We are modelling ROS management and mitochondrial dysfunction. Mitochondria produce both energy and reactive oxygen species (ROS), and suffer from ROS. Experimental data from University Milan-Bicocca.
Programme: Model repository for M4 (Make Me My Model) clients of ISBE
SEEK ID: https://fairdomhub.org/projects/62
Public web page: Not specified
Organisms: Homo sapiens
FAIRDOM PALs: No PALs for this Project
Project created: 21st Mar 2017
Related items
Projects: SulfoSys, FAIRDOM user meeting, Service to Milano-Bicocca with respect to their ATP-ROS model (Active NOW), Make Me My Model, Service to University of Lisbon (Portugal) with respect to their CFTR maturation model (Active NOW), Service to LCSB (Luxembourg) with respect to ROS management in Parkinson’s disease and cancer model (Active NOW), Service to URV Tarragona, Spain with respect to their Safety Assessment of Endocrine Disrupting Chemicals model (Active NOW), Service to Universidade Católica Portugues with respect to their Molecular Insight into Autism Spectrum Disorder (ASD) model (Active NOW), Service to Slovenia with respect to their Protease signaling network in neurodegeneration model (Active NOW), Service to University of Duisburg- Essen (Germany): with respect to their The Yin-Yang of Metabolism; Endometatoxicity (YYME) model (Active NOW), Service to Sheffield University (UK): with respect to Mitochondrial perfect adaptation model (Active NOW), Service to Sanquin (Amsterdam): with respect to Modelling of acute and chronic inflammation (Prospective), Service to Munich (Germany): with respect toCharged peptide to charged membrane binding model (Prospective), Training Hunfeld, EraCoBiotech 2 nd call proposal preparation, ROS detailed model for MSB manucript, Mechanism based modeling viral disease ( COVID-19 ) dynamics in human population, COVID-19 Disease Map, Modelling COVID-19 epidemics, SNAPPER: Synergistic Neurotoxicology APP for Environmental Regulation
Institutions: University of Amsterdam, VU University Amsterdam, Infrastructure Systems Biology Europe, University of Luxembourg, Luxembourg Centre for Systems Biomedicine (LCSB)
I have modelling expertise in precise kinetic models of metabolism and signal transduction; metabolic control analysis, hierarchical regulation analysis, non-equilibrium dynamics, statistical mechanics, enzyme kinetics, flux balance analysis. Energy and carbohydrate metabolism in Archaea, Bacteria and human; ammonium assimilation in Bacteria; differential network-based drug design; cancer metabolic rewiring; cell cycle; genome wide metabolic map and inborn errors of metabolism; epigenetics.
ISBE-Light provides M4 service (Make Me My Mode) where non modelers can request (assistance with) the making of a computational model of their biological system. These models are deposited here.
Projects: Service to Milano-Bicocca with respect to their ATP-ROS model (Active NOW), Service to University of Lisbon (Portugal) with respect to their CFTR maturation model (Active NOW), Service to LCSB (Luxembourg) with respect to ROS management in Parkinson’s disease and cancer model (Active NOW), Service to URV Tarragona, Spain with respect to their Safety Assessment of Endocrine Disrupting Chemicals model (Active NOW), Service to Universidade Católica Portugues with respect to their Molecular Insight into Autism Spectrum Disorder (ASD) model (Active NOW), Service to Slovenia with respect to their Protease signaling network in neurodegeneration model (Active NOW), Service to University of Duisburg- Essen (Germany): with respect to their The Yin-Yang of Metabolism; Endometatoxicity (YYME) model (Active NOW), Service to Sheffield University (UK): with respect to Mitochondrial perfect adaptation model (Active NOW), Service to Sanquin (Amsterdam): with respect to Modelling of acute and chronic inflammation (Prospective), Service to Munich (Germany): with respect toCharged peptide to charged membrane binding model (Prospective), Training Hunfeld, EraCoBiotech 2 nd call proposal preparation, ROS detailed model for MSB manucript, Mechanism based modeling viral disease ( COVID-19 ) dynamics in human population
Web page: http://www.isbe.nl
Submitter: Alexey Kolodkin
Studies: ROS Models and Data for NPJ Systems Biology and Application (A. Kolodkin...
Assays: Comprehensive model of ROS management, Main Figure 1, Main Figure 2, Main Figure 3, Main Figure 4, Supplementary_Information_Data_Model_Archives
Snapshots: Snapshot 1, Snapshot 2, Snapshot 3, Snapshot 4
Submitter: Alexey Kolodkin
Investigation: ROS networks: designs, aging, Parkinson's disea...
Assays: Comprehensive model of ROS management, Main Figure 1, Main Figure 2, Main Figure 3, Main Figure 4, Supplementary_Information_Data_Model_Archives
Snapshots: No snapshots
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: Homo sapiens
Models: Calibrated comprehensive model of ROS management, Calibrated comprehensive model of ROS managemen..., Detailed model of ROS management
SOPs: No SOPs
Data files: No Data files
Snapshots: No snapshots
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: No organisms
Models: No Models
SOPs: No SOPs
Data files: Main Figure 1
Snapshots: No snapshots
To obtain each of the figure 2A - 2E please download "Main Figure Copasi" and open the sub-directory with the name of the sub-figure, run the Copasi files and the time dependence simulation. This will reproduce the figure in this paper.
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: No organisms
Models: Main Figure 2 COPASI
SOPs: No SOPs
Data files: Main Figure 2 Excel files
Snapshots: No snapshots
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: No organisms
Models: Figure-3_Detailed Model Diagram
SOPs: No SOPs
Data files: No Data files
Snapshots: No snapshots
To obtain each of the figure 4A - 4D please download "Main Figure 4 Copasi" and open the sub-directory with the name of the sub-figure, run the Copasi files and the time dependence simulation. This will reproduce the figure in this paper.
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: No organisms
Models: Main Figure 4 Models_Copasi
SOPs: No SOPs
Data files: Data-Model_Menadione, Data_Models_ATP_mRNA
Snapshots: No snapshots
Submitter: Alexey Kolodkin
Biological problem addressed: Model Analysis Type
Investigation: ROS networks: designs, aging, Parkinson's disea...
Organisms: No organisms
Models: No Models
SOPs: No SOPs
Data files: Section B2A, Section A, Section B1, Section B2B, Section B3, Section B4, Section B5, Section C, Section D, Section E, Section F, Section G, Section H, Section I
Snapshots: No snapshots
RUN the model for steady state.
For the Menadione experiment set the initial concentration of 'Menadione' species to experimental dosing i.e. 100 000 nM (0.1 mM) and make the simulation type "reaction" for both the species i.e. 'Menadione' and 'Menadione_internal'. Then run for 24 hr i.e. 1500 minutes approx. Plot e.g. ATP.
For H2O2 experimental data validation for repeated treatment at 50uM, 150uM, and 300uM. To run the model with different dosing scenarios, one has to set both the H2O2 initial ...
Creators: Alexey Kolodkin, Hans V. Westerhoff, Raju Prasad Sharma
Submitter: Alexey Kolodkin
Model type: Ordinary differential equations (ODE)
Model format: Copasi
Environment: Copasi
This is a model about a ROS network that exhibits five design principles, and has been calibrated so as to predict quantitatively various steady state concentrations. 10191125.
Instructions RUN the model for steady state. For the Menadione experiment set the initial concentration of 'Menadione' species to experimental dosing i.e. 100 000 nM (0.1 mM) and make the simulation type "reaction" for both the species i.e. 'Menadione' and 'Menadione_internal'. Then run for 24 hr i.e. 1500 minutes approx. ...
Creators: Alexey Kolodkin, Hans V. Westerhoff, Raju Prasad Sharma
Submitter: Alexey Kolodkin
Model type: Ordinary differential equations (ODE)
Model format: Copasi
Environment: Copasi
Organism: Not specified
Investigations: ROS networks: designs, aging, Parkinson's disea...