Collection of models submitted to PLaSMo by Uriel Urquiza Garcia and automatically transferred to FAIRDOM Hub.
SEEK ID: https://fairdomhub.org/investigations/257
Projects: PlaSMo model repository
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Uriel Urquiza Garcia
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Created: 10th Jan 2019 at 16:37
Last updated: 20th Dec 2019 at 12:39
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Projects: Millar group, TiMet, PHYTOCAL: Phytochrome Control of Resource Allocation and Growth in Arabidopsis and in Brassicaceae crops, POP - the Parameter Optimisation Problem, Regulation of flowering time in natural conditions, PlaSMo model repository
Institutions: University of Edinburgh
https://orcid.org/0000-0003-1756-3654Projects: PlaSMo model repository
Institutions: University of Edinburgh
Projects: Millar group, PlaSMo model repository, PHYTOCAL: Phytochrome Control of Resource Allocation and Growth in Arabidopsis and in Brassicaceae crops, Light and plant development, Light control of leaf development, Toggle switch, Reduce Complexity (RCO) reconstruction, Model Driven Prime Editing, PULSE 2.0, Plant optogenetics
Institutions: University of Edinburgh, Heinrich Heine University of Düsseldorf
https://orcid.org/0000-0002-7975-5013SynthSys is the University of Edinburgh's research organisation in interdisciplinary, Synthetic and Systems Biology, founded in 2012 as the successor to the Centre for Systems Biology at Edinburgh (CSBE).
Projects: Millar group, PHYTOCAL: Phytochrome Control of Resource Allocation and Growth in Arabidopsis and in Brassicaceae crops, TiMet, POP - the Parameter Optimisation Problem, Regulation of flowering time in natural conditions, PlaSMo model repository
Web page: http://www.synthsys.ed.ac.uk
What is PlaSMo? PlaSMo stands for Plant Systems-biology Modelling Ensuring the achievements of yesterday's Mathematical Modellers will be available for the Systems Biologists of tomorrow.
Our aims
To identify plant mathematical models useful to the UK plant systems biology community, which are currently in a variety of legacy formats and in danger of being lost To represent these models in a declarative XML-based format, which is closer to the systems biology standard SBML To evaluate the behaviour ...
Programme: SynthSys
Public web page: Not specified
Organisms: Arabidopsis thaliana, Ostreococcus tauri
The model is an extensio of PLM_67v3 with an additional an additional variable Temp in ODE 25. This change allows to simulated warm pulses that affect EC stability using COPASI.
Originally submitted to PLaSMo on 2014-03-10 13:16:25
Submitter: BioData SynthSys
Investigation: Urquiza Garcia, Uriel
Snapshots: No snapshots
Model that eliminates several light inputs. RVE8, NOX are incorporated. Individual representation of CCA1 and LHY. Several changes in conections and light inputs. Fogelmark reports eight parameter sets. This SBML file contains the first parameter set Related PublicationsFogelmark K, Troein C (2014). Rethinking transcriptional activation in the Arabidopsis circadian clock.. PLoS Comput Biology. Retrieved from: http://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1003705Originally ...
Submitter: BioData SynthSys
Investigation: Urquiza Garcia, Uriel
Assays: F2014.1 - PLM_1030, version 1
Snapshots: No snapshots
Model that eliminates several light inputs. RVE8, NOX are incorporated. Individual representation of CCA1 and LHY. Several changes in conections and light inputs. Fogelmark reports eight parameter sets. This SBML file contains the first parameter set Related PublicationsFogelmark K, Troein C (2014). Rethinking transcriptional activation in the Arabidopsis circadian clock.. PLoS Comput Biology. Retrieved from: http://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1003705Originally ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Urquiza Garcia, Uriel
Study: F2014.1 - PLM_1030
Organisms: No organisms
Models: F2014 all parameters in SBML, F2014.1 - PLM_1030, version 1, SUBMITTED, F2014.1.2 Copasi, F2014.1.2 with stepfunction and 1 hidden item
SOPs: No SOPs
Data files: No Data files
Snapshots: No snapshots
The model is an extensio of PLM_67v3 with an additional an additional variable Temp in ODE 25. This change allows to simulated warm pulses that affect EC stability using COPASI.
Originally submitted to PLaSMo on 2014-03-10 13:16:25
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Urquiza Garcia, Uriel
Organisms: No organisms
Models: 2 hidden items
SOPs: No SOPs
Data files: No Data files
Snapshots: No snapshots
Originally submitted model file for PLaSMo accession ID PLM_1030, version 1
Creators: BioData SynthSys, Uriel Urquiza Garcia, Andrew Millar
Submitter: BioData SynthSys
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Copasi
From published files, Uriel Urquiza created SBML models with all 8 parameter sets published, and versions of F2014.1 to simulate multiple clock mutants, using SloppyCell
Creators: Andrew Millar, Uriel Urquiza Garcia
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
F2014.1.2 SBML file including Stepfunction imported back into Copasi v4.8
Creators: Andrew Millar, Karl Fogelmark, Carl Troein
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: Copasi
Environment: Copasi
Organism: Arabidopsis thaliana
Investigations: Urquiza Garcia, Uriel
Studies: F2014.1 - PLM_1030
Assays: F2014.1 - PLM_1030, version 1
F2014.1.1 becomes the published version, with SBML file originally created from SloppyCell by Uriel Urquiza - see separate file. then Andrew Millar converted into SBML L2V4 in Copasi and added ISSF for light input, using SBSI Stepfunction editor (see Adams et al. 2011 J Biol Rhythms).
Creators: Andrew Millar, Karl Fogelmark, Carl Troein
Submitter: Andrew Millar
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified