An additional PII in Escherichia coli: a new regulatory protein in the glutamine synthetase cascade

Abstract The P_II protein in the glutamine synthetase cascade transduces the nitrogen signal, as sensed by uridylyltransferase, both to the NRII/NRI two-component system and to adenylyltransferase, to regulate the activity of glutamine synthetase. Here we describe the amplification of a chromosomal DNA fragment from Escherichia coli which contains the sequence of a P_II homologue. The derived amino acid sequence of this DNA fragment is 67% identical to E. coli P_II. It contains the conserved tyrosine residue which is known to be the site of uridylylation in P_II. E. coli is the first organism in which two different P_II proteins have been detected.     

Modification of the pII protein in response to carbon and nitrogen availability in filamentous heterocystous cyanobacteria

Abstract In the filamentous cyanobacterium Calothrix PCC 7504, which fixes N₂ aerobically, the modification state of the regulatory P_II protein (GlnB) was shown to depend on nitrogen and carbon availability, as observed in the unicellular non-fixing strain Synechococcus PCC 7942. However, the conditions for modifications, the time dependence of the process and the electrophoretic behavior of the native P_II isoforms differed somewhat between the two strains. In another strain, Calothrix PCC 7601, which has lost the capability to fix N₂, P_II was modified only if ammonia plus an inhibitor of glutamine synthetase were present. It is proposed that: (i) the behavior of the P_II proteins depends upon the physiological properties of the strains; and (ii) the modification system of P_II per se may differ between the two cyanobacterial genera.     

The glnB gene of Rhizobium leguminosarum biovar viceae

Abstract An open-reading frame (ORF111) upstream of the glutamine synthetase I structural gene ( glnA ) in Rhizobium leguminosarum biovar viceae encodes a protein which is highly homologous to the P_II protein (encoded by glnB ) of enteric bacteria. ORF111 was cloned in a number of different plasmid vectors and shown to complement a K. pneumoniae glnB mutant. We propose that ORF111 encodes the P_II protein of R. leguminosarum and that it should be designated glnB .     

Heterotrimerization of PII-like signalling proteins: implications for PII-mediated signal transduction systems

PII-like signalling molecules are trimeric proteins composed of 12-13 kDa polypeptides encoded by the glnB gene family. Heterologous expression of a cyanobacterial glnB gene in Escherichia coli leads to an inactivation of E. coli's own PII signalling system. In the present work, we show that this effect is caused by the formation of functionally inactive heterotrimers between the cyanobacterial glnB gene product and the E. coli PII paralogues GlnB and GlnK. This led to the discovery that GlnK and GlnB of E. coli also form heterotrimers with each other. The influence of the oligomerization partner on the function of the single subunit was studied using heterotrimerization with the Synechococcus PII protein. Uridylylation of GlnB and GlnK was less efficient but still possible within these heterotrimers. In contrast, the ability of GlnB-UMP to stimulate the adenylyl-removing activity of GlnE (glutamine synthetase adenylyltransferase/removase) was almost completely abolished, confirming that rapid deadenylylation of glutamine synthetase upon nitrogen stepdown requires functional homotrimeric GlnB protein. Remarkably, however, rapid adenylylation of glutamine synthetase upon exposing nitrogen-starved cells to ammonium was shown to occur in the absence of a functional GlnB/GlnK signalling system as efficiently as in its presence.     

Dephosphorylation of the phosphoprotein PII in Synechococcus PCC 7942: identification of an ATP and 2-oxoglutarate-regulated phosphatase activity

The phosphorylation state of the putative signal transduction protein P_II from the cyanobacterium Synechococcus sp. strain PCC 7942 depends on the cellular state of nitrogen and carbon assimilation. In this study, dephosphorylation of phosphorylated P_II protein (P_II-P) was investigated both in vivo and in vitro . The in vivo studies implied that P_II-P dephosphorylation is regulated by inhibitory metabolites involved in the glutamine synthetase–glutamate synthase pathway of ammonium assimilation. An in vitro assay for P_II-P dephosphorylation was established that revealed a Mg²⁺-dependent P_II-P phosphatase activity. P_II-P phosphatase and P_II kinase activities could be separated biochemically. A partially purified P_II-P phosphatase preparation also catalysed the dephosphorylation of phosphoserine/phosphothreonine residues on other proteins in a Mg²⁺-dependent manner. However, only dephosphorylation of P_II-P was regulated by synergistic inhibition by ATP and 2-oxoglutarate. As the same metabolites stimulate the P_II kinase activity, it appears that the phosphorylation state of P_II is determined by ATP and 2-oxoglutarate-dependent reciprocal reactivity of P_II towards its phosphatase and kinase.     

Identification of three genes encoding P(II)-like proteins in Gluconacetobacter diazotrophicus: studies of their role(s) in the control of nitrogen fixation

In our studies on the regulation of nitrogen metabolism in Gluconacetobacter diazotrophicus, an endophytic diazotroph of sugarcane, three glnB-like genes were identified and their role(s) in the control of nitrogen fixation was studied. Sequence analysis revealed that one P(II) protein-encoding gene, glnB, was adjacent to a glnA gene (encoding glutamine synthetase) and that two other P(II) protein-encoding genes, identified as glnK1 and glnK2, were located upstream of amtB1 and amtB2, respectively, genes which in other organisms encode ammonium (or methylammonium) transporters. Single and double mutants and a triple mutant with respect to the three P(II) protein-encoding genes were constructed, and the effects of the mutations on nitrogenase expression and activity in the presence of either ammonium starvation or ammonium sufficiency were studied. Based on the results presented here, it is suggested that none of the three P(II) homologs is required for nif gene expression, that the GlnK2 protein acts primarily as an inhibitor of nif gene expression, and that GlnB and GlnK1 control the expression of nif genes in response to ammonium availability, both directly and by relieving the inhibition by GlnK2. This model includes novel regulatory features of P(II) proteins.     

Physiological role of the GlnK signal transduction protein of Escherichia coli: survival of nitrogen starvation

Escherichia coli contains two PII-like signal trans-duction proteins, PII and GlnK, involved in nitrogen assimilation. We examined the roles of PII and GlnK in controlling expression of glnALG, glnK and nac during the transition from growth on ammonia to nitrogen starvation and vice versa. The PII protein exclusively controlled glnALG expression in cells adapted to growth on ammonia, but was unable to limit nac and glnK expression under conditions of nitrogen starvation. Conversely, GlnK was unable to limit glnALG expression in cells adapted to growth on ammonia, but was required to limit expression of the glnK and nac promoters during nitrogen starvation. In the absence of GlnK, very high expression of the glnK and nac promoters occurred in nitrogen-starved cells, and the cells did not reduce glnK and nac expression when given ammonia. Thus, one specific role of GlnK is to regulate the expression of Ntr genes during nitrogen starvation. GlnK also had a dramatic effect on the ability of cells to survive nitrogen starvation and resume rapid growth when fed ammonia. After being nitrogen starved for as little as 10 h, cells lacking GlnK were unable to resume rapid growth when given ammonia. In contrast, wild-type cells that were starved immediately resumed rapid growth when fed ammonia. Cells lacking GlnK also showed faster loss of viability during extended nitrogen starvation relative to wild-type cells. This complex phenotype resulted partly from the requirement for GlnK to regulate nac expression; deletion of nac restored wild-type growth rates after ammonia starvation and refeeding to cells lacking GlnK, but did not improve viability during nitrogen starvation. The specific roles of GlnK during nitrogen starvation were not the result of a distinct function of the protein, as expression of PII from the glnK promoter in cells lacking GlnK restored the wild-type phenotypes.     

Purification and characterization of the bifunctional uridylyltransferase and the signal transducing proteins GlnB and GlnK from Herbaspirillum seropedicae

GlnD is a bifunctional uridylyltransferase/uridylyl-removing enzyme that has a central role in the general nitrogen regulatory system NTR. In enterobacteria, GlnD uridylylates the PII proteins GlnB and GlnK under low levels of fixed nitrogen or ammonium. Under high ammonium levels, GlnD removes UMP from these proteins (deuridylylation). The PII proteins are signal transduction elements that integrate the signals of nitrogen, carbon and energy, and transduce this information to proteins involved in nitrogen metabolism. In Herbaspirillum seropedicae, an endophytic diazotroph isolated from grasses, several genes coding for proteins involved in nitrogen metabolism have been identified and cloned, including glnB, glnK and glnD. In this work, the GlnB, GlnK and GlnD proteins of H. seropedicae were overexpressed in their native forms, purified and used to reconstitute the uridylylation system in vitro. The results show that H. seropedicae GlnD uridylylates GlnB and GlnK trimers producing the forms PII (UMP)(1), PII (UMP)(2) and PII (UMP)(3), in a reaction that requires 2-oxoglutarate and ATP, and is inhibited by glutamine. The quantification of these PII forms indicates that GlnB was more efficiently uridylylated than GlnK in the system used.     

Cloning, heterologous expression, and sequencing of the Proteus vulgaris glnAntrBC operon and implications of nitrogen control on heterologous urease expression

Abstract The glnAntrBC operon of Proteus vulgaris was cloned and heterologously expressed in Escherichia coli . The nucleotide sequence was determined. An open reading frame of 1407 bp was identified as the glnA gene and the deduced amino acid sequence showed 82% identity with the E. coli glutamine synthetase protein. Heterologous expression of the glnA gene in E. coli restored glutamine synthetase (GS) activity in a GS-negative mutant and a 52 kDa protein was detected and addressed as the GS subunit of P. vulgaris . Adjacent to the glnA gene the regulatory genes ntrB and ntrC were identified. Their coding regions comprised 1053 and 1452 bp, respectively, and the deduced gene products NR_II (NtrB) and NR_I (NtrC) shared 72% identity with the corresponding E. coli proteins. Heterologous expression in E. coli revealed only a 54 kDa protein which was shown to be NR_I. NR_II was not detectable using the methods employed.     

Ammonium sensing in Escherichia coli. Role of the ammonium transporter AmtB and AmtB-GlnK complex formation

The Amt proteins are high affinity ammonium transporters that are conserved in all domains of life. In bacteria and archaea the Amt structural genes (amtB) are invariably linked to glnK, which encodes a member of the P(II) signal transduction protein family, proteins that regulate many facets of nitrogen metabolism. We have now shown that Escherichia coli AmtB is inactivated by formation of a membrane-bound complex with GlnK. Complex formation is reversible and occurs within seconds in response to micromolar changes in the extracellular ammonium concentration. Regulation is mediated by the uridylylation/deuridylylation of GlnK in direct response to fluctuations in the intracellular glutamine pool. Furthermore under physiological conditions AmtB activity is required for GlnK deuridylylation. Hence the transporter is an integral part of the signal transduction cascade, and AmtB can be formally considered to act as an ammonium sensor. This system provides an exquisitely sensitive mechanism to control ammonium flux into the cell, and the conservation of glnK linkage to amtB suggests that this regulatory mechanism may occur throughout prokaryotes.     

Effects of tabtoxin on nitrogen metabolism

Tabtoxin is a chlorosis-inducing toxin produced by the plant pathogenic bacterium Pseudomonas syringae pv. tabaci. Previous studies have indicated that tabtoxin inhibits glutamine synthetase (EC 6.3.1.2) in vitro. We report here that tabtoxin also inhibits glutamine synthetase in vivo. The main evidence was that assimilation of exogenous ¹⁵NH₃ into Asparagus sprengeri protein was rapidly inhibited in isolated cells exposed to tabtoxin. This was associated with an equivalent decline in glutamine synthetase activity in extracts of these cells and the accumulation of extracellular ammonia. Glutamine synthetase was also inhibited in leaves of Nicotiana tabacum L. cv. White Burley treated with tabtoxin and the affected tissue accumulated ammonia and became chlorotic. However, the development of symptoms and accumulation of ammonia was suppressed when the leaves were held in air containing 1% CO₂ to reduce photorespiration. This indicates that the chlorotic symptom did not result from the inhibition of nitrogen assimilation but was a consequence of the interruption of the photorespiratory nitrogen cycle.     

Enzymes involved in ammonia assimilation in the fungus Acremonium persicinum

Abstract Acremonium persicinum grown in batch culture with ammonium tartrate as the nitrogen source possessed an NADP⁺-dependent glutamate dehydrogenase and a glutamine synthetase. Glutamate synthase was not detected under the culture conditions used. Kinetic studies of the NADP⁺-dependent glutamate dehydrogenase at 25°C and pH 7.6 revealed an apparent K _m of 3.2 × 10⁻⁴ M for 2-oxoglutarate and an apparent K _m of 1.0 × 10⁻⁵ M for ammonium ions, with corresponding apparent V _max values of 0.089 and 0.13 μmol substrate converted/min/mg of protein, respectively. Glutamine synthetase was measured by the γ-glutamyl transferase reaction at 30°C and pH 7.55. This transferase reaction of glutamine synthetase had a higher rate at 30°C than at 25°C or 37°C.