Team:TU Munich/Project
From 2010.igem.org
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== '''Overall project''' == | == '''Overall project''' == | ||
We, the TU Munich 2010 team, would like to change the usage and handling of Biobricks. Over the years so many teams spent time on evolving and constructing receptors and systems to detect a certain input that a variety of gorgeous oppurtunities is available so far. Nevertheless, up to now there are not real possibilities to link all those functionalities and built a network which can respond to many of those input signals in a highly differenciated way. We would like to provide a new system to control gene expression on RNA level which can be easily upscaled, which is capable of forming and/or/xor-links and offers for the first time the opportunity to built up complex and logical networks in ''E. coli'' cells. Isn't that great? <br> | We, the TU Munich 2010 team, would like to change the usage and handling of Biobricks. Over the years so many teams spent time on evolving and constructing receptors and systems to detect a certain input that a variety of gorgeous oppurtunities is available so far. Nevertheless, up to now there are not real possibilities to link all those functionalities and built a network which can respond to many of those input signals in a highly differenciated way. We would like to provide a new system to control gene expression on RNA level which can be easily upscaled, which is capable of forming and/or/xor-links and offers for the first time the opportunity to built up complex and logical networks in ''E. coli'' cells. Isn't that great? <br> | ||
+ | [Image:TUM2010 network.png|300 px|right|Network] | ||
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The concept on which we rely is a totally new on, based on the principle of attenuation. Attenuation is a very smart way of gene regulation which is known from bacterial cells. For example, E. coli only needs very little amounts of Tryptophan in its metabolism, so the amino-acyl-Synthetase for Tryptophan is only rarely synthesized. So the trp-operon contains an attenuator before the actual enzymes. If Tryptophan is absent, the rare tRNA loaded with Tryptophan will not be available at once, so the RNA Polymerase (RPO) is forced to stop. Sterics do not allow the formation of a stemloop with the RPO attached. If there is Tryptophan available and many tRNA-Trps float through the cell, the RPO can just continue, a stem loop is formed and the RPO falls off: The transcription of the following trp-operon is terminated. <br> | The concept on which we rely is a totally new on, based on the principle of attenuation. Attenuation is a very smart way of gene regulation which is known from bacterial cells. For example, E. coli only needs very little amounts of Tryptophan in its metabolism, so the amino-acyl-Synthetase for Tryptophan is only rarely synthesized. So the trp-operon contains an attenuator before the actual enzymes. If Tryptophan is absent, the rare tRNA loaded with Tryptophan will not be available at once, so the RNA Polymerase (RPO) is forced to stop. Sterics do not allow the formation of a stemloop with the RPO attached. If there is Tryptophan available and many tRNA-Trps float through the cell, the RPO can just continue, a stem loop is formed and the RPO falls off: The transcription of the following trp-operon is terminated. <br> | ||
We applied this principle of RNA-RNA interaction based transcription regulation to build switches based on antitermination. Antitermination means the avoidance of trancription termination by interaction with another RNA sequence (the signal), which binds to the transcription mRNA and anticipates the formation of a stem loop. So you basicly get a yes/no answer with a first switch: If the small RNA piece is available, transcription will continue. If not, it will be terminated. It's that easy! <br> | We applied this principle of RNA-RNA interaction based transcription regulation to build switches based on antitermination. Antitermination means the avoidance of trancription termination by interaction with another RNA sequence (the signal), which binds to the transcription mRNA and anticipates the formation of a stem loop. So you basicly get a yes/no answer with a first switch: If the small RNA piece is available, transcription will continue. If not, it will be terminated. It's that easy! <br> |
Revision as of 18:14, 5 September 2010
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Overall projectWe, the TU Munich 2010 team, would like to change the usage and handling of Biobricks. Over the years so many teams spent time on evolving and constructing receptors and systems to detect a certain input that a variety of gorgeous oppurtunities is available so far. Nevertheless, up to now there are not real possibilities to link all those functionalities and built a network which can respond to many of those input signals in a highly differenciated way. We would like to provide a new system to control gene expression on RNA level which can be easily upscaled, which is capable of forming and/or/xor-links and offers for the first time the opportunity to built up complex and logical networks in E. coli cells. Isn't that great? The concept on which we rely is a totally new on, based on the principle of attenuation. Attenuation is a very smart way of gene regulation which is known from bacterial cells. For example, E. coli only needs very little amounts of Tryptophan in its metabolism, so the amino-acyl-Synthetase for Tryptophan is only rarely synthesized. So the trp-operon contains an attenuator before the actual enzymes. If Tryptophan is absent, the rare tRNA loaded with Tryptophan will not be available at once, so the RNA Polymerase (RPO) is forced to stop. Sterics do not allow the formation of a stemloop with the RPO attached. If there is Tryptophan available and many tRNA-Trps float through the cell, the RPO can just continue, a stem loop is formed and the RPO falls off: The transcription of the following trp-operon is terminated. Project DetailsPart 2The ExperimentsPart 3Results |