Team:Grenoble-EMSE-LSU/Project/Biology

From 2013.igem.org

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                                       <h3>Influence of Light Intensity</h3>
                                       <h3>Influence of Light Intensity</h3>
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                                       <p>After having shown that the KillerRed protein was suitable for controlling living bacterial cell density with light, we decided to perform additional characterization experiments. The first idea was to evaluate the half-life of this fluorescent protein, a parameter that was of interest for our model. Additionally, isolation of the protein from bacteria enabled us to derive a relationship between fluorescence and protein concentration, in order to more accurately estimate the amount of KR per cell.<br><br>
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                                       <p>After having shown that the KillerRed protein was suitable for controlling living bacterial cell density with light, we decided to perform additional characterization experiments. Isolation of the protein from bacteria enabled us to derive a relationship between fluorescence and protein concentration, in order to more accurately estimate the amount of KR per cell.<br><br>
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                                      <p>Results of the experiments performed on the purified KR protein. A. Absorbance spectrum. B. SDS-Page gel from the protein electrophoresis.<br><br>
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                                        <h4>Conversion between fluorescence units and protein concentration</h4>
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<p>The fluorescence of the purified protein solution was used to calibrate fluorescence measurements made on the Tristar microplate reader (200 µL volume). We obtained the following relationship: 48000 ± 5000 RFU (relative fluorescence units) correspond to a 1 µM KR concentration.<br><br>
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<h4>Number of KillerRed molecules per cell </h4>
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<p>It is also possible to calculate how many KR molecules are expressed per bacteria, as a function of the RFU/OD600 ratio. From LB-agar cell plating, we determined that 1 OD600 corresponds to 3.109 cells/mL. Since a bacterial suspension exhibiting a RFU of 1000 contains KR at a 0.021 ± 0.002 µM concentration, amounting to 1.3 1013 molecules/mL, a RFU/OD600 ratio of 1000 therefore signifies that each bacterium contains 4200 KillerRed molecules. ROS generated by a KR fluorophore affects proteins in a radius of 1–6 nm (Florian Baumgart, Andrea Rossi, and A.S. Verkman 2012. Light inactivation of water transport and protein–protein interactions of aquaporin–Killer Red chimeras, J Gen Physiol. 139: 83–91). One can thus estimate that the maximum volume damaged in the cell by the ROS generated by KillerRed is 4200 * (6 nm)3 = 900000 nm3. This volume is very small, amounting to about 0.15% of the total volume of the bacterium (0.6 µm3; Kubitschek HE 1990. Cell volume increase in Escherichia coli after shifts to richer media. J. Bacteriol. 172 : 94–101). In our experiments, we observed cell killing at a RFU/OD600 ratio of 4000-8000, indicating that about 1% of the cell volume was exposed to high ROS concentrations. <br><br>
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                                        <h4>Influence of Light Intensity</h4>
 

Revision as of 01:20, 5 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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