Difference between revisions of "Team:Paris Bettencourt"
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<header><div id=name>iGEM Paris-Bettencourt 2017</div></header> | <header><div id=name>iGEM Paris-Bettencourt 2017</div></header> | ||
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<img src="http://maisonchateauneuf.fr/medusa/images/header-home-animado.gif?crc=3964752341"/> | <img src="http://maisonchateauneuf.fr/medusa/images/header-home-animado.gif?crc=3964752341"/> | ||
<div id=abstract><b>Project Description</b></br></div> | <div id=abstract><b>Project Description</b></br></div> | ||
Revision as of 22:52, 14 September 2017
iGEM Paris-Bettencourt 2017
Project Description
From spider silk to mollusc nacre, living organisms have evolved of a wide variety with astonishing physical properties. The synthesis of biomaterials occurs thanks to a sequence of localized physiological events which have remained difficult to harness artificially.
Our iGEM project aims to engineer E. coli to enable a greater spatial and timing control necessary to
the synthesis of biomaterials. To do so, three research axes will be developed.
The first axis will focus on the synthesis of biomaterials such as biominerals
and biopolymers. The second axis will investigate the use of recently described
RNA scaffolding to optimize the enzymatic catalysis involved in the materials synthesis.
The third axis will develop the optogenetic circuits enabling the light induced
control of our bacteria. In its most advanced state, our technology will enable
us to define the 3D shape and to control the composition (and, hence, the physical
properties) of our biomaterial.
Contact us bettencourt.igem2017@gmail.com
