Team:RHIT/Modeling
From 2012.igem.org
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<p>The team had a collaborative effort with the iGEM team from Norwegian University of Science and Technology (NTNU). Their contribution to the project was the development of a stochastic model of the yeast pheromone response pathway presented in the Kofahl and Klipp’s paper. In particular, the NTNU team was looking at the system’s Ste12 activation response from varying amounts of initial mating factor. Using a paper from <i>Nature</i>, the team discovered that there was a directly proportional relationship between the amount of activated Ste12 and the amount of free Fus3. This allowed for a substantial simplification of the system. The result of their stochastic simulations for 250 micromolar mating factor is shown below:</p> | <p>The team had a collaborative effort with the iGEM team from Norwegian University of Science and Technology (NTNU). Their contribution to the project was the development of a stochastic model of the yeast pheromone response pathway presented in the Kofahl and Klipp’s paper. In particular, the NTNU team was looking at the system’s Ste12 activation response from varying amounts of initial mating factor. Using a paper from <i>Nature</i>, the team discovered that there was a directly proportional relationship between the amount of activated Ste12 and the amount of free Fus3. This allowed for a substantial simplification of the system. The result of their stochastic simulations for 250 micromolar mating factor is shown below:</p> | ||
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<p>This plot shows that a given amount of mating factor will result in a fairly steady amount of activated Ste12. Taking the average of the various values produced by the simulation allowed for the production of a dose-response curve of the system. This curve is shown below:</p> | <p>This plot shows that a given amount of mating factor will result in a fairly steady amount of activated Ste12. Taking the average of the various values produced by the simulation allowed for the production of a dose-response curve of the system. This curve is shown below:</p> | ||
- | image here | + | image here<br /> |
<p>This result is significant because it supports the differential model’s conclusion that for a particular amount of mating factor, a relatively constant level of Ste12 activation is observed. This provided the team with more evidence for the assumption that the original input signal can be treated as a gradually decaying constant.</p> | <p>This result is significant because it supports the differential model’s conclusion that for a particular amount of mating factor, a relatively constant level of Ste12 activation is observed. This provided the team with more evidence for the assumption that the original input signal can be treated as a gradually decaying constant.</p> | ||
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Revision as of 21:22, 1 October 2012