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| | <table id="toc" class="toc"><tr><td><div id="toctitle"><h2>Contents</h2></div> | | <table id="toc" class="toc"><tr><td><div id="toctitle"><h2>Contents</h2></div> |
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| | <li class="toclevel-1"><a href="#References"><span class="tocnumber">4</span> <span class="toctext">References</span></a></li> | | <li class="toclevel-1"><a href="#References"><span class="tocnumber">4</span> <span class="toctext">References</span></a></li> |
| | </td></tr></table> | | </td></tr></table> |
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| | <nowiki><div class="art-postcontent"><a name="Circuit"></a><h1><span class="mw-headline"> <b>The circuit</b> </span></h1></div></nowiki> | | <nowiki><div class="art-postcontent"><a name="Circuit"></a><h1><span class="mw-headline"> <b>The circuit</b> </span></h1></div></nowiki> |
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| - | <div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><img alt="" src="https://static.igem.org/mediawiki/2011/8/89/QS_system_circuito.png" class="thumbimage" width="85%"></a></div></div> | + | <div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><img alt="" src="https://static.igem.org/mediawiki/2011/c/c7/QS_system_synthetic_circuit.png" class="thumbimage" width="85%"></a></div> |
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| | + | <div style='text-align:center; font-size: 12px; font-style:italic; margin-top=50px; padding-top=50px;'>Schematic description of Ctrl+E system behavior</div> |
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| - | <p>The goal of the project is to provide a proof of concept for the design and implementation of an ‘<em>in vivo</em> control system’ in <em>E. coli</em>: <b>CTRL-E. </b> This circuit is realized by assembling BioBrick parts with rational criteria, exploiting the information available for the basic modules (experimental data) to support a model-based approach. | + | <p>The goal of the project is to provide a proof of concept for the design and implementation of an ‘<em>in vivo</em> control system’ in <em>E. coli</em>: <b>CTRL+E. </b> This circuit is realized by assembling BioBrick parts with rational criteria, exploiting the information available for the basic modules (experimental data) to support a model-based approach. |
| | The circuit implementing the negative-feedback loop control is designed with the purpose to keep constant over time the concentration of the cellular signalling molecule 3OC6-HSL (involved in <em>V. fischeri</em> quorum sensing system), by regulating the expression of an enzyme that degrades it.</p> | | The circuit implementing the negative-feedback loop control is designed with the purpose to keep constant over time the concentration of the cellular signalling molecule 3OC6-HSL (involved in <em>V. fischeri</em> quorum sensing system), by regulating the expression of an enzyme that degrades it.</p> |
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| - | <b>CTRL-E.</b> is composed by two elements: a LuxI (BBa_C0061, 3OC6-HSL synthetase) expression cassette driven by the aTc-inducible pTet promoter and an AiiA (BBa_C0060, autoinducer lactonase) expression cassette driven by the 3OC6-HSL-inducible pLux promoter.</p> | + | <b>CTRL+E.</b> is composed by two elements: a LuxI (BBa_C0061, 3OC6-HSL synthetase) expression cassette driven by the aTc-inducible pTet promoter and an AiiA (BBa_C0060, autoinducer lactonase) expression cassette driven by the 3OC6-HSL-inducible pLux promoter.</p> |
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| - | In <em>E.coli</em> MGZ1 strain <a href="#Cox">(<i><b>Cox RS 3rd </b> et al. 2007</i>)</i></a>, singled out for the case study, pTet promoter is normally repressed, due to the presence of <em>tetR</em> gene, from Z1 cassette, integrated in its genome (<i><b>Lutz R</b> et al. 1997</i>): TetR product is able to inhibit the activity of pTet, thereby the 3OC6-HSL production. This allows the modulation of pTet activity by using tetracycline or anhydrotetracyclin (aTc) as inducers. A variation in the inducer concentration in input permits to modify the set-point of the 3OC6-HSL production in output. | + | In <em>E.coli</em> MGZ1 strain <a href="#Cox">(<i><b>Cox RS 3rd </b> et al. 2007)</i></a>, singled out for the case study, pTet promoter is normally repressed, due to the presence of <em>tetR</em> gene, from Z1 cassette, integrated in its genome <a href="#Lutz">(<i><b>Lutz R</b> et al. 1997</i>)</a>: TetR product is able to inhibit the activity of pTet, thereby the 3OC6-HSL production. This allows the modulation of pTet activity by using tetracycline or anhydrotetracyclin (aTc) as inducers. A variation in the inducer concentration in input permits to modify the set-point of the 3OC6-HSL production in output. |
| | When a critical amount of signal molecule is reached into the cells, the complex consisting of 3OC6-HSL and its transcriptional factor LuxR (constitutively expressed by pLambda promoter) is able to activate the pLux promoter, that regulates the expression of AiiA lactonase. | | When a critical amount of signal molecule is reached into the cells, the complex consisting of 3OC6-HSL and its transcriptional factor LuxR (constitutively expressed by pLambda promoter) is able to activate the pLux promoter, that regulates the expression of AiiA lactonase. |
| | So the HSL molecule regulates its own production via a negative feed-back loop system.</p> | | So the HSL molecule regulates its own production via a negative feed-back loop system.</p> |
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| | <a name="Circuit_design"></a><div class="art-postcontent"><h1> <span class="mw-headline"> <b>Circuit design</b> </span></h1></div> | | <a name="Circuit_design"></a><div class="art-postcontent"><h1> <span class="mw-headline"> <b>Circuit design</b> </span></h1></div> |
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| | + | <div style='text-align:center; font-size: 12px; font-style:italic; margin-top=50px; padding-top=50px;'>Schematic description of Ctrl+E system behavior</div> |
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| - | <p>The circuit was built assembling <em>aiiA</em> protein generator and <em>luxI</em> translational unit with <partinfo>BBa_K081022</partinfo> composite part (<i><b>Pasotti L</b> et al. 2011</i>). Due to the length of the final circuit, the BioBrick parts were selected to reduce the internal homology, that could be cause of recombination or mutation events (<i><b>Sleight SC</b> et al. 2010</i>) (since the circuit is implemented in a strain expressing <em>recA</em> gene). The <partinfo>BBa_K081022</partinfo> part was purposely selected: in fact, the single terminator <partinfo>BBa_B1006</partinfo> and the double terminator <partinfo>BBa_B0015</partinfo> alignment does not show a significant sequence homology.</p> | + | <p>The circuit was built assembling <em>aiiA</em> protein generator and <em>luxI</em> translational unit with <partinfo>BBa_K081022</partinfo> composite part <a href="#Paso">(<i><b>Pasotti L</b> et al. 2011</i>) </a>. Due to the length of the final circuit, the BioBrick parts were selected to reduce the internal homology, that could be cause of recombination or mutation events <a href="#Sleight">(<i><b>Sleight SC</b> et al. 2010</i>) </a> (since the circuit is implemented in a strain expressing <em>recA</em> gene). The <partinfo>BBa_K081022</partinfo> part was purposely selected: in fact, the single terminator <partinfo>BBa_B1006</partinfo> and the double terminator <partinfo>BBa_B0015</partinfo> alignment does not show a significant sequence homology.</p> |
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| | The circuit was designed without a terminator element downstream the <em>luxI</em> coding sequence. The lack of a terminator doesn't affect the behaviour of our circuit, since a terminator (<partinfo>BBa_B0054</partinfo>) is present in the low copy plasmid <partinfo>pSB4C5</partinfo> used. | | The circuit was designed without a terminator element downstream the <em>luxI</em> coding sequence. The lack of a terminator doesn't affect the behaviour of our circuit, since a terminator (<partinfo>BBa_B0054</partinfo>) is present in the low copy plasmid <partinfo>pSB4C5</partinfo> used. |
| - | The <em>aiiA</em> and <em>luxI</em> coding sequences are LVA tagged to decrease the protein half-life. (<i><b>Andersen JB</b> et al. 1998</i>)</p> | + | The <em>aiiA</em> and <em>luxI</em> coding sequences are LVA tagged to decrease the protein half-life. <a href="#Andersen">(<i><b>Andersen JB</b> et al. 1998</i>)</a></p> |
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| - | In order to achieve the desired system output, a fine tuning of the whole circuit is required. A deeper understanding of the transcriptional and translational strength of the regulatory elements (promoter+RBS in several combination) and of the kinetic and the activity of the involved enzymes can be exploited to identify a mathematical model able to predict the behaviour of the controlled system, in order to avoid a cost and time expensive combinatorial approach.(<i><b>Howard M Salis</b> et al. 2009</i>)</p> | + | In order to achieve the desired system output, a fine tuning of the whole circuit is required. A deeper understanding of the transcriptional and translational strength of the regulatory elements (promoter+RBS in several combination) and of the kinetics and the activity of the involved enzymes can be exploited to identify a mathematical model able to predict the behaviour of the controlled system, in order to avoid a cost and time expensive combinatorial approach.<a href="#Salis">(<i><b>Salis HM</b> et al. 2009</i>)</a></p> |
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| | <p>All modules were tested in <em>E.coli</em> MGZ1 strain.</p> | | <p>All modules were tested in <em>E.coli</em> MGZ1 strain.</p> |
| | <p>More in detail, the <b>promoters</b> were tested with four different <b>RBSs</b> (RBS<em>X</em> stands for one of these BioBrick parts: <partinfo>BBa_B0030</partinfo>, <partinfo>BBa_B0031</partinfo>, <partinfo>BBa_B0032</partinfo>, <partinfo>BBa_B0034</partinfo>) upstream of an <em>mRFP</em> coding device. The <b>enzymes</b> were assembled under the control of pTet promoter and HSL was measured (using <b>T9002 biosensor</b> – see <a href='https://2011.igem.org/Team:UNIPV-Pavia/Project/Modelling#t9002'>Modelling section</a>) to determine the degradation or synthesis kinetics. | | <p>More in detail, the <b>promoters</b> were tested with four different <b>RBSs</b> (RBS<em>X</em> stands for one of these BioBrick parts: <partinfo>BBa_B0030</partinfo>, <partinfo>BBa_B0031</partinfo>, <partinfo>BBa_B0032</partinfo>, <partinfo>BBa_B0034</partinfo>) upstream of an <em>mRFP</em> coding device. The <b>enzymes</b> were assembled under the control of pTet promoter and HSL was measured (using <b>T9002 biosensor</b> – see <a href='https://2011.igem.org/Team:UNIPV-Pavia/Project/Modelling#t9002'>Modelling section</a>) to determine the degradation or synthesis kinetics. |
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| - | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/4/43/Caratterizzazione_ptet.jpg" class="thumbimage" width="33%"></a></div></div> | + | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/9/91/Caratterizzazione_ptetN.jpg" class="thumbimage" width="33%"></a></div></div> |
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| - | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/0/0e/Caratterizzazione_plux.jpg" class="thumbimage" width="70%"></a></div></div> | + | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/7/79/Caratterizzazione_pluxN.jpg" class="thumbimage" width="60%"></a></div></div> |
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| | Note: Whilst in the final circuit <em>aiiA</em> expression is regulated by pLux promoter, in the measurement system it is driven by pTet promoter in order to avoid interference between inducer and gene product. | | Note: Whilst in the final circuit <em>aiiA</em> expression is regulated by pLux promoter, in the measurement system it is driven by pTet promoter in order to avoid interference between inducer and gene product. |
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| | <nowiki><a name="LuxI"></a><div class="art-postcontent"><h2><span class="mw-headline"> <b>LuxI</b> </span></h2></div></nowiki> | | <nowiki><a name="LuxI"></a><div class="art-postcontent"><h2><span class="mw-headline"> <b>LuxI</b> </span></h2></div></nowiki> |
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| - | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/4/4b/Caratterizzazione_luxI.jpg" class="thumbimage" width="28%"></a></div></div> | + | <div style='text-align:center'><div class="thumbinner" style="width:100%;"><img alt="" src="https://static.igem.org/mediawiki/2011/4/48/Caratterizzazione_luxIN.jpg" class="thumbimage" width="28%"></a></div></div> |
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| | <div style='text-align:justify'> | | <div style='text-align:justify'> |
| | <ol type='1'> | | <ol type='1'> |
| - | <a name='Cox'></a><li>Cox RS 3rd, Surette MG, Elowitz MB (2007) <b> Programming gene expression with combinatorial promoters. </b> <i> Mol. Syst. Biol. </i> 3:145. | + | <li><a name='Cox'></a>Cox RS 3rd, Surette MG, Elowitz MB (2007) <b> Programming gene expression with combinatorial promoters. </b> <i> Mol. Syst. Biol. </i> 3:145. </a> |
| | </li><br> | | </li><br> |
| - | <a name='Lutz'></a><li>Lutz R, Bujard H (1997) <b> Independent and tight regulation of transcriptional units in Escherichia coli via the LacR/O, the TetR/O and AraC/I1-I2 regulatory elements. </b> <i>Nucleic Acids Res.</i> 25(6):1203-10. | + | <li><a name='Lutz'></a>Lutz R, Bujard H (1997) <b> Independent and tight regulation of transcriptional units in Escherichia coli via the LacR/O, the TetR/O and AraC/I1-I2 regulatory elements. </b> <i>Nucleic Acids Res.</i> 25(6):1203-10. |
| | </li><br> | | </li><br> |
| - | <a name='Paso'></a><li>Pasotti L, Quattrocelli M, Galli D et al. (2011) <b>Multiplexing and demultiplexing logic functions for computing signal processing tasks in synthetic biology. </b> <i>Biotechnol. J. </i>6(7):784-95. </li><br> | + | <li><a name='Paso'></a>Pasotti L, Quattrocelli M, Galli D et al. (2011) <b>Multiplexing and demultiplexing logic functions for computing signal processing tasks in synthetic biology. </b> <i>Biotechnol. J. </i>6(7):784-95. </li><br> |
| - | <a name=''>Sleight</a><li>Sleight SC, Bartley BA, Lieviant JA et al. (2010) <b>Designing and engineering evolutionary robust genetic circuits. </b> <i>J. Biol. Eng. </i>4:12. | + | <li><a name=' Sleight'></a>Sleight SC, Bartley BA, Lieviant JA et al. (2010) <b>Designing and engineering evolutionary robust genetic circuits. </b> <i>J. Biol. Eng. </i>4:12. |
| | </li><br> | | </li><br> |
| - | <a name='Andersen'></a><li>Andersen JB, Sternberg C, Poulsen LK et al. (1998) <b>New unstable variants of green fluorescent protein for studies of transient gene expression in bacteria.</b> <i> Appl. Environ. Microbiol.</i> 64(6):2240-6. | + | <li><a name='Andersen'></a>Andersen JB, Sternberg C, Poulsen LK et al. (1998) <b>New unstable variants of green fluorescent protein for studies of transient gene expression in bacteria.</b> <i> Appl. Environ. Microbiol.</i> 64(6):2240-6. |
| | </li><br> | | </li><br> |
| - | <a name='Salis'></a><li>Salis HM, Mirsky EA, Voight CA (2009)<b> Automated design of synthetic ribosome binding sites to control protein expression. </b> <i>Nat. Biotechnol.</i>27:946-950. </li> | + | <li><a name='Salis'></a>Salis HM, Mirsky EA, Voight CA (2009)<b> Automated design of synthetic ribosome binding sites to control protein expression. </b> <i>Nat. Biotechnol.</i>27:946-950. </li> |
| | </ol> | | </ol> |
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| | {{end}} | | {{end}} |
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