|
Course Catalog 2012-2013
SGN-6236 Modeling Techniques for Stochastic Gene Regulatory Networks, 3 cr |
Additional information
The course is lectured every year.
Course webpage: http://www.cs.tut.fi/~sanchesr/SGN-6236/index.htm
Suitable for postgraduate studies
Person responsible
Andre Sanches Ribeiro
Lessons
Study type | P1 | P2 | P3 | P4 | Summer | Implementations | Lecture times and places |
|
|
|
|
|
|
|
|
Requirements
a) Project work (20% of the final grade). b) Exercises(1 per exercises lesson, 40% of the final grade). c) Final exam (40% of the final grade). d) Must attend at least 50% of the lectures and must complete all the three requirements above.
Principles and baselines related to teaching and learning
-
Learning outcomes
From this course the student will know how to do exact stochastic simulations, delayed stochastic simulations, and how to create models of delayed stochastic gene regulatory networks. Students will become familiar with detailed models and experimental results related to single gene expression and its underlying mechanisms. Also, the student will be introduced to basic concepts of cell type and cell differentiation and learn the latest modeling techniques in these topics. After the course, the student will be able to: 1) Identify and define techniques used in modeling gene expression and gene regulatory networks. Demonstrate the accuracy of the models. 2) Interpret data generated from the models, classify strengths and weaknesses of the modeling strategies, summarize results and explain the connection between models and native gene networks. 3) Implement models, apply them to mimic experiments, and calculate statistical features associated to gene expression in cells. Apply the knowledge to construct models of engineered genetic circuits. 4) Analyze results of simulations of models of gene networks. Compare different methodologies for verifying a hypothesis or measuring a variable using such models. 5) Compare and appraise different computational models, and interpret conclusions using different models. 6) Create and develop models of gene networks from experimental data, and use the models to address questions on the dynamics of gene networks and processes regulated by these networks, e.g., cell differentiation.
Content
Content | Core content | Complementary knowledge | Specialist knowledge |
1. | The Stochastic Simulation Algorithm and The Delayed Stochastic Simulation Algorithm | ||
2. | Modeling single gene expression with the delayed Stochastic Simulation Algorithm | ||
3. | A stochastic delayed modeling strategy of Gene Regulatory Networks: models of noisy attractors as cell types, and ergodic sets | ||
4. | Stochastic models of cell differentiation | ||
5. | Examples and applications of the modeling strategies |
Evaluation criteria for the course
Grading is 0 to 5. 2 for exams, 2 for project, 1 for exercises.
Assessment scale:
Numerical evaluation scale (1-5) will be used on the course
Study material
Type | Name | Author | ISBN | URL | Edition, availability, ... | Examination material | Language |
Journal | A General Modeling Strategy for Gene Regulatory Networks with Stochastic Dynamics | Andre S. Ribeiro, R. Zhu, S. A. Kauffman | Andre S. Ribeiro, R. Zhu, S. A. Kauffman, A General Modeling Strategy for Gene Regulatory Networks with Stochastic Dynamics, Journal of Computational Biology, Vol. 13 (9), 1630-1639, 2006. | English | |||
Journal | A general method for numerically simulating the stochastic time evolution of coupled chemical reactions | Gillespie, D. T. | Gillespie, D. T., A general method for numerically simulating the stochastic time evolution of coupled chemical reactions, J. Comput. Phys., 22, 1976, 403-434. | English | |||
Journal | Exact stochastic simulation of coupled chemical reactions | Gillespie, D. T. | Gillespie, D. T., Exact stochastic simulation of coupled chemical reactions, J. Phys. Chem., 81, 1977, 2340-2361 | English | |||
Journal | Modeling and Simulation of Genetic Regulatory Systems: A Literature Review | Hidde de Jong | Hidde de Jong, Modeling and Simulation of Genetic Regulatory Systems: A Literature Review, Journal of Computational Biology. 2002, 9(1): 67-103. | English | |||
Journal | Noisy Attractors and Ergodic Sets in Models of Genetic Regulatory Networks | Andre S. Ribeiro, S. A. Kauffman | Andre S. Ribeiro, S. A. Kauffman, Noisy Attractors and Ergodic Sets in Models of Genetic Regulatory Networks, J. of Theoretical Bio., 247, Issue 4, 2007, Pgs 743-755 | English | |||
Journal | SGNSim a stochastic gene network simulator | Andre S. Ribeiro and Jason Lloyd-Price | Bioinformatics | English | |||
Journal | Studying genetic regulatory networks at the molecular level: Delayed reaction stochastic models | Rui Zhu, Andre S. Ribeiro, Dennis Salahub, and Stuart A. Kauffman | Rui Zhu, Andre S. Ribeiro, Dennis Salahub, and Stuart A. Kauffman, "Studying genetic regulatory networks at the molecular level: Delayed reaction stochastic models", Journal of Theoretical Biology, 246(4):725-45, 2007. | English | |||
Other literature | A Model of Genetic Networks with Delayed Stochastic Dynamics | Andre S. Ribeiro | Andre S. Ribeiro, A Model of Genetic Networks with Delayed Stochastic Dynamics, in Analysis of Microarray Data: Network based Approaches, Wiley, Matthias Dehmer and Frank Emmert-Streib (Editors), 2007. | English |
Prerequisite relations (Requires logging in to POP)
Correspondence of content
Course | Corresponds course | Description |
|
|
More precise information per implementation
Implementation | Description | Methods of instruction | Implementation |
In this course, the student will learn how to perform exact stochastic simulations of chemical reaction systems. This method can be used to model systems ranging from simple bimolecular reaction systems to models of gene expression. Next, the student will learn how to implement delayed stochastic simulations of models of gene expression and gene regulatory networks. Students will become familiar with detailed models and experimental measurements of single gene expression and many underlying regulatory mechanisms of gene expression. Finally, the student will be introduced to the latest modeling strategies of cell differentiation, and transcriptional and translational elongation at the nucleotide and codon levels. |