Team:TU-Delft/Project
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In our project we strive for full control of the attachment and detachment of cells. In nature attachment consists of a complex network involving an extracellular matrix containing a wide variety of compounds. This complexity has hindered easy regulation. We will give Escherichia coli a much simpler but equally effective way of binding: mussel glue. Expressing the strongest protein responsible for the attachment of mussels to rocks, we can allow E coli to strongly attach to even glass and plastic, whenever we want it, and subsequently releasing it again. This system should be viewed in the same category as “ the wheel”, by itself it is just a neat trick, but combination is key. Combining it for example with an E coli capable biocatalytic conversion , one can create microbial production lines, use attachment for temporary rapid settling of biomass before product removal, or achieve fundamental premiers like bacterial cells forming a micro circle on command. | In our project we strive for full control of the attachment and detachment of cells. In nature attachment consists of a complex network involving an extracellular matrix containing a wide variety of compounds. This complexity has hindered easy regulation. We will give Escherichia coli a much simpler but equally effective way of binding: mussel glue. Expressing the strongest protein responsible for the attachment of mussels to rocks, we can allow E coli to strongly attach to even glass and plastic, whenever we want it, and subsequently releasing it again. This system should be viewed in the same category as “ the wheel”, by itself it is just a neat trick, but combination is key. Combining it for example with an E coli capable biocatalytic conversion , one can create microbial production lines, use attachment for temporary rapid settling of biomass before product removal, or achieve fundamental premiers like bacterial cells forming a micro circle on command. | ||
- | + | ===Workflow=== | |
+ | Our workflow has been designed in such a way that each project is individual and independent. All the projects however contribute to one greater project. | ||
+ | [[File:TUDelft-Horizontal_Workflow.jpg|center]] | ||
{{TU-footer}} | {{TU-footer}} |
Revision as of 09:56, 7 June 2011
Project Overview
In life one is bound to encounter problems. Nature knows this more than any other and her problem-solving ingenuity is impressive. With synthetic biology we are able to combine the best of all Nature's solutions. Designing these combinations with utility for humans in mind results in so-called “Genetically Engineered Machines”, the core of iGEM.
In our project we strive for full control of the attachment and detachment of cells. In nature attachment consists of a complex network involving an extracellular matrix containing a wide variety of compounds. This complexity has hindered easy regulation. We will give Escherichia coli a much simpler but equally effective way of binding: mussel glue. Expressing the strongest protein responsible for the attachment of mussels to rocks, we can allow E coli to strongly attach to even glass and plastic, whenever we want it, and subsequently releasing it again. This system should be viewed in the same category as “ the wheel”, by itself it is just a neat trick, but combination is key. Combining it for example with an E coli capable biocatalytic conversion , one can create microbial production lines, use attachment for temporary rapid settling of biomass before product removal, or achieve fundamental premiers like bacterial cells forming a micro circle on command.
Workflow
Our workflow has been designed in such a way that each project is individual and independent. All the projects however contribute to one greater project.