"
Team:Grenoble-EMSE-LSU/Project/Biology
From 2013.igem.org
(Difference between revisions)
| Line 50: | Line 50: | ||
<h3>Cell Growth Recovery after Stopping Illumination</h3> | <h3>Cell Growth Recovery after Stopping Illumination</h3> | ||
| - | <p align="center"><img src="https://static.igem.org/mediawiki/2013/5/5d/Grenoble_courbe_drawing.png" alt="cell recovery" width=" | + | <p align="center"><img src="https://static.igem.org/mediawiki/2013/5/5d/Grenoble_courbe_drawing.png" alt="cell recovery" width="600px"><br><br></p> |
<p>We showed that we could either increase or decrease the amount of living cells within our sample, by modulating the amount of light reaching the culture. KR-expressing cells were shown to be able to divide in the dark whereas they were killed upon appropriate illumination. But can the amount of living cells re increase after stopping illuminating the culture with light? In which shape are the cells that survive oxidative stress?<br><br> | <p>We showed that we could either increase or decrease the amount of living cells within our sample, by modulating the amount of light reaching the culture. KR-expressing cells were shown to be able to divide in the dark whereas they were killed upon appropriate illumination. But can the amount of living cells re increase after stopping illuminating the culture with light? In which shape are the cells that survive oxidative stress?<br><br> | ||
To answer the first question, we decided to perform another kinetic, in which a square light function (120 min, P = X W/cm2) was applied to the system. In this experiment, cells were inoculated at OD610 = 0.02 in 25 mL LB medium, supplemented with antibiotics and 0.05 mM IPTG. The first measurement was performed 30 min after induction.<br><br></p> | To answer the first question, we decided to perform another kinetic, in which a square light function (120 min, P = X W/cm2) was applied to the system. In this experiment, cells were inoculated at OD610 = 0.02 in 25 mL LB medium, supplemented with antibiotics and 0.05 mM IPTG. The first measurement was performed 30 min after induction.<br><br></p> | ||
<h4>Results</h4> | <h4>Results</h4> | ||
| - | <p align="center"><img src="https://static.igem.org/mediawiki/2013/2/26/Grenoble_recovery_graph.png" alt="results" | + | <p align="center"><img src="https://static.igem.org/mediawiki/2013/2/26/Grenoble_recovery_graph.png" alt="results" width="750px"></p> |
<p id="legend"><strong>Figure2.</strong><br>OD610 <strong>A</strong> and Fluorescence <strong>B</strong> responses to the system to a 120 min constant light illumination (P = X W/cm2). The illuminated sample is represented in red, the dark sample in blue. Error bars represent the standard errors of duplicates.<br><br></p> | <p id="legend"><strong>Figure2.</strong><br>OD610 <strong>A</strong> and Fluorescence <strong>B</strong> responses to the system to a 120 min constant light illumination (P = X W/cm2). The illuminated sample is represented in red, the dark sample in blue. Error bars represent the standard errors of duplicates.<br><br></p> | ||
<p>As mentioned before, photobleaching of KR is a good indicator of the cytotoxicity induced by this protein upon light stimulations. This phenomenon occurs right after the beginning of the illumination (t = 210 min), moment at which ROS start being produced and accumulating inside bacteria (figure 2.B). Fluorescence of the illuminated cell sample still increases during illumination, possibly because of KR still being produced by E. coli. This could be explained by progressive accumulation of the intracellular damages caused by oxidative stress during light illumination. 120 min of illumination seems enough for these damages to reach a threshold value, above which a significant decrease in the amount of living cells occurs, ultimately leading to stabilization of OD610 from 365 to 510 min (figure 2.A.). During this time, in absence of light stimulations, the cells that have survived oxidative stress divides. After 510 min of experiment, the number of living cells becomes high enough to trigger a significant increase in the amount of 610 nm light that is absorbed by the sample.<br><br> | <p>As mentioned before, photobleaching of KR is a good indicator of the cytotoxicity induced by this protein upon light stimulations. This phenomenon occurs right after the beginning of the illumination (t = 210 min), moment at which ROS start being produced and accumulating inside bacteria (figure 2.B). Fluorescence of the illuminated cell sample still increases during illumination, possibly because of KR still being produced by E. coli. This could be explained by progressive accumulation of the intracellular damages caused by oxidative stress during light illumination. 120 min of illumination seems enough for these damages to reach a threshold value, above which a significant decrease in the amount of living cells occurs, ultimately leading to stabilization of OD610 from 365 to 510 min (figure 2.A.). During this time, in absence of light stimulations, the cells that have survived oxidative stress divides. After 510 min of experiment, the number of living cells becomes high enough to trigger a significant increase in the amount of 610 nm light that is absorbed by the sample.<br><br> | ||
Revision as of 16:55, 28 September 2013
