Difference between revisions of "Team:EPFL/Proof"

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                <div class="simple-page">
 
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            <section class="">
<div class="column full_size judges-will-not-evaluate">
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                <div class="container">
<h3>★  ALERT! </h3>
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                    <div class="col-md-10 col-md-offset-1 text-center">
<p>This page is used by the judges to evaluate your team for the <a href="https://2016.igem.org/Judging/Medals">gold medal criterion for proof of concept</a>. </p>
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                        <h2 class="lead animate-box">Proof of Concept</h2>
 
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                        <div class="spacer h20"></div>
 
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                        <hr class="animate-box"/>
<p> Delete this box in order to be evaluated for this medal. See more information at <a href="https://2016.igem.org/Judging/Pages_for_Awards/Instructions"> Instructions for Pages for awards</a>.</p>
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                        <div class="spacer h20"></div>
</div>
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                        <p class="sub-lead text-justify animate-box">
 
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                            When we started the lab project at the beginning of the summer,
 
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                            nobody on the team could imagine the we would end up making something
 
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                            that might actually work. But we had to change our mind! We actually
 
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                            managed to build a biologically inducible NOT gate!
 
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                        </p>                      
<div class="column full_size">
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                        <br>
 
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                        <p class="sub-lead text-justify animate-box">
 
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                            Why all this excitement? One of the goals of synthetic biology is to control
<p>
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                            the behaviour of living organisms in order to make our life easier. One way
iGEM teams are great at making things work! We value teams not only doing an incredible job with theoretical models and experiments, but also in taking the first steps to make their project real.  
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                            to achieve this goal is to create biological circuits within cells, capable
</p>
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                            of executing complex logic tasks. The NOT gate is the first step to building
 
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                            these complex circuits and is thus the first basic Boolean Operator that we
 
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                            decided to create. However, using Intelligene, we can potentially build any
<h4> What should we do for our proof of concept? </h4>
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                            gate. <a href="https://2016.igem.org/Team:EPFL/Results#CYC">Click here to see the summary of our results regarding our experiments
<p>  
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                                on CYC minimal promoter.</a>  
You can assemble a device from BioBricks and show it works. You could build some equipment if you're competing for the hardware award. You can create a working model of your software for the software award. Please note that this not an exhaustive list of activities you can do to fulfill the gold medal criterion. As always, your aim is to impress the judges!
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                        </p>
</p>
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                        <br>
 
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                        <p class="sub-lead text-justify">
</div>
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                            Our NOT gate is unique for many reasons. Firstly, it is built on an innovative
 
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                            system based on scaffold RNAs (scRNAs). Secondly, to our knowledge, our repressor
 
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                            system represents the <a href="https://2016.igem.org/Team:EPFL/Results">first successful
 
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                            example</a> of repression in yeast using scRNAs.  
</div>
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                            Finally, the NOT gate is inducible and thus it is an important proof of concept as a first
 
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                            step towards biosensor systems, in which a molecule acts as an INPUT and can switch between
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                            ON/OFF states.
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                        </p>
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                        <br>
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                        <p class="sub-lead text-justify">In our gate, the INPUT signal is galactose and it switches the system OFF by inducing repression of GFP expression.
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                        </p>
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                        <br>
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                        <img src="https://static.igem.org/mediawiki/2016/0/03/Results_not_gate_figB.png" class="text-center proof-img">
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                        <div class="spacer h20"></div>
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                        <h2 class="lead text-center">Design and Parts</h2>
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                        <br>
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                        <p class="sub-lead text-justify">
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                            We integrated the following elements into the yeast genome: dCas9 coding
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                            sequence (controlled by the inducible promoter GAL1), the reporter gene
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                            yeGFP under the CYC1 promoter, the scRNA Cyc1_PP7 and the fused repressor
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                            protein PCP_Mxi1. When all the components are present but GAL inducer is
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                            absent, dCas9 is not expressed and GFP is produced. On the other hand, when
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                            the GAL inducer is present, dCas9 is expressed and it drives  the repressor
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                            module to the c6 region of the CYC1 promoter. Then, Mxi1 mediates chromatin
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                            condensation via histone deacetylase, and the expression of GFP strongly
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                            decreases. GFP expression were measured using Fluorescence-Activated Cell
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                            Sorting (FACS) and results are reported <a href="https://2016.igem.org/Team:EPFL/Results#NOT gate">here</a>.
 +
                        </p>
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                        <br>
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                        <img class="text-center proof-img" src="https://static.igem.org/mediawiki/2016/4/4e/NOT_gate_RESULTS.png">
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                    </div>
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                </div>
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            </section>
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        </div>
 
</html>
 
</html>
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Latest revision as of 03:19, 20 October 2016

iGEM EPFL 2016

Proof of Concept


When we started the lab project at the beginning of the summer, nobody on the team could imagine the we would end up making something that might actually work. But we had to change our mind! We actually managed to build a biologically inducible NOT gate!


Why all this excitement? One of the goals of synthetic biology is to control the behaviour of living organisms in order to make our life easier. One way to achieve this goal is to create biological circuits within cells, capable of executing complex logic tasks. The NOT gate is the first step to building these complex circuits and is thus the first basic Boolean Operator that we decided to create. However, using Intelligene, we can potentially build any gate. Click here to see the summary of our results regarding our experiments on CYC minimal promoter.


Our NOT gate is unique for many reasons. Firstly, it is built on an innovative system based on scaffold RNAs (scRNAs). Secondly, to our knowledge, our repressor system represents the first successful example of repression in yeast using scRNAs. Finally, the NOT gate is inducible and thus it is an important proof of concept as a first step towards biosensor systems, in which a molecule acts as an INPUT and can switch between ON/OFF states.


In our gate, the INPUT signal is galactose and it switches the system OFF by inducing repression of GFP expression.


Design and Parts


We integrated the following elements into the yeast genome: dCas9 coding sequence (controlled by the inducible promoter GAL1), the reporter gene yeGFP under the CYC1 promoter, the scRNA Cyc1_PP7 and the fused repressor protein PCP_Mxi1. When all the components are present but GAL inducer is absent, dCas9 is not expressed and GFP is produced. On the other hand, when the GAL inducer is present, dCas9 is expressed and it drives the repressor module to the c6 region of the CYC1 promoter. Then, Mxi1 mediates chromatin condensation via histone deacetylase, and the expression of GFP strongly decreases. GFP expression were measured using Fluorescence-Activated Cell Sorting (FACS) and results are reported here.