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Team:Tokyo Tech
From 2013.igem.org
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<iframe width="400" height="300" src="" frameborder="1" allowfullscreen>Coming soon...</iframe> | <iframe width="400" height="300" src="" frameborder="1" allowfullscreen>Coming soon...</iframe> | ||
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| + | <td colspan=3 align="center"> | ||
| + | <a href=""><img src="https://static.igem.org/mediawiki/2013/b/bf/Titech2013_home_Story_and_Circuit.png" width="800"></a><br> | ||
| + | <h4>[Fig3. E.ninja genetic circuit]<br> | ||
| + | x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x | ||
| + | <div align="right"><a href="">(see more)</a></div> | ||
| + | </h4> | ||
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<td colspan=2 align="center"> | <td colspan=2 align="center"> | ||
| - | <h2><p> | + | <h2><p>In our programing of artificial genetic circuit, E. ninja heads the cast. In response to E. civilian signal or E. samurai signal, E. ninja changes its state: “mimic state” and “attack state”. The circuit of E. ninja contains a bi-stable switch and a signal dependent switching part. We decided to use C6-AHL and C12-AHL as signals. The crosstalk between the two signals in synthetic biology, is well known as a big problem to be addressed. To realize accurate switching, by network engineering, we designed circumvention of the crosstalk that occurs in bacterial cell-cell communication system. (fig.3) |
| - | In our programing of artificial genetic circuit, E. ninja heads the cast. In response to E. civilian signal or E. samurai signal, E. ninja changes its state: “mimic state” and “attack state”. The circuit of E. ninja contains a bi-stable switch and a signal dependent switching part. We decided to use C6-AHL and C12-AHL as signals. The crosstalk between the two signals in synthetic biology, is well known as a big problem to be addressed. To realize accurate switching, by network engineering, we | + | |
<div align="right"><a href="">(go to State Changing page)</a></div> | <div align="right"><a href="">(go to State Changing page)</a></div> | ||
</p></h2> | </p></h2> | ||
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<td align="center"> | <td align="center"> | ||
<a href=""><img src="https://static.igem.org/mediawiki/2013/9/95/Titech2013_home_crosstalk-assay.png" width="200"></a><br> | <a href=""><img src="https://static.igem.org/mediawiki/2013/9/95/Titech2013_home_crosstalk-assay.png" width="200"></a><br> | ||
| - | <h4>[ | + | <h4>[Fig4. Crosstalk assay]<br>This graph shows that Plux/tet hybrid promoter can suppress the crosstalk.<div align="right"><a href="">(see more)</a></div> |
</h4><br> | </h4><br> | ||
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<td colspan=3 align="center"> | <td colspan=3 align="center"> | ||
| - | <a href=""><img src="https://static.igem.org/mediawiki/2013/ | + | <h2><p> |
| - | <h4>[ | + | Our wet experiments shows combination of lux/tet hybrid promoter and TetR prohibited the cross talk of activated LasR protein to luxR-binding sequences (fig4.) Mathematical modeling including results from our wet experiments shows the circumvention in the whole circuit (please compare green solid and dotted lines.). |
| + | <div align="right"><a href="">(go to Modeling page)</a></div> | ||
| + | </p></h2> | ||
| + | </td> | ||
| + | </tr> | ||
| + | <tr> | ||
| + | <td colspan=3 align="center"> | ||
| + | <a href=""><img src="https://static.igem.org/mediawiki/2013/f/f4/Titech2013_home_modeling.jpg" width="700"></a><br> | ||
| + | <h4>[Fig5. Modeling]<br> | ||
x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x | x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x | ||
<div align="right"><a href="">(see more)</a></div> | <div align="right"><a href="">(see more)</a></div> | ||
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<a href=""><img src="https://static.igem.org/mediawiki/2013/4/41/Titech2013_home_M13phage-plaque.png" width="200"></a><br> | <a href=""><img src="https://static.igem.org/mediawiki/2013/4/41/Titech2013_home_M13phage-plaque.png" width="200"></a><br> | ||
| - | <h4>[ | + | <h4>[Fig6. M13 phage plaque]<br>We confirmed inducible M13 release by plaque assay.<div align="right"><a href="">(see more)</a></div> |
</h4> | </h4> | ||
</td> | </td> | ||
<td colspan=2 align="center"> | <td colspan=2 align="center"> | ||
<h2><p> | <h2><p> | ||
| - | In addition, E. ninja releases M13 phage, which corresponds to shuriken, when it receives E. samurai signal. The inducible phage release will open new synthetic biology by programmed DNA messaging. (fig. | + | In addition, E. ninja releases M13 phage, which corresponds to shuriken, when it receives E. samurai signal. The inducible phage release will open new synthetic biology by programmed DNA messaging. (fig.6) |
<div align="right"><a href="">(go to Shuriken page)</a></div> | <div align="right"><a href="">(go to Shuriken page)</a></div> | ||
</p></h2> | </p></h2> | ||
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<td colspan=2 align="center"> | <td colspan=2 align="center"> | ||
<h2><p> | <h2><p> | ||
| - | In the second-life story, E. ninja starts farming in a peaceful village. It can synthesize plant hormone efficiently, depending on the soil environment. We constructed a new phosphate sensor (phoA promoter). Also, we learned methods for quantitative analysis for activity of cytokinin, a plant hormone, through a bioassay of cucumber seed sprouts. Towards further consideration of farming with microbes, we have also continued the human practice investigation through some interviews with Science Foundation or Organizations spreading the science. (fig. | + | In the second-life story, E. ninja starts farming in a peaceful village. It can synthesize plant hormone efficiently, depending on the soil environment. We constructed a new phosphate sensor (phoA promoter). Also, we learned methods for quantitative analysis for activity of cytokinin, a plant hormone, through a bioassay of cucumber seed sprouts. Towards further consideration of farming with microbes, we have also continued the human practice investigation through some interviews with Science Foundation or Organizations spreading the science. (fig.7) |
<div align="right"><a href="">(go to Farming page)</a></div> | <div align="right"><a href="">(go to Farming page)</a></div> | ||
</p></h2> | </p></h2> | ||
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<td align="center"> | <td align="center"> | ||
<a href=""><img src="https://static.igem.org/mediawiki/2013/9/9b/Titech2013_home_plant-bioassay.png" width="200"></a><br> | <a href=""><img src="https://static.igem.org/mediawiki/2013/9/9b/Titech2013_home_plant-bioassay.png" width="200"></a><br> | ||
| - | <h4>[ | + | <h4>[Fig7. Bioassay of plant]<br>We learned methods for quantitative analysis for cytokinin, a plant hormone, through a bioassay of cucumber seed sprouts.<div align="right"><a href="">(see more)</a></div> |
</h4> | </h4> | ||
</td> | </td> | ||
Revision as of 17:35, 24 September 2013
Abstract
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We intend to send a message to society so as to let them know the development of synthetic biology, especially the development of the network programming, as well as we enjoy our activity for iGEM. |
 [Fig1. Human Practice experiment]
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 [Fig2. Human Practice questionnaire]
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Ninja is a Japan’s ancient spy-warrior. Usually Ninja disguises himself as an ordinary civilian in public. Once he detects samurai who is the assassination target, he immediately gets ready for battle. He defeats samurai with shuriken, throwing knives. |
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 [Fig3. E.ninja genetic circuit]
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In our programing of artificial genetic circuit, E. ninja heads the cast. In response to E. civilian signal or E. samurai signal, E. ninja changes its state: “mimic state” and “attack state”. The circuit of E. ninja contains a bi-stable switch and a signal dependent switching part. We decided to use C6-AHL and C12-AHL as signals. The crosstalk between the two signals in synthetic biology, is well known as a big problem to be addressed. To realize accurate switching, by network engineering, we designed circumvention of the crosstalk that occurs in bacterial cell-cell communication system. (fig.3) |
 [Fig4. Crosstalk assay] |
|
|
Our wet experiments shows combination of lux/tet hybrid promoter and TetR prohibited the cross talk of activated LasR protein to luxR-binding sequences (fig4.) Mathematical modeling including results from our wet experiments shows the circumvention in the whole circuit (please compare green solid and dotted lines.). |
||
 [Fig5. Modeling]
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||
 [Fig6. M13 phage plaque]
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In addition, E. ninja releases M13 phage, which corresponds to shuriken, when it receives E. samurai signal. The inducible phage release will open new synthetic biology by programmed DNA messaging. (fig.6) |
|
|
In the second-life story, E. ninja starts farming in a peaceful village. It can synthesize plant hormone efficiently, depending on the soil environment. We constructed a new phosphate sensor (phoA promoter). Also, we learned methods for quantitative analysis for activity of cytokinin, a plant hormone, through a bioassay of cucumber seed sprouts. Towards further consideration of farming with microbes, we have also continued the human practice investigation through some interviews with Science Foundation or Organizations spreading the science. (fig.7) |
 [Fig7. Bioassay of plant]
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Aizawa Foundation
Mr. Isao Ono Mr. Fumio Hombo
