Difference between revisions of "Team:Peking"

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                     <div class="texttitle">Abstract</div>
 
                     <div class="texttitle">Abstract</div>
                     <p class="lead add-bottom" style="color:#5E5656">The problems of uranium contamination have aroused people’s concern. Uranium could cause health effects (harmful to liver, kidney and bones) and environment issue (chemical and radioactive hazard). Current treatment for uranium leak of nuclear power plants or uranium pollution around the ore-fields, such as ion exchange, flocculating setting and phytoremediation, all have limitations: high cost, low efficiency and tedious procedure.
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                     <p class="lead add-bottom" style="color:#5E5656">The problem of uranium contamination is a source of great concern. Uranium can have severe detrimental health effects (it is particularly harmful to the liver, kidney and bones) 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 or flocculation-setting and phytoremediation, all have limitations including their high cost, low efficiency and the sheer complexity of the involved procedures.
 
             </p>
 
             </p>
  
             <p class="lead add-bottom" style="color:#5E5656">To alleviate 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 automatically self-assemble to form a protein network. With the employment of a specific uranium-binding protein module, it obtains the capability to adsorb uranyl. After treating the polluted water in a very short time, the uranyl-binding biomaterial which contains another monomeric streptavidin module can be easily isolated by using biotinylated magnetic beads.</p>
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             <p class="lead add-bottom" style="color:#5E5656">To address these problems, the 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 automatically self-assemble to form a protein network. In combination with a specific uranium-binding protein module, 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, can be easily retrieved using biotinylated magnetic beads.</p>
 
                          
 
                          
             <p class="lead add-bottom" style="color:#5E5656">This uranyl-binding biomaterial shows many advantages, such as high specificity, high efficiency, self-assembly and self-reproduction. Besides, the uranyl-binding module can be replaced with other heavy metal ion binding proteins or fluorescent proteins for multi-functionality. By taking advantage of modularization in our design, more applications beyond uranium absorption can be developed.</p>
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             <p class="lead add-bottom" style="color:#5E5656">This uranyl-binding biomaterial shows many advantages, such as high specificity, high efficiency, self-assembly and renewability. Furthermore, the uranyl-binding module can 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 can be developed based on this material in the future.</p>
  
 
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Revision as of 13:12, 13 October 2016

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Abstract

The problem of uranium contamination is a source of great concern. Uranium can have severe detrimental health effects (it is particularly harmful to the liver, kidney and bones) 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 or 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, the 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 automatically self-assemble to form a protein network. In combination with a specific uranium-binding protein module, 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, can be easily retrieved using biotinylated magnetic beads.

This uranyl-binding biomaterial shows many advantages, such as high specificity, high efficiency, self-assembly and renewability. Furthermore, the uranyl-binding module can 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 can be developed based on this material in the future.