Team:Imperial College/Genetic Circuit Details
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{{Imperial/StartPage2}} | {{Imperial/StartPage2}} | ||
- | {{Imperial/Box1|Simple Model ({{ref|1}}) | | + | {{Imperial/Box1|Simple Model ({{ref|1}})| |
- | ====Equilibria==== | + | [[Image:Igem2008_-_inducible_promoters.jpg|450px]] |
+ | ====== 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. | Interactions between IPTG, LacI and free promoter and the formation of the promoter-LacI and IPTG-LacI complexes are described using the following equilibria. | ||
- | [[Image:Simple_model_equilibria.jpg| | + | [[Image:Simple_model_equilibria.jpg|350px]] |
Note: 1:1 stoichiometry has been assumed; this model could be adapted to use different stoichiometric coefficients. | Note: 1:1 stoichiometry has been assumed; this model could be adapted to use different stoichiometric coefficients. | ||
- | k<sub>2</sub>, | + | k<sub>2</sub>, k<sub>3</sub>, k<sub>4</sub> and k<sub>5</sub> represent binding constants for formation and dissociation of complexes. |
- | ====Equations==== | + | ====== Equations ====== |
Before IPTG is introduced the system is at steady-state. The steady-state levels of LacI, free promoter, and GFP are given by: | Before IPTG is introduced the system is at steady-state. The steady-state levels of LacI, free promoter, and GFP are given by: | ||
[[Image:Simple_model_steady_state_pre_induction.jpg|300px]] | [[Image:Simple_model_steady_state_pre_induction.jpg|300px]] | ||
- | Note: | + | Note: k<sub>1</sub> and k<sub>8</sub> represent the rate of transcription through the constitutive promoter upstream of LacI and the promoter upstream of GFP respectively. |
- | + | d<sub>1</sub> and d<sub>GFP</sub> represent the degradation rates of LacI and GFP respectively. | |
- | + | k<sub>ß</sub> is defined as k<sub>4</sub>/k<sub>5</sub>. | |
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: | ||
- | [[Image:Simple_model_ODEs.jpg| | + | [[Image:Simple_model_ODEs.jpg|700px]] |
These are evaluated numerically using Matlab's ODE solver. | These are evaluated numerically using Matlab's ODE solver. | ||
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}} | }} | ||
- | {{Imperial/Box1|More Sophisticated Model({{ref|2}})| | + | {{Imperial/Box1|More Sophisticated Model ({{ref|2}})| |
- | ====Equilibria==== | + | [[Image:Inducible_promoters_2.jpg|450px]] |
- | [[Image:Complex_model_equilibria.jpg| | + | ====== Equilibria ====== |
+ | [[Image:Complex_model_equilibria.jpg|350px]] | ||
Assumptions: | Assumptions: | ||
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We assumed 2 LacI molecules bind to the promoter, in accordance with the model description ({{ref|2}}). | We assumed 2 LacI molecules bind to the promoter, in accordance with the model description ({{ref|2}}). | ||
- | Note: | + | Note: k<sub>2</sub>, k<sub>3</sub>, k<sub>4</sub>, k<sub>5</sub>, k<sub>6</sub> and k<sub>7</sub> represent binding constants for formation and dissociation of complexes. |
- | ====Equations==== | + | ====== Equations ====== |
Before IPTG is introduced the system is in a steady state: | Before IPTG is introduced the system is in a steady state: | ||
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[[Image:Pre_IPTG_Steady_States_Complex_Model.jpg|400px]] | [[Image:Pre_IPTG_Steady_States_Complex_Model.jpg|400px]] | ||
- | Note: | + | Note: k<sub>1</sub> and k<sub>8</sub> represent the rate of transcription through the constitutive promoter upstream of LacI and the promoter upstream of GFP respectively. |
- | + | d<sub>1</sub> and d<sub>GFP</sub> represent the degradation rates of LacI and GFP respectively. | |
- | + | k<sub>ß</sub> is defined as k<sub>4</sub>/k<sub>5</sub>. | |
When IPTG is introduced, the dynamic behaviour of the system is described using a system of ODEs. | When IPTG is introduced, the dynamic behaviour of the system is described using a system of ODEs. | ||
- | [[Image:Complex_Model_ODEs.jpg| | + | [[Image:Complex_Model_ODEs.jpg|750px]] |
These are evaluated numerically using Matlab's ODE solver. | These are evaluated numerically using Matlab's ODE solver. | ||
- | ====Qualitative effect of parameters on behaviour==== | + | ====== Qualitative effect of parameters on behaviour ====== |
Two different regimes of behaviour can be exhibited by the concentration of GFP over time as described by the more complex model, dependent on the parameters defining the ODE system. | Two different regimes of behaviour can be exhibited by the concentration of GFP over time as described by the more complex model, dependent on the parameters defining the ODE system. | ||
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{{Imperial/Box2|| | {{Imperial/Box2|| | ||
===== References ===== | ===== References ===== | ||
- | |||
#{{FormatRef|Alon, U|2006|An Introduction to Systems Biology: Design Principles of Biological Circuits|||Chapman & Hall/Crc Mathematical and Computational Biology}} | #{{FormatRef|Alon, U|2006|An Introduction to Systems Biology: Design Principles of Biological Circuits|||Chapman & Hall/Crc Mathematical and Computational Biology}} | ||
+ | #{{FormatRef|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|}} | ||
|}} | |}} | ||
{{Imperial/EndPage|Genetic_Circuit|Genetic_Circuit}} | {{Imperial/EndPage|Genetic_Circuit|Genetic_Circuit}} |
Latest revision as of 02:50, 30 October 2008
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