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− | <section id="cta" style="background-image:url('https://static.igem.org/mediawiki/2015/0/04/Unitn_pics_slider_5.jpg');"> | + | <section id="cta" class="cta-interlab"> |
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| <span class="rotate-box-icon"><i class="faa flaticon-bacteria"></i></span> | | <span class="rotate-box-icon"><i class="faa flaticon-bacteria"></i></span> |
| </div><br />In-vivo Measurements </h4> | | </div><br />In-vivo Measurements </h4> |
− | <p>The confirmed devices were then transformed in different bacterial strains of <i>E. coli</i>: <span class="i_enph">NEB10β</span>, <span class="i_enph">NEB Express</span>, and <span class="i_enph">JM109</span>. Each measurement was taken at the same optical density to allow a more precise comparison of the data. For each device we have <span class="i_enph">3 biological</span> and <span class="i_enph">3 technical measurements</span> for each used technique. We measured in vivo fluorescence emission in different ways using <b>Tecan Infinite 200 PRO plate reader</b>, <b>Varian Cary Eclipse spectrofluorometer</b>, and <b>BD FACSCanto FACS</b>.</p> | + | <p>The confirmed devices were then transformed in different bacterial strains of <i>E. coli</i>: <span class="i_enph">NEB10β</span>, <span class="i_enph">NEB Express</span>, and <span class="i_enph">JM109</span>. Each measurement was taken at the same optical density to allow a more precise comparison of the data. For each device we have <span class="i_enph">3 biological</span> and <span class="i_enph">3 technical measurements</span> for each used technique. We measured in vivo fluorescence emission in different ways using <b>Tecan Infinite 200 PRO plate reader</b>, <b>Varian Cary Eclipse spectrofluorometer</b>, and <b>BD FACSCanto flow cytometer</b>.</p> |
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| </div><br />In-vitro Measurements </h4> | | </div><br />In-vitro Measurements </h4> |
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− | <p>We also focused on <span class="i_enph">transcription</span> since the characterization is about promoters. To do so we performed RT-qPCR using a <b>BioRad CFX96 Touch™ Real-Time PCR Detection System</b>. Additionally, we performed an <span class="i_enph">in vitro characterization</span> study, by measuring the fluorescence intensities of each device with a <b>Cell-Free <i>E. coli</i> S30 Extract System</b> with a <b>Qiagen Rotor-Gene Q</b>.</p> | + | <p>We also focused on <span class="i_enph">transcription</span> since the characterization is about promoters. To do so we performed RT-qPCR using a <b>BioRad CFX96 Touch™ Real-Time PCR Detection System</b>. Additionally, we performed an <span class="i_enph">in vitro characterization</span> study, by measuring the fluorescence intensities of each device with a <b>Cell-Free <i>E. coli</i> S30 Extract System</b> with a <b>Qiagen Rotor-Gene Q as the spectrofluorometer</b>.</p> |
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| <h3 class="wow fadeInDown">Final Discussion</h3> | | <h3 class="wow fadeInDown">Final Discussion</h3> |
| </header> | | </header> |
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− | <h4 class="header4-resume wow fadeInDown">Our characterization confirmed the relative strength of the promoters</h4>
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− | <p><span class="i_enph">J23101 is the strongest promoter</span> among the three, showing high expression of GFP in all three strains, regardless of the technique used. <span class="i_enph">J23106 is the medium promoter</span>
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− | and <span class="i_enph">J23117 the weakest</span>.</p>
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− | <h4 class="header4-resume wow fadeInDown">Ratios across promoters are kept the same</h4>
| + | <h4 class="header4-resume wow fadeInDown">Our characterization confirmed the relative strength of the promoters</h4> |
− | <p><span class="i_enph">J23101/J23106</span> fluorescence ratios ranged from <span class="i_enph quantity">2.0</span> to <span class="i_enph quantity">4.5</span>, depending on the strain and the technique. Differently from the other two promoters, <span class="i_enph">J23117</span> showed a very low GFP production, as it was <span class="i_enph">not detectable by eye</span> or using the trans-illuminator and showed little fluorescence with the three techniques used.</p>
| + | <p><span class="i_enph">J23101 is the strongest promoter</span> among the three, showing high expression of GFP in all three strains, regardless of the technique used. <span class="i_enph">J23106 is the medium promoter</span> and <span class="i_enph">J23117 the weakest</span>.</p> |
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− | <h4 class="header4-resume wow fadeInDown">Different techniques lead to the same results, with different sensitivities</h4>
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− | <p>The best way to perform a characterization is to <span class="i_enph">use various techniques</span>. Throughout our experiments we saw that each instrument has a specific sensitivity, which alters the output data. The <span class="i_enph">FACS happened to be the most accurate among all</span>, due to its extremely high intrinsic sentivity. The plate reader also showed a good accuracy while the <span class="i_enph">fluorometer was not able to detect the weakest promoter</span> from the background noise, due to its low intrinsic sensitivity. The qPCR and the Cell-Free Extract also gave positive results, in line with our expectations.</p>
| + | <h4 class="header4-resume wow fadeInDown">Ratios across promoters are kept the same</h4> |
− |
| + | <p><span class="i_enph">J23101/J23106</span> fluorescence ratios ranged from <span class="i_enph quantity">2.0</span> to <span class="i_enph quantity">4.5</span>, depending on the strain and the technique. Differently from the other two promoters, <span class="i_enph">J23117</span> showed a very low GFP production, as it was <span class="i_enph">not detectable by eye</span> or using the trans-illuminator and showed little fluorescence with the three techniques used.</p> |
− | <h4 class="header4-resume wow fadeInDown">Bacterial strain does matter</h4>
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− | <p>The three promoters behaved differently in the different bacterial strains used. The bacterial strain which gave the highest fluorescence was <span class="i_enph">NEB10β cells in all cases showed a significant increased expression of the protein</span>, compared to JM109 and NEB Express. We hypothesized this discordance among strains is due to their <span class="i_enph">different genotypes</span>. A different bacterial proteome (i.e. presence/lack of specific proteases and/or chaperonins, polymerases efficiency) may alter protein production, processing and folding, thus fluorescence emission.</p>
| + | <h4 class="header4-resume wow fadeInDown">Different techniques lead to the same results, with different sensitivities</h4> |
− |
| + | <p>The best way to perform a characterization is to <span class="i_enph">use various techniques</span>. Throughout our experiments we saw that each instrument has a specific sensitivity, which alters the output data. The <span class="i_enph">FACS happened to be the most accurate among all</span>, due to its extremely high intrinsic sensitivity. The plate reader also showed a good accuracy while the <span class="i_enph">fluorometer was not able to detect the weakest promoter</span> from the background noise. The use of the qPCR machine as a spectrofluorometer also gave positive results.</p> |
− | <h4 class="header4-resume wow fadeInDown">Looking at promoters from a different angle</h4>
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− | <p>Characterization in vitro using the qPCR allows to <span class="i_enph">quantify the promoter strength by measuring transcript level</span>, rather than just looking at the protein production. This approach gives a <span class="i_enph">better understanding on the promoter`s nature</span>, since it`s well known that the central dogma in biology is not always respected. </p>
| + | <h4 class="header4-resume wow fadeInDown"><i>In vitro</i> conditions mimic the <i>in vivo</i> reality</h4> |
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| + | <p>Comparing the results obtained from the cell-free extract to the others, we discovered that the <span class="i_enph">promoters behave the same when working <i>in vitro</i> or in living bacteria</span>. Since testing constructs in vitro is much faster than in vivo, our results suggest that it may be wise to first screen parts and/or genetic circuitry in vitro. Then the activity of a smaller subset could be confirmed with in vivo measurements.</p> |
− | <h4 class="header4-resume wow fadeInDown"><i>In vitro</i> conditions mimic the <i>in vivo</i> reality</h4>
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− | <p>Comparing the results obtained from the cell-free extract to the others, we discovered that the <span class="i_enph">promoters behave the same when working <i>in vitro</i> or in living bacteria</span>.</p>
| + | <h4 class="header4-resume wow fadeInDown">Looking at promoters from a different angle</h4> |
| + | <p>In vitro characterization by qPCR allows for the <span class="i_enph">quantification of promoter strength by measuring RNA transcript levels</span>, rather than by looking at the concentrations of something one step removed, i.e. protein. This approach gives a <span class="i_enph">a more direct measure of promoter strength</span>.</p> |
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| + | <div class="captionbox" style="max-width:850px; width:80%;"> |
| + | <a class="fancybox" rel="group" href="https://static.igem.org/mediawiki/2015/1/1c/Unitn_pics_interlab_concl1.png" title=""><img src="https://static.igem.org/mediawiki/2015/7/7b/Unitn_pics_interlab_concl2.png" alt="" style="width:100%;"/></a> |
| + | <p class="image_caption"><span> Promoter strength across strains and techniques </span> Values presented are the average of three technical replicates for each of the three biological samples (total of 9 replicates). Data normalized on the maximum expression value of each technique. Heatmap calculated with R Project.</p> |
| + | </div> |
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| + | <br> |
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| + | <h4 class="header4-resume wow fadeInDown">Bacterial strain does matter</h4> |
| + | <p>The three promoters behaved differently in the different bacterial strains used. The bacterial strain which gave the highest fluorescence was <span class="i_enph">NEB10β</span>, which showed significantly increased expression of protein in all cases </span> when compared with JM109 and NEB Express. Clearly this discordance among strains must to be due to their <span class="i_enph">different genotypes</span>. A different bacterial proteome (e.g. presence/lack of specific proteases and/or chaperonins) may alter protein production, processing and folding, and thus fluorescence emission.</p> |
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| + | <div class="captionbox" style="max-width:850px; width:80%;"> |
| + | <a class="fancybox" rel="group" href="https://static.igem.org/mediawiki/2015/7/79/Unitn_pics_interlab_supp2.png" title=""><img src="https://static.igem.org/mediawiki/2015/8/80/Unitn_pics_interlab_supp2_thumb.png" alt="" style="width:100%;"/></a> |
| + | <p class="image_caption"><span> Strain influence on promoters efficiency </span> Values presented are the average of three technical replicates for each of the three biological samples (total of 9 replicates). Data normalized on the the maximum expression value of each technique. Heatmap calculated with R Project.</p> |
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