Saint Petersburg\Theoretical study

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Revision as of 09:33, 17 July 2007 by Gena (Talk | contribs)

The Tri-stable Toggle Switch project was performed by Brown iGEM2006 team, but we need to adapt this to our needs.


Simple Trigger

The main part of system is simple trigger, containing two repressors and to promotors. Each repressor inhibit another repressor synthesis.

Simple trigger

Concentration of inhibitors x and y describes the next system equations.

Simple trigger equations

Here the constants D, K, n and r are used to describe the promoter strength and inhibition efficiency.

This system can hold state with high concentration of one inhibitor, and low concentraion of another inhibitor. But we need to have only one stable state, another state must be unstable, and exist only in high copper concentrations.

One-stable switch

To design a switch with one stable state we decided to use the constitutive promoter on the one hand of trigger, and copper-dependent promoter on the another hand. So, this lead to such scheme:

Trigger with copper-depended promoter

Concentration of inhibitors x and y describes the next system: Saint-Petersburg Trigger Cu eq.gif

Here the additive "1" in upper equation describes the constitutive promoter. The additive R describes the additional level of expression, depending on the availability of copper.

Now, we can solve this equations and see, how additional expression level alternate the levels of x and y inhibitors.

Saint-Petersburg Trigger Cu graph.gif

Here we can see, that high concentration of inhibitor x, establishes wiry quickly, despite low initial level of x. When we turn on the copper-induced promoter, we can alterate the level of inhibitors y and x, producing the signal.

Now, let's look, what happened, if we alternate the level of activation slowly.

Saint-Petersburg Trigger Cu graph 2.gif

Here we can see the alteration of y concentration, but it happened rather slow. Increasing y concentration limited by increasing R from the copper-depended promoter.

Next time we will try to make the switching faster.


Trigger with Cu-inverter

In this work we tried to use trigger with inverted copper-depended promoter instead of constitutive. So, this lead to such scheme:

Trigger with two copper-depended promoters

Concentration of inhibitors x and y describes the next system: Saint-Petersburg Trigger invCu eq.gif

Here we can see the additive "Rmax - R" instead of 1 (in previous equation system).

Then, we can solve this system under the different R levels Saint-Petersburg Trigger invCu graph.gif

In this scheme the alteration of repressor y level are faster. For my mind, this is enough to construct the fast switch.