Liu2012-Hybrid modeling and simulation of stochastic effects on progression through the eukaryotic cell cycle.
Model Identifier
MODEL2004140002
Short description
The eukaryotic cell cycle is regulated by a complicated chemical reaction network. Although many deterministic models have been proposed, stochastic models are desired to capture noise in the cell resulting from low numbers of critical species. However, converting a deterministic model into one that accurately captures stochastic effects can result in a complex model that is hard to build and expensive to simulate. In this paper, we first apply a hybrid (mixed deterministic and stochastic) simulation method to such a stochastic model. With proper partitioning of reactions between deterministic and stochastic simulation methods, the hybrid method generates the same primary characteristics and the same level of noise as Gillespie's stochastic simulation algorithm, but with better efficiency. By studying the results generated by various partitionings of reactions, we developed a new strategy for hybrid stochastic modeling of the cell cycle. The new approach is not limited to using mass-action rate laws. Numerical experiments demonstrate that our approach is consistent with characteristics of noisy cell cycle progression, and yields cell cycle statistics in accord with experimental observations
Format
SBML
(L2V4)
Related Publication
-
Hybrid modeling and simulation of stochastic effects on progression through the eukaryotic cell cycle.
- Liu Z, Pu Y, Li F, Shaffer CA, Hoops S, Tyson JJ, Cao Y
- The Journal of chemical physics , 1/ 2012 , Volume 136 , Issue 3 , pages: 034105 , PubMed ID: 22280742
- Department of Computer Science, Virginia Tech, Blacksburg, Virginia 24061, USA. zhenliu@vt.edu
- The eukaryotic cell cycle is regulated by a complicated chemical reaction network. Although many deterministic models have been proposed, stochastic models are desired to capture noise in the cell resulting from low numbers of critical species. However, converting a deterministic model into one that accurately captures stochastic effects can result in a complex model that is hard to build and expensive to simulate. In this paper, we first apply a hybrid (mixed deterministic and stochastic) simulation method to such a stochastic model. With proper partitioning of reactions between deterministic and stochastic simulation methods, the hybrid method generates the same primary characteristics and the same level of noise as Gillespie's stochastic simulation algorithm, but with better efficiency. By studying the results generated by various partitionings of reactions, we developed a new strategy for hybrid stochastic modeling of the cell cycle. The new approach is not limited to using mass-action rate laws. Numerical experiments demonstrate that our approach is consistent with characteristics of noisy cell cycle progression, and yields cell cycle statistics in accord with experimental observations.
Contributors
Submitter of the first revision: Ahmad Zyoud
Submitter of this revision: Ahmad Zyoud
Modellers: Ahmad Zyoud
Submitter of this revision: Ahmad Zyoud
Modellers: Ahmad Zyoud
Metadata information
isDerivedFrom (6 statements)
hasProperty (3 statements)
occursIn (1 statement)
isDescribedBy (2 statements)
Mathematical Modelling Ontology
Ordinary differential equation model
NCIt Eukaryotic Cell
Gene Ontology cell cycle
Mathematical Modelling Ontology stochastic differential equation model
19246388
NCIt Eukaryotic Cell
Gene Ontology cell cycle
Mathematical Modelling Ontology stochastic differential equation model
19246388
hasProperty (3 statements)
Mathematical Modelling Ontology
Ordinary differential equation model
NCIt Cyclin
Gene Ontology cell cycle
NCIt Cyclin
Gene Ontology cell cycle
occursIn (1 statement)
isDescribedBy (2 statements)
Curation status
Non-curated
Modelling approach(es)
Tags
Connected external resources
SBGN view in Newt Editor
| Name | Description | Size | Actions |
|---|---|---|---|
Model files |
|||
| Liu2012.xml | SBML L2V4 Liu2012-Hybrid modeling and simulation of stochastic effects on progression through the eukaryotic cell cycle-Orignal | 59.04 KB | Preview | Download |
Additional files |
|||
| Liu2012.cps | COPASI version 4.27 (Build 217) Liu2012-Hybrid modeling and simulation of stochastic effects on progression through the eukaryotic cell cycle-Orignal | 127.24 KB | Preview | Download |
- Model originally submitted by : Ahmad Zyoud
- Submitted: Apr 14, 2020 5:25:12 PM
- Last Modified: Apr 14, 2020 5:25:12 PM
Revisions
-
Version: 1
- Submitted on: Apr 14, 2020 5:25:12 PM
- Submitted by: Ahmad Zyoud
- With comment: Import of Liu2012-Hybrid modeling and simulation of stochastic effects on progression through the eukaryotic cell cycle.