Genome-Scale Model Enterococcus faecalis V583
Metabolic network of Enterococcus faecalis including primary metabolism, polysaccharide metabolism, purine and pyrimidine biosoynthesis, teichoic acid biosynthesis, fatty acid and phospholipid bioynthesis, amino acid metabolism, vitamins and cofactors
SEEK ID: https://fairdomhub.org/assays/170
Modelling Analysis
Projects: SysMO-LAB
Investigation: Investigation of glycolysis and pyruvate branching of three lactic acid bacteria
Study: Reconstructing the metabolic pathways of S. pyogenes and E. faecalis from their genome sequence
Assay position:
Biological problem addressed: Metabolic Network
Organisms: Enterococcus faecalis : V583 (wild-type / wild-type) (chemostat)
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Created: 10th Apr 2012 at 10:10
Last updated: 8th Nov 2017 at 15:21
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Projects: SysMO-LAB
Institutions: University of Heidelberg
SysMO is a European transnational funding and research initiative on "Systems Biology of Microorganisms".
The goal pursued by SysMO was to record and describe the dynamic molecular processes going on in unicellular microorganisms in a comprehensive way and to present these processes in the form of computerized mathematical models.
Systems biology will raise biomedical and biotechnological research to a new quality level and contribute markedly to progress in understanding. Pooling European research ...
Projects: BaCell-SysMO, COSMIC, SUMO, KOSMOBAC, SysMO-LAB, PSYSMO, SCaRAB, MOSES, TRANSLUCENT, STREAM, SulfoSys, SysMO DB, SysMO Funders, SilicoTryp, Noisy-Strep
Web page: http://sysmo.net/
Comparative Systems Biology: Lactic Acid Bacteria
Programme: SysMO
Public web page: http://www.sysmo.net/index.php?index=57
Challenge: Comparative analyses, as demonstrated by comparative genomics and bioinformatics, are extremely powerful for (i) transfer of information from (experimentally) well-studied organisms to the other organisms, and (ii) when coupled to functional and phenotypic information, insight in the relative importance of components to the observed differences and simalities. The central principle of this proposal is that important aspects of the functional differences between organisms derive not ...
Submitter: Martijn Bekker
Studies: Comparative modeling and phosphate dependence flux distributions and glu..., Kinetics of L-lactate dehydrogenase from S. pyogenes, E. faecalis and L...., Reconstructing the metabolic pathways of S. pyogenes and E. faecalis fro..., Study of the physiological characterization of three lactic acid bacteri...
Assays: BIOLOG substrate utilization assay, Genome-Scale Model Enterococcus faecalis V583, Genome-scale model of Streptococcus pyogenes, Global sensitivity analysis, Glucose pulsed L. lactis, Glucose pulsed S. pyogenes, Kinetics of L-lactate dehydrogenase from L. lactis, Kinetics of L-lactate dehydrogenase from S. pyogenes, E. faecalis, and L..., Maximal specific growth rates of the three lactic acid bacteria and thei..., Model of L. lactis glycolysis, Physiological characterization of Lactic acid bacteria grown in C-limite..., Regulation of the activity of lactate dehydrogenases from four lactic ac...
The reconstruction of the metabolic networks is done by sequence comparison with already annotated genomes of L. lactis, L. plantarum, B. subtilis and E. coli
Submitter: Martijn Bekker
Provider Name: Not specified
Provider's strain ID: Not specified
Organism: Enterococcus faecalis
Genotypes: wild-type
Phenotypes: wild-type
Comment: Not specified
A reconstruction of the cellular metabolism of the opportunistic human pathogen Enterococcus faecalis V583 represented as stoichiometric model and analysed using constraint-based modelling approaches
Creators: Nadine Veith, Margrete Solheim, Koen van Grinsven, Jennifer Levering, Jeroen Hugenholtz, Helge Holo, Ingolf Nes, Bas Teusink, Ursula Kummer, Brett G Olivier, Ruth Grosseholz
Submitter: Nadine Veith
Model type: Linear equations
Model format: SBML
Environment: Not specified
