Team:Paris Bettencourt/tRNA diffusion

From 2011.igem.org

(Difference between revisions)
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<p>The <em>amber codon</em> is one of the less used stop codon in bacteria. The principle of the artificial amber suppressor tRNA is to provide a tRNA corresponding to this stop codon.</p>
<p>The <em>amber codon</em> is one of the less used stop codon in bacteria. The principle of the artificial amber suppressor tRNA is to provide a tRNA corresponding to this stop codon.</p>
-
<p>When the ribosome translates the RNA into a protein, it first looks for the RBS sequence and fixes on it. It tries to fit the codon it is located on with the three complementary bases of tRNA flying round. When it finds the correct tRNA with the <em>anti-codon</em> of the start codon with a methionine loaded on it, the translation starts. Then, codon after codon, the ribosome tries to fit many tRNA on the codon it is placed on, until it find the correct one, fixes the corresponding amino-acid and then moves to the next codon. When the ribosome does not find the correct tRNA for the codon it is located on, the ribosome declares this codon is a stop, and releases the peptide and the mRNA.</p>
+
<p>When the ribosome translates the RNA into a protein, it first looks for the RBS sequence and fixes on it. It tries to fit the codon it is located on with the three complementary bases of tRNA flying round. When it finds the correct tRNA with the <em>anti-codon</em> of the start codon with a methionine loaded on it, the translation starts. Then, codon after codon, the ribosome tries to fit many tRNA on the codon it is placed on, until it find the correct one, fixes the corresponding amino-acid and then moves to the next codon. When the ribosome reaches a codon that is sotp codon in the genetic code of the cell, the translation stops.</p>
 +
 
 +
<p>The idea behind the tRNA amber supressor is to create an <em>artificial tRNA</em>, based on an existing tRNA that is loaded with a chosen amino-acid, and to change its anti-codon, replacing it by <em>the amber anti-codon</em>. By expressing this artificial tRNA in the cell, the ribosome will read-trhough the amber codon, and keep polymerasing the protein.</p>
-
<p>The idea behind the tRNA amber supressor is to create an <em>artificial tRNA</em>, based on an existing tRNA that is loaded with a specific amino-acid, and to change its anti-codon, replacing it by <em>the amber anti-codon</em>. By expressing this artificial tRNA in the cell, the ribosome can find a tRNA that matches the amber codon, skip the stop and keep polymerasing the protein.</p>
 
-
</td>
 
-
<td>&nbsp; &nbsp; &nbsp;</td>
 
-
<td>
 
<img src="https://static.igem.org/mediawiki/2011/a/a3/Translation_short.gif"/>
<img src="https://static.igem.org/mediawiki/2011/a/a3/Translation_short.gif"/>
<center><p><u><b>Fig1:</b></u> Transcription schematics animation<br/>(modified version of <a href="http://en.wikipedia.org/wiki/Ribosome">this animation</a>)</p></center>
<center><p><u><b>Fig1:</b></u> Transcription schematics animation<br/>(modified version of <a href="http://en.wikipedia.org/wiki/Ribosome">this animation</a>)</p></center>
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</table>
</table>
-
<p>By creating DNA that carries <zm>amber mutations</em> in the middle of its coding sequence, we create a protein that can be properly transcribed only if the artificial tRNA amber suppressor is present in the cell. Of course the mutations have to replace DNA coding for the same amino-acid that is on the artificial tRNA. This approach is sometime used in synthetic biology to create <em>artificial AND gates</em>.</a>
+
<p>By creating DNA that carries <zm>amber mutations</em> in the middle of its coding sequence, we create a protein that can be properly transcribed only if the artificial tRNA amber suppressor is present in the cell. Of course the mutations have to replace DNA coding for the same amino-acid that is on the artificial tRNA. This approach is sometime used in synthetic biology to create <em>artificial AND gates</em>.(Anderson 2007 <a href="https://2011.igem.org/Team:Paris_Bettencourt/tRNA_diffusion#references">[2]</a> and PKU Beijing team 2007  <a href="https://2011.igem.org/Team:Paris_Bettencourt/tRNA_diffusion#references">[3]</a>) </a>
<p>Surprisingly, the cells survive the expression of the amber tRNA although it is a really lethal object, because it prevents the cell from expressing properly almost 20% of its endogenic proteins.<p>
<p>Surprisingly, the cells survive the expression of the amber tRNA although it is a really lethal object, because it prevents the cell from expressing properly almost 20% of its endogenic proteins.<p>
-
<h2>Building a new tRNA amber supressor for B. subtilis</h2>
+
<h2>An emitter/receiver design</h2>
-
<p>There was no tRNA amber supressor in the registry for <i>B. Subtilis</i>. Using biofinformatics analysis we found out that the tRNA sequence is quite different than the one of <i>E. coli</i>. We therefore decided to <em>build our new tRNA amber suppressor</em>. The problem was the choice of the amino-acid we wanted to hijack. We found that some of the loading proteins recognize the anti-codon. As we were going to modify it, we needed to choose a tRNA that the anti-codon is not strongly recognized by the loading protein.</p>
 
-
<p>We found out in a paper by Grundy et al. <a href="https://2011.igem.org/Team:Paris_Bettencourt/tRNA_diffusion#references">[1]</a> that some people managed to create a tyrosine amber tRNA in <i>B. Subtilis</i> (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K606034">BBa_K606034</a>), so we decided to work on this amino-acid. Many questions around the maturation of the mRNA into the tRNA remained unsolved so we decide to build it with and without a translation terminator.</p>
+
<p><li>Here the <em>emitter cell</em> produces this mutated tRNA and makes it diffuse through the nanotubes.</li>
 +
<li>The <em>receiver cell</em> is then able to translate a protein (the T7 polymerase) with the gene containing the amber mutation. This protein triggers the reporter system.</li></p>
-
<p>We also had to build two kind of amber mutated proteins. A <em>T7 amber</em> (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K606032">K606032</a>) and a <em>GFP amber</em> (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K606043">BBa_K606043</a>) to characterize the tRNA. As we wanted a very clean system, we implemented two amber mutations for the T7 polymerase. This should reduce leaking to a minimum.</p>
+
<center>
 +
<img src="https://static.igem.org/mediawiki/2011/2/29/TRNA_Amber_principle2.jpg" width=700px />
 +
<p><u><b>Fig3:</b></u>
 +
</center>
-
<h2>Principles of the design</h2>
+
<h3>The emitter cell construction</h3>
-
<p>As in the other designs, we wanted an emitter cell producing a message, that can be <em>unambiguously</em> interpreted by the receiver cell.</p>
+
<p>We wanted to measure the response time and to be able to induce it, therefore we use an inducible promoter (pHyperSpank BBa_K606044)behind the tRNA amber itself (BBa_K606034). No RBS was needed as it is an RNA, but  to report the production of tRNA we add a RBS, a RFP and a terminator.</p>
-
<p><li>The <em>emitter cell</em> produces this mutated tRNA and makes it diffuse through the nanotubes.</li>
+
-
<li>The <em>receiver cell</em> is then able to translate a protein (the T7 polymerase) with the gene containing the amber mutation. This protein triggers the reporter system.</li></p>
+
 +
<h3>The receiver cell construction</h3>
-
<p>We summed up this principles in the scheme below:</p>
+
<p>There we want the receiver cell to answer fast, so we put a constitutive promoter(pVeg BBa_K143012) in front of the T7 amber(BBa_K606032). Indeed when the tRNA amber is not in that cell the ribosome will always stop the translation at the first codon stop, so no T7 would be expressed. However amber tRNAs entering the cell will allow the ribosome to finish the translation and a T7 RNA polymerase will be produced. That last will then fix to a pT7 promoter(BBa_I719005) that we placed in front of a T7 gene(BBa_K145001) and a RFP gene(BBa_E1010). Therefore the first polymerase will induce an autoamplification system and an increase of green fluorescence.</p>
-
<center>
 
-
<img src="https://static.igem.org/mediawiki/2011/8/85/TRNA_Amber_principle1.jpg" width=700px />
 
-
<p><u><b>Fig2:</b></u> Complete schematic of the system</p>
 
-
</center>
 
-
<p>Explanation step by step:</p>
+
<h3>Explanation step by step</h3>
-
<p><em>I.</em> The tRNA is over expressed and matured in the emitter cell. The loading proteins add the amino-acid tyrosine on the tRNA. In the receiver cell, the translation of the T7 RNA polymerase is blocked by the amber codons in the sequence. It cannot be maturated and so the reporter system is silent.</p>
+
<p><em>I.</em> The tRNA isn't expressed in the emitter cell, thanks to the Hyper Spank promoter. In the receiver cell, the translation of the T7 RNA polymerase is blocked by the amber codons in the sequence. It cannot be maturated and so the reporter system is silent. We launch the IPTG induction to produce amber tRNAs in the emitter cell, RFP fluorescence is also appearing.</p>
-
 
+
-
<center>
+
-
<img src="https://static.igem.org/mediawiki/2011/2/29/TRNA_Amber_principle2.jpg" width=700px />
+
-
<p><u><b>Fig3:</b></u> tRNA amber is produced in the emittor cell. In the absence of the tRNA in the receiver cell, the T7 polymerase cannot be translated.</p>
+
-
</center>
+
-
<br />
+
-
 
+
-
<p><em>II.</em> The connection through the nanotube is established. Some tRNA diffuse to the receiver cell, and this is sufficient for the ribosome to skip the two amber codons and polymerasing a few T7 RNA polymerase.</p>
+
<center>
<center>
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<br />
<br />
-
<p><em>III.</em> Then, the T7 RNA polymerase is maturated and becomes functionnal. It can trigger the pT7 promoter of the construct.</p>
+
<p><em>II.</em> The connection through the nanotube is established. Some tRNA diffuse to the receiver cell, and this is sufficient for the ribosome to read-through the two amber codons and polymerasing a few T7 RNA polymerase.</p>
<center>
<center>
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<br />
<br />
-
<p><em>IV.</em> The T7 polymerase triggers the self amplifying switch by producing a few normal T7 RNA polymerases, which will keep self producing. In the mean time, because it is on the same mRNA, a proportional quantity of GFP will be produced.</p>
+
<p><em>III.</em> Then, the T7 RNA polymerase is maturated and becomes functionnal. It can trigger the pT7 promoter of the construct and the production of RFP.</p>
<center>
<center>
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</center>
</center>
<br />
<br />
 +
 +
<p><em>IV.</em> The T7 polymerase triggers the self amplifying switch by producing a few normal T7 RNA polymerases, which will keep self producing. In the mean time, because it is on the same mRNA, a proportional quantity of GFP will be produced.</p>
 +
 +
<center>
 +
<img src="https://static.igem.org/mediawiki/2011/8/85/TRNA_Amber_principle1.jpg" width=700px />
 +
<p><u><b>Fig2:</b></u> Complete scheme of the system</p>
 +
</center>
 +
<br />
 +
<p>The reporter system is active. We can look under the microscope. When a red cell (emitter cell) meets a dark cell (receiver cell) and that, a few minutes later, the receiver cell becomes green, we are sure that the message has passed through the nanotubes.
<p>The reporter system is active. We can look under the microscope. When a red cell (emitter cell) meets a dark cell (receiver cell) and that, a few minutes later, the receiver cell becomes green, we are sure that the message has passed through the nanotubes.
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<h2>Models and experiments</h2>
<h2>Models and experiments</h2>
-
<p>We have managed to build all these constructs, and to model this system. We kindly invite you to visit the corresponding pages:</p>
+
<p>We have managed to build most of these constructs, and to model this system. We kindly invite you to visit the corresponding pages:</p>
<li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/Modeling/tRNA_diffusion">Modeling</a></em></li>
<li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/Modeling/tRNA_diffusion">Modeling</a></em></li>
-
<li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/Experiments/tRNA_diffusion">Experiments</a></em></li>
+
<li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/Experiments/tRNA_diffusion">Results</a></em></li>
<div id="citation_box">
<div id="citation_box">
<p id="references">References</p>
<p id="references">References</p>
<ol>
<ol>
<li><i>tRNA determinants for transcription antitermination of the Bacillus subtilis tyrS gene</i>, F J Grundy, J A Collins, S M Rollins, and T M Henkin, available <a href="http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1369987/">here</a></li>
<li><i>tRNA determinants for transcription antitermination of the Bacillus subtilis tyrS gene</i>, F J Grundy, J A Collins, S M Rollins, and T M Henkin, available <a href="http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1369987/">here</a></li>
 +
<li><i>Environmental signal integration by a modular AND gate</i>, J Christopher Anderson, Christopher A Voigt, and Adam P Arkin, available <a href="http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1964800/">here</a></li>
 +
<li><i>Wiki of the 2009 PKU Beijing iGEM team, available </i> <a href="https://2009.igem.org/Team:PKU_Beijing/Project/AND_Gate_1/Design">here</a></li>
</ol>
</ol>
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Revision as of 00:00, 22 September 2011

Team IGEM Paris 2011

The tRNA amber diffusion

The amber codon and the tRNA amber suppressor

The amber codon is one of the less used stop codon in bacteria. The principle of the artificial amber suppressor tRNA is to provide a tRNA corresponding to this stop codon.

When the ribosome translates the RNA into a protein, it first looks for the RBS sequence and fixes on it. It tries to fit the codon it is located on with the three complementary bases of tRNA flying round. When it finds the correct tRNA with the anti-codon of the start codon with a methionine loaded on it, the translation starts. Then, codon after codon, the ribosome tries to fit many tRNA on the codon it is placed on, until it find the correct one, fixes the corresponding amino-acid and then moves to the next codon. When the ribosome reaches a codon that is sotp codon in the genetic code of the cell, the translation stops.

The idea behind the tRNA amber supressor is to create an artificial tRNA, based on an existing tRNA that is loaded with a chosen amino-acid, and to change its anti-codon, replacing it by the amber anti-codon. By expressing this artificial tRNA in the cell, the ribosome will read-trhough the amber codon, and keep polymerasing the protein.

Fig1: Transcription schematics animation
(modified version of this animation)

By creating DNA that carries amber mutations in the middle of its coding sequence, we create a protein that can be properly transcribed only if the artificial tRNA amber suppressor is present in the cell. Of course the mutations have to replace DNA coding for the same amino-acid that is on the artificial tRNA. This approach is sometime used in synthetic biology to create artificial AND gates.(Anderson 2007 [2] and PKU Beijing team 2007 [3])

Surprisingly, the cells survive the expression of the amber tRNA although it is a really lethal object, because it prevents the cell from expressing properly almost 20% of its endogenic proteins.

An emitter/receiver design

  • Here the emitter cell produces this mutated tRNA and makes it diffuse through the nanotubes.
  • The receiver cell is then able to translate a protein (the T7 polymerase) with the gene containing the amber mutation. This protein triggers the reporter system.
  • Fig3:

    The emitter cell construction

    We wanted to measure the response time and to be able to induce it, therefore we use an inducible promoter (pHyperSpank BBa_K606044)behind the tRNA amber itself (BBa_K606034). No RBS was needed as it is an RNA, but to report the production of tRNA we add a RBS, a RFP and a terminator.

    The receiver cell construction

    There we want the receiver cell to answer fast, so we put a constitutive promoter(pVeg BBa_K143012) in front of the T7 amber(BBa_K606032). Indeed when the tRNA amber is not in that cell the ribosome will always stop the translation at the first codon stop, so no T7 would be expressed. However amber tRNAs entering the cell will allow the ribosome to finish the translation and a T7 RNA polymerase will be produced. That last will then fix to a pT7 promoter(BBa_I719005) that we placed in front of a T7 gene(BBa_K145001) and a RFP gene(BBa_E1010). Therefore the first polymerase will induce an autoamplification system and an increase of green fluorescence.

    Explanation step by step

    I. The tRNA isn't expressed in the emitter cell, thanks to the Hyper Spank promoter. In the receiver cell, the translation of the T7 RNA polymerase is blocked by the amber codons in the sequence. It cannot be maturated and so the reporter system is silent. We launch the IPTG induction to produce amber tRNAs in the emitter cell, RFP fluorescence is also appearing.

    Fig4: When tRNA passes through the nanotube, it allows the receiver cell to translate the T7 polymerase


    II. The connection through the nanotube is established. Some tRNA diffuse to the receiver cell, and this is sufficient for the ribosome to read-through the two amber codons and polymerasing a few T7 RNA polymerase.

    Fig5: The T7 polymerase triggers the self amplifying reporter switch


    III. Then, the T7 RNA polymerase is maturated and becomes functionnal. It can trigger the pT7 promoter of the construct and the production of RFP.

    Fig6: The positive feed back loop helps the signal to be amplified


    IV. The T7 polymerase triggers the self amplifying switch by producing a few normal T7 RNA polymerases, which will keep self producing. In the mean time, because it is on the same mRNA, a proportional quantity of GFP will be produced.

    Fig2: Complete scheme of the system


    The reporter system is active. We can look under the microscope. When a red cell (emitter cell) meets a dark cell (receiver cell) and that, a few minutes later, the receiver cell becomes green, we are sure that the message has passed through the nanotubes.

    Models and experiments

    We have managed to build most of these constructs, and to model this system. We kindly invite you to visit the corresponding pages:

  • Modeling
  • Results
  • References

    1. tRNA determinants for transcription antitermination of the Bacillus subtilis tyrS gene, F J Grundy, J A Collins, S M Rollins, and T M Henkin, available here
    2. Environmental signal integration by a modular AND gate, J Christopher Anderson, Christopher A Voigt, and Adam P Arkin, available here
    3. Wiki of the 2009 PKU Beijing iGEM team, available here