Team:Wash U

From 2009.igem.org

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== '''Team''' ==
== '''Team''' ==
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The first ever Washington University iGEM team is composed of nine undergraduate juniors and seniors majoring in Biology, Molecular Biology and Bioechmisty, Biomedical Engineering Chemical Engineering.  Under the leadership of Dr. Blankenship (Biology and Chemistry departments) the teams hopes to succeed in modifying the pathway of photosynthesis, which we believe is a first for the iGEM competition.  Highly motivated and well trained Wash U looks to make a big splash at MIT in October.  To learn more about our team, please click [https://2009.igem.org/Team:Wash_U/Team here].
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The first ever Washington University iGEM team is composed of nine undergraduate juniors and seniors majoring in Biology, Molecular Biology and Bioechmisty, Biomedical Engineering and Chemical Engineering.  Under the leadership of Dr. Blankenship (Biology and Chemistry departments) our team plans to synthetically regulate expression of the photosynthetic apparatus, which we believe is a first for both the iGEM competition and synthetic biology.  To learn more about our highly motivated and well-trained team, please click [https://2009.igem.org/Team:Wash_U/Team here].
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== '''Project''' ==
== '''Project''' ==

Revision as of 17:29, 22 June 2009



Welcome to Washington University's 2009 iGEM Team page!
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Our Team Our Project

Team

The first ever Washington University iGEM team is composed of nine undergraduate juniors and seniors majoring in Biology, Molecular Biology and Bioechmisty, Biomedical Engineering and Chemical Engineering. Under the leadership of Dr. Blankenship (Biology and Chemistry departments) our team plans to synthetically regulate expression of the photosynthetic apparatus, which we believe is a first for both the iGEM competition and synthetic biology. To learn more about our highly motivated and well-trained team, please click here.

Project

Our goal for this project is to modify the purple bacteria, Rhodobacter Sphaeroides, and thereby increase the efficiency of its photosynthetic pathway. The reaction center of the photosystem (where light photons are converted to chemical energy) is surrounded by antenna complexes which feed energy into the reaction center. Low light conditions favor a larger number of antenna molecules while more intense lighting calls for fewer. We will attempt to insert a light sensor into the pathway to create a more dynamic antenna size and which will increase the overall efficiency of the cell. To learn more about our project, please click here.



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