Structural Underpinnings of Nitrogen Regulation by the Prototypical Nitrogen-Responsive Transcriptional Factor NrpR

Plants and microorganisms reduce environmental inorganic nitrogen to ammonium, which then enters various metabolic pathways solely via conversion of 2-oxoglutarate (2OG) to glutamate and glutamine. Cellular 2OG concentrations increase during nitrogen starvation. We recently identified a family of 2O...

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Bibliographic Details
Published in:Structure (London) 2010-11, Vol.18 (11), p.1512-1521
Main Authors: Wisedchaisri, Goragot, Dranow, David M., Lie, Thomas J., Bonanno, Jeffrey B., Patskovsky, Yury, Ozyurt, Sinem A., Sauder, J. Michael, Almo, Steven C., Wasserman, Stephen R., Burley, Stephen K., Leigh, John A., Gonen, Tamir
Format: Article
Language:English
Subjects:
Control
Conversion
Deoxyribonucleic acid
Gene Expression Regulation, Archaeal - genetics
Genes
Ketoglutaric Acids - metabolism
Methanococcus - chemistry
Microscopy, Electron
Models, Molecular
Molecular Dynamics Simulation
Nitrogen - metabolism
Optimization
PII Nitrogen Regulatory Proteins - chemistry
PII Nitrogen Regulatory Proteins - metabolism
Protein Conformation
Proteins
Quaternary Ammonium Compounds - metabolism
Residues
Transcription Factors - chemistry
Transcription Factors - metabolism
X-rays
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Summary:Plants and microorganisms reduce environmental inorganic nitrogen to ammonium, which then enters various metabolic pathways solely via conversion of 2-oxoglutarate (2OG) to glutamate and glutamine. Cellular 2OG concentrations increase during nitrogen starvation. We recently identified a family of 2OG-sensing proteins—the nitrogen regulatory protein NrpR—that bind DNA and repress transcription of nitrogen assimilation genes. We used X-ray crystallography to determine the structure of NrpR regulatory domain. We identified the NrpR 2OG-binding cleft and show that residues predicted to interact directly with 2OG are conserved among diverse classes of 2OG-binding proteins. We show that high levels of 2OG inhibit NrpRs ability to bind DNA. Electron microscopy analyses document that NrpR adopts different quaternary structures in its inhibited 2OG-bound state compared with its active apo state. Our results indicate that upon 2OG release, NrpR repositions its DNA-binding domains correctly for optimal interaction with DNA thereby enabling gene repression. ► Structure of the nitrogen regulatory protein in the active and inhibited states ► The identification of conservation of 2OG binding in diverse proteins ► The well-known ferredoxin fold is expanded to reveal a novel fold ► Transcriptional regulation of nitrogen assimilating genes is dynamically controlled
ISSN:0969-2126
1878-4186
DOI:10.1016/j.str.2010.08.014