BRENDA - Enzyme Database show
show all sequences of 2.7.8.42

Complex transcriptional and post-transcriptional regulation of an enzyme for lipopolysaccharide modification

Moon, K.; Six, D.A.; Lee, H.J.; Raetz, C.R.; Gottesman, S.; Mol. Microbiol. 89, 52-64 (2013)

Data extracted from this reference:

Organism
Organism
Primary Accession No. (UniProt)
Commentary
Textmining
Escherichia coli
P37661
-
-
Expression
Organism
Commentary
Expression
Escherichia coli
Hfq-dependent small RNA MgrR negatively regulates expression of EptB. Envelope stress response protein Sigma E has positively regulates EptB. The effects of Sigma E and deletion of MgrR on levels of EptB mRNA are independent, and the same 5? end is found in both cases. Sigma E acts directly at the level of transcription initiation for EptB, from the same start point as Sigma 70. When Sigma E is active, synthesis of EptB transcript may outstrip MgrR-dependent degradation. A second sRNA, ArcZ, also directly and negatively regulates EptB
additional information
General Information
General Information
Commentary
Organism
metabolism
Hfq-dependent small RNA MgrR negatively regulates expression of EptB. Envelope stress response protein Sigma E has positively regulates EptB. The effects of Sigma E and deletion of MgrR on levels of EptB mRNA are independent, and the same 5' end is found in both cases. Sigma E acts directly at the level of transcription initiation for EptB, from the same start point as Sigma 70. When Sigma E is active, synthesis of EptB transcript may outstrip MgrR-dependent degradation. A second sRNA, ArcZ, also directly and negatively regulates EptB
Escherichia coli
General Information (protein specific)
General Information
Commentary
Organism
metabolism
Hfq-dependent small RNA MgrR negatively regulates expression of EptB. Envelope stress response protein Sigma E has positively regulates EptB. The effects of Sigma E and deletion of MgrR on levels of EptB mRNA are independent, and the same 5' end is found in both cases. Sigma E acts directly at the level of transcription initiation for EptB, from the same start point as Sigma 70. When Sigma E is active, synthesis of EptB transcript may outstrip MgrR-dependent degradation. A second sRNA, ArcZ, also directly and negatively regulates EptB
Escherichia coli
Expression (protein specific)
Organism
Commentary
Expression
Escherichia coli
Hfq-dependent small RNA MgrR negatively regulates expression of EptB. Envelope stress response protein Sigma E has positively regulates EptB. The effects of Sigma E and deletion of MgrR on levels of EptB mRNA are independent, and the same 5? end is found in both cases. Sigma E acts directly at the level of transcription initiation for EptB, from the same start point as Sigma 70. When Sigma E is active, synthesis of EptB transcript may outstrip MgrR-dependent degradation. A second sRNA, ArcZ, also directly and negatively regulates EptB
additional information
Other publictions for EC 2.7.8.42
No.
1st author
Pub Med
title
organims
journal
volume
pages
year
Activating Compound
Application
Cloned(Commentary)
Crystallization (Commentary)
Engineering
General Stability
Inhibitors
KM Value [mM]
Localization
Metals/Ions
Molecular Weight [Da]
Natural Substrates/ Products (Substrates)
Organic Solvent Stability
Organism
Oxidation Stability
Posttranslational Modification
Purification (Commentary)
Reaction
Renatured (Commentary)
Source Tissue
Specific Activity [micromol/min/mg]
Storage Stability
Substrates and Products (Substrate)
Subunits
Temperature Optimum [°C]
Temperature Range [°C]
Temperature Stability [°C]
Turnover Number [1/s]
pH Optimum
pH Range
pH Stability
Cofactor
Ki Value [mM]
pI Value
IC50 Value
Activating Compound (protein specific)
Application (protein specific)
Cloned(Commentary) (protein specific)
Cofactor (protein specific)
Crystallization (Commentary) (protein specific)
Engineering (protein specific)
General Stability (protein specific)
IC50 Value (protein specific)
Inhibitors (protein specific)
Ki Value [mM] (protein specific)
KM Value [mM] (protein specific)
Localization (protein specific)
Metals/Ions (protein specific)
Molecular Weight [Da] (protein specific)
Natural Substrates/ Products (Substrates) (protein specific)
Organic Solvent Stability (protein specific)
Oxidation Stability (protein specific)
Posttranslational Modification (protein specific)
Purification (Commentary) (protein specific)
Renatured (Commentary) (protein specific)
Source Tissue (protein specific)
Specific Activity [micromol/min/mg] (protein specific)
Storage Stability (protein specific)
Substrates and Products (Substrate) (protein specific)
Subunits (protein specific)
Temperature Optimum [°C] (protein specific)
Temperature Range [°C] (protein specific)
Temperature Stability [°C] (protein specific)
Turnover Number [1/s] (protein specific)
pH Optimum (protein specific)
pH Range (protein specific)
pH Stability (protein specific)
pI Value (protein specific)
Expression
General Information
General Information (protein specific)
Expression (protein specific)
KCat/KM [mM/s]
KCat/KM [mM/s] (protein specific)
739099
Moon
Complex transcriptional and po ...
Escherichia coli
Mol. Microbiol.
89
52-64
2013
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734192
Cullen
Characterization of unique mod ...
Campylobacter jejuni
J. Biol. Chem.
287
3326-3336
2012
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734149
Reynolds
A phosphoethanolamine transfer ...
Escherichia coli
J. Biol. Chem.
280
21202-21211
2005
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734135
Kanipes
Ca2+-induced phosphoethanolami ...
Escherichia coli
J. Biol. Chem.
276
1156-1163
2001
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