Engineering Genetic Circuits: Modeling and Analysis

Engineering Genetic Circuits: Modeling and Analysis

This course is part of Engineering Genetic Circuits Specialization

Instructors: Chris Myers

What you'll learn

Design and analyze models of genetic circuits.
Simulate genetic circuit models using ODE simulation methods.
Simulate genetic circuit models using stochastic simulation methods.
Utilize genetic technology mappers to select parts for genetic designs.

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Assessments

16 assignments

Taught in English

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This course is part of the Engineering Genetic Circuits Specialization

When you enroll in this course, you'll also be enrolled in this Specialization.

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There are 5 modules in this course

This course gives an introduction to how to create genetic circuit models. These models leverage chemical reactions represented using the Systems Biology Markup Language (SBML). The second module introduces methods to simulate these models using ordinary differential equation (ODE) methods. The third module teach stochastic simulation methods. The fourth module introduces several variations of the stochastic simulation algorithm. Finally, the fifth module introduces genetic technology method that leverage computational analysis for selecting parts and verifying their performance.  

This week will describe the basics of modeling biological systems using chemical reactions, how these models can be represented using the Systems Biology Markup Language (SBML) standard, and how these models can be constructed using software tools such as iBioSim.

What's included

23 videos6 readings2 assignments1 peer review

23 videosTotal 155 minutes

Chemical Reaction Models7 minutesPreview module
Laws of Thermodynamics9 minutes
Law of Mass Action10 minutes
Genetic Circuit Models14 minutes
System Biology Markup Language11 minutes
Overview9 minutes
Project Management 5 minutes
Creating a Model3 minutes
Species6 minutes
Promoters4 minutes
Compartments 0 minutes
Modules7 minutes
Events14 minutes
Event Examples15 minutes
Unit Definitions 2 minutes
Model Editor2 minutes
Constraints, Parameters, and Variables1 minute
Reactions6 minutes
SBML Mathmatical Formulas7 minutes
iBioSim Functions3 minutes
Rules4 minutes
Constraints 1 minute
Model Editor Preferences3 minutes

6 readingsTotal 120 minutes

Engineering Genetic Circuits - Chapter 1 (Section 1.1)10 minutes
Engineering Genetic Circuits - Chapter 1 (Section 1.7.4)10 minutes
SBML Level 3: An Extensible Format for the Exchange and Reuse of Biological Models25 minutes
iBioSim 3: A Tool for Model-Based Genetic Circuit Design25 minutes
iBioSim Tutorial45 minutes
iBioSim Demo Video5 minutes

2 assignmentsTotal 25 minutes

Chemical Reaction Model Basics10 minutes
Genetic Circuit Models Using SMBL15 minutes

1 peer reviewTotal 60 minutes

Genetic Toggle Switch Model60 minutes

This module will introduce the theory and methods for the analysis of genetic circuit models using ordinary differential equations (ODEs). In particular, it will describe the classical chemical kinetic model, numerical methods for ODE simulation of these models, and techniques to analyze these ODE models qualitatively.

What's included

13 videos3 readings3 assignments1 peer review

13 videosTotal 98 minutes

Overview10 minutesPreview module
Classic Chemical Kinetic Model9 minutes
ODE Model Example9 minutes
Differential Equation Simulation2 minutes
Euler's Method12 minutes
Runge-Kutta Method3 minutes
Adaptive Stepsize Control9 minutes
Qualitative ODE Analysis2 minutes
Saddle-Node Example7 minutes
Transcritical Bifurcation Example2 minutes
Pitchfork Bifurcation Example1 minute
Two-Dimentional ODE Model10 minutes
Spatial Methods16 minutes

3 readingsTotal 40 minutes

Engineering Genetic Circuits Chapter 3 (Section 3.1)10 minutes
Engineering Genetic Circuits Chapter 3 (Section 3.2)15 minutes
Engineering Genetic Circuits Chapter 3 (Sections 3.3 and 3.4)15 minutes

3 assignmentsTotal 60 minutes

Chemical Kinetic Models15 minutes
ODE Simulation Methods30 minutes
Qualitative ODE Analysis15 minutes

1 peer reviewTotal 60 minutes

ODE Simulation Using iBioSim60 minutes

This module will introduce stochastic analysis methods for genetic circuits. In particular, it will introduce the stochastic chemical kinetics model, Gillespie's Stochastic Simulation Algorithm (SSA) to analyze these models, and various alternative stochastic analysis methods. Finally, the module will conclude with some additional topics: the Chemical Langevin Equation, stochastic Petri nets, the phage lambda model, and spatial Gillespie methods.

What's included

20 videos4 readings4 assignments1 peer review

20 videosTotal 155 minutes

Introduction5 minutesPreview module
Stochastic Chemical Kinetic Model8 minutes
Biomolecular Reaction Channel14 minutes
Monomolecular Reactions1 minute
Trimolecular Reactions6 minutes
Jump Markov Processes8 minutes
Introduction1 minute
Derivation of Gillespie's Stochastic Simulation Algorithm8 minutes
Implementation of Gillespie's SSA2 minutes
Gillespie's SSA Examples6 minutes
Gillespie's First Reaction Method4 minutes
Gibson/Bruck's Improvements8 minutes
Composition and Rejection8 minutes
Tau Leaping18 minutes
Explicit Tau-Leaping Simulation Algorithm12 minutes
The Chemical Langevin Equation8 minutes
The Reaction Rate Equation8 minutes
Stochastic Petri Nets6 minutes
Phage Lambda Model11 minutes
Spatial Gillespie3 minutes

4 readingsTotal 65 minutes

Engineering Genetic Circuits Chapter 4 (Sections 4.1 and 4.2)15 minutes
Engineering Genetic Circuits Chapter 4 (Section 4.3)15 minutes
Engineering Genetic Circuits Chapter 4 (Sections 4.4 and 4.5)15 minutes
Engineering Genetic Circuits Chapter 4 (Sections 4.6 to 4.9)20 minutes

4 assignmentsTotal 70 minutes

Stochastic Chemical Kinetics10 minutes
Stochastic Simulation Methods30 minutes
Alternative Stochastic Simulation Algorithms15 minutes
Additional Stochastic Simulation Topics15 minutes

1 peer reviewTotal 60 minutes

Stochastic Simulation Using iBioSim60 minutes

This module presents several variations on the SSA algorithm to solve particular analysis problems. In particular, the hierarchical SSA (hSSA) methods enable the analysis of large models, the weighted SSA (wSSA) methods allow for the analysis of rare events, and the incremental SSA (iSSA) methods enable the determination of typical behaviors.

What's included

18 videos4 readings3 assignments

18 videosTotal 79 minutes

Population-Based Models3 minutesPreview module
The Hierarchical Stochastic Simulation Algorithm5 minutes
Hierarchical Simulation Example10 minutes
Runtime Comparison between hSSA and SSA2 minutes
Array Package for Tracking Cellular Populations6 minutes
Population of Repressilator Circuits Using Arrays1 minute
Population of Genetic Toggle Circuits Using Arrays5 minutes
Motivation and Background5 minutes
Important Sampling2 minutes
Underlying Mathematics of the wSSA7 minutes
The weighted stochastic simulation algorithm 3 minutes
Introduction and Motivation2 minutes
Incremental Stochastic Simulation Algorithm4 minutes
Marginal Probability Density Evolution4 minutes
Mean Path3 minutes
Median Path2 minutes
Adaptive Time Step2 minutes
Multiple Paths3 minutes

4 readingsTotal 125 minutes

Hierarchical Stochastic Simulation Algorithm for SBML Models of Genetic Circuits35 minutes
Efficient Analysis of Systems Biology Markup Language Models of Cellular Populations using Arrays30 minutes
An Efficient and Exact Stochastic Simulation Method to Analyze Rare Events in Biochemical Systems30 minutes
Efficient Analysis Methods in Synthetic Biology30 minutes

3 assignmentsTotal 35 minutes

Hierarchical SSA (hSSA)10 minutes
Weighted SSA (wSSA)15 minutes
Incremental SSA (iSSA)10 minutes

This module presents various ways that modeling can be utilized in genetic circuit design to select parts for optimal performance.

What's included

21 videos4 readings4 assignments

21 videosTotal 102 minutes

Introduction3 minutesPreview module
Crosstalk1 minute
Signal Mismatch3 minutes
Roadblocking8 minutes
Genetic Context Effects3 minutes
Automation and Computer Aided Design4 minutes
Library Creation12 minutes
Existing Technology Mapping2 minutes
Overview of Cello6 minutes
Genetic Gate Assignment5 minutes
Impact of Gate Isolation and Gate and Gate Library3 minutes
Cello Circuit Examples6 minutes
Analysis of Circuit Failures8 minutes
Overview of iBioSim's Technology Mapping1 minute
DAG Representation2 minutes
Partitioning and Decomposition2 minutes
Matching and Covering7 minutes
Technology Mapping's Cost2 minutes
Model Generation3 minutes
Rule 30 Example2 minutes
Sequential Genetic Circuits10 minutes

4 readingsTotal 120 minutes

Technology Mapping of Genetic Circuits: From Optimal to Fast Solutions30 minutes
Genetic Circuit Design Automation30 minutes
Directed Acyclic Graph-Based Technology Mapping of Genetic Circuit Models30 minutes
Design of Asynchronous Genetic Circuits30 minutes