PII signal transduction proteins: sensors of alpha-ketoglutarate that regulate nitrogen metabolism.
about
Specificity and regulation of interaction between the PII and AmtB1 proteins in Rhodospirillum rubrumStructure of GlnK1 with bound effectors indicates regulatory mechanism for ammonia uptakeThe crystal structure of the Escherichia coli AmtB-GlnK complex reveals how GlnK regulates the ammonia channelThe 2.2 Å resolution crystal structure ofBacillus cereusNif3-family protein YqfO reveals a conserved dimetal-binding motif and a regulatory domainStructural basis for the regulation of N-acetylglutamate kinase by PII in Arabidopsis thalianaStructural basis for the allosteric control of the global transcription factor NtcA by the nitrogen starvation signal 2-oxoglutarateStructural basis for the regulation of NtcA-dependent transcription by proteins PipX and PIIMechanism of 2-oxoglutarate signaling by the Synechococcus elongatus PII signal transduction proteinStructure of GlnK1, a signalling protein fromArchaeoglobus fulgidusMechanism of Disruption of the Amt-GlnK Complex by PII-Mediated Sensing of 2-OxoglutarateStructural Basis and Target-specific Modulation of ADP Sensing by the Synechococcus elongatus PII Signaling ProteinAn engineered PII protein variant that senses a novel ligand: atomic resolution structure of the complex with citrateUnderstanding nitrate assimilation and its regulation in microalgaeThe 5' untranslated region of the soybean cytosolic glutamine synthetase β(1) gene contains prokaryotic translation initiation signals and acts as a translational enhancer in plantsFunctional characterization of the incomplete phosphotransferase system (PTS) of the intracellular pathogen Brucella melitensisAdenylylation of mycobacterial Glnk (PII) protein is induced by nitrogen limitationThe two-component sensor KinB acts as a phosphatase to regulate Pseudomonas aeruginosa VirulenceSensory properties of the PII signalling protein family.Nitrogen assimilation in Escherichia coli: putting molecular data into a systems perspectiveTernary complex formation between AmtB, GlnZ and the nitrogenase regulatory enzyme DraG reveals a novel facet of nitrogen regulation in bacteria.Comparative genomic analysis of carbon and nitrogen assimilation mechanisms in three indigenous bioleaching bacteria: predictions and validations.Community genomic and proteomic analyses of chemoautotrophic iron-oxidizing "Leptospirillum rubarum" (Group II) and "Leptospirillum ferrodiazotrophum" (Group III) bacteria in acid mine drainage biofilms.Chloroplast acetyl-CoA carboxylase activity is 2-oxoglutarate-regulated by interaction of PII with the biotin carboxyl carrier subunitFlux balance analysis of ammonia assimilation network in E. coli predicts preferred regulation point.Engineering glucose metabolism of Escherichia coli under nitrogen starvation.A transcriptome study of the QseEF two-component system and the QseG membrane protein in enterohaemorrhagic Escherichia coli O157 : H7.Functional genomic analysis of three nitrogenase isozymes in the photosynthetic bacterium Rhodopseudomonas palustris.Molecular basis for the distinct divalent cation requirement in the uridylylation of the signal transduction proteins GlnJ and GlnB from Rhodospirillum rubrum.In vitro analysis of the Escherichia coli AmtB-GlnK complex reveals a stoichiometric interaction and sensitivity to ATP and 2-oxoglutarate.Analysis of the enzymatic properties of a broad family of alanine aminotransferasesRegulation of nitrogenase by 2-oxoglutarate-reversible, direct binding of a PII-like nitrogen sensor protein to dinitrogenase.From PII signaling to metabolite sensing: a novel 2-oxoglutarate sensor that details PII-NAGK complex formation.Energy Sensing versus 2-Oxoglutarate Dependent ATPase Switch in the Control of Synechococcus PII Interaction with Its Targets NAGK and PipX.Interplay between CRP-cAMP and PII-Ntr systems forms novel regulatory network between carbon metabolism and nitrogen assimilation in Escherichia coli.Defining the nitrogen regulated transcriptome of Mycobacterium smegmatis using continuous culturePhosphonate analogs of 2-oxoglutarate perturb metabolism and gene expression in illuminated Arabidopsis leaves.Genetic screen for regulatory mutations in Methanococcus maripaludis and its use in identification of induction-deficient mutants of the euryarchaeal repressor NrpRThe auxiliary protein complex SaePQ activates the phosphatase activity of sensor kinase SaeS in the SaeRS two-component system of Staphylococcus aureus.Identification and functional characterization of NifA variants that are independent of GlnB activation in the photosynthetic bacterium Rhodospirillum rubrumReciprocal regulation of the autophosphorylation of enzyme INtr by glutamine and α-ketoglutarate in Escherichia coli
P2860
Q24671952-9AFC88D2-8A39-4A74-B04F-9D812E598F21Q27641055-720A0865-241D-462F-8899-074588DB6C5AQ27641125-01C15082-FABF-425C-9914-3AC07D0A72E7Q27646317-0F3B60D6-73B9-48C3-824B-ECFE850C7553Q27648704-78B06FD9-37CF-420F-BA25-20888E0F10EFQ27663291-F7D7EDC7-0F13-4B5D-8B8E-68BE494CE7A7Q27664074-BC819D60-C773-4553-9F7B-B5E767A5339BQ27665523-79B532F8-2B38-4DFA-9841-A9FE7AAFA81BQ27666887-F9389B69-42B6-4CC3-9A53-E5AF4569AE24Q27675303-11046DDA-9A67-46DE-B0EC-877EAE06D107Q27681686-E6BCD5D1-DA63-4C0A-9791-7E768683FC86Q27681894-3095CE85-33C0-41EA-91E8-89AC9DD8BB1EQ28083852-311BCCB3-931F-44FB-846E-5CDA22E88D2FQ28277491-D23BA40B-336C-44F6-9197-91D2D575F668Q28475478-E45FE54D-4193-4C17-8CA2-451A094966D5Q28487086-AB7234EA-6694-414D-9CA7-7A5ABC3677AEQ28493057-C7F6FAC1-EAD9-4F7A-A8B4-3CB20BB69631Q30380973-F04861BF-7156-46C5-A8C6-8D868786B36CQ30705590-104807C3-D699-4649-9BAB-3BEBF2DC7631Q33306597-76DCED38-6BDB-4C7A-A58C-F1D405310D03Q33389552-0DFD6110-89EE-4E6B-B2D3-E4B0A53DE32DQ33442693-6D508412-3283-43EF-8165-4C0C104B5887Q33591438-FB3B0489-804F-44A3-81D5-90CAF3442F1EQ33808569-0CEC7266-1916-45C9-B663-D4E9350D0BBAQ33917871-E03416F4-3E16-4504-9440-263147429E74Q33928947-15B39A9E-6659-42EF-A0E8-57E7B02530A3Q34124347-0C73940D-9F4D-43DD-9256-4D8AF9B26037Q34329505-86144BD5-0B12-4635-8400-E8AB23671A8DQ34550641-434ECC60-F74E-4CA1-B533-2181D7C808ABQ34585935-14EF7F10-726B-4516-AD13-C57B32C01E3CQ34772773-9DC7AE0E-224B-47E7-BECE-AE857E349683Q35070792-058E4A4D-3ADD-411C-97B1-C2AE20952041Q35758821-E07CB116-C901-4D4F-932F-7BFF0BA8D314Q35781854-B8BEBA24-EBCC-48FF-8626-50D8E4D66A2BQ35813543-88F3E3E8-53A7-475A-8F36-1ACF6863639EQ36135909-29A46F1E-17AA-4750-8411-E84D6EA150A9Q36137150-B08837BE-8C85-435C-9815-E17065FF1A01Q36309811-97F66811-D420-498A-BA15-0DCF3FC02C9AQ36358561-FC2F1AC0-7B34-41FF-8718-5BD9D17DE1E0Q36788144-5D31AA94-229A-413D-8D6E-8EAA7AA61885
P2860
PII signal transduction proteins: sensors of alpha-ketoglutarate that regulate nitrogen metabolism.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
PII signal transduction protei ...... regulate nitrogen metabolism.
@ast
PII signal transduction protei ...... regulate nitrogen metabolism.
@en
type
label
PII signal transduction protei ...... regulate nitrogen metabolism.
@ast
PII signal transduction protei ...... regulate nitrogen metabolism.
@en
prefLabel
PII signal transduction protei ...... regulate nitrogen metabolism.
@ast
PII signal transduction protei ...... regulate nitrogen metabolism.
@en
P1476
PII signal transduction protei ...... regulate nitrogen metabolism.
@en
P2093
Alexander J Ninfa
Peng Jiang
P304
P356
10.1016/J.MIB.2005.02.011
P577
2005-04-01T00:00:00Z