Carbon catabolite repression of phenol degradation in Pseudomonas putida is mediated by the inhibition of the activator protein PhlR.
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Novel regulator MphX represses activation of phenol hydroxylase genes caused by a XylR/DmpR-type regulator MphR in Acinetobacter calcoaceticusAnaerobic catabolism of aromatic compounds: a genetic and genomic view.Genes involved in anaerobic metabolism of phenol in the bacterium Thauera aromatica.Generation of novel bacterial regulatory proteins that detect priority pollutant phenols.Role of the DmpR-mediated regulatory circuit in bacterial biodegradation properties in methylphenol-amended soils.The PalkBFGHJKL promoter is under carbon catabolite repression control in Pseudomonas oleovorans but not in Escherichia coli alk+ recombinants.A functional 4-hydroxysalicylate/hydroxyquinol degradative pathway gene cluster is linked to the initial dibenzo-p-dioxin pathway genes in Sphingomonas sp. strain RW1.Monitoring intracellular levels of XylR in Pseudomonas putida with a single-chain antibody specific for aromatic-responsive enhancer-binding proteins.Repression of phenol catabolism by organic acids in Ralstonia eutropha.The black cat/white cat principle of signal integration in bacterial promoters.The quantity and quality of dissolved organic matter as supplementary carbon source impacts the pesticide-degrading activity of a triple-species bacterial biofilm.Measurement of biologically available naphthalene in gas and aqueous phases by use of a Pseudomonas putida biosensor.A tricarboxylic acid cycle intermediate regulating transcription of a chloroaromatic biodegradative pathway: fumarate-mediated repression of the clcABD operon.Bacterial transcriptional regulators for degradation pathways of aromatic compounds.Biodegradation of Phenol by Bacteria Strain Acinetobacter Calcoaceticus PA Isolated from Phenolic Wastewater.Benzoate catabolite repression of the phenol degradation in Acinetobacter calcoaceticus PHEA-2.Carbon catabolite repression in Pseudomonas : optimizing metabolic versatility and interactions with the environment.Adaptation of Comamonas testosteroni TA441 to utilization of phenol by spontaneous mutation of the gene for a trans-acting factor.Metabolic Regulation of a Bacterial Cell System with Emphasis on Escherichia coli Metabolism.Transcriptional modulation of transport and metabolism associated gene clusters leading to utilization of benzoate in preference to glucose in Pseudomonas putida CSV86.Draft Genome Sequence of the Phenol-Degrading Bacterium Pseudomonas putida H.Correspondence between community structure and function during succession in phenol- and phenol-plus-trichloroethene-fed sequencing batch reactors.Physiological analysis of the expression of the styrene degradation gene cluster in Pseudomonas fluorescens ST.HbpR, a new member of the XylR/DmpR subclass within the NtrC family of bacterial transcriptional activators, regulates expression of 2-hydroxybiphenyl metabolism in Pseudomonas azelaica HBP1.PhcS represses gratuitous expression of phenol-metabolizing enzymes in Comamonas testosteroni R5.Role of the crc gene in catabolic repression of the Pseudomonas putida GPo1 alkane degradation pathway.Whole-cell kinetics of trichloroethylene degradation by phenol hydroxylase in a ralstonia eutropha JMP134 derivativeCarbon-source-dependent expression of the PalkB promoter from the Pseudomonas oleovorans alkane degradation pathway.Fumarate-mediated inhibition of erythrose reductase, a key enzyme for erythritol production by Torula corallina.Genetic and biochemical characterization of a 2,4,6-trichlorophenol degradation pathway in Ralstonia eutropha JMP134.Inactivation of cytochrome o ubiquinol oxidase relieves catabolic repression of the Pseudomonas putida GPo1 alkane degradation pathway.An AraC/XylS family member at a high level in a hierarchy of regulators for phenol-metabolizing enzymes in Comamonas testosteroni R5An active role for a structured B-linker in effector control of the sigma54-dependent regulator DmpR.The Crc/CrcZ-CrcY global regulatory system helps the integration of gluconeogenic and glycolytic metabolism in Pseudomonas putida.Modulation of glucose transport causes preferential utilization of aromatic compounds in Pseudomonas putida CSV86Preferential utilization of aromatic compounds over glucose by Pseudomonas putida CSV86Utilization of acidic amino acids and their amides by pseudomonads: role of periplasmic glutaminase-asparaginase.Variovorax sp.-mediated biodegradation of the phenyl urea herbicide linuron at micropollutant concentrations and effects of natural dissolved organic matter as supplementary carbon source.Analysis of preference for carbon source utilization among three strains of aromatic compounds degrading Pseudomonas.Strict and direct transcriptional repression of the pobA gene by benzoate avoids 4-hydroxybenzoate degradation in the pollutant degrader bacterium Cupriavidus necator JMP134.
P2860
Q28477492-994D500C-9D3B-4056-8A85-F0E5C81E3D0DQ28755251-2278E7C2-9419-4C34-B154-A78089E9FCF4Q30928395-808094E6-0782-44D3-ADF5-F475A01E3BE4Q33986425-8F8D9C49-FE2A-4D9E-B556-BDE4AD2DC438Q33988525-38F96572-558D-462E-99A2-93E01429986AQ33991407-308BEEB3-1512-42F7-8A40-986021378CC7Q33992155-BFEDC612-39F7-4EA4-8CB8-2C2719D40645Q33996901-B289AF6A-4A6A-4684-B953-076F24C1789EQ34070545-8C6D0524-B96B-4DA3-BAF5-58EB415F07D3Q34166888-4FCBBC43-2D2F-4B78-A2BD-F69EF073796EQ34709596-610FA125-03C9-4D6D-BC65-E0FEA0EDA37CQ35540658-272BC127-A9CF-4AD2-B7C0-FED17DE4CC8DQ35631881-EA00EE84-87CA-4FBE-A329-3DD97D02D82AQ35880920-479540A8-412D-4ADB-ADE5-34B4CC2D2B80Q36732438-9EEA3ACC-D5A9-4436-B69A-53620DB86A59Q37348781-B2223A2A-18CA-44E7-8950-9A90438A2174Q37735901-5EF22DA7-B6B8-45AC-B128-AD83188A51A6Q38319844-901EAEDA-22A8-4E0A-93D9-B821E782E05FQ38456985-3FF91BA3-9AFA-4C2A-9038-87D381C23E16Q38667344-D94B1E67-B8A5-41E6-94C3-8419E5EFE876Q38972176-91D8FB77-23B6-4827-A4AE-980E542A5A66Q39308318-67334219-4980-4851-BE97-EBB386E2D4AEQ39485622-98CA4E1D-498F-4D02-97EB-6BAF88B15369Q39498570-DBFC4122-CA2E-49A3-855C-45A41BA71F90Q39504157-547FC16C-AACB-4141-9912-024F86DAB2CBQ39529668-17D05D37-735F-4503-8684-BEA5811ADEB8Q39562951-5A17592E-0E43-4DF8-8A94-E80174BC76A3Q39568021-2E7802AA-5612-4005-8D32-7B42A8BF3811Q39640736-18AF5733-0CD1-4B30-B8A9-6DB9CFB4E808Q39679593-06CF0A7E-3035-44D1-866C-EDE518B91124Q39679675-DF5DCE2E-58A9-4C7E-AA39-A70B0CE7F683Q39679724-9CE799D1-AEC0-4F29-B569-E80FA7745423Q39714567-19C918BE-1B75-43CF-9587-869E8C79431FQ41357226-1B006FEE-1ED2-470C-865F-AFDDDB3C53D5Q42705903-DB154FA5-8313-4A33-AF17-1236C6D35CB7Q42736277-CEFF69DD-01C5-49EB-8067-594686167EC9Q44334547-06160CC3-8E81-447F-BB17-A02A192569B3Q46102243-C7EC60EC-A9C8-474C-BD49-7E210815DB6CQ51599923-7B8661A0-63BA-4430-80C3-040A7F832246Q51603141-12D0C1E7-C71D-403F-A6AC-429B20DEBAC7
P2860
Carbon catabolite repression of phenol degradation in Pseudomonas putida is mediated by the inhibition of the activator protein PhlR.
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年学术文章
@wuu
1996年学术文章
@zh-cn
1996年学术文章
@zh-hans
1996年学术文章
@zh-my
1996年学术文章
@zh-sg
1996年學術文章
@yue
1996年學術文章
@zh
1996年學術文章
@zh-hant
name
Carbon catabolite repression o ...... of the activator protein PhlR.
@en
Carbon catabolite repression o ...... of the activator protein PhlR.
@nl
type
label
Carbon catabolite repression o ...... of the activator protein PhlR.
@en
Carbon catabolite repression o ...... of the activator protein PhlR.
@nl
prefLabel
Carbon catabolite repression o ...... of the activator protein PhlR.
@en
Carbon catabolite repression o ...... of the activator protein PhlR.
@nl
P2093
P2860
P1476
Carbon catabolite repression o ...... of the activator protein PhlR.
@en
P2093
Burchhardt G
Herrmann H
Petruschka L
P2860
P304
P356
10.1128/JB.178.7.2030-2036.1996
P577
1996-04-01T00:00:00Z