Difference between revisions of "Team:Newcastle/Results"

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           Through conversations with biosensor developers, we found that this problem was common in biosensor development - large amounts of often unavailable data is required for system design. For the Sensynova framework, we needed a more generic solution to this issue. Therefore, we expanded our search to look for biochemical reactions which we could monitor instead. This resulted in our concept of “adaptor” devices which can biochemically convert a difficult to sense molecule into a molecule for which there is already a genetic sensing component. </p>
 
           Through conversations with biosensor developers, we found that this problem was common in biosensor development - large amounts of often unavailable data is required for system design. For the Sensynova framework, we needed a more generic solution to this issue. Therefore, we expanded our search to look for biochemical reactions which we could monitor instead. This resulted in our concept of “adaptor” devices which can biochemically convert a difficult to sense molecule into a molecule for which there is already a genetic sensing component. </p>
 
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           <p>The plasmid DNA preps with the correctly assembled SOX gBlock present were then transformed into  <i> E. coli</i>  BL21-DE3 cells ready for testing.</p>
 
           <p>The plasmid DNA preps with the correctly assembled SOX gBlock present were then transformed into  <i> E. coli</i>  BL21-DE3 cells ready for testing.</p>
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           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Characterisation </h2>
 
           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Characterisation </h2>
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<p>To prepare SOX for testing, cell cultures were grown following <a href="https://www.neb.com/protocols/1/01/01/protein-expression-using-bl21de3-c2527">this</a> protocol to step 4. The protocol used for <a href="https://static.igem.org/mediawiki/2017/e/e6/T--Newcastle--BB_protocol_bacterial_cell_extract.pdf">CFPS extract preparation</a> was then followed. SDS-PAGE gel electrophoresis of the samples was done to check for SOX expression. 1 ml of each culture was lysed with lysozyme and incubated at room temperature before being boiled at 100°C for 10 minutes. 20 µl samples were loaded into each lane.  At this point, an error was spotted with the size of SOX on the SDS-PAGE gel (Figure 6), as mentioned above.</p>
 
<p>To prepare SOX for testing, cell cultures were grown following <a href="https://www.neb.com/protocols/1/01/01/protein-expression-using-bl21de3-c2527">this</a> protocol to step 4. The protocol used for <a href="https://static.igem.org/mediawiki/2017/e/e6/T--Newcastle--BB_protocol_bacterial_cell_extract.pdf">CFPS extract preparation</a> was then followed. SDS-PAGE gel electrophoresis of the samples was done to check for SOX expression. 1 ml of each culture was lysed with lysozyme and incubated at room temperature before being boiled at 100°C for 10 minutes. 20 µl samples were loaded into each lane.  At this point, an error was spotted with the size of SOX on the SDS-PAGE gel (Figure 6), as mentioned above.</p>
 
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         <p>Due to time constraints, we were unable to produce an <i>in vivo</i> formaldehyde detector variant of the Sensynova framework. Future characterisation of this part would include using the platform customised as a formaldehyde biosensor in order to sense compound produce and therefore creating a biosensor of glyphosate.
 
         <p>Due to time constraints, we were unable to produce an <i>in vivo</i> formaldehyde detector variant of the Sensynova framework. Future characterisation of this part would include using the platform customised as a formaldehyde biosensor in order to sense compound produce and therefore creating a biosensor of glyphosate.
 
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             <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> References </h2>
 
             <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> References </h2>

Revision as of 17:24, 1 November 2017

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Our Experimental Results


Below is a diagram of our Sensynova Framework. Clicking on each part of the framework (e.g. detector modules) links to the relevant results.

Alternatively, at the bottom of this page are tabs which will show you results for every part of the project



Framework

Framework Chassis

Biochemical Adaptor

Target

Detector Modules

Multicellular Framework Testing

C12 HSL: Connector 1

Processor Modules

Framework in Cell Free Protein Synthesis Systems

C4 HSL: Connector 2

Reporter Modules



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