Team:ETH Zurich
From 2013.igem.org
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<li><b>From Minesweeper to Colisweeper</b><br>Mines secrete the signaling molecule OHHL whereas non-mines process the signal after diffusion of OHHL. High-pass filters were constructed to control the expression of different orthogonal hydrolases in non-mines, depending on the concentration of the OHHL molecules from the surrounding mines. The constant expression of ''lacZ'' enables the flagging of both mines and non mine colonies. Additionally, the mines express their own hydrolase. | <li><b>From Minesweeper to Colisweeper</b><br>Mines secrete the signaling molecule OHHL whereas non-mines process the signal after diffusion of OHHL. High-pass filters were constructed to control the expression of different orthogonal hydrolases in non-mines, depending on the concentration of the OHHL molecules from the surrounding mines. The constant expression of ''lacZ'' enables the flagging of both mines and non mine colonies. Additionally, the mines express their own hydrolase. | ||
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- | <li><b>The Model</b><br>As our system is based on sensing the OHHL concentration, the diffusion of the signalling molecule in the mine field is a vital part of the model; we carried out simulations to determine time and distance scales. In addition to OHHL diffusion, we modelled synthesis, regulation and degradation reactions of the molecules involved in our genetic circuits. To account for both processes: diffusion and reactions, we developed a spatio-temporal model in two dimensions comprised by three modules: mines, receivers, and the agar plate. To solve the system of partial differential equations we used finite element methods. The information from the model was used to validate and improve our system. | + | <li><b>The Model</b><br>As our system is based on sensing the OHHL concentration, the diffusion of the signalling molecule in the mine field is a vital part of the model; we carried out simulations to determine time and distance scales. In addition to OHHL diffusion, we modelled synthesis, regulation and degradation reactions of the molecules involved in our genetic circuits. To account for both processes: diffusion and reactions, we developed a spatio-temporal model in two dimensions comprised by three modules: mines, receivers, and the agar plate. To solve the system of partial differential equations (PDEs) we used finite element methods. The information from the model was used to validate and improve our system. |
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<li><b>High pass filter</b> | <li><b>High pass filter</b> |
Revision as of 12:41, 3 October 2013