A Conserved Structural Module Regulates Transcriptional Responses to Diverse Stress Signals in Bacteria
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Competition for zinc binding in the host-pathogen interactionBacterial Sigma Factors and Anti-Sigma Factors: Structure, Function and DistributionStructural and Biochemical Bases for the Redox Sensitivity of Mycobacterium tuberculosis RslAA structural model of anti-anti-σ inhibition by a two-component receiver domain: the PhyR stress response regulatorPromoter-Specific Transcription Inhibition in Staphylococcus aureus by a Phage ProteinMycobacterium tuberculosis RsdA provides a conformational rationale for selective regulation of -factor activity by proteolysisStructural basis for sigma factor mimicry in the general stress response of AlphaproteobacteriaStructural basis of a protein partner switch that regulates the general stress response of α-proteobacteriaStructural basis for the redox sensitivity of the Mycobacterium tuberculosis SigK-RskA σ-anti-σ complexMycothiol regulates and is regulated by a thiol-specific antisigma factor RsrA and sigma(R) in Streptomyces coelicolorAn extracytoplasmic function sigma factor-dependent periplasmic glutathione peroxidase is involved in oxidative stress response of Shewanella oneidensis.BioGraphE: high-performance bionetwork analysis using the Biological Graph Environment.Identification of a novel anti-sigmaE factor in Neisseria meningitidis.CorE from Myxococcus xanthus is a copper-dependent RNA polymerase sigma factor.Reactive oxygen species-inducible ECF σ factors of Bradyrhizobium japonicumStructural biology of bacterial RNA polymerase.DegS and RseP homologous proteases are involved in singlet oxygen dependent activation of RpoE in Rhodobacter sphaeroidesDeterminants of redox sensitivity in RsrA, a zinc-containing anti-sigma factor for regulating thiol oxidative stress response.Evidence of a bacterial receptor for lysozyme: binding of lysozyme to the anti-σ factor RsiV controls activation of the ecf σ factor σV.Interactions between an anti-sigma protein and two sigma factors that regulate the pyoverdine signaling pathway in Pseudomonas aeruginosaAnalysis of sigma32 mutants defective in chaperone-mediated feedback control reveals unexpected complexity of the heat shock response.The extracytoplasmic function sigma factor σS protects against both intracellular and extracytoplasmic stresses in Staphylococcus aureus.Structural insights into the regulation of Bacillus subtilis SigW activity by anti-sigma RsiWMechanistic Implications of the Unique Structural Features and Dimerization of the Cytoplasmic Domain of the Pseudomonas Sigma Regulator, PupRNo single way to understand singlet oxygen signalling in plantsRegulation of bacterial RNA polymerase sigma factor activity: a structural perspective.Regulation of the SigH stress response regulon by an essential protein kinase in Mycobacterium tuberculosis.Organization and evolution of the biological response to singlet oxygen stress.Advances in bacterial promoter recognition and its control by factors that do not bind DNA.Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters.Bacterial responses to photo-oxidative stress.Cell-surface signaling in Pseudomonas: stress responses, iron transport, and pathogenicity.Coregulation of host-adapted metabolism and virulence by pathogenic yersiniaeRegulation of transcription by eukaryotic-like serine-threonine kinases and phosphatases in Gram-positive bacterial pathogens.Role of the extracytoplasmic function sigma factor RpoE4 in oxidative and osmotic stress responses in Rhizobium etliOxidative Unfolding of the Rubredoxin Domain and the Natively Disordered N-terminal Region Regulate the Catalytic Activity of Mycobacterium tuberculosis Protein Kinase G.Themes and variations in gene regulation by extracytoplasmic function (ECF) sigma factors.Role of cell surface signaling in proteolysis of an alternative sigma factor in Pseudomonas aeruginosa.Self-cleavage of the Pseudomonas aeruginosa Cell-surface Signaling Anti-sigma Factor FoxR Occurs through an N-O Acyl RearrangementEnvironmental Sensing in Actinobacteria: a Comprehensive Survey on the Signaling Capacity of This Phylum.
P2860
Q27001616-2008B21B-28AF-4FB3-AF70-A678B6B32237Q27012703-0FFAD32D-826E-4B8D-8303-B8AB0CE36D57Q27660054-7E880114-F80C-42A5-AEA4-31DBDFD31503Q27664153-E4356D0A-BF4A-400E-A4AA-42E3E1E13A9FQ27675215-AA0DC8B7-6FBF-4AA5-8E93-BBAAB979E8C4Q27675886-4B06DD96-4B53-45F4-98F0-3A9BCFD6CFDAQ27678856-26E16A42-3003-40E4-A0FC-F6D8AB45CAE3Q27678860-527DA15C-C051-4F4D-AC9C-CC9E6D946EC3Q27689853-0547701D-B8DE-4E85-9FBE-9B58DBA0C8E5Q28504071-F9A9719B-5356-41B4-8846-67F91F9AF7BAQ30300173-0E08B37E-A6CC-4935-AC39-35C8DA2AF947Q33341549-915103C6-BC90-4CDF-A4D6-F4DE6E084464Q33595238-284B6EB5-8A6D-41E0-9895-3EB0ED8162DEQ33926855-87CE53A5-013E-4E7D-A783-951868F17F8CQ34391588-20AB4D41-E24A-41E2-AA70-7AB6DFF01F64Q34669788-6663866D-3F84-4897-B06C-92D8050F3F33Q35041357-B2202BA9-3503-45CA-A8F7-F09B4BEBA3B7Q35224408-3ABD79DA-B784-4EDF-AFB6-19122AE029FCQ35295202-59F83610-92D9-4163-809A-3D41F94F2716Q35459873-353C5FC8-29CE-4C57-B885-D222AE12318EQ36140761-8F1E1934-6D72-45A1-A6F9-337660C65297Q36155300-2A231C23-72AE-40E9-9C26-EA8320AFEEBAQ36314674-3A703A3F-AD13-46E7-8B88-0ABF996B6887Q36429678-630302B8-1F8C-42AF-A184-977B6ACBAEBFQ36638854-DF5D29BF-FE94-4608-8C10-ED36FCAEA754Q36662639-4715B5D9-2035-4B86-897E-D962A75EBA0AQ36861908-32C6BB08-DEAE-4075-9420-8A9E45A48E20Q36964081-5F1635DF-1965-4792-86EE-1911DCFAC86FQ36980036-5C6E982E-6E64-4484-BCA3-C6A8CC0349CCQ37279503-4DCF670F-E330-48E2-9224-1C2F66B15F13Q37475290-5F0E4423-C698-43F0-816D-2FF77B3BDC0CQ38219797-87946B77-270A-455C-A224-CB10FE0B5896Q38264926-EBEF113F-5D50-463A-BA82-090C4889F9E0Q38325104-F4FDE318-E57C-416B-AD9D-0DAB5EAC95AAQ38354938-627632BE-5DD4-4897-8EA0-68EC32BCC96EQ39218676-FCF8225D-EA75-4CC4-B466-522609EC3DD2Q39346572-ED9F873A-3A81-454E-AE2A-BF1F87221D27Q39764754-71F74406-9FCB-4E97-B3EF-0D63977000BAQ40432169-B6580C37-4B63-411A-B588-898B0C2C3D86Q40926419-E2925345-30D2-4A55-9D8B-A3EB7F37ABC8
P2860
A Conserved Structural Module Regulates Transcriptional Responses to Diverse Stress Signals in Bacteria
description
2007 nî lūn-bûn
@nan
2007 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@ast
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@en
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@nl
type
label
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@ast
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@en
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@nl
prefLabel
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@ast
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@en
A Conserved Structural Module ...... rse Stress Signals in Bacteria
@nl
P2093
P2860
P50
P3181
P1433
P1476
A conserved structural module ...... rse stress signals in bacteria
@en
P2093
Heidi J Sofia
Jennifer R Anthony
Lionel Lim
Roger Greenwell
Seth A Darst
Sheng Wang
P2860
P304
P3181
P356
10.1016/J.MOLCEL.2007.07.009
P577
2007-09-01T00:00:00Z