With this file the user can type
docker-compose up
and will be able to run the operating system were the modelling and analysis took place
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Created: 20th Oct 2024 at 18:06
Last updated: 19th Dec 2024 at 11:29
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Version 1 (earliest) Created 20th Oct 2024 at 18:06 by Uriel Urquiza Garcia
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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
Andrew Millar's research group, University of Edinburgh
Programme: SynthSys
Public web page: http://www.amillar.org
Organisms: Escherichia coli, Arabidopsis thaliana, Ostreococcus tauri
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...
Snapshots: Snapshot 1
Submitter: Andrew Millar
Investigation: Absolute units for proteins in Arabidopsis cloc...
Assays: Propagating scaling factors into model parameters for U2019.4->U2019.5 a..., Reproducibility tool set
Snapshots: No snapshots
This section contains the links to the tools used for reproducing the computational results presented in Urquiza-Garcia et al. 2022. This is required in particular because the SloppyCell model optimisation software is at some risk. Using Docker we can assure persistence for the computational environment that allows you to run SloppyCell.
The associated git repository can be found in https://hub.docker.com/r/uurquiza/urquiza2019a_tellurium_sloppycell/tags which can be cloned.
The docker image can ...
Submitter: Andrew Millar
Biological problem addressed: Model Analysis Type
Investigation: Absolute units for proteins in Arabidopsis cloc...
Organisms: No organisms
Models: No Models
SOPs: No SOPs
Data files: No Data files
Snapshots: No snapshots