Project description:Nitrogen limitation imposes a major transition in the life-style of non-diazotrophic cyanobacteria, which is regulated via a complex interplay of regulatory factors, involving, the nitrogen-specific transcription factor NtcA and the pervasive signal processor PII. Immediately upon nitrogen-limitation, newly fixed carbon is re-directed towards glycogen synthesis. How operation of the metabolic switch for distributing fixed carbon to either glycogen or cellular building blocks was poorly understood. Here we identify from Synechocystis sp. PCC 6803 a novel PII interactor, PirC, (Sll0944) that controls 3-phosphoglycerate mutase (PGAM), the enzyme that deviates newly fixed CO2 towards lower glycolysis. PirC acts as competitive inhibitor of PGAM and this interaction is tuned by PII/2-oxoglutarate. High oxoglutarate release PirC from PII-complex to inhibit PGAM. Accordingly, PirC deficient mutant, as compared to the wild-type, shows strongly reduced glycogen levels upon nitrogen deprivation whereas polyhydroxybutyrate granules are over-accumulated. Metabolome analysis revealed an imbalance in 3-phosphoglycerate to pyruvate levels in the PirC mutant, conforming that PirC controls the carbon flux in cyanobacteria via mutually exclusive interaction with either PII or PGAM.

Project description:PII signal transduction proteins are widely spread among all domains of life where they regulate a multitude of carbon and nitrogen metabolism related processes. Non-diazotrophic cyanobacteria can utilize a high variety of organic and inorganic nitrogen sources. In recent years, several physiological studies indicated an involvement of the cyanobacterial PII protein in regulation of ammonium, nitrate/nitrite and cyanate uptake. However, direct interaction of PII has not been demonstrated so far. In this study, we used biochemical, molecular genetic and physiological approaches to demonstrate that PII regulates all relevant nitrogen uptake systems in Synechocystis sp. strain PCC 6803: PII controls ammonium uptake by interacting with the Amt1 ammonium permease, probably similar to the known regulation of E. coli ammonium permease AmtB by the PII homologue GlnK. We could further clarify that PII mediates the ammonium- and dark-induced inhibition of nitrate uptake by interacting with the NrtC and NrtD subunits of the nitrate/nitrite transporter NrtABCD. We further identified the ABC-type urea transporter UrtABCDE as novel PII target. PII interacts with the UrtE subunit without involving the standard interaction surface of PII interactions. The deregulation of urea uptake in a PII deletion mutant causes ammonium excretion when urea is provided as nitrogen source. Furthermore, the urea hydrolyzing urease enzyme complex appears to be coupled to urea uptake. Overall, this study underlines the great importance of the PII signal transduction protein in the regulation of nitrogen utilization in cyanobacteria.

Project description:Acquisition and utilization of nitrogen is governed by the Nitrogen Stress Response regulatory cascade. GlnD is the primary nitrogen sensor in this system, and modifies the PII proteins to effect changes in the expression of target genes. We used microarrays to evaluate changes in gene expression due to nitrogen availability, mutation of the glnD gene, and deletion of both PII proteins.

Project description:PII proteins are signal transduction proteins that belong to a widely distributed family involved in modulating various bacterial metabolisms. These homotrimeric proteins carry a flexible loop, known as the T-loop, whose conformation changes upon recognition of key metabolites such as ADP, ATP, and 2-oxoglutarate. PII proteins interact with various partners to primarily regulate nitrogen pathways, and in some organisms, they can also control carbon metabolism by interacting with the biotin carboxyl carrier protein (BCCP), a critical component of the acetyl-CoA carboxylase (ACC) enzyme complex, inhibiting its activity and consequently reducing fatty acid biosynthesis. In mycobacteria, only one PII protein has been identified; however, its physiological role remains unknown. In this study, we constructed a M. smegmatis deletion mutant, ∆MsPII, which exhibited growth deficiency when nitrate and nitrite were the sole nitrogen sources, leading to nitrite accumulation in the culture supernatant.

Project description:Members of the genus Burkholderia are versatile bacteria capable of colonizing highly diverse environmental niches. In this study, we investigated the global response of the opportunistic pathogen Burkholderia cenocepacia H111 to nitrogen limitation at the transcript and protein expression level. In addition to a classical response to nitrogen starvation, including the activation of glutamine synthetase, PII proteins and the two component regulatory system ntrBC, B. cenocepacia H111 also up-regulated polyhydroxybutyrate (PHB) accumulation and exopolysaccharide (EPS) production in response to nitrogen shortage. A search for consensus sequences in promoter regions of nitrogen responsive genes identified a s54 consensus sequence. The mapping of the s54 regulon as well as the characterization of a s54 mutant suggests an important role of s54 not only in control of nitrogen metabolism, but also in virulence of this organism. Nitrogen limitation and s54 regulon in B. cenocepacia

Project description:Nitrogen is essential for microbial growth and its importance is demonstrated by complex regulatory systems used to control the transport, assimilation and metabolism of nitrogen. To gain further insight into the response of mycobacteria to nitrogen limitation, we developed a nitrogen-limited chemostat and compared the transcriptional response of nitrogen-limited cells to nitrogen-replete cells in a continuous culture model at a constant growth rate (0.12 h-1) (td = 5.7 hrs) and 50% oxygen saturation.

Project description:Members of the genus Burkholderia are versatile bacteria capable of colonizing highly diverse environmental niches. In this study, we investigated the global response of the opportunistic pathogen Burkholderia cenocepacia H111 to nitrogen limitation at the transcript and protein expression level. In addition to a classical response to nitrogen starvation, including the activation of glutamine synthetase, PII proteins and the two component regulatory system ntrBC, B. cenocepacia H111 also up-regulated polyhydroxybutyrate (PHB) accumulation and exopolysaccharide (EPS) production in response to nitrogen shortage. A search for consensus sequences in promoter regions of nitrogen responsive genes identified a s54 consensus sequence. The mapping of the s54 regulon as well as the characterization of a s54 mutant suggests an important role of s54 not only in control of nitrogen metabolism, but also in virulence of this organism.

Project description:In E.Coli, PII protein is known to be a sensor of medium nitrogen status and to regulate some nitrogen metabolism steps (e.g.glutamin synthase and ammonium transporter regulations). Arabidopsis PII protein is the only homolog gene found in the arabidopsis genome and its role is still unclear. The goal of this sudy is to obtain transcriptional information from PII mutants grown on different nitrogen sources. Wild type and PII mutant were grown hydroponically in a growth chamber under 1mM nitrate for 5 weeks then they were submitted to N-deficiency for 5 days followed by a resupply of 1 mM or 5mM NH4. The rosette leaves of three plants were harvested and pooled for each genotype and treatment.

Project description:Acquisition and utilization of nitrogen is governed by the Nitrogen Stress Response regulatory cascade. GlnD is the primary nitrogen sensor in this system, and modifies the PII proteins to effect changes in the expression of target genes. We used microarrays to evaluate changes in gene expression due to nitrogen availability, mutation of the glnD gene, and deletion of both PII proteins. Sinorhizobium meliloti cultures were grown at 30C to mid-log phase (0.5–0.6 OD600) for RNA extraction and hybridization on Affymetrix microarrays. Wild-type 1021, a strain containing a mutation in glnD, and a strain with both PII proteins deleted were grown in media containing either 0.05% ammonium chloride or 0.02% sodium glutamate as the nitrogen source.

Project description:BACKGROUND: Nitrogen is an essential element for bacterial growth and an important component of biological macromolecules. Consequently, responding to nitrogen limitation is critical for bacterial survival and involves the interplay of signalling pathways and transcriptional regulation of nitrogen assimilation and scavenging genes. In the soil dwelling saprophyte Mycobacterium smegmatis the OmpR-type response regulator GlnR is thought to mediate the transcriptomic response to nitrogen limitation. However, to date only ten genes have been shown to be in the GlnR regulon, a vastly reduced number compared to other organisms. RESULTS: We investigated the role of GlnR in the nitrogen limitation response and determined the entire GlnR regulon, by combining expression profiling of M. smegmatis wild type and glnR deletion mutant, with GlnR-specific chromatin immunoprecipitation and high throughput sequencing. We identify 53 GlnR binding sites during nitrogen limitation that control the expression of over 100 genes, demonstrating that GlnR is the regulator controlling the assimilation and utilisation of nitrogen. We also determine a consensus GlnR binding motif and identify key residues within the motif that are required for specific GlnR binding. CONCLUSIONS: We have demonstrated that GlnR is the global nitrogen response regulator in M. smegmatis, directly regulating the expression of more than 100 genes. GlnR controls key nitrogen stress survival processes including primary nitrogen metabolism pathways, the ability to utilise nitrate and urea as alternative nitrogen sources, and the potential to use cellular components to provide a source of ammonium. These studies further our understanding of how mycobacteria survive nutrient limiting conditions. [Data is also available from http://bugs.sgul.ac.uk/E-BUGS-143]