Team:SDU-Denmark/project-t

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(Photosensor)
(Photosensor)
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Note that although the bacteria will be stationary in our system, since they are glued to the inner surface of the flowchannel, our construct in reality confers phototactic ability to E. coli.<br><br>
Note that although the bacteria will be stationary in our system, since they are glued to the inner surface of the flowchannel, our construct in reality confers phototactic ability to E. coli.<br><br>
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[[Image:Phototaxis_without_attractant.png‎ | 700px]][[Image:Phototaxis_with_attractant.png‎ | 600px]]
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[[Image:Phototaxis_without_attractant.png‎ | 700px]]
The way the halobacterial pathway works is that the photonreceptor is a protein called sensory rhodopsin II, which absorbs the blue light and in response changes it's conformation. HtrII is just a transducer and signals this to CheA, which in turn gets phosphorylated and afterwards passes the phosphate group on to CheB. Phosphorylated CheB binds to the flagellar motor switch, so that the flagella starts rotating clockwise, which induces the tumbling motility pattern. The more CheY gets phosphorylated the higher the tumbling frequency will be.  
The way the halobacterial pathway works is that the photonreceptor is a protein called sensory rhodopsin II, which absorbs the blue light and in response changes it's conformation. HtrII is just a transducer and signals this to CheA, which in turn gets phosphorylated and afterwards passes the phosphate group on to CheB. Phosphorylated CheB binds to the flagellar motor switch, so that the flagella starts rotating clockwise, which induces the tumbling motility pattern. The more CheY gets phosphorylated the higher the tumbling frequency will be.  

Revision as of 09:58, 25 October 2010