Presentation is loading. Please wait.

Presentation is loading. Please wait.

Modeling the Cell Cycle with JigCell and DARPA’s BioSPICE Software Departments of Computer Science* and Biology +, Virginia Tech Blacksburg, VA 24061 Faculty:

Published byCollin Lawrence Modified over 9 years ago

Similar presentations

Presentation on theme: "Modeling the Cell Cycle with JigCell and DARPA’s BioSPICE Software Departments of Computer Science* and Biology +, Virginia Tech Blacksburg, VA 24061 Faculty:"— Presentation transcript:

1 Modeling the Cell Cycle with JigCell and DARPA’s BioSPICE Software Departments of Computer Science* and Biology +, Virginia Tech Blacksburg, VA 24061 Faculty: Kathy Chen + Cliff Shaffer * John Tyson + Layne Watson * Students: Nick Allen * Emery Conrad + Ranjit Randhawa * Marc Vass * Jason Zwolak *

2 The Fundamental Goal of Molecular Cell Biology

3 Application: Cell Cycle Modeling How do cells convert genes into behavior? Create proteins from genes Protein interactions Protein effects on the cell Our study organism is the cell cycle of the budding yeast Saccharomyces cerevisiae.

4

5 mitosis (M phase) DNA replication (S phase) cell division G1 G2

6 Modeling Techniques We use ODEs that describe the rate at which each protein concentration changes Protein A degrades protein B: … with initial condition [A](0) = A 0. Parameter c determines the rate of degradation.

7 Modeling Lifecycle Data Notebook Wiring Diagram Differential Equations Parameter Values AnalysisSimulation Comparator Data Notebook ExperimentalDatabases

8 Tyson’s Budding Yeast Model Tyson’s model contains over 30 ODEs, some nonlinear. Events can cause concentrations to be reset. About 140 rate constant parameters Most are unavailable from experiment and must set by the modeler “Parameter twiddling” Far better is automated parameter estimation

9 JigCell Current Primary Software Components: JigCell Model Builder JigCell Run Manager JigCell Comparator Automated Parameter Estimation (PET) Bifurcation Analysis (Oscill8) http://jigcell.biol.vt.edu

10 JigCell Model Builder (Frogegg model)

11 Mutations Wild type cell Mutations Typically caused by gene knockout Consider a mutant with no B to degrade A. Set c = 0 We have about 130 mutations each requires a separate simulation run

12 JigCell Run Manager

13 Phenotypes Each mutant has some observed outcome (“experimental” data). Generally qualitative. Cell lived Cell died in G1 phase Model should match the experimental data. Model should not be overly sensitive to the rate constants. Overly sensitive biological systems tend not to survive

14 Comparator

15 BioSPICE DARPA project Approximately 15 groups Many (not all) active systems biology modelers and software developers represented An explicit integration team Goal: Define mechanisms for interoperability of software tools, build an expandable problem solving environment for systems biology Result: software tools contributed by the community to the community

16 Tools Specifications for defining models (SBML) Standards for data representation, APIs Simulators (equation solvers; stochastic) Automated parameter estimation Analysis tools (plotters, bifurcation analysis, flux balance, etc.) Database support for simulations (data mining)

Download ppt "Modeling the Cell Cycle with JigCell and DARPA’s BioSPICE Software Departments of Computer Science* and Biology +, Virginia Tech Blacksburg, VA 24061 Faculty:"

Similar presentations

1 BASIS is a GRID pilot project to provide a tool for the quantitative study of the biology of ageing (MRC, BBSRC and the DTI) Virtual ageing cell ~200.

1 BASIS is a GRID pilot project to provide a tool for the quantitative study of the biology of ageing (MRC, BBSRC and the DTI) Virtual ageing cell ~200.
Modeling the Cell Cycle Engine of Eukaryotes

Modeling the Cell Cycle Engine of Eukaryotes
Béla Novák Molecular Network Dynamics Research Group Hungarian Academy of Sciences and Budapest University of Technology and Economics Béla Novák Molecular.

Béla Novák Molecular Network Dynamics Research Group Hungarian Academy of Sciences and Budapest University of Technology and Economics Béla Novák Molecular.
Network Dynamics and Cell Physiology John J. Tyson Dept. Biological Sciences Virginia Tech.

Network Dynamics and Cell Physiology John J. Tyson Dept. Biological Sciences Virginia Tech.
John J. Tyson Biological Sciences, Virginia Tech

John J. Tyson Biological Sciences, Virginia Tech
Cell and Molecular Biology Behrouz Mahmoudi Cell cycle 1.

Cell and Molecular Biology Behrouz Mahmoudi Cell cycle 1.
Béla Novák Molecular Network Dynamics Research Group Budapest University of Technology and Economics and Hungarian Academy of Sciences John J. Tyson Department.

Béla Novák Molecular Network Dynamics Research Group Budapest University of Technology and Economics and Hungarian Academy of Sciences John J. Tyson Department.
Computational Modeling of the Cell Cycle

Computational Modeling of the Cell Cycle
Analysis of Yeast Mutants to Test a Mathematical Model of the Cell Cycle Neil R. Adames 1, Logan Schuck 1, Kathy Chen 2, John J. Tyson 2, and Jean Peccoud.

Analysis of Yeast Mutants to Test a Mathematical Model of the Cell Cycle Neil R. Adames 1, Logan Schuck 1, Kathy Chen 2, John J. Tyson 2, and Jean Peccoud.
Deterministic Global Parameter Estimation for a Budding Yeast Model T.D Panning*, L.T. Watson*, N.A. Allen*, C.A. Shaffer*, and J.J Tyson + Departments.

Deterministic Global Parameter Estimation for a Budding Yeast Model T.D Panning*, L.T. Watson*, N.A. Allen*, C.A. Shaffer*, and J.J Tyson + Departments.
Åbo Akademi University & TUCS, Turku, Finland Ion PETRE Andrzej MIZERA COPASI Complex Pathway Simulator.

Åbo Akademi University & TUCS, Turku, Finland Ion PETRE Andrzej MIZERA COPASI Complex Pathway Simulator.
Killer Yeast vs. Sensitive Yeast Data from experiments in a chemostat undertaken by Nick McClure, a former PhD student in the department Killer yeasts.

Killer Yeast vs. Sensitive Yeast Data from experiments in a chemostat undertaken by Nick McClure, a former PhD student in the department Killer yeasts.
Introduction to yeast genetics Michelle Attner July 24, 2012.

Introduction to yeast genetics Michelle Attner July 24, 2012.
DARPA BioComp PI Meeting, 2001 “The Eukaryotic Cell Cycle as a Test Case for Modeling Cellular Regulation in a Collaborative Problem Solving Environment”

DARPA BioComp PI Meeting, 2001 “The Eukaryotic Cell Cycle as a Test Case for Modeling Cellular Regulation in a Collaborative Problem Solving Environment”
1 Bioinformatics in the Department of Computer Science Lenwood S. Heath Department of Computer Science Blacksburg, VA 24061 College of Engineering Northern.

1 Bioinformatics in the Department of Computer Science Lenwood S. Heath Department of Computer Science Blacksburg, VA College of Engineering Northern.
Computational Biology, Part 19 Cell Simulation: Virtual Cell Robert F. Murphy, Shann-Ching Chen, Justin Newberg Copyright  2004-2009. All rights reserved.

Computational Biology, Part 19 Cell Simulation: Virtual Cell Robert F. Murphy, Shann-Ching Chen, Justin Newberg Copyright  All rights reserved.
Welcome To Math 463: Introduction to Mathematical Biology

Welcome To Math 463: Introduction to Mathematical Biology
Mathematical Modelling of Phage Dynamics: Applications in STEC studies Tom Evans.

Mathematical Modelling of Phage Dynamics: Applications in STEC studies Tom Evans.
The JigCell Problem Solving Environment (PSE) Marc Vass and Nick Allen Department of Computer Science Virginia Tech.

The JigCell Problem Solving Environment (PSE) Marc Vass and Nick Allen Department of Computer Science Virginia Tech.
Cell cycles and clocking mechanisms in systems biology ESE 680 – 003 : Systems Biology Spring 2007.

Cell cycles and clocking mechanisms in systems biology ESE 680 – 003 : Systems Biology Spring 2007.

Similar presentations

Ads by Google