Assays
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This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the degradation rate of TOC1 has been eliminated by setting the rate to the value it had in the light in the original model. This model was used to generate Figure 2D in Dixon et al. New Phytologist (2014)Related Publications Laura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the degradation rate of TOC1 has been eliminated by setting the rate to the value it had in the dark in the original model. This model was used to generate Figure 2D in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the activation rate of TOC1 has been eliminated by setting the rate to the value it had in the light in the original model. This model was used to generate Figure 2E in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the activation rate of TOC1 has been eliminated by setting the rate to the value it had in the dark in the original model. This model was used to generate Figure 2E in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the transcription rate of CCA1 has been eliminated by setting the rate to the value it had in the light in the original model. This model was used to generate Figure 2C in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the transcription rate of CCA1 has been eliminated by setting the rate to the value it had in the dark in the original model. This model was used to generate Figure 2C in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the degradation rate of CCA1 has been eliminated by setting the rate to the value it had in the light in the original model. This model was used to generate Figure 2B in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where light input to the degradation rate of CCA1 has been eliminated by setting the rate to the value it had in the dark in the original model. This model was used to generate Figure 2B in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where the light accumulator (acc) has been eliminated by setting its value to 1. This model was used to generate Figure 2F in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to environmental signals. New Phytologist. Originally submitted to ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
This is a version of the T2011.1.2 Ostreococcus tauri 1-loop clock model where the light accumulator (acc) has been eliminated by replacing it with immediate light input. This model was used to generate Figure 2F in Dixon et al. New Phytologist (2014)Related PublicationsLaura E. Dixon, Sarah K. Hodge, Gerben van Ooijen, Carl Troein, Ozgur E. Akman, Andrew J. Millar (2014). Light and circadian regulation of clock components aids flexible responses to environmental signals. New Phytologist. Originally ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Troein, Carl
The model is applied to spring wheat, with ample supply of nutrients and water, also without pests, diseases and weeds. Radiation and temperature, being the most important environmental factors, and crop characteristics determine growth and development. Crop growth and development are simulated based on underlying chemical, physiological and physical processes. Dry matter accumulation is calculated from daily crop CO2 assimilation based on leaf CO2 assimilation and taking into account the respiration ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Massheder, Jonathan
Study: SUCROS1 - PLM_24
This model, derived from Biomodels299, is a variant of the Neurospora Circadian clock model of Leloup et al., 1999. It is supplemented with a periodic light function (SBO:0000475) that is parameterized to produce sinusoidal oscillations in the light sensitive parameter Vs with an amplitude of 5. These sinusoidal wave-form maintains entrained oscillations even with high light input, and is described in Figures 6 and 7 of Gonze and Goldbeter, 2000.Related PublicationsDidier Gonze and Albert Goldbeter ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Adams, Richard
This model is derived from Biomodels 299 - the Leloup et al Neurospora clock model. This variant contains an embedded light-forcing function (SBO:000475) that provides a periodic light input. In this model, after 72h of LD12:12, the amplitude of Vs ( the light dependent parameter ) increases to 4.1, leading to chaotic oscillations. For this to happen, the periodic light function needs to produce a square-wave pattern. Execution of this model will result in the behaviour depicted in Figure 2D ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Adams, Richard
Neuronal musch signalling sbml diagram
Originally submitted to PLaSMo on 2012-03-05 12:33:43
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin
This is a modified version of Biomodels89, containing a light-forcing function. This variant is configured to run cycles of LD8:16Related Publicationsocke JC, Kozma-Bognár L, Gould PD, Fehér B, Kevei E, Nagy F, Turner MS, Hall A, Millar AJ. (2006). Experimental validation of a predicted feedback loop in the multi-oscillator clock of Arabidopsis thaliana. . Mol Syst Biol . Originally submitted to PLaSMo on 2012-03-29 10:24:44
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Adams, Richard
Model files accompanying Seaton et al., Molecular Systems Biology, 2015 Abstract: Clock?regulated pathways coordinate the response of many developmental processes to changes in photoperiod and temperature. We model two of the best?understood clock output pathways in Arabidopsis, which control key regulators of flowering and elongation growth. In flowering, the model predicted regulatory links from the clock to CYCLING DOF FACTOR 1 (CDF1) and FLAVIN?BINDING, KELCH REPEAT, F?BOX 1 (FKF1) transcription. ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Seaton, Daniel
Validation: Validated against the original running in Excel. Each calculation in the model was individually validated as well. Comments on numerical integration: Euler integration with time steps of 1. In Simile the "time units" were set to "day" and execution was for 364 days as the simulation starts at time 0 (not time 1 as in the Excel model). Comments on running Simile model: Users must specify the temperature controlled growing season themselves. To do this use the following steps which take ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Davey, Chris
Study: Miscanmod - PLM_3
This is a very simple generic vegetation model, with just one state variable (plant biomass), and two processes: assimilation and respiration. In the original paper, the model is used twice, once for the trees and once for the grass under the trees, with the grass receiving light not intercepted by the trees. The model provided here is just for a single vegetation component.Related PublicationsMcMurtrie RE, Wolf L (1983). A model of competition between trees and grass for radiation, water and ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Muetzelfeldt, Robert
This is a very simple generic vegetation model, with just one state variable (plant biomass), and two processes: assimilation and respiration. In the original paper, the model is used twice, once for the trees and once for the grass under the trees, with the grass receiving light not intercepted by the trees. The model provided here is just for a single vegetation component.Related PublicationsMcMurtrie RE, Wolf L (1983). A model of competition between trees and grass for radiation, water and ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Muetzelfeldt, Robert
Test by Martin for simileXML
Version Comments
Version 2, the product of many seconds of research..
Originally submitted to PLaSMo on 2012-03-08 11:39:23
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin
Study: Martin test - PLM_65
Test by Martin for simileXML
Originally submitted to PLaSMo on 2012-03-08 11:39:23
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin
Study: Martin test - PLM_65
This is a verified version of the model named LINTUL in this repository. The model is verified against the benchmark FST implmmentation. LINTUL assumes non-limiting conditions. See the "LINTUL" model entry in this repository for a description
Originally submitted to PLaSMo on 2011-02-23 00:08:23
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Massheder, Jonathan
Study: LINTUL_V2 - PLM_42
"LINTUL simulates potential growth of a crop, i.e. its dry matter accumulation under ample supply of water and nutrients in a pest-, disease- and weed-free environment, under the prevailing weather conditions. The rate of dry matter accumulation is a function of irradiation and crop characteristics. The model makes use of the common observation that the crop growth rate under favourable conditions is proportional to the amount of light intercepted (Monteith, 1977). Dry matter production is, ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Muetzelfeldt, Robert
Study: LINTUL - PLM_4
sbgn model of signalling
Originally submitted to PLaSMo on 2012-03-05 11:53:41
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin
SBGN model of glycolysis
Originally submitted to PLaSMo on 2012-03-05 11:43:15
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin
Study: Glycolysis SBGN - PLM_60
Model outputs mRNA expression of PIF4/5 that is under control of the Pokhilko extended circadian clock. The first version (Model 2a in the supplementary file) has inhibition of PIFs from TOC1. The second version (Model 2c) has PIF activity promoted by LHY/CCA1 - this is currently the most accurate model when compared to data. Models shall be updated later to include PIF4/5 protein levels. Parameter values for this and other External Coincidence models found in supplementary file.Version Comments ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Smith, Rob
Model outputs mRNA expression of PIF4/5 that is under control of the Pokhilko extended circadian clock. The first version (Model 2a in the supplementary file) has inhibition of PIFs from TOC1. The second version (Model 2c) has PIF activity promoted by LHY/CCA1 - this is currently the most accurate model when compared to data. Models shall be updated later to include PIF4/5 protein levels. Parameter values for this and other External Coincidence models found in supplementary file.Originally submitted ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Smith, Rob
DALEC (Data Assimilation Linked Ecosystem Carbon) represents the C cycle with a simple box model of pools connected via fluxes. There are five pools: C content of foliage (Cf); woody stems and coarse roots (Cw) and fine roots (Cr); and of fresh leaf and fine root litter (Clitter) and soil organic matter (SOM) plus WD (CSOM/WD). The fluxes among pools are based on the following assumptions: All C fixed during a day is either expended in autotrophic respiration or else allocated to one of three ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Muetzelfeldt, Robert
Study: DALEC - PLM_23
"The CENTURY model is a general model of plant-soil nutrient cycling which is being used to simulate carbon and nutrient dynamics for different types of ecosystems including grasslands, agricultural lands, forests and savannas. CENTURY is composed of a soil organic matter/ decomposition submodel, a water budget model, a grassland/crop submodel, a forest production submodel, and management and events scheduling functions. It computes the flow of carbon, nitrogen, phosphorus, and sulfur through ...
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Muetzelfeldt, Robert
Study: CENTURY_Rowe_daily - PLM_22
This is the representation of major parts of the central metabolism in monocotyledon plants. The information has been derived from the MetaCrop [2] database, a manually curated repository of high quality information concerning the metabolism of crop plants. This includes pathways, reactions, locations, transport processes, and moreOriginally submitted to PLaSMo on 2012-03-05 11:52:18
Submitter: BioData SynthSys
Biological problem addressed: Gene Regulatory Network
Investigation: Beaton, Martin