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.     

Tight linkage of glnA and a putative regulatory gene in Rhizobium leguminosarum.

Rhizobium leguminosarum, biovar viceae, strain RCC1001 contains two glutamine synthetase activities, GSI and GSII. We report here the identification of glnA, the structural gene for GSI. A 2 kb fragment of DNA was shown to complement the Gln- phenotype of Klebsiella pneumoniae glnA mutant strains. DNA sequence analysis revealed an open reading frame (ORF) of 469 codons specifying a polypeptide of 52,040 daltons. Its deduced amino acid sequence was found to be highly homologous to other glutamine synthetase sequences. This ORF was expressed in Escherichia coli minicells and the corresponding polypeptide reacted with an antiserum raised against GSI. Upstream of glnA we found an ORF of 111 codons (ORF111) preceded by the consensus sequence for an ntrA-dependent promoter. Minicells experiments showed a protein band, with a molecular weight in good agreement with that (10,469) deduced from the nucleotide sequence. On the basis of homology studies we discuss the possibility that the product of ORF111 is equivalent to the PII protein of E. coli and plays a similar role in regulation of nitrogen metabolism.     

Isolation, characterization, and complementation of Rhizobium meliloti 104A14 mutants that lack glutamine synthetase II activity.

The glutamine synthetase (GS)-glutamate synthase pathway is the primary route used by members of the family Rhizobiaceae to assimilate ammonia. Two forms of glutamine synthetase, GSI and GSII, are found in Rhizobium and Bradyrhizobium species. These are encoded by the glnA and glnII genes, respectively. Starting with a Rhizobium meliloti glnA mutant as the parent strain, we isolated mutants unable to grow on minimal medium with ammonia as the sole nitrogen source. For two auxotrophs that lacked any detectable GS activity, R. meliloti DNA of the mutated region was cloned and partially characterized. Lack of cross-hybridization indicated that the cloned regions were not closely linked to each other or to glnA; they therefore contain two independent genes needed for GSII synthesis or activity. One of the cloned regions was identified as glnII. An R. meliloti glnII mutant and an R. meliloti glnA glnII double mutant were constructed. Both formed effective nodules on alfalfa. This is unlike the B. japonicum-soybean symbiosis, in which at least one of these GS enzymes must be present for nitrogen-fixing nodules to develop. However, the R. meliloti double mutant was not a strict glutamine auxotroph, since it could grow on media that contained glutamate and ammonia, an observation that suggests that a third GS may be active in this species.     

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.     

Cloning and analysis of Agrobacterium tumefaciens C58 loci involved in glutamine biosynthesis: Neither the glnA (GSI) nor the glnII (GSII) gene plays a special role in virulence

Summary Using heterologous complementation of a glutamine synthetase deficient (glnA; GS^-) Escherichia coli mutant strain and heterologous DNA hybridization probes from Rhizobium meliloti and Bradyrhizobium japonicum, three distinct Agrobacterium tumefaciens loci involved in glutamine biosynthesis were identified. These loci correspond to the glnA (GSI), glnII (GSII) and a third previously unidentified locus, which is capable of complementing an E. coli glnA mutant, but may be cryptic in A. tumefaciens. The gene products encoded by the cloned glnA and glnII loci were identified using maxicells. Single insertion mutations in the glnA (GSI) and glnII (GSII) genes and a glnA glnII double mutant were constructed using gene replacement techniques. These mutant strains were examined for GSI and II activities, for growth on a variety of nitrogen (N) sources and for virulence properties on Kalanchoë plants. Neither glnA (GSI) nor glnII (GSII) were found to be essential for tumour induction on Kalanchoë nor for opine catabolism.     

Ammonium assimilation in Rhizobium phaseoli by the glutamine synthetase-glutamate synthase pathway.

Evidence from in vitro and in vivo studies showed that in Rhizobium phaseoli ammonium is assimilated by the glutamine synthetase (GS)-glutamate synthase NADPH pathway. No glutamate dehydrogenase activity was detected. R. phaseoli has two GS enzymes, as do other rhizobia. The two GS activities are regulated on the basis of the requirement for low (GSI) or high (GSII) ammonium assimilation. When the 2-oxoglutarate/glutamine ratio decreases, GSI is adenylylated. When GSI is inactivated, GSII is induced. However, induction of GSII activity varied depending on the rate of change of this ratio. GSII was inactivated after the addition of high ammonium concentrations, when the 2-oxoglutarate/glutamine ratio decreased rapidly. Ammonium inactivation resulted in alteration of the catalytic and physical properties of GSII. GSII inactivation was not relieved by shifting of the cultures to glutamate. After GSII inactivation, ammonium was excreted into the medium. Glutamate synthase activity was inhibited by some organic acids and repressed when cells were grown with glutamate as the nitrogen source.     

Cloning of the glutamine synthetase I gene from Rhizobium meliloti.

Glutamine synthetase is a major enzyme in the assimilation of ammonia by members of the genus Rhizobium. Two forms of glutamine synthetase are found in members of the genus Rhizobium, a heat-stable glutamine synthetase I (GSI) and a heat-labile GSII. As a step toward clarifying the role of these enzymes in symbiotic nitrogen fixation, we have cloned the structural gene for GSI from Rhizobium meliloti 104A14. A gene bank of R. meliloti was constructed by using the bacteriophage P4 cosmid pMK318. Cosmids that contain the structural gene for GSI were isolated by selecting for plasmids that permit ET8051, an Escherichia coli glutamine autotroph, to grow with ammonia as the sole nitrogen source. One of the cosmids, pJS36, contains an insert of 11.9 kilobases. ET8051(pJS36) grows slowly on minimal media. When a 3.7-kilobase HindIII fragment derived from this DNA is cloned into the HindIII site of pACYC177 and the plasmids are transformed into ET8051, rapid growth is observed when the insert is in one orientation (pJS44) but not the other (pJS45). Glutamine synthetase activity can be detected in ET8051(pJS44); most of this activity is heat stable. pJS36 hybridizes with the glnA structural gene from Escherichia coli. Insertion of a 2.7-kilobase Tetr determinant into a BglII site located within pJS44 abolishes all glutamine synthetase activity. This interrupted version of a glutamine synthetase gene was substituted for the normal R. meliloti sequence by homologous recombination in R. meliloti. Recombinants lose GSI activity, but retain GSII activity and grow well with ammonia as the sole nitrogen source. These mutants are unaffected in nodulation and nitrogen fixation.     

Comparative properties of glutamine synthetases I and II in Rhizobium and Agrobacterium spp

Some properties of glutamine synthetase I (GSI) and GSII are described for a fast-growing Rhizobium sp. (Rhizobium trifolii T1), a slow-growing Rhizobium sp. (Rhizobium japonicum USDA 83), and Agrobacterium tumefaciens C58. GSII of the fast-growing Rhizobium sp. and GSII of the Agrobacterium sp. were considerably more heat labile than GSII of the slow-growing Rhizobium sp. As previously shown in R. japonicum 61A76, GSI became adenylylated rapidly in all species tested in response to ammonium. GSII activity disappeared within one generation of growth in two of the strains, but the disappearance of GSII activity required two generations in another. Isoactivity points for transferase assay, which were derived from the pH curves of adenylylated GSI and deadenylylated GSI, were approximately pH 7.8 for both R. trifolii and A. tumefaciens. No isoactivity point was found for R. japonicum under the standard assay conditions used. When the feedback inhibitor glycine was used to inhibit differentially the adenylylated GSI and deadenylylated GSI of R. japonicum, an isoactivity point was observed at pH 7.3. Thus, the transferase activity of GSI could be determined independent of the state of adenylation. A survey of 23 strains of bacteria representing 11 genera indicated that only Rhizobium spp. and Agrobacterium spp. contained GSII. Thus, this enzyme appears to be unique for the Rhizobiaceae.     

Role of the Escherichia coli glnALG operon in regulation of ammonium transport.

Escherichia coli expresses a specific ammonium (methylammonium) transport system (Amt) when cultured with glutamate or glutamine as the nitrogen source. Over 95% of this Amt activity is repressed by growth of wild-type cells on media containing ammonia. The control of Amt expression was studied with strains containing specific mutations in the glnALG operon. GlnA- (glutamine synthetase deficient) mutants, which contain polar mutations on glnL and glnG genes and therefore have the Reg- phenotype (fail to turn on nitrogen-regulated operons such as histidase), expressed less than 10% of the Amt activity observed for the parental strain. Similarly, low levels of Amt were found in GlnG mutants having the GlnA+ Reg- phenotype. However, GlnA- RegC mutants (a phenotype constitutive for histidase) contained over 70% of the parental Amt activity. At steady-state levels, GlnA- RegC mutants accumulated chemically unaltered [14C]methylammonium against a 60- to 80-fold concentration gradient, whereas the labeled substrate was trapped within parental cells as gamma-glutamylmethylamide. GlnL Reg- mutants (normal glutamine synthetase regulation) had less than 4% of the Amt activity observed for the parental strain. However, the Amt activity of GlnL RegC mutants was slightly higher than that of the parental strain and was not repressed during growth of cells in media containing ammonia. These findings demonstrate that glutamine synthetase is not required for Amt in E. coli. The loss of Amt in certain GlnA- strains is due to polar effects on glnL and glnG genes, whose products are involved in expression of nitrogen-regulated genes, including that for Amt.     

The relationship between the state of adenylylation of glutamine synthetase I and the export of ammonium in free-living,N2-fixing Rhizobium

The relationship between ammonium assimilation and ammonium export has been studied in free-living, N₂-fixing Rhizobium sp. 32H1. After 55 to 67 h of microaerobic growth under a gas phase of 0.2% O₂ – 1.0% CO₂ – 98.8% Ar high levels of nitrogenase were observed concomitant with a slightly adenylylated glutamine synthetase (GSI) and some glutamine synthetase (GSII) activity. However, after growth of 89 h, or longer, GSI became adenylylated and the level of GSII had decreased. When the gas phase was shifted to 0.2% O₂ – 1.0% CO₂ – 98.8% N₂, a lag was observed before ammonium export could be detected in the 55 to 67 h cultures. No lag in ammonium export was observed in the cultures previously grown for 89 h. The onset of ammonium export in the 55 to 67 h cultures was found to correlate with the adenylylation state of GSI. There appeared to be no correlation between the level of GSII and the export of ammonium. Neither an increase in the adenylylation level of GSI nor ammonium export was observed when the 55 to 67 h cultures were maintained under the Ar gas mixture.Abbreviations GOGAT Glutamate synthase - GS glutamine synthetase - BES [N,N-bis(2-hydroxyethyl)-2-aminoethanesulfonic acid] - CTAB cetyltrimethylammonium bromide - MES [2-(N-morpholino)-ethane sulfonic acid]     

Physiological characteristics of glutamine synthetases I and II of Frankia sp. strain CpI1

Frankia sp. strain CpI1 has two glutamine synthetases designated GSI and GSII. Biosynthetic activities of both GSI and GSII were strongly inhibited by ADP and AMP. Alanine, aspartate, glycine and serine inhibited both GSI and GSII activities, whereas asparagine and lysine inhibited only slightly. Glutamine inhibited GSII but did not affect GSI. Since GSII is more heat labile than GSI, their relative heat stabilities can be used to determine their contribution to total GS activity. In cells grown on ammonia and on glutamine as sole combined-nitrogen sources most GS activity detected in crude extracts was due to GSI. In cells transferred to glutamate, GSI accounted for all GS activity in the first 15 h and then heat labile GSII was induced and increased to account for 40% of total GS activity within 50 h. Transfer of N₂-fixing cells to ammonia-containing medium led to a rapid decrease of GSII and a slow increase of GSI activity within 24 h. Conversely, when ammonia-grown cells were transferred to combined nitrogen-free medium, GSI activity gradually decreased and GSII increased before total activity leveled off in 50 h. GSII appears to be an ammonia-assimilating enzyme specifically synthesized during perceived N-starvation of Frankia cells.     

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

Abstract: 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.     

Inhibition of F plasmid replication in htpR mutants of Escherichia coli deficient in sigma 32 protein

Summary In Drosophila melanogaster there are two glutamine synthetase (GS) (EC 6.3.1.2) isozymes. They are called GSI and GSII. The two enzymes have different subunits and different genetic determination. A DNA fragment that comprises 80% of the coding region of the glutamine synthetase gene of Chinese hamster ovary (CHO) cells allowed the identification and cloning of an homologous DNA fragment of Drosophila. This sequence is located at the 10B8-11 region on the X chromosome. Dose variation of a chromosomal segment from 9F3 to 10C1-2, which encompasses the 10B region, leads to proportional variations of GSII without apparently influencing the amount of GSI.     

The glutamine synthetases of rhizobia: phylogenetics and evolutionary implications

Glutamine synthetase exists in at least two related forms, GSI and GSII, the sequences of which have been used in evolutionary molecular clock studies. GSI has so far been found exclusively in bacteria, and GSII has been found predominantly in eukaryotes. To date, only a minority of bacteria, including rhizobia, have been shown to express both forms of GS. The sequences of equivalent internal fragments of the GSI and GSII genes for the type strains of 16 species of rhizobia have been determined and analyzed. The GSI and GSII data sets do not produce congruent phylogenies with either neighbor-joining or maximum-likelihood analyses. The GSI phylogeny is broadly congruent with the 16S rDNA phylogeny for the same bacteria; the GSII phylogeny is not. There are three striking rearrangements in the GSII phylograms, all of which might be explained by horizontal gene transfer to Bradyrhizobium (probably from Mesorhizobium), to Rhizobium galegae (from Rhizobium), and to Mesorhizobium huakuii (perhaps from Rhizobium). There is also evidence suggesting intrageneric DNA transfer within Mesorhizobium. Meta-analysis of both GS genes from the different genera of rhizobia and other reference organisms suggests that the divergence times of the different rhizobium genera predate the existence of legumes, their host plants.