Team:Tokyo Tech/Experiment/Crosstalk Confirmation Assay

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<p style="line-height:0em; text-indent:0em;" name="top">Crosstalk Confirmation Assay</p>
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<h1>1. Introduction </h1>
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<h1>Crosstalk Confirmation
 
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</h1>
 
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<h3>1. Introduction
 
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</h3>
 
<h2>
<h2>
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<p>Through the human practice, we felt the importance of the explanation of the genetic programming in synthetic biology with interesting story. Thus we decided to make E. coli play "Ninja" story. In this story, there are three characters, so we prepared three E. coli which have different plasmids for each role, One is the hero, E. Ninja and the others are E. civilian and E. samurai (Fig1-1).
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<p>Our goal in this project is to construct a system to circumvent crosstalk by 3OC12HSL-LasR complex on lux promoter. We thought that we could prove that our system precisely works only after we obtain data of crosstalk happening by ourselves. Therefore, we confirmed that crosstalk really happened by the following assay.
</p>
</p>
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<p> E. ninja switch between two states depending on whether there is E. civilian or E. samurai (Fig1-2). First, E. civilian is around E. ninja. E. civilian emit the small intercellular molecules 3OC6HSL. When E. ninja detect 3OC6HSL, E. ninja switch into the “mimic state” (Fig1-2 Step1). E. ninja maintain “mimic state” even after E. civilian go away (Fig1-2 Step2). Then the E. samurai come.  
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</h2>
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<h1>2. Summary of the experiment </h1>
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<h2>
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<p>Our purpose is to confirm 3OC12HSL-LasR complex really activates lux promoter. We prepared four plasmid sets shown in below (Fig. 3-1-1). We checked what would happen when we added intercellular molecules 3OC6HSL and 3OC12HSL to these plasmid sets.
</p>
</p>
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<p>E. samurai emit a different small intercellular molecules, 3OC12HSL. When E. ninja detect 3OC12HSL, E. ninja switch into the “attack state” (Fig1-2 Step3). E. ninja continue to maintain “attack state” even after the E. samurai leave (Fig1-2 Step4). Finally E. civilian return. E. ninja detect 3OC6HSL again, and switch back to the “mimic state” (Fig1-2 Step5).
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We prepared twelve conditions as follow.<br>
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</p>
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<blockquote>
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<p>To try to put this story into practice, we designed two genetic circuits: Signal-dependent state change circuit and Signal-dependent state change circuit with crosstalk circumvention (Fig 2-1).  Both of the circuit has a toggle switch subcircuit and toggle-repressor overexpression subcircuit induced by intercellular communication molecules.  In the case without cross talk, each of intercellular communication molecules, 3OC6HSL and 3OC12HSL, can switch the state of the toggle as reported by Collins group. (H. Kobayashi et al., 2004) However, crosstalk between 3OC12HSL-LasR complex and lux promoter disrupts our scenario.  In order to circumvent the cross talk, we thus introduced two modifications.  One is replacement of lux promoter for the overexpression with lux/tet hybrid promoter produced Tokyo tech 2012 (BBa_934024).  The other is addition of a repressor network containing CI434 and TetR.  We confirmed cross talk circumvention on the hybrid promoter experimentally (FigX) and also showed the circumvention in the whole network by mathematical modeling (FigX). The results correspond to the following scenario.  When E. ninja receive 3OC6HSL, 3OC6HSL-LuxR complex activates Plux/tet hybrid promoter, and E. ninja switch into LacI dominant "mimic state."  On the other hand, when E. ninja receive 3OC12HSL, 3OC12HSL-LasR complex activates las promoter, and E. ninja switch into CI dominant "attack state" (Fig2-1) because of crosstalk inhibition by tetR expressed in the LacI-dominant "mimic state."
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<li>A-1) Culture containing Ptrc-<i>lasR</i> and Plas-<i>GFP</i> cell with 3OC6HSL induction
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<li>A-2) Culture containing Ptrc-<i>lasR</i> and Plas-<i>GFP</i> cell with 3OC12HSL induction
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<li>A-3) Culture containing Ptrc-<i>lasR</i> and Plas-<i>GFP</i> cell with DMSO ( no induction)
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<br><br>
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<li>B-1) Culture containing Ptrc-<i>lasR</i> and Plux-<i>GFP</i> cell with 3OC6HSL induction
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<li>B-2) Culture containing Ptrc-<i>lasR</i> and Plux-<i>GFP</i> cell with 3OC12HSL induction
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<li>B-3) Culture containing Ptrc-<i>lasR</i> and Plux-<i>GFP</i> cell with DMSO (no induction)
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<br><br>
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<li>C-1) Culture containing Ptrc-<i>luxR</i> and Plas-<i>GFP</i> cell with 3OC6HSL induction
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<li>C-2) Culture containing Ptrc-<i>luxR</i> and Plas-<i>GFP</i> cell with 3OC12HSL induction
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<li>C-3) Culture containing Ptrc-<i>luxR</i> and Plas-<i>GFP</i> cell with DMSO (no induction)
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<br><br>
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<li>D-1) Culture containing Ptrc-<i>luxR</i> and Plux-<i>GFP</i> cell with 3OC6HSL induction
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<li>D-2) Culture containing Ptrc-<i>luxR</i> and Plux-<i>GFP</i> cell with 3OC12HSL induction
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<li>D-3) Culture containing Ptrc-<i>luxR</i> and Plux-<i>GFP</i> cell with DMSO (no induction)
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<br><br>
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<li>Positive control and negative control are similarly operated.
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</blockquote>
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</h2>
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<h1>3. Prediction</h1>
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<h2>
 +
<p>If the GFP expression level of B-2) is as high as that of A-2), it shows that 3OC12HSL-LasR complex crosstalk happened.
</p>
</p>
</h2>
</h2>
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<h3>2. Gene Circuit in Theory
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<h1>4. Materials and Methods </h1>
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</h3>
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<h3>4-1. Construction </h3>
<h2>
<h2>
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<p>To try to put this story into practice, we designed two genetic circuits: Signal-dependent state change circuit and Signal-dependent state change circuit with crosstalk circumvention
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<p>We used <i>lasR</i> or <i>luxR</i> with constitutive promoter as a regulator and <i>GFP</i> understream of <i>las</i> promoter or <i>lux</i> promoter as a reporter. Making pairs from 2 regulators and 2 repressors, we had to prepare four plasmid sets. These sets are transformed into different cells (Gray KM et al., 1994).
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</p>
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<p>2-1 Signal-dependent state change circuit
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</p>
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<p> Originally, we designed the Signal-dependent state change circuit by combination with bistable "toggle switch"(T. Gardner et al., 2000)  and toggle-repressor overexpression subcircuit induced by intercellular communication molecules. (Fig2-1). small molecules 3OC6HSL and 3OC12HSL. can switch the state of the toggle as expressed in the following step-by-step descriptions.  The toggle switch has two promoter-gene sets Pλ and Plac. Pλ and Plac promoter are repressed by CI and LacI, and coding regions of these proteins CI and LacI are in downstream of each promoter gene (Fig2-1).
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With the combination of the tow subcircuits, our genetic circuit switches into two stable states by inducing of intercellular molecules, this change proceed step-by-step. Note that the explanation of below is in a situation without cross talk problem which we addressed in the latter part of this page.
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</p>
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<p>Step1. When E. civilian emit 3OC6HSL and E. ninja receive these molecules, the 3OC6HSL-LuxR complex activate lux promoter. LuxR is expressed constitutively in E. ninja, so 3OC6HSL combine LuxR when 3OC6HSL is received by E. ninja. Then protein LacI start to be expressed because its upstream's lux promoter is activated by 3OC6HSL-LuxR complex, and LacI repress lacI promoter. Finally, E. ninja switch into the "mimic state" where LacI is expressed from lux promoter and Pλ on toggle switch (Fig2-2-1). (H. Kobayashi et al., 2004)
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</p>
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<p>Step2. When E. civilian leave from around E. ninja, lux promoter activation disappears because 3OC6HSL-LuxR complex are not formed by lack of 3OC6HSL. However, LacI continue to be expressed from Pλ on toggle switch. Therefore E. ninja maintain the "mimic state" (Fig2-2-2).
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</p>
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<p>Step3. Next, E. samurai come along. When E. samurai emit 3OC12HSL and E. ninja receive this molecules, the 3OC12HSL-LasR complex activate las promoter. LasR is expressed constitutively in E. ninja, so 3OC12HSL combine LasR when 3OC12HSL is received by E. ninja. Then protein CI start to be expressed because its upstream's las promoter is activated by 3OC12HSL-LasR complex, and CI repress Pλ. Finally, E. ninja switch into the "attack state" where CI is expressed from las promoter and lac promoter on toggle switch (Fig2-2-3).
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</p>
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<p>Step4. When E. samurai leave from around E. ninja, las promoter activation disappears because 3OC12HSL-LasR complex are not formed by lack of 3OC12HSL. However, CI continue to be expressed from Plac on toggle switch. Therefore E. ninja maintain the "attack state" (Fig2-2-4).
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</p>
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<p>Step5. When E. civilian return and in the same situation like spet1, E. ninja switch into "mimic state" again. When E. civilian emit 3OC6HSL and E. ninja receive these molecules, the 3OC6HSL-LuxR complex activate lux promoter. Then protein LacI start to be expressed because its upstream's lux promoter is activated by 3OC6HSL-LuxR complex, and LacI repress lacI promoter. Finally, E. ninja switch into the "mimic state" where LacI is expressed from lux promoter and Pλ on toggle switch (Fig2-2-5).
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</p>
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<p>2-2. The problem: crosstalk
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</p>
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<p>Though we described an ideal case in the above description, this genetic circuit had a crosstalk problem. In the case of this genetic circuit, LasR, which turn E. ninja into the "attack state," activates not only las promoter but also lux promoter. The crosstalk of LasR confuses E. ninja when E. samurai come. When E.ninja received intercellular molecules 3OC12HSL from E. samurai, 3OC12HSL-LasR complex activate las promoter and also activate lux promoter (Fig2-3-1).
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</p>
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<p>The crosstalk between intercellular molecules 3OC6HSL and 3OC12HSL has been reported in a scientific paper. (Gray KM et al., 1994), We also quantified the crosstalk to confirm whether 3OC12HSL-LasR complex actually activate both las promoter and lux promoter (FigX). We prepared two different plasmids; one with GFP-gene regulated by las promoter (パーツ番号) and the other with  GFP-gene regulated by lux promoter (パーツ番号). We introduced each plasmid into E. coli which have another plasmid to express LasR constitutively. Then, we added 3OC6HSL or 3OC12HSL in the culture growing these two strains. The result of this experiment is shown in Fig2-3-2. When we added 3OC6HSL, we could not confirmed adequate expression of GFP in both strains. This result shows little crosstalk between C6-HSL and LasR. On the other hand, when we added 3OC12HSL, we confirmed expression of GFP in both strains. This shows that 3OC12HSL-LasR complex activate not only las promoter but and lux promoter due to the crosstalk.
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</p>
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<p>2-3 Signal-dependent state change circuit with crosstalk circumvention
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</p>
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<p>We thought of two possible approaches to solve the crosstalk. One is protein/promoter engineering and the other is gene network engineering. We then decided to choose gene network engineering to solve crosstalk problem.
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</p>
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<p>We designed new genetic circuit shown shown in fig2-3-3. Our new gene circuit can circumvent crosstalk between intercellular molecules 3OC6HSL and 3OC12HSL (Fig2-3-3). Two new proteins, CI434 and TetR are added to the original Signal-dependent state change circuit. In addition, the lux promoter is changed to the Plux/tet hybrid promoter, which is Plux/tet hybrid promoter is repressed by TetR. In the case when changing from the "mimic state" to the "attack state," the tetR presence due to the absence of CI434 inhibits expression from the hybrid promoter.  Without this inihibition, LasR protein, activated by 3OC12HSL from E. samurai, binding to luxR-binding sequence of the hybrid promoter would stimulate Lac I expression from the promoter.  This expression, in addition to the CI expression from the las promoter to makes E. ninja confused. However, using new gene network, crosstalk is circumvented and E. ninja switch "mimic state" into "attack state" normally. This is because Plux/tet hybrid promoter is repressed by TetR (Fig2-3-4). Contraly, in the attack state, Plux/tet hybrid promoter is not repressed due to the absence of tetR. This is because expression of tetR is repressed by CI434. So when E. civilian come, Plux/tet hybrid promoter is activated by 3OC6HSL-luxI complex, then E. ninja switch into “mimic state.
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</p>
</p>
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[[Image:Titech2013_CrosstalkConfirmationAssay_3-1_1.jpg|500px|thumb|center|Fig. 3-1-1. Circuit of the crosstalk confirmation assay]]
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<p>To construct plasmids above, we ligated Ptrc-RBS-<i>lasR</i>-TT or Ptrc-RBS-<i>luxR</i>-TT as the regulator, and Plas-RBS-<i>GFP</i>-TT or Plux-RBS-<i>GFP</i>-TT as the reporter plasmid.<blockquote>
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<li>Regulator: pSB6A1-Ptrc-<i>lasR</i> / Reporter: pSB3K3-Plas-<i>GFP</i> (JM2.300)…Ptrc-<i>lasR</i> and Plas-<i>GFP</i> cell
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<li>Regulator: pSB6A1-Ptrc-<i>lasR</i> / Reporter: pSB3K3-Plux-<i>GFP</i> (JM2.300)…Ptrc-<i>lasR</i> and Plux-<i>GFP</i> cell
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<li>Regulator: pSB6A1-Ptrc-<i>luxR</i> / Reporter: pSB3K3-Plas-<i>GFP</i> (JM2.300)…Ptrc-<i>luxR</i> and Plas-<i>GFP</i> cell
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<li>Regulator: pSB6A1-Ptrc-<i>luxR</i> / Reporter: pSB3K3-Plux-<i>GFP</i> (JM2.300)…Ptrc-<i>luxR</i> and Plux-<i>GFP</i> cell
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<li>pSB6A1-Ptet-<i>GFP</i> (JM2.300)…positive control
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<li>pSB6A1-Promoterless-<i>GFP</i> (JM2.300)…negative control
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</blockquote></p></h2>
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<h3>4-2. Strain </h3>
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<h2>
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&nbsp;&nbsp;&nbsp;JM2.300
</h2>
</h2>
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<h3>4-3. Protocol </h3>
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<h2>
 +
<blockquote>
 +
<b>1. O/N -> FC -> Induction</b>
 +
</blockquote>
 +
<p><blockquote>
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1.1 Prepare overnight culture of each cell (GFP posi, GFP nega, and samples) at 37°C for 12 h. <br> (=> O/N)
 +
</blockquote></p>
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<p><blockquote>
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1.2 Take 30 µL (from GFP posi, GFP nega, sample) of the overnight culture of inducer cell into LB (3 mL) + antibiotics (Amp 50 µg/mL+ Kan 30 µg/mL).<br>  (=> Fresh Culture)
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</blockquote></p>
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<p><blockquote>
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1.3 Incubate the flesh culture of cells (GFP posi, GFP nega, sample) until the observed OD600 reaches around 0.50.
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</blockquote></p>
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<p><blockquote>
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1.4 Dilute the flesh culture by the following conditions:
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<blockquote>LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)<br> + 5 µM 3OC6HSL (3 µL)</blockquote>
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<blockquote>LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)<br> + 5 µM 3OC12HSL (3 µL)</blockquote>
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<blockquote>LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)<br> + 5 µM DMSO (3 µL)</blockquote>
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</blockquote></p>
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<p><blockquote>
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1.5 Incubate the flesh culture of diluted inducer cell for 4 h at 37°C.<br>  (=> Induction)
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</blockquote></p>
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<br>
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<blockquote>
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<b>2. Measurement (Flow cytometer)</b>
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</blockquote>
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<p><blockquote>
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2.1 Measure all samples' OD600.
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</blockquote></p>
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<p><blockquote>
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2.2 Dilute all samples with 1X PBS to keep OD600 in the range from 0.2 to 0.5.
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</blockquote></p>
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<p><blockquote>
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2.3 Take 1 mL (from all samples) into a disposable tube (for flow cytometer).
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</blockquote></p>
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<p><blockquote>
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2.4 Centrifuge them at 9,000g, 4°C, 1 min. and take their supernatant away.
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</blockquote></p>
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<p><blockquote>
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2.5 Suspend all samples with 1 mL 1X PBS.
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</blockquote></p>
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<p><blockquote>
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2.6 Measure all samples.
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</blockquote></p>
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<p><blockquote>
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2.7 Save and organize data.
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</blockquote></p>
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</h2>
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<h1>5. Results of the assay </h1>
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<h2>
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[[Image:Titech2013_CrosstalkConfirmationAssay_3-1_2.jpg|500px|thumb|center|Fig. 3-1-2. Crosstalk confirmation results]]
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</h2>
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<h2>
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<p>Fig. 3-1-2 shows the following, <i>las</i> promoter is activated by 3OC12HSL-LasR complex.  Similarly, <i>lux</i> promoter is activated by 3OC12HSL-LasR complex, too.  From this result we confirmed that crosstalk by 3OC12HSL-LasR complex really happened.
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</p>
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</h2>
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<h1>6. Reference </h1>
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<h2><OL><LI>
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Gray KM, Passador L (1994) Interchangeability and specificity of components from the quorum-sensing regulatory systems of Vibrio fischeri and Pseudomonas aeruginosa.  Journal of bacteriology 176(10): 3076–3080.</LI></OL>
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</h2>
</div><br>
</div><br>
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Latest revision as of 02:59, 29 October 2013


Crosstalk Confirmation Assay

Contents

1. Introduction

Our goal in this project is to construct a system to circumvent crosstalk by 3OC12HSL-LasR complex on lux promoter. We thought that we could prove that our system precisely works only after we obtain data of crosstalk happening by ourselves. Therefore, we confirmed that crosstalk really happened by the following assay.

2. Summary of the experiment

Our purpose is to confirm 3OC12HSL-LasR complex really activates lux promoter. We prepared four plasmid sets shown in below (Fig. 3-1-1). We checked what would happen when we added intercellular molecules 3OC6HSL and 3OC12HSL to these plasmid sets.

We prepared twelve conditions as follow.

  • A-1) Culture containing Ptrc-lasR and Plas-GFP cell with 3OC6HSL induction
  • A-2) Culture containing Ptrc-lasR and Plas-GFP cell with 3OC12HSL induction
  • A-3) Culture containing Ptrc-lasR and Plas-GFP cell with DMSO ( no induction)

  • B-1) Culture containing Ptrc-lasR and Plux-GFP cell with 3OC6HSL induction
  • B-2) Culture containing Ptrc-lasR and Plux-GFP cell with 3OC12HSL induction
  • B-3) Culture containing Ptrc-lasR and Plux-GFP cell with DMSO (no induction)

  • C-1) Culture containing Ptrc-luxR and Plas-GFP cell with 3OC6HSL induction
  • C-2) Culture containing Ptrc-luxR and Plas-GFP cell with 3OC12HSL induction
  • C-3) Culture containing Ptrc-luxR and Plas-GFP cell with DMSO (no induction)

  • D-1) Culture containing Ptrc-luxR and Plux-GFP cell with 3OC6HSL induction
  • D-2) Culture containing Ptrc-luxR and Plux-GFP cell with 3OC12HSL induction
  • D-3) Culture containing Ptrc-luxR and Plux-GFP cell with DMSO (no induction)

  • Positive control and negative control are similarly operated.

    • 3. Prediction

    If the GFP expression level of B-2) is as high as that of A-2), it shows that 3OC12HSL-LasR complex crosstalk happened.

    4. Materials and Methods

    4-1. Construction

    We used lasR or luxR with constitutive promoter as a regulator and GFP understream of las promoter or lux promoter as a reporter. Making pairs from 2 regulators and 2 repressors, we had to prepare four plasmid sets. These sets are transformed into different cells (Gray KM et al., 1994).

    Fig. 3-1-1. Circuit of the crosstalk confirmation assay

    To construct plasmids above, we ligated Ptrc-RBS-lasR-TT or Ptrc-RBS-luxR-TT as the regulator, and Plas-RBS-GFP-TT or Plux-RBS-GFP-TT as the reporter plasmid.

  • Regulator: pSB6A1-Ptrc-lasR / Reporter: pSB3K3-Plas-GFP (JM2.300)…Ptrc-lasR and Plas-GFP cell
  • Regulator: pSB6A1-Ptrc-lasR / Reporter: pSB3K3-Plux-GFP (JM2.300)…Ptrc-lasR and Plux-GFP cell
  • Regulator: pSB6A1-Ptrc-luxR / Reporter: pSB3K3-Plas-GFP (JM2.300)…Ptrc-luxR and Plas-GFP cell
  • Regulator: pSB6A1-Ptrc-luxR / Reporter: pSB3K3-Plux-GFP (JM2.300)…Ptrc-luxR and Plux-GFP cell
  • pSB6A1-Ptet-GFP (JM2.300)…positive control
  • pSB6A1-Promoterless-GFP (JM2.300)…negative control

    • 4-2. Strain

       JM2.300

    4-3. Protocol

    1. O/N -> FC -> Induction

    1.1 Prepare overnight culture of each cell (GFP posi, GFP nega, and samples) at 37°C for 12 h.
    (=> O/N)

    1.2 Take 30 µL (from GFP posi, GFP nega, sample) of the overnight culture of inducer cell into LB (3 mL) + antibiotics (Amp 50 µg/mL+ Kan 30 µg/mL).
    (=> Fresh Culture)

    1.3 Incubate the flesh culture of cells (GFP posi, GFP nega, sample) until the observed OD600 reaches around 0.50.

    1.4 Dilute the flesh culture by the following conditions:
    LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)
    + 5 µM 3OC6HSL (3 µL)
    LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)
    + 5 µM 3OC12HSL (3 µL)
    LB (3 mL) + antibiotics (Amp 50 µg/mL + Kan 30 µg/mL)
    + 5 µM DMSO (3 µL)

    1.5 Incubate the flesh culture of diluted inducer cell for 4 h at 37°C.
    (=> Induction)


    2. Measurement (Flow cytometer)

    2.1 Measure all samples' OD600.

    2.2 Dilute all samples with 1X PBS to keep OD600 in the range from 0.2 to 0.5.

    2.3 Take 1 mL (from all samples) into a disposable tube (for flow cytometer).

    2.4 Centrifuge them at 9,000g, 4°C, 1 min. and take their supernatant away.

    2.5 Suspend all samples with 1 mL 1X PBS.

    2.6 Measure all samples.

    2.7 Save and organize data.

    5. Results of the assay

    Fig. 3-1-2. Crosstalk confirmation results

    Fig. 3-1-2 shows the following, las promoter is activated by 3OC12HSL-LasR complex. Similarly, lux promoter is activated by 3OC12HSL-LasR complex, too. From this result we confirmed that crosstalk by 3OC12HSL-LasR complex really happened.

    6. Reference

    1. Gray KM, Passador L (1994) Interchangeability and specificity of components from the quorum-sensing regulatory systems of Vibrio fischeri and Pseudomonas aeruginosa. Journal of bacteriology 176(10): 3076–3080.


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