Difference between revisions of "Team:TokyoTech/Experiment/TraI Assay"

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Quorum Sensing is cell-to-cell communication system which is used variety of microorganism. Signal molecular used in Quorum sensing has variety of chemical structure. LuxI is 合成遺伝子 of 3OC6AHL and TraI is 合成遺伝子 of 3OC8AHL. Chemical structures of these molecule are shown Figure. 1. LuxR gene express intracellular LuxR receptor. Signal molecular and this receptor form complex. This complex interacts with responsive promoters, Plux and regulates transcription of downstream genes. The concentration of signal molecular increase with cell density. By using this system, microorganism assess their local density and regulates gene expression.<br>
+
Quorum Sensing is cell-to-cell communication system used by variety of microorganism. Signal molecular used in Quorum sensing has variety of chemical structure. LuxI is synthesis gene of 3OC6AHL and TraI is synthesis gene of 3OC8AHL. Chemical structures of these molecules are shown in Figure. 1.  
In previous study, a novel, inducible, eukaryotic gene expression system based on the quorum-sensing transcription factor TraR was developed. In this system, transcription downstream of a region called CMV minimal promoter is induced in the presence of signal molecular 3OC8AHL. Therefore, we chose 3OC8AHL as signal molecule and tried to make E.coli to produce 3OC8AHL.
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<figure>
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    <img src="https://static.igem.org/mediawiki/2017/2/25/T--TokyoTech--Construct1.jpg" style="max-width:50%">
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    <figcaption style="font-family: Poppins;font-size: 16px">Fig.1 Chemical structure of signal molecules</figcaption>
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    </figure>
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    <p style="font-family: Poppins;font-size: 16px">
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LuxR gene express intracellular LuxR receptor. Signal molecular and this receptor form complex. This complex interacts with responsive promoters, Plux and regulates transcription of downstream genes. The concentration of signal molecular increase with cell density. By using this system, microorganism assess their local density and regulates gene expression.<br>
 +
In previous study, a novel, inducible, eukaryotic gene expression system based on the quorum-sensing transcription factor TraR was developed.1) In this system, transcription   of downstream of a region called CMV minimal promoter is induced in the presence of signal molecular 3OC8AHL. Therefore, we chose 3OC8AHL as a signal molecule and tried to make E.coli to produce 3OC8AHL.<br>
 
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In this section, we confirmed whether E. coli expressing Tral protein truly produced signal molecules, AHL (Acyl Homoserine Lactone). <br>
+
In this section, we confirmed whether E. coli expressing Tral protein truly produced signal molecules, AHL (Acyl Homoserine Lactone). <br>
 
To achieve this goal, we constructed two types of E. coli. One is the “Sender” E. coli which produces AHL and the other is the “Reporter” E. coli which expresses GFP in the presence of AHL.<br>
 
To achieve this goal, we constructed two types of E. coli. One is the “Sender” E. coli which produces AHL and the other is the “Reporter” E. coli which expresses GFP in the presence of AHL.<br>
 
To begin with, we evaluated whether “Reporter” cell could express GFP dependent on AHL by culturing them in liquid LB medium containing various concentrations of AHL (0.1nM - 1000nM).<br>
 
To begin with, we evaluated whether “Reporter” cell could express GFP dependent on AHL by culturing them in liquid LB medium containing various concentrations of AHL (0.1nM - 1000nM).<br>
Then we confirmed whether the “Sender” could produce AHL. The supernatant of the “Sender” cell’s medium was added into the medium of “Reporter” cells and the production of AHL was confirmed by the expression of GFP from the “Reporter” cells.<br>  
+
Then we confirmed whether the “Sender” could produce AHL. The supernatant of the “Sender” cell’s medium was added into the medium of “Reporter” cells and the production of AHL was confirmed by the expression of GFP from the “Reporter” cells.<br>
 +
<br>
 
Following plasmids were introduced into E. coli. <br>
 
Following plasmids were introduced into E. coli. <br>
 
Reporter<br>
 
Reporter<br>
Fig. 1で示したプラスミドをE.coliのDH5α株にダブルトラフォメすることで、E.coliが3OC8AHLシグナルや3OC6AHLシグナルに反応してGFPを生産するようになる。<br>
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By introducing plasmids shown in Figure. 2, E.coli will be able to produce gfp in response to 3OC8AHL signal and 3OC6AHL signal.<br>
 
<figure>
 
<figure>
 
     <img src="https://static.igem.org/mediawiki/2017/2/25/T--TokyoTech--Construct1.jpg" style="max-width:50%">
 
     <img src="https://static.igem.org/mediawiki/2017/2/25/T--TokyoTech--Construct1.jpg" style="max-width:50%">
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.1Construction of LuxR gene and Plux-gfp gene</figcaption>
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     <figcaption style="font-family: Poppins;font-size: 16px">Fig.2 Construction of LuxR gene and Plux-gfp gene</figcaption>
 
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     </figure>
 
<figure>
 
 
<br>
 
<br>
Sender<br>
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Sender
Fig. 2 に示したように、恒常プロモーターであるPtetの下流にTraIをつなぐことによって、常に3OC8AHLを合成するE.coliを作ることができる。<br>
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<br>
 +
We create Sender E.coli by introducing a plasmid shown in Fig. 3.<br>
 +
Sender E.coli constantly produce signal molecule, 3OC8AHL because TraI gene is placed at downstream of constitutive promoter, Ptet.<br>
 
<figure>
 
<figure>
 
     <img src="https://static.igem.org/mediawiki/2017/d/d8/T--TokyoTech--Construct3.jpg" style="max-width:50%">
 
     <img src="https://static.igem.org/mediawiki/2017/d/d8/T--TokyoTech--Construct3.jpg" style="max-width:50%">
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.2 Construction of TraI gene</figcaption>
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     <figcaption style="font-family: Poppins;font-size: 16px">Fig.3 Construction of TraI gene</figcaption>
 
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LuxR protein is a receptorfor C6 signals. However, previous study (文献) showed that it can also bind to other kinds of AHL, such as C10 .<br>
+
LuxR protein is a receptor for C6 signals. However, previous study showed that it can also bind to other kinds of AHL, such as C10.2) We confirmed that LuxR could also respond to C8 signals as sensitive as respoding of C6 signals. Receiver E.coli’s RFU (Reletive Fluoroscent Units) in each AHL concentration (0.01 nM ? 1000 nM) is shown in Figure. 4. Detection limit was over 10nM in case of C6 and C8. RFU values were almost same over 100nM.<br>
We confirmed that LuxR could also respond to C8 signals as sensitive as respoding of C6 signals. Receiver E.coli’s RFU (Reletive Fluoroscent Units) in each AHL concentration (0.01 nM ? 1000 nM) is shown in Figure . <br>
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  Detection limit was over 10nM in case of C6 and C8. RFU valueswere almost same over 100nM.  
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     <figure>
 
     <figure>
 
     <img src="https://static.igem.org/mediawiki/2017/9/95/T--TokyoTech--TraIfigure1.jpg" style="max-width:50%">
 
     <img src="https://static.igem.org/mediawiki/2017/9/95/T--TokyoTech--TraIfigure1.jpg" style="max-width:50%">
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.3 Concentration dependance of <br>Reletive Fluoroscent Units </figcaption>
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     <figcaption style="font-family: Poppins;font-size: 16px">Fig.4 Concentration dependance of <br>Reletive Fluoroscent Units </figcaption>
 
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<br>
    <p style="font-family: Poppins;font-size: 16px">
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Error bar have a same width as standard deviation (n=3).<br>
Error bar have a same width as standard deviation (n=3).
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Based on the data which is shown in Fig. 4, parameter was obtained to fit Hill’s equation.<br>
</div>
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Hill’s equation is shown in Eq. 1<br>
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     <img src="https://static.igem.org/mediawiki/2017/9/95/T--TokyoTech--TraIfigure1.jpg" style="max-width:50%">
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    <figcaption style="font-family: Poppins;font-size: 16px">Eq.1 Hill's equation  </figcaption>
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    </figure>
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The values of Parameter is shown in Table. 1<br>
 +
<figure>
 +
    <img src="https://static.igem.org/mediawiki/2017/9/95/T--TokyoTech--TraIfigure1.jpg" style="max-width:50%">
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    <figcaption style="font-family: Poppins;font-size: 16px">Eq.1 Hill's equation  </figcaption>
 +
    </figure>
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Actual measurement value and Theoretical formula is shown in Fig. 5.<br>
 
<figure>
 
<figure>
 
     <img src="https://static.igem.org/mediawiki/2017/a/a7/T--TokyoTech--TraIfigure2.jpg" style="max-width:50%">
 
     <img src="https://static.igem.org/mediawiki/2017/a/a7/T--TokyoTech--TraIfigure2.jpg" style="max-width:50%">
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.4 Theoretical formula </figcaption>
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     <figcaption style="font-family: Poppins;font-size: 16px">Table. 1 Parameters of Hill’s equation </figcaption>
 
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<br>
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Supernatant Assay <br>
 
Supernatant Assay <br>
 
Temperature dependence of AHL production. <br>
 
Temperature dependence of AHL production. <br>
 
We found that Amount of C8 production is depend on  temperature. RFU was 14 folds larger than DH5α. <br>
 
We found that Amount of C8 production is depend on  temperature. RFU was 14 folds larger than DH5α. <br>
 
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     <img src="https://static.igem.org/mediawiki/2017/4/46/T--TokyoTech--TraIfigure3.jpg" style="max-width:50%">
 
     <img src="https://static.igem.org/mediawiki/2017/4/46/T--TokyoTech--TraIfigure3.jpg" style="max-width:50%">
 
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.5 Temperature dependancies of 3OC8AHL production</figcaption>
 
     <figcaption style="font-family: Poppins;font-size: 16px">Fig.5 Temperature dependancies of 3OC8AHL production</figcaption>
 
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We confirmed that E. coli can produce uuu μM. However previous study (文献) showed that 20μM of C8 is required to activate the target gene in human cells.Therefore, we need further improvement of C8 production.<br>
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We confirmed that E. coli can produce over 200nM of 3OC8AHL. However previous study1) showed that 20μM of C8 is required to activate the target gene in human cells. Therefore, we need further improvement of C8 production. <br>
Result of Figure.5 shows temperature dependancies of 3OC8AHL production. TraI is derived from soil microorganism A. Tumefaciens. It is rarely happen that Temperature of the soil rise above 37 ℃. Therefore it is considered that TraI protein  does not work properly above 37℃.  <br>
+
Result of Figure.5 shows temperature dependence of 3OC8AHL production. TraI is derived from soil microorganism A. Tumefaciens. It is rarely happen that Temperature of the soil rise above 37 ℃. Therefore it is considered that TraI protein  does not work properly above 37℃.  <br>
 
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Revision as of 21:38, 29 October 2017

<!DOCTYPE html> Coli Sapiens

iGEM Tokyo Tech

TraI Assay

Introduction

Quorum Sensing is cell-to-cell communication system used by variety of microorganism. Signal molecular used in Quorum sensing has variety of chemical structure. LuxI is synthesis gene of 3OC6AHL and TraI is synthesis gene of 3OC8AHL. Chemical structures of these molecules are shown in Figure. 1.

Fig.1 Chemical structure of signal molecules

LuxR gene express intracellular LuxR receptor. Signal molecular and this receptor form complex. This complex interacts with responsive promoters, Plux and regulates transcription of downstream genes. The concentration of signal molecular increase with cell density. By using this system, microorganism assess their local density and regulates gene expression.
In previous study, a novel, inducible, eukaryotic gene expression system based on the quorum-sensing transcription factor TraR was developed.1) In this system, transcription of downstream of a region called CMV minimal promoter is induced in the presence of signal molecular 3OC8AHL. Therefore, we chose 3OC8AHL as a signal molecule and tried to make E.coli to produce 3OC8AHL.

Summary of experiment

In this section, we confirmed whether E. coli expressing Tral protein truly produced signal molecules, AHL (Acyl Homoserine Lactone).
To achieve this goal, we constructed two types of E. coli. One is the “Sender” E. coli which produces AHL and the other is the “Reporter” E. coli which expresses GFP in the presence of AHL.
To begin with, we evaluated whether “Reporter” cell could express GFP dependent on AHL by culturing them in liquid LB medium containing various concentrations of AHL (0.1nM - 1000nM).
Then we confirmed whether the “Sender” could produce AHL. The supernatant of the “Sender” cell’s medium was added into the medium of “Reporter” cells and the production of AHL was confirmed by the expression of GFP from the “Reporter” cells.

Following plasmids were introduced into E. coli.
Reporter
By introducing plasmids shown in Figure. 2, E.coli will be able to produce gfp in response to 3OC8AHL signal and 3OC6AHL signal.

Fig.2 Construction of LuxR gene and Plux-gfp gene

Sender
We create Sender E.coli by introducing a plasmid shown in Fig. 3.
Sender E.coli constantly produce signal molecule, 3OC8AHL because TraI gene is placed at downstream of constitutive promoter, Ptet.
Fig.3 Construction of TraI gene

Results

LuxR protein is a receptor for C6 signals. However, previous study showed that it can also bind to other kinds of AHL, such as C10.2) We confirmed that LuxR could also respond to C8 signals as sensitive as respoding of C6 signals. Receiver E.coli’s RFU (Reletive Fluoroscent Units) in each AHL concentration (0.01 nM ? 1000 nM) is shown in Figure. 4. Detection limit was over 10nM in case of C6 and C8. RFU values were almost same over 100nM.

Fig.4 Concentration dependance of
Reletive Fluoroscent Units

Error bar have a same width as standard deviation (n=3).

Based on the data which is shown in Fig. 4, parameter was obtained to fit Hill’s equation.
Hill’s equation is shown in Eq. 1
Eq.1 Hill's equation
The values of Parameter is shown in Table. 1
Eq.1 Hill's equation
Actual measurement value and Theoretical formula is shown in Fig. 5.
Table. 1 Parameters of Hill’s equation

Supernatant Assay
Temperature dependence of AHL production.
We found that Amount of C8 production is depend on temperature. RFU was 14 folds larger than DH5α.
Fig.5 Temperature dependancies of 3OC8AHL production

Discussion

We confirmed that E. coli can produce over 200nM of 3OC8AHL. However previous study1) showed that 20μM of C8 is required to activate the target gene in human cells. Therefore, we need further improvement of C8 production.
Result of Figure.5 shows temperature dependence of 3OC8AHL production. TraI is derived from soil microorganism A. Tumefaciens. It is rarely happen that Temperature of the soil rise above 37 ℃. Therefore it is considered that TraI protein does not work properly above 37℃.

Material and Methods

Reagent assay
1. Cultivate Receiver E.coli in LB medium containing antibiotics for about 15hours
2. Dilute the culture to 1/200 with flesh LB medium containing antibiotics
3. Incubate the flesh culture for 2 hours
4. Mix 495μL of the culture with 5μL of DMSO solution (each DMSO is containing 100 microM,10microM...of AHL to reach final concentration 1microM 100nM...) in micro tube
5. Incubate the micro tube for 5 hours with Small shaking incubator in 37℃
6. Take 100μL of culture and Measure fluorescent (excitation wave length is 495nm, Measurement wavelength is 520nm) and absorbance (Measurement wavelength is 600nm) Supernatant assay
Supernatant Assay
1. Cultivate Sender E.coli in LB medium for about 15hours
2. Centrifuge the culture 16,000rpm and 5minutes
3. Follow Reagent assay process (1~4) and Prepare Reporter culture.
4. Mix 250μL of sender culture’s supernatant with Reporter culture in micro tube.
5. Incubate the micro tube for 5 hours with Small shaking incubator in 37℃
6. Take 100μL of culture and Measure fluorescent (excitation wave length is 495nm, Measurement wavelength is 520nm gain is 45) and absorbance (Measurement wavelength is 600nm)

Reference

参考文献

Hajime Fujita: All Rights Reserved