Team:TU Munich/project/design

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<a href="https://static.igem.org/mediawiki/2011/c/c2/Plasmid_1.jpg" rel="lightbox" title="Plasmid1"><img src="https://static.igem.org/mediawiki/2011/c/c2/Plasmid_1.jpg" alt="plasmid1" style="float:right;width:200px;padding-left:20px;padding-bottom:20px;margin-top:-10px;"></a>
<a href="https://static.igem.org/mediawiki/2011/c/c2/Plasmid_1.jpg" rel="lightbox" title="Plasmid1"><img src="https://static.igem.org/mediawiki/2011/c/c2/Plasmid_1.jpg" alt="plasmid1" style="float:right;width:200px;padding-left:20px;padding-bottom:20px;margin-top:-10px;"></a>
The basic idea of the logical gate we are using was developed at UCSF in the lab of Prof. Voigt [<a href="#r1">1</a>]. It is based on amber stop-codon suppression via the non-canonical supD tRNA. We designed the part as followed:
The basic idea of the logical gate we are using was developed at UCSF in the lab of Prof. Voigt [<a href="#r1">1</a>]. It is based on amber stop-codon suppression via the non-canonical supD tRNA. We designed the part as followed:
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Our plasmid insert starts with the sequences (<a href="http://partsregistry.org/Part:BBa_K322123">BBa_K322123</a> and <a href="http://partsregistry.org/Part:BBa_I15010" target="_blank">BBa_I15010</a>) needed to produce the red light sensing chromophores. Each part includes a constitutive promotor and a terminator sequence. Downstream, we cloned the red light sensing promotor (<a href="http://partsregistry.org/Part:BBa_R0082" target="_blank">BBa_R0082</a>) in front of the supD tRNA (<a href="http://partsregistry.org/Part:BBa_K228001" target="_blank">BBa_K228001</a>). To stop the transcription directly behind the supD tRNA we put in a double terminator sequence (<a href="http://partsregistry.org/Part:BBa_B0015" target="_blank">BBa_B0015</a>) downstream. This is followed by a blue light sensing promotor (<a href="http://partsregistry.org/Part:BBa_K238013" target="_blank">BBa_K238013</a>). In order to allow ribosome-binding upstream of the next part we introduced a ribosome binding site (<a href="http://partsregistry.org/Part:BBa_J44001" target="_blank">BBa_J44001</a>) directly downstream of the blue light sensing promotor. The AND-gate construct is completed by a T7 polymerase with the amber stop codon mutation (<a href="http://partsregistry.org/Part:BBa_K228000" target="_blank">BBa_K228000</a>). Since all standard biobrick vectors include a termination sequence after suffix there was no need to introduce a further termination sequence.</p>
+
Our plasmid insert starts with the sequences (<a href="http://partsregistry.org/Part:BBa_K322123">BBa_K322123</a> and <a href="http://partsregistry.org/Part:BBa_I15010" target="_blank">BBa_I15010</a>) needed to produce the red light sensing chromophores. Downstream, we cloned the red light sensing promotor (<a href="http://partsregistry.org/Part:BBa_R0082" target="_blank">BBa_R0082</a>) in front of the supD tRNA (<a href="http://partsregistry.org/Part:BBa_K228001" target="_blank">BBa_K228001</a>). To stop the transcription directly behind the supD tRNA we put in a double terminator sequence (<a href="http://partsregistry.org/Part:BBa_B0015" target="_blank">BBa_B0015</a>) downstream. This is followed by a blue light sensing promotor (<a href="http://partsregistry.org/Part:BBa_K238013" target="_blank">BBa_K238013</a>). In order to allow ribosome-binding upstream of the next part we introduced a ribosome binding site (<a href="http://partsregistry.org/Part:BBa_J44001" target="_blank">BBa_J44001</a>) directly downstream of the blue light sensing promotor. The AND-gate construct is completed by a T7 polymerase with the amber stop codon mutation (<a href="http://partsregistry.org/Part:BBa_K228000" target="_blank">BBa_K228000</a>). Since all standard biobrick vectors include a termination sequence after the suffix there was no need to introduce a further termination sequence.</p>
<a href="https://static.igem.org/mediawiki/2011/d/da/Plasmid_2.jpg" rel="lightbox" title="Plasmid2"><img src="https://static.igem.org/mediawiki/2011/d/da/Plasmid_2.jpg" alt="plasmid2" style="float:right;width:150px;padding-left:20px;margin-top:-40px;"></a>
<a href="https://static.igem.org/mediawiki/2011/d/da/Plasmid_2.jpg" rel="lightbox" title="Plasmid2"><img src="https://static.igem.org/mediawiki/2011/d/da/Plasmid_2.jpg" alt="plasmid2" style="float:right;width:150px;padding-left:20px;margin-top:-40px;"></a>
<p><i>Reporter construct (low copy):</i>
<p><i>Reporter construct (low copy):</i>
-
Our second plasmid carries the reporter construct, which can be exchanged, depending on what kind of reporter system you want to use. For simple proof of principle we used lacZ (<a href="http://partsregistry.org/Part:BBa_I732017" target="_blank">BBa_I732017</a>) as reporter gene downstream of the T7 promotor (<a href="http://partsregistry.org/Part:BBa_I712074" target="_blank">BBa_I712074</a>). Since the used lacZ part already includes a ribosome-binding site (rbs), it is not necessary to add another rbs. For the same reason as mentioned under "Optogenetical AND-gate construct" we did not add a terminator sequence downstream of lacZ. </p>
+
Our second plasmid carries the reporter construct, which can be exchanged, depending on what kind of reporter system you want to use. For simple proof of principle we used lacZ (<a href="http://partsregistry.org/Part:BBa_I732017" target="_blank">BBa_I732017</a>) as reporter gene downstream of the T7 promotor (<a href="http://partsregistry.org/Part:BBa_I712074" target="_blank">BBa_I712074</a>). Since the used lacZ part already includes a ribosome-binding site (rbs), it is not necessary to add another rbs. For the same reason as mentioned under "Optogenetical AND-gate construct" we did not add a terminator sequence downstream of lacZ. As alternative we also used gfp behind the T7 promoter(<a href="http://partsregistry.org/Part:BBa_I746907" target="_blank">BBa_I746907</a>). This made the testing of the other parts easier due to an assay easier to handle than the Miller assay.</p>
<br />
<br />
<h2>Bacteria and block matrix</h2>
<h2>Bacteria and block matrix</h2>
-
<p>We could obtain the heat resistant <i>E. Coli</i> strain BM28 (derived via directed evolution of strain MG1655 zba::kan) [<a href="#r2">2</a>], which endure temperatures up to 50°C. This is very important to us since we have chosen a matrix named GELRITE to immobilize our bacteria. It can be penetrated by light with only little refraction and it contains a minimum of nutrient to enable growth and protein synthesis but it polymerizes at 46°C. To ensure an even distribution of the bacteria we need to add them into the liquid gel which in turn means that they need to endure more than 46°C for at least 2 or 3 minutes.</p>
+
<p>We could obtain the heat resistant <i>E. coli</i> strain BM28 (derived via directed evolution of strain MG1655 zba::kan) [<a href="#r2">2</a>], which endure temperatures up to 50°C. This is very important to us since we have chosen a matrix named GELRITE to immobilize our bacteria. It can be penetrated by light with only little refraction and it contains a minimum of nutrient to enable growth and protein synthesis but it polymerizes at 46°C. To ensure an even distribution of the bacteria we need to add them into the liquid gel which in turn means that they need to endure more than 46°C for at least 2 or 3 minutes.</p>
<br />
<br />
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<a href="https://static.igem.org/mediawiki/2011/c/cd/TumDesign2.jpg" rel="lightbox" title="Design"><img src="https://static.igem.org/mediawiki/2011/c/cd/TumDesign2.jpg" alt="design" style="float:right;width:300px;padding-left:20px;margin-top:0px;"></a>
<a href="https://static.igem.org/mediawiki/2011/c/cd/TumDesign2.jpg" rel="lightbox" title="Design"><img src="https://static.igem.org/mediawiki/2011/c/cd/TumDesign2.jpg" alt="design" style="float:right;width:300px;padding-left:20px;margin-top:0px;"></a>
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<p>By addition of S-Gal to the GELRITE matrix a fully functional AND-gate should lead to dark spots/colonies when hit with blue and red light. For proof of principle, one could also think about GFP coupled to fluorescence detection.</p>
+
<p>By addition of S-Gal to the GELRITE matrix a fully functional AND-gate should lead to dark spots/colonies when hit with blue and red light. For proof of principle, we also used gfp coupled to fluorescence detection.</p>
<p>Since the red light sensor is active in the ground state, one needs to shut down the signalling. This can be achieved by irradiation with light of 650 nm [<a href="#r3">3</a>].  
<p>Since the red light sensor is active in the ground state, one needs to shut down the signalling. This can be achieved by irradiation with light of 650 nm [<a href="#r3">3</a>].  
-
Afterwards, bacteria get hit by both far red light (705 nm [<a href="#r3">3</a>]) and blue light (465 nm [<a href="#r4">4</a>]) beams. Cph8 consist of the extracellular membrane domain cph1 and intracellular of EnvZ. The red light induces the autophosphorylation at the cytosolic site of cph8[<a href="#r5">5</a>]. This leads to phosphorylation of OmpR [<a href="#r6">6</a>] which subsequently binds to OmpC promoter and enables transcription of the supD t-RNA.  
+
Afterwards, bacteria get hit by both far red light (705 nm [<a href="#r3">3</a>]) and blue light (465 nm [<a href="#r4">4</a>]) beams. Cph8 consist of the extracellular membrane domain cph1 and the intracellular part envZ. The red light induces the autophosphorylation at the cytosolic site of cph8[<a href="#r5">5</a>]. This leads to phosphorylation of ompR [<a href="#r6">6</a>] which subsequently binds to the ompC promoter and enables transcription of the supD t-RNA.  
<p>When YcgF senses blue light it dimerizes and binds to the repressor YcgE. The formation of the YcgE-YcgF complex leads to the unbinding of YcgE from the YcgZ promoter which activates the transcription of T7ptag (T7 polymerase with the amber stop codon mutation). However, translation of this mRNA is only possible if enough supD tRNA is available. </p>
<p>When YcgF senses blue light it dimerizes and binds to the repressor YcgE. The formation of the YcgE-YcgF complex leads to the unbinding of YcgE from the YcgZ promoter which activates the transcription of T7ptag (T7 polymerase with the amber stop codon mutation). However, translation of this mRNA is only possible if enough supD tRNA is available. </p>
-
<p>This AND-gate should ensure that expression of T7ptag is only induced when both wavelengths hit the bacteria. Since the reporter gene is under the control of a T7 promoter, lacZ expression is only enabled when the generated T7 polymerase binds to the T7 promoter.</p>
+
<p>This AND-gate should ensure that expression of T7ptag is only induced when both wavelengths hit the bacteria. Since the reporter gene is under the control of a T7 promoter, lacZ or gfp expression is only enabled when the generated T7 polymerase binds to the T7 promoter.</p>
<p>The red light signal transduction pathway is supposedly also an osmolarity sensor, mainly dependent on aspartate [<a href="#r7">7</a>] concentration, a substance which is present in LB as well as other common media for <i>E. coli</i>. Hence a strain with EnvZ knockout is desireable. For this, the strain CP919 (<a href="http://partsregistry.org/Part:BBa_V1012" target="_blank">BBa_V1012</a>) can be used.</p> CP919 has a kanamycin insertion mutation into the EnvZ genomic region, therefore no kanamycin vectors can be used. Furthermore, in CP919 an additional genomic fusion of ompC-lacZ is present, which makes the usage of a lacZ reporter inappropriate in our AND-Gate system.[<a href="#r3">3</a>]</p>
<p>The red light signal transduction pathway is supposedly also an osmolarity sensor, mainly dependent on aspartate [<a href="#r7">7</a>] concentration, a substance which is present in LB as well as other common media for <i>E. coli</i>. Hence a strain with EnvZ knockout is desireable. For this, the strain CP919 (<a href="http://partsregistry.org/Part:BBa_V1012" target="_blank">BBa_V1012</a>) can be used.</p> CP919 has a kanamycin insertion mutation into the EnvZ genomic region, therefore no kanamycin vectors can be used. Furthermore, in CP919 an additional genomic fusion of ompC-lacZ is present, which makes the usage of a lacZ reporter inappropriate in our AND-Gate system.[<a href="#r3">3</a>]</p>
-
<p>For testing of our construct in CP919 we therefore use the GFP reporter part <a href="http://partsregistry.org/Part:BBa_I746907">BBa_I746907</a>, which we subsequently cloned into the low copy origin of replication vector <a href="http://partsregistry.org/Part:pSB6A1">pSB6A1</a>. As both plasmids need to be electroporated into the same cells, two different origins of replications and antibiotica resistances have to be choosen. </p>
+
<p>For testing our construct in CP919 we therefore use the GFP reporter part <a href="http://partsregistry.org/Part:BBa_I746907">BBa_I746907</a>, which we subsequently cloned into the low copy origin of replication vector <a href="http://partsregistry.org/Part:pSB6A1">pSB6A1</a>. As both plasmids need to be electroporated into the same cells, two different origins of replications and antibiotica resistances have to be choosen. </p>
<p>
<p>
-
The desired bacteria for our final system is the heat resistant <i>E. Coli</i> strain BH28, in which we aim to insertion knock-out the EnvZ genomic region in a last step.  
+
The desired bacteria for our final system is the heat resistant <i>E. coli</i> strain BH28, in which we aim to insert a knock-out in the EnvZ genomic region in a last step.  
</p>
</p>
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<a href="https://static.igem.org/mediawiki/2011/3/3a/Klonierungsschema_Plasmid_2.jpg" rel="lightbox" title="Scheme Plasmid 2"><img src="https://static.igem.org/mediawiki/2011/3/3a/Klonierungsschema_Plasmid_2.jpg" alt="design" style="float:left;width:300px;padding-left:20px;margin-top:0px;"></a>
<a href="https://static.igem.org/mediawiki/2011/3/3a/Klonierungsschema_Plasmid_2.jpg" rel="lightbox" title="Scheme Plasmid 2"><img src="https://static.igem.org/mediawiki/2011/3/3a/Klonierungsschema_Plasmid_2.jpg" alt="design" style="float:left;width:300px;padding-left:20px;margin-top:0px;"></a>
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<br>
 
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<hr />
 
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<div style="clear:both"><h4>References:</h4>
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 +
 
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<div style="clear:both"><hr /><h4>References:</h4>
<div id="r1"><p>1. J Christopher Anderson, Christopher A Voigt, and Adam P Arkin. Environmental signal
<div id="r1"><p>1. J Christopher Anderson, Christopher A Voigt, and Adam P Arkin. Environmental signal
integration by a modular and gate. <i>Mol Syst Biol</i>, 3, 08 2007.</p></div>
integration by a modular and gate. <i>Mol Syst Biol</i>, 3, 08 2007.</p></div>

Latest revision as of 21:59, 28 October 2011

Design

You want to know about our project idea in detail? Then this is the right page for you! Here we describe the complete and detailed implementation of our ideas into one project and working parts.


Plasmid design

Optogenetical AND-gate construct (high copy): plasmid1 The basic idea of the logical gate we are using was developed at UCSF in the lab of Prof. Voigt [1]. It is based on amber stop-codon suppression via the non-canonical supD tRNA. We designed the part as followed: Our plasmid insert starts with the sequences (BBa_K322123 and BBa_I15010) needed to produce the red light sensing chromophores. Downstream, we cloned the red light sensing promotor (BBa_R0082) in front of the supD tRNA (BBa_K228001). To stop the transcription directly behind the supD tRNA we put in a double terminator sequence (BBa_B0015) downstream. This is followed by a blue light sensing promotor (BBa_K238013). In order to allow ribosome-binding upstream of the next part we introduced a ribosome binding site (BBa_J44001) directly downstream of the blue light sensing promotor. The AND-gate construct is completed by a T7 polymerase with the amber stop codon mutation (BBa_K228000). Since all standard biobrick vectors include a termination sequence after the suffix there was no need to introduce a further termination sequence.

plasmid2

Reporter construct (low copy): Our second plasmid carries the reporter construct, which can be exchanged, depending on what kind of reporter system you want to use. For simple proof of principle we used lacZ (BBa_I732017) as reporter gene downstream of the T7 promotor (BBa_I712074). Since the used lacZ part already includes a ribosome-binding site (rbs), it is not necessary to add another rbs. For the same reason as mentioned under "Optogenetical AND-gate construct" we did not add a terminator sequence downstream of lacZ. As alternative we also used gfp behind the T7 promoter(BBa_I746907). This made the testing of the other parts easier due to an assay easier to handle than the Miller assay.


Bacteria and block matrix

We could obtain the heat resistant E. coli strain BM28 (derived via directed evolution of strain MG1655 zba::kan) [2], which endure temperatures up to 50°C. This is very important to us since we have chosen a matrix named GELRITE to immobilize our bacteria. It can be penetrated by light with only little refraction and it contains a minimum of nutrient to enable growth and protein synthesis but it polymerizes at 46°C. To ensure an even distribution of the bacteria we need to add them into the liquid gel which in turn means that they need to endure more than 46°C for at least 2 or 3 minutes.


How the final construct should work

design

By addition of S-Gal to the GELRITE matrix a fully functional AND-gate should lead to dark spots/colonies when hit with blue and red light. For proof of principle, we also used gfp coupled to fluorescence detection.

Since the red light sensor is active in the ground state, one needs to shut down the signalling. This can be achieved by irradiation with light of 650 nm [3]. Afterwards, bacteria get hit by both far red light (705 nm [3]) and blue light (465 nm [4]) beams. Cph8 consist of the extracellular membrane domain cph1 and the intracellular part envZ. The red light induces the autophosphorylation at the cytosolic site of cph8[5]. This leads to phosphorylation of ompR [6] which subsequently binds to the ompC promoter and enables transcription of the supD t-RNA.

When YcgF senses blue light it dimerizes and binds to the repressor YcgE. The formation of the YcgE-YcgF complex leads to the unbinding of YcgE from the YcgZ promoter which activates the transcription of T7ptag (T7 polymerase with the amber stop codon mutation). However, translation of this mRNA is only possible if enough supD tRNA is available.

This AND-gate should ensure that expression of T7ptag is only induced when both wavelengths hit the bacteria. Since the reporter gene is under the control of a T7 promoter, lacZ or gfp expression is only enabled when the generated T7 polymerase binds to the T7 promoter.

The red light signal transduction pathway is supposedly also an osmolarity sensor, mainly dependent on aspartate [7] concentration, a substance which is present in LB as well as other common media for E. coli. Hence a strain with EnvZ knockout is desireable. For this, the strain CP919 (BBa_V1012) can be used.

CP919 has a kanamycin insertion mutation into the EnvZ genomic region, therefore no kanamycin vectors can be used. Furthermore, in CP919 an additional genomic fusion of ompC-lacZ is present, which makes the usage of a lacZ reporter inappropriate in our AND-Gate system.[3]

For testing our construct in CP919 we therefore use the GFP reporter part BBa_I746907, which we subsequently cloned into the low copy origin of replication vector pSB6A1. As both plasmids need to be electroporated into the same cells, two different origins of replications and antibiotica resistances have to be choosen.

The desired bacteria for our final system is the heat resistant E. coli strain BH28, in which we aim to insert a knock-out in the EnvZ genomic region in a last step.

Cloning Scheme:

design design

References:

1. J Christopher Anderson, Christopher A Voigt, and Adam P Arkin. Environmental signal integration by a modular and gate. Mol Syst Biol, 3, 08 2007.

2. Birgit Rudolph, Katharina M. Gebendorfer, Johannes Buchner, and Jeannette Winter. Evolution of escherichia coli for growth at high temperatures. Journal of Biological Chemistry, 285(25):19029–19034, 2010.

3. Jeffrey J. Tabor, Anselm Levskaya, and Christopher A. Voigt. Multichromatic control of gene expression in escherichia coli. Journal of Molecular Biology, 405(2):315 – 324, 2011.

4. Y. Nakasone and T. Ono and A. Ishii and S. Masuda and M. Terazima . Transitional Dimerization and Conformation Change of a BLUF Protein YcgF. Journal of the American Chemical Society, 129(22):7028–7035, 2007.

5. Julia Rausenberger, Andrea Hussong, Stefan Kircher, Daniel Kirchenbauer, Jens Timmer, Ferenc Nagy, Eberhard Schäfer, and Christian Fleck. An integrative model for phytochrome b mediated photomorphogenesis: from protein dynamics to physiology. PLoS One, 5(5):e10721, 2010.

6. Oleg A Igoshin, Rui Alves, and Michael A Savageau. Hysteretic and graded responses in bacterial two-component signal transduction. Mol Microbiol, 68(5):1196–215, Jun 2008

7. R Utsumi, RE Brissette, A Rampersaud, SA Forst, K Oosawa, and M Inouye. Activation of bacterial porin gene expression by a chimeric signal transducer in response to aspartate. Science, 245(4923):1246–1249, 1989.