Team:Imperial College London/Reporters

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<h1>Fluorescent Reporters</h1>
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<h1>Fluorescent reporters</h1>
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<h2>Dendra2</h2>
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<p><i>They can also be used for stunning visual effects.</i></p>
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<p>Fluorescent reporters are an important tool in molecular biology, as they are frequently used to label various intracellular processes. In synthetic biology, fluorescent reporters are often used as the output of a genetic circuit, for example to signal the detection of a chemical.</p>
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<p>As part of our iGEM project, we implemented a new fluorescent reporter, Dendra 2. In addition, we introduced a new coding sequence for superfolder GFP that is codon optimised for E.coli.</p>
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<p>Dendra2 is the first photoconvertible protein that has been introduced into the <a href="http://partsregistry.org/Main_Page">Registry of Standard Biological Parts</a>. When excited with a certain wavelength of light (405 nm or the less cytotoxic 488 nm), the protein is permanently converted from green to red. This interesting property allows it to be used for monitoring a variety of processes. In our experiments, we did preliminary experiments to test the use of Dendra2 to monitor the metabolic viability of our <i>Escherichia coli</i> once they are in the root.</p>
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<img class="border" style="border-color:#B2B2B2;" src="https://static.igem.org/mediawiki/2011/b/b1/ICL_RFP_Culture.png" width=300px/>
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<p><i>A culture of E.coli expressing mRFP.</i></p>
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<p><i>Samples of sfGFP from our thermostability assay. Note the colour change as the temperature increases from left to right.</i></p>
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<p>Each of the fluorescent reporters that we studied was transformed into 5-alpha competent E.coli cells and then grown in large batch culture overnight. The cells were then lysed and the cell debris removed, leaving the protein suspended in 20mM Tris buffer.</p>
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<p>To further characterise these parts, we have conducted a thermostability assay to determine the temperature at which these proteins denature and cease to fluoresce.</p>
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<p style="text-align:center;"><iframe width="560" height="315" src="http://www.youtube.com/embed/dEyfjhkS-gQ?rel=0" frameborder="0" allowfullscreen></iframe></p>
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<p><i>Fig. 1: A time-lapse video shows the conversion of cells in area 1 (cluster of cells in the center of image). The single cell in area 3 (bottom right) serves as a negative control. It was not photoconverted by the laser and therefore continued to absorb light at a lower wavelength and emit green fluorescence. To find out more about this experiment, go to <a href="https://2011.igem.org/Team:Imperial_College_London/Project_Chemotaxis_Testing">Phyto Route testing</a>.
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<p>The protocols can be found in full on our Protocols page, which can be found by clicking on the button below.</p>
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<p style="text-align:right;"><a href="https://2011.igem.org/Team:Imperial_College_London/Protocols_Auxin"><img src="https://static.igem.org/mediawiki/2011/5/58/ICL_ProtocolIconDark.png" width="180px" /></a></p>
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<h3>Dendra 2</h3>
 
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<p>Dendra 2 is a green fluorescent protein that is capable of being irreversibly photoconverted by single-photon stimulation from excitation at 486nm and emission at 505nm wavelength to 558nm excitation and 575nm emission wavelength. This means that its natural state is similar to GFP, but upon photoconversion it can be excited as RFP. Photoconversion can occur using two wavelengths 488 and 405nm (Gurskaya et al., 2006)</p>
 
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<h4>Photoconversion</h4><p><img align="right" class="border" src="" width="100px" height="300px" /></p>
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<img class="border" src="http://farm7.static.flickr.com/6063/6144983986_aa8dbef68d_m.jpg" width=320px />
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<p><i>Fig. 2: Photo of Tim Wilson setting up the FluoroMax-3 machine for the Dendra2 photoconversion experiment.</i></p>
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<iframe width="420" height="315" src="http://www.youtube.com/embed/dXS8v6jhmPI?rel=0" frameborder="0" allowfullscreen></iframe>
 
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<p><i>Video 1:A time-lapse video shows the conversion of cells in area 1. The single cell in area 3 serves as a negative control. It was not bleached by the laser and therefore continued to absorb light at a lower wavelength and emit green fluorescence.</i></p>
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<p> Dendra2 has advantages over non-photoconvertible fluorescent proteins when used to monitor <i>e.g.</i> protein production and promoter characterisation. More accurate promoter characterisation will be possible since one would be able to photoconvert all of the Dendra2 and then measure the synthesis rate from point zero at different OD's.</p>
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<iframe width="420" height="315" src="http://www.youtube.com/embed/EFYe296tu1I?rel=0" frameborder="0" allowfullscreen></iframe>
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<p>From the literature [1] we found out that Dendra2 can be photoconverted using two wavelengths, however one of them (488 nm) is very close to excitation wavelength of green fluorescence (486 nm). Therefore we had to determine if the excitation wavelength (486 nm) for the Dendra2 before photoconversion would cause the Dendra2 to photoconvert. In order to test for that we excited cells with 486 nm & 558 nm wavelengths and measured the fluorescence at the emission  wavelengths 505 nm and 575 nm.</p>
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<p><i>Video 2:A video of another photoconversion of Dendra in E. coli cells that have been taken up into Arabidopsis roots can be seen.</i></p>
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<p><b>How did we photoconvert Dendra 2 whilst exciting and detecting RFP?</b></p>
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<h3>Results for photostability of Dendra2:</h3>
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<img class="border" src="https://static.igem.org/mediawiki/2011/e/e1/ICL_dendra_photostability_%282%29.png" width=880px />
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<p><i>Tim uses his expertise to assist us.</i></p>
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<p><i>Fig. 3:</i></p>
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<p><i>The finished setup.</i></p>
 
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<p>Using a FluoroMax-3 machine, and enlisting the expertise of Tim Wilson, we used Tim's 405nm laser to photoconvert Dendra 2. This was done by aiming the laser into the sample cuvette from above.</p>
 
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<p>So that we could excite Dendra 2 and measure its fluorescence as it was being photoconverted, Tim placed a filter taken from the Gel Imager in front of the detector so that we could detect the fluorescence from Dendra 2 without any interference from the excitation laser</p>
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<p>We found that there was no RFP signal above that of background meaning that imaging the Dendra2 for GFP will not photoconvert the protein.</p>
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<p>Once it was clear that the excitation wavelength does not interfere with the photoconversion wavelength we tested the photoconvertability of the Dendra2. In order to do that we used a FluoroMax-3 machine. Luckily, Tim Wilson was kind enough to help us set up the fluorometer in order to perform our experiments. We found that Dendra2 will fluoresce red upon conversion by light at a wavelength of 405 nm very quickly.</p>  
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<h3>Results of photoconversion experiment:</h3>
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<img class="border" src="https://static.igem.org/mediawiki/2011/9/9a/ICL_dendra_photoconversion.png" width=600px />
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<p><img align="center" class="border" src="https://static.igem.org/mediawiki/2011/9/9a/ICL_dendra_photoconversion.png" width="600px" /></p>
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<p><i>Fig. 3: Results of the photoconversion experiment. Dendra2 is photoconverted with a wavelength of 405nm.</i></p>
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<p>This graph illustrates the photoconversion of Dendra 2. The increase in fluorescence at 575nm indicates that Dendra 2 begins to fluoresce red upon conversion by light at a wavelength of 405nm. This also shows that the conversion is very rapid, which lends itself well to in vivo use as a fluorescent reporter.</p>
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<h4>Thermostability</h4>
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<h2>Thermostability assay</h2>
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<p><img align="center" class="border" src="https://static.igem.org/mediawiki/2011/a/a2/DendraCurve.png" width="600px" /></p>
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<p>Fluorescent reporters are an important tool in synthetic biology that are often used as the output of a genetic circuit.</p>
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<p>As part of our iGEM project, we implemented a new fluorescent reporter, Dendra2. In addition, we introduced a new coding sequence for superfolder GFP (sfGFP) that is codon-optimised for <i>E. coli</i>. These were both used as part of our imaging experiments of bacteria inside plant roots. sfGFP was also used in our soil experiments to label our bacteria so that we could later identify them.</p>
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<p>sfGFP and mRFP were also used in our assembly strategy for the Gene Guard module. sfGFP was part of the construct of our CRIM plasmid, and would be used as a reporter to evaluate the level of expression of anti-holin. mRFP formed part of the plasmid construct of the Gene Guard and this would be used to measure the expression of holin and endolysin. The mRFP would also be used to track the transmission of the plasmid in subsequent conjugation assays that would be carried out to test the effectiveness of the Gene Guard.</p>
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<p>Since we ended up working with so many fluorescent reporters during our project, we decided to further characterize these important BioBricks. An important characteristic that has been omitted from the registry page is the thermostability of these proteins. This is an important aspect when choosing a fluorescent protein for a thermophile.</p>
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<p>To characterise these parts, we determined the temperature at which these proteins denature and cease to fluoresce. The data was collected in two overlapping sets, ranging from 35°C to 66°C, and from 57°C to 96°C. This was because it was only possible to fit a maximum of eight samples into the thermocycler at once.</p>
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<p>Once the data was collected by taking fluorescence readings from a 96-well plate, it was normalised to a sample of untreated cell lysate containing the fluorescent protein. This gave a value for Relative Fluorescence, which was plotted against temperature to create a scatter plot. A line of best fit was applied, and the mid point of the sigmoid region of the line was taken as the denaturation point of the protein.</p>
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<h3>Superfolder GFP</h3><p><img align="right" class="border" src="https://static.igem.org/mediawiki/2011/6/60/ICL_sfGFP_PURE.png" width="100px" height="300px" /></p>
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<p>This is a variant of GFP that has been engineered to be faster folding so that it can be used for tagging proteins more efficiently. The variant that we're submitting to the registry has been codon optimised for E.coli.</p>
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<img class="border" src="https://static.igem.org/mediawiki/2011/f/f8/ICL_Heat_Denaturation_Curve_of_Fluorescent_Proteins.png" width=700px />
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<h4>Thermostability</h4>
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<p><i>Fig. 4: Results of the heat denaturation experiment. The temperature at which half of the protein is denatured measured by looking at its fluorescence (PTm50) mRFP1: 92.3°C; GFPmut3b: 59.1°C; Dendra2: 83.7°C; sfGFP: 75.3°C.</i></p>
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<p><img align="center" class="border" src="https://static.igem.org/mediawiki/2011/b/ba/SfGFPCurve.png" width="600px" /></p>
 
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<p>From the midpoint of the sigmoidal curve, we can find the point at which half of the protein is denatured. For sfGFP, that point occurs at 78°C.</p>
 
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<h3>References:</h3>
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<h3>GFP</h3><p><img align="right" class="border" src="https://static.igem.org/mediawiki/2011/f/f1/ICL_GFP_PURE.png" width="100px" height="300px" /></p>
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<p>[1] Gurskaya, N.G. et al, (2006) Engineering of a monomeric green-to-red photoactivatable fluorescent protein induced by blue light. Nat Biotech, 24(4), pp.461-465.
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<p>This GFP expression sequence is BioBrick BBa_I13522, from the Standard Registry of Biological Parts. This is a GFP coding sequence under the control of a pTet promoter. This was taken from the registry distribution and transformed into competent E.coli cells.</p>
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<p>This helped to form the part of our project that required the re-categorisation of existing BioBricks as we carried out a thermostability assay.</p>
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<h4>Thermostability</h4>
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<h3>mRFP</h3><p><img align="right" class="border" src="https://static.igem.org/mediawiki/2011/7/7a/ICL_RFP_PURE.png" width="100px" height="300px" /></p>
 
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<p>mRFP is a monomeric form of Red Fluorescent Protein, and the expression sequence that we used to obtain our samples is BioBrick BBa_I13521 from the Registry. This is a composite part made up of the coding sequence for mRFP under the control of a pTet promoter. This was taken from the registry distribution and transformed into competent E.coli cells.</p>
 
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<p>We carried out a thermostability assay on mRFP in order to add the data to the registry data sheet.</p>
 
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<h4>Thermostability</h4>
 
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<h3>CFP</h3><p><img align="right" class="border" src="https://static.igem.org/mediawiki/2011/8/86/ICL_CFP_PURE.png" width="100px" height="300px" /></p>
 
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<p>CFP, or Cyan Fluorescent Protein, was taken from the registry as composite BioBrick BBa_I13600. This is the coding sequence for CFP under the control of a pTet promoter. This will </p>
 
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Latest revision as of 00:04, 21 September 2011




Fluorescent reporters


Dendra2

Dendra2 is the first photoconvertible protein that has been introduced into the Registry of Standard Biological Parts. When excited with a certain wavelength of light (405 nm or the less cytotoxic 488 nm), the protein is permanently converted from green to red. This interesting property allows it to be used for monitoring a variety of processes. In our experiments, we did preliminary experiments to test the use of Dendra2 to monitor the metabolic viability of our Escherichia coli once they are in the root.

Fig. 1: A time-lapse video shows the conversion of cells in area 1 (cluster of cells in the center of image). The single cell in area 3 (bottom right) serves as a negative control. It was not photoconverted by the laser and therefore continued to absorb light at a lower wavelength and emit green fluorescence. To find out more about this experiment, go to Phyto Route testing.


Fig. 2: Photo of Tim Wilson setting up the FluoroMax-3 machine for the Dendra2 photoconversion experiment.

Dendra2 has advantages over non-photoconvertible fluorescent proteins when used to monitor e.g. protein production and promoter characterisation. More accurate promoter characterisation will be possible since one would be able to photoconvert all of the Dendra2 and then measure the synthesis rate from point zero at different OD's.

From the literature [1] we found out that Dendra2 can be photoconverted using two wavelengths, however one of them (488 nm) is very close to excitation wavelength of green fluorescence (486 nm). Therefore we had to determine if the excitation wavelength (486 nm) for the Dendra2 before photoconversion would cause the Dendra2 to photoconvert. In order to test for that we excited cells with 486 nm & 558 nm wavelengths and measured the fluorescence at the emission wavelengths 505 nm and 575 nm.




Results for photostability of Dendra2:

Fig. 3:

We found that there was no RFP signal above that of background meaning that imaging the Dendra2 for GFP will not photoconvert the protein.

Once it was clear that the excitation wavelength does not interfere with the photoconversion wavelength we tested the photoconvertability of the Dendra2. In order to do that we used a FluoroMax-3 machine. Luckily, Tim Wilson was kind enough to help us set up the fluorometer in order to perform our experiments. We found that Dendra2 will fluoresce red upon conversion by light at a wavelength of 405 nm very quickly.

Results of photoconversion experiment:


Fig. 3: Results of the photoconversion experiment. Dendra2 is photoconverted with a wavelength of 405nm.

Thermostability assay

Fluorescent reporters are an important tool in synthetic biology that are often used as the output of a genetic circuit.

As part of our iGEM project, we implemented a new fluorescent reporter, Dendra2. In addition, we introduced a new coding sequence for superfolder GFP (sfGFP) that is codon-optimised for E. coli. These were both used as part of our imaging experiments of bacteria inside plant roots. sfGFP was also used in our soil experiments to label our bacteria so that we could later identify them.

sfGFP and mRFP were also used in our assembly strategy for the Gene Guard module. sfGFP was part of the construct of our CRIM plasmid, and would be used as a reporter to evaluate the level of expression of anti-holin. mRFP formed part of the plasmid construct of the Gene Guard and this would be used to measure the expression of holin and endolysin. The mRFP would also be used to track the transmission of the plasmid in subsequent conjugation assays that would be carried out to test the effectiveness of the Gene Guard.

Since we ended up working with so many fluorescent reporters during our project, we decided to further characterize these important BioBricks. An important characteristic that has been omitted from the registry page is the thermostability of these proteins. This is an important aspect when choosing a fluorescent protein for a thermophile.

To characterise these parts, we determined the temperature at which these proteins denature and cease to fluoresce. The data was collected in two overlapping sets, ranging from 35°C to 66°C, and from 57°C to 96°C. This was because it was only possible to fit a maximum of eight samples into the thermocycler at once.

Once the data was collected by taking fluorescence readings from a 96-well plate, it was normalised to a sample of untreated cell lysate containing the fluorescent protein. This gave a value for Relative Fluorescence, which was plotted against temperature to create a scatter plot. A line of best fit was applied, and the mid point of the sigmoid region of the line was taken as the denaturation point of the protein.

Fig. 4: Results of the heat denaturation experiment. The temperature at which half of the protein is denatured measured by looking at its fluorescence (PTm50) mRFP1: 92.3°C; GFPmut3b: 59.1°C; Dendra2: 83.7°C; sfGFP: 75.3°C.

References:

[1] Gurskaya, N.G. et al, (2006) Engineering of a monomeric green-to-red photoactivatable fluorescent protein induced by blue light. Nat Biotech, 24(4), pp.461-465. <>