Difference between revisions of "GudB"
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{{SubtiWiki category|[[utilization of amino acids]]}}, | {{SubtiWiki category|[[utilization of amino acids]]}}, | ||
{{SubtiWiki category|[[transcription factors and their control]]}}, | {{SubtiWiki category|[[transcription factors and their control]]}}, | ||
− | {{SubtiWiki category|[[trigger enzyme]]}} | + | {{SubtiWiki category|[[trigger enzyme]]}}, |
+ | {{SubtiWiki category|[[phosphoproteins]]}} | ||
= This gene is a member of the following [[regulons]] = | = This gene is a member of the following [[regulons]] = |
Revision as of 15:19, 20 April 2012
- Description: trigger enzyme: glutamate dehydrogenase (cryptic in 168 and derivatives)
Gene name | gudB |
Synonyms | ypcA |
Essential | no |
Product | trigger enzyme: glutamate dehydrogenase |
Function | glutamate utilization, control of GltC activity |
Metabolic function and regulation of this protein in SubtiPathways: Ammonium/ glutamate | |
MW, pI | 47 kDa, 5.582 |
Gene length, protein length | 1278 bp, 426 aa |
Immediate neighbours | ypdA, ypbH |
Get the DNA and protein sequences (Barbe et al., 2009) | |
Genetic context This image was kindly provided by SubtiList
| |
Expression at a glance PubMed |
Contents
[hide]
Categories containing this gene/protein
utilization of amino acids, transcription factors and their control, trigger enzyme, phosphoproteins
This gene is a member of the following regulons
The gene
Basic information
- Locus tag: BSU22960
Phenotypes of a mutant
- The gene is cryptic. If gudB is activated (gudB1 mutation), the bacteria are able to utilize glutamate as the only carbon source. PubMed
- A rocG gudB mutant is sensitive to ß-lactam antibiotics such as cefuroxime and to fosfomycin due to the downregulation of the SigW regulon PubMed
- transcription profile of a rocG gudB mutant strain: GEO PubMed
Database entries
- DBTBS entry: [1]
- SubtiList entry: [2]
Additional information
The protein
Basic information/ Evolution
- Catalyzed reaction/ biological activity: L-glutamate + H2O + NAD+ = 2-oxoglutarate + NH3 + NADH + H+ (according to Swiss-Prot)
- Protein family: Glu/Leu/Phe/Val dehydrogenases family (according to Swiss-Prot)
- Paralogous protein(s): RocG
Extended information on the protein
- Kinetic information:
- Domains:
- Modification:
- Cofactor(s):
- Effectors of protein activity:
Database entries
- UniProt: P50735
- KEGG entry: [4]
- E.C. number: 1.4.1.2
Additional information
Expression and regulation
- Operon: gudB PubMed
- Regulation: constitutively expressed PubMed
- Regulatory mechanism:
- Additional information: GudB is subject to Clp-dependent proteolysis upon glucose starvation PubMed
Biological materials
- Mutant: GP691 (cat), GP1160 (del aphA3) both available in Stülke lab
- Expression vector:
- for purification of GudB from E. coli carrying an N-terminal Strep-tag: pGP863 (in pGP172) available in Stülke lab
- for purification of GudB1 from E. coli carrying an N-terminal Strep-tag: pGP864 (in pGP172) available in Stülke lab
- for ectopic expression of gudB with its native promoter: pGP900 (in pAC5), available in Stülke lab
- wild type gudB, expression in B. subtilis, in pBQ200: pGP1712, available in Stülke lab
- lacZ fusion: pGP651 (in pAC5), available in Stülke lab
- FLAG-tag construct: GP1194 (gudB, spc, based on pGP1331), GP1195 (gudB1, spc, based on pGP1331), available in Stülke lab
- GFP fusion:
- two-hybrid system:
Labs working on this gene/protein
Linc Sonenshein, Tufts University, Boston, MA, USA Homepage
Jörg Stülke, University of Göttingen, Germany Homepage
Fabian Commichau University of Göttingen, Germany Homepage
Your additional remarks
The GudB protein is active in other legacy B. subtilis strains (e.g. strain 122). Thus, it can be speculated that the ancestral gudB gene was not cryptic, but became so as a product of the "domestication" of B. subtilis 168 in the lab. PubMed
References
Reviews
Jason R Treberg, Margaret E Brosnan, Malcolm Watford, John T Brosnan
On the reversibility of glutamate dehydrogenase and the source of hyperammonemia in the hyperinsulinism/hyperammonemia syndrome.
Adv Enzyme Regul: 2010, 50(1);34-43
[PubMed:19895831]
[WorldCat.org]
[DOI]
(I p)
Victoria I Bunik, Alisdair R Fernie
Metabolic control exerted by the 2-oxoglutarate dehydrogenase reaction: a cross-kingdom comparison of the crossroad between energy production and nitrogen assimilation.
Biochem J: 2009, 422(3);405-21
[PubMed:19698086]
[WorldCat.org]
[DOI]
(I e)
N M Brunhuber, J S Blanchard
The biochemistry and enzymology of amino acid dehydrogenases.
Crit Rev Biochem Mol Biol: 1994, 29(6);415-67
[PubMed:7705101]
[WorldCat.org]
[DOI]
(P p)
R C Hudson, R M Daniel
L-glutamate dehydrogenases: distribution, properties and mechanism.
Comp Biochem Physiol B: 1993, 106(4);767-92
[PubMed:8299344]
[WorldCat.org]
[DOI]
(P p)
Original publications
Additional publications: PubMed
Katrin Gunka, Stefan Tholen, Jan Gerwig, Christina Herzberg, Jörg Stülke, Fabian M Commichau
A high-frequency mutation in Bacillus subtilis: requirements for the decryptification of the gudB glutamate dehydrogenase gene.
J Bacteriol: 2012, 194(5);1036-44
[PubMed:22178973]
[WorldCat.org]
[DOI]
(I p)
Lope A Flórez, Katrin Gunka, Rafael Polanía, Stefan Tholen, Jörg Stülke
SPABBATS: A pathway-discovery method based on Boolean satisfiability that facilitates the characterization of suppressor mutants.
BMC Syst Biol: 2011, 5;5
[PubMed:21219666]
[WorldCat.org]
[DOI]
(I e)
Katrin Gunka, Joseph A Newman, Fabian M Commichau, Christina Herzberg, Cecilia Rodrigues, Lorraine Hewitt, Richard J Lewis, Jörg Stülke
Functional dissection of a trigger enzyme: mutations of the bacillus subtilis glutamate dehydrogenase RocG that affect differentially its catalytic activity and regulatory properties.
J Mol Biol: 2010, 400(4);815-27
[PubMed:20630473]
[WorldCat.org]
[DOI]
(I p)
Daniel R Zeigler, Zoltán Prágai, Sabrina Rodriguez, Bastien Chevreux, Andrea Muffler, Thomas Albert, Renyuan Bai, Markus Wyss, John B Perkins
The origins of 168, W23, and other Bacillus subtilis legacy strains.
J Bacteriol: 2008, 190(21);6983-95
[PubMed:18723616]
[WorldCat.org]
[DOI]
(I p)
Shigeki Kada, Masahiro Yabusaki, Takayuki Kaga, Hitoshi Ashida, Ken-ichi Yoshida
Identification of two major ammonia-releasing reactions involved in secondary natto fermentation.
Biosci Biotechnol Biochem: 2008, 72(7);1869-76
[PubMed:18603778]
[WorldCat.org]
[DOI]
(I p)
Fabian M Commichau, Katrin Gunka, Jens J Landmann, Jörg Stülke
Glutamate metabolism in Bacillus subtilis: gene expression and enzyme activities evolved to avoid futile cycles and to allow rapid responses to perturbations of the system.
J Bacteriol: 2008, 190(10);3557-64
[PubMed:18326565]
[WorldCat.org]
[DOI]
(I p)
Ulf Gerth, Holger Kock, Ilja Kusters, Stephan Michalik, Robert L Switzer, Michael Hecker
Clp-dependent proteolysis down-regulates central metabolic pathways in glucose-starved Bacillus subtilis.
J Bacteriol: 2008, 190(1);321-31
[PubMed:17981983]
[WorldCat.org]
[DOI]
(I p)
Fabian M Commichau, Ingrid Wacker, Jan Schleider, Hans-Matti Blencke, Irene Reif, Philipp Tripal, Jörg Stülke
Characterization of Bacillus subtilis mutants with carbon source-independent glutamate biosynthesis.
J Mol Microbiol Biotechnol: 2007, 12(1-2);106-13
[PubMed:17183217]
[WorldCat.org]
[DOI]
(P p)
B R Belitsky, A L Sonenshein
Role and regulation of Bacillus subtilis glutamate dehydrogenase genes.
J Bacteriol: 1998, 180(23);6298-305
[PubMed:9829940]
[WorldCat.org]
[DOI]
(P p)