Difference between revisions of "Team:TU Darmstadt/Part Collection"

 
Line 13: Line 13:
 
    <h1>PART COLLECTION</h1>
 
    <h1>PART COLLECTION</h1>
 
</div>
 
</div>
<a href="https://2016.igem.org/Team:TU_Darmstadt/Parts"><button class="einstein_rosen_bridge" style="margin-bottom:2rem;padding-left:42px;padding-right:42px;">Back to Parts</button></a>
+
<a href="https://2016.igem.org/Team:TU_Darmstadt/Parts"><button class="einstein_rosen_bridge" style="margin-right:20px;margin-bottom:2rem;">Back to Parts &#x2192;</button></a>
 +
<a href="https://2016.igem.org/Team:TU_Darmstadt/Basic_Part"><button class="einstein_rosen_bridge"style="margin-right:20px;margin-bottom:2rem;">Basic Part &#x2192;</button></a>
 +
<a href="https://2016.igem.org/Team:TU_Darmstadt/Composite_Part"><button class="einstein_rosen_bridge" style="margin-bottom:2rem;">Composite Part &#x2192;</button></a>
 +
 
 
         <div class="abstract">
 
         <div class="abstract">
 
  <p><b>A genetic circuit is generated ensuring that genetically modified E.coli cannot survive outside of the required conditions. This genetic circuit is based on the availability of a non-natural amino acid (nnAA) which continuously has to be added to the medium. A reporter protein called mVenus is expressed as the level of nnAA in the medium decreases, signalizing the low nnAA concentration. If the level decreases further, colicin will no longer be inhibited, which leads to the complete destruction of the bacterias DNA and eventually their death. In order to keep the metabolic burden of our system as low as possible, we engineered a minimalized Colicin which consists of the DNase domain only. In addition to that, we employed a method to easily measure the metabolic burden by integrating GFP into the genome and even generated the possibility to integrate our entire safety approach into the genome to reduce the metabolic burden again.  
 
  <p><b>A genetic circuit is generated ensuring that genetically modified E.coli cannot survive outside of the required conditions. This genetic circuit is based on the availability of a non-natural amino acid (nnAA) which continuously has to be added to the medium. A reporter protein called mVenus is expressed as the level of nnAA in the medium decreases, signalizing the low nnAA concentration. If the level decreases further, colicin will no longer be inhibited, which leads to the complete destruction of the bacterias DNA and eventually their death. In order to keep the metabolic burden of our system as low as possible, we engineered a minimalized Colicin which consists of the DNase domain only. In addition to that, we employed a method to easily measure the metabolic burden by integrating GFP into the genome and even generated the possibility to integrate our entire safety approach into the genome to reduce the metabolic burden again.  

Latest revision as of 23:41, 19 October 2016

If you can see this message, you do not use Javascript. This Website is best to use with Javascript enabled. Without Javascript enabled, many features including the mobile version are not usable.
iGEM TU Darmstadt 2016

PART COLLECTION

A genetic circuit is generated ensuring that genetically modified E.coli cannot survive outside of the required conditions. This genetic circuit is based on the availability of a non-natural amino acid (nnAA) which continuously has to be added to the medium. A reporter protein called mVenus is expressed as the level of nnAA in the medium decreases, signalizing the low nnAA concentration. If the level decreases further, colicin will no longer be inhibited, which leads to the complete destruction of the bacterias DNA and eventually their death. In order to keep the metabolic burden of our system as low as possible, we engineered a minimalized Colicin which consists of the DNase domain only. In addition to that, we employed a method to easily measure the metabolic burden by integrating GFP into the genome and even generated the possibility to integrate our entire safety approach into the genome to reduce the metabolic burden again.