Reporter Project
From 2011.igem.org
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<h2>The Reporter</h2> | <h2>The Reporter</h2> | ||
- | <p> Our reporter system focused on modifying the part created by Imperial College London iGEM 2010 for their fast reporter system. Imperial’s quick acting response module used the transcription of TEV protease to cleave the bond between the GFP, C23O fusion protein. This unbound form of C230 could then form a tetramer and convert the colorless substrate catechol into a yellow product. The details on their part can be found <a href="http://partsregistry.org/Part:BBa_K316007">here</a>. | + | <p> Our reporter system focused on modifying and improving the part created by Imperial College London iGEM 2010 for their fast reporter system. Imperial’s quick acting response module used the transcription of TEV protease to cleave the bond between the GFP, C23O fusion protein. This unbound form of C230 could then form a tetramer and convert the colorless substrate catechol into a yellow product. The details on their part can be found <a href="http://partsregistry.org/Part:BBa_K316007">here</a>. |
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<h2>Our modifications and expansions of part K316007: Recombinant GFP-XylE protein</h2> | <h2>Our modifications and expansions of part K316007: Recombinant GFP-XylE protein</h2> | ||
- | <p>We have cloned and created a catalog of the individual fusion parts included in the fast acting reporter, each with standard 25 prefix and suffix. These parts can be quickly assembled using the Freiburg BioBricking Assembly technique, | + | <p>We have cloned and created a catalog of the individual fusion parts included in the fast acting reporter, each with standard 25 prefix and suffix. These parts can be quickly assembled using the Freiburg BioBricking Assembly technique, and recombined to produce and experiment with new variations of the recombinant fusion protein. New variations of this part can be created, optimized, and applied to many different situations requiring the use of a rapid reporter in a "in vivo" system. For example, this could be done in our proposed bacterial dosimeter device. |
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- | Along these lines our team has designed our own iterations and improvements to the fast reporter protein. In particular, we focused on reducing any leakiness of Imperial’s construct (see our experimental data section for information on our assessment of the original part. To achieve this we plan to link a second GFP to the C-terminus of C230; this new linkage would be cleavable by RecA and create a fast reporter system specifically customized for our biosensor system.</p> | + | Along these lines our team has designed our own iterations and improvements to the fast reporter protein. In particular, we focused on reducing any leakiness of Imperial’s construct (see our experimental data section for information on our assessment of the original part). To achieve this we plan to link a second GFP to the C-terminus of C230; this new linkage would be cleavable by RecA and create a fast reporter system specifically customized for our biosensor system.</p> |
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<h2>Looking Towards the Future</h2> | <h2>Looking Towards the Future</h2> | ||
- | <p>Assembly and testing of over 40 different variations of the fast reporter system are currently | + | <p>Assembly and testing of over 40 different variations of the fast reporter system are currently underway. Completion and characterization of some of these variants should be accomplished in time for the 2011 Jamboree.</p> |
+ | </br> | ||
+ | <p><a href="https://static.igem.org/mediawiki/2011/8/80/PUSReporter_Tables_of_Parts.pdf">Click Here</a> for a list of what we've constructed, what were working on, and what we've tested.</p> | ||
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Latest revision as of 03:06, 29 September 2011
The Reporter
Our reporter system focused on modifying and improving the part created by Imperial College London iGEM 2010 for their fast reporter system. Imperial’s quick acting response module used the transcription of TEV protease to cleave the bond between the GFP, C23O fusion protein. This unbound form of C230 could then form a tetramer and convert the colorless substrate catechol into a yellow product. The details on their part can be found here.
Our modifications and expansions of part K316007: Recombinant GFP-XylE protein
We have cloned and created a catalog of the individual fusion parts included in the fast acting reporter, each with standard 25 prefix and suffix. These parts can be quickly assembled using the Freiburg BioBricking Assembly technique, and recombined to produce and experiment with new variations of the recombinant fusion protein. New variations of this part can be created, optimized, and applied to many different situations requiring the use of a rapid reporter in a "in vivo" system. For example, this could be done in our proposed bacterial dosimeter device. Along these lines our team has designed our own iterations and improvements to the fast reporter protein. In particular, we focused on reducing any leakiness of Imperial’s construct (see our experimental data section for information on our assessment of the original part). To achieve this we plan to link a second GFP to the C-terminus of C230; this new linkage would be cleavable by RecA and create a fast reporter system specifically customized for our biosensor system.
Other proposed modifications by our team included the use of new fusion protein linkers and new enzyme subunits, specifically the B-glucuronidase and B-galactose reporters. These two possible enzymes could be made to produce rapidly a blue color product from substrates that are slightly less toxic to cells then catechol.
Looking Towards the Future
Assembly and testing of over 40 different variations of the fast reporter system are currently underway. Completion and characterization of some of these variants should be accomplished in time for the 2011 Jamboree.
Click Here for a list of what we've constructed, what were working on, and what we've tested.