Difference between revisions of "Team:Tokyo Tech/Experiment/Replicating the Payoff Matrix"
(7 intermediate revisions by 2 users not shown) | |||
Line 46: | Line 46: | ||
<div class="textarea"> | <div class="textarea"> | ||
<h2 id="Introduction" class="smalltitle">1. Introduction</h2> | <h2 id="Introduction" class="smalltitle">1. Introduction</h2> | ||
− | <p class="text">We genetically engineered two prisoner <i>coli</i>, Prisoner A and Prisoner B. They are able to cooperate or to defect. The genetic circuits, with the improved chloramphenicol | + | <p class="text">We genetically engineered two prisoner <i>coli</i>, Prisoner A and Prisoner B. They are able to cooperate or to defect. The genetic circuits, with the improved chloramphenicol resistance protein(CmR) part, of Prisoner A and B are shown in Fig. 3-2-1-1. Our goal in this project is to replicate the payoff matrix (Fig. 3-2-1-2) with the four types of growth inhibition. Using the improved plasmids we constructed, our <i>E.coli</i> version payoff matrix is replicated through wet experiments. </p> |
<table width="940 px" border="0px"> | <table width="940 px" border="0px"> | ||
<tr> | <tr> | ||
Line 81: | Line 81: | ||
<h2 id="Summary" class="smalltitle">2. Summary of the Experiment</h2> | <h2 id="Summary" class="smalltitle">2. Summary of the Experiment</h2> | ||
<h3 id="Summary1" class="sub5">2.1. Replicating the Payoff Matrix of Prisoner A <i>coli</i></h3> | <h3 id="Summary1" class="sub5">2.1. Replicating the Payoff Matrix of Prisoner A <i>coli</i></h3> | ||
− | <p class="text2">The cell growth of the | + | <p class="text2">The cell growth of the prisoner <i>colis</i> containing the pairs of plasmids (1) and (2), as shown in the following (Fig. 3-2-2-1.), in the lower chloramphenicol (Cm) concentration (75 microg/mL) were measured and the payoff matrix was replicated.</p> |
<table width="940 px" border="0px"> | <table width="940 px" border="0px"> | ||
<tr> | <tr> | ||
Line 94: | Line 94: | ||
</table><br> | </table><br> | ||
<h3 id="Summary2" class="sub5">2.2. Replicating the Payoff Matrix of Prisoner B <i>coli</i></h3> | <h3 id="Summary2" class="sub5">2.2. Replicating the Payoff Matrix of Prisoner B <i>coli</i></h3> | ||
− | <p class="text2">We have prepared | + | <p class="text2">We have prepared new pairs of plasmids, (3) and (4), as shown in the following (Fig. 3-2-2-2.). The cell growth of the prisoner <i>colis</i> containing the pairs of plasmids (3) and (4), under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were measured and the payoff matrix was replicated.</p> |
<table width="940 px" border="0px"> | <table width="940 px" border="0px"> | ||
<tr> | <tr> | ||
Line 106: | Line 106: | ||
</tr> | </tr> | ||
</table><br> | </table><br> | ||
− | <p class="text2">Using the pair of plasmids we constructed, our <i>E.coli</i> version payoff matrix with the four types of growth inhibition was replicated through wet experiments. The cell growth of the | + | <p class="text2">Using the pair of plasmids we constructed, our <i>E.coli</i> version payoff matrix with the four types of growth inhibition was replicated through wet experiments. The cell growth of the prisoner <i>colis</i> containing the pairs of plasmids (3) and (4), grown under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were observed. |
Line 116: | Line 116: | ||
<h2 id="Results" class="smalltitle">3. Results</h2> | <h2 id="Results" class="smalltitle">3. Results</h2> | ||
<h3 id="Result1" class="sub5">3.1. Replicating the Payoff Matrix of Prisoner A <i>coli</i></h3> | <h3 id="Result1" class="sub5">3.1. Replicating the Payoff Matrix of Prisoner A <i>coli</i></h3> | ||
− | <p class="text2">The cell growth of the | + | <p class="text2">The cell growth of the prisoner <i>colis</i> containing the pairs of plasmids (1) and (2) in the lower chloramphenicol (Cm) concentration (75 microg/mL) were measured after an eight hour incubation. The payoff matrix was replicated as the following.</p> |
<table width="940 px" border="0px"> | <table width="940 px" border="0px"> | ||
<tr> | <tr> | ||
Line 139: | Line 139: | ||
<h3 id="Result2" class="sub5">3.2. Replicating the Payoff Matrix of Prisoner B <i>coli</i></h3> | <h3 id="Result2" class="sub5">3.2. Replicating the Payoff Matrix of Prisoner B <i>coli</i></h3> | ||
− | <p class="text2">The cell growth of the | + | <p class="text2">The cell growth of the prisoner <i>colis</i> containing the pairs of plasmids (3) and (4),under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were measured. The payoff matrix was replicated as the following.</p> |
<table width="940 px" border="0px"> | <table width="940 px" border="0px"> | ||
<tr> | <tr> |
Latest revision as of 03:10, 19 September 2015
Replicating the Payoff Matrix
contents
1. Introduction
2. Summary of the Experiment
2.1. Replicating the Payoff Matrix of Prisoner A coli
2.2. Replicating the Payoff Matrix of Prisoner B coli
3. Results
3.1. Replicating the Payoff Matrix of Prisoner A coli
3.2. Replicating the Payoff Matrix of Prisoner B coli
4. Materials and Methods
4.1. Construction
4.2. Assay Protocol
4.2.1. C4HSL-dependent CmR expression assay ([Cm] = 75 microg/mL)
4.2.2. 3OC12HSL concentration-dependent CmR expression assay
5. Reference
1. Introduction
We genetically engineered two prisoner coli, Prisoner A and Prisoner B. They are able to cooperate or to defect. The genetic circuits, with the improved chloramphenicol resistance protein(CmR) part, of Prisoner A and B are shown in Fig. 3-2-1-1. Our goal in this project is to replicate the payoff matrix (Fig. 3-2-1-2) with the four types of growth inhibition. Using the improved plasmids we constructed, our E.coli version payoff matrix is replicated through wet experiments.
Fig. 3-2-1-1. The genetic circuits of prisoner colis with the options of cooperation or defection |
Fig. 3-2-1-2. Payoff Matrix of Prisoner A and B |
2. Summary of the Experiment
2.1. Replicating the Payoff Matrix of Prisoner A coli
The cell growth of the prisoner colis containing the pairs of plasmids (1) and (2), as shown in the following (Fig. 3-2-2-1.), in the lower chloramphenicol (Cm) concentration (75 microg/mL) were measured and the payoff matrix was replicated.
Fig. 3-2-2-1. Cells for the experiment to replicate the payoff matrix of Prisoner A coli |
2.2. Replicating the Payoff Matrix of Prisoner B coli
We have prepared new pairs of plasmids, (3) and (4), as shown in the following (Fig. 3-2-2-2.). The cell growth of the prisoner colis containing the pairs of plasmids (3) and (4), under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were measured and the payoff matrix was replicated.
Fig. 3-2-2-2. Cells for the experiment to replicate the payoff matrix of Prisoner B coli |
Using the pair of plasmids we constructed, our E.coli version payoff matrix with the four types of growth inhibition was replicated through wet experiments. The cell growth of the prisoner colis containing the pairs of plasmids (3) and (4), grown under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were observed.
3. Results
3.1. Replicating the Payoff Matrix of Prisoner A coli
The cell growth of the prisoner colis containing the pairs of plasmids (1) and (2) in the lower chloramphenicol (Cm) concentration (75 microg/mL) were measured after an eight hour incubation. The payoff matrix was replicated as the following.
Fig. 3-2-3-1. Payoff matrix of Prisoner A coli with 75 microg/mL Cm |
3.2. Replicating the Payoff Matrix of Prisoner B coli
The cell growth of the prisoner colis containing the pairs of plasmids (3) and (4),under 75 microg/mL chloramphenicol and also under 1nM 3OC12HSL, were measured. The payoff matrix was replicated as the following.
Fig. 3-2-3-2. Payoff matrix of Prisoner B coli with gfp in 75 microg/mL Cm and 1 nM 3OC12HSL |
4. Materials and Methods
4.1. Construction
-Strain
All the samples were JM2.300 strain.
-Plasmids
(1) Pcon_rhlR_TT_Plux_CmRssrA (pSB6A1) + Plac_lasI (pSB3K3)
Fig. 3-2-4-1. |
(2) Pcon_rhlR_TT_Plux_CmRssrA (pSB6A1) + promoter less_lasI (pSB3K3)
Fig. 3-2-4-2. |
(3) Pcon_lasR_TT_Plux_CmRssrA (pSB6A1) + Pcon_gfp_rhlI (pSB3K3)
Fig. 3-2-4-3. |
(4) Pcon_lasR_TT_Plux_CmRssrA (pSB6A1) + promoter less_rhlI (pSB3K3)
Fig. 3-2-4-4. |
4.2. Assay Protocol
4.2.1. C4HSL-dependent CmR expression assay ([Cm] = 75 microg/mL)
-samples
(1) Pcon_rhlR_TT_Plux_CmRssrA (pSB6A1) + Plac_lasI (pSB3K3)
(2) Pcon_rhlR_TT_Plux_CmRssrA (pSB6A1) + promoter less_lasI (pSB3K3)
-Procedure
1. Prepare overnight cultures (n=2) for the samples in 3 mL LB medium, containing ampicillin (50 microg/mL) and kanamycin (30 microg/mL) at 37°C for 12 hours.
2. Make a 1:100 dilution in 3 mL of fresh LB (containing Amp and Kan) and grow the cells at 37°C until the observed OD590 reaches 0.5.
3. Centrifuge 1 mL of the sample at 5000g, RT for 1 minute.
4. Suspend the pellet in 1mL of LB (containing Amp and Kan).
5. Add 30 microL of suspension in the following medium.
a)LB (containing Amp and Kan) (3 mL) + 50 microM C4HSL (30 microL) + Chloramphenicol (75 microg/mL)
b)LB (containing Amp and Kan) (3 mL) + DMSO (30 microL) + Chloramphenicol (75 microg/mL)
6.Incubate the samples of cells at 37°C for more than 8 hours.
7.Measure OD590 every hour.
4.2.2. 3OC12HSL concentration-dependent CmR expression assay
-samples
(3) Pcon_lasR_TT_Plux_CmRssrA (pSB6A1) + Pcon_gfp_rhlI (pSB3K3)
(4) Pcon_lasR_TT_Plux_CmRssrA (pSB6A1) + promoter less_rhlI (pSB3K3)
-Procedure
1. Prepare overnight cultures (n=2) for the samples in 3 mL LB medium, containing ampicillin (50 microg/mL) and kanamycin (30 microg/mL) at 37°C for 12 hours.
2. Make a 1:100 dilution in 3 mL of fresh LB containing Amp and Kan and grow the cells at 37°C until the observed OD590 reaches 0.5.
3. Centrifuge 1 mL of the sample at 5000g, RT for 1 minute.
4. Suspend the pellet in 1mL of LB containing Amp and Kan.
5.Add 30 microL of suspension in the following medium.
a) LB (containing Amp and Kan) (3 mL) + 5 microM 3OC12HSL (0.6 microL) + Chloramphenicol (75 microg/mL)
b) LB (containing Amp and Kan) (3 mL) + DMSO (0.6 microL) + Chloramphenicol (75 microg/mL)
6. Incubate the samples of cells at 37°C for more than 8 hours.
Measure OD590 every hour.
5. Reference
1. Bo Hu et al. (2010) An Environment-Sensitive Synthetic Microbial Ecosystem. PLoS ONE 5(5): e10619