Team:SDU-Denmark/project-t

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(Phototaxis)
(Phototaxis)
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Different taxis pathways that steer cells towards favorable conditions and away from danger work by regulating the frequency of tumbling events [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 5]]. An example is when a bacterium gets close to the source of a lethal toxin, then intracellular pathways will increase the frequency of tumbling events, in effect preventing the cell from death. Since the frequency of tumbling events will decrease if the cell is going in a direction away from the toxin, it will “encourage” the cell to continue in that direction. In the case of an attractant such as an increase in nutrient concentration, the pattern will be opposite, so that the cell is encouraged to continue towards the source of the attractant. This form of movement, combining tumbling and running, with regulation of the tumbling frequency is termed a biased random walk [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 5]]. <br><br>
Different taxis pathways that steer cells towards favorable conditions and away from danger work by regulating the frequency of tumbling events [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 5]]. An example is when a bacterium gets close to the source of a lethal toxin, then intracellular pathways will increase the frequency of tumbling events, in effect preventing the cell from death. Since the frequency of tumbling events will decrease if the cell is going in a direction away from the toxin, it will “encourage” the cell to continue in that direction. In the case of an attractant such as an increase in nutrient concentration, the pattern will be opposite, so that the cell is encouraged to continue towards the source of the attractant. This form of movement, combining tumbling and running, with regulation of the tumbling frequency is termed a biased random walk [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 5]]. <br><br>
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[[Image:Team-SDU-Denmark-Biased_random_walk.png | 300px | thumb |right | A biased random walk motion pattern.]] <br>
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[[Image:Team-SDU-Denmark-Biased_random_walk.png | 300px | thumb |right | '''Figure 1:''' A biased random walk motion pattern.]] <br>
To understand how this can work we need a simplified understanding of the chemotaxis pathway at a molecular level. Chemotactic receptors can both increase and decrease tumbling frequencies to generate a biased random walk behavior. Increased tumbling is achieved through a phosphorylation cascade beginning with the binding of a repellant to a transmembrane receptor. The receptor is linked to two proteins CheW and CheA. CheA is a histidine-kinase that will autophosphorylate when the repellant binds. The phosphoryl group is then transferred to CheY, thereby activating the protein. The flagellar motor complex has high affinity for phosphorylated CheY (CheY-p), and binding reverses the mode of movement from run to tumble. CheY-p is continuously dephosphorylated back to CheY by CheZ which is always present in the cytosol. A receptor sensing an attractant might instead switch from the default active CheA state to an inactive state when it’s ligand is bound, thus decreasing CheY phosphorylation [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 4]].<br><br>
To understand how this can work we need a simplified understanding of the chemotaxis pathway at a molecular level. Chemotactic receptors can both increase and decrease tumbling frequencies to generate a biased random walk behavior. Increased tumbling is achieved through a phosphorylation cascade beginning with the binding of a repellant to a transmembrane receptor. The receptor is linked to two proteins CheW and CheA. CheA is a histidine-kinase that will autophosphorylate when the repellant binds. The phosphoryl group is then transferred to CheY, thereby activating the protein. The flagellar motor complex has high affinity for phosphorylated CheY (CheY-p), and binding reverses the mode of movement from run to tumble. CheY-p is continuously dephosphorylated back to CheY by CheZ which is always present in the cytosol. A receptor sensing an attractant might instead switch from the default active CheA state to an inactive state when it’s ligand is bound, thus decreasing CheY phosphorylation [[https://2010.igem.org/Team:SDU-Denmark/project-t#References 4]].<br><br>
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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 a phototactic ability to ''E. coli''.
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 a phototactic ability to ''E. coli''.
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[[image:Phototaxis_mechanism.png‎ | 600px | thumb | '''A.''' The SRII rhodopsin has not been activated. Note that CheA is active by default, continuosly autophosphorylating itself, and cycling back to it's unphosphorylated state by transfering the phosphoryl group to CheY. High levels of CheY-P will induce tumbling motion in the flagella. Also, note that CheZ continuously dephosphorylates CheY.<br>
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[[image:Phototaxis_mechanism.png‎ | 600px | thumb |'''Figure 2:'''' '''A.''' The SRII rhodopsin has not been activated. Note that CheA is active by default, continuosly autophosphorylating itself, and cycling back to it's unphosphorylated state by transfering the phosphoryl group to CheY. High levels of CheY-P will induce tumbling motion in the flagella. Also, note that CheZ continuously dephosphorylates CheY.<br>
'''B.''' SRII is hit with a photon, causing conformational change of the entire complex, and shutting of CheA. The Inactivation of CheA halts production of CheY-P, and CheZ rapidly dephosphorylates the remaining CheY-P, resulting in a reduced frequency of tumbling.]]
'''B.''' SRII is hit with a photon, causing conformational change of the entire complex, and shutting of CheA. The Inactivation of CheA halts production of CheY-P, and CheZ rapidly dephosphorylates the remaining CheY-P, resulting in a reduced frequency of tumbling.]]

Revision as of 16:30, 26 October 2010