Difference between revisions of "Team:ETH Zurich/Experiments"

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<div class="expContainer">
 
 
 
<h2>Mammalian cell experiments</h2>
 
 
<div class="highlightBox">
 
<h3>Overview</h3>
 
<p>The detection of CTC with our engineered MicroBeacon bacteria relies on the detection of two cancer markers, <b>susceptibility to sTRAIL</b> and <b>elevated lactate production</b> by cancer cells. To reproduce literature data on these two points We performed a lot of experiments with several mammalian cell lines, optimizing our protocols until we reached the most reliable results. We perormed all our experiments with Jurkat cells and 3T3 cells, representing a cancerogenic and non-cancerogenic cell line, respectively. We performed our experiments also for HL60 cells, another cancerogenic cell line, and also made some experience with HeLa cells. For more clarity, in our <a href="https://2015.igem.org/Team:ETH_Zurich/Results">Results page</a> we will however focus only on Jurkat and 3T3 since the other lines did not lead to significantly different results.</p>
 
<p>Below you can find the protocols we applied for measurements of lactate output of mammalian cells and their sTRAIL susceptibility.</p>
 
 
 
</div>
 
 
 
 
<h3>Apoptosis susceptibility experiment with sTRAIL</h3>
 
<p>sTRAIL is a sinaling molecule activating the TNF pathway in cancer cells, specifically inducing apoptosis in these cells, as opposed to the case of healthy cells which are not susceptible to sTRAIL. With the following experiment we are determining the <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Methods_and_results">optimal incubation time and sTRAIL concentration</a> for induction of apoptosis in our cancer cell lines of interest.</p>
 
 
<div class="info" style="max-height:30px">
 
 
<ol>
 
          <li>Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired controls, concentrations, incubation periods, and replicates. </li>
 
<li>Distribute the cells into the wells of a 96-well plate, 200 &micro;L per well.</li>
 
<li>Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.</li>
 
<li>Apply 5 &micro;L of the desired dillutions of sTRAIL to the appropriate wells and incubate for 2 to 6 hours at 30&ordm;C.</li>
 
<li>After incubation, separate cells from their medium (spin down suspension cells, remove medium from wells with adhesive cell.</li>
 
<li>Wash 3 times with DPBS.</li>
 
 
<p>For detection of apoptosis, Annexin V-Alexa488 can be used. It will bind to externalizes phosphatidylserine on apoptotic cells.</p>
 
</li>
 
          <li>Resuspend cells in <a href="https://2015.igem.org/Team:ETH_Zurich/Materials#Annexin_V_binding_buffer">Annexin binding buffer</a>  and add 5 &micro;L per sample. Incubate at RT for 15 min.</li>
 
          <li>Dillute Annexin V-Alexa488 by addition of 50 &micro;L of Annexin binding buffer. Alternatively, engineered <i>E. coli</i> bacteria expressing our INP-Annexin V construct along with RFP <a href="http://parts.igem.org/Part:BBa_K1847015">(BBa_K1847015)</a> can be used for detection.</li>
 
          <li>Analyse cells by FACS.</li>
 
          <li>PI staining can be used to distinguish apoptotic from necrotic cells. Apply 5 &micro;L of PI to the respective samples 5 min prior to FACS analysis.</li>
 
</ol>
 
<p>Application of the appropriate positive controls (eg. PMA for Jurkat cells) and control staining (PI for necrotic cells) will lead to more detailed and reliable results.</p>
 
 
<h4>Alternative induction of apoptosis using PMA</h4>
 
<p>Susceptible cell lines can be incubated with PMA in appropriate incubation period and concentrations as a positive control to sTRAIL induced apoptosis. The following protocol is designed for Jurkat cells.</p>
 
<ol>
 
          <li>Incubate cells with blabla PMA and Ionomycin for 24 hours.<li>
 
          <li>Wash cells 3 times with DPBS and resuspend in Annexin V binding buffer for detection with Annexin V-Alexa488.</li>
 
</ol>
 
 
<a class="expander" href="#" onclick="expand(this);return false;"><img src="https://static.igem.org/mediawiki/2015/1/1f/Blank_square.png"></a>
 
</div>
 
 
<h3>Measurement of the Lactate output of mammalian cell lines.</h3>
 
<p>Our project relies on the phenomenon of elevated lactate output of cancer cells upon metabolic reprogramming referred to as the <a href="https://2015.igem.org/Team:ETH_Zurich/Description#Warburg_effect">Warburg effect</a>. To validate this effect in our <a href="https://2015.igem.org/Team:ETH_Zurich/Materials#Bacterial_strains_and_Mammalian_Cell_Lines">cell lines of interest</a> we determined the lactate level of the cell’s culture medium after cell culture within the timeframe in which our system will be applied. Based on this, the lactate production by single cells can be <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Lactate_production">estimated</a>.</p>
 
<p>The experiment can be carried out in any volume of interest. We performed our measurement in 24-well plates.</p>
 
<p>Click <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Lactate_production">here</a> to see the results of this experiment.</p>
 
<div class="info" style="max-height:30px">
 
 
<ol>
 
          <li>Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired time points and replicates. Counting must be very accurate if the determination of the lactate output per cell is the aim of the experiment. Consider using a cell counter.</li>
 
<li>Distribute the cells into the wells of a 24-well plate, 500 &micro;L  per well.</li>
 
<li>Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.</li>
 
<li>At the beginning of the measurement, the medium has to be exchanged to start at the minimal level. To this end, spin down the cells at 250 rcf for 3 min and resuspend the pellet in 500 &micro;L  of fresh, prewarmed medium. The sample for time zero has to be taken right after the exchange of the medium.</li>
 
<li>Samples are collected in regular time intervals by transferring the medium into an Eppendorf tube. Centrifuge samples at 250 rcf for 3 min and transfer the cell free medium into a new Eppendorf tube.</li>
 
<li>Samples can be stored at 4 to 8 &ordm;C for analysis at a later time point.</li>
 
<li>The lactate concentration of the collected samples can be determined using the <a href="Lactate_Detection_Kit">L-Lactate Kit</a> according to its instructions. In order to get good results with this kit, it is essential to use medium free of serum and phenol red.</li>
 
</ol>
 
 
<a class="expander" href="#" onclick="expand(this);return false;"><img src="https://static.igem.org/mediawiki/2015/1/1f/Blank_square.png"></a>
 
</div>
 
 
</div>
 
  
  
Line 333: Line 266:
  
 
</div>
 
</div>
 +
 +
<div class="expContainer">
 +
 +
 +
<h2>Mammalian cell experiments</h2>
 +
 +
<div class="highlightBox">
 +
<h3>Overview</h3>
 +
<p>The detection of CTC with our engineered MicroBeacon bacteria relies on the detection of two cancer markers, <b>susceptibility to sTRAIL</b> and <b>elevated lactate production</b> by cancer cells. To reproduce literature data on these two points We performed a lot of experiments with several mammalian cell lines, optimizing our protocols until we reached the most reliable results. We perormed all our experiments with Jurkat cells and 3T3 cells, representing a cancerogenic and non-cancerogenic cell line, respectively. We performed our experiments also for HL60 cells, another cancerogenic cell line, and also made some experience with HeLa cells. For more clarity, in our <a href="https://2015.igem.org/Team:ETH_Zurich/Results">Results page</a> we will however focus only on Jurkat and 3T3 since the other lines did not lead to significantly different results.</p>
 +
<p>Below you can find the protocols we applied for measurements of lactate output of mammalian cells and their sTRAIL susceptibility.</p>
 +
 +
 +
</div>
 +
 +
 +
 +
<h3>Apoptosis susceptibility experiment with sTRAIL</h3>
 +
<p>sTRAIL is a sinaling molecule activating the TNF pathway in cancer cells, specifically inducing apoptosis in these cells, as opposed to the case of healthy cells which are not susceptible to sTRAIL. With the following experiment we are determining the <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Methods_and_results">optimal incubation time and sTRAIL concentration</a> for induction of apoptosis in our cancer cell lines of interest.</p>
 +
 +
<div class="info" style="max-height:30px">
 +
 +
<ol>
 +
          <li>Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired controls, concentrations, incubation periods, and replicates. </li>
 +
<li>Distribute the cells into the wells of a 96-well plate, 200 &micro;L per well.</li>
 +
<li>Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.</li>
 +
<li>Apply 5 &micro;L of the desired dillutions of sTRAIL to the appropriate wells and incubate for 2 to 6 hours at 30&ordm;C.</li>
 +
<li>After incubation, separate cells from their medium (spin down suspension cells, remove medium from wells with adhesive cell.</li>
 +
<li>Wash 3 times with DPBS.</li>
 +
 +
<p>For detection of apoptosis, Annexin V-Alexa488 can be used. It will bind to externalizes phosphatidylserine on apoptotic cells.</p>
 +
</li>
 +
          <li>Resuspend cells in <a href="https://2015.igem.org/Team:ETH_Zurich/Materials#Annexin_V_binding_buffer">Annexin binding buffer</a>  and add 5 &micro;L per sample. Incubate at RT for 15 min.</li>
 +
          <li>Dillute Annexin V-Alexa488 by addition of 50 &micro;L of Annexin binding buffer. Alternatively, engineered <i>E. coli</i> bacteria expressing our INP-Annexin V construct along with RFP <a href="http://parts.igem.org/Part:BBa_K1847015">(BBa_K1847015)</a> can be used for detection.</li>
 +
          <li>Analyse cells by FACS.</li>
 +
          <li>PI staining can be used to distinguish apoptotic from necrotic cells. Apply 5 &micro;L of PI to the respective samples 5 min prior to FACS analysis.</li>
 +
</ol>
 +
<p>Application of the appropriate positive controls (eg. PMA for Jurkat cells) and control staining (PI for necrotic cells) will lead to more detailed and reliable results.</p>
 +
 +
<h4>Alternative induction of apoptosis using PMA</h4>
 +
<p>Susceptible cell lines can be incubated with PMA in appropriate incubation period and concentrations as a positive control to sTRAIL induced apoptosis. The following protocol is designed for Jurkat cells.</p>
 +
<ol>
 +
          <li>Incubate cells with blabla PMA and Ionomycin for 24 hours.<li>
 +
          <li>Wash cells 3 times with DPBS and resuspend in Annexin V binding buffer for detection with Annexin V-Alexa488.</li>
 +
</ol>
 +
 +
<a class="expander" href="#" onclick="expand(this);return false;"><img src="https://static.igem.org/mediawiki/2015/1/1f/Blank_square.png"></a>
 +
</div>
 +
 +
<h3>Measurement of the Lactate output of mammalian cell lines.</h3>
 +
<p>Our project relies on the phenomenon of elevated lactate output of cancer cells upon metabolic reprogramming referred to as the <a href="https://2015.igem.org/Team:ETH_Zurich/Description#Warburg_effect">Warburg effect</a>. To validate this effect in our <a href="https://2015.igem.org/Team:ETH_Zurich/Materials#Bacterial_strains_and_Mammalian_Cell_Lines">cell lines of interest</a> we determined the lactate level of the cell’s culture medium after cell culture within the timeframe in which our system will be applied. Based on this, the lactate production by single cells can be <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Lactate_production">estimated</a>.</p>
 +
<p>The experiment can be carried out in any volume of interest. We performed our measurement in 24-well plates.</p>
 +
<p>Click <a href="https://2015.igem.org/Team:ETH_Zurich/Results#Lactate_production">here</a> to see the results of this experiment.</p>
 +
<div class="info" style="max-height:30px">
 +
 +
<ol>
 +
          <li>Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired time points and replicates. Counting must be very accurate if the determination of the lactate output per cell is the aim of the experiment. Consider using a cell counter.</li>
 +
<li>Distribute the cells into the wells of a 24-well plate, 500 &micro;L  per well.</li>
 +
<li>Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.</li>
 +
<li>At the beginning of the measurement, the medium has to be exchanged to start at the minimal level. To this end, spin down the cells at 250 rcf for 3 min and resuspend the pellet in 500 &micro;L  of fresh, prewarmed medium. The sample for time zero has to be taken right after the exchange of the medium.</li>
 +
<li>Samples are collected in regular time intervals by transferring the medium into an Eppendorf tube. Centrifuge samples at 250 rcf for 3 min and transfer the cell free medium into a new Eppendorf tube.</li>
 +
<li>Samples can be stored at 4 to 8 &ordm;C for analysis at a later time point.</li>
 +
<li>The lactate concentration of the collected samples can be determined using the <a href="Lactate_Detection_Kit">L-Lactate Kit</a> according to its instructions. In order to get good results with this kit, it is essential to use medium free of serum and phenol red.</li>
 +
</ol>
 +
 +
<a class="expander" href="#" onclick="expand(this);return false;"><img src="https://static.igem.org/mediawiki/2015/1/1f/Blank_square.png"></a>
 +
</div>
 +
 +
</div>
 +
 +
  
 
<div class="expContainer">
 
<div class="expContainer">

Revision as of 21:45, 17 September 2015

"What I cannot create I do not understand."
- Richard Feynmann

Experiments & Protocols

In the course of our project we performed a lot of different experiments, ranging from construction and transformations of plasmids into E. coli over the testing of their functionality and response measurements after induction of our circuit, up to experiments with mammalian cells, which are the subjects of our analysis.

Below you can find the protocols for all our experiments, grouped into experiments with bacteria, mammalian cells, the combination of both, and some general useful things.

E. coli experiments

Overview

The first important feature of our engineered E. coli is their binding to apoptotic cells via our INP-Annexin V construct which makes them display Annexin V on their outer membrane. We performed experiments to show expression, externalization, and functionality of this construct.

In our system, the actual detection of E. Coli binding to apoptotic cancer cells happens via quorum sensing upon colocalisation of bound bacteria. We therefore designed experiments to test the quorum sensing properties of our final and working constructs.

The second signal which will be integrated by our bacteria is the elevated lactate production by cancer cells when compared to helathy cells. The main part of the lactate sensor we implemented in our system consists of synthetically designed promoters that react to lactate, as well as LacI. We characterized the sensitivity of these promoters to lactate and IPTG to find the best solution to fit our model with a good ON/OFF-ratio. Going one step further, we also probed our E. coli cells for their reaction to the actual lactate output of mammalian cells, the protocol of which you can find in the section of experiments combining mammalian cells with bacteria.

Antibody staining for Annexin V

To find out whether or not our INP-Annexin V construct leads to proper exposition of Annexin V on the outer membrane of our E. coli we performed an antibody assay where we stained the strains listed below with a primary antibody against Annexin V and YFP, respectively. Using flow cytometry and confocal microscopy we would then detect binding of this antibody by staining with a secondary antibody (antimouse) which is coupled to Alexa488.

strain expected staining?
INP-Annexin yes
INP-Annexin + rfp yes
INP-Annexin (high copy) yes
Annexin no
INP-YFP yes
no construct no

Table: Six strains were tested. We expect staining only for the strains expressing an INP-AnnexinV or INP-YFP construct, respectively, since without INP, Annexin should not be visible on the surface of our bacteria. Negative controls therefore include cells without any construct as well as cells expressing Annexin V but lacking INP. As a positive control we used an adapted BioBrick (BBa_K523013) as well as our construct expressed on a high copy plasmid. One construct includes red fluorescent protein which will make it possible to probe our cells for colocalization of RFP and Alexa488, as well as colocalization of RFP-expressing E. coli with CTCs.

  1. Dillute overnight cultures (biological triplicates) to an OD600 of 0.5 in a final volume of 20 µL.
  2. Add primary antibody to a final concentration of 5 µg/mL and incubate for 2 h at 37 ºC.
  3. Centrifuge at low speed for 2 min to precipitate cells. Discard supernatant to remove excess primary antibody.
  4. Resuspend cells in LB medium including antibiotics and add secondary antibody to a concentration of 1 µg/mL and incubate for 1 h at 37 ºC.
  5. Centrifuge at low speed for 2 min to precipitate cells. Discard supernatant to remove excess secondary antibody.
  6. Resuspend cells in PBSand observe fluorescence by FACS or Confocal microscopy.

Dynabeads for verification of Annexin externalization

Dnyabeads bind to any kind of antibody you expose them to. With dynabeads coated with anti-Annexin V antibody we are probing our cells for proper expression of INP-Annexin V.

  1. Wash beads twice in PBS.
  2. Dilute stock 6x and use 25 µL per two experiments.
  3. Incubate 1 µg anti-Annexin antibody on beads for 30 min on ice.
  4. Wash beads twice in PBS.
  5. Incubate beads with bacteria expressing Annexin V on their surface for 30-60 min on ice. As a control Annexin V-Alexa488 can be used.
  6. Wash beads in PBS at least twice.
  7. Analyze beads by FACS or microscopy.

Phosphatidylserine-coated beads for verification of Annexin functionality

Magnetic beads coated in Streptavidin can be coated with biotinylated phosphatidylserine to simulate an apoptotic cell. After validation of Annexin V expression by our genetically engineered bacteria we therey test the functionality of the INP-Annexin construct.

  1. Wash beads twice in PBS.
  2. Use 5 µL beads suspension per experiment and incubate them with biotinylated phosphatidylserine for 30 min at RT.
  3. Wash beads twice in PBS and once in Annexin binding buffer.
  4. Incubate beads with bacteria expressing Annexin V on their surface for 30-60 min. Use 25 µL of a bacterial preculture. To support binding of Annexin V to phosphatidylserine, add 25 µL of Annexin binding buffer. As a control beads without PS coating, as well as bacteria without the INP-Annexin V construct can be used.
  5. Wash beads in PBS three times.
  6. Analyze beads by FACS or microscopy.

Western Blot

  1. Make overnight cultures of all samples and controls.
  2. Make quick extract or emulsification of overnight cultures at OD600=2.0 by spinning them down and redisolving the pellet in 50 µL of 1x SDS loading buffer and boiling it for 10 min. Then spin down at max speed for 10 min.
  3. Take 8 mL of the supernatant and load onto SDS-PAGE gel.
  4. Run according to common sense.
  5. Equilibrate gel in transfer buffer for 15 min at RT. Pre-wet 2 fibre pads, 2 pieces of filter paper of appropriate size, and 1 piece of nitrocellulose in transfer buffer.
  6. Set up transfer sandwich on the black side of the cassette, in a plastic tray, in the order filter pad, filter paper, nitrocellulose, gel, filter paper, fibre pad, black side of cassette. Add buffer between each layer and avoid air bubbles! Fold the white half of the cassette over the sandwich and close.
  7. Insert cassette into the transfer apparatus in the correct orientation.
  8. Insert ice block (filled with ice or with water), fill box with transfer buffer.
  9. Transfer at 250 mA (or 100 V) for 45 min.
  10. Disassemble the transfer apparatus. Shake the membrane in water for 5 min.
  11. Block the blot in 10 ml of 5% non-fat dry milk in 1x PBS + 0.15% Tween 20 for 1 hour at RT.
  12. Remove block, add primary antibody in 5 ml of block, incubate for 1 hour at RT. Typical concentrations of primary antibodies are 1:5000, 0.2-2 µg/mL.
  13. Remove primary antibody and wash 3x with 10 ml PBS, 5 minutes each at RT.
  14. Add secondary antibody in appropriate concentration. Incubate for 1 hour at RT.
  15. Remove secondary antibody and wash four times with 10 mL PBS, 5 min each at RT.
  16. Detect on Li-COR.

Characterization of the lldR-promoter's response to lactate

  1. Dilute overnight culture in new medium plus antibiotics by adding 40 µL of overnight culture to 2.96 mL of medium.
  2. Add diluted cultures into 96-well plate.
  3. Incubate for 90 to 120 min at 37ºC.
  4. In the meantime prepare 300 µL of desired concentrations of lactate. Careful: prepare 20x stock!
  5. Add 10 µL of the lactate solution to the samples in the 96-well plate.
  6. Set up kinetic cycle in plate reader:
    1. Shaking for 300 s, orbital, 6 mm amplitude.
    2. Measure OD600.
    3. Shaking for 5 s, orbital, 6 mm amplitude.
    4. Measure fluorescence at excitation at 488 and emission at 530. Set gain manually to 70.
  7. Run kinetic cycle for 7 hours.

Alternatively, the reaction of bacteria to any sample of interest containing lactate can be determined in this manner. Variation of the nutrient content of the medium used for these experiments may be considered for further characterization.

Characterize the Fold Change Sensor in the same way. Over time, adaption is expected due to delayed expression of LacI.

Characterization of the lacI-lldR-fusion promoter's response to lactate and IPTG

  1. Dilute overnight culture in new medium plus antibiotics by adding 40 µL of overnight culture to 2.96 mL of medium.
  2. Add diluted cultures into 96-well plate.
  3. Incubate for 90 to 120 min at 37ºC.
  4. In the meantime prepare 300 µL of desired concentrations of lactate and IPTG. Careful: prepare 20x stock!
  5. Add 10 µL of the lactate solution to the samples in the 96-well plate, creating rising a gradient from line 1 to 11.
  6. Add 10 µL of the IPTG solution to the samples in the 96-well plate, creating rising a gradient from row A to H.
  7. Set up kinetic cycle in plate reader:
    1. Shaking for 300 s, orbital, 6 mm amplitude.
    2. Measure OD600.
    3. Shaking for 5 s, orbital, 6 mm amplitude.
    4. Measure fluorescence at excitation at 488 and emission at 530. Set gain manually to 70.
  8. Run kinetic cycle for 7 hours.

AHL response experiments

  1. Dilute overnight culture in new medium plus antibiotics by adding 40 µL of overnight culture to 2.96 mL of medium.
  2. Add diluted cultures into 96-well plate.
  3. Incubate for 90 to 120 min at 37ºC.
  4. In the meantime prepare 20x stock solutions of desired concentrations of AHL.
  5. Add 10 µL of the AHL solution to the samples in the 96-well plate.
  6. Set up kinetic cycle in plate reader:
    1. Shaking for 300 s, orbital, 6 mm amplitude.
    2. Measure OD600.
    3. Shaking for 5 s, orbital, 6 mm amplitude.
    4. Measure fluorescence at excitation at 488 and emission at 530. Set gain manually to 70.
  7. Run kinetic cycle for 7 hours.

Charactreization of the AND gate between lactate and quorum sensing

  1. Dilute overnight culture in new medium plus antibiotics by adding 40 µL of overnight culture to 2.96 mL of medium.
  2. Add diluted cultures into 96-well plate. Include blank samples in row 12.
  3. Incubate for 90 to 120 min at 37ºC.
  4. In the meantime prepare 20x stock solutions of desired concentrations of AHL, along with 20x stock solutions of desired concentrations of L-lactate.
  5. Add 10 µL of the lactate solution to the samples in the 96-well plate, forming a rising gradient from row 1 to row 11.
  6. Add 10 µL of the AHL solution to the samples in the 96-well plate, forming a rising gradient from line A to line H.
  7. Set up kinetic cycle in plate reader:
    1. Shaking for 300 s, orbital, 6 mm amplitude.
    2. Measure OD600.
    3. Shaking for 5 s, orbital, 6 mm amplitude.
    4. Measure fluorescence at excitation at 488 and emission at 530. Set gain manually to 70.
  8. Run kinetic cycle for 7 hours.

Mammalian cell experiments

Overview

The detection of CTC with our engineered MicroBeacon bacteria relies on the detection of two cancer markers, susceptibility to sTRAIL and elevated lactate production by cancer cells. To reproduce literature data on these two points We performed a lot of experiments with several mammalian cell lines, optimizing our protocols until we reached the most reliable results. We perormed all our experiments with Jurkat cells and 3T3 cells, representing a cancerogenic and non-cancerogenic cell line, respectively. We performed our experiments also for HL60 cells, another cancerogenic cell line, and also made some experience with HeLa cells. For more clarity, in our Results page we will however focus only on Jurkat and 3T3 since the other lines did not lead to significantly different results.

Below you can find the protocols we applied for measurements of lactate output of mammalian cells and their sTRAIL susceptibility.

Apoptosis susceptibility experiment with sTRAIL

sTRAIL is a sinaling molecule activating the TNF pathway in cancer cells, specifically inducing apoptosis in these cells, as opposed to the case of healthy cells which are not susceptible to sTRAIL. With the following experiment we are determining the optimal incubation time and sTRAIL concentration for induction of apoptosis in our cancer cell lines of interest.

  1. Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired controls, concentrations, incubation periods, and replicates.
  2. Distribute the cells into the wells of a 96-well plate, 200 µL per well.
  3. Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.
  4. Apply 5 µL of the desired dillutions of sTRAIL to the appropriate wells and incubate for 2 to 6 hours at 30ºC.
  5. After incubation, separate cells from their medium (spin down suspension cells, remove medium from wells with adhesive cell.
  6. Wash 3 times with DPBS.
  7. For detection of apoptosis, Annexin V-Alexa488 can be used. It will bind to externalizes phosphatidylserine on apoptotic cells.

  8. Resuspend cells in Annexin binding buffer and add 5 µL per sample. Incubate at RT for 15 min.
  9. Dillute Annexin V-Alexa488 by addition of 50 µL of Annexin binding buffer. Alternatively, engineered E. coli bacteria expressing our INP-Annexin V construct along with RFP (BBa_K1847015) can be used for detection.
  10. Analyse cells by FACS.
  11. PI staining can be used to distinguish apoptotic from necrotic cells. Apply 5 µL of PI to the respective samples 5 min prior to FACS analysis.

Application of the appropriate positive controls (eg. PMA for Jurkat cells) and control staining (PI for necrotic cells) will lead to more detailed and reliable results.

Alternative induction of apoptosis using PMA

Susceptible cell lines can be incubated with PMA in appropriate incubation period and concentrations as a positive control to sTRAIL induced apoptosis. The following protocol is designed for Jurkat cells.

  1. Incubate cells with blabla PMA and Ionomycin for 24 hours.
  2. Wash cells 3 times with DPBS and resuspend in Annexin V binding buffer for detection with Annexin V-Alexa488.

Measurement of the Lactate output of mammalian cell lines.

Our project relies on the phenomenon of elevated lactate output of cancer cells upon metabolic reprogramming referred to as the Warburg effect. To validate this effect in our cell lines of interest we determined the lactate level of the cell’s culture medium after cell culture within the timeframe in which our system will be applied. Based on this, the lactate production by single cells can be estimated.

The experiment can be carried out in any volume of interest. We performed our measurement in 24-well plates.

Click here to see the results of this experiment.

  1. Count cells and prepare a mastermix to have 80’000 cells or 600’000 cells per well for adherent and suspension cells, respectively. Prepare enough mastermix for all desired time points and replicates. Counting must be very accurate if the determination of the lactate output per cell is the aim of the experiment. Consider using a cell counter.
  2. Distribute the cells into the wells of a 24-well plate, 500 µL per well.
  3. Adherent cells must be allowed to settle for 2 hours previous to the start of the experiment.
  4. At the beginning of the measurement, the medium has to be exchanged to start at the minimal level. To this end, spin down the cells at 250 rcf for 3 min and resuspend the pellet in 500 µL of fresh, prewarmed medium. The sample for time zero has to be taken right after the exchange of the medium.
  5. Samples are collected in regular time intervals by transferring the medium into an Eppendorf tube. Centrifuge samples at 250 rcf for 3 min and transfer the cell free medium into a new Eppendorf tube.
  6. Samples can be stored at 4 to 8 ºC for analysis at a later time point.
  7. The lactate concentration of the collected samples can be determined using the L-Lactate Kit according to its instructions. In order to get good results with this kit, it is essential to use medium free of serum and phenol red.

Bacteria and mammalian cells

Overview

A rather uncommon thing in mammalian cell culture is the central part of our system: the coculture with bacteria. To anticipate unexpected side effects of such a coculture in our final setup, we performed initial experiments combining mammalian cells and E. coli. In a next step, we tested the funcionality of our engineered cells in respect to binding to apoptotic cells. The results we achieved from these tests were obtained applying the following protocols.

Coculture

Since it is a rather unusual experimental setup wanting to combine mammalian cells with bacteria, we performed preliminary tests to find out if anything undesired would happen if we mixed our bacteria with mammalian cells.

  1. Introduce mammalian cells of interest into the wells of a 12-well plate. Adherent cells must be allowed to settle for 2 hours previous to any experiment.
  2. Add 500 µL of a bacterial preculture to the mammalian cells. For analysis using microscopy it is best to use bacteria expressing a fluorophore.
  3. Incubate for 4 hours. Do not incubate in a mammalian cell incubator to avoid contamination of neighbouring cultures!
  4. Analyze samples using a microscope. Check for colocalization or possible internalization of bacteria by mammalian cells, as well as viability of mammalian cells with or without bacteria.

Binding assay

Our engineered bacteria are designed to bind to apoptotic mammalian cells. To verify this interaction we performed the following experiment.

  1. Apoptosis can be induced in sTRAIL susceptible cells as described elsewhere using the optimal incubation time with sTRAIL using the optimal concentration of this agent.
  2. Detection of apoptotic cells can be performed by applying 50 µL of INP-Annexin V and RFP expressing E. coli at an OD600 between 0.6 and 0.8 to the samples followed by 30 min incubation.
  3. Analyse samples by FACS.

Variations of the conditions, for example incubation temperature or Calcium content of the buffer were adjusted to find the best setup. We found that incubation on ice at a Calcium concentration of 2.5 mM is optimal.

Chip

Overview

The final setup of our CTC-detection system will be a water in oil emulsion within a microfluidic chip. To approximate this environment in the limited amount of time we had, we invested a lot of thoughts into our Chip design. We were able to test some components of our final system in the nanowell plate that resulted from this design process. We used our test setup to investigate quorum sensing and lactate detection by our bacteria in a single cell analysis setup.

Fabrication of the chip

Below we describe the sequence of steps to fabricate the chip. Many thanks to Tay group PDMS room facility for making the chip for us.

  1. Draw the design on Autocad software.
  2. Order the transparency mask from CAD/Art Services, Inc
  3. Use a negative photoresist for mold making
  4. Non-stick functionalize wafer: first, place wafer in closed wafer carrier box with a beaker containing a few drops of TMCS. Incubate for 15-60 minutes.
  5. Prepare the PDMS: Mix 10:1 PDMS: Weigh in 66g base PDMS + 6.6g curing agent. Then mix and defoam PDMS in Thinky mixer (3 min at 2000 RPM mix + 3 min at 2200 RPM defoam).
  6. Cast chips: Pour 30 g of the mixed PDMS over wafer in a glass petri dish, degas wafers in excitator for 60 minutes and place in oven on level surfaces. Cure 45 minutes at 80 °C
  7. Finalize chips: Carefully chips from wafers and cut the chips into the desired shape.

Preparation of the chip for the experiments

  1. Clean chip with scotch tape to remove all dust particles
  2. Plasma treat chip for 50 s at 40% power
  3. Submerse chip in double distilled H 2 O
  4. Incubate the chip in Fibronectin solution (0.1 mg/mL) for at least one hour.
  5. Wash chip with PBS (2 times).
  6. Seed cells as explained in Loading of Mammalian cells and bacteria.
  7. After chip usage, clean by incubation in 1M NaOH, no more than 5 minutes

Loading of Mammalian Cells and bacteria

To allow for single cell analysis, we need to reach the stage where most wells in our chip contain only one mammalian cell. We tried several techniques of administration of mammalian cells and bacteria to our chip.

  1. Dilute the mammalian cells to a concentration of 15 cells/µL.
  2. Load 3 mL of the cell suspension into the 6-well plate containing the chip.
  3. Add bacteria to have a concentration of 15 cells/nL into the chip, after measuring the OD.
  4. Mix the solution with a pipette carefully.
  5. Let the cells adhere for 15 minutes.
  6. Optionally, seal the chip with a coverslip.

Lactate sensing of cancer cells

As a prove that the lactate levels produced by cancer cells are enough to trigger GFP expression from our lldR-promoters, we introduced our bacteria into a nanowell plate, along with Jurkat cells. Fluorescence and bacterial cell count were monitored using ImageJ and lead to data presented here.

  1. Dilute the mammalian cells to a concentration of 15 cells/µL.
  2. Load 3 mL of the cell suspension into the 6-well plate containing the chip.
  3. Add bacteria to have a concentration of 15 cells/nL into the chip .
  4. Mix the solution with a pipette carefully.
  5. Let the cells adhere for 30 minutes.
  6. Observe chip for 7 h using the confocal microscope.

General useful things

Overview

A substantial amout of our time in the lab was of course also spent on tasks like cloning, PCRs, transfromations, and many other things. The protocols we applied for these general duties can be found here.

Cryostock of bacteria

  1. Add 1 mL of 40% glycerol to a cryogenic vial.
  2. Add 1 mL sample from the bacterial culture.
  3. Vortex the vial.
  4. Store in -80ºC freezer.

Preparation of chemically competent cells

  1. Take a trace of Escherichia coli from a glycerol stock vial and put it on a LB plate with the correspondent antibiotic.
  2. Incubate overnight at 37ºC.
  3. Pick a colony and inoculate 10 mL LB medium containing the relevant antibiotic. Grow overnight at 37ºC.
  4. Add 1mL overnight culture to 100mL prewarmed LB medium containing the relevant antibiotic in a 500mL flask, and shake at 37ºC until an OD600 of 0.5 is reached (usually 90-120 min).
  5. Cool the culture on ice 5min, and transfer the culture to a sterile, round-bottom centrifuge tube.
  6. Collect the cells by centrifugation at low speed (5 min, 4000 xg, 4ºC).
  7. Resuspend the cells gently in cold (4ºC) TFB1 buffer (30 mL for 100 mL culture) and keep the suspension on ice for 90min.
  8. Collect the cells by centrifugation (5min, 4000 xg, 4ºC).
  9. Discard the supernatant carefully. Always keep the cells on ice.
  10. Resuspend the cells carefully in 4 mL ice-cold TFB2 buffer.
  11. Prepare aliquots of 100-200µL in sterile microcentrifuge tubes and freeze in dry-ice-ethanol mix. Store the competent cells at -80ºC

Transformation of chemically competent cells

  1. Take 1 µL DNA to be transformed and put into a cold sterile 1.5 mL microcentrifuge tube, and keep on ice.
  2. Thaw an aliquot of frozen competent cells on ice.
  3. Resuspend the cells and transfer 50 of the cell suspension into the microcentrifuge tube with the plasmid DNA, mix carefullu, and keep on ice for 20 min.
  4. Transfer the tube to a 42ºC water bath for 90 s.
  5. Add 500 µL SOC medium to the cells and incubate for 60-90 min at 37ºC. Shaking increases transformation efficiency.
  6. Plate 100 µL on LB-agar plates containing antibiotics. Incubate the plates overnight at 37ºC.

Electrocompetent cells

  1. Dillute overnight cultures and let them grow to an OD600 of 0.6 to 0.8. Use approximately 2 mL of culture per transformation.
  2. Spin down the cells at 1600 rcf for 10 min and remove the supernatant.
  3. Wash cells three times in 1 mL ice cold water to remove all residual salts of the LB medium.
  4. Resuspend cells in 50 µL ice cold water and add 1 µL of DNA.
  5. Pipett the cells into a clean cuvette and apply an electric pulse. Check the pulse time. If it is above 5 ms you are fine.
  6. Immediately resuspend the cells in 1 mL fresh medium and transfer them to an eppi. Incubate at 37ºC for 1 h.
  7. Plate 100 µL and 300 µL onto LB plates containing the appropriate antibiotics.

Digest with restriction enzymes

  1. Produce the following master mix:
    1. Water up to 50µL
    2. 1µg of DNA
    3. 5µL CutSmart buffer (bought in BioLabs)
    4. 1µL of each restriction enzyme
  2. Incubate 1 hour at 37ºC.
  3. Inactivate the enzyme with the correspondent temperature during 20 minutes.
  4. Purify the product using an agarose gel.

Ligation

  1. Produce the following master mix on ice:
    1. Water up to 20µL
    2. 50 ng of vector DNA
    3. 37.5 ng of insert DNA
    4. 2µL T4 DNA ligase buffer (bought in BioLabs)
  2. Incubate overnight at 16ºC (if the ends are sticky).
  3. Heat inactivate at 65ºC for 10 minutes.
  4. Put on ice and transform.

Gibson Assembly

  1. Calculate the concentration needed of the correspondent fragments:
    1. For 2 fragments: 2-3x molar excess of the insert.
    2. For 2-3 fragments: total molarity 0.02-0.5 pmol.
    3. For 4-6 fragments: total molarity 0.2-1 pmol.
  2. Put 5 µL of DNA with 15 µL of Gibson Assembly mix. 6mL of this mix consist in:
    1. 3 mL of 1M Tris-HCl pH 7.5
    2. 150 µ of 2 M MgCl2
    3. 60 µl of 100 mM dGTP
    4. 60 µl of 100 mM dATP
    5. 60 µl of 100 mM dTTP
    6. 60 µl of 100 mM dCTP
    7. 300 µL of 1M DTT
    8. 1.5 g PEG-800
    9. 300 µl of 100 mM NAD
  3. Incubate at 50ºC for 60 minutes.
  4. Transform the correspondent microorganism.

Colony PCR

  1. Take 20 µL of LB and put one colony inside.
  2. Prepare master mix for PCR containing:
    1. Water up to 25µL
    2. 1µL of resuspended cells
    3. 10µL ThermoPol buffer (bought in BioLabs)
    4. 10 mM dNTPs
    5. 10 µM forward primer
    6. 10 µM reverse primer
    7. 0.125 µL of taq DNA polymerase
  3. Use the thermocycler with the following conditions:
    1. Initial denaturation at 98ºC for 30 seconds.
    2. 35 cycles, with a denaturation at 98ºC for 10 seconds; primer hybridization temperature depending on the primer for 25 seconds; and an elongation of the sequence at 72ºC for 30 seconds per each kb.
    3. Final extension at 72º for 10 minutes.

Phusion PCR

  1. Prepare master mix for PCR containing:
    1. Water up to 50 µL
    2. 1 µL of resuspended cells
    3. 10 µL Phusion HF buffer (bought in BioLabs)
    4. 10 mM dNTPs
    5. 10 µM forward primer
    6. 10 µM reverse primer
    7. 0.5 µL of phusion DNA polymerase
  2. Use the thermocycler with the following conditions:
    1. Initial denaturation at 98ºC for 30 seconds.
    2. 35 cycles, with a denaturation at 98ºC for 10 seconds; primer hybridization temperature depending on the primer for 25 seconds; and an elongation of the sequence at 72ºC for 30 seconds per each kb.
    3. Final extension at 72º for 10 minutes

Spheroblast Protocol

In order to bind to their target cells, the bacteria designed by the iGEM team of Stockholm have to be turned into Spheroblast, since their construct is located in the inner membrane.

  1. 5 mL overnight culture in Terrific Broth (TB) 2% glucose
  2. 7 mL culture in 100 mL Erlenmeyer flast (1/100 dilluted overnight culture) for 2 h at 37ºC
  3. Cool down samples 20 min at RT
  4. Spin down at 14'000 rpm for 2 min
  5. Wash 2x with 1 mL of Tris-HCL (pH 8.0)
  6. Resuspend cells in 1 mL od STE
  7. Incubate on roto-mixer for 30 min at 37ºC
  8. Spin down at 14'000 rpm for 1 min
  9. Wash with 1 mL of freshly made Solution A. Centrifuge at 14'000 rpm for 1 min
  10. Prepare lysozyme solution (50 mg/mL) with cold water
  11. Resuspend in 1 mL freshly made Solution A and add 20 µL of lysozyme solution
  12. Rota-incubate for 15 min at 37ºC
  13. Centrifuge at 14'000 for 1 min
  14. Resuspend pellet in 1 mL PBS
 

Mammalian cell culture: splitting cells

Depending on the preferences of certain cell lines, split cells at different levels of confluency as described in the following.

Adherent cell lines

  1. Remove the medium by aspirating it using the vacuum pump.
  2. Wash cells with 10 mL of DPBS to remove traces of medium.
  3. Remove the DPBS by aspirating it using the vacuum pump.
  4. Incubate the cells for 2-5 min with Accutase or Trypsin. Use one or two mL for a 25 cm2 flask and 75 cm2 flask, respectively.
  5. Check if the cells are detached after the incubation using the microscope or checking by eye. If they are detached resuspend the cells in approximately 7mL of fresh prewarmed medium to neutralize Trypsin or Accutase. Transfer the resuspended cells into a 15 mL falkon tube.
  6. Spin down the cells for 3 min at 250 rcf.
  7. Remove the medium by aspirating it using the vacuum pump.
  8. Resuspend the cells in 3 to 5 mL depending on size of the pellet.
  9. Count cells using a Neubauer chamber.
  10. Prepare new cultures in 5 or 10 mL in 25 or 75 cm2 flasks, respectively. Seed 10'000 or 5'000 cells per cm2 to reach confluency after 2 or 3 days, respectively.

Suspension cells

  1. Transfer the whole volume of the culture into a 15 mL falkon tube.
  2. Spin down the cells for 3 min at 250 rcf.
  3. Remove the medium by aspirating it using the vacuum pump.
  4. Resuspend the cells in 3 to 5 mL depending on size of the pellet.
  5. Count cells using a Neubauer chamber.
  6. Prepare new cultures in 5 or 10 mL in 25 or 75 cm2 flasks, respectively. Seed 100'000 cells per mL to reach confluency after 2.

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