Team:Evry/Achievements

From 2012.igem.org

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-We provided 3 new plasmids for using this method, which include debugging tools</p><br>
-We provided 3 new plasmids for using this method, which include debugging tools</p><br>
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-We designed a multicellular hormonal system<br>
-We designed a multicellular hormonal system<br>
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-We showed the first Synthetic ecosystem, with a unicellular chassis (<i>E.coli</i>) inside a multicellular chassis (<i>Xenopus</i>)</p><br>
-We showed the first Synthetic ecosystem, with a unicellular chassis (<i>E.coli</i>) inside a multicellular chassis (<i>Xenopus</i>)</p><br>
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-We designed a new biobrick standard which allows one-shot coding device assembly, while still being compatible with the RFC10 standard</p> <br>
-We designed a new biobrick standard which allows one-shot coding device assembly, while still being compatible with the RFC10 standard</p> <br>
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-We modelled a whole multicellular system using an integrated multilayered model</p><br>
-We modelled a whole multicellular system using an integrated multilayered model</p><br>
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-We submitted an extensive report of our conclusions about synthetic biology in vertebrates, which is the fruit of our long reflection we conducted over the summer.</p> <br>
-We submitted an extensive report of our conclusions about synthetic biology in vertebrates, which is the fruit of our long reflection we conducted over the summer.</p> <br>

Revision as of 01:16, 27 September 2012

iGEM Evry 2012 achievements


Asides from having lots of fun, meeting great people, gathering around cheese and wine and lazying around the Genopole gardens during lunch break, we also did a little bit of work. Here is a list of our achievements:



-We brought a new multicellular chassis to iGEM
-We submitted 28 biobricks to the registry, including the first working Xenopus biobricks
-We characterized 12 Biobricks:
BBa_K812000,
BBa_K812050,
BBa_K812010,
BBa_K812030,
BBa_K81203,
BBa_K812032,
BBa_K812110,
BBa_K812130,
BBa_K812132,
BBa_K812133,
BBa_K812200,
BBa_K812233.

-We designed a method for testing multicellular systems in Xenopus rapidly
-We provided 3 new plasmids for using this method, which include debugging tools


-We designed a multicellular hormonal system
-We improved the Auxin production device for use in eukaryotes
-We submitted the Tir1 auxin detection device to the registry
-We showed the first Synthetic ecosystem, with a unicellular chassis (E.coli) inside a multicellular chassis (Xenopus)


-We designed a new biobrick standard which allows one-shot coding device assembly, while still being compatible with the RFC10 standard


-We modelled a whole multicellular system using an integrated multilayered model


-We submitted an extensive report of our conclusions about synthetic biology in vertebrates, which is the fruit of our long reflection we conducted over the summer.