Team:ESBS-Strasbourg/Project/Application

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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team">&nbsp;&nbsp;TEAM</a></p>
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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team">
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&nbsp;&nbsp;TEAM</a></p>
<ul>
<ul>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team">Overview</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team">
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Overview</a></li>
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#under">
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#under">
Students</a></li>
Students</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#instructors">
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#advisors">
Advisors</a></li>
Advisors</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#instructors">
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Instructors</a></li>
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#uni">
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#uni">
Strasbourg</a></li>
Strasbourg</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Team#collaboration">
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Collaboration</a></li>
                                
                                
</ul>
</ul>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project">&nbsp;&nbsp;PROJECT</a></p>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project">
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&nbsp;&nbsp;PROJECT</a></p>
<ul>
<ul>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project">Overview</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project">
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Overview</a></li>
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy">
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy">
Strategy</a></li>
Strategy</a></li>
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                                <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/visual">
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Visual Description</a></li>
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Application">
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Application">
Application</a></li>
Application</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Acknowledgment">Acknowledgment</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Acknowledgment">
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Acknowledgment</a></li>
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">
<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">
Reference</a></li>
Reference</a></li>
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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results">&nbsp;&nbsp;RESULTS</a></p>                 
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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Biobricks">
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&nbsp;&nbsp;RESULTS</a></p>                 
                         <ul>
                         <ul>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Biobricks">Biobricks</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Biobricks">
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Biobricks</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Assembly">
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<font size="3">Biobrick Assembly Technique</font></a></li>
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Characterization">
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Characterization">
Characterization</a></li>
Characterization</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Modelling">Modelling</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Modelling">
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Modeling</a></li>
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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook">&nbsp;&nbsp;NOTEBOOK</a></p>
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<p><br/><a>
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&nbsp;&nbsp;NOTEBOOK</a></p>
                         <ul>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Syntethic">Synthetic Photoreceptors</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Syntethic">
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Synthetic Photoreceptors</a></li>
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Microfluidics">
                                 <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Microfluidics">
Microfluidics</a></li>
Microfluidics</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Labbook">Lab-book</a></li>
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                                <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Results/Device">Lighting device</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Notebook/Labbook">
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Lab-book</a></li>
</ul>
</ul>
</li>
</li>
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<li>
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<p><br/><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice">
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HUMAN PRACTICE</a></p>
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                        <ul>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice#organisation">
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Organisation</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice#survey">
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Survey</a></li>
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                                <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice#video">
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The ClpX video</a></li>
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                                <li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice#game">
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The ClpX game</a></li>
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<li><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Humanpractice#safety">
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Project Safety</a></li>
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</ul>
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</li>
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                 <li class="last">
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<p><br />
<p><br />
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Sponsors">&nbsp;&nbsp;SPONSORS</a></p>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Sponsors">
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&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;SPONSORS</a></p>
</li>
</li>
</ul>
</ul>
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</div>
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</div>
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<div class="heading">PROJECT INDEX</div>
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<div class="heading">Application</div>
<div class="desc">
<div class="desc">
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Our device construction is divided into 4 components :<br><br>
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<ul>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy#degradation">1. Degradation system</a>
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<li><a href="#knock">Protein analysis</a></li>
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<li><a href="#flip">Flip Flop</a></li>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy#light">2. Light detection system</a>
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<li><a href="#geneos">Genetic Oscillator </a></li>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy#tagging">3. Protein Tagging</a>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Strategy#system">4. Light controllable protease</a>
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/notebook">Notebook</a>
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</p></div>
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<span style="color:ivory;">
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&nbsp;&nbsp;
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<a href="https://2010.igem.org/Team:ESBS-Strasbourg/science">
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<img border="0" src="https://static.igem.org/mediawiki/2010/d/da/ESBS-Strasbourg-Clpx.gif" width="70" height="85" ></a>
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Let me guide you</span>
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<div class="heading">Applications:</div>
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As previously described, our degradation system consists of an engineered protease which can be activated by light impulses. This allows a tight control over the catalytic activity core enabling the modulation of protein function in a general fashion with the combined characteristics of specificity, high temporal precision and rapid reversibility.
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The system is easily adaptable to new targets proteins, the target-labeling only requires the fusion to the specific degradation tag and PIF. This offers a very cheap, easy and applicable method for protein analysis.
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<br><br>
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One of the major advantages is the "non invasive" induction of the protein degradation. Chemical genetics enable perturbations through the introduction of cell membrane-permeable small molecules, allowing the conditional regulation of activity through non-covalent and reversible interactions which is convenient for studies at the cellular level. The use of photolabile ‘‘caged’’ chemical compounds allows to affect subcellular targets in a second-timescale. Some chemical photoswitches such as azobenzene even offer reversible photo-control when attached to macromolecules <i><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">[26]</a></i>. However, the requirement to introduce exogenous, chemically modified materials into cells limits the use of these methods in biological applications.
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<br><br>
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<a name="knock"></a>
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<p><b>A universal tool for protein analysis</b></p>
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A complex understanding of living cells requires methods to affect and control the activities of their constituent proteins at fine spatial and temporal resolutions. Measuring responses to precise perturbations, allows the testing and improvement of predictive models of cellular networks.<br>
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Instead of the induction by chemical agents, the induction of our system is achieved by light impulses. Chemical agents can interfere with host cell metabolism thereby changing their behavior and impact on complex pathways which may create the impossibility of obtaining neutral results. The induction by light enables the studies of target proteins in a natural unaffected environment.
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Another alternative in protein function studies is the use of gene-knockout techniques. These approaches can provide information about incompletely known gene functions, for instance the role of the corresponding protein in interactions with other proteins. But they do not provide any possibility to study kinetic characteristics or the dynamic of protein interactions.
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Our system provides a very effective alternative to this approach. Due to the possibility to regulate protein degradation by light-guided on/off switching of the protease activity, it is a tool to control the level of target protein concentration. The common gene knock out methods do not provide any insight to the impact of varying protein concentration.
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This new system allows through its high turnover rate for proteins <i><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">[13]</a></i> a complete degradation of the protein, simulating a gene knockdown. After light induction with 660nm the system should rest in its active state until a light impulse of 730nm changes its back on its inactive state. So a permanent on switch simulates a gene knockdown as every protein is immediately degraded and a permanent off switch favors the native gene expression.
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Abstract
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The aim of our project is to engineer a new fundamental component that could be universally used to build more complex or more controllable biological circuits inside chassis organisms. This new component consists of the E.coli protease ClpXP to which the phytochrome B of arabidopsis thaliana is fused. Any given protein can be degraded as long as it is tagged with our especially designed Biobrick containing a PIF sequence. This Biobrick can be added to the C-terminal end by standard assembly methods. The activity of this system is tightly controlled and reversible by light inducement.
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The system can be constitutively expressed in the chassis but remains  inactive for the tagged protein. However it is expected to stay active for the background of naturally SsrA tagged proteins and so it will not interfere with the metabolism of E.coli. Instantly after the light inducement the system is turned on, due to the lack of transcriptional or translational delay and is expected to remain active until another light signal turns it off.
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With alternating light impulses it should be also possible to adjust certain protein levels by switching the system on and off. This allows the control of complex protein dynamics in vivo as all protein levels can be adjusted to simulate the desired condition.
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In our modeling part we will used this system for a genetic oscillator which could be used for multi step synthesis.  
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Such a system would be useful in any domain of research. The tight control of light regulation should enable gene expression to be spatially and temporally controlled, leading to potential applications in the production of biological material composites and the study of multicellular signalling networks. Both medical researches as fundamental cell biology require a deep understanding of protein function and their role in interactions with other proteins as in signal cascades and metabolic pathways. The possibility to control protein dynamics in a general manner offers a great approach for medical treatments.  
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<p><b>Theoretical Background:</b></p>
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An example of this tightly controlled system can be seen in figure 1.
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Our system combines two main components: the ClpXP protease and the phytochrome B/ PIF system The ClpXP component is important for the specificity and the phytochrome B/ PIF system is important for the light sensitivity.
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<a target="_blank" href="https://static.igem.org/mediawiki/2010/4/4b/ESBS-Strasbourg-Appfig1.jpg">
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<img src="https://static.igem.org/mediawiki/2010/4/4b/ESBS-Strasbourg-Appfig1.jpg" width="500px" height="400px"></a>
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<div style="position: relative; width: 500px; height: 100px; id="layer1" align="justify">
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<a target="_blank" href="https://static.igem.org/mediawiki/2010/4/4b/ESBS-Strasbourg-Appfig1.jpg">
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<i><font color="#E9AF03" size="1">Figure 1 An example of how protein levels can be adjusted by alternating light impulses. In the beginning, the protein levels are at native concentration. After a light impulse the degradation system is on and will degrade the protein very fast and efficient. These first two steps are like a gene knock out with an on and off switch. After this an alternation of light impulses turn the system on and off in certain time periods. So the protease is turned between active and inactive. This allows the fine tuned adjustment of protein concentration in the cells.</font></i></a></div>
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<a name="flip"></a>
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<p><b>Flip Flop</b></p>
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The system further allows the control of transcriptional regulation. Another application of this system is the creating of a flip flop mechanism which can be induced by light. This can allow the expression of two different genes sequentially. In the beginning just the gene in gene cassette one is expressed. In the example this is the GPF protein. After a light induction the gene expression is switched to gene cassette two, which is RFP in this example. Figure 2 gives a more detailed description of this mechanism. This allows the tight control of two genes in one host organism. The tight control and sequentially nature of this flip flop mechanism allows a light-controlled multistep synthesis which a huge potential for industrial applications.
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-Specificity : We based our system on the ClpXP protease, from E. coli. In wild type E. coli, ClpX forms a hexametric ring and binds to a double heptamer of ClpP. ClpX recognizes a specific C-terminal degradation tag called SsrA and starts to unfold the tagged protein. The denatured polypeptide is translocated into the ClpP subunit, which breaks down peptide bonds.
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Moreover several enzymatic steps can be conducted sequentially in one single organism, so even complex biomolecules can be produced in a single bioreactor. This is an enormous gain of time and money.  
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Note : In the native organism, the SsrA tag is added to incomplete proteins whose translation has been aborted. Thus, misfunctionnal proteins do not accumulate inside the cell.
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<a target="_blank" href="https://static.igem.org/mediawiki/2010/e/e0/ESBS-Strasbourg-Appfig2.jpg">
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<img src="https://static.igem.org/mediawiki/2010/e/e0/ESBS-Strasbourg-Appfig2.jpg" width="500px" height="325px"></a>
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<div style="position: relative; width: 500px; height: 100px; id="layer1" align="justify">
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<a target="_blank" href="https://static.igem.org/mediawiki/2010/e/e0/ESBS-Strasbourg-Appfig2.jpg">
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<i><font color="#E9AF03" size="1" >Figure 2 The flip flop mechanism. This mechanism shows how to change from the expression of a gene in the first cassette to a gene in the second cassette. P is the promoter, CR is a cross repressor, the symbol besides the cross repressor symbolize that this protein is tagged with the DAS degradation sequence, CA is a cross activator and C is the gene cassette. At start condition P1 expresses all the proteins of gene cassette one (C1). The cross repressor for promoter P2 (CR2) represses P2 stronger than the cross activator for P2 (CA2) activates it. This results in an expression of the GFP protein. After light induction with 660nm, the ClpXP protease will degrade the tagged CR2. After the degradation of the repressor, the cross activator will activate the promoter P2 which will lead to an complete expression of gene cassette two (C2). The CR1 of the C2 will now repress P1 which will terminate the expression of gene cassette one. So a switch from C1 to C2 is achieved. An light impulse of 730nm will switch of the ClpXP protease. With another light impulse of 660nm the ClpXP system will be turned on and a switch from C2 to C1 will occur. A detailed analysis of this mechanism can be seen in the modeling part.</font></i></a></div>
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<br><br><br><br><br><br>
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-Light sensitivity : We used PhyB (phytochrome B) from A. thaliana and its natural chromophore PCB (phycocyanobilline). This system has two configurations. The Pf configuration which describes the inactive state of the PhyB and the Pfr configuration which describes the active state. The PCB of the holo phytochrome can absorb red light (pick at 660 nm) and through a structural transition it reaches its activated Pfr state. Under far red light (730 nm) the holo phytochrome goes back to its fundamental inactive Pr state. PIF-3 and PIF-6 (Phytochrome Interacting Factor 3 and 6) are natural partners of PhyB in A. thaliana and bind to PhyB in the Pfr state but not in the Pr state. This is the basis of the controllable feature of our system.
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<a name="geneos"></a>
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<p><b>Genetic Oscillator</b></p>
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The idea of the flip flop mechanism can be extended to a genetic oscillator with three, four or even more sequential steps. Such an implementation would present a genetically encoded device to store multiple bits of information within a living cell.<br>
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Natural oscillator circuits are autonomous orchestrating periodic inductions of specific target genes and are found in central and peripheral circadian clocks <i><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">[38]</a></i>. Many physiological activities are coordinated  by circadian pacemakers <i><a href="https://2010.igem.org/Team:ESBS-Strasbourg/Project/Reference">[43],[44]</a></i>, making them particular interesting. Synthetic oscillator circuits which mediate protein expression dynamics could provide new insights into protein networks of by simulating natural conditions. <br>
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Figure 3 shows an example of a three step oscillator. This oscillator is tightly controlled by light and allows the sequentially expression of three different genes.
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<p><b>How does the native ClpX system work?</b></p>
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There are different variant of SsrA tags which are more or less efficiently recognized by ClpX. The DAS tag (T.Baker et al.) has a higher Kd value than wild type SsrA tag, and thus degradation of DAS-tagged proteins is not significant.
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In vivo though, DAS-tagged protein can still be significantly degraded within the range of physiological concentrations under the action of an adaptator protein (SspB) which help tethering the tagged protein to the protease.
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Our idea is to replace this adaptator system with a light sensitive tethering system.
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<i><font color="#E9AF03" size="1">Figure 3 The three step oscillator. The principle is the same as with the flip flop mechanism. In the beginning gene cassette C1 with GFP is expressed and CR2 and CR3 represses P2 and P3. After a light impulse of 660nm, CR2 and CR3 are degraded and CA2 can activate P2. The ClpXP system will be switch off by a light impulse with 730nm. Due to the absence of CR2 and CR3 gene cassette C2 and C3 will be no longer repressed. But as just an CA for the P2 was expressed from C1, C2 will be far stronger expressed than C3. So the CR3 on the C2 will terminate gene expression of P3 and thus will terminate the whole expression of C3. CR1 will also repress the expression of P1 and thus the whole expression of C1. After another light impulse of 660nm, the switch from gene cassette two (C1) to gene cassette three (C3) will occur with the same mechanism as from C1 to C2. </font></i></a>.</font></i></a></div>
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The light-dependent protease with its specific degradation tags is a versatile approach for transcriptional regulation and protein analysis. It gives the synthetic biology community a basic device with a broad range of applications in fundamental research. The only limits are imagination and motivation.
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<p><b>How did we proceed?</b></p>
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For the protease, we fused either the 642 or 908 first amino acids of PhyB to a trimer of the last 364 amino acids of ClpX. Indeed, the N terminal end of ClpX contains a domain, which is responsible for interaction with its natural adaptator protein (SspB) that we would avoid. As this N-terminal domain is also partially responsible for ClpX subunits complexation into an hexamer, fusing three C-terminal end of ClpX together with appropriate linkers increases the stability of the system (T. Baker et al.) in the absence of this N-terminal domain.
 
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The target protein will be tagged with both DAS at C-terminal end, and with the Active Phytochrome Binding (APB) motif (the first hundred amino acids of PIF-3 or PIF-6), either at N terminal end or just upstream the DAS tag.
 
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Under red light, the APB motif of the target protein binds to PhyB and facilitate recognition of DAS tag by ClpX, thus promoting degradation.
 
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Far red light instantly inhibits degradation of further tagged proteins.
 
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Latest revision as of 00:15, 28 October 2010

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ESBS - Strasbourg



Application

  
Let me guide you
Applications:

As previously described, our degradation system consists of an engineered protease which can be activated by light impulses. This allows a tight control over the catalytic activity core enabling the modulation of protein function in a general fashion with the combined characteristics of specificity, high temporal precision and rapid reversibility. The system is easily adaptable to new targets proteins, the target-labeling only requires the fusion to the specific degradation tag and PIF. This offers a very cheap, easy and applicable method for protein analysis.

One of the major advantages is the "non invasive" induction of the protein degradation. Chemical genetics enable perturbations through the introduction of cell membrane-permeable small molecules, allowing the conditional regulation of activity through non-covalent and reversible interactions which is convenient for studies at the cellular level. The use of photolabile ‘‘caged’’ chemical compounds allows to affect subcellular targets in a second-timescale. Some chemical photoswitches such as azobenzene even offer reversible photo-control when attached to macromolecules [26]. However, the requirement to introduce exogenous, chemically modified materials into cells limits the use of these methods in biological applications.

A universal tool for protein analysis

A complex understanding of living cells requires methods to affect and control the activities of their constituent proteins at fine spatial and temporal resolutions. Measuring responses to precise perturbations, allows the testing and improvement of predictive models of cellular networks.
Instead of the induction by chemical agents, the induction of our system is achieved by light impulses. Chemical agents can interfere with host cell metabolism thereby changing their behavior and impact on complex pathways which may create the impossibility of obtaining neutral results. The induction by light enables the studies of target proteins in a natural unaffected environment.
Another alternative in protein function studies is the use of gene-knockout techniques. These approaches can provide information about incompletely known gene functions, for instance the role of the corresponding protein in interactions with other proteins. But they do not provide any possibility to study kinetic characteristics or the dynamic of protein interactions.
Our system provides a very effective alternative to this approach. Due to the possibility to regulate protein degradation by light-guided on/off switching of the protease activity, it is a tool to control the level of target protein concentration. The common gene knock out methods do not provide any insight to the impact of varying protein concentration.

This new system allows through its high turnover rate for proteins [13] a complete degradation of the protein, simulating a gene knockdown. After light induction with 660nm the system should rest in its active state until a light impulse of 730nm changes its back on its inactive state. So a permanent on switch simulates a gene knockdown as every protein is immediately degraded and a permanent off switch favors the native gene expression.

With alternating light impulses it should be also possible to adjust certain protein levels by switching the system on and off. This allows the control of complex protein dynamics in vivo as all protein levels can be adjusted to simulate the desired condition.

Such a system would be useful in any domain of research. The tight control of light regulation should enable gene expression to be spatially and temporally controlled, leading to potential applications in the production of biological material composites and the study of multicellular signalling networks. Both medical researches as fundamental cell biology require a deep understanding of protein function and their role in interactions with other proteins as in signal cascades and metabolic pathways. The possibility to control protein dynamics in a general manner offers a great approach for medical treatments.

An example of this tightly controlled system can be seen in figure 1.

Flip Flop

The system further allows the control of transcriptional regulation. Another application of this system is the creating of a flip flop mechanism which can be induced by light. This can allow the expression of two different genes sequentially. In the beginning just the gene in gene cassette one is expressed. In the example this is the GPF protein. After a light induction the gene expression is switched to gene cassette two, which is RFP in this example. Figure 2 gives a more detailed description of this mechanism. This allows the tight control of two genes in one host organism. The tight control and sequentially nature of this flip flop mechanism allows a light-controlled multistep synthesis which a huge potential for industrial applications.
Moreover several enzymatic steps can be conducted sequentially in one single organism, so even complex biomolecules can be produced in a single bioreactor. This is an enormous gain of time and money.


Figure 2 The flip flop mechanism. This mechanism shows how to change from the expression of a gene in the first cassette to a gene in the second cassette. P is the promoter, CR is a cross repressor, the symbol besides the cross repressor symbolize that this protein is tagged with the DAS degradation sequence, CA is a cross activator and C is the gene cassette. At start condition P1 expresses all the proteins of gene cassette one (C1). The cross repressor for promoter P2 (CR2) represses P2 stronger than the cross activator for P2 (CA2) activates it. This results in an expression of the GFP protein. After light induction with 660nm, the ClpXP protease will degrade the tagged CR2. After the degradation of the repressor, the cross activator will activate the promoter P2 which will lead to an complete expression of gene cassette two (C2). The CR1 of the C2 will now repress P1 which will terminate the expression of gene cassette one. So a switch from C1 to C2 is achieved. An light impulse of 730nm will switch of the ClpXP protease. With another light impulse of 660nm the ClpXP system will be turned on and a switch from C2 to C1 will occur. A detailed analysis of this mechanism can be seen in the modeling part.







Genetic Oscillator

The idea of the flip flop mechanism can be extended to a genetic oscillator with three, four or even more sequential steps. Such an implementation would present a genetically encoded device to store multiple bits of information within a living cell.
Natural oscillator circuits are autonomous orchestrating periodic inductions of specific target genes and are found in central and peripheral circadian clocks [38]. Many physiological activities are coordinated by circadian pacemakers [43],[44], making them particular interesting. Synthetic oscillator circuits which mediate protein expression dynamics could provide new insights into protein networks of by simulating natural conditions.

Figure 3 shows an example of a three step oscillator. This oscillator is tightly controlled by light and allows the sequentially expression of three different genes.


Figure 3 The three step oscillator. The principle is the same as with the flip flop mechanism. In the beginning gene cassette C1 with GFP is expressed and CR2 and CR3 represses P2 and P3. After a light impulse of 660nm, CR2 and CR3 are degraded and CA2 can activate P2. The ClpXP system will be switch off by a light impulse with 730nm. Due to the absence of CR2 and CR3 gene cassette C2 and C3 will be no longer repressed. But as just an CA for the P2 was expressed from C1, C2 will be far stronger expressed than C3. So the CR3 on the C2 will terminate gene expression of P3 and thus will terminate the whole expression of C3. CR1 will also repress the expression of P1 and thus the whole expression of C1. After another light impulse of 660nm, the switch from gene cassette two (C1) to gene cassette three (C3) will occur with the same mechanism as from C1 to C2. .



The light-dependent protease with its specific degradation tags is a versatile approach for transcriptional regulation and protein analysis. It gives the synthetic biology community a basic device with a broad range of applications in fundamental research. The only limits are imagination and motivation.