Team:Tokyo Tech/Experiment/Inducible Plaque Forming Assay

From 2013.igem.org

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<h1>Plaque Forming Assay PlacI<sup>q</sup></h1>
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<h1>Plaque Forming Assay Plux</h1>
<h3>1.Introduction
<h3>1.Introduction
</h3>
</h3>
<h2>
<h2>
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<p>We confirmed that M13 phage genes and M13 origin worked properly with pSB origin, using a plaque forming assayThe plasmid construction is as follows.  First, from M13mp18 phage vector, we amplified the sequence that includes from <i>g2p</i> RBS to M13 origin (with prefix and suffix sequence), by PCR (Fig. 1)Second, we inserted the amplified sequence to pSB3K3 backbone.  Finally, upstream of the RBS-<i>g2p</i>, we inserted PlacI<sup>q</sup> (constitutive) promoter.
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<p>It was revealed that M13 phage genes and M13 origin worked together with pSB origin.  Next, we confirmed whether the release of M13 phage particle depends on the induction of <i>g2p</i> expressionWe inserted <i>lux</i> promoter (activated by LuxR-3OC6HSL complex) upstream of <i>g2p</i>, as an inducible promoter
</p>
</p>
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<p><img src="https://static.igem.org/mediawiki/2013/d/df/Titech2013_M13_PlacIq_Fig.1.PNG" width="600"></p>
 
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<p>Fig. 1. Our designed plasmid constrction</p>
 
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</h2>
</h2>
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<h3>2.Materials and Methods
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<h4>Fig 1.  Flow chart of this experiment.
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</h4>
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<h5>Prepare <i>E</i>. coli surrounded by a red circle. We add inducer (AHL) to the <i>E. coli.</i>  Phage is released by induction of AHL.  Spin the culture of the <i>E. coli.</i>  Decant the supernatant of the culture including phages to soft agar ( the agar which is easy to melt ).  Add lawn (<i>E. coli</i> containing pSB6A1-Ptet-<i>luxR</i> ) to the soft agar.  Mix them in soft agar.  Then, decant the soft agar to YT plate.
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</h5>
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<h3>2.Materials and Method
</h3>
</h3>
<h2>
<h2>
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2-2-0 Plasmid construction
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2-1 Plasmid construction
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<p>pSB3K3-PlacI<sup>q</sup>-M13-Plac-<i>GFP</i> (BBa_K1139020)
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<p>pSB3K3-Plux-M13-Plac-<i>GFP</i> (BBa_K1139021)
</p>
</p>
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<p>pSB3K3-M13-Plac-<i>GFP</i> (BBa_K113922)
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<p>pSB6A1-Ptet-<i>luxR</i>  
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</p><br>
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2-2-1Strains
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<p>DH5alpha (<i>E.  coli</i> of high competence)
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</p>
</p>
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<p>JM109 (F+ strain <i>E. coli</i>)
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2-2 assay protocol
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</p><br>
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2-2-0 Strains
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2-2-2 Media
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<p>DH5alpha (<i>E. coli</i> of high competence)
 +
</p>
 +
<p>JM109 (F+ strain <i>E. coli</i>)
 +
</p>
 +
2-2-1 Media
<p>LB
<p>LB
</p>
</p>
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<p>Yeast Extract  5 g/L
<p>Yeast Extract  5 g/L
</p>
</p>
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<p>NaCl           10 g/L
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<p>NaCl           10 g/L
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</p><br>
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</p>
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<p>YT plate
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<p>YT soft agar
</p>
</p>
<p>Bacto tryptone  8 g/L
<p>Bacto tryptone  8 g/L
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<p>Yeast Extract  5 g/L
<p>Yeast Extract  5 g/L
</p>
</p>
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<p>NaCl          5 g/L
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<p>NaCl:           5 g/L
</p>
</p>
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<p>Agarose        15 g/L
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<p>Agarose:       6 g/L
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</p><br>
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</p>
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<p>YT soft agar
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<p>YT plate
</p>
</p>
<p>Bacto tryptone  8 g/L
<p>Bacto tryptone  8 g/L
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<p>Yeast Extract  5 g/L
<p>Yeast Extract  5 g/L
</p>
</p>
-
<p>NaCl          5 g/L
+
<p>NaCl:           5 g/L
 +
</p>
 +
<p>Agarose:        15 g/L
 +
</p>
 +
2-2-2 Others
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<p>3OC6HSL dissolved in DMSO (>100 microM)
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</p>
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<p>Autoclaved pieces of filter paper (about 1.5 cm in diameter)
</p>
</p>
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<p>Agarose        6 g/L
 
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</p><br>
 
2-2-3 Protocol
2-2-3 Protocol
<p>Preparation
<p>Preparation
</p>
</p>
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<p>1.Transform DH5alpha with pSB3K3-PlacI<sup>q</sup>-M13.</p>
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1.Transform DH5alpha with pSB3K3-Plux-M13-Plac-<i>GFP</i> and pSB6A1-Ptet-<i>luxR</i>  
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<p>2.Grow overnight culture of the transformed DH5alpha and JM109 at 37°C.</p><br>
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2.Grow overnight culture (Amp + Kan) of the transformed DH5alpha and JM109 at 37°C.
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3.Take 30 microL of the overnight culture into 3 mL LB (Amp + Kan).  (→fresh culture)
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4.Incubate the fresh culture at 37°C for 2 hours.
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5.Add 3 microL of 5 microM 3OC6HSL in DMSO (final concentration: 5 nM) to the fresh culture and incubate at 37°C for 4 hours.
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6.Spin the overnight culture of the transformed DH5alpha at 9,000 g for 1 minute.
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7.Pipette the supernatant into a 1.5 mL tube.
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8.Dilute it 100 times with water. (→ phage-particle-solution)
<p>Plaque formation
<p>Plaque formation
</p>
</p>
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<p>3.Spin the overnight culture of the transformed DH5alpha at 9,000 g for 1 min.</p>
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9.Transform JM109 with pSB6A1-Ptet-<i>luxR</i>
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<p>4.Pipette the supernatant into a 1.5 mL tube.</p>
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10.Grow overnight culture of the transformed JM109 at 37°C.
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<p>5.Dilute it 100 times with water.  (-> phage-particle-solution)</p>
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11.Melt YT soft agar using a microwave.
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<p>6.Melt YT soft agar using a microwave. </p>
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12.Add ampicillin to the YT soft agar.
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<p>7.Dispense 3.5 mL of the melted soft agar to a new round tube, and keep them at 50°C in an incubator.</p>
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13.Dispense 3.5 mL of the melted soft agar to a new round tube, and keep them at 50°C in an incubator.
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<p>8.Dispense 400 microL of overnight culture of JM109 to a 1.5 mL tube.</p>
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14.Dispense 400 microL of overnight culture of the transformed JM109 to a 1.5 mL tube.
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<p>9.Into the 1.5 mL tube, add 100 microL of the phage-particle-solution.</p>
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15.Into the 1.5 mL tube, add 100 microL of the phage-particle-solution.
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<p>10.Transfer all the content of the 1.5 mL tube to the dispensed soft agar, mix them, and decant all of it on a YT plate.</p>
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16.Transfer all the content of the 1.5 mL tube to the dispensed soft agar, mix them, and decant all of it on a YT plate.
 +
17.Wait for YT soft agar to solidify at room temperature (for about 5 minutes).
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18.Put an autoclaved piece of filter paper on the plate, and drip 20 mL of 3OC6HSL in DMSO (100 microM, 5 microM or DMSO only) on the piece of filter paper.
</h2>
</h2>
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<h3>
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<h3>3.Result
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3.Result
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</h3>
</h3>
<h2>
<h2>
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<p>The result of the plaque forming assay is showed in Fig. 2M13 phage genes and M13 origin worked together with <i>lacI<sup>q</sup></i> promoter and pSB origin.
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<p>The result of the plaque forming assay is showed in Fig 3. On the plate, the plaques were formed at some distance from the piece of filter paperThe result shows that phage release is regulated by induction of 3OC6HSL.
</p>
</p>
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<p>
+
<p>We also analyze the distribution of the plaques (Fig 4.). The histogram result implicates that the plaques are formed only at the appropriate concentration of 3OC6HSL in medium (Fig 5.)In the neighborhood of the piece of filter paper, the expression of <i>g2p</i> is so activated that the phage particles cannot be produced efficiently, because the production of the coat proteins largely exceeds that of the single stranded DNA, and vice versa.
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</a><br><p><img src="https://static.igem.org/mediawiki/2013/8/89/Titech2013_M13_PlacIq_A.jpg" width="600"></p>
+
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<p>Fig. 2-A. The plaques were formed using JM109 overnight culture and phage-particle-solutionThe phage particles were obtained from the supernatant of the overnight culture of transformed DH5alpha (with pSB3K3- PlacI<sup>q</sup>-M13) at 9,000 g. A mixture of 3.5 mL YT soft agar, 100 microL of 100X supernatant and 400 microL of overnight culture of JM109 was poured on a YT plate.
+
</p>
</p>
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<p><img src="https://static.igem.org/mediawiki/2013/9/9c/Titech2013_M13_PlacIq_B.jpg" width="600"></p>
+
 
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<p>Fig. 2-B. A mixture of only 3.5 mL YT soft agar and 500 microL of overnight culture of JM109 was poured on a YT plate.
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Fig 3.  The plaques formed with 3OC6HSL induction (plaque plotted)
 +
<p>The plaques were formed using JM109 (with pSB6A1-Ptet-<i>luxR</i>) overnight culture as a lawn and phage-particle-solution. The phage particles were obtained from the supernatant of the fresh culture (+3OC6HSL) of transformed DH5alpha (with pSB3K3-Plux-M13) at 9,000 g. A mixture of 3.5 mL YT soft agar, 100 microL of X 100 supernatant and 400 microL of overnight culture of JM109 (with pSB6A1-Ptet-<i>luxR</i>) was poured on a YT plate.  After solidifying the soft agar, we put a piece of filter paper on the plate and dripped 3OC6HSL in DMSO (or DMSO only) on the piece of filter paper.
</p>
</p>
-
</h2>
 
 +
Fig 4.  The analysis of distribution of the plaques
 +
<p>We totalize the distances from the center of the piece of filter paper to each plaque, by using ImageJ.
 +
</p>
 +
Fig 5.  The distribution histogram of the plaques
 +
<p>This histogram shows distance from the piece of paper (+ inducer) in a horizontal axis, and shows number of plaques over distance squared, which means the rate of plaque formation, in a vertical axis.  The bin range is 0.2 cm.
 +
</p>
 +
</h2>

Revision as of 07:31, 26 September 2013


Plaque Forming Assay Plux

1.Introduction

It was revealed that M13 phage genes and M13 origin worked together with pSB origin. Next, we confirmed whether the release of M13 phage particle depends on the induction of g2p expression. We inserted lux promoter (activated by LuxR-3OC6HSL complex) upstream of g2p, as an inducible promoter

Fig 1. Flow chart of this experiment.

Prepare E. coli surrounded by a red circle. We add inducer (AHL) to the E. coli. Phage is released by induction of AHL. Spin the culture of the E. coli. Decant the supernatant of the culture including phages to soft agar ( the agar which is easy to melt ). Add lawn (E. coli containing pSB6A1-Ptet-luxR ) to the soft agar. Mix them in soft agar. Then, decant the soft agar to YT plate.

2.Materials and Method

2-1 Plasmid construction

pSB3K3-Plux-M13-Plac-GFP (BBa_K1139021)

pSB6A1-Ptet-luxR

2-2 assay protocol 2-2-0 Strains

DH5alpha (E. coli of high competence)

JM109 (F+ strain E. coli)

2-2-1 Media

LB

Bacto tryptone 10 g/L

Yeast Extract 5 g/L

NaCl 10 g/L

YT soft agar

Bacto tryptone 8 g/L

Yeast Extract 5 g/L

NaCl: 5 g/L

Agarose: 6 g/L

YT plate

Bacto tryptone 8 g/L

Yeast Extract 5 g/L

NaCl: 5 g/L

Agarose: 15 g/L

2-2-2 Others

3OC6HSL dissolved in DMSO (>100 microM)

Autoclaved pieces of filter paper (about 1.5 cm in diameter)

2-2-3 Protocol

Preparation

1.Transform DH5alpha with pSB3K3-Plux-M13-Plac-GFP and pSB6A1-Ptet-luxR 2.Grow overnight culture (Amp + Kan) of the transformed DH5alpha and JM109 at 37°C. 3.Take 30 microL of the overnight culture into 3 mL LB (Amp + Kan). (→fresh culture) 4.Incubate the fresh culture at 37°C for 2 hours. 5.Add 3 microL of 5 microM 3OC6HSL in DMSO (final concentration: 5 nM) to the fresh culture and incubate at 37°C for 4 hours. 6.Spin the overnight culture of the transformed DH5alpha at 9,000 g for 1 minute. 7.Pipette the supernatant into a 1.5 mL tube. 8.Dilute it 100 times with water. (→ phage-particle-solution)

Plaque formation

9.Transform JM109 with pSB6A1-Ptet-luxR 10.Grow overnight culture of the transformed JM109 at 37°C. 11.Melt YT soft agar using a microwave. 12.Add ampicillin to the YT soft agar. 13.Dispense 3.5 mL of the melted soft agar to a new round tube, and keep them at 50°C in an incubator. 14.Dispense 400 microL of overnight culture of the transformed JM109 to a 1.5 mL tube. 15.Into the 1.5 mL tube, add 100 microL of the phage-particle-solution. 16.Transfer all the content of the 1.5 mL tube to the dispensed soft agar, mix them, and decant all of it on a YT plate. 17.Wait for YT soft agar to solidify at room temperature (for about 5 minutes). 18.Put an autoclaved piece of filter paper on the plate, and drip 20 mL of 3OC6HSL in DMSO (100 microM, 5 microM or DMSO only) on the piece of filter paper.

3.Result

The result of the plaque forming assay is showed in Fig 3. On the plate, the plaques were formed at some distance from the piece of filter paper. The result shows that phage release is regulated by induction of 3OC6HSL.

We also analyze the distribution of the plaques (Fig 4.). The histogram result implicates that the plaques are formed only at the appropriate concentration of 3OC6HSL in medium (Fig 5.). In the neighborhood of the piece of filter paper, the expression of g2p is so activated that the phage particles cannot be produced efficiently, because the production of the coat proteins largely exceeds that of the single stranded DNA, and vice versa.

Fig 3. The plaques formed with 3OC6HSL induction (plaque plotted)

The plaques were formed using JM109 (with pSB6A1-Ptet-luxR) overnight culture as a lawn and phage-particle-solution. The phage particles were obtained from the supernatant of the fresh culture (+3OC6HSL) of transformed DH5alpha (with pSB3K3-Plux-M13) at 9,000 g. A mixture of 3.5 mL YT soft agar, 100 microL of X 100 supernatant and 400 microL of overnight culture of JM109 (with pSB6A1-Ptet-luxR) was poured on a YT plate. After solidifying the soft agar, we put a piece of filter paper on the plate and dripped 3OC6HSL in DMSO (or DMSO only) on the piece of filter paper.

Fig 4. The analysis of distribution of the plaques

We totalize the distances from the center of the piece of filter paper to each plaque, by using ImageJ.

Fig 5. The distribution histogram of the plaques

This histogram shows distance from the piece of paper (+ inducer) in a horizontal axis, and shows number of plaques over distance squared, which means the rate of plaque formation, in a vertical axis. The bin range is 0.2 cm.