Team:Manchester/Modelling

From 2013.igem.org

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   <b><u>Key Achievements</u></b><br>
   <b><u>Key Achievements</u></b><br>
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<li>Produced the first kinetic model of the fatty acid biosynthesis pathway using uncertainty modelling in order to represent the fatty acid production in our system: E.c(oil)i and identify areas of the pathway requiring further study in the lab</li>
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<li>Produced the first kinetic model of the fatty acid biosynthesis pathway using uncertainty modelling</li>
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<li>Used a molecular dynamics simulation to determine the optimal location for His-tag addition onto FabA</li>
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<li>Used molecular dynamics simulations to determine the optimal location for His-tag addition onto FabA</li>
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<li>Modelled the Population dynamics of the sumatran orangutan to examine the effect of our project on the endangered species</li>
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<li>Modelled the population dynamics of the sumatran orangutan to examine the effect of our project on the endangered species</li>
<li>Generated a repository of modelling tutorials in collaboration with other UK iGEM teams</li>
<li>Generated a repository of modelling tutorials in collaboration with other UK iGEM teams</li>

Latest revision as of 18:19, 27 October 2013

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Key Achievements
  • Produced the first kinetic model of the fatty acid biosynthesis pathway using uncertainty modelling
  • Used molecular dynamics simulations to determine the optimal location for His-tag addition onto FabA
  • Modelled the population dynamics of the sumatran orangutan to examine the effect of our project on the endangered species
  • Generated a repository of modelling tutorials in collaboration with other UK iGEM teams
  • Enzymes in the FAB pathway showed a lack of experimentally determined kinetic parameters. To account for this, we used probability distributions for each individual parameter defined with respect to the uncertainty of the value. We were then able to generate not one but a series of unbiased models to illustrate the FAB pathway. We believe that this innovative approach to modelling appropriately addresses uncertainties in biology and is important for use in future computational investigations.

    Trying to experimentally study the overexpression of some enzymes involved in palm oil synthesis, as predicted by our “system” level model isn’t easy, particularly when they are involved in cyclic reactions (eg FAB pathway). Our strategy was to simply add a His-tag to the N- and C-terminus of βHACdH, but to make it even more complex βHACdH is a homodimer. Therefore, we did another model but this time of the molecular dynamics kind to see which terminal, if any, would be best to add the His-tags to.

    As part of our Human Practices investigations, we created a series of in depth population dynamics models to show the impact that the palm oil industry has on the population of the Sumatran Orangutan. We were then able to project this into the future to demonstrate a series of likely scenarios. Sadly, things are looking pretty bleak for the Orangutan - however, it appears there could be a way to save them...

    Here at Manchester iGEM team, we believe that modelling is a vital step in the production of any synthetic biology system. However, often the production of such models can be hindered or left out altogether due to lack of expertise and outside help. With this in mind, we enlisted the help of another two UK iGEM teams in a quest to educate the iGEM community about the software available to them.