Difference between revisions of "Team:Uppsala"

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                             <p><b>-</b> For the first one, we have been developing a custom transcriptomic analysis protocol. This was necessary because transcriptomics is a new application for Oxford Nanopore technology. The transcriptomics procedure relies on the co-culturing of nematodes with E.coli and subsequent sequencing of the bacterial mRNA. This will ideally reveal which genes are upregulated when the worm is next to the nematode. The promoters of these genes can then be used to develop a biosensor by linking them to a reporter!  
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                             <p>For the first one, we have been developing a custom transcriptomic analysis protocol. This was necessary because transcriptomics is a new application for Oxford Nanopore technology. The transcriptomics procedure relies on the co-culturing of nematodes with E.coli and subsequent sequencing of the bacterial mRNA. This will ideally reveal which genes are upregulated when the worm is next to the nematode. The promoters of these genes can then be used to develop a biosensor by linking them to a reporter!  
 
                     As our result show, transcriptomics with the nanopore MinIon works if a better technique to reduce the amount of RNA in the sample is discovered thus we have discovered a new application to Oxford Nanopore Technology.<br><br><b>Figure 3: </b>Flowchart representing the trancsriptomics outline.</p>
 
                     As our result show, transcriptomics with the nanopore MinIon works if a better technique to reduce the amount of RNA in the sample is discovered thus we have discovered a new application to Oxford Nanopore Technology.<br><br><b>Figure 3: </b>Flowchart representing the trancsriptomics outline.</p>
 
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                             <p><b>-</b> The second approach used a technique called “Phage Display”, which utilizes a random peptide library expressed on the surface of phages. By repeated rounds of affinity screening, only phages with high affinity to the molecule of interest will be selected. Sequencing the genetic information of these phages has allowed us to construct multiple peptide suggestions that may bind to our nematodes’ surface proteins.  This would allow the biosensor to aggregate at the detection sites and create a stronger signal. <br><br>
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                             <p>The second approach used a technique called “Phage Display”, which utilizes a random peptide library expressed on the surface of phages. By repeated rounds of affinity screening, only phages with high affinity to the molecule of interest will be selected. Sequencing the genetic information of these phages has allowed us to construct multiple peptide suggestions that may bind to our nematodes’ surface proteins.  This would allow the biosensor to aggregate at the detection sites and create a stronger signal. <br><br>
 
                             In our project, phage display has been used in a whole new way. Performing phage display on a whole organism is an unconventional and unpublished procedure. By creating a working protocol for the purpose of finding a specific binder for strongyles we have applied this Nobel-prize winning method in a new way.<br><br><b>Figure 4: </b>Flowchart representing the phage display outline.</p>
 
                             In our project, phage display has been used in a whole new way. Performing phage display on a whole organism is an unconventional and unpublished procedure. By creating a working protocol for the purpose of finding a specific binder for strongyles we have applied this Nobel-prize winning method in a new way.<br><br><b>Figure 4: </b>Flowchart representing the phage display outline.</p>
 
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Revision as of 12:04, 16 October 2018




Uppsala iGEM 2018