Team:Minnesota

From 2009.igem.org

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!align="center"|[[Team:Minnesota/Team|<font color="gold">The Team</font>]]
!align="center"|[[Team:Minnesota/Team|<font color="gold">The Team</font>]]
!align="center"|[[Team:Minnesota/Project|<font color="gold">The Project</font>]]
!align="center"|[[Team:Minnesota/Project|<font color="gold">The Project</font>]]
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!align="center"|[[Team:Minnesota/Parts|<font color="gold">Submitted Parts</font>]]
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!align="center"|[[Team:Minnesota/Designer|<font color="gold">SynBioSS Designer</font>]]
!align="center"|[[Team:Minnesota/Modeling|<font color="gold">Modeling</font>]]
!align="center"|[[Team:Minnesota/Modeling|<font color="gold">Modeling</font>]]
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!align="center"|[[Team:Minnesota/Designer|<font color="gold">SynBioSS Designer</font>]]
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!align="center"|[[Team:Minnesota/Notebook|<font color="gold">Experimental</font>]]
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!align="center"|[[Team:Minnesota/Parts Characterization|<font color="gold">Parts Characterization</font>]]
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!align="center"|[[Team:Minnesota/Parts Characterization|<font color="gold">Competition Requirements</font>]]
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!align="center"|[[Team:Minnesota/Notebook|<font color="gold">Experiments and Calendar</font>]]
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<h2>The Mission</h2>
<h2>The Mission</h2>
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<p>Recently, the field of synthetic biology has produced genetic circuits that are capable of emulating logic circuits commonly found in digital electronics. One such circuit is an AND gate, which takes two inputs and produces a response if and only if both inputs are present. Otherwise the system produces no response. A system capable of generating these responses has been produced in both prokaryotes and eukaryotes. However, these systems are not high fidelity logic gates because of the fact that they are in biological systems. This is the problem our group will work on this summer.</p>
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<p>We are working on a very well studied AND gate, which is composed of elements of the Tet, Lac, and lambda-phage promoters and is responsive to the commonly-used inducers IPTG and aTc, producing GFP as an output signal.  
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<p>We will use a very well studied AND gate, which is composed of elements of the Tet, Lac, and lambda-phage promoters and is responsive to the commonly-used inducers IPTG and aTc, producing GFP as an output signal. Instead of using the AND gate in its complete form, we will isolate elements of the gate and study them individually. This will allow for a greater understanding of how exactly this AND gate works, and will eventually allow for creation of better AND gates, and a more predictable response to inputs by the biological systems.</p>
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Well, we have decided not to ride the wave of ever-more complex synthetic constructs. Instead, we will isolate elements of the AND gate and study them individually. This will allow for a greater understanding of how exactly this AND gate works, and will eventually allow for creation of better AND gates, and a more predictable response to inputs by the biological systems.</p>
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<p>Our group will be doing both experimental and modeling work this year. These two approachs will both complement each other. The experimental data will be used to refine the mathematical models, while the models will determine good directions for the experiments to pursue. We will go into greater detail on both these aspects on theeir respective wiki pages. The approach we are taking can be applied to many other biological circuits and can lead to greater understanding of how to engineer biological circuits.
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<p>Our group will be doing both experimental and modeling work this year. These two approachs will complement each other. The experimental data will be used to refine the mathematical models, while the models will determine good directions for the experiments to pursue. We will go into greater detail on both these aspects on theeir respective wiki pages. The approach we are taking can be applied to many other biological circuits and can lead to greater understanding of how to engineer biological circuits.</p>
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<p> What is unique in our work is the effort to develop software tools that streamline the construction of synthetic biological systems. The Synthetic Biology Software Suite is the product of our work, and this year iGEM students are working on SynBioSS Designer, a tool that uses Registry parts to build a model of biomolecular interaction. This model can be used to simulate the dynamic behavior of the gene network.</p>
<h2>Highlights for the Judges</h2>
<h2>Highlights for the Judges</h2>
Judges! Please navigate to our [http://2009.igem.org/Team:Minnesota/Criteria Judging Criteria] page for a comprehensive list of UMN's fulfilled medal requirements and links throughout the wiki.
Judges! Please navigate to our [http://2009.igem.org/Team:Minnesota/Criteria Judging Criteria] page for a comprehensive list of UMN's fulfilled medal requirements and links throughout the wiki.

Latest revision as of 20:18, 23 June 2010

Mnlogo.jpg
Home The Team The Project SynBioSS Designer Modeling Experimental Competition Requirements


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Welcome!

Welcome to the Team Minnesota Wiki for iGEM 2009!

We are a team of undergraduate and graduate students along with many advisors. This is the second year that Minnesota has sent a team to iGEM. Last year we were runners-up for the Best New BioBrick part (Natural) and we hope to accomplish even more with our design of a logical AND gate in E. coli this year.

The Mission

We are working on a very well studied AND gate, which is composed of elements of the Tet, Lac, and lambda-phage promoters and is responsive to the commonly-used inducers IPTG and aTc, producing GFP as an output signal. Well, we have decided not to ride the wave of ever-more complex synthetic constructs. Instead, we will isolate elements of the AND gate and study them individually. This will allow for a greater understanding of how exactly this AND gate works, and will eventually allow for creation of better AND gates, and a more predictable response to inputs by the biological systems.

Our group will be doing both experimental and modeling work this year. These two approachs will complement each other. The experimental data will be used to refine the mathematical models, while the models will determine good directions for the experiments to pursue. We will go into greater detail on both these aspects on theeir respective wiki pages. The approach we are taking can be applied to many other biological circuits and can lead to greater understanding of how to engineer biological circuits.

What is unique in our work is the effort to develop software tools that streamline the construction of synthetic biological systems. The Synthetic Biology Software Suite is the product of our work, and this year iGEM students are working on SynBioSS Designer, a tool that uses Registry parts to build a model of biomolecular interaction. This model can be used to simulate the dynamic behavior of the gene network.

Highlights for the Judges

Judges! Please navigate to our Judging Criteria page for a comprehensive list of UMN's fulfilled medal requirements and links throughout the wiki.