Reversible uridylylation of the Escherichia coli PII signal transduction protein regulates its ability to stimulate the dephosphorylation of the transcription factor nitrogen regulator I (NRI or NtrC).

We have reconstituted the signal transduction system responsible for the negative regulation of the transcription of the Escherichia coli glnA gene, encoding glutamine synthetase, by glutamine. This signal transduction system consists of four proteins: the transcription factor NRI (NtrC), which activates glnA transcription when it is phosphorylated, the kinase/phosphatase protein NRII (NtrB) that directly controls the extent of NRI phosphorylation, the PII signal transduction protein that controls the phosphatase activity of NRII, and the uridylyltransferase/uridylyl-removing (UTase/UR) enzyme that is regulated by glutamine and controls the activity of PII. In the reconstituted system, the removal of uridylyl groups from the PII protein, catalyzed by the UTase/UR protein in the presence of glutamine, resulted in the stimulation of NRI approximately P dephosphorylation. In contrast, the uridylylated form of the PII protein had no discernible effect on NRI phosphorylation. The uridylylation of the trimeric PII protein by the monomeric UTase/UR protein is a non-cooperative reaction in which the partially modified species accumulated and were readily observed. Partially modified PII trimers were partially active in stimulating the dephosphorylation of NRI approximately P. Thus, both the PII-UTase/UR and PII-NRII interactions display the continuous variability characteristic of rheostats as opposed to the binary variability characteristic of toggle switches.

Atkinson MR ，Kamberov ES ，Weiss RL ，Ninfa AJ ... -  《JOURNAL OF BIOLOGICAL CHEMISTRY》

Characterization of the reconstituted UTase/UR-PII-NRII-NRI bicyclic signal transduction system that controls the transcription of nitrogen-regulated (Ntr) genes in Escherichia coli.

A reconstituted UTase/UR-PII-NRII-NRI bicyclic cascade regulated PII uridylylation and NRI phosphorylation in response to glutamine. We examined the sensitivity and robustness of the responses of the individual cycles and of the bicyclic system. The sensitivity of the glutamine response of the upstream UTase/UR-PII monocycle depended upon the PII concentration, and we show that PII exerted substrate inhibition of the UTase activity of UTase/UR, potentially contributing to this dependence of sensitivity on PII. In the downstream NRII-NRI monocycle, PII controlled NRI phosphorylation state, and the response to PII was hyperbolic at both saturating and unsaturating NRI concentration. As expected from theory, the level of NRI∼P produced by the NRII-NRI monocycle was robust to changes in the NRII or NRI concentrations when NRI was in excess over NRII, as long as the NRII concentration was above a threshold value, an example of absolute concentration robustness (ACR). Because of the parameters of the system, at physiological protein levels and ratios of NRI to NRII, the level of NRI∼P depended upon both protein concentrations. In bicyclic UTase/UR-PII-NRII-NRI systems, the NRI phosphorylation state response to glutamine was always hyperbolic, regardless of the PII concentration or sensitivity of the upstream UTase/UR-PII cycle. In these bicyclic systems, NRI phosphorylation state was only robust to variation in the PII/NRII ratio within a narrow range; when PII was in excess NRI∼P was low, and when NRII was in excess NRI phosphorylation was elevated, throughout the physiological range of glutamine concentrations. Our results show that the bicyclic system produced a graded response of NRI phosphorylation to glutamine under a range of conditions, and that under most conditions the response of NRI phosphorylation state to glutamine levels depended on the concentrations of NRI, NRII, and PII.

Jiang P ，Ventura AC ，Ninfa AJ 《-》

Reconstitution of the signal-transduction bicyclic cascade responsible for the regulation of Ntr gene transcription in Escherichia coli.

Nitrogen-regulation of gene transcription in Escherichia coli results from the regulation of the phosphorylation state of the enhancer-binding transcription factor NRI (NtrC). We examined the regulation of NRI phosphorylation in a reconstituted bicyclic cascade system containing four regulatory proteins: NRI, the signal-transducing uridylyltransferase/uridylyl-removing enzyme (UTase/UR), its substrate the signal transduction protein PII, and the kinase/phosphatase NRII (NtrB), which is a PII receptor that phosphorylates and dephosphorylates NRI. In this reconstituted system, the phosphorylation state of NRI was regulated reciprocally by the small molecule effectors glutamine, which prevented the accumulation of NRI-P, and 2-ketoglutarate, which caused accumulation of NRI-P. Regulation of the bicyclic system by glutamine was exclusively due to sensation and signal-transduction by the UTase/UR-PII monocycle, which was observed to function essentially as a glutamine-sensing apparatus. In contrast, regulation of NRI phosphorylation by 2-ketoglutarate, which binds to PII, was due to direct regulation of the NRII-PII interaction and the rate of NRI-P dephosphorylation. Thus, the PII protein transduces the glutamine signal to the NRII-NRI monocycle in the form of its uridylylation state and is also the receptor of the antagonistic 2-ketoglutarate signal, which blocks the activity of unmodified PII.

Jiang P ，Peliska JA ，Ninfa AJ 《BIOCHEMISTRY》

Role of the GlnK signal transduction protein in the regulation of nitrogen assimilation in Escherichia coli.

Two structurally similar but functionally distinct PII-like proteins, PII and GlnK, regulate nitrogen assimilation in Escherichia coli. Studies with cells indicated that both PII (the glnB product) and GlnK (the glnK product) acted through the kinase/phosphatase NRII [NtrB, the glnL (ntrB) product] to reduce transcription initiation from Ntr promoters, apparently by regulating the phosphorylation state of the transcriptional activator NRI-P (NtrC-P, the phosphorylated form of the glnG (ntrC) product). Both GlnK and PII also acted through adenylyltransferase (ATase, the glnE product) to regulate the adenylylation state of glutamine synthetase (GS). The activity of both GlnK and PII was regulated by the signal-transducing uridylyltransferase/uridylyl-removing enzyme (UTase/UR, glnD product). Our experiments indicate that either PII or GlnK could effectively regulate ATase, but that PII was required for the efficient regulation of NRII required to prevent expression of glnA, which encodes GS. Yet, GlnK also participated in regulation of NRII. Although cells that lack either PII or GlnK grew well, cells lacking both of these proteins were defective for growth on nitrogen-rich minimal media. This defect was alleviated by the loss of NRII, and was apparently due to unregulated expression of the Ntr regulon. Also, mutations in glnK, designated glnK*, were obtained as suppressors of the Ntr- phenotype of a double mutant lacking PII and the UTase/UR. These suppressors appeared to reduce, but not eliminate, the ability of GlnK to prevent Ntr gene expression by acting through NRII. We hypothesize that one role of GlnK is to regulate the expression of the level of NRI-P during conditions of severe nitrogen starvation, and by so doing to contribute to the regulation of certain Ntr genes.

Atkinson MR ，Ninfa AJ 《MOLECULAR MICROBIOLOGY》

Characterization of the GlnK protein of Escherichia coli.

The GlnK and PII signal transduction proteins are paralogues that play distinct roles in nitrogen regulation. Although cells lacking GlnK appear to have normal nitrogen regulation, in the absence of PII, the GlnK protein controls nitrogen assimilation by regulating the activities of the PII receptors glutamine synthetase adenylyltransferase (ATase) and the kinase/phosphatase nitrogen regulator II (NRII or NtrB), which controls transcription from nitrogen-regulated promoters. Here, the wild-type GlnK protein and two mutant forms of GlnK were purified, and their activities were compared with those of PII using purified components. GlnK and PII were observed to have unique properties. Both PII and GlnK were potent activators of the phosphatase activity of NRII, although PII was slightly more active. In contrast, PII was approximately 40-fold more potent than GlnK in the activation of the adenylylation of glutamine synthetase by ATase. While both GlnK and PII were readily uridylylated by the uridylyltransferase activity of the signal-transducing uridylyltransferase/uridylyl-removing enzyme (UTase/UR), only PII approximately UMP was effectively deuridylylated by the UR activity of the UTase/UR. Finally, there were subtle differences in the regulation of GlnK activity by the small molecule effector 2-ketoglutarate compared with the regulation of PII activity by this effector. Altogether, these results suggest that GlnK is unlikely to play a significant role in the regulation of ATase in wild-type cells, and that the main role of GlnK may be to contribute to the regulation of NRII and perhaps additional, unknown receptors in nitrogen-starved cells. Also, the slow deuridylylation of GlnK approximately UMP by the UTase/UR suggests that rapid interconversion of GlnK between uridylylated and unmodified forms is not necessary for GlnK function. One mutant form of GlnK, containing the alteration R47W, was observed to lack specifically the ability to activate the NRII phosphatase in vitro; it was able to be uridylylated by the UTase/UR and to activate the adenylylation activity of ATase. Another mutant form of GlnK, containing the Y51N alteration at the site of uridylylation, was not uridylylated by the UTase/UR and was defective in the activation of both the NRII phosphatase activity and the ATase adenylylation activity.

Atkinson MR ，Ninfa AJ 《MOLECULAR MICROBIOLOGY》