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Team:Toulouse/Project/Overviews
From 2014.igem.org
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<img style="width:700px; margin: 45px 0 45px 130px;" ; src="https://static.igem.org/mediawiki/parts/2/2b/Overview_.jpg"> | <img style="width:700px; margin: 45px 0 45px 130px;" ; src="https://static.igem.org/mediawiki/parts/2/2b/Overview_.jpg"> | ||
| - | <p class=" | + | <p class="title1">Chemotaxis<a href="https://2014.igem.org/Team:Toulouse/Project/Chemotaxis"; style="font-size: 13px; cursor: pointer; color: #888; margin-left: 10px;"> Show more</a></p> |
<p class="texte">First, the bacterium targets the pathogen thanks to a chemotaxis module which recognizes the soluble chitin monomers (N-acetyl-glucosamine) released by the fungi.</p> | <p class="texte">First, the bacterium targets the pathogen thanks to a chemotaxis module which recognizes the soluble chitin monomers (N-acetyl-glucosamine) released by the fungi.</p> | ||
| - | <p class=" | + | <p class="title1">Binding<a href="https://2014.igem.org/Team:Toulouse/Project/Binding"; style="font-size: 13px; cursor: pointer; color: #888; margin-left: 10px;"> Show more</a></p> |
<p class="texte">Then, SubtiTree binds onto the pathogen by a chimeric protein anchored to the bacterium peptidoglycan and which can make a bridge between bacterial cell wall and fungal chitin, the main component of the pathogen's cell wall.</p> | <p class="texte">Then, SubtiTree binds onto the pathogen by a chimeric protein anchored to the bacterium peptidoglycan and which can make a bridge between bacterial cell wall and fungal chitin, the main component of the pathogen's cell wall.</p> | ||
| - | <p class=" | + | <p class="title1">Fungicides<a href="https://2014.igem.org/Team:Toulouse/Project/Fungicides"; style="font-size: 13px; cursor: pointer; color: #888; margin-left: 10px;"> Show more</a></p> |
<p class="texte">To finish, our designed bacterium fights against the pathogen by setting up a powerful treatment based on the production of three different fungicides.</p> | <p class="texte">To finish, our designed bacterium fights against the pathogen by setting up a powerful treatment based on the production of three different fungicides.</p> | ||
| - | <p class=" | + | <p class="title1">Spreading <a href="https://2014.igem.org/Team:Toulouse/Project/Spreading"; style="font-size: 13px; cursor: pointer; color: #888; margin-left: 10px;">Show more</a></p> |
<p class="texte">Our team worked on different aspects to keep control on SubtiTree. The aim is to prevent horizontal transfers between different bacteria and to contain the engineered bacterium inside the tree during one season.</p> | <p class="texte">Our team worked on different aspects to keep control on SubtiTree. The aim is to prevent horizontal transfers between different bacteria and to contain the engineered bacterium inside the tree during one season.</p> | ||
| - | <p class=" | + | <p class="title1">Choice of the chassis </p> |
| - | <i>Bacillus subtilis</i> has been reported to be an endophytic bacterium of a large variety of plants and trees. This model organism is a perfect chassis for our project. Already used to treat plant diseases and fungal pathogens, we aim to engineer Bacillus subtilis so as to fight Canker Stain from the inside of the tree. Injected directly in the tree sap, our smart bacterium will act as a curative and preventive drug. | + | <p class="texte"><i>Bacillus subtilis</i> has been reported to be an endophytic bacterium of a large variety of plants and trees. This model organism is a perfect chassis for our project. Already used to treat plant diseases and fungal pathogens, we aim to engineer Bacillus subtilis so as to fight Canker Stain from the inside of the tree. Injected directly in the tree sap, our smart bacterium will act as a curative and preventive drug.</p> |
Revision as of 12:16, 10 October 2014
Overview
SubtiTree, a bacterium to save our trees
Project > Overview
Among many other things, Southern France is well-known for the gorgeousness of its landscapes. Plane trees (Platanus sp.) are widely present and participate to the charm of this area, especially along the famous “Canal du Midi”. It is impossible to imagine this UNESCO World Heritage masterpiece without its trees. Unfortunately, these trees are threatened by a severe fungal infection called Canker, and today the only treatment consists in preventive tree-cutting which has a huge cost and implies significant ecological troubles.
Facing this emergency, the students from the iGEM Toulouse Team decided to be committed to the protection of their local heritage. Indeed, using a bacterium vector naturally present in the trees, our team offers an alternative solution originated from synthetic biology. Thanks to different genetic modules, the engineered bacterium called SubtiTree is first able to head towards the pathogen, then to bind to its cell wall in order to finally deliver different fungicides to save the tree from its invaders. Taking into account the ecological and ethical matters, our team thinks about how to limit the spreading of the optimized microorganism through different strategies. Although our project was born from a local problematic, it is transposable to other tree vascular diseases.
Chemotaxis Show more
First, the bacterium targets the pathogen thanks to a chemotaxis module which recognizes the soluble chitin monomers (N-acetyl-glucosamine) released by the fungi.
Binding Show more
Then, SubtiTree binds onto the pathogen by a chimeric protein anchored to the bacterium peptidoglycan and which can make a bridge between bacterial cell wall and fungal chitin, the main component of the pathogen's cell wall.
Fungicides Show more
To finish, our designed bacterium fights against the pathogen by setting up a powerful treatment based on the production of three different fungicides.
Spreading Show more
Our team worked on different aspects to keep control on SubtiTree. The aim is to prevent horizontal transfers between different bacteria and to contain the engineered bacterium inside the tree during one season.
Choice of the chassis
Bacillus subtilis has been reported to be an endophytic bacterium of a large variety of plants and trees. This model organism is a perfect chassis for our project. Already used to treat plant diseases and fungal pathogens, we aim to engineer Bacillus subtilis so as to fight Canker Stain from the inside of the tree. Injected directly in the tree sap, our smart bacterium will act as a curative and preventive drug.
Socialize
