Team:USTC CHINA

From 2013.igem.org

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<div id="content1p">project discription</div>
<div id="content1p">project discription</div>
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<div id="content2p"><p>Based on the fundamental principles and technology of synthetic biology, our team aims at designing a brand-new immune system containing transdermal peptide that expresses genes and produces immune response simultaneously. To reach this goal, we need to build four kinds of engineering bacteria and find out effective immune stimulations and responses. Meanwhile, an appropriate reporting system guiding vaccination at different stages is also required to meet the demand of practical, safe and human-friendly production. The bacillus subtilis we use is WB800N. By Modifying it into four types of engineering bacteria, we combine the gene coding transdermal peptide with the gene coding LTB, HBsAg, reporter, and LC Luman-recruiting factor. Then, the engineering bacteria will produce mixture of fusion protein in the skin and activate immune response.</p>
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<div id="content2p"><p>Based on the fundamental principles and technology of synthetic biology, our team aims at designing a new immune system containing transdermal peptide that expresses genes and produces immune responses simultaneously. To reach this goal, we need to build four kinds of engineered bacteria and find out effective immune responses. Meanwhile, an appropriate reporting system guiding vaccination at different stages is also required to meet the demand of practical, safe and human-friendly production. The Bacillus subtilis we use is WB800N, which is modified into four types of engineered bacteria, combined with the gene coding LTB, HBsAg, reporter, and LC Luman-recruiting factor respectively, each of which contains the gene coding transdermal peptide. Then, the engineered bacteria will produce mixture of fusion protein in the skin and activate immune responses.</p>
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  <p> Due to the introducing of transdermal peptide and the simultaneous immune response with protein expression, our work has great advantages compared with the existing immune system for it is not only economical but also easy to operate. It is expected to become a promising new vaccine research field.</P>
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  <p> The introducing of transdermal peptide, together with the simultaneous immune response with protein expression, has granted our work great advantages over other existing immune system, both in economy and operation. Therefore it is expected to become a promising new vaccine research field.</P>
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  <p> So far, we have successfully synthesize four kinds of plasmid, the sequence of which is proved to be correct. And we have managed to transform three plasmid from E. coli to Bacillus subtilis, and there is still one,GFP, in progress.</p>
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  <p> So far, we have successfully synthesize four kinds of plasmids, and the sequences of them all have been proved correct. Additionally, we have managed to transform three plasmids from E. coli to Bacillus subtilis, leaving GFP in progress. </p>
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   <p> For the coming days, we plan to continue our transformation. Besides, experiments on the mice are also necessary to check the effect of our vaccine. And other tasks, such as human practice and the standardization of our parts, are in our future schedule.</p></div>
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   <p> For the coming days, we plan to continue our transformation and experiment on the mice to check the effects of our vaccine, whereas other tasks, such as human practice and the standardization of our parts, are in our future schedule.</p></div>
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Revision as of 13:23, 8 August 2013

USTC_China

project discription

Based on the fundamental principles and technology of synthetic biology, our team aims at designing a new immune system containing transdermal peptide that expresses genes and produces immune responses simultaneously. To reach this goal, we need to build four kinds of engineered bacteria and find out effective immune responses. Meanwhile, an appropriate reporting system guiding vaccination at different stages is also required to meet the demand of practical, safe and human-friendly production. The Bacillus subtilis we use is WB800N, which is modified into four types of engineered bacteria, combined with the gene coding LTB, HBsAg, reporter, and LC Luman-recruiting factor respectively, each of which contains the gene coding transdermal peptide. Then, the engineered bacteria will produce mixture of fusion protein in the skin and activate immune responses.

The introducing of transdermal peptide, together with the simultaneous immune response with protein expression, has granted our work great advantages over other existing immune system, both in economy and operation. Therefore it is expected to become a promising new vaccine research field.

So far, we have successfully synthesize four kinds of plasmids, and the sequences of them all have been proved correct. Additionally, we have managed to transform three plasmids from E. coli to Bacillus subtilis, leaving GFP in progress.

For the coming days, we plan to continue our transformation and experiment on the mice to check the effects of our vaccine, whereas other tasks, such as human practice and the standardization of our parts, are in our future schedule.

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