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Team:MIT/Projects/Project1
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==Metabolic Engineering of PCB Synthesis in Yeast== | ==Metabolic Engineering of PCB Synthesis in Yeast== | ||
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As shown in the image above, phycocyanobilin (PCB) plays a crucial part in the PhyB-PIF3 system. Once PCB is in the active conformation it allows the phytochrome (PhyB) to bind to the integrating factor (PIF3). | As shown in the image above, phycocyanobilin (PCB) plays a crucial part in the PhyB-PIF3 system. Once PCB is in the active conformation it allows the phytochrome (PhyB) to bind to the integrating factor (PIF3). | ||
| - | [[Image:PCB_Structure.gif|350px]] [[Image:Pr_Pfr_Cartoon.png|170px]] | + | <center>[[Image:PCB_Structure.gif|350px]] [[Image:Pr_Pfr_Cartoon.png|170px]]</center> |
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Revision as of 01:09, 20 October 2009
Metabolic Engineering of PCB Synthesis in Yeast
As shown in the image above, phycocyanobilin (PCB) plays a crucial part in the PhyB-PIF3 system. Once PCB is in the active conformation it allows the phytochrome (PhyB) to bind to the integrating factor (PIF3).
Developing the Standard: PCB from Spirulina
We decided to use a standard used in many other experiments involving phytochromes. Phycocyanobilin (PCB) extracted from Spirulina is a commonly used standard, as Spirulina produces a large amount of chromophores. We used Spirulina which was bought at Vitamin World as it is commonly used as a dietary supplement.
Chromophores have a very high absorbance around 680nm. Here is an example of an absorbance spectrum:
We followed the protocol that the Quail Lab used to extract the PCB from Spirulina, and were able to produce the following spectrum:
The concentration is found by this formula:
Engineering the PCB Synthesis Pathway into Yeast
