PII, an ancient and widespread signaling protein, transduces nitrogen/carbon/energy abundance signals through interactions with target proteins. We clarify structurally how PII regulates gene expression mediated by the transcription factor NtcA, the global nitrogen regulator of cyanobacteria, shedding light on NtcA structure and function and on how NtcA is activated by 2-oxoglutarate (2OG) and coactivated by the nonenzymatic PII target, protein PipX. We determine for the cyanobacteria Synechococcus elongatus the crystal structures of the PII-PipX and PipX-NtcA complexes and of NtcA in active and inactive conformations (respective resolutions, 3.2, 2.25, 2.3, and 3.05 A). The structures and the conclusions derived from them are consistent with the results of present and prior site-directed mutagenesis and functional studies. A tudor-like domain (TLD) makes up most of the PipX structure and mediates virtually all the contacts of PipX with PII and NtcA. In the PII-PipX complex, one PII trimer sequesters the TLDs of three PipX molecules between its body and its extended T loops, preventing PipX activation of NtcA. Changes in T loop conformation triggered by 2OG explain PII-PipX dissociation when 2OG is bound. The structure of active dimeric NtcA closely resembles that of the active cAMP receptor protein (CRP). This strongly suggests that with these proteins DNA binding, transcription activation, and allosteric regulation occur by common mechanisms, although the effectors are different. The PipX-NtcA complex consists of one active NtcA dimer and two PipX monomers. PipX coactivates NtcA by stabilizing its active conformation and by possibly helping recruit RNA polymerase but not by providing extra DNA contacts.
Interaction network in cyanobacterial nitrogen regulation: PipX, a protein that interacts in a 2‐oxoglutarate dependent manner with PII and NtcA
SummaryCyanobacteria perceive nitrogen status by sensing intracellular 2-oxoglutarate levels. The global nitrogen transcription factor NtcA and the signal transduction protein PII are both involved in 2-oxoglutarate sensing. PII proteins, probably the most conserved signal transduction proteins in nature, are remarkable for their ability to interact with very diverse protein targets in different systems. Despite widespread efforts to understand nitrogen signalling in cyanobacteria, the involvement of PII in the regulation of transcription activation by NtcA remains enigmatic. Here we show that PipX, a protein only present in cyanobacteria, interacts with both PII and NtcA and provides a mechanistic link between these two factors. A variety of in vivo and in vitro approaches were used to study PipX and its interactions with PII and NtcA. 2-Oxoglutarate favours complex formation between PipX and NtcA, but impairs binding to PII, suggesting that partner swapping between these nitrogen regulators is driven by the 2-oxoglutarate concentration. PipX is required for NtcA-dependent transcriptional activation in vivo, thus implying that PipX may function as a prokaryotic transcriptional coactivator.
The crystal structure of the complex of P II and acetylglutamate kinase reveals how P II controls the storage of nitrogen as arginine
Photosynthetic organisms can store nitrogen by synthesizing arginine, and, therefore, feedback inhibition of arginine synthesis must be relieved in these organisms when nitrogen is abundant. This relief is accomplished by the binding of the P II signal transduction protein to acetylglutamate kinase (NAGK), the controlling enzyme of arginine synthesis. Here, we describe the crystal structure of the complex between NAGK and P II of Synechococcus elongatus, at 2.75-Å resolution. We prove the physiological relevance of the observed interactions by site-directed mutagenesis and functional studies. The complex consists of two polar P II trimers sandwiching one ring-like hexameric NAGK (a trimer of dimers) with the threefold axes of these molecules aligned. The binding of P II favors a narrow ring conformation of the NAGK hexamer that is associated with arginine sites having low affinity for this inhibitor. Each PII subunit contacts one NAGK subunit only. The contacts map in the inner circumference of the NAGK ring and involve two surfaces of the P II subunit. One surface is on the PII body and interacts with the C-domain of the NAGK subunit, helping widen the arginine site found on the other side of this domain. The other surface is at the distal region of a protruding large loop (T-loop) that presents a novel compact shape. This loop is inserted in the interdomain crevice of the NAGK subunit, contacting mainly the N-domain, and playing key roles in anchoring P II on NAGK, in activating NAGK, and in complex formation regulation by MgATP, ADP, 2-oxoglutarate, and by phosphorylation of serine-49.arginine synthesis ͉ regulation ͉ x-ray structure ͉ signaling ͉ cyanobacteria I n photosynthetic organisms nitrogen can be stored by synthesizing arginine (1, 2) and, therefore, feedback inhibition of arginine synthesis must be relieved when nitrogen is abundant. The enzyme of arginine biosynthesis that is the target of arginine inhibition, N-acetyl-L-glutamate (NAG) kinase (NAGK) (1, 3-5), was found in cyanobacteria and plants (2, 4-8) to be a target of the carbon/ nitrogen P II signaling protein (9, 10), forming with it a complex in which arginine inhibition is alleviated (6, 7). P II signaling proteins are homotrimers of a 12-to 13-kDa subunit that interact with enzymes, transcription factors, and ammonia channels, regulating their activity (9, 10) and carbon/ nitrogen homeostasis. Numerous structures of P II proteins, including those for cyanobacteria and plants (9-12), are known, but it was unclear how P II proteins carry out their functions. The body of the P II trimer is roughly hemispheric. Its subunits have ␣␣ topology, with ␣ helices looking outward and the  sheet inward and providing the intersubunit interactions. Each subunit has three loops: the B-and C-loops and the larger flexible T-loop. The T-loop residues Y51 and S49 are, respectively, the sites of the regulatory uridylylation and phosphorylation in enterobacterial and cyanobacterial P II proteins (9, 10), with S49 phosphorylation abolishing interaction wi...
PII, one of the most conserved signal transduction proteins, is believed to be a key player in the coordination of nitrogen assimilation and carbon metabolism in bacteria, archaea, and plants. However, the identity of PII receptors remains elusive, particularly in photosynthetic organisms. Here we used yeast two-hybrid approaches to identify new PII receptors and to explore the extent of conservation of PII signaling mechanisms between eubacteria and photosynthetic eukaryotes. Screening of Synechococcus sp. strain PCC 7942 libraries with PII as bait resulted in identification of N-acetyl glutamate kinase (NAGK), a key enzyme in the biosynthesis of arginine. The integrity of Ser49, a residue conserved in PII proteins from organisms that perform oxygenic photosynthesis, appears to be essential for NAGK binding. The effect of glnB mutations on NAGK activity is consistent with positive regulation of NAGK by PII. Phylogenetic and yeast two-hybrid analyses strongly suggest that there was conservation of the NAGK-PII regulatory interaction in the evolution of cyanobacteria and chloroplasts, providing insight into the function of eukaryotic PII-like proteins.PII, one of the most conserved and widespread nitrogen signal transduction proteins, is an important player in the coordination of nitrogen assimilation and carbon metabolism (1,8,27). In the enteric system, two paralogous genes, glnB and glnK, encode PII proteins. Their receptors include converter enzymes (uridylyltranferase/uridylyl-removing enzyme or GlnD) and downstream targets (NtrB, the histidine kinase of the NtrB-NtrC two-component system, adenylyltransferase or GlnE, and the membrane-bound ammonium transporter AmtB). In cyanobacteria, a unique PII protein (referred to as GlnB), encoded by the glnB gene, is regulated by separate kinase and phosphatase activities (11); one of these activities, PphA, a PP2C-type phosphatase, has recently been identified in Synechocystis sp. strain PCC 6803 (18) as the PII phosphatase. In Synechococcus sp. strain PCC 7942, involvement of PII in the short-term ammonium inhibition of nitrate uptake has been well established (21), but direct protein-protein interactions between transport components and PII have not been reported.Eukaryotic PII-encoding genes were first found in the chloroplast of the red alga Porphyra purpurea (31), and they seem to be present in a wide variety of higher plants, encoding proteins with high levels of homology to cyanobacterial PII proteins. Although PII from Arabidopsis thaliana, encoded by GLB1, has been identified and biochemically characterized, the physiological role of PII proteins in plants remains elusive (17, 26, 37). As it is in cyanobacteria, transcription of GLB1 is regulated by light and carbon-nitrogen status (12,17,22), in agreement with a role in coordination of photosynthesis and nitrogen assimilation. Given the common evolutionary origin of PII proteins in organisms that perform oxygenic photosynthesis, it seems likely that mechanisms and components of the corresponding signal tra...
Coumarins are inhibitors of the ATP hydrolysis and DNA supercoiling reactions catalysed by DNA gyrase. Their target is the B subunit of gyrase (GyrB), encoded by the gyrB gene. The exact mode and site of action of the drugs is unknown. We have identified four mutations conferring coumarin resistance to Escherichia coli: Arg-136 to Cys, His or Ser and Gly-164 to Val. In vitro, the ATPase and supercoiling activities of the mutant GyrB proteins are reduced relative to the wild-type enzyme and show resistance to the coumarin antibiotics. Significant differences in the susceptibility of mutant GyrB proteins to inhibition by either chlorobiocin and novobiocin or coumermycin have been found, suggesting wider contacts between coumermycin and GyrB. We discuss the significance of Arg-136 and Gly-164 in relation to the notion that coumarin drugs act as competitive inhibitors of the ATPase reaction.
Synechococcus elongatus PCC 7942 is a paradigmatic model organism for nitrogen regulation in cyanobacteria. Expression of genes involved in nitrogen assimilation is positively regulated by the 2-oxoglutarate receptor and global transcriptional regulator NtcA. Maximal activation requires the subsequent binding of the co-activator PipX. PII, a protein found in all three domains of life as an integrator of signals of the nitrogen and carbon balance, binds to PipX to counteract NtcA activity at low 2-oxoglutarate levels. PII-PipX complexes can also bind to the transcriptional regulator PlmA, whose regulon remains unknown. Here we expand the nitrogen regulatory network to PipY, encoded by the bicistronic operon pipXY in S. elongatus. Work with PipY, the cyanobacterial member of the widespread family of COG0325 proteins, confirms the conserved roles in vitamin B6 and amino/keto acid homeostasis and reveals new PLP-related phenotypes, including sensitivity to antibiotics targeting essential PLP-holoenzymes or synthetic lethality with cysK. In addition, the related phenotypes of pipY and pipX mutants are consistent with genetic interactions in the contexts of survival to PLP-targeting antibiotics and transcriptional regulation. We also showed that PipY overexpression increased the length of S. elongatus cells. Taken together, our results support a universal regulatory role for COG0325 proteins, paving the way to a better understanding of these proteins and of their connections with other biological processes.
A model for the domain structure of sigma 54-dependent transcriptional activators, based on sequence data, has been tested by examining the function of truncated and chimaeric proteins. Removal of the N-terminal domain of NtrC abolishes transcriptional activation, indicating that this domain is positively required for activator function. Over-expression of this domain as a separate peptide appears to titrate out the phosphorylating activity of NtrB. Removal of the N-terminal domain of NifA reduces activation 3-4-fold. The residual activity is particularly sensitive to inhibition by NifL, suggesting that the role of the N-terminal domain is to block the action of NifL in derepressing conditions. The C-terminal domain of NtrC showed repressor activity when expressed as a separate peptide. This domain is necessary for activator function even when NtrC binding sites are deleted from promoters. A point mutation in the ATP-binding motif of the NtrC central domain, Ser169 to Ala, also abolished activator function. Exchanging the N-terminal domains of Klebsiella pneumoniae NtrC, NifA and Escherichia coli OmpR, did not produce any hybrid activity, suggesting that N-terminal domains in the native proteins specifically recognize the rest of the molecule.
To modulate the expression of genes involved in nitrogen assimilation, the cyanobacterial P II -interacting protein X (PipX) interacts with the global transcriptional regulator NtcA and the signal transduction protein P II , a protein found in all three domains of life as an integrator of signals of the nitrogen and carbon balance. PipX can form alternate complexes with NtcA and P II , and these interactions are stimulated and inhibited, respectively, by 2-oxoglutarate, providing a mechanistic link between P II signaling and NtcA-regulated gene expression. Here, we demonstrate that PipX is involved in a much wider interaction network. The effect of pipX alleles on transcript levels was studied by RNA sequencing of S. elongatus strains grown in the presence of either nitrate or ammonium, followed by multivariate analyses of relevant mutant/control comparisons. As a result of this process, 222 genes were classified into six coherent groups of differentially regulated genes, two of which, containing either NtcA-activated or NtcA-repressed genes, provided further insights into the function of NtcA-PipX complexes. The remaining four groups suggest the involvement of PipX in at least three NtcA-independent regulatory pathways. Our results pave the way to uncover new regulatory interactions and mechanisms in the control of gene expression in cyanobacteria.nitrogen regulation | transcription | translation | photosynthesis
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