Team:Tokyo Tech/Experiment/positivefeedback1

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(Construction of the positive feedback system)
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[[File:positivefeedbackassay27tokyotech.png|450px|thumb|left|Fig2-1-3-1-8, Six conditions prepared for positive feedback assay
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[[File:positivefeedbackassay28tokyotech.png|500px|thumb|left|Fig2-1-3-1-9, How to evaluate the positive feedback
[[File:positivefeedbackassay28tokyotech.png|500px|thumb|left|Fig2-1-3-1-9, How to evaluate the positive feedback

Revision as of 06:12, 16 October 2012

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Contents

Construction of the positive feedback system

Fig2-1-3-1-1, Positive feedback system in the cell-cell communication

To accomplish complete positive feedback system, we mixed and co-cultured Plux-LasI cell and Plas-LuxI cell (Fig2-1-3-1-1). As a control co-culture, ⊿P-LasI cell and ⊿P-LuxI cell were mixed. For a trigger of the positive feedback system, we added the initial does of 3OC6HSL (5nM) or 3OC12HSL (2.5nM) to the co-cultures. Including no-induction controls, we thus prepared six conditions (Fig2-1-3-1-8). To confirm that both 3OC6HSL and 3OC12HSL are produced in the positive feedback, the signals content in the supernatants of the co-cultures were evaluated by Las reporter strain and Lux reporter strain (Fig2-1-3-1-9).










Fig2-1-3-1-8, Six conditions prepared for positive feedback assay
Fig2-1-3-1-9, How to evaluate the positive feedback


















In these co-cultures, following behavior would be expected. In the condition I, 3OC6HSL induces 3OC12HSL production of Plux-LasI cell. Then, 3OC12HSL synthesized by Plux-LasI cell induces Plas-LuxI cell. The concentration of 3OC6HSL thus increases compared to the initial amount. Increased amount of 3OC6HSL induces higher production of 3OC12HSL. As a result, the production of both signals increased in the condition I. In this situation, the concentration of 3OC6HSL is higher than the initial concentration of 3OC6HSL (ideal positive feedback behavior). Similarly in the condition II, total amount of 3OC12HSL also increases compared to the initial amount. In the conditions III and VI, no signal is produced because of the lack of inducer. In conditions IV and V, little amount of 3OC6HSL and 3OC12HSL are remained without degradation, respectively.

Fig2-1-3-1-10, Positive feedback assay




Fig2-1-3-1-10 shows that the fluorescence intensity of the Lux reporter cell in the condition I was higher than that in the condition IV. Similarly, the fluorescence intensity of the Las reporter in the condition II was higher than that in the condition V. From these results and circuit design described above, it is suggested that the appearance of positive feedback where cooperation of Plas-LuxI cell and Plux-LasI cell increase the production of 3OC6HSL and 3OC12HSL. [Protocol]
















Materials & Methods

1.Construction

A) Sender cells


pSB6A1-Ptet-LuxR / pSB3K3-Plux-LasI (JM2.300)…Plux-LasI cell

Positivefeedbackassay13tokyotech.png


pSB6A1-Ptrc-LasR / pSB3K3-Plas-LuxI (JM2.300)…Plas-LuxI cell

Positivefeedbackassay14tokyotech.png


pSB6A1-Ptet-LuxR / pSB3K3-ΔP-LasI (JM2.300)…ΔP-LasI cell

Positivefeedbackassay5tokyotech.png



pSB6A1-Ptrc-LasR / pSB3K3-ΔP-LuxI (JM2.300)…ΔP-LuxI cell

Positivefeedbackassay6tokyotech.png








B) Reporter cells


pSB6A1-Ptrc-LasR / pSB3K3-Plas-GFP (JM2.300)…Las reporter cell

Positivefeedbackassay7tokyotech.png


pSB6A1-Ptet-LuxR / pSB3K3-Plux-GFP (JM2.300)…Lux reporter cell

Positivefeedbackassay8tokyotech.png


pSB6A1-Ptrc-LasR / pSB3K3-ΔP-GFP (JM2.300)…negative control

Positivefeedbackassay9tokyotech.png


pSB6A1-Ptrc-LasR / pSB3K3-pλ-GFP (JM2.300)…positive control

Positivefeedbackassay10tokyotech.png


pSB6A1-Ptet-LuxR / pSB3K3-ΔP-GFP (JM2.300)…negative control

Positivefeedbackassay11tokyotech.png


pSB6A1-Ptet-LuxR / pSB3K3-pλ-GFP (JM2.300)…positive control

Positivefeedbackassay12tokyotech.png

2.Strain

JM2.300

Protocol

[Go to the project page "Construction of the positive feedback system"]

1. collect liquid culture

1.1 Prepare overnight culture of inducer cells at 37°C for 12hours.

1.2 Take 30μl of the overnight culture of inducer cells into LB (3ml) + antibiotics (Amp 50μg/ml + Kan 30μg/ml). (→fresh culture)

1.3 Incubate the flesh culture of inducer cells until the observed OD600 reaches around 0.50. Centrifuge the cells at 5000g, 25°C, 1 min, suspend it with 1ml LB + antibiotics (Amp 50μg/ml + Kan 30μg/ml).

1.4 According to the Fig.3-1-3-1-1, take 30μl cell suspensions into LB(3ml) + antibiotics (Amp 50μg/ml + Kan 30μg/ml) + 3OC6HSL (5nM) or OC6HSL(2.5nM)


Fig.3-1-3-1-1

1.5 Incubate the inducer cell for another 4 hours at 37°C.

1.6 Centrifuge the inducer cell at 9000g, 4°C, 1 min, and filter the cultured cell.

1.7 Dilute the filtrate by LB + antibiotics (Amp 50μg/ml + Kan 30μg/ml) in 1:30.

2 Reporter assay

2.1 Prepare overnight culture of reporter cells at 37°C for 12hours.

2.2 Take 30μl of the overnight culture of reporter cells into LB (3ml) + antibiotics (Amp 50μg/ml + Kan 30μg/ml). (→fresh culture)

2.3 Incubate the flesh culture of reporter cells until the observed OD600 reaches around 0.50, and gather the supernatant of culture of inducer cells.

2.4 Centrifuge the reporter cells at 5000g, 25°C, 1 min, and take it into LB + antibiotics (Amp 50μg/ml + Kan 30μg/ml).

2.5 Add 30μl samples of process 2.4 to filtrate + LB (3ml) + antibiotics (Amp 50μg/ml + Kan 30μg/ml) from process 1.7

2.6 Incubate the reporter cells for 4 hours at 37°C.

2.7 Flow cytometer measurements for GFP expression of reporter cells.

[Go to the project page "Construction of the positive feedback system"]