Team:ETH Zurich/labblog/20140825

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(Diffusion Experiments)
(Monday, 25th August)
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==== Monday, 25th August ====
==== Monday, 25th August ====
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Now that we tested the different constructs for leakiness, dose response and cross talk, we are investigating in the diffusion rate of AHL. Therefor we designed a chip with chambers connected by channels of different length (see figure). In one chamber we added a strain containing a regulator and a sensor plasmid, to the second chamber we added AHL or an AHL producer strain. As soon as AHL is diffused to the former chamber it induces sfGFP production on the sensor plasmid. The time it takes until we can measure the sfGFP signal and the length of the channel gives us information about the velocity of AHL diffusion.
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Now that we tested the different constructs for leakiness, dose response and cross talk, we are investigating in the diffusion rate of AHL. Therefore we designed a chip with chambers connected by channels of different length (see figure). In one chamber we added a strain containing a regulator and a sensor plasmid, to the second chamber we added AHL or an AHL producer strain. As soon as AHL is diffused to the former chamber it induces sfGFP production on the sensor plasmid. The time it takes until we can measure the sfGFP signal and the length of the channel gives us information about the velocity of AHL diffusion.
[[File:Channelchip.jpg|x300px]]
[[File:Channelchip.jpg|x300px]]

Revision as of 13:36, 3 September 2014

Diffusion Experiments

Monday, 25th August

Now that we tested the different constructs for leakiness, dose response and cross talk, we are investigating in the diffusion rate of AHL. Therefore we designed a chip with chambers connected by channels of different length (see figure). In one chamber we added a strain containing a regulator and a sensor plasmid, to the second chamber we added AHL or an AHL producer strain. As soon as AHL is diffused to the former chamber it induces sfGFP production on the sensor plasmid. The time it takes until we can measure the sfGFP signal and the length of the channel gives us information about the velocity of AHL diffusion.

Channelchip.jpg

Two main experiment designs were tested and modified: the agar-design and the beads-design. For the agar-design we filled the chamber and channels with LB-agar or in a second attempt with agarose only. Subsequently, we punched a cylindric hole in each chamber. The capacities were filled with regulator/sensor strain culture or AHL/AHL producer strain culture, respectively. After 3 to 4 h at 37 °C we could observe an increase in the sfGFP signal. Since we used comparably high concentration of AHL in our first attempts, we could not detect a delayed sfGFP signal for chambers connected by a longer channel. The experiment will be repeated using lower concentrations. However, the conducting the experiment using the agar-design, we encountered a problem: after some hours the LB-agar/agarose started to shrink and dried out. Thus, the agar-design cannot be used without modifications for experiments of longer duration. In an attempt we only left a small agar fragment in each channel, so as to decrease chance of it drying out, while avoiding at the same time that bacteria from one chamber reach the other chamber. At the moment, we are optimising the agar-design. The bead-design consists of an alginate bead for each chamber and a liquid medium in between. The beads either contained regulator/sensor-bacteria or AHL.

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