Construction and Testing
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==Construction Tree== | ==Construction Tree== | ||
The diagram below outlines our parallel construction plan, from individual registry parts to the final half-adder. Because many people were working on the project at once, it is designed to keep everyone organised. | The diagram below outlines our parallel construction plan, from individual registry parts to the final half-adder. Because many people were working on the project at once, it is designed to keep everyone organised. | ||
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[[Image:UW_Construction_Chart.jpg|thumb|500px|left|Construction Chart]] | [[Image:UW_Construction_Chart.jpg|thumb|500px|left|Construction Chart]] | ||
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Diagram details: | Diagram details: | ||
*Expected fragment sizes are shown at every node so gel results can be analyzed quickly. | *Expected fragment sizes are shown at every node so gel results can be analyzed quickly. | ||
- | *Vector resistances for each part/construct are shown, with | + | *Vector resistances for each part/construct are shown, with blue representing ampicillin resistance and red representing kanamycin resistance. Purple represents a resistance to both. |
*Parts and developing constructs all have abbreviated names for ease of labeling. To make the subtle distinction between a coding sequence and a coding sequence with a ribosome binding site, we use a ' on the computer and an underline when writing. A double ' or double underline indicates a coding sequence with a ribosome binding site and a transcriptional terminator. | *Parts and developing constructs all have abbreviated names for ease of labeling. To make the subtle distinction between a coding sequence and a coding sequence with a ribosome binding site, we use a ' on the computer and an underline when writing. A double ' or double underline indicates a coding sequence with a ribosome binding site and a transcriptional terminator. | ||
- | *Arrows show the direction of DNA cloning and specify which restriction enzymes to use for cutting. Hollow arrows are present when two parts are ligated from vectors of the same resistance, requiring additional methods such as the use of alkaline phosphatase, gel extraction, or a three-way ligation into a vector | + | *Arrows show the direction of DNA cloning and specify which restriction enzymes to use for cutting. Hollow arrows are present when two parts are ligated from vectors of the same resistance, requiring additional methods such as the use of alkaline phosphatase, gel extraction, or a three-way ligation into a vector with different resistance. |
- | *The numbers 1-2-3-3.5-4 | + | *The numbers 1-2-3-3.5-4 indicate which major protocols need to be carried at each step in the assembly cycle. |
<br style="clear:both;"/> | <br style="clear:both;"/> | ||
Revision as of 16:44, 26 October 2007
Contents |
Construction Tree
The diagram below outlines our parallel construction plan, from individual registry parts to the final half-adder. Because many people were working on the project at once, it is designed to keep everyone organised.
Diagram details:
- Expected fragment sizes are shown at every node so gel results can be analyzed quickly.
- Vector resistances for each part/construct are shown, with blue representing ampicillin resistance and red representing kanamycin resistance. Purple represents a resistance to both.
- Parts and developing constructs all have abbreviated names for ease of labeling. To make the subtle distinction between a coding sequence and a coding sequence with a ribosome binding site, we use a ' on the computer and an underline when writing. A double ' or double underline indicates a coding sequence with a ribosome binding site and a transcriptional terminator.
- Arrows show the direction of DNA cloning and specify which restriction enzymes to use for cutting. Hollow arrows are present when two parts are ligated from vectors of the same resistance, requiring additional methods such as the use of alkaline phosphatase, gel extraction, or a three-way ligation into a vector with different resistance.
- The numbers 1-2-3-3.5-4 indicate which major protocols need to be carried at each step in the assembly cycle.
Testing Constructs
We use the fluorescent proteins GFP and RFP as reporter genes to test the functionality of some of the components and constructs of our half-adder design. Where possible, we make use of the lac inducible promoter to control expression of the enhancing or repressing elements.
Comparing basal and induced expression levels for the quorum sensing promoters
Testing functionality of the various promoters
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