Team:EPF Lausanne/Data

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<h2>Engineering stress-related pathways to create a BioPad</h2>
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<h2> <b><u>Characterisation of the CpxR & split IFP1.4 stress-sensitive response </u> </b> </h2>
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<h3> <b>Experiment 1: </b> Promoter characterisation and folding ability of fused GFP to CpxR via 10 amino acid 2 x (GGGGS) flexible linker </h3>
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<p>Pellentesque habitant morbi tristique senectus et netus et malesuada fames ac turpis egestas. Vestibulum tortor quam, feugiat vitae, ultricies eget, tempor sit amet, ante. Donec eu libero sit amet quam egestas semper. Aenean ultricies mi vitae est. Mauris placerat eleifend leo. Quisque sit amet est et sapien ullamcorper pharetra. Vestibulum erat wisi, condimentum sed, commodo vitae, ornare sit ameh2t, wisi. Aenean fermentum, elit eget tincidunt condimentum, eros ipsum rutrum orci, sagittis tempus lacus enim ac dui. Donec non enim in turpis pulvinar facilisis. Ut felis. Praesent dapibus, neque id cursus faucibus, tortor neque egestas augue, eu vulputate magna eros eu erat. Aliquam erat volutpat. Nam dui mi, tincidunt quis, accumsan porttitor, facilisis luctus, metus</p>
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<h3><b>Experiment 2: </b>CpxR dimerization & Dimerization Orientation </h3>
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<u>Introduction</u> <br />
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CpxR is the relay protein in the stress resonsive CpxAR two component regulatory system. It has been shown by split beta galactosidase assay that CpxR dimerizes when phosphorylated (activated) in yersinia pseudotuberculosis. Moreover, following other in vitro FRET studies, it was shown that E.Coli CpxR interacted with itself.  We therefore hypothesised that dimerization would also be true in vivo in E.Coli.</p>
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<u>Aim</u> <br />
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This experiment aimed to determine if and how CpxR dimerised in vivo in E.Coli. This experiment intended to get a first idea of the real-time temporal dynamics of the activation of CpxR (the cytoplasmic relay protein of the CpxA-R pathway) by KCl stress via CpxA (the periplasmic sensor protein of the CpxA-R pathway). This experiment is a first of its kind.
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<u>Methods</u> <br />
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To evaluate if and how CpxR dimerized under KCl stress, we built four constructs with the various possible orientations that the split IFP1.4 fragments could have with CpxR: IFP[1] and IFP[2] on the N-terminus of CpxR, IFP[1] on the N-terminus of CpxR and IFP[2] on the C-terminus of CpxR, and finally IFP[1] and IFP[2] on the N-terminus of CpxR. The protocol for this experiment can be downloaded <a href="https://static.igem.org/mediawiki/2014/a/a5/EPFL_Protocol_IFP_stress_1.pdf">here</a>.
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<u>Results</u> <br />
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As shown in the graph bellow, we successfully proved that CpxR dimerized in vivo and that dimerization led to close interaction of its C-terminus. As seen in the graph, induction of the signal was done at minute 24 (marked via a vertically spoted line). It is to be noted that the signal is immediate (3 fold increase in 2 minutes) and that the signal overall increased 30-fold. This finding is important as CpxR is part of the highly conserved OmpR/PhoB subfamily - especially for their C-terminus. This system could be used to study various other components of the OmpR/PhoB subfamily and thus lead to a new generation of highly senstitive and reactive biosensors.
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<h3 id="characterization">Our BioBricks</h3>
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<h4 id="doc_and_sub"><b>New Parts</b> </h4>
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<h3><b> Experiment 3: </b>Signal induction by various concentrations of KCl & signal shutdown by centrifugation </h3>
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<li>Submitted a BioBrick consisting of CpxR under Arabinose Promoter (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486001">BBa_K1486001</a>). Reporter sfGFP was fused to CpxR's N terminus (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486002">BBa_K1486002</a>) and C terminus (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486005">BBa_K1486005</a>), to evaluate the expression of our construct and characterize the Arabinose promoter in <i>E. coli</i>.</li><br/>
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<li>Submitted four BioBricks coding for CpxR fused to one of the two fragments of the split reporter Infrared Fluorescent Protein (IFP1.4). Fragments IFP1 and IFP2 (corresponding to the N and C terminal of the IFP respectively) were fused at the N or C terminal of the CpxR, leading two four different constructs: CpxR-IFP1 (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486012">BBa_K1486012</a>), CpxR-IFP2 (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486013">BBa_K1486013</a>), IFP1-CpxR (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486014">BBa_K1486014</a>) and IFP2-CpxR (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486015">BBa_K1486015</a>). Sequences are under arabinose promoter. These Biobricks are construction intermediates to build our four final constructs below. </li><br/>
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<li>Submitted four BioBricks, which are the final constructs of the IFP subproject. Each BioBrick codes for two proteins: CpxR fused to IFP1, and CpxR fused to IFP2. The different combinations with the split at the C or N terminal of CpxR lead to four constructs: CpxR-IFP1 & CpxR-IFP2 (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486056">BBa_K1486056</a> and <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486008">BBa_K1486008</a>), IFP1-CpxR & IFP2-CpxR (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486009">BBa_K1486009</a>), IFP1-CpxR & Cpxr-IFP2 (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486010">BBa_K1486010</a>), CpxR-IFP1 & IFP2-CpxR (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486011">BBa_K1486011</a>). Sequences are under arabinose promoter.
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<u>Aim</u> <br />
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These BioBricks aimed at first to study the orientation of CpxR's homodimerization by observing the IFP signal measured from the four strains under stress. We discovered that only the orientations with both parts of the split are at the C terminal of the CpxR lead to an IFP signal when cells are stressed. Since all of these Biobricks are incompatible with RFC[10], we removed illegal restriction sites from <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486008">BBa_K1486008</a> and created <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486056">BBa_K1486056</a> (version without PstI illegal restriction enzyme sites). The experiment mentioned above was repeated with <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486056">BBa_K1486056</a> and identical results were reproduced. All further experiments were done with <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486056">BBa_K1486056</a>.  </li><br/>
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Having found that KCl was a good signal inducer for our signal, we decided to characterise our biobrick by testing if the signal could be modulated by various concentrations of KCl and if we were able to remove the signal by centrifugation and medium change.  
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To do so, we read  our signal for 20 minutes without stress and then added KCl. At minute 144 we centrifuged our cells and replaced the medium with PBS to be able to get a shutdown of the signal.
 
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<li>CpxR reporters were made with the promoter in forward and reverse direction, respectively <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486049">BBa_K1486049</a> and <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486050">BBa_K1486050</a>. These Biobricks are improvements of <a target="_blank" href="http://parts.igem.org/Part:BBa_K339007">BBa_K339007</a> </li><br/>
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<u>Methods</u> <br />
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To evaluate if a modulation in KCl concentrations affected the intensity of the intensity of the fluorescent signal, and if a change in medium by centrifugation shutdown the signal; we read our signal on a plate reader for 20 minutes without stress and then added KCl. At minute 144 we centrifuged our cells and replaced the medium with PBS to be able to get a shutdown of the signal. The protocol for this experiment can be downloaded <a href="https://static.igem.org/mediawiki/2014/a/a5/EPFL_Protocol_IFP_stress_1.pdf">here</a>.
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<u>Results</u> <br />
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We successfully showed that increasing concentrations of KCl led to stronger signals up to a saturation concentration of about 80 mM KCl. Moreover we were able to shut the signal down, thus proving the reversibility of our system. These results prove the reversibility of the split IFP1.4 and suggest that real-time temporal dynamics analysis are possible for our system.
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<li>Submitted the two parts of the split yeast optimized superfolder GFP  (N-terminal part (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486029">BBa_K1486029</a>) and C-terminal part (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486035">BBa_K1486035</a>)) created from plasmids pFA6a-link-yoSuperfolderGFP-Kan (44901) and pFA6a-link-yoSuperfolderGFP-Ura (44873) ordered from Addgene. We attached them to the ADH1 terminator, regulating the transcripion of our fusion proteins and to the selection markers Kan and Ura3. We stressed our cells under various conditions to trigger the HOG pathway and were able to show that interaction of Hog1 and Pbs2 in response to osmotic stress allowed the re-assembly of the full GFP protein.
 +
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<li>Submitted a BioBrick (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486043">BBa_K1486043</a>) containing two leucine zipper sequences, each fused with one moiety of renilla Luciferase, to test the efficiency of the split renilla luciferase in order to use it for a complementation assay.</li>
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<br />
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+
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<h3><b> Experiment 4: </b>Visualization of the the CpxR split IFP1.4 activation by KCl stress  </h3>
+
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<h4 id="improvement"><b>Further Characterization and Improvement of Parts Already in the Registry</b> </h4>
<p>
<p>
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<u>Aim</u> <br />
+
<ul>
 +
<li>After several experiments with stress induction we realised that the biobrick <a target="_blank" href="http://parts.igem.org/Part:BBa_K339007"> BBa_K339007 </a> was missing its CpxR responsive promoter. So we repaired it and sent it as <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486048">BBa_K1486048</a>. The biobrick was further engineered by testing the native CpxR target sequence that is found in front of CpxA in the E.coli genome (as Calgary's <a target="_blank" href="http://parts.igem.org/Part:BBa_K339007"> BBa_K339007 </a> did not include the whole sequence). These are the biobricks <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486049">BBa_K1486049</a> and <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486050">BBa_K1486050</a>, with the promoter in forward and reverse direction respectively.</li><br/>
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</p>
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<li>Submitted the two parts of the split of <a target="_blank" href="http://parts.igem.org/Part:BBa_K325108">EPIC Firefly luciferase</a> (N-terminal part (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486016">BBa_K1486016</a>) and C-terminal part (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486017">BBa_K1486017</a>)) from Cambridge 2010. The plasmid (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486018">BBa_K1486018</a>) containing the two parts of the split separated by a spacer can be very useful as a negative control or to establish a background noise for a complementation assay experiment.</li><br/>
 +
<li>Compared the <a target="_blank" href="http://parts.igem.org/Part:BBa_K325108">EPIC Firefly luciferase</a> from Cambridge 2010 team to the renilla luciferase (<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486022">BBa_K1486022</a>) in the same conditions, to determine which one is best suited for a complementation assay experiment. The full and split luciferases have been compared. Renilla luciferase (full and splits(<a target="_blank" href="http://parts.igem.org/Part:BBa_K1486021">BBa_K1486021</a>)) have been submitted.</li>
 +
</ul></p><br/>
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<h3 id="title_microfluidics"><b>Microfluidics</b> </h3>
<p>
<p>
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<u>Results</u> <br />
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<ul>
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<li>Design of <a target="_blank" href="https://static.igem.org/mediawiki/2014/b/b7/SmashColi_iGEM_EPFL_2014.zip">SmashColi</a> - a testing chip to analyse the effects of different mechanical stresses on cells. This chip was used to characterize <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486056">BBa_K1486056</a> and <a target="_blank" href="http://parts.igem.org/Part:BBa_K1486013">BBa_K1486013</a>. </li>
 +
<li>Design of <a target="_blank" href="https://static.igem.org/mediawiki/2014/7/79/FilterColi_iGEM_EPFL_2014.zip">FilterColi</a> - a testing chip to analyse the effects of different osmotic stresses on cells</li>
 +
<li>Design of <a target="_blank" href="https://static.igem.org/mediawiki/2014/3/33/TheBioPad_iGEM_EPFL_2014.zip">The BioPad</a> - a large-scaled chip implemented to be the touch-senstive interface of our final trackpad</li>
 +
<li>Design of <a target="_blank" href="https://static.igem.org/mediawiki/2014/b/b3/CleanColi_iGEM_EPFL_2014.zip">CleanColi</a> - an "on-chip waste treatment" unit that can be integrated at the end of any chip to decontaminate GMOs or pathogens</li>
 +
<br /><p>To find out more about what we did for each chip, click <a target="_blank" href="https://2014.igem.org/Team:EPF_Lausanne/Results#Micro_exp1">here</a></p>
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<h3 id="title_human_practices"><b>Human Practices</b> </h3><br/>
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<li>Met with a journalist from the biggest newspaper of our region (Le Temps) and got an article about our project.</li>
 +
<li>Our work was commented by Bent Stumpe, inventor of the touchscreen, as well as Rolf Heuer, the current director of the CERN, in Geneva.</li>
 +
<li>Organized an outreach event with 80 highschool students at EPFL, teaching them about synthetic biology as well as laboratory techniques and made them participate in a game called « <a target="_blank" href="https://static.igem.org/mediawiki/2014/7/76/Mini_iGEM_projects.pdf">mini iGEM</a> ».</li>
 +
<li>Presented iGEM and our work at the Hackuarium, the new BioHackerspace in Lausanne.</li>
 +
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                  <li><a href="#doc_and_sub">New Parts</a></li>
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<p>Pellentesque habitant morbi tristique senectus et netus et malesuada fames ac turpis egestas. Vestibulum tortor quam, feugiat vitae, ultricies eget, tempor sit amet, ante. Donec eu libero sit amet quam egestas semper. Aenean ultricies mi vitae est. Mauris placerat eleifend leo. Quisque sit amet est et sapien ullamcorper pharetra. Vestibulum erat wisi, condimentum sed, commodo vitae, ornare sit amet, wisi. Aenean fermentum, elit eget tincidunt condimentum, eros ipsum rutrum orci, sagittis tempus lacus enim ac dui. Donec non enim in turpis pulvinar facilisis. Ut felis. Praesent dapibus, neque id cursus faucibus, tortor neque egestas augue, eu vulputate magna eros eu erat. Aliquam erat volutpat. Nam dui mi, tincidunt quis, accumsan porttitor, facilisis luctus, metus</p>
 
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<p>Pellentesque habitant morbi tristique senectus et netus et malesuada fames ac turpis egestas. Vestibulum tortor quam, feugiat vitae, ultricies eget, tempor sit amet, ante. Donec eu libero sit amet quam egestas semper. Aenean ultricies mi vitae est. Mauris placerat eleifend leo. Quisque sit amet est et sapien ullamcorper pharetra. Vestibulum erat wisi, condimentum sed, commodo vitae, ornare sit amet, wisi. Aenean fermentum, elit eget tincidunt condimentum, eros ipsum rutrum orci, sagittis tempus lacus enim ac dui. Donec non enim in turpis pulvinar facilisis. Ut felis. Praesent dapibus, neque id cursus faucibus, tortor neque egestas augue, eu vulputate magna eros eu erat. Aliquam erat volutpat. Nam dui mi, tincidunt quis, accumsan porttitor, facilisis luctus, metus</p>
 
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Latest revision as of 03:21, 18 October 2014

DATA

Engineering stress-related pathways to create a BioPad


touch response
Touch response in yeast and bacteria


Our BioBricks

New Parts

  • Submitted a BioBrick consisting of CpxR under Arabinose Promoter (BBa_K1486001). Reporter sfGFP was fused to CpxR's N terminus (BBa_K1486002) and C terminus (BBa_K1486005), to evaluate the expression of our construct and characterize the Arabinose promoter in E. coli.

  • Submitted four BioBricks coding for CpxR fused to one of the two fragments of the split reporter Infrared Fluorescent Protein (IFP1.4). Fragments IFP1 and IFP2 (corresponding to the N and C terminal of the IFP respectively) were fused at the N or C terminal of the CpxR, leading two four different constructs: CpxR-IFP1 (BBa_K1486012), CpxR-IFP2 (BBa_K1486013), IFP1-CpxR (BBa_K1486014) and IFP2-CpxR (BBa_K1486015). Sequences are under arabinose promoter. These Biobricks are construction intermediates to build our four final constructs below.

  • Submitted four BioBricks, which are the final constructs of the IFP subproject. Each BioBrick codes for two proteins: CpxR fused to IFP1, and CpxR fused to IFP2. The different combinations with the split at the C or N terminal of CpxR lead to four constructs: CpxR-IFP1 & CpxR-IFP2 (BBa_K1486056 and BBa_K1486008), IFP1-CpxR & IFP2-CpxR (BBa_K1486009), IFP1-CpxR & Cpxr-IFP2 (BBa_K1486010), CpxR-IFP1 & IFP2-CpxR (BBa_K1486011). Sequences are under arabinose promoter. These BioBricks aimed at first to study the orientation of CpxR's homodimerization by observing the IFP signal measured from the four strains under stress. We discovered that only the orientations with both parts of the split are at the C terminal of the CpxR lead to an IFP signal when cells are stressed. Since all of these Biobricks are incompatible with RFC[10], we removed illegal restriction sites from BBa_K1486008 and created BBa_K1486056 (version without PstI illegal restriction enzyme sites). The experiment mentioned above was repeated with BBa_K1486056 and identical results were reproduced. All further experiments were done with BBa_K1486056.

  • CpxR reporters were made with the promoter in forward and reverse direction, respectively BBa_K1486049 and BBa_K1486050. These Biobricks are improvements of BBa_K339007

  • Submitted the two parts of the split yeast optimized superfolder GFP (N-terminal part (BBa_K1486029) and C-terminal part (BBa_K1486035)) created from plasmids pFA6a-link-yoSuperfolderGFP-Kan (44901) and pFA6a-link-yoSuperfolderGFP-Ura (44873) ordered from Addgene. We attached them to the ADH1 terminator, regulating the transcripion of our fusion proteins and to the selection markers Kan and Ura3. We stressed our cells under various conditions to trigger the HOG pathway and were able to show that interaction of Hog1 and Pbs2 in response to osmotic stress allowed the re-assembly of the full GFP protein.

  • Submitted a BioBrick (BBa_K1486043) containing two leucine zipper sequences, each fused with one moiety of renilla Luciferase, to test the efficiency of the split renilla luciferase in order to use it for a complementation assay.


Further Characterization and Improvement of Parts Already in the Registry

  • After several experiments with stress induction we realised that the biobrick BBa_K339007 was missing its CpxR responsive promoter. So we repaired it and sent it as BBa_K1486048. The biobrick was further engineered by testing the native CpxR target sequence that is found in front of CpxA in the E.coli genome (as Calgary's BBa_K339007 did not include the whole sequence). These are the biobricks BBa_K1486049 and BBa_K1486050, with the promoter in forward and reverse direction respectively.

  • Submitted the two parts of the split of EPIC Firefly luciferase (N-terminal part (BBa_K1486016) and C-terminal part (BBa_K1486017)) from Cambridge 2010. The plasmid (BBa_K1486018) containing the two parts of the split separated by a spacer can be very useful as a negative control or to establish a background noise for a complementation assay experiment.

  • Compared the EPIC Firefly luciferase from Cambridge 2010 team to the renilla luciferase (BBa_K1486022) in the same conditions, to determine which one is best suited for a complementation assay experiment. The full and split luciferases have been compared. Renilla luciferase (full and splits(BBa_K1486021)) have been submitted.


Microfluidics

  • Design of SmashColi - a testing chip to analyse the effects of different mechanical stresses on cells. This chip was used to characterize BBa_K1486056 and BBa_K1486013.
  • Design of FilterColi - a testing chip to analyse the effects of different osmotic stresses on cells
  • Design of The BioPad - a large-scaled chip implemented to be the touch-senstive interface of our final trackpad
  • Design of CleanColi - an "on-chip waste treatment" unit that can be integrated at the end of any chip to decontaminate GMOs or pathogens

  • To find out more about what we did for each chip, click here


Human Practices


  • Met with a journalist from the biggest newspaper of our region (Le Temps) and got an article about our project.
  • Our work was commented by Bent Stumpe, inventor of the touchscreen, as well as Rolf Heuer, the current director of the CERN, in Geneva.
  • Organized an outreach event with 80 highschool students at EPFL, teaching them about synthetic biology as well as laboratory techniques and made them participate in a game called « mini iGEM ».
  • Presented iGEM and our work at the Hackuarium, the new BioHackerspace in Lausanne.

Sponsors