Team:Harvard/Judging
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=Foundational Advance= | =Foundational Advance= | ||
==Combining Computational Design, High-throughput Synthesis, and Selection== | ==Combining Computational Design, High-throughput Synthesis, and Selection== | ||
- | We <html><x>brought together 3 new technologies</x></html> to create a working pipeline that allows scientists to <html><x>engineer novel protein-DNA interactions</x></html>. Our methods represents a <html><x>fundamentally different way of building new biological parts and devices</x></html>: using selection to | + | We <html><x>brought together 3 new technologies</x></html> to create a working pipeline that allows scientists to <html><x>engineer novel protein-DNA interactions</x></html>. Our methods represents a <html><x>fundamentally different way of building new biological parts and devices</x></html>: using selection to identify working members of a large computationally predicted library of potential designs. |
==Putting parts and devices directly onto the genome== | ==Putting parts and devices directly onto the genome== | ||
<html><x>The genome is the next frontier in synthetic biology</x></html>. Our project has made use of genome modification in order to design a new device that allows the testing of DNA-protein interactions. We want iGEM and the broader synthetic biology community to use these techniques as an alternative to plasmids. To encourage their adoption, <html><x>we have submitted new E. coli chassis that allow easy genome modification</x></html>, and <html><x>we have provided detailed protocols</x></html> for their use. | <html><x>The genome is the next frontier in synthetic biology</x></html>. Our project has made use of genome modification in order to design a new device that allows the testing of DNA-protein interactions. We want iGEM and the broader synthetic biology community to use these techniques as an alternative to plasmids. To encourage their adoption, <html><x>we have submitted new E. coli chassis that allow easy genome modification</x></html>, and <html><x>we have provided detailed protocols</x></html> for their use. | ||
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Revision as of 03:51, 29 October 2011
Wiki Highlights
- Read our project description and summary on our Project page: more details on how team members completed work for the three sections of our project are on Design, Synthesize, and Test pages, respectively.
- Results of all parts of our project (including our biobricks) are located on our Results page, along with an Attributions and Acknowledgments section.
- Human practices can be found on our Human Practices page.
Please be sure to stop by our poster during the poster session with any questions.
Accomplishments
Experimental Results
✓ Researched zinc finger proteins and choose 6 novel,
✓ Generated
✓ Used three recently developed technologies together for the first time: a
✓ Expressed those 55,000 sequences
✓ Created a
✓ Found at least
Biobricks and Protocols
✓ Submitted
✓ Created several
✓ Used and shared our
✓ Made protocols, Biobricks, and source code
Human Practices
✓ [http://www.youtube.com/watch?feature=player_embedded&v=eBT8SaBAm80 Interviewed]
✓ Researched
✓ Created a
✓ Reached out to our elected representatives about the potential effects of IP on zinc finger research and synthetic biology generally
✓ Handed out
✓
Foundational Advance
Combining Computational Design, High-throughput Synthesis, and Selection
We