Team:Tokyo Tech/Experiment/3OC12HSL-dependent C4HSL production

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<li class="current_page_item"><a href="#">Experiment</a>
<li class="current_page_item"><a href="#">Experiment</a>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/C4HSL-dependent_3oxoC12HSL_production" style="width:400px; margin-left:-135px;">C4HSL-dependent 3oxoC12HSL production</a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/Prhl_reporter_assay" style="width:400px; margin-left:-135px;">Prhl reporter assay </a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/3oxoC12HSL-dependent_C4HSL_production" style="width:400px; margin-left:-135px;">3oxoC12HSL-dependent C4HSL production</a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/C4HSL-dependent_3OC12HSL_production" style="width:400px; margin-left:-135px;">C4HSL-dependent 3OC12HSL production</a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/3OC12HSL-dependent_C4HSL_production" style="width:400px; margin-left:-135px;">3OC12HSL-dependent C4HSL production</a></li>
        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/Symbiosis_confirmation_by_co-culture" style="width:400px; margin-left:-135px;">Symbiosis confirmation by co-culture </a></li>
        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/Symbiosis_confirmation_by_co-culture" style="width:400px; margin-left:-135px;">Symbiosis confirmation by co-culture </a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/Prhl_reporter_assay" style="width:400px; margin-left:-135px;">Prhl reporter assay </a></li>
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        <li><a href="https://2014.igem.org/Team:Tokyo_Tech/Experiment/Transporter_assay" style="width:400px; margin-left:-135px;">Transporter assay</a></li>
 
 
  </ul>
  </ul>

Revision as of 09:52, 12 October 2014

Tokyo_Tech

Experiment

3OC12HSL-dependent C4HSL production

 

3OC12HSL-dependent C4HSL production module
 
 

1. Summary of the experiment

Construction of the 3OC12HSL-dependent C4HSL production and chloramphenicol resistance expression module

We created a symbiosis of Company E.coli and Customer E.coli for reproducing the situation in real economy. We used signaling molecules and antibiotics resistance gene ,and constructed signal-dependent signal production in our system.

For construction of the 3OC12HSL-dependent chloramphenicol resistance (CmR) and C4HSL production module, we constructed a new part Plux-CmR-rhlI (BBa_K1529265). Plux-CmR-RhlI cell is an engineered E.coli that contains a 3OC12HSL-dependent rhlI generator and a constitutive luxR generator. We constructed a new Biobrick part Plux-CmR-rhlI by combining Plux-CmR (BBa_K39562) and rhlI (BBa_). As a constitutive luxR generator, we used Pret-luxR (BBa_S0319). In our bank story, this part is customer.

1-1 3OC12HSL-dependent C4HSL production

First, we performed a reporter assay by using rhl reporter cell to characterize the function of 3OC12HSL-dependent C4HSL production. As the negative control of C4HSL production, we prepared C4HSL non-producer cell. C4HSL non-producer cell contains PlacIq-CmR instead of Plux-CmR-rhlI. The cell of negative control does not produce C4HSL even in the presence of 3C12HSL.

 

Sender

 
 

Repoter

 
 

We prepared four culture conditions as follow.

    A) Culture containing Plux-CmR-RhlI cell with 3OC12HSL induction
    B) Culture containing Plux-CmR-RhlI cell without 3OC12HSL induction
    C) Culture containing Plux-CmR cell with 3OC12HSL induction
    D) Culture containing Plux-CmR cell without 3OC12HSL induction

The supernatants of this four different culture were used as the inducer in the reporter assay.

 

In the reporter assay, we used a Rhl reporter strain that contains Ptet-rhlR and Plux-GFP. Also, a reporter cell that expresses GFP constitutively and a reporter cell that does not express GFP were used as the positive control and the negative control, respectively.

 

1-2 3OC12HSL-dependent growth

The cell which contains Plux-CmR-rhlI can grow in the medium even containing chloramphenicol .( Chloramphenicol is one of the antibiotics. )

After induction, we added chloramphenicol into the medium and measured optical density hourly after induction.

 

2. Results

 

2-1 3OC12HSL-dependent C4HSL production

We measured GFP expression in the reporter cell by flow cytometer

2-2 3OC12HSL-dependent growt

After induction, optical density were measured to estimate the concentration of the cell.

Fig. 3-2-1
 
Fig. 3-2-2
 

As Fig 3-2-1 shows, the cell containing Plux-CmR-RhlI can grow with induction of 3OC12SL, but can’t without induction. Plux-CmR-RhlI cell grows more slowly than the positive control. The amount of CmR is lower than the positive control, Compared Fig 3-2-1 to Fig 3-2-2, With Cm, the cell grow more slowly than without Cm.  geExpression of CmR in Plux-CmR-RhlI depende on induction by adding 2OC12HSL.         

 

3. Materials and methods

 

3-1 Construction

-Strain

All the samples were JM2.300 strain

-Plasmids

 

3-2 Protocol

3-2-1. 3OC12HSL-dependent C4HSL production assay by using reporter assay

Prepare the supernatant of the sender cell

1. Grow the colony of sender cell in LB containing antibiotic O/N at 37°C.
2. Make a 1:100 dilution in 3 mL of fresh LB containing antibiotic and grow the cells at 37°C
          until the observed OD590 reaches 0.5.
3. Centrifuge 1mL of the sample at 5000g, RT for 1 minute.
4. Suspend the pellet in 1 mL of LB containing Ampicillin(50μg/mL)and Kanamycin (30μg/mL)
5. Add 30µL of suspension in the following medium.
           Add 3µL of 5µM C12HSL to 3mL LB containing Amp and Kan
           Add 3µL DMSO to 3 µM of LB containing Amp and Kan
6. Grow the samples of sender cell at 37°C for 4 hours.
7. Measure optical density every hour (If optical density is over 1.0, dilute the cell medium.)
8. Centrifuge sample at 9000g, 4°C for 1minute.Filter sterilize supernatant.
9. Use the supernatant in reporter assay
 

Reporter Assay

1. Grow the colony of Reporter cell(D~F) in LB containing antibiotic O/N at 37°C.
2. Make a 1:100 dilution in 3 mL of fresh LB+ antibiotic and grow the cells at 37C until you reach an 0.5 OD590.(fresh culture)
3. Centrifuge sample at 5000g, 25°C RT for 1 minute. Discard the supernatant.
4. Suspended the sample in 3 mL of LB containing Ampicillin(50μg/mL) and Kanamycin(30μg/mL)
5. Add 30µL of suspension in the following medium.
           Filtrate of A①+3mL of LB containing Amp and Kan
           Filtrate of A②+3mL of LB containing Amp and Kan
           Filtrate of B①+3mL of LB containing Amp and Kan
           Filtrate of B②+3mL of LB containing Amp and Kan
           Filtrate of C①+3mL of LB containing Amp and Kan
          Filtrate of C②+3mL of LB containing Amp and Kan
          C4HSL+3mL of LB containing Amp and Kan
          DMSO + 3mL of LB containing Amp and Kan
6. Grow the samples of Reporter cell in incubator at 37°C for 4 hours.
7. Start preparing the flow cytometer 1 h before the end of incubation.
8. Take 200 microL of the sample, and centrifuge at 9000 Xg, 1 min, 4°C.
9. Remove the supernatant by using P1000 pipette.
10. Add 1 mL of filtered PBS (phosphate-buffered saline) and suspend.
11. Dispense all of each suspension into a disposable tube through a cell strainer.
12. Use flow cytometer to measure the fluorescence of GFP. (We used BD FACSCaliburTM Flow Cytometer of Becton, Dickenson and Company).
 

3-2-2. 3OC12HSL-depemdent CmR expression

1. Grow the colony of sender cell in LB containing antibiotic O/N at 37°C.
2. Make a 1:100 dilution in 3 mL of fresh LB containig antibiotic and grow the cells at 37°C until the observed OD590 reaches 0.5.(fresh culture)
3. Centrifuge 1mL of the sample at 5000g, RT for 1 minute.
4. Suspend the pellet in 1 mL of LB containing Ampicillin(50 microg/mL)and Kanamycin(30 microg/mL)
5. Add 30µL of suspension in the following medium.
           Add 3µL of 5µM C12HSL to 3mL LB containing Amp,Kan(concentration is described upper) and Cm(100 microg /mL)
           Add 3µ DMSO to 3mL of LB containing Amp and Kan
6. Grow the samples of sender cell at 37°C for 4 hours.
7. Measure optical density every hour.  (If optical density is over 1.0, dilute the cell medium.)
 

4. Reference