Team:Peking/Project/Communication/Results
From 2012.igem.org
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<div class="PKU_context floatR first"> | <div class="PKU_context floatR first"> | ||
- | + | <p>In this page, we will show you different kinds of results and characterization indicating that we have successfully constructed a light communication system and it works very well. | |
- | <p> | + | </p> |
- | + | </div> | |
- | <div class= | + | <div class="PKU_context floatR"> |
- | <img src= | + | <h3 class="title1">Direct results of the response to<br/>bio-luminescence</h3> |
- | <p class="description"> | + | <p>As shown in the photo (Figure 1), GFP expression is able to be repressed by LexA408-VVD under both bio-luminescence (tube 1) and blue LED (tube 3), indicating that the light-sensing cell can sense bio-luminescence quite well. The cells in our device with no light emitting cells (tube 2), or just inoculated test tubes wrapped with aluminum foil (tube 4) have expressed GFP, indicating that our device wrapped with aluminum foil effectively excludes the influence of other sources of light.</p> |
- | Figure 1. The light sensing cells were grown in different conditions. Tube 1 and 2 contain cells grown in the communication device, but for tube 2 there is no light emitting cell in the conical flask but only normal DH5α. Tube 3 and 4 contain the same light sensing cells grown in test tubes under blue LED (tube 3) or in pure darkness (tube 4). </p> | + | <div class=”floatC”> |
+ | <img src=”” alt=”Figure 1” /> | ||
+ | <p class="description">Figure 1. The light sensing cells were grown in different conditions. Tube 1 and 2 contain cells grown in the communication device, but for tube 2 there is no light emitting cell in the conical flask but only normal DH5α. Tube 3 and 4 contain the same light sensing cells grown in test tubes under blue LED (tube 3) or in pure darkness (tube 4).</p> | ||
</div> | </div> | ||
- | <p>To give more quantitative data, we measured the GFP expression level using a | + | <p>To give more quantitative data, we measured the GFP expression level using a Tecan infinite 200 reader. As is shown in the graph(Figure 2), the expression levels of GFP in darkness (in our device with no glowing cells) is about 200-fold higher than that of the cells under bio-luminescence.</p> |
- | <div class= | + | |
- | <img src= | + | <div class=”floatC”> |
- | <p class="description"> | + | <img src=”” alt=”Figure 2” /> |
- | Figure | + | <p class="description">Figure 2.</p> |
</div> | </div> | ||
- | <p>Since we had confirmed that our sensing cell could respond to bio-luminescence quite well, we were interested in more detailed information regarding our light communication system.<br /><br /> | + | </div> |
- | In the spectrum | + | <div class="PKU_context floatR"> |
- | <div class= | + | <h3 class=”title2”>Detailed characterization</h3> |
- | <img src= | + | <p>Since we had confirmed that our sensing cell could respond to bio-luminescence quite well, we were interested in more detailed information regarding our light communication system.<br/><br/><b>spectrum</b><br/>Firstly, although the spectrum of the luminescence produced by lux genes was given in scientific literature, there may be some slight variation when the genes are expressed in E.coli grown in LB medium. The Cambridge 2010 iGEM team did not provide the spectrum for their luxbrick biopart, therefore, in order for us to confirm that the luminescence from our light emitting cell is able to meet the required of wavelength described in the “design” section. Also, as a supplementary characterization for Cambridge 2010 iGEM team’s luxbrick part, we measured the spectrum of the luminescence emitted by our glowing cell.<br/><br/>In the spectrum diagram(Figure 3), we can see an emission peak at about 485nm, which matches the maximum absorption wavelength of our Luminesensor.</p> |
- | <p class="description"> | + | <div class=”floatC”> |
- | Figure 3. BMTOP10 cells harboring the luxbrick were cultured in LB medium and induced with L-arabinose at 10-3M. 10 hours after induction, the glowing cells were measured for spectrum using SHIMADZU RF5301PC Spectrofluorophotometer. </p> | + | <img src=”” alt=”Figure 3” /> |
+ | <p class="description">Figure 3. BMTOP10 cells harboring the luxbrick were cultured in LB medium and induced with L-arabinose at 10-3M. 10 hours after induction, the glowing cells were measured for spectrum using SHIMADZU RF5301PC Spectrofluorophotometer.</p> | ||
</div> | </div> | ||
- | <p>Then we wanted to figure out when our light emitting cell induced with L-arabinose would begin to glow. Although the 2010 Cambridge iGEM team has provided a graph showing the evolution of luminescence intensity with time during the light emitting process, we wanted to create a more visualized characterization of the luxbrick. Therefore, we make a short movie in order to show the time course of our light emitting cell transformed with luxbrick.<br /><br /> | + | <p><b>Time Course</b><br/><p>Then we wanted to figure out when our light emitting cell induced with L-arabinose would begin to glow. Although the 2010 Cambridge iGEM team has provided a graph showing the evolution of luminescence intensity with time during the light emitting process, we wanted to create a more visualized characterization of the luxbrick. Therefore, we make a short movie in order to show the time course of our light emitting cell transformed with luxbrick.<br/><br/>As we can see in the movie, the cells begin to glow 9 hours after induction, and the entire visible glowing process lasts about 10 hours. So in the light communication experiment, we decided to put light sensing cell in the light emitting cell 9 hours after induction in order to maintain illumination on the light sensing cell, especially in their logarithmic phase.</p> |
- | As we can see in the movie, the cells begin to glow 9 hours after induction, and the entire visible glowing process lasts about 10 hours. So in the light communication experiment, we decided to put light sensing cell in the light emitting cell 9 hours after induction in order to maintain illumination on the light sensing cell, especially in their logarithmic phase.</p> | + | <div class=”floatC”> |
- | <div class= | + | <object ></object> |
- | + | <p class=”description”>a short movie</p> | |
- | + | <div> | |
- | <p>Then we go on to the time course of light sensing cells’ behavior. | + | <p>Then we go on to the time course of light sensing cells’ behavior.<br/><br/>In the short video below, the reaction of our light sensing cell is shown at the top right corner of each group. The experiment group (left) with a luminescence pulse lasting 10 hours from light emitting cell, as expected, didn’t express GFP, while the control group (right) in the same device with nonluminous cell, began to express GFP 10hours after inoculation.</p> |
- | </p> | + | <div class=”floatC”> |
+ | <object ></object> | ||
+ | <p class=”description”>Newly inoculated light sensing cells culture was immersed into the light emitting cells when the latter began to glow. And every 15 minutes, 0.5ml light sensing cells culture were taken out from our device and harvested in the bottom of an EP tube. Then GFP expression was observed under blue light excitation, and was shown in the video.</p> | ||
+ | </div> | ||
+ | </div> | ||
+ | <div class=”PKU_context floatR”><p> | ||
+ | So far we have confirmed and characterized our light communication system through many different ways and all the results shows that we realized cell-cell communication through light. And we are really looking forward to its wide application in the future.</p> | ||
</div> | </div> | ||
- | </html> | + | |
+ | </html>{{Template:Peking2012_Color_Epilogue}} |
Revision as of 14:28, 20 September 2012
In this page, we will show you different kinds of results and characterization indicating that we have successfully constructed a light communication system and it works very well.
Direct results of the response to
bio-luminescence
As shown in the photo (Figure 1), GFP expression is able to be repressed by LexA408-VVD under both bio-luminescence (tube 1) and blue LED (tube 3), indicating that the light-sensing cell can sense bio-luminescence quite well. The cells in our device with no light emitting cells (tube 2), or just inoculated test tubes wrapped with aluminum foil (tube 4) have expressed GFP, indicating that our device wrapped with aluminum foil effectively excludes the influence of other sources of light.
Figure 1. The light sensing cells were grown in different conditions. Tube 1 and 2 contain cells grown in the communication device, but for tube 2 there is no light emitting cell in the conical flask but only normal DH5α. Tube 3 and 4 contain the same light sensing cells grown in test tubes under blue LED (tube 3) or in pure darkness (tube 4).
To give more quantitative data, we measured the GFP expression level using a Tecan infinite 200 reader. As is shown in the graph(Figure 2), the expression levels of GFP in darkness (in our device with no glowing cells) is about 200-fold higher than that of the cells under bio-luminescence.
Figure 2.
Detailed characterization
Since we had confirmed that our sensing cell could respond to bio-luminescence quite well, we were interested in more detailed information regarding our light communication system.
spectrum
Firstly, although the spectrum of the luminescence produced by lux genes was given in scientific literature, there may be some slight variation when the genes are expressed in E.coli grown in LB medium. The Cambridge 2010 iGEM team did not provide the spectrum for their luxbrick biopart, therefore, in order for us to confirm that the luminescence from our light emitting cell is able to meet the required of wavelength described in the “design” section. Also, as a supplementary characterization for Cambridge 2010 iGEM team’s luxbrick part, we measured the spectrum of the luminescence emitted by our glowing cell.
In the spectrum diagram(Figure 3), we can see an emission peak at about 485nm, which matches the maximum absorption wavelength of our Luminesensor.
Figure 3. BMTOP10 cells harboring the luxbrick were cultured in LB medium and induced with L-arabinose at 10-3M. 10 hours after induction, the glowing cells were measured for spectrum using SHIMADZU RF5301PC Spectrofluorophotometer.
Time Course
Then we wanted to figure out when our light emitting cell induced with L-arabinose would begin to glow. Although the 2010 Cambridge iGEM team has provided a graph showing the evolution of luminescence intensity with time during the light emitting process, we wanted to create a more visualized characterization of the luxbrick. Therefore, we make a short movie in order to show the time course of our light emitting cell transformed with luxbrick.
As we can see in the movie, the cells begin to glow 9 hours after induction, and the entire visible glowing process lasts about 10 hours. So in the light communication experiment, we decided to put light sensing cell in the light emitting cell 9 hours after induction in order to maintain illumination on the light sensing cell, especially in their logarithmic phase.
a short movie
Then we go on to the time course of light sensing cells’ behavior.
In the short video below, the reaction of our light sensing cell is shown at the top right corner of each group. The experiment group (left) with a luminescence pulse lasting 10 hours from light emitting cell, as expected, didn’t express GFP, while the control group (right) in the same device with nonluminous cell, began to express GFP 10hours after inoculation.
Newly inoculated light sensing cells culture was immersed into the light emitting cells when the latter began to glow. And every 15 minutes, 0.5ml light sensing cells culture were taken out from our device and harvested in the bottom of an EP tube. Then GFP expression was observed under blue light excitation, and was shown in the video.
So far we have confirmed and characterized our light communication system through many different ways and all the results shows that we realized cell-cell communication through light. And we are really looking forward to its wide application in the future.