. The Mg2+ -dependent activity of this GS significantly increased after incubation with phosphodiesterase, indicating that GS is subject to adenylyl/deadenylyl regulation, a posttranslational modification system reported mainly among enterobacteria. The degree of this posttranslational modification changed depending on growth phase, confirming that adenylyl/deadenylyl regulation functions in vivo. Interestingly, the Km for glutamate of H. thermophilus GS was significantly higher than those of other organisms, suggesting that GS activity is affected by intracellular glutamate concentration.

Nitrogen metabolism in Streptomyces coelicolor A3(2): modification of glutamine synthetase I by an adenylyltransferase

An internal adenylyltransferase gene (glnE) fragment from Streptomyces coelicolor was amplified using heterologous PCR primers derived from consensus motifs. The sequence had significant similarity to bacterial glnE genes, and included a motif typical of the C-terminal adenylyltransferase domain of glnE. glnE from S. coelicolor lies on the Asel-C fragment of the chromosome and is localized near glnA (encoding glutamine synthetase I, GSI) and glnII (encoding GSII). To analyse the function of glnE in S. coelicolor, glnE (S. coelicolor E4) and glnA (S. coelicolor HT107) gene replacement mutants were constructed. The GSI activity of the glnE mutant was not down-regulated after an ammonium shock. However, the GSI activity of the wild-type cells decreased to 60% of the original activity. The glnA mutant is not glutamine auxotrophic, but in the gamma-glutamyltransferase assay no GSI activity was detected in unshifted and shifted HT107 cells. By snake venom phosphodiesterase treatment the GSI activity in the wild-type can be reconstituted, whereas no alteration is observed in the E4 mutant. Additionally, the loss of short-term GSI regulation in the E4 mutant was accompanied by an increased glutamine:glutamate ratio.

Nitrogen control in bacteria

Nitrogen metabolism in prokaryotes involves the coordinated expression of a large number of enzymes concerned with both utilization of extracellular nitrogen sources and intracellular biosynthesis of nitrogen-containing compounds. The control of this expression is determined by the availability of fixed nitrogen to the cell and is effected by complex regulatory networks involving regulation at both the transcriptional and posttranslational levels. While the most detailed studies to date have been carried out with enteric bacteria, there is a considerable body of evidence to show that the nitrogen regulation (ntr) systems described in the enterics extend to many other genera. Furthermore, as the range of bacteria in which the phenomenon of nitrogen control is examined is being extended, new regulatory mechanisms are also being discovered. In this review, we have attempted to summarize recent research in prokaryotic nitrogen control; to show the ubiquity of the ntr system, at least in gram-negative organisms; and to identify those areas and groups of organisms about which there is much still to learn.

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.

Evolutionary relationships of bacterial and archaeal glutamine synthetase genes

Glutamine synthetase (GS), an essential enzyme in ammonia assimilation and glutamine biosynthesis, has three distinctive types: GSI, GSII and GSIII. Genes for GSI have been found only in bacteria (eubacteria) and archaea (archaebacteria), while GSII genes only occur in eukaryotes and a few soil-dwelling bacteria. GSIII genes have been found in only a few bacterial species. Recently, it has been suggested that several lateral gene transfers of archaeal GSI genes to bacteria may have occurred. In order to study the evolution of GS, we cloned and sequenced GSI genes from two divergent archaeal species: the extreme thermophile Pyrococcus furiosus and the extreme halophile Haloferax volcanii. Our phylogenetic analysis, which included most available GS sequences, revealed two significant prokaryotic GSI subdivisions: GSI-alpha and GSI-beta. GSI-alpha-genes are found in the thermophilic bacterium, Thermotoga maritima, the low G+C Gram-positive bacteria, and the Euryarchaeota (includes methanogens, halophiles, and some thermophiles). GSI-beta-type genes occur in all other bacteria. GSI-alpha- and GSI-beta-type genes also differ with respect to a specific 25-amino-acid insertion and adenylylation control of GS enzyme activity, both absent in the former but present in the latter. Cyanobacterial genes lack adenylylation regulation of GS and may have secondarily lost it. The GSI gene of Sulfolobus solfataricus, a member of the Crenarchaeota (extreme thermophiles), is exceptional and could not be definitely placed in either subdivision.

Effects of Mn2+ and Mg2+ on assimilation of NO3- and NH4+ by soil microorganisms

Although it has been demonstrated that Mn2+ and Mg2+ can influence the activity of glutamine synthetase in various organisms, there is little information concerning the effects of these cations on the activity of this enzyme in soil microorganisms or on ability of these microorganisms to assimilate NO3- and NH4+. We studied the effects of different concentrations of Mn2+ and Mg2+ on assimilatory NO3- reduction and NH4+ assimilation in cultures of two microorganisms commonly found in soil [Pseudomonas fluorescens (ATCC 13525) and Azotobacter chroococcum (ATCC 9043)] and in an enrichment culture of soil microorganisms. We found that Mn2+ strongly inhibited NH4+ assimilation by soil microorganisms and blocked the inhibitory effect of NH4+ on assimilatory NO3- reductase (ANR) activity, thereby uncoupling ANR activity from nitrogen assimilation and causing the NH4+ formed by ANR activity to be released to the environment. Mg2+ counteracted the effect of Mn2+ on microbial metabolism of nitrogen, which suggests that the overall effect of these cations on nitrogen assimilation by soil microorganisms will depend on the ratio of their concentrations in soil.

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.

Specific in vitro guanylylation of a 43-kilodalton membrane-associated protein of Streptomyces coelicolor

Incubation of [alpha-32P]GTP with cellular extracts or membranes of Streptomyces coelicolor labels a protein of 43 kDa, which was also labeled with [8,5'-3H]GTP but not with [alpha-32P]ATP or [gamma-32P]GTP. Radioactivity remained associated with this protein after boiling in 0.1 N NaOH, but it was dissociated after incubation in 0.1 N HCl or hydroxylamine. Chromatographic analysis of the HCl-dissociated compound showed that GMP was the covalently bound nucleotide. Furthermore, guanylylation appeared to be reversible and to take place by a pyrophosphorylytic mechanism. Guanylylation was more efficient at low temperatures. Several Streptomyces species showed a guanylylated protein with a similar molecular mass.

Identification and cloning of the glnR locus, which is required for transcription of the glnA gene in Streptomyces coelicolor A3(2)

Six Streptomyces coelicolor mutants that required glutamine for growth at the wild-type rate on all nitrogen sources (Gln-) were isolated. The phenotypes of all six mutants were similar. The glutamine synthetase (GS) levels were 20- to 100-fold lower in extracts of the Gln- mutants than in extracts of their parents. The reduced levels of GS activity in the Gln- mutants were not due to adenylylation of the GS protein, because GS activity in Gln- extracts did not increase after snake venom phosphodiesterase treatment. No transcripts of the GS structural gene (glnA) could be detected in RNA isolated from the Gln- mutants in primer extension experiments. All six gln mutations mapped adjacent to adeA. S. coelicolor chromosomal DNA complementing the Gln- mutants was isolated from a library of S. coelicolor chromosomal DNA constructed in the low-copy-number S. coelicolor plasmid pIJ922. Subcloning experiments showed that a 1.45-kb DNA fragment could complement all six Gln- mutants. This DNA fragment did not hybridize with either the cloned S. coelicolor glnA gene or the cloned S. viridochromogenes GSII gene in Southern blots. Since glnA transcription was restored in the Gln- mutants containing the complementing DNA, the gln mutations appear to lie in one or more closely linked genes that are required for glnA transcription in S. coelicolor.

Overexpression of a Streptomyces viridochromogenes gene (glnII) encoding a glutamine synthetase similar to those of eucaryotes confers resistance against the antibiotic phosphinothricyl-alanyl-alanine

Phosphinothricyl-alanyl-alanine (PTT), also known as bialaphos, contains phosphinothricin, a potent inhibitor of glutamine synthetase (GS). A 2.75-kilobase NcoI fragment of the Streptomyces viridochromogenes PTT-resistant mutant ES2 cloned on a multicopy vector mediated PTT resistance to S. lividans and to S. viridochromogenes. Nucleotide sequence analysis of the 2.75-kb NcoI fragment revealed the presence of three open reading frames. Open reading frame 3 was termed glnII since significant similarity was found between its deduced amino acid sequence and those from GS of eucaryotes and GSII of members of the family Rhizobiaceae. Subcloning experiments showed that PTT resistance is mediated by overexpression of glnII encoding a 37.3-kilodalton protein of 343 amino acids. A three- to fourfold increase in gamma-glutamyltransferase activity could be observed in S. lividans transformants carrying the glnII gene on a multicopy plasmid. For S. viridochromogenes it was shown that PTT resistance conferred by the 2.75-kb NcoI fragment was dependent on its multicopy state. GS activity encoded by glnII was found to be heat labile. Southern hybridization with seven different Streptomyces strains suggested that they all carry two types of GS genes, glnA and glnII.

Cloning and nucleotide sequence of an archaebacterial glutamine synthetase gene: phylogenetic implications

The glnA gene of the thermophilic sulphur-dependent archaebacterium Sulfolobus solfataricus was identified by hybridization with the corresponding gene of the cyanobacterium Spirulina platensis and cloned in Escherichia coli. The nucleotide sequence of the 1696 bp DNA fragment containing the structural gene for glutamine synthetase was determined, and the derived amino acid sequence (471 residues) was compared to the sequences of glutamine synthetases from eubacteria and eukaryotes. The homology between the archaebacterial and the eubacterial enzymes is higher (42%-49%) than that found with the eukaryotic counterpart (less than 20%). This was true also when the five most conserved regions, which it is possible to identify in both eubacterial and eukaryotic glutamine synthetases, were analysed.

Regulation of glutamine synthetase in Streptomyces coelicolor

Glutamine synthetase (GS) in Streptomyces coelicolor was shown to be regulated at two levels. First, the S. coelicolor GS protein is subject to a posttranslational covalent modification which is likely to involve adenylylation. Adenylylation is important in regulating GS activity both after sudden changes in ammonium availability and during steady-state growth. Since higher levels of adenylylated GS were seen in S. coelicolor mutants deficient in glutamate synthase than in wild-type cells, glutamine or a metabolite derived from glutamine is likely to be involved in the metabolic signal that regulates GS adenylylation. Second, the GS structural gene (glnA) is transcriptionally regulated in response to nitrogen availability during steady-state growth. Transcription of the glnA gene occurred from the same promoter during vegetative growth, stationary phase, and sporulation. The nucleotide sequence of this promoter has significant homology with the -10, but not the -35, region of the consensus sequence of Streptomyces vegetative promoters. The glnA gene is transcribed as a monocistronic mRNA.

Purification and characterisation of glutamine synthetase from Nocardia corallina

Glutamine synthetase (GS) (EC 6.3.1.2) has been purified 67-fold from Nocardia corallina. The apparent Mr of the GS subunit was approximately 56,000. Assuming the enzyme is a typical dodecamer this indicates a particle mass for the undissociated enzyme of 672,000. The GS is regulated by adenylylation and deadenylylation, and subject to feedback inhibition by alanine and glycine. The pH profiles assayed by the gamma-glutamyl transferase method were similar for NH+4-treated and untreated cell extracts and an isoactivity point was not obtained from these curves. GS activity was repressed by (NH4)2SO4 and glutamate. Cells grown in the presence of glutamine, alanine, proline and histidine had enhanced levels of GS activity. The GS of N. corallina cross-reacted with antisera prepared against GS from a Gram-negative Thiobacillus ferrooxidans strain but not with antisera raised against GS from a Gram-positive Clostridium acetobutylicum strain.

Isolation and nitrogen-fixing activity of Frankia sp. strain CpI1 vesicles

Under N2-fixing conditions in aerobic culture and in symbiosis, frankiae produce spherical, multicellular structures that have been called vesicles. The vesicles have been proposed as the site of nitrogen fixation. We isolated vesicles by using density centrifugation in a single-step sucrose gradient. Vesicles migrated out of 50% (wt/vol) sucrose and banded at the 40 to 50% sucrose interface; they were intact, as assessed by transmission electron microscopy, and were free of hyphal contamination. Specific activities of nitrogenase in vesicles prepared anaerobically were up to 100-fold greater than the specific activity of the largely hyphal pellet, depending on the recovery of vesicles. All of the activity in the pellet could be accounted for by the number of vesicles present in the pellet. Glutamine synthetase activity in crude extracts of vesicles was extremely low.

Properties and regulation of glutamine synthetase from Rhodospirillum rubrum

Glutamine synthetase from Rhodospirillum rubrum was purified and characterized with respect to its pH optimum and the effect of Mg2+ on its active and inactive forms. Both adenine and phosphorus were incorporated into the inactive form of the enzyme, indicating covalent modification by AMP. The modification could not be removed by phosphodiesterase. Evidence for regulation of the enzyme by oxidation was obtained. Extracts from oxygen-treated cells had lower specific activities than did extracts from cells treated anaerobically. Glutamine synthetase activity was found to decrease in the dark in phototrophically grown cells; activity was recovered on re-illumination.

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.

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.

Sporulation of Streptomyces griseus in submerged culture

A wild-type strain of Streptomyces griseus forms spores both on solid media (aerial spores) and in liquid culture (submerged spores). Both spore types are highly resistant to sonication, but only aerial spores are resistant to lysozyme digestion. Electron micrographs suggest that lysozyme sensitivity may result from the thinner walls of the submerged spores. Studies of the life cycle indicate that neither streptomycin excretion nor extracellular protease activity is required for sporulation: the analysis of mutants, however, suggests that antibiotic production may be correlated with the ability to sporulate. A method was devised to induce the rapid sporulation of S. griseus in a submerged culture. This method, which depends on nutrient deprivation, was used to determine that either ammonia or phosphate starvation can trigger sporulation and that the enzyme glutamine synthetase may be useful as a sporulation marker after phosphate deprivation.

Inactivation of Glutamine Synthetase by Ammonia Shock in the Gram-Positive Bacterium Streptomyces cattleya

In cultures of the gram-positive bacterium Streptomyces cattleya , a rapid inactivation of glutamine synthetase was seen after ammonia shock. pH activity curves for ammonia-shocked and control cultures are shown. A peak of glutamine synthetase activity was seen during fermentation for production of the antibiotic thienamycin.

Regulation of glutamine synthetase from Saccharomyces cerevisiae by repression, inactivation and proteolysis

Glutamine synthetase activity is modulated by nitrogen repression and by two distinct inactivation processes. Addition of glutamine to exponentially grown yeast leads to enzyme inactivation. 50% of glutamine synthetase activity is lost after 30 min (a quarter of the generation time). Removing glutamine from the growth medium results in a rapid recovery of enzyme activity. A regulatory mutation (gdhCR mutation) suppresses this inactivation by glutamine in addition to its derepressing effect on enzymes involved in nitrogen catabolism. The gdhCR mutation also increases the level of proteinase B in exponentially grown yeast. Inactivation of glutamine synthetase is also observed during nitrogen starvation. This inactivation is irreversible and consists very probably of a proteolytic degradation. Indeed, strains bearing proteinase A, B and C mutations are no longer inactivated under nitrogen starvation.