Models
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Simplified model file for PLaSMo accession ID PLM_71, version 1 (use simplified if your software cannot read the file, e.g. Sloppy Cell)
Creators: BioData SynthSys, Andrew Millar, Andrew Millar
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
DownloadOriginally submitted model file for PLaSMo accession ID PLM_71, version 1
Creators: BioData SynthSys, Andrew Millar, Andrew Millar
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
Originally submitted model file for PLaSMo accession ID PLM_1041, version 1
Creators: BioData SynthSys, Andrew Millar, Andrew Millar
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
Simplified model file for PLaSMo accession ID PLM_1041, version 1 (use simplified if your software cannot read the file, e.g. Sloppy Cell)
Creators: BioData SynthSys, Andrew Millar, Andrew Millar
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
Arabidopsis clock model P2011.6.1 SBML imported into Copasi 4.8 and saved as native Copasi file.
Creators: Andrew Millar, Uriel Urquiza Garcia, Kevin Stratford, EPCC
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: Copasi
Environment: Copasi
The P2011.3.1 SBML model imported into Copasi v4.8, saved as native Copasi file
Creators: Andrew Millar, Uriel Urquiza Garcia, Kevin Stratford, EPCC
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: Copasi
Environment: Copasi
Originally submitted model file for PLaSMo accession ID PLM_73, version 1
Creators: BioData SynthSys, Yin Hoon Chew
Submitter: BioData SynthSys
Model type: Not specified
Model format: Simile XML v3
Environment: Not specified
Originally submitted model file for PLaSMo accession ID PLM_75, version 1
Creators: BioData SynthSys, Yin Hoon Chew
Submitter: BioData SynthSys
Model type: Not specified
Model format: Simile XML v3
Environment: Not specified
Originally submitted model file for PLaSMo accession ID PLM_74, version 1
Creators: BioData SynthSys, Yin Hoon Chew
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: Simile XML v3
Environment: Not specified
Originally submitted model file for PLaSMo accession ID PLM_76, version 1
Creators: BioData SynthSys, Yin Hoon Chew
Submitter: BioData SynthSys
Model type: Not specified
Model format: Simile XML v3
Environment: Not specified
This record includes Matlab and Simile format versions of the Arabidopsis Framework Model version 1, FMv1 (Chew et al, PNAS 2014; http://www.pnas.org/content/early/2014/08/27/1410238111), copied from the PlaSMo resource (www.plasmo.ed.ac.uk), PLM_ID=76. The model description is in the Supplementary Materials of the publication, which should be uploaded somewhere here also but I don't see how to do it.
The FMv1 links the following sub-models:
- Arabidopsis leaf carbohydrate model (Rasse and ...
Creators: Andrew Millar, Yin Hoon Chew
Submitter: Andrew Millar
Model type: Not specified
Model format: Matlab package
Environment: Matlab
Exactly the same as model 243, but uploaded as a file rather than copied from PlaSMo.
Creator: Andrew Millar
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: JWS Online
This version is P2011.1.2, model ID PLM_71 version 1. Dynamics identical to P2011.1.1 of the Pokhilko et al. 2012 publication.
http://www.plasmo.ed.ac.uk/plasmo/models/download.shtml?accession=PLM_71&version=1
Creator: Andrew Millar
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: JWS Online
Creator: Daniel Seaton
Submitter: Daniel Seaton
Model type: Algebraic equations
Model format: Not specified
Environment: Not specified
The model presents a multi-compartmental (mesophyll, phloem and root) metabolic model of growing Arabidopsis thaliana. The flux balance analysis (FBA) of the model quantifies: sugar metabolism, central carbon and nitrogen metabolism, energy and redox metabolism, proton turnover, sucrose translocation from mesophyll to root and biomass growth under both dark- and light-growth conditions with corresponding growth either on starch (in darkness) or on CO2 (under light). The FBA predicts that ...
Creators: Maksim Zakhartsev, Olga Krebs, Irina Medvedeva, Ilya Akberdin, Yuriy Orlov
Submitter: Maksim Zakhartsev
Model type: Metabolic network
Model format: SBML
Environment: Not specified
