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Team:Grenoble/Modeling/Amplification
From 2012.igem.org
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In this part we will model the amplification module. Our work in this module is subdivided in three main parts: a deterministic model of the reactions at the local scale, another version of the former taking into account random noise and perturbations, and a model including diffusion in space and time. | In this part we will model the amplification module. Our work in this module is subdivided in three main parts: a deterministic model of the reactions at the local scale, another version of the former taking into account random noise and perturbations, and a model including diffusion in space and time. | ||
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<h1> Overview</h1> | <h1> Overview</h1> | ||
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<span style="text-decoration:underline;">Remark:</span> | <span style="text-decoration:underline;">Remark:</span> | ||
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The protein GFP is a reporter protein for adenylate cyclase. Thus, in the development, gfp will be omitted, and we will consider that the adenylate cyclase gives us the signal. | The protein GFP is a reporter protein for adenylate cyclase. Thus, in the development, gfp will be omitted, and we will consider that the adenylate cyclase gives us the signal. | ||
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<b>Why an amplification module?</b> | <b>Why an amplification module?</b> | ||
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| - | + | How to do this? | |
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| - | First, we | + | First, we chose a molecule, which is produced by bacteria and diffuses from bacteria to the other bacterium. We chose cyclic AMP, whose production is catalyzed by the adenylate cyclase. Thus, we designed: |
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Latest revision as of 02:57, 27 September 2012
Amplification module
In this part we will model the amplification module. Our work in this module is subdivided in three main parts: a deterministic model of the reactions at the local scale, another version of the former taking into account random noise and perturbations, and a model including diffusion in space and time. In the deterministic model, we determine the sensitivity of our system and we link it to the signaling module. Then, in the diffusion part we check if our system has a fast answer. Eventually, in the random perturbations model, we check that it is robust to perturbations.Overview
Remark: When our biosensor detects a dipeptide specific to a pathogen,the bacterium activates the production of a green fluorescent protein (GFP). In our system the production of GFP begins when the production of an other protein, the adenylate cyclase (Ca) begins. Indeed, they are under the control of the same promotor, paraBAD (pBad), and thus they have exatly the same behavior:
