Team:Imperial College/Genetic Circuit Details

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To describe the change in concentration of the interacting species over time we used the following system of differential equations:
To describe the change in concentration of the interacting species over time we used the following system of differential equations:
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[[Image:Simple_model_ODEs.jpg|500px]]

Revision as of 00:11, 29 October 2008


Simple Model (1)

Equilibria

Interactions between IPTG, LacI and free promoter and the formation of the promoter-LacI and IPTG-LacI complexes are described using the following equilibria.

Simple model equilibria.jpg

Note: 1:1 stoichiometry has been assumed; this model could be adapted to use different stoichiometric coefficients.

k2, k3, k4 and k5 represent binding constants for formation and dissociation of complexes.

Equations

Before IPTG is introduced the system is at steady-state. The steady-state levels of LacI, free promoter, and GFP are given by:

Simple model steady state pre induction.jpg

Note: k1 and k8 represent the rate of transcription through the constitutive promoter upstream of LacI and the promoter upstream of GFP respectively.

d1 and dGFP represent the degradation rates of LacI and GFP respectively.

k_beta is defined as k4/k5.

To describe the change in concentration of the interacting species over time we used the following system of differential equations:

Simple model ODEs.jpg



More Sophisticated Model(2)

Equilibria

Assumptions:

No intermediary P-IPTG-LacI complex is formed.

We assumed 2 LacI molecules bind to the promoter.

Equations

Qualitative effect of parameters on behaviour


References
  1. Kuhlman T, Zhang Z, Saier MH Jr, & Hwa T (2007) Combinatorial transcriptional control of the lactose operon of Escherichia coli. - PNAS 104 (14) 6043-6048
  2. Alon, U (2006) An Introduction to Systems Biology: Design Principles of Biological Circuits - Chapman & Hall/Crc Mathematical and Computational Biology