This repository contains the current consensus genome-scale metabolic model of Saccharomyces cerevisiae. It is the continuation of the legacy project yeastnet. For the latest release please click here.
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If you use yeast-GEM please cite the yeast8 paper:
Lu, H. et al. A consensus S. cerevisiae metabolic model Yeast8 and its ecosystem for comprehensively probing cellular metabolism. Nature Communications 10, 3586 (2019). doi:10.1038/s41467-019-11581-3
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Additionally, all yeast-GEM releases are archived in Zenodo, for you to cite the specific version of yeast-GEM that you used in your study, to ensure reproducibility. You should always cite the original publication + the specific version, for instance:
The yeast consensus genome-scale model [Lu et al. 2019], version 8.3.4 [Sánchez et al. 2019], was used.
Find the citation details for your specific version here.
Utilisation: experimental data reconstruction; multi-omics integrative analysis; in silico strain design; model template
Field: metabolic-network reconstruction
Type of model: reconstruction; curated
Model source: YeastMetabolicNetwork
Omic source: genomics; metabolomics
Taxonomic name: Saccharomyces cerevisiae
Taxonomy ID: taxonomy:559292
Genome ID: insdc.gca:GCA_000146045.2
Metabolic system: general metabolism
Strain: S288C
Condition: aerobic, glucose-limited, defined media
Taxonomy | Latest update | Version | Reactions | Metabolites | Genes |
---|---|---|---|---|---|
Saccharomyces cerevisiae | 05-Sep-2022 | 8.6.2 | 4063 | 2744 | 1160 |
- Accuracy: 0.881
- True non-essential genes: 926
- True essential genes: 63
- False non-essential genes: 96
- False essential genes: 38
- Correlation coefficient R2: 0.865
You can obtained the model by any of the following methods:
- If you have a Git client installed on your computer, you can clone the
main
branch of the yeast-GEM repository. - You can directly download the latest release as a ZIP file.
- If you want to contribute to the development of yeast-GEM (see below), it is best to fork the yeast-GEM repository to your own Github account.
If you want to use the model for your own model simulations, you can use any software that accepts SBML L3V1 FBCv3 formatted model files. This includes any of the following:
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MATLAB-based
- RAVEN Toolbox version 2.7.1 or later (recommended)
- COBRA Toolbox
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Python-based
Please see the installation instructions for each software package.
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MATLAB-based
If you want to contribute to the development of yeast-GEM, or otherwise want to run any of the provided MATLAB functions, then the following software is required:- RAVEN Toolbox version 2.7.1 or later
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Python-based
Contribution via python (cobrapy) is not yet functional. In essence, if you can retain the same format of the model files, you can still contribute to the development of yeast-GEM. However, you cannot use the MATLAB functions.If you want to use any of the provided Python functions, you may create an environment with all requirements:
pip install -r code/requirements/requirements.txt # installs all dependencies touch .env # creates a .env file for locating the root
If you want to locally run memote run
or memote report history
, you should also install git lfs, as results.db
(the database that stores all memote results) is tracked with git lfs.
Make sure to load/save the model with the corresponding wrapper functions
- In Matlab:
cd ./code model = loadYeastModel(); % loading saveYeastModel(model); % saving
- If RAVEN is not installed, you can also use COBRA-native functions (
readCbModel
,writeCbModel
), but these model-files cannot be committed back to the GitHub repository.
- If RAVEN is not installed, you can also use COBRA-native functions (
- In Python:
import code.io as io model = io.read_yeast_model() # loading io.write_yeast_model(model) # saving
- You can visualize selected pathways of yeast-GEM and perform online constraint-based simulations using Caffeine, by creating a simulation with the latest yeast-GEM version available, and choosing any S. cerevisiae map (currently only
iMM904
maps are available). Learn more about Caffeine. - Additionally, you can interactively navigate model components and visualize 3D representations of all compartments and subsystems of yeast-GEM at Metabolic Atlas. Learn more about Metabolic Atlas.
Contributions are always welcome! Please read the contributions guideline to get started.
Code contributors are reported automatically by GitHub under Contributors, while other contributions come in as Issues.