Difference between revisions of "Team:Newcastle/Results"

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           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Rationale and Aim </h2>
 
           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Rationale and Aim </h2>
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          <p>Glyphosate is a herbicide that works by blocking the activity of the enzyme enolpyruvylshikimate-3-phosphate synthase (EPSPS), which converts carbohydrates derived from glycolysis and the pentose phosphate pathway to plant metabolites and aromatic amino acids.
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          </br></br>
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          We attempted to design a system capable of glyphosate detection. With little information regarding mechanisms of glyphosate interactions with the cell, we could not design a simple system, representative of the majority of synthetic biology biosensor designs, in which a responsive transcription factor was able to affect the production of a reporter gene.
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          </br></br>
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          The mining of transcriptome data has previously been used to find responsive DNA elements to a molecule of interest (Groningen 2012). Therefore, we analysed differences in transcriptome data between glyphosate sensitive and insensitive plants. A number of genes were found which were differently expressed. However, it was determined that it is more likely that this differential expression was not due to glyphosate directly, but rather the aromatic amino acid starvation caused by EPSPS inhibition by glyphosate, making these systems unsuitable for direct glyphosate detection. Various other systems we designed were also far from ideal, with high levels of complexity and reliance on native plant machinery.
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          </br></br>
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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 alter difficult to sense molecules using biochemical reactions. </p>
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          <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Background Information </h2>
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           <p>Sarcosine Oxidase (SOX) is an enzyme that oxidatively demethylates sarcosine to form glycine, hydrogen peroxide and formaldehyde (Figure 1) (Trickey <i>et al</i>. 1999). SOX was selected to be an example of a possible solution to one of the 5 problems in biosensor production that we identified - unconventional substrates. We defined an unconventional substrate as a substrate that we have little prior knowledge of but that can be adapted into something with an existing biosensor. SOX was specifically chosen to demonstrate that glyphosate, an unconventional substrate which there is not a lot information on, can be converted into formaldehyde which there are existing biosensors for (Ling and Heng 2010).
 
           <p>Sarcosine Oxidase (SOX) is an enzyme that oxidatively demethylates sarcosine to form glycine, hydrogen peroxide and formaldehyde (Figure 1) (Trickey <i>et al</i>. 1999). SOX was selected to be an example of a possible solution to one of the 5 problems in biosensor production that we identified - unconventional substrates. We defined an unconventional substrate as a substrate that we have little prior knowledge of but that can be adapted into something with an existing biosensor. SOX was specifically chosen to demonstrate that glyphosate, an unconventional substrate which there is not a lot information on, can be converted into formaldehyde which there are existing biosensors for (Ling and Heng 2010).
 
           </br></br>
 
           </br></br>
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           </p>
 
           </p>
  
          <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Background Information </h2>
+
 
          <p>Glyphosate is a herbicide that works by blocking the activity of the enzyme enolpyruvylshikimate-3-phosphate synthase (EPSPS), which converts carbohydrates derived from glycolysis and the pentose phosphate pathway to plant metabolites and aromatic amino acids.
+
 
          </br></br>
+
 
          We attempted to design a system capable of glyphosate detection. With little information regarding mechanisms of glyphosate interactions with the cell, we could not design a simple system, representative of the majority of synthetic biology biosensor designs, in which a responsive transcription factor was able to affect the production of a reporter gene.
+
 
          </br></br>
+
 
          The mining of transcriptome data has previously been used to find responsive DNA elements to a molecule of interest (Groningen 2012). Therefore, we analysed differences in transcriptome data between glyphosate sensitive and insensitive plants. A number of genes were found which were differently expressed. However, it was determined that it is more likely that this differential expression was not due to glyphosate directly, but rather the aromatic amino acid starvation caused by EPSPS inhibition by glyphosate, making these systems unsuitable for direct glyphosate detection. Various other systems we designed were also far from ideal, with high levels of complexity and reliance on native plant machinery.
+
 
          </br></br>
+
          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 alter difficult to sense molecules using biochemical reactions. </p>
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           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Design Stage </h2>
 
           <h2 style="font-family: Rubik; text-align: left; margin-top: 1%"> Design Stage </h2>

Revision as of 16:38, 1 November 2017

spacefill

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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