Team:Edinburgh
From 2011.igem.org
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Welcome to '''Edinburgh's''' 2011 iGEM effort, a.k.a. '''Team Synergy'''. | Welcome to '''Edinburgh's''' 2011 iGEM effort, a.k.a. '''Team Synergy'''. | ||
- | == | + | ==Whereas...== |
There exist situations where: | There exist situations where: | ||
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Last year, [https://2010.igem.org/Team:Slovenia Slovenia] found a way to achieve <span class="hardword" id="synergy">synergy</span> in the periplasm. This year, Edinburgh is focusing on achieving <span class="hardword" id="synergy">synergy</span> outside the cell. | Last year, [https://2010.igem.org/Team:Slovenia Slovenia] found a way to achieve <span class="hardword" id="synergy">synergy</span> in the periplasm. This year, Edinburgh is focusing on achieving <span class="hardword" id="synergy">synergy</span> outside the cell. | ||
- | == | + | ==Therefore be it resolved...== |
We will create microscopic <span class="hardword" id="bioreactor">bioreactors</span>, which we define as scaffolds holding various enzymes which carry out reactions in the extracellular environment. Our hope is that, by combining the activity of multiple enzymes in a small space, high efficiency will be achieved. At least 4 systems are being considered: | We will create microscopic <span class="hardword" id="bioreactor">bioreactors</span>, which we define as scaffolds holding various enzymes which carry out reactions in the extracellular environment. Our hope is that, by combining the activity of multiple enzymes in a small space, high efficiency will be achieved. At least 4 systems are being considered: |
Revision as of 12:09, 17 July 2011
Welcome to Edinburgh's 2011 iGEM effort, a.k.a. Team Synergy.
Whereas...
There exist situations where:
- several enzymes are needed to produce the desired product
- these enzymes work synergistically; meaning they are best kept close together
Last year, Slovenia found a way to achieve synergy in the periplasm. This year, Edinburgh is focusing on achieving synergy outside the cell.
Therefore be it resolved...
We will create microscopic bioreactors, which we define as scaffolds holding various enzymes which carry out reactions in the extracellular environment. Our hope is that, by combining the activity of multiple enzymes in a small space, high efficiency will be achieved. At least 4 systems are being considered:
Cell surface display
- The simplest system: use bacteria as the scaffold, and attach enzymes by cell surface display techniques.
- A modified version of the above: concentrate the enzymes on small parts of the bacterial surface, such as the flagella.
Phage display
- A radical proposal: use M13 phage as the scaffold, and attach enzymes by phage-display techniques to the pVIII coat protein.
- A modified version of the above: attach multiple such phage to small beads via the pIII protein, making a larger "reactor".
There are probably many uses for an extracellular reaction scaffold, so this technique is fairly general and could hopefully be used for many purposes, just by swapping in the correct BioBricks. As example systems, we will try to use cellulases as our enzymes of interest.
Biorefinery
While we're at it, it makes sense to create something from the sugar we will generate. This would involve creation of a biorefinery.