PII T-loop mutations affecting signal transduction to NtrB also abolish yeast two-hybrid interactions

Mutations A49P and Delta47-53 at the T loop of the Escherichia coli GlnB (PII) protein impair regulatory interactions with the two-component sensor regulator NtrB (P. Jiang, P. Zucker, M. R. Atkinson, E. S. Kamberov, W. Tirasophon, P. Chandran, B. R. Schepke, and A. J. Ninfa, J. Bacteriol. 179: 4342-4353, 1997). We show here that these mutations also impair interactions between PII and NtrB in the yeast two-hybrid system, indicating that defects in NtrB regulation closely reflect binding impairment. The reported results underline the strength of two-hybrid assays for analysis of interactions involving the T loop of PII proteins.     

A source of ultrasensitivity in the glutamine response of the bicyclic cascade system controlling glutamine synthetase adenylylation state and activity in Escherichia coli

Glutamine synthetase (GS) activity in Escherichia coli is regulated by reversible adenylylation, brought about by a bicyclic system comprised of uridylyltransferase/uridylyl-removing enzyme (UTase/UR), its substrate, PII, adenylyltransferase (ATase), and its substrate, GS. The modified and unmodified forms of PII produced by the upstream UTase/UR-PII cycle regulate the downstream ATase-GS cycle. A reconstituted UTase/UR-PII-ATase-GS bicyclic system has been shown to produce a highly ultrasensitive response of GS adenylylation state to the glutamine concentration, but its composite UTase/UR-PII and ATase-GS cycles displayed moderate glutamine sensitivities when examined separately. Glutamine sensitivity of the bicyclic system was significantly reduced when the trimeric PII protein was replaced by a heterotrimeric form of PII that was functionally monomeric, and coupling between the two cycles was different in systems containing wild-type or heterotrimeric PII. Thus, the trimeric nature of PII played a role in the glutamine response of the bicyclic system. We therefore examined regulation of the individual AT (adenylylation) and AR (deadenylylation) activities of ATase by PII preparations with various levels of uridylylation. AR activity was affected in a linear fashion by PII uridylylation, but partially modified wild-type PII activated the AT much less than expected based on the extent of PII modification. Partially modified wild-type PII also bound to ATase less than expected based upon the fraction of modified subunits. Our results suggest that the AT activity is only bound and activated by completely unmodified PII and that this design is largely responsible for ultrasensitivity of the bicyclic system.     

Cascade control of Escherichia coli glutamine synthetase. Purification and properties of PII protein and nucleotide sequence of its structural gene

A procedure was developed to purify large quantities of PII protein from an Escherichia coli strain which contains a multicopy plasmid harboring the structural gene of PII (the glnB gene). Ultraviolet spectra of uridylylated and unuridylylated PII were obtained using the purified PII and empirical formulas to calculate the concentration of protein and the average number of uridylylated subunits per molecule were derived. A continuous fluorometric assay for the measurement of uridylylated PII (PIID) and adenylyltransferase (ATase) was also established. Rate measurements at various concentrations of PIID and at a fixed concentration of ATase showed that a tetrameric PIID molecule interacts with only one ATase molecule at a time. The complete nucleotide sequence of the glnB gene was determined and parts of the deduced amino acid sequence were confirmed by the results of amino acid sequence analysis of peptides. The PII subunit consists of 103 amino acids (Mr = 11,580). Two tyrosines reside at positions 46 and 51, where Tyr51 is the site of uridylylation. Nucleotide sequence analysis of the upstream region showed no obvious sites for the binding of RNA polymerase, indicating that the glnB gene is a part of an as yet unidentified operon.     

Escherichia coli PII signal transduction protein controlling nitrogen assimilation acts as a sensor of adenylate energy charge in vitro

PII signal transduction proteins are among the most widely distributed signaling proteins in nature, controlling nitrogen assimilation in organisms ranging from bacteria to higher plants. PII proteins integrate signals of cellular metabolic status and interact with and regulate receptors that are signal transduction enzymes or key metabolic enzymes. Prior work with Escherichia coli PII showed that all signal transduction functions of PII required ATP binding to PII and that ATP binding was synergistic with the binding of alpha-ketoglutarate to PII. Furthermore, alpha-ketoglutarate, a cellular signal of nitrogen and carbon status, was observed to strongly regulate PII functions. Here, we show that in reconstituted signal transduction systems, ADP had a dramatic effect on PII regulation of two E. coli PII receptors, ATase, and NRII (NtrB), and on PII uridylylation by the signal transducing UTase/UR. ADP acted antagonistically to alpha-ketoglutarate, that is, low adenylylate energy charge acted to diminish signaling of nitrogen limitation. By individually studying the interactions that occur in the reconstituted signal transduction systems, we observed that essentially all PII and PII-UMP interactions were influenced by ADP. Our experiments also suggest that under certain conditions, the three nucleotide binding sites of the PII trimer may be occupied by combinations of ATP and ADP. In the aggregate, our results show that PII proteins, in addition to serving as sensors of alpha-ketoglutarate, have the capacity to serve as direct sensors of the adenylylate energy charge.     

Cascade control of E. coli glutamine synthetase. II. Metabolite regulation of the enzymes in the cascade.

Enzymes and regulatory proteins involved in the cascade control of glutamine synthetase activity of Escherichia coli have been separated from one another and the effects of numerous metabolites on each step in the cascade have been determined. The adenylyl transferase (ATase) -catalyzed adenylylation of glutamine synthetase, which requires the presence of the unmodified form of the regulatory protein PII is enhanced by glutamine and is inhibited by either α-ketoglutarate (α-KG) or the uridylylated form (PII·UMP) of the regulatory protein. PII·UMP and α-KG act synergistically to inhibit this activity. In contrast, the PII·UMP-dependent, ATase-catalyzed deadenylylation of glutamine synthetase requires α-KG and ATP and is inhibited by glutamine or PII and synergistically by glutamine plus PII. The capacity of uridylyl transferase (UTase) to catalyze the uridylylation of PII is dependent on the presence of α-KG and ATP and is inhibited by glutamine. The deuridylylation of PII·UMP by the uridylyl removing enzyme (UR) is enhanced by glutamine but is unaffected by α-KG. However, CMP, UMP, and CoA all inhibit activity at 10^?6m. High concentrations of ATase inhibit both UR and UTase activities, presumably by binding the regulatory protein. Of more than 50 substances that alter the activity of at least one enzyme in the cascade, only α-KG and glutamine affect the activity at every step. This accounts for the observation that glutamine synthetase activity in vivo is very sensitive to the intracellular ratio of α-KG to glutamine.     

New methods for the colorimetric assay of PIID regulatory protein, uridylyltransferase, and uridylyl-removing enzyme in glutamine synthetase cascade

Adenylylation and deadenylylation of glutamine synthetase (GS) are catalyzed by the same adenylyltransferase (ATase). The ability of ATase to catalyze adenylylation is markedly stimulated by the unmodified form of a regulatory protein, P_IIA, whereas its capacity to catalyze deadenylylation is stimulated by the uridylylated form (P_IID) of the regulatory protein. Interconversion between P_IIA and P_IID is catalyzed by uridylyltransferase (UTase) and uridylylremoving enzyme (UR). New colorimetric methods were developed for the assays of P_IID, UTase, and UR activities. The P_IID activity is monitored by its unique ability to stimulate the ATase catalyzed formation of unadenylylated subunits from adenylylated GS. The inerease of unadenylylated subunits is determined by measuring the γ-glutamyltransferase activity of GS under conditions where the activity of an unadenylylated subunit is about 15 times greater than that of an adenylylated subunit (i.e., at pH 8.0 in the presence of Mn²⁺). Assays for UTase and UR enzyme are derived by coupling the P_IID assay to the UTase and UR reactions. For the UTase reaction, the formation of P_IID from P_IIA is measured, whereas the decrease in P_IID is followed for the UR assay. These assays have been applied to follow the activities of these proteins during their purification procedures, to the mechanistic studies on the deadenylylation reaction, and to determine the activities of these proteins in mutants produced during the genetic study of glutamine synthetase cascade. The problems evolved from these assays are discussed.     

Cascade control of E. coli glutamine synthetase. I. Studies on the uridylyl transferase and uridylyl removing enzyme(s) from E. coli.

The state of adenylylation of glutamine synthetase in Escherichia coli is regulated by the adenylyl transferase, the PII regulatory protein, uridylyl transferase (UTase), and the uridylyl removing enzyme (UR). The regulatory protein exists in an unmodified state (PII) which promotes adenylylation and in a uridylylated form (PII·UMP) which promotes deadenylylation of glutamine synthetase. The UR and UTase enzymes catalyze the interconversion of PII and PII·UMP. The UR and UTase have been partially purified by chromatography over DEAE-cellulose, AH-Sepharose 4B, Sephadex G-200, and gel electrophoresis. The two activities co-purify at all steps in the isolation although preparations containing different ratios of UTase:UR activities have been isolated. These UR·UTase activities have apparent molecular weight of 140,000. Both activities are inactivated by sulfhydryl reagents, both activities are heat inactivated, and both are stabilized by high salt concentrations. Both activities are inhibited in the crude extract by dialyzable inhibitors, but the UR is also inhibited by a nondialyzable inhibitor. This endogenous inhibitor is of molecular weight greater than 100,000 daltons, and binds CMP and UMP which are the apparent inhibitory agents. CMP and UMP are antagonistic in their effects on the UR activity. No effect of the CMP, UMP, or the large inhibitor on the other steps in the cascade could be demonstrated. The Mn²⁺-supported UR activity was also shown to be inhibited by a number of divalent cations, particularly Zn²⁺.     

Dissociation and reassociation of oligomeric viral glycoprotein subunits in the endoplasmic reticulum.

The vesicular stomatitis virus (VSV) glycoprotein (G) forms noncovalently linked trimers in the endoplasmic reticulum (ER) prior to transport to the cell surface. Here we examined the formation of heterotrimers between wild-type and mutant subunits that were retained in the ER by C-terminal retention signals. When G protein was coexpressed with mutant subunits that formed trimers at the wild-type rate and were transported from the ER at the wild-type rate, heterotrimers were readily detected. In contrast, when G protein was coexpressed with mutant subunits that formed trimers at the wild-type rate, but were retained in the ER, heterotrimers were not detected unless transport of the wild-type molecules from the ER was blocked. After removal of transport block, the heterotrimers then dissociated and reassorted to homotrimers of the mutant protein that were retained in the ER and wild-type trimers that were transported to the cell surface. These and other results presented here indicate that there is an equilibrium between G protein trimers and monomers in vivo, at least in the ER. This equilibrium may function to allow escape of wild-type subunits from aberrant retained subunits.     

Lack of evidence for phosphorylation of Arabidopsis thaliana PII: implications for plastid carbon and nitrogen signaling

The PII signal transduction protein is regulated by covalent modification in most prokaryotic organisms. In enteric bacteria PII is uridylylated on a specific tyrosine residue in the T-loop region, while in certain cyanobacteria it is phosphorylated at the serine residue two positions away from the equivalent modified tyrosine of enteric bacteria. Covalent modification functions primarily to signal cellular nitrogen status in prokaryotes. Here we have examined the phospho-status of Arabidopsis thaliana PII under various growth conditions employing a variety of techniques, including in vivo labeling, phosphospecific antibodies, protein phosphatase treatment, mass spectrometry and protein kinase assays. All results indicate that plant PII is not regulated by phosphorylation. Edman sequencing of immunoprecipitated A. thaliana PII revealed the N-terminal sequences AQISSD and QISSDY, indicating that the mature protein is cleaved from its transit peptide in vivo at the site(s) predicted by ChloroP. Western blot analysis also demonstrated that plant PII protein expression varies little with nutrient regime.     

Genetic and biochemical analysis of phosphatase activity of Escherichia coli NRII (NtrB) and its regulation by the PII signal transduction protein

Mutant forms of Escherichia coli NRII (NtrB) were isolated that retained wild-type NRII kinase activity but were defective in the PII-activated phosphatase activity of NRII. Mutant strains were selected as mimicking the phenotype of a strain (strain BK) that lacks both of the related PII and GlnK signal transduction proteins and thus has no mechanism for activation of the NRII phosphatase activity. The selection and screening procedure resulted in the isolation of numerous mutants that phenotypically resembled strain BK to various extents. Mutations mapped to the glnL (ntrB) gene encoding NRII and were obtained in all three domains of NRII. Two distinct regions of the C-terminal, ATP-binding domain were identified by clusters of mutations. One cluster, including the Y302N mutation, altered a lid that sits over the ATP-binding site of NRII. The other cluster, including the S227R mutation, defined a small surface on the "back" or opposite side of this domain. The S227R and Y302N proteins were purified, along with the A129T (NRII2302) protein, which has reduced phosphatase activity due to a mutation in the central domain of NRII, and the L16R protein, which has a mutation in the N-terminal domain of NRII. The S227R, Y302N, and L16R proteins were specifically defective in the PII-activated phosphatase activity of NRII. Wild-type NRII, Y302N, A129T, and L16R proteins bound to PII, while the S227R protein was defective in binding PII. This suggests that the PII-binding site maps to the "back" of the C-terminal domain and that mutation of the ATP-lid, central domain, and N-terminal domain altered functions necessary for the phosphatase activity after PII binding.     

Structure-function analysis of glutamine synthetase adenylyltransferase (ATase, EC 2.7.7.49) of Escherichia coli

Glutamine synthetase adenylyltransferase (ATase) regulates the activity of glutamine synthetase by adenylylation and deadenylylation in response to signals of nitrogen and carbon status: glutamine, alpha-ketoglutarate, and the uridylylated and unmodified forms of the PII signal transduction protein. ATase consists of two conserved nucleotidyltransferase (NT) domains linked by a central region of approximately 200 amino acids. Here, we study the activities and regulation of mutated and truncated forms of ATase. Our results indicate the following. (i) The N-terminal NT domain contained the adenylyl-removing (AR) active site, and the C-terminal NT domain contained the adenylyltransferase (AT) active site. (ii) The enzyme contained a glutamine binding site, and glutamine increased the affinity for PII. (iii) The enzyme appeared to contain multiple sites for the binding of PII and PII-UMP. (iv) Truncated versions of ATase missing the C-terminal (NT) domain lacked both AT and AR activity, suggesting a role for the C-terminal NT domain in both activities. (v) The purified C-terminal NT domain and larger polypeptides containing this domain had significant basal AT activity, which was stimulated by glutamine. These polypeptides were indifferent to PII and PII-UMP, or their ATase activity was inhibited by either PII or PII-UMP. (vi) Certain point mutations in the central region or an internal deletion removing most of this part of the protein eliminated the AR activity and eliminated activation of the AT activity by PII, while not eliminating the binding of PII or PII-UMP. That is, these mutations in the central region appeared to destroy the communication between the PII and PII-UMP binding sites and the AT and AR active sites. (vii) Certain mutations in the central region of ATase appeared to dramatically improve the binding of glutamine to the enzyme. (viii) While the isolated AT and AR domains of ATase bound poorly to PII and PII-UMP, these domains bound PII and PII-UMP significantly better when linked to the central region of ATase. Together, our results indicate a highly coordinated enzyme, in which the AT and AR domains participate in each other's regulation and distant regulatory sites are in communication with each other. A model for the regulation of ATase by glutamine, PII, and PII-UMP consistent with all data is presented.     

Coexistence of two structurally similar but functionally different PII proteins in Azospirillum brasilense.

The coexistence of two different PII, proteins in Azospirillum brasilense was established by comparing proteins synthesized by the wild-type strain and two null mutants of the characterized glnB gene (encoding PII) adjacent to glnA. Strains were grown under conditions of nitrogen limitation or nitrogen excess. The proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) or isoelectric focusing gel electrophoresis and revealed either by [32P]phosphate or [3H]uracil labeling or by cross-reaction with an anti-A. brasilense PII-antiserum. After SDS-PAGE, a single band of 12.5 kDa revealed by the antiserum in all conditions tested was resolved by isoelectric focusing electrophoresis into two bands in the wild-type strain, one of which was absent in the glnB null mutant strains. The second PII protein, named Pz, was uridylylated under conditions of nitrogen limitation. The amino acid sequence deduced from the nucleotide sequence of the corresponding structural gene, called glnZ, is very similar to that of PII. Null mutants in glnB were impaired in regulation of nitrogen fixation and in their swarming properties but not in glutamine synthetase adenylylation. No glnZ mutant is yet available, but it is clear that PII and Pz are not functionally equivalent, since glnB null mutant strains exhibit phenotypic characters. The two proteins are probably involved in different regulatory steps of the nitrogen metabolism in A. brasilense.     

Escherichia coli glutamine synthetase adenylyltransferase (ATase, EC 2.7.7.49): kinetic characterization of regulation by PII, PII-UMP, glutamine, and alpha-ketoglutarate

Glutamine synthetase adenylyltranferase (ATase, EC 2.7.7.49) catalyzes the adenylylation and deadenylylation of glutamine synthetase (GS), regulating GS activity. The adenylyltransferase (AT) reaction is activated by glutamine and by the unmodified form of the PII signal transduction protein and is inhibited by the uridylylated form of PII, PII-UMP. Conversely, the adenylyl-removing (AR) reaction is activated by PII-UMP and is inhibited by glutamine and by PII. Both AT and AR reactions are regulated by alpha-ketoglutarate, which binds to PII and PII-UMP. Here, we present a kinetic analysis of the AT and AR activities and their regulation. Both AT and AR reactions used a sequential mechanism of rapid equilibrium random binding of substrates and products. Activators and inhibitors had little effect on the binding of substrates, instead exerting their effects on catalysis. Our results were consistent with PII, PII-UMP, and glutamine shifting the enzyme among at least six different enzyme forms, two of which were inactive, one of which exhibited AR activity, and three of which exhibited AT activity. In addition to a site for glutamine, the enzyme appeared to contain two distinct sites for PII and PII-UMP. The PII, PII-UMP, and glutamine sites were in communication so that the apparent activation and inhibition constants for regulators depended upon each other. The binding of PII was favored by glutamine and its level reduced by PII-UMP, whereas glutamine and PII-UMP competed for the enzyme. alpha-Ketoglutarate, which acts exclusively through its binding to PII and PII-UMP, did not alter the binding of PII or PII-UMP to the enzyme. Rather, alpha-ketoglutarate dramatically affected the extent of activation or inhibition of the enzyme by PII or PII-UMP. A working hypothesis for the regulation of the AT and AR activities, consistent with all data, is presented.     

Crystal structure of Arabidopsis PII reveals novel structural elements unique to plants

The 1.9 A resolution crystal structure of PII from Arabidopsis thaliana reveals for the first time the molecular structure of a widely conserved regulator of carbon and nitrogen metabolism from a eukaryote. The structure provides a framework for understanding the arrangement of highly conserved residues shared with PII proteins from bacteria, archaea, and red algae as well as residues conserved only in plant PII. Most strikingly, a highly conserved segment at the N-terminus that is found only in plant PII forms numerous interactions with the alpha2 helix and projects from the surface of the homotrimer opposite to that occupied by the T-loop. In addition, solvent-exposed residues near the T-loop are highly conserved in plants but differ in prokaryotes. Several residues at the C-terminus that are also highly conserved only in plants contribute part of the ATP-binding site and likely participate in an ATP-induced conformational change. Structures of PII also reveal how citrate and malonate bind near the triphosphate binding site occupied by ATP in bacterial and archaeal PII proteins.