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The dataset presents mathematical models of the gene regulatory network of the circadian clock, in the plant Arabidopsis thaliana. The work will be published as Urquiza-Garcia, Molina, Halliday and Millar, title "Abundant clock proteins point to missing molecular regulation in the plant circadian clock", in Molecular Systems Biology, 2025.
Starting from the U2019.3 and U2020.3 models, this project rescales parameters to match protein levels that were predicted using a simple model from the TiMet ...
Submitter: Andrew Millar
Studies: Construction of NanoLUC-tagged plants, Estimating DNA-binding affinities for Arabidopsis proteins, Measuring absolute levels of clock proteins with calibrated NanoLUC assays, Predicting absolute levels of clock proteins with a simple model, Recalibrating the clock models for absolute protein levels, to create mo..., Reproducibility documentation
Assays: Clock protein number determination with NanoLUC calibration, Clock proteins NanoLUC fusion raw data, Gatway maps of genomic regions of clock genes, In vivo bioluminescence of clock protein-NanoLUC fusions: example experi..., Jupyter notebook Predicting Protein Numbers, Propagating scaling factors into model parameters for U2019.4->U2019.5 a..., Protein level time series, Python packages, Reproducibility tool set, Selection of complemented transgenic lines, TiMet RNA timeseries data, promoter binding affinity calculations on the genome based on PBMs and E...
Data, FMv2 model and simulations for the Chew et al. 2017 paper (bioRxiv https://doi.org/10.1101/105437 ), updated in 2022, mostly on the prr7 prr9 double mutant, with controls in lsf1 and prr7 single mutants. This is one of the outputs from the EU FP7 TiMet project, https://fairdomhub.org/projects/92.
This data archive was updated during submisson to the journal _in Silico _Plants in 2022, and a Snapshot was published. The updates are not changing the core data or the FMv2 model that has been ...
Submitter: Andrew Millar
Studies: Analysis of Framework Model version 2 (FMv2), Construction of Framework Model version 2 (FMv2), Test of FMv2, follow-on: mechanisms of malate/fumarate accumulation, Test of FMv2, photoperiodic flowering and hypocotyl elongation, Test of FMv2, study Gibberellins 1, Test of FMv2, study Laurel & Hardy 1, Test of FMv2, study Laurel & Hardy 2, Test of FMv2, study Laurel & Hardy 3, Tests of FMv2, compilations and figures
Assays: Assimilation and partitioning of 14CO2 at night, Biomass and metabolites, Biomass and metabolites, Biomass and metabolites, Biomass, leaf area and gas exchange data, Biomass, leaf number and metabolites, Circadian period analysis, Composition of FMv2, FMv2 simulation, FMv2 simulation, FMv2 simulation, Mizuno lab, Flowering time in clock mutants, Mizuno lab, Hypocotyl length in clock mutants, Relationship among FMv2 outputs, Sensitivity analysis of FMv2, Simulating clock gene expression with model P2011.1.2, Thiamine vitamers, TiMet WP1.1, Clock gene expression in clock mutants, TiMet WP1.1a Metabolite analysis of clock mutants
The dataset presents mathematical models of the gene regulatory network of the circadian clock, in the plant Arabidopsis thaliana. The work is published in Urquiza-Garcia and Millar, Testing the inferred transcription rates of a dynamic, gene network model in absolute units, In Silico Plants, 2021.
Starting from the P2011 model, this project corrects theoretical issues (EC steady state binding assumption) to form an intermediate model (first version U2017.1; published as U2019.1) model, rescales ...
Project to test effects of temperature cycles on expression of Arabidopsis florigen gene FT, and whether these are mediated by temperature-dependent leaf development or temperature-specific FT expression, or both. Re-used and extended Arabidopsis Framework Model v1 to address this question. Led by Hannah Kinmonth-Schultz in Kim and Imaizumi labs, collaborating with Millar lab.
Submitter: Andrew Millar
Collection of models submitted to PLaSMo by Andrew Millar and automatically transferred to FAIRDOM Hub.
Submitter: BioData SynthSys
Studies: Arabidopsis clock model P2011, graphical diagram - PLM_1045, Arabidopsis clock model P2011.3.1 - PLM_1041, Arabidopsis clock model P2011.4.1 - PLM_1042, Arabidopsis clock model P2011.5.1 - PLM_1043, Arabidopsis clock model P2011.6.1 - PLM_1044, Arabidopsis clock models P2011.1.2 and P2011.2.1 - PLM_71, Arabidopsis_clock_P2011 - PLM_64, Arabidopsis_clock_P2012 - PLM_70, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, At_Pokh2011v6_plasmo_ltdParams.xml - PLM_68, AuxSim - PLM_27, AuxSim full - PLM_30, DomijanTS_AtClock2011 - PLM_50, Locke2005_CircadianClock_tanh - PLM_8, Locke2006_CircadianClock_tanh - PLM_10, OK MEP pathway 2013 - PLM_72, P2012_AJMv2_NoABA - PLM_69, Salazar2009_FloweringPhotoperiod - PLM_9, Sorokina2011_Ostreo_starch - PLM_44, Wilczek photothermal Science - PLM_48
Assays: Arabidopsis clock model P2011, graphical diagram - PLM_1045, version 1, Arabidopsis clock model P2011.1.2 - PLM_71, version 1, Arabidopsis clock model P2011.2.1 - PLM_71, version 2, Arabidopsis clock model P2011.3.1 - PLM_1041, version 1, Arabidopsis clock model P2011.4.1 - PLM_1042, version 1, Arabidopsis clock model P2011.5.1 - PLM_1043, version 1, Arabidopsis clock model P2011.6.1 - PLM_1044, version 1, Arabidopsis_clock_P2011 - PLM_64, version 1, Arabidopsis_clock_P2011 - PLM_64, version 2, Arabidopsis_clock_P2011 - PLM_64, version 3, Arabidopsis_clock_P2011 - PLM_64, version 4, Arabidopsis_clock_P2012 - PLM_70, version 1, Arabidopsis_clock_P2012 - PLM_70, version 2, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 1, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 2, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 3, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 4, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 5, At_Pokh2011_LD_degr_Op1Ap3.xml - PLM_67, version 6, At_Pokh2011v6_plasmo_ltdParams.xml - PLM_68, version 1, AuxSim - PLM_27, version 1, AuxSim full - PLM_30, version 1, DomijanTS_AtClock2011 - PLM_50, version 1, DomijanTS_AtClock2011 - PLM_50, version 2, Locke2005_CircadianClock_tanh - PLM_8, version 1, Locke2006_CircadianClock_tanh - PLM_10, version 1, OK MEP pathway 2013 - PLM_72, version 1, P2012_AJMv2_NoABA - PLM_69, version 1, P2012_AJMv2_NoABA - PLM_69, version 2, Salazar2009_FloweringPhotoperiod - PLM_9, version 1, Salazar2009_FloweringPhotoperiod - PLM_9, version 2, Sorokina2011_Ostreo_starch - PLM_44, version 1, Wilczek photothermal Science - PLM_48, version 1, Wilczek photothermal Science - PLM_48, version 2
Project to test effects of natural compared to growth chamber 16:8 LD cycles, on expression of Arabidopsis flowering-time genes, and to define the genetic mechanisms and environmental triggers involved. Led by Young-Hun Song and Akane Kubota in the Imaizumi lab, with collaborators testing plants in parallel in Zurich and Edinburgh.
Click on Snapshot 2 to download data, models and analysis for Daniel Seaton et al. biorXiv 2017 https://doi.org/10.1101/182071 and Molecular Systems Biology, accepted Jan 2018, https://doi.org/10.15252/msb.20177962. Note that the published paper cannot be fully linked into this record as the DOI above was not live when we made the Research Object from this Investigation on FAIRDOMHub.
Submitter: Andrew Millar
Studies: Modelling and analysis of translational coincidence, Photoperiod-specific proteome data for Arabidopsis, Proteome and translation rate data for the Ostreococcus alga and for cya..., Rhythmic and photoperiod-specific transcriptome datasets for Arabidopsis
Assays: Aryal et al, 2011, metabolic labelling of Cyanothece protein synthesis, Blasing et al, 2005, diurnal microarray in 12L:12D, Estimation of rates of translation and turnover from proteomics datasets, Martin et al, 2012, Ostreococcus N15 labelling proteomics data, Photoperiod proteomics, Stitt lab, TiMet photoperiod microarrays, Translational coincidence model
Data, models and simulations for the Chew et al. 2014 paper (PNAS, https://doi.org/10.1073/pnas.1410238111), using wild-type Arabidopsis ecotype Col-0 in standard 12hL:12hD growth conditions, compared to La(er) or Fei-0 accessions, or to plants overexpressing a micro RNA (miR156).
Submitter: Andrew Millar
Studies: Construction of Framework Model v1, Test of FMv1, growth study of Col-0 accession in 12L:12D, Test of FMv1, growth study of Col-0 accession in 5 photoperiods, Test of FMv1, growth study of other accessions and transgenic line in 12...
Assays: Arabidopsis Framework Model v1, Matlab and Simile version, Gas exchange of Fei-0 and Ler plants in 12hL:12hD, Growth of Col-0 and 35S:miR156 plants in 12hL:12hD, Growth of Col-0 in 12hL:12hD, Growth of Col-0 plants in 5 photoperiods, Growth of Fei-0 and Ler plants in 12hL:12hD