Difference between revisions of "Team:DTU-Denmark/achievements"

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                             <p>"Only those who attempt the absurd can achieve the impossible"</p>
 
                             <p>"Only those who attempt the absurd can achieve the impossible"</p>
 
                             <small>Albert Einstein<cite title="Source Title"></cite></small>
 
                             <small>Albert Einstein<cite title="Source Title"></cite></small>
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         <h2 class="h2">Medal Requirements</h2>
 
         <h2 class="h2">Medal Requirements</h2>
 
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                     <p>We registred for iGEM, had great and educational (sometimes frustrating) summer. We also attended the Giant jamboree. </p>
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                     <p>We registred for iGEM, and had a great and educational (sometimes frustrating) summer. We will also attended the Giant jamboree. </p>
 
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                     <p>Yes, we met all the deliverables. Take a look around on our awesome wiki. We have registered and submitted all our    
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                     <p>Yes, we met all the deliverables. Take a look around on our awesome wiki. We have registered and submitted all our  
                    <a href="https://2016.igem.org/Team:DTU-Denmark/Description">parts </a>. We have filled out the safety, judging and registry forms as required. The team is ready with the presentation and poster for the Giant Jamboree.</p>
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                    <a href="https://2016.igem.org/Team:DTU-Denmark/Description">parts </a>. We have filled out the safety, judging and registry forms as required. The team is ready with the presentation and poster for the Giant Jamboree.</p>
 
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                     <p>Even though this project was driven and conducted by the team only, we have gotten a lot of much appreciated help during this project. Everyone should of course be credited for their attributions. Please see our  <a href="https://2016.igem.org/Team:DTU-Denmark/Attributions">attribution site</a> </p>
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                     <p>Even though this project was driven and conducted by the team only, we have gotten a lot of much appreciated help during this project. Everyone should of course be credited for their attributions. Please see our  <a href="https://2016.igem.org/Team:DTU-Denmark/Attributions">attribution page</a>.</p>
 
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                     <p>We have registered and submitted our new part  <a href="http://parts.igem.org/Part:BBa_K2117003">BBa_K2117003</a>. This part encodes the Human Proinsulin peptide. The gene has been codon-optimized for the yeast <i>Yarrowia lipolytica</i> using a DTU-Denmark iGEM 2016 team designed <a href="https://2016.igem.org/Team:DTU-Denmark/Software">codon-optimization tool</a> that also considers illegal restriction sites.</p>
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                     <p>We have registered and submitted our new part  <a href="http://parts.igem.org/Part:BBa_K2117003">BBa_K2117003</a>. This part encodes the human proinsulin peptide. The gene has been codon-optimized for the yeast <i>Yarrowia lipolytica</i> using a DTU-Denmark iGEM 2016 team designed <a href="https://2016.igem.org/Team:DTU-Denmark/Software">codon-optimization tool</a> that also considers illegal restriction sites.</p>
 
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                     <p>Our new BioBrick device <a href="http://parts.igem.org/Part:BBa_K2117005">BBa_K2117005</a> encodes the humanized Renilla reniformis green fluorescent protein (hrGFP) codon-optimized for <i>Yarrowia lipolytica</i> and the translation elongation factor-1α (TEF1) promoter. We have used this device to demonstrate heterologous protein expression in <i>Y. lipolytica</i> and experimentally validated it through confocal laser scanning microscope. </p>
+
                     <p>Our new BioBrick device <a href="http://parts.igem.org/Part:BBa_K2117005">BBa_K2117005</a> encodes the humanized <i>Renilla reniformis</i> green fluorescent protein (hrGFP) codon-optimized for <i>Y. lipolytica</i> and the translation elongation factor-1α (TEF1) promoter. We have used this device to demonstrate heterologous protein expression in <i>Y. lipolytica</i> and experimentally validated it through confocal laser scanning microscope. </p>
 
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                     <p>We have helped different iGEM teams during summer: Uppsala iGEM, UNIK-cph, SDU-Denmark. For more information please see <a href="https://2016.igem.org/Team:DTU-Denmark/Collaborations">collaborations.</a></p>
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                     <p>We have helped different iGEM teams during summer: <a href="https://2016.igem.org/Team:Uppsala/Collaborations">Uppsala iGEM</a>, <a href="https://2016.igem.org/Team:UNIK_Copenhagen/Collaborations">UNIK_Copenhagen</a>, <a href="https://2016.igem.org/Team:SDU-Denmark/Collaborations">SDU-Denmark</a>. For more information please see our <a href="https://2016.igem.org/Team:DTU-Denmark/Collaborations">collaborations page.</a></p>
 
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                     <p>We sure went beyond the lab bench during this project. Our biggest achievement was the launch of the <a href="https://2016.igem.org/Team:DTU-Denmark/Engagement">Biosensor project</a>, a platform for allowing over 200 high schools nationwide. We also held meet-ups for other iGEM teams, presented our project at different events and got media coverage. Please see our            
+
                     <p>We sure went beyond the lab bench during this project. Our biggest achievement was the launch of the <a href="https://2016.igem.org/Team:DTU-Denmark/Engagement">Biosensor project</a>, a platform for allowing over 200 high schools nationwide to work with synthetic biology. We also held meet-ups for other iGEM teams, presented our project at different events and got media coverage. Please see our <a href="https://2016.igem.org/Team:DTU-Denmark/HP/Silver">practices page</a> for elaboration.</p>
                    <a href="https://2016.igem.org/Team:DTU-Denmark/HP/Silver">practices page</a> for elaboration.</p>
+
 
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                     <p>We have improved the two BioBricks; <a href="http://parts.igem.org/Part:BBa_K530001">BBa_K530001</a> (CrtE gene) and <a href="http://parts.igem.org/Part:BBa_K530002">BBa_K530002</a>
 
                     <p>We have improved the two BioBricks; <a href="http://parts.igem.org/Part:BBa_K530001">BBa_K530001</a> (CrtE gene) and <a href="http://parts.igem.org/Part:BBa_K530002">BBa_K530002</a>
 
                              
 
                              
                     (CrtI gene) created by the John Hopkins iGEM team 2011. We used site directed mutagenesis to successfully remove of two illegal restriction sites and further improved the characterization. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Description">parts page</a> for elaboration.</p>
+
                     (CrtI gene) created by the John Hopkins iGEM team 2011. We used site directed mutagenesis to successfully remove two illegal restriction sites and furthermore we improved the characterization. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Description">parts page</a> for elaboration.</p>
 
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                     <p>We successfully designed a functional plasmid (pSBB1A8YL) for transformation and replication in both E. coli and Y. lipolytica. pSBB1A8YL is also compatible with the BioBrick standard by assembly with our own BioBrick device <a href="http://parts.igem.org/Part:BBa_K2117005">BBa_K2117005</a>. Further we showed that we could utilize the construct in Y. lipolytica to express a heterologous protein, hrGFP. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Proof">proof of concept page</a> for elaboration.</p>
+
                     <p>We successfully designed a functional plasmid (<a href="http://parts.igem.org/Part:BBa_K2117009">pSBB1A8YL</a>) for transformation and replication in both <em>Escherichia coli</em> and <em>Y. lipolytica</em>. pSBB1A8YL is also compatible with the BioBrick standard by assembly with our own BioBrick device <a href="http://parts.igem.org/Part:BBa_K2117005">BBa_K2117005</a>. This was proved by showing that we could utilize the construct in <em>Y. lipolytica</em> to express a heterologous protein, hrGFP. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Proof">proof of concept page</a> for elaboration.</p>
 
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                     <p></p>
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                     <p>We did not have time to check our construct under simulated real-world conditions unfortunately</p>
 
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         </div> <!-- /overview-->
 
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         <div><a class="anchor" id="section-2"></a>
           
 
           
 
 
         <h2 class="h2">Special prizes</h2>
 
         <h2 class="h2">Special prizes</h2>
 
             <p>
 
             <p>
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             <p>
 
             <p>
 
             The Biosensor project is an outstanding project, where kits for GMO exercises are sent for free to all highschools in Denmark. The Biosensor kit contains everything needed for making 100 biosensors; DNA with BioBricks from the iGEM registry, enzymes, antibiotics, buffers, ligases, cells and sterile equipment.  
 
             The Biosensor project is an outstanding project, where kits for GMO exercises are sent for free to all highschools in Denmark. The Biosensor kit contains everything needed for making 100 biosensors; DNA with BioBricks from the iGEM registry, enzymes, antibiotics, buffers, ligases, cells and sterile equipment.  
             The students can create biosensors by assembling a detection and response gene using 3A assembly to genetically modify E. coli. Until now GMO exercises have been unavailable for Danish highschools due to costs and law, but with the biosensor project it is no longer a problem. We tested the kit at a local highschool and raised almost 135,000 USD from both Danish and international sponsors and we expect the kit to be distributed by the end of this year. We hope it will inspire and encourage the next generation to work in the field of synthetic biology. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Engagement">Biosensor page</a>
+
             The students can create biosensors by assembling a detection and response gene using 3A assembly to genetically modify <em>E. coli.</em> Until now GMO exercises have been unavailable for Danish highschools due to costs and law, but with the biosensor project it is no longer a problem. We tested the kit at a local highschool and raised almost 135,000 USD from both Danish and international sponsors and we expect the kit to be distributed by the end of this year. We hope it will inspire and encourage the next generation to work in the field of synthetic biology. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Engagement">Biosensor page</a>
 
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             <p>
 
             <p>
             One of the numerous capabilities and features that iGEM is providing to current and future science disciplines and societies around the globe, is the ability of “building interdisciplinary bridges”. Therefore, the DTU-Denmark team confidently believes that the developed CodonOpt Tool will bring wetlabs and computational biology a step closer to bidirectional understanding. This tool is a stand-alone cross-platform software developed in Python (using only standard libraries) and provides comprehensive codon optimization of DNA sequences from protein sequences. Its uniqueness lies in the fact that the researcher can specify the organism and the desired protein sequences to optimize according to the tRNA adaptation index (TAI) for the specified organism. This is novel in terms of codon optimization methods approach is framed by a user friendly GUI along with the option of removal of desired restriction sites from the resulting DNA sequences. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Hardware">microfermentation platform page</a>
+
             One of the numerous capabilities and features that iGEM is providing to current and future science disciplines and societies around the globe, is the ability of “building interdisciplinary bridges”. Therefore, the DTU BioBuilders team confidently believes that the developed TaiCO tool will bring wetlabs and computational biology a step closer to bidirectional understanding. This tool is a stand-alone cross-platform software developed in Python (using only standard libraries) and provides comprehensive codon optimization of DNA sequences from protein sequences. Its uniqueness lies in the fact that the researcher can specify the organism and the desired protein sequences to optimize according to the tRNA adaptation index (TAI) for the specified organism. This is novel in terms of codon optimization methods approach is framed by a user friendly GUI along with the option of removal of desired restriction sites from the resulting DNA sequences. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Software">codon optimization page</a> for elaboration.
 
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             <p>
 
             <p>
             When taking your synbio project to real applications, fast growth is crucial for the viability. The optical density is commonly used as a proximation for cell count and numerous instructions for DIY spectrophotometers exist. However, in order to estimate growth rates, cultures must be sampled over a long period of time. During our project, this was done by a robot handling microtiter plates. We are aware that this is a technology not everybody has access to. Therefore, we took the concept of a DIY spectrophotometer and expanded it to a platform that carries out small scale fermentations comparing growth of your modifed strain to a wild type or other organisms. To take it even further, we encapsuled it in a compact housing that fits on any lab bench. It can be rebuild or modified by anyone with access to a PC, a 3D-printer and a laser cutter. Please see <a href="https://2016.igem.org/Team:DTU-Denmark/Software">codon optimization page</a>
+
             When taking your synbio project to real applications, fast growth is crucial for the viability. The optical density is commonly used as a proximation for cell count and numerous instructions for DIY spectrophotometers exist. However, in order to estimate growth rates, cultures must be sampled over a long period of time. During our project, this was done by a robot handling microtiter plates. We are aware that this is a technology not everybody has access to. Therefore, we took the concept of a DIY spectrophotometer and expanded it to a platform that carries out small scale fermentations comparing growth of your modifed strain to a wild type or other organisms. To take it even further, we encapsuled it in a compact housing that fits on any lab bench. It can be rebuild or modified by anyone with access to a PC, a 3D-printer and a laser cutter. Please see the <a href="https://2016.igem.org/Team:DTU-Denmark/Hardware">microfermentation platform page</a> for elaboration.
 
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             </p>
 
              
 
              
           
+
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         <div><a class="anchor" id="section-3"></a>
 
         <div><a class="anchor" id="section-3"></a>
       
 
 
         <h2 class="h2">Milestones</h2>
 
         <h2 class="h2">Milestones</h2>
  
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-content right">
 
<div class="timeline-content right">
<p>We decided on a project! To utilize a waste source as a substrate for a production organism to produce something valuable as insulin! </p>
+
<p>We decided on a project! To utilize a waste source as a substrate for a production organism to produce something valuable such as insulin! </p>
 
<span class="label label-main">April</span> </div>
 
<span class="label label-main">April</span> </div>
 
</div>
 
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-content">
 
<div class="timeline-content">
<p>The DTU annual BioBrick Tutorial was hosted for danish iGEM teams from SDU and KU.   </p>
+
<p>The DTU annual BioBrick Tutorial was hosted for Danish iGEM teams from SDU and KU.</p>
 
<span class="label label-main">May</span>  
 
<span class="label label-main">May</span>  
 
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<div class="timeline-content right">
<p>Our preliminary idea for an ideal waste substrate as glycerol, was shot down by industry. Keep going! </p>
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<p>Our preliminary idea for glycerol as the ideal waste substrate was shot down by industry. Keep going! </p>
 
<span class="label label-main">June</span> </div>
 
<span class="label label-main">June</span> </div>
 
</div>
 
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<div class="timeline-content">
<p>Getting approached by local journalists - our vision is reaching the greater public! </p>
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<p>Getting approached by local journalists - our vision is reaching the greater public!</p>
 
<span class="label label-main">June</span>  
 
<span class="label label-main">June</span>  
 
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<div class="timeline-content right">
<p>Found a great waste source in form of cold-pressed canola oil sediment, that is just burnt off. Out to find an organism that can utilize this waste! </p>
+
<p>Found a great waste source in form of cold-pressed canola oil sediment, that is just burned off. Out to find an organism that can utilize this waste! </p>
 
<span class="label label-main">June</span> </div>
 
<span class="label label-main">June</span> </div>
 
</div>
 
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<div class="timeline-content">
<p>Our BioBrick plasmid, pSB1A8YL, was finally constructed! </p>
+
<p>Preliminary versions of our Codon Optimization Software was used for the first time to codon optimize the proinsulin gene for <em>Y. lipolytica</em>, our organism of choice!</p>
 
<span class="label label-main">July</span>  
 
<span class="label label-main">July</span>  
 
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-content right">
 
<div class="timeline-content right">
<p>Preliminary versions of our Codon Optimization Software was used for the first time to codon optimize the proinsulin gene for <em>Yarrowia lipolytica</em>, our organism of choice! </p>
+
<p>Our BioBrick plasmid, pSB1A8YL, was finally constructed!</p>
 
<span class="label label-main">July</span> </div>
 
<span class="label label-main">July</span> </div>
 
</div>
 
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<p>Approached industry with our idea, and after going back and forth we decided a clear path for our project. </p>
+
<p>We approached industry with our idea, and after going back and forth we decided a clear path for our project.</p>
 
<span class="label label-main">July</span>  
 
<span class="label label-main">July</span>  
 
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<div class="timeline-content">
<p>After 10 weeks of trial and error, a transformation protocol compliant with <em>Y. lipolytica</em> was obtained. Making this yeast engineerable is getting closer! </p>
+
<p>After 10 weeks of trial and error, a transformation protocol compliant with <em>Y. lipolytica</em> was obtained. Making this yeast engineerable is getting closer!</p>
 
<span class="label label-main">August</span>  
 
<span class="label label-main">August</span>  
 
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<div class="timeline-content right">
<p>Our goal to fund USD 60.000 was way over achieved, when the final funding totaled at USD 120.000! Now we can start buying equipment for our own DTU iGEM lab for future teams.  </p>
+
<p>Our goal to fund the project with 60,000 USD was way over achieved, when the final funding totaled at 120,000 USD! Now we can start buying equipment for our own DTU iGEM lab for future teams.  </p>
 
<span class="label label-main">August</span> </div>
 
<span class="label label-main">August</span> </div>
 
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
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<div class="timeline-content">
<p>Getting rid of the breadboards! The DIY micro fermentation platform has finally fits into the housing using the printed circuit board we designed. </p>
+
<p>Getting rid of the breadboards! The DIY microfermentation platform has been finally fit into the housing using the printed circuit board we designed. </p>
 
<span class="label label-main">September</span>  
 
<span class="label label-main">September</span>  
 
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
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<div class="timeline-content right">
<p>Genome Scale Modeling is coming along. We achieved to get the same PHPP values as in published papers, for growth rate changes in E. coli when varying oxygen and nutrient uptake rates. </p>
+
<p>Genome scale modeling is coming along. We achieved getting the same PHPP values for growth rate changes in <em>E. coli</em> when varying oxygen and nutrient uptake rates, as in published papers.</p>
 
<span class="label label-main">September</span> </div>
 
<span class="label label-main">September</span> </div>
 
</div>
 
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<div class="timeline-content">
 
<div class="timeline-content">
<p>Our DIY lab is coming along, with the first growth curve measured with the final prototype of our micro fermentation platform. </p>
+
<p>Our DIY lab is coming along, with the first growth curve measured with the final prototype of our microfermentation platform. </p>
 
<span class="label label-main">September</span>  
 
<span class="label label-main">September</span>  
 
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<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-icon"> <span class="star">&#9733;</span> </div>
 
<div class="timeline-content">
 
<div class="timeline-content">
<p>We achieved to optimize preexisting beta-Carotene BioBricks by removing illegal restriction sites! </p>
+
<p>We optimized preexisting &beta;-Carotene BioBricks by removing illegal restriction sites!</p>
 
<span class="label label-main">October</span>  
 
<span class="label label-main">October</span>  
 
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<div class="timeline-content right">
<p> Finally! We managed to insert a gene (<em>URA3</em>) in the <em>Y. lipolytica</em> genome by CRISPR induced homologous recombination. Where is the limit now?! </p>
+
<p>Finally! We managed to insert a gene (<em>URA3</em>) in the <em>Y. lipolytica</em> genome by CRISPR induced homologous recombination. Where is the limit now?! </p>
 
<span class="label label-main">October</span> </div>
 
<span class="label label-main">October</span> </div>
 
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<div class="timeline-content">
<p>We managed use FSEOF to stimulate gene amplification targets to optimize beta-Carotene production in <em>Y. lipolytica</em>. Hopefully we can replicate these results in the lab. </p>
+
<p>We managed to use FSEOF to stimulate gene amplification targets to optimize beta-Carotene production in <em>Y. lipolytica</em>. Hopefully we can replicate these results in the lab. </p>
 
<span class="label label-main">Month</span>  
 
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<p>Eureka! <em>Y. lipolytica</em> PO1f colonies with changed morphology was observed, indicating that we successfully have knocked out a gene by CRISPR induced error prone NHEJ. Sequencing awaits! </p>
+
<p>Eureka! <em>Y. lipolytica</em> PO1f colonies with changed morphology was observed, indicating that we have successfully knocked out a gene by CRISPR induced error prone NHEJ. Sequencing awaits! </p>
 
<span class="label label-main">October</span>  
 
<span class="label label-main">October</span>  
 
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<div class="timeline-content right">
<p>Our DIY micro fermentation platform was successfully tested by prospective users: a high school student and a local hackerspace. </p>
+
<p>Our DIY micro fermentation platform was successfully tested by prospective users: a high school student and a local hackerspace. </p>
 
<span class="label label-main">October</span> </div>
 
<span class="label label-main">October</span> </div>
 
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             <li><a href="#section-1">Medal Requirements</a></li>
 
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Revision as of 22:26, 19 October 2016

New HTML template for the wiki




Bootstrap Example

Achievements

We have fulfilled all bronze medal requirements, all the requirements for the silver medal and 3/4 criteria for achieving a gold medal. Further we have qualified for 3 special prizes; Education and Public engagement, Software and Hardware


Medal Requirements

"Only those who attempt the absurd can achieve the impossible"

Albert Einstein

Bronze

Register and attend

We registred for iGEM, and had a great and educational (sometimes frustrating) summer. We will also attended the Giant jamboree.

Deliverables

Yes, we met all the deliverables. Take a look around on our awesome wiki. We have registered and submitted all our parts . We have filled out the safety, judging and registry forms as required. The team is ready with the presentation and poster for the Giant Jamboree.

Attribution

Even though this project was driven and conducted by the team only, we have gotten a lot of much appreciated help during this project. Everyone should of course be credited for their attributions. Please see our attribution page.

Part

We have registered and submitted our new part BBa_K2117003. This part encodes the human proinsulin peptide. The gene has been codon-optimized for the yeast Yarrowia lipolytica using a DTU-Denmark iGEM 2016 team designed codon-optimization tool that also considers illegal restriction sites.

Silver

Validated Part

Our new BioBrick device BBa_K2117005 encodes the humanized Renilla reniformis green fluorescent protein (hrGFP) codon-optimized for Y. lipolytica and the translation elongation factor-1α (TEF1) promoter. We have used this device to demonstrate heterologous protein expression in Y. lipolytica and experimentally validated it through confocal laser scanning microscope.

Collaboration

We have helped different iGEM teams during summer: Uppsala iGEM, UNIK_Copenhagen, SDU-Denmark. For more information please see our collaborations page.

Human Practices

We sure went beyond the lab bench during this project. Our biggest achievement was the launch of the Biosensor project, a platform for allowing over 200 high schools nationwide to work with synthetic biology. We also held meet-ups for other iGEM teams, presented our project at different events and got media coverage. Please see our practices page for elaboration.

Gold

Integrated Human Practices

Throughout our project we have been in close contact and collaboration with the industry. We started out searching for abundant waste streams in Denmark by contacting and visiting local factories, then we presented our idea to biotech manufacturing companies and all together the feedback made us more aware of the challenges our technology is facing and it ultimately led us to a more feasible product. Please see the Integrated practice page

Improve a previous part

We have improved the two BioBricks; BBa_K530001 (CrtE gene) and BBa_K530002 (CrtI gene) created by the John Hopkins iGEM team 2011. We used site directed mutagenesis to successfully remove two illegal restriction sites and furthermore we improved the characterization. Please see the parts page for elaboration.

Proof of concept

We successfully designed a functional plasmid (pSBB1A8YL) for transformation and replication in both Escherichia coli and Y. lipolytica. pSBB1A8YL is also compatible with the BioBrick standard by assembly with our own BioBrick device BBa_K2117005. This was proved by showing that we could utilize the construct in Y. lipolytica to express a heterologous protein, hrGFP. Please see the proof of concept page for elaboration.

Demonstrate your work

We did not have time to check our construct under simulated real-world conditions unfortunately

Special prizes

We have worked hard during the summer to obtain our goals. The results of our efforts are presented below.

Education and Public Engagement

The Biosensor project is an outstanding project, where kits for GMO exercises are sent for free to all highschools in Denmark. The Biosensor kit contains everything needed for making 100 biosensors; DNA with BioBricks from the iGEM registry, enzymes, antibiotics, buffers, ligases, cells and sterile equipment. The students can create biosensors by assembling a detection and response gene using 3A assembly to genetically modify E. coli. Until now GMO exercises have been unavailable for Danish highschools due to costs and law, but with the biosensor project it is no longer a problem. We tested the kit at a local highschool and raised almost 135,000 USD from both Danish and international sponsors and we expect the kit to be distributed by the end of this year. We hope it will inspire and encourage the next generation to work in the field of synthetic biology. Please see the Biosensor page

Software Tool

One of the numerous capabilities and features that iGEM is providing to current and future science disciplines and societies around the globe, is the ability of “building interdisciplinary bridges”. Therefore, the DTU BioBuilders team confidently believes that the developed TaiCO tool will bring wetlabs and computational biology a step closer to bidirectional understanding. This tool is a stand-alone cross-platform software developed in Python (using only standard libraries) and provides comprehensive codon optimization of DNA sequences from protein sequences. Its uniqueness lies in the fact that the researcher can specify the organism and the desired protein sequences to optimize according to the tRNA adaptation index (TAI) for the specified organism. This is novel in terms of codon optimization methods approach is framed by a user friendly GUI along with the option of removal of desired restriction sites from the resulting DNA sequences. Please see the codon optimization page for elaboration.

Hardware

When taking your synbio project to real applications, fast growth is crucial for the viability. The optical density is commonly used as a proximation for cell count and numerous instructions for DIY spectrophotometers exist. However, in order to estimate growth rates, cultures must be sampled over a long period of time. During our project, this was done by a robot handling microtiter plates. We are aware that this is a technology not everybody has access to. Therefore, we took the concept of a DIY spectrophotometer and expanded it to a platform that carries out small scale fermentations comparing growth of your modifed strain to a wild type or other organisms. To take it even further, we encapsuled it in a compact housing that fits on any lab bench. It can be rebuild or modified by anyone with access to a PC, a 3D-printer and a laser cutter. Please see the microfermentation platform page for elaboration.

Milestones

The DTU BioBuilders 2016 team formed!

February

We decided on a project! To utilize a waste source as a substrate for a production organism to produce something valuable such as insulin!

April

The DTU annual BioBrick Tutorial was hosted for Danish iGEM teams from SDU and KU.

May

Our preliminary idea for glycerol as the ideal waste substrate was shot down by industry. Keep going!

June

Getting approached by local journalists - our vision is reaching the greater public!

June

Found a great waste source in form of cold-pressed canola oil sediment, that is just burned off. Out to find an organism that can utilize this waste!

June

Preliminary versions of our Codon Optimization Software was used for the first time to codon optimize the proinsulin gene for Y. lipolytica, our organism of choice!

July

Our BioBrick plasmid, pSB1A8YL, was finally constructed!

July

We approached industry with our idea, and after going back and forth we decided a clear path for our project.

July

Color proteins encoded in pSB1A8YL was successfully expressed in E. coli!

July

After 10 weeks of trial and error, a transformation protocol compliant with Y. lipolytica was obtained. Making this yeast engineerable is getting closer!

August

Our goal to fund the project with 60,000 USD was way over achieved, when the final funding totaled at 120,000 USD! Now we can start buying equipment for our own DTU iGEM lab for future teams.

August

Getting rid of the breadboards! The DIY microfermentation platform has been finally fit into the housing using the printed circuit board we designed.

September

Genome scale modeling is coming along. We achieved getting the same PHPP values for growth rate changes in E. coli when varying oxygen and nutrient uptake rates, as in published papers.

September

Our DIY lab is coming along, with the first growth curve measured with the final prototype of our microfermentation platform.

September

Sequencing confirmed that we constructed the BioBrick Device pTEF:ProInsulin (BBa_K2117002) for optimized proinsulin expression in Y. lipolytica!

September

We optimized preexisting β-Carotene BioBricks by removing illegal restriction sites!

October

Sequencing confirmed that we constructed the BioBrick Device pTEF:HrGFP (BBa_K2117005) for optimized GFP expression in Y. lipolytica!

October

After months of laboratory work and planning, we unleashed the BioSensor project at a local high school with great success!

October

Finally! We managed to insert a gene (URA3) in the Y. lipolytica genome by CRISPR induced homologous recombination. Where is the limit now?!

October

We managed to use FSEOF to stimulate gene amplification targets to optimize beta-Carotene production in Y. lipolytica. Hopefully we can replicate these results in the lab.

Month

We can express proteins in Y. lipolytica by our BioBrick plasmid pSB1A8YL! pTEF:HrGFP was successfully integrated into pSB1A8YL and transformed into Y. lipolytica and convincing GFP expression was observed!

October

Eureka! Y. lipolytica PO1f colonies with changed morphology was observed, indicating that we have successfully knocked out a gene by CRISPR induced error prone NHEJ. Sequencing awaits!

October

Our DIY micro fermentation platform was successfully tested by prospective users: a high school student and a local hackerspace.

October

Our Codon Optimization software finally has a great Graphic User Interface, so we can share this tool with everyone!

October

Giant Jamboree! We can’t wait to show off our hard work!

October

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