Team:British Columbia/Project

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(Tools used and produced)
(Traffic Light Overview)
 
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Depending on the concentration of a particular substrate in the medium, E. coli will respond accordingly by producing different coloured fluorescence proteins. A diagram would look like this:
Depending on the concentration of a particular substrate in the medium, E. coli will respond accordingly by producing different coloured fluorescence proteins. A diagram would look like this:
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[[Image:E_coli_Traffic_Light_Subprojects.png|center|thumb||400px|The ''E. coli'' Traffic Light Biosensor is composed of three major subparts: variable arabinose-inducible promoters, RNA lock and key system, and reverse antisense promoters for input detection, color activation and traffic light switching respectively.]]
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[[Image:E_coli_Traffic_Light_Subprojects.png|center|thumb||600px|The ''E. coli'' Traffic Light Biosensor is composed of three major subparts: variable arabinose-inducible promoters, RNA lock and key system, and reverse antisense promoters for input detection, color activation and traffic light switching respectively.]]
Here is what's happening inside our traffic light:
Here is what's happening inside our traffic light:
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[[Image:E_coli_Traffic_Light_Step_by_Step.png|thumb|center|700px|Schematic black-box representation of the E. coli Biosensor that detects various concentration inputs and color outputs. The idea is discrete analog outputs based on a user-specified threshold for each range of concentration.]]
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[[Image:E_coli_Traffic_Light_Step_by_Step.png|thumb|center|850px|Schematic black-box representation of the E. coli Biosensor that detects various concentration inputs and color outputs. The idea is discrete analog outputs based on a user-specified threshold for each range of concentration.]]
For our ideas to work, we will need:<br>
For our ideas to work, we will need:<br>
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:http://www.pkts.ca/brickedit/ - Biobrick picture maker - enter a sequence of letters corresponding to the icons, and the program will produce a concatenated file of the Biobrick.
:http://www.pkts.ca/brickedit/ - Biobrick picture maker - enter a sequence of letters corresponding to the icons, and the program will produce a concatenated file of the Biobrick.
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Also, we generated a handy Fasta file containing every biobrick:
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Also, we generated a handy Fasta file containing every biobrick from [http://partsregistry.org/cgi/partsdb/pgroup.cgi?pgroup=List Here]:
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:[[Media:Biobricks.zip|Biobricks.zip]] - Fasta file containing every biobrick from [http://partsregistry.org/cgi/partsdb/pgroup.cgi?pgroup=List Here]
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:[[Media:Biobricks.zip|Biobricks.zip]] - Fasta file containing every biobrick
We also found the following tools very helpful:
We also found the following tools very helpful:
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http://rna.tbi.univie.ac.at/ - a package of prediction tools for RNA structures; we used RNAfold to annotate the key and lock structures
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:http://rna.tbi.univie.ac.at/ - a package of prediction tools for RNA structures; we used RNAfold to annotate the key and lock structures
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http://mobyle.pasteur.fr/cgi-bin/portal.py - a set of web-accessible bioinformatics tools including Mfold, which determines 2D RNA structure and draws it
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:http://mobyle.pasteur.fr/cgi-bin/portal.py - a set of web-accessible bioinformatics tools including Mfold, which determines 2D RNA structure and draws it
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http://frodo.wi.mit.edu/ - Primer3, a primer design program
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:http://frodo.wi.mit.edu/ - Primer3, a primer design program

Latest revision as of 03:08, 22 October 2009

Traffic Light Overview

Depending on the concentration of a particular substrate in the medium, E. coli will respond accordingly by producing different coloured fluorescence proteins. A diagram would look like this:

The E. coli Traffic Light Biosensor is composed of three major subparts: variable arabinose-inducible promoters, RNA lock and key system, and reverse antisense promoters for input detection, color activation and traffic light switching respectively.

Here is what's happening inside our traffic light:

Schematic black-box representation of the E. coli Biosensor that detects various concentration inputs and color outputs. The idea is discrete analog outputs based on a user-specified threshold for each range of concentration.

For our ideas to work, we will need:
1. A variable sensitivity biosensor
2. A lock-and-key logic gate system]
3. An antisense "off" switch






Tools used and produced

To assist our project, we produced a Biobrick digestion engine and Biobrick picture maker to help out the project:

http://www.pkts.ca/bb - Biobrick digestion engine - enter the name of a biobrick plasmid and biobrick insert, and this will show you the product of an EcoRI and PstI digestion/ligation as a FASTA file (suitable for viewing in your favorite program).
http://www.pkts.ca/brickedit/ - Biobrick picture maker - enter a sequence of letters corresponding to the icons, and the program will produce a concatenated file of the Biobrick.

Also, we generated a handy Fasta file containing every biobrick from [http://partsregistry.org/cgi/partsdb/pgroup.cgi?pgroup=List Here]:

Biobricks.zip - Fasta file containing every biobrick

We also found the following tools very helpful:

http://rna.tbi.univie.ac.at/ - a package of prediction tools for RNA structures; we used RNAfold to annotate the key and lock structures
http://mobyle.pasteur.fr/cgi-bin/portal.py - a set of web-accessible bioinformatics tools including Mfold, which determines 2D RNA structure and draws it
http://frodo.wi.mit.edu/ - Primer3, a primer design program