Team:CityU HK/project/futureplan

From 2014.igem.org

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     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
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     <td><h2>Replication of quantitative RT-PCR and GC-MS experiments.</h2><br>
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     <td><b>Replication of quantitative RT-PCR and GC-MS experiments.</b><br><br>
Due to time constraint, the RT-PCR and GC-MS experiments on the different recombinant E. coli clones were performed only once, and will have to be repeated in future studies in order to verify the statistical significance of the data.
Due to time constraint, the RT-PCR and GC-MS experiments on the different recombinant E. coli clones were performed only once, and will have to be repeated in future studies in order to verify the statistical significance of the data.
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     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
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     <td><b>Construction of Δ9-Δ12-Δ15 desaturase gene cluster downstream of the LacI promoter in pSB1C3. </b><br>
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     <td><b>Construction of Δ9-Δ12-Δ15 desaturase gene cluster downstream of the LacI promoter in pSB1C3. </b><br><br>
For overexpression studies of the Δ9-Δ12-Δ15 desaturase gene cluster in E. coli, we will repeat subcloning of the  desaturase gene cluster into pSB1C3 to create a regulatable expression system for ALA production.  
For overexpression studies of the Δ9-Δ12-Δ15 desaturase gene cluster in E. coli, we will repeat subcloning of the  desaturase gene cluster into pSB1C3 to create a regulatable expression system for ALA production.  
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     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
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     <td><b>Cotransformation of TOP10 cells with three different gene cassettes. </b><br>
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     <td><b>Cotransformation of TOP10 cells with three different gene cassettes. </b><br><br>
Attempts will be made to co-transform E. coli TOP10 cells with (1) the fadL-fadD expression cassette, (2) the ‘tesA expression cassette, and (3) the Δ9-Δ12-Δ15 desaturase gene cassette to construct a Fit Coli strain. Expression of the gene cassettes will be analysed by qRT-PCR, whilst fatty acid uptake and ALA production will be monitored by GC-MS analyses.
Attempts will be made to co-transform E. coli TOP10 cells with (1) the fadL-fadD expression cassette, (2) the ‘tesA expression cassette, and (3) the Δ9-Δ12-Δ15 desaturase gene cassette to construct a Fit Coli strain. Expression of the gene cassettes will be analysed by qRT-PCR, whilst fatty acid uptake and ALA production will be monitored by GC-MS analyses.
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   <tr>
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     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
     <th><img class="displayed" src="http://2014.igem.org/wiki/images/0/0a/CityU_HK_futureplan_telescope.png" width="50%"> </th>
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     <td><b>Studies on efficiency of ALA exportation by Fit Coli strain.  </b><br>
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     <td><b>Studies on efficiency of ALA exportation by Fit Coli strain.  </b><br><br>
Because unsaturated fatty acids are expensive sources of carbon and energy from the perspective of a cell, and an ALA export protein may not be present in E. coli to facilitate ALA export for human uptake, we will consider a pH-induced autolysis system to facilitate extracellular ALA release. When bacteria reach a certain section of the gut of a particular pH, the cell will open up so the human gut may gain access to the useful ALA. Alternatively, a bile salt-inducible system to activate yet another engineered gene from E. coli, which encodes the <a href="http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2958.2005.04956.x/pdf" target="_blank">MazF protein</a> (a stable toxin) that initiates program death in the cells will also be tested.
Because unsaturated fatty acids are expensive sources of carbon and energy from the perspective of a cell, and an ALA export protein may not be present in E. coli to facilitate ALA export for human uptake, we will consider a pH-induced autolysis system to facilitate extracellular ALA release. When bacteria reach a certain section of the gut of a particular pH, the cell will open up so the human gut may gain access to the useful ALA. Alternatively, a bile salt-inducible system to activate yet another engineered gene from E. coli, which encodes the <a href="http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2958.2005.04956.x/pdf" target="_blank">MazF protein</a> (a stable toxin) that initiates program death in the cells will also be tested.
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Revision as of 07:58, 17 October 2014

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Future plan

Replication of quantitative RT-PCR and GC-MS experiments.

Due to time constraint, the RT-PCR and GC-MS experiments on the different recombinant E. coli clones were performed only once, and will have to be repeated in future studies in order to verify the statistical significance of the data.

Construction of Δ9-Δ12-Δ15 desaturase gene cluster downstream of the LacI promoter in pSB1C3.

For overexpression studies of the Δ9-Δ12-Δ15 desaturase gene cluster in E. coli, we will repeat subcloning of the desaturase gene cluster into pSB1C3 to create a regulatable expression system for ALA production.

Cotransformation of TOP10 cells with three different gene cassettes.

Attempts will be made to co-transform E. coli TOP10 cells with (1) the fadL-fadD expression cassette, (2) the ‘tesA expression cassette, and (3) the Δ9-Δ12-Δ15 desaturase gene cassette to construct a Fit Coli strain. Expression of the gene cassettes will be analysed by qRT-PCR, whilst fatty acid uptake and ALA production will be monitored by GC-MS analyses.

Studies on efficiency of ALA exportation by Fit Coli strain.

Because unsaturated fatty acids are expensive sources of carbon and energy from the perspective of a cell, and an ALA export protein may not be present in E. coli to facilitate ALA export for human uptake, we will consider a pH-induced autolysis system to facilitate extracellular ALA release. When bacteria reach a certain section of the gut of a particular pH, the cell will open up so the human gut may gain access to the useful ALA. Alternatively, a bile salt-inducible system to activate yet another engineered gene from E. coli, which encodes the MazF protein (a stable toxin) that initiates program death in the cells will also be tested.



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