Difference between revisions of "Team:Peking"

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                                    <div class="texttitle">HOME</div>
                            <div class="texttitle">Overall design
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                                    <p class="lead add-bottom" style="color:#5E5656">The problem of uranium contamination is a source of great concern. Uranium could have severe detrimental health effects (it is particularly harmful to the liver, kidney and bone) and lead to environment issues (chemical and radioactive hazards). <a href="https://2016.igem.org/Team:Peking/HP/311">Current treatment options</a> available for uranium leaks in nuclear power plants or uranium pollution around ore-fields, such as ion exchange, flocculation-setting and phytoremediation, all have limitations including their high cost, low efficiency and the sheer complexity of the involved procedures.</p>
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                                    <p class="lead add-bottom" style="color:#5E5656">To address these problems, Peking iGEM team aims to construct <a href="https://2016.igem.org/Team:Peking/Description">a novel functional biomaterial</a> consisting of multiple functional protein modules. This material is designed to be produced and secreted by bacteria, and self-assembled to form a polymer network. In combination with a specific <a href="https://2016.igem.org/Team:Peking/Uranyl-adsorption">Super Uranyl-binding Protein</a>, it obtains the ability to adsorb uranyl ions. After very short contacting with polluted water, the uranyl-laden biomaterial, which also contains a <a href="https://2016.igem.org/Team:Peking/Clearance">monomeric streptavidin module</a>, could be easily cleared using biotinylated magnetic beads.
 
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                                    <p class="lead add-bottom" style="color:#5E5656">This uranyl-binding biomaterial shows a series of advantages, such as high specificity, high efficiency, self-assembly and renewability. Furthermore, the uranyl-binding module could be replaced or combined with modules that are capable of binding other heavy metal ions, as well as fluorescent proteins, obtaining <a href="https://2016.igem.org/Team:Peking/Proof">multi-functionality</a>. By taking advantage of modularization in the design, additional applications beyond uranium adsorption could be developed based on this material in the future.</p>
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                                    <p>Then we put forward two questions: Why phase separation in cells can produce membraneless organelles? And how can we design our system to fulfill its intended functions?
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Like oil in water, the contents of cells can separate into droplets. According to physical principles, the process where material self-assemble into organelles is described as ‘phase separation’, which is the conversion of a single-phase system into a multiphase system. In general, materials flow to regions with low chemical potential instead of low concentration. Finally, the components no longer distribute uniformly but form granules locally which are organelles in the cell.
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That is to say, the main work to synthesize an organelle is to fulfill phase separation in a cell. Then, how can we do it? Composition can switch rapidly through changes in scaffold concentration or multivalency. And our design was inspired by recent works showing that multivalency drives protein phase separation and formation of synthetic organelles. What’s more, we take our inspiration from existing life systems and previous works. For example, Intrinsic Disordered Regions are the symbol of massive phase separation in the cell. They interact with each other through the van der Waals force, hydrophobic effect and electrostatic attraction. And there are many interactions like this in nature, such as FKBP and FRB, SUMO and SIM, SH3 and PRM, phyB and PIF6. Thus, we can make good use of them to induce our designed organelles and regulate them variously.!
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In a conclusion,multivalency drives protein’s -self-assemblyies and interaction binds the parts together. It means, interaction can induce phase separation and multivalency can make larger assemblies, which are two essential elementmodules in our design and ensure the formation of synthetic organelles.
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<div align="center"><img src="https://static.igem.org/mediawiki/2018/f/f1/T--Peking--project_design1.jpeg" width="300px" height="100 px" ></div>
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                                  Figure. 1 Overall design
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Revision as of 13:21, 16 October 2018

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The problem of uranium contamination is a source of great concern. Uranium could have severe detrimental health effects (it is particularly harmful to the liver, kidney and bone) and lead to environment issues (chemical and radioactive hazards). Current treatment options available for uranium leaks in nuclear power plants or uranium pollution around ore-fields, such as ion exchange, flocculation-setting and phytoremediation, all have limitations including their high cost, low efficiency and the sheer complexity of the involved procedures.

To address these problems, Peking iGEM team aims to construct a novel functional biomaterial consisting of multiple functional protein modules. This material is designed to be produced and secreted by bacteria, and self-assembled to form a polymer network. In combination with a specific Super Uranyl-binding Protein, it obtains the ability to adsorb uranyl ions. After very short contacting with polluted water, the uranyl-laden biomaterial, which also contains a monomeric streptavidin module, could be easily cleared using biotinylated magnetic beads.

This uranyl-binding biomaterial shows a series of advantages, such as high specificity, high efficiency, self-assembly and renewability. Furthermore, the uranyl-binding module could be replaced or combined with modules that are capable of binding other heavy metal ions, as well as fluorescent proteins, obtaining multi-functionality. By taking advantage of modularization in the design, additional applications beyond uranium adsorption could be developed based on this material in the future.