Team:Groningen/Lab/experiments/Motility assay

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<h1>Motility test</h1>
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<h2>Motility assay</h2>
<h2>Motility assay</h2>
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<p>A motility assay is done for <i>Bacillus subtilis</i> of different knockout strains as well as a wild type strain.  
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To test the difference in motility between the wild type <i>Bacillus subtilis</i> 168 strain and the both knockout strains, &Delta;cheY and &Delta;cheY&Delta;des, a motility test is done.
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<p>This is to determine how different the knockouts move compared to the wild type <i>B. subtilis</i>.
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<br>The plates are inoculated in 25&deg;C and 37&deg;C to determine the different behaviour of the strain at different temperatures, as these are the temperatures we expect changes when the Pdes-cheY construct is inserted into the &Delta;cheY&Delta;des strain. In general we expect the wildtype strain to be more motile than the knock out strains.
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<p>The results will be used to determine if the temperature controlled strain works as desired, moving more as a CheY knockout in warm environments and more as a wild type in cold environments.
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The design we used for our motility assay is a simple one. The LB agar plates are made with the normal amount of LB-broth as nutrient, but with a reduced amount of agar. Low concentrations of agar are needed to allow movement through the medium, but when the concentrations are getting too low the observed movement can be caused by dispersal and turbulence during movement.
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<p>The design of the motility assay is a simple one. LB agar Plates are made with the normal amount of LB-broth as nutrients but with a reduced amount of agar.  
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<br>So we decided to use LB agar plates with a concentration of 0.4% of agar. For the reproducibility of the project, it is decided to pipet 13 ml of agar to all of the plates. On every plate 10 &micro;l of liquid culture with an OD<sub>600</sub> of 0.4 is pipetted.  
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<p>Different concentrations are used to find out the optimal amount of agar to show the motility.
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<br>The assay is performed in triplo for each strain and the plates are inoculated for 16 hours. The bacteria that are motile should spread out over the agar creating a cloudy look while the non-motile bacteria should stay at the spot. How quickly the bacteria spread from their spot to the edge can be used as an indicator of how fast they move.  
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Low concentrations are needed to allow movement through the medium but too low and the observed movement can be caused by dispersal and turbulence during movement.  
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The concentrations that are used are, 0.4% agar and 0.7% agar. The plates contained 13 ml agar.
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<p>
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<p>The plates are inoculated in the center with the strain that is to be tested. This is done with 10 ul of liquid culture at an OD<sub>600</sub> of 0.4. The inoculation was done by sticking the pipette in to the agar, injecting the sample in to it, and by injecting the sample on top of the agar.
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<h2>Microscopy</h2>
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<p>For each strain 9 plates of each agar concentration and inoculation method is made. Three of the plates per treatment are placed in a 37&deg;C stove and three placed in a 30&deg;C stove and three placed in a 27&deg;C stove to grow.  
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Pictures were taken with a phase-contrast microscope every second for 2 min with an exposure to white-light of 0,025 seconds.
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<p>The colonies are left to grow for 16 hours. Then how the colonies spread on the plates are observed every hour. The bacteria that are more motile should spread out over the agar creating a cloudy look while the non-motile bacteria should stay in the center, close together.
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<p>How quickly the bacteria spread from the center to the edge can be used as an indicator of how fast they move.  
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<p>
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<h2>To test the <i>cheY</i> and <i>des</i> knockout </h2>
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For our heat motility model we need at least a double knockout strain of <i>B.subtilis</i>. A knockout of both <i>cheY</i> and <i>des</i> are necessary. To obtain the double knockout strain, first a knockout of <i>cheY</i> is made. This is done by transforming the complete genomic DNA of the <i>cheY</i> mutant of Ordal to the <B. subtilis</i> 168 strain [1]. After obtaining this mutant strain, <i>des</i> knockout is inserted.
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<h3>Correct insertion of the <i>des</i> knockout</h3>
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A knockout of gene <i>des</i> is inserted into the genomic DNA of <i>B.subtilis</i> strain 168 with a tetracyclin resistance marker. Colony PCR showed that <i>des</i> is indeed transformed into the genomic DNA (Figure 1).
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<img src="https://static.igem.org/mediawiki/2013/b/b0/DeltaDES.jpg" width="100%"> <!--only insert the link, do not change the percentage!-->
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<font size="1">Figure 1: Colony PCR of the <i>des</i> knock out </font>
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<h3>Motility of the knockout strains</h3>
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To observe whether or not the mutant strains are less motile than the wild type strain. Two different tests are done.
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<h4>Motility assay</h4>
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To compare the motility of the wildtype strain with the two knockout strains, &Delta;cheY and &Delta;cheY&Delta;des, a motility assay is made. All the results obtained from this assay is from an experiment performed in triplo. When the strains are grown on a 0.4% LB agar plate, after 16 hours of growth it is visible that the wildtype strain shows more swimming behaviour than both of the mutant strains (Figure 2). A comparison between the two mutant strains indicates that &Delta;cheY has better swimming behaviour than &Delta;cheY&Delta;des.
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<img src="https://static.igem.org/mediawiki/2013/f/f8/Figure_motility_assay.png" width="100%"> <!--only insert the link, do not change the percentage!-->
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<font size="1">Figure 2: Motility assay results after 16 hours of growth</font>
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<br>When the plates are incubated for 21 hours, it is more distinguishable that the wildtype strain shows more swimming behaviour than the mutant strains. A comparison at two temperatures, 25&deg;C and 37&deg;C, is made. A comparison between the strains at both temperatures shows that the wildtype strain swims better than the &Delta;cheY strain and the &Delta;cheY swims better than the &Delta;cheY&Delta;des strain. It is also visible that cells grow better when they are in a warmer environment (Figure 3).
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<font size="1">Figure 3: Motility assay results after 16 hours of growth at 25&deg;C and 37&deg;C.</font>
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<h4>Microscope movies</h4>
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Another way of analyzing the swimming behaviour is to make microscope movies (4x real time). These movies are made for the wildtype, the &Delta;cheY and the &Delta;cheY&Delta;des strain. These movies show that the wildtype strain (Movie 1) is more motile than both mutant strains. The comparison between the movie of the &Delta;cheY (Movie 2) and &Delta;cheY&Delta;des (Movie 3) strain shows just as seen in the motility assay, that the &Delta;cheY&Delta;des strain is less motile than the &Delta;cheY strain.<p>  
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<br><iframe width="420" height="315" src="//www.youtube.com/embed/vRjSmewTEDc" frameborder="0" allowfullscreen></iframe>
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<br><font size="1">Movie 1: Motility of the wild type strain. A constant flow of cells is visible with cells swimming against/through the stream, indicating for motile bacteria.</font>
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<br><iframe width="420" height="315" src="//www.youtube.com/embed/Seilf16g3OI" frameborder="0" allowfullscreen></iframe>
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<br><font size="1">Movie 2: Motility of &Delta;cheY. A constant flow of cells is visible with one cell tumbling around his own axis on a fixed position. Indicating a non-motile cell.</font>
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<br><iframe width="420" height="315" src="//www.youtube.com/embed/Y_qiqkzbAj8" frameborder="0" allowfullscreen></iframe>
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<br><font size="1">Movie 3: Motility of &Delta;cheY&Delta;des. Cells seem to be non-motile during this time-lapse.</font>
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<br>[1] Rosario, M. M., et al. "Chemotaxis in Bacillus subtilis requires either of two functionally redundant CheW homologs." Journal of bacteriology 176.9 (1994): 2736-2739.
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Latest revision as of 02:01, 5 October 2013

Motility test

Motility assay

To test the difference in motility between the wild type Bacillus subtilis 168 strain and the both knockout strains, ΔcheY and ΔcheYΔdes, a motility test is done.
The plates are inoculated in 25°C and 37°C to determine the different behaviour of the strain at different temperatures, as these are the temperatures we expect changes when the Pdes-cheY construct is inserted into the ΔcheYΔdes strain. In general we expect the wildtype strain to be more motile than the knock out strains. The design we used for our motility assay is a simple one. The LB agar plates are made with the normal amount of LB-broth as nutrient, but with a reduced amount of agar. Low concentrations of agar are needed to allow movement through the medium, but when the concentrations are getting too low the observed movement can be caused by dispersal and turbulence during movement.
So we decided to use LB agar plates with a concentration of 0.4% of agar. For the reproducibility of the project, it is decided to pipet 13 ml of agar to all of the plates. On every plate 10 µl of liquid culture with an OD600 of 0.4 is pipetted.
The assay is performed in triplo for each strain and the plates are inoculated for 16 hours. The bacteria that are motile should spread out over the agar creating a cloudy look while the non-motile bacteria should stay at the spot. How quickly the bacteria spread from their spot to the edge can be used as an indicator of how fast they move.

Microscopy

Pictures were taken with a phase-contrast microscope every second for 2 min with an exposure to white-light of 0,025 seconds.

To test the cheY and des knockout

For our heat motility model we need at least a double knockout strain of B.subtilis. A knockout of both cheY and des are necessary. To obtain the double knockout strain, first a knockout of cheY is made. This is done by transforming the complete genomic DNA of the cheY mutant of Ordal to the 168 strain [1]. After obtaining this mutant strain, des knockout is inserted.

Correct insertion of the des knockout

A knockout of gene des is inserted into the genomic DNA of B.subtilis strain 168 with a tetracyclin resistance marker. Colony PCR showed that des is indeed transformed into the genomic DNA (Figure 1).
Figure 1: Colony PCR of the des knock out

Motility of the knockout strains

To observe whether or not the mutant strains are less motile than the wild type strain. Two different tests are done.

Motility assay

To compare the motility of the wildtype strain with the two knockout strains, ΔcheY and ΔcheYΔdes, a motility assay is made. All the results obtained from this assay is from an experiment performed in triplo. When the strains are grown on a 0.4% LB agar plate, after 16 hours of growth it is visible that the wildtype strain shows more swimming behaviour than both of the mutant strains (Figure 2). A comparison between the two mutant strains indicates that ΔcheY has better swimming behaviour than ΔcheYΔdes.
Figure 2: Motility assay results after 16 hours of growth

When the plates are incubated for 21 hours, it is more distinguishable that the wildtype strain shows more swimming behaviour than the mutant strains. A comparison at two temperatures, 25°C and 37°C, is made. A comparison between the strains at both temperatures shows that the wildtype strain swims better than the ΔcheY strain and the ΔcheY swims better than the ΔcheYΔdes strain. It is also visible that cells grow better when they are in a warmer environment (Figure 3).
Figure 3: Motility assay results after 16 hours of growth at 25°C and 37°C.

Microscope movies

Another way of analyzing the swimming behaviour is to make microscope movies (4x real time). These movies are made for the wildtype, the ΔcheY and the ΔcheYΔdes strain. These movies show that the wildtype strain (Movie 1) is more motile than both mutant strains. The comparison between the movie of the ΔcheY (Movie 2) and ΔcheYΔdes (Movie 3) strain shows just as seen in the motility assay, that the ΔcheYΔdes strain is less motile than the ΔcheY strain.



Movie 1: Motility of the wild type strain. A constant flow of cells is visible with cells swimming against/through the stream, indicating for motile bacteria.

Movie 2: Motility of ΔcheY. A constant flow of cells is visible with one cell tumbling around his own axis on a fixed position. Indicating a non-motile cell.

Movie 3: Motility of ΔcheYΔdes. Cells seem to be non-motile during this time-lapse.


[1] Rosario, M. M., et al. "Chemotaxis in Bacillus subtilis requires either of two functionally redundant CheW homologs." Journal of bacteriology 176.9 (1994): 2736-2739.