Team:Arizona State/science

From 2014.igem.org

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<td width="90%" ><p><strong style="font-size: 34px">The Arizona State University iGEM team</strong></p>
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<td width="90%" ><p><strong style="font-size: 32px">Biodiesel Production in a Multi-Strain System</strong></p>
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   <p>&nbsp;</p>
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   <p><strong>Current system of biodiesel production in E. coli</strong> <br>
   <p><strong>Current system of biodiesel production in E. coli</strong> <br>
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     When attempting to produce biodesiel in E. Coli, certain problems emerge, especially surrounding the metabolic use of certain intermediate products. E. coli has to use the pyruvate from glycolysis to produce both intermediates of wax ethyl ester, ethanol and acyl-COAs. In order to circumvent this metabolic competition, we decided that specialization </p>
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     When attempting to produce biodiesel in E. Coli, certain problems emerge, especially surrounding the metabolic use of certain intermediate products. E. coli has to use the pyruvate from glycolysis to produce both intermediates of wax ethyl ester, ethanol and acyl-COAs. In order to circumvent this metabolic competition, we decided that specialization in a multi strain system would be our solution. Two colonies of E. Coli will create the intermediates individually, therefore avoiding competition for use of resources inside of the individual cells. With the two colonies growing together, a greater titer of the final product (FAEE's) can be accomplished.
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<p><strong>Our Solution</strong>
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<br>
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The first intermediate, ethanol, is formed using a two enzyme plasmid. Pdc and adhB take pyruvate from glycolisis and convert it into first, acetaldehyde, and then into ethanol.
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<p>
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The second intermediates, acyl coa's, are formed with a thioesterase combined with the four components of the Acc plasmid (A,B,C,D). The two intermediates are combined with a wax-synthase and a coa-ligase to produce fatty acid ethyl esters.
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<p>&nbsp;</p>
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<img src="https://static.igem.org/mediawiki/2014/a/ae/Metabolic_pathway.jpg" alt="" align="center" height="400" >
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   <p>&nbsp;</p>
   <p>&nbsp;</p>
   <hr>
   <hr>
   <p>&nbsp;</p>
   <p>&nbsp;</p>
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   <p><strong>Future plans for this project</strong> <br>
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   <p><strong>Future plans for this project</strong><br>
     There are some future objectives that can expand upon this project. Maximizing the production of ethanol and acyl-COAs without stopping normal cellular metabolism can optimize the production of the fatty ethyl esters. Another consideration is the balance between the ethanol and fatty acid populations. It is possible that more of one population is required to optimize production. Quorum sensing techniques could be used to track the two populations and reach an equilibrium with high production.  </p></td>
     There are some future objectives that can expand upon this project. Maximizing the production of ethanol and acyl-COAs without stopping normal cellular metabolism can optimize the production of the fatty ethyl esters. Another consideration is the balance between the ethanol and fatty acid populations. It is possible that more of one population is required to optimize production. Quorum sensing techniques could be used to track the two populations and reach an equilibrium with high production.  </p></td>
<td width="5%">&nbsp;</td>
<td width="5%">&nbsp;</td>

Revision as of 20:14, 16 October 2014

 

 

Biodiesel Production in a Multi-Strain System

 

Current system of biodiesel production in E. coli
When attempting to produce biodiesel in E. Coli, certain problems emerge, especially surrounding the metabolic use of certain intermediate products. E. coli has to use the pyruvate from glycolysis to produce both intermediates of wax ethyl ester, ethanol and acyl-COAs. In order to circumvent this metabolic competition, we decided that specialization in a multi strain system would be our solution. Two colonies of E. Coli will create the intermediates individually, therefore avoiding competition for use of resources inside of the individual cells. With the two colonies growing together, a greater titer of the final product (FAEE's) can be accomplished.

Our Solution
The first intermediate, ethanol, is formed using a two enzyme plasmid. Pdc and adhB take pyruvate from glycolisis and convert it into first, acetaldehyde, and then into ethanol.

The second intermediates, acyl coa's, are formed with a thioesterase combined with the four components of the Acc plasmid (A,B,C,D). The two intermediates are combined with a wax-synthase and a coa-ligase to produce fatty acid ethyl esters.

 

 

 

Future plans for this project
There are some future objectives that can expand upon this project. Maximizing the production of ethanol and acyl-COAs without stopping normal cellular metabolism can optimize the production of the fatty ethyl esters. Another consideration is the balance between the ethanol and fatty acid populations. It is possible that more of one population is required to optimize production. Quorum sensing techniques could be used to track the two populations and reach an equilibrium with high production.

 

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