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| <!-- Head End --> | | <!-- Head End --> |
| <!-- Content Begin --> | | <!-- Content Begin --> |
− | <img id="TopPicture" width="960" src="https://static.igem.org/mediawiki/2017/b/be/T--Munich--FrontPagePictures_Attributions.jpg"> | + | <img id="TopPicture" width="960" src="https://static.igem.org/mediawiki/2017/0/04/T--Munich--FrontPagePictrues_FinalResults.jpg"> |
| <table width="960" border=0 cellspacing=0 cellpadding=10> | | <table width="960" border=0 cellspacing=0 cellpadding=10> |
| <tr> | | <tr> |
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| <td width=160></td> | | <td width=160></td> |
| <td width=160></td> | | <td width=160></td> |
− | </tr>
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− | <tr><td colspan=6 align=left valign=center>
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− | <font size=7 color=#51a7f9><b style="color: #51a7f9">Results</b></font>
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− | </td>
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| </tr> | | </tr> |
| <tr> | | <tr> |
− | <td colspan = 6 align="left"> | + | <td style="background-color: #51a7f9;" colspan = 6 align="left"> |
− | <p class="introduction">
| + | <ul class="menuList" id="menu"> |
− | </p>
| + | <li><a href="/Team:Munich/Results">Overview</a></li> |
| + | <li><a href="/Team:Munich/Cas13a">Cas13a</a></li> |
| + | <li><a href="/Team:Munich/Readouts">Readouts</a></li> |
| + | <li><a href="/Team:Munich/Targets">Targets</a></li> |
| + | <li><a href="/Team:Munich/DetectionOnChip">Detection Chip</a></li> |
| + | <li><a href="/Team:Munich/Amplification">Amplification</a></li> |
| + | |
| + | </ul> |
| | | |
| </td> | | </td> |
| </tr> | | </tr> |
− | | + | <tr><td colspan=6 align=left valign=center> |
− | | + | <div style="margin-top: 40px"><font size=7 color=#51a7f9><b style="color: #51a7f9">Final Results</b></font></div> |
− | | + | |
− | | + | |
− | | + | |
− | | + | |
− | <tr><td colspan=6 align=center valign=center> | + | |
− | <h3>Bacterial targets used for the experiments</h3>
| + | |
− | <h4><i>Escherichia coli</i></h4>
| + | |
− | <p>
| + | |
− | We took 16s rRNA of the <i> E. coli </i> as our target RNA. Since 16s rRNA is highly conserved in all bacterial species and can used as a well characterized site for our cleavage assays. It can also be easily extracted from bacterial cultures. For our experiments, we used only a part of the 16s rRNA since the whole 16s rRNA is too large to be transcribed (1500 bp). For this particular target RNA sequence we took, we designed the crRNA and <i> in vitro </i> transcribed the crRNA and the target RNA in our lab. We also performed RNA extraction using chemical lysis and heat lysis for the <i> E. coli </i> samples. Although the chemical lysis gave us good quality and detectable concentration of the RNA, the heat lysis didn’t work so well. There was always some cellular residues, RNases present in the sample due to which the fluorescence activity in the cleavage assay was way higher than the positive controls.</p>
| + | |
− | <div class="captionPicture"> | + | |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg"> | + | |
− | <p>16s rRNA part used for the experiment</p> | + | |
− | </div>
| + | |
− | <div class="captionPicture">
| + | |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| + | |
− | <p>Figure 1: Gel picture showing the our 16s rRNA partial sequence used for our experiments</p>
| + | |
− | </div> | + | |
− | <div class="captionPicture">
| + | |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| + | |
− | <p>Figure 2: Urea gel picture of the different crRNAs</p>
| + | |
− | </div> | + | |
| </td> | | </td> |
| </tr> | | </tr> |
| | | |
− | <tr><td colspan=6 align=center valign=center>
| + | |
− | <h4><i>Bacillus subtilis</i></h4>
| + | |
− | <p>
| + | |
− | We also focused on trying out our experiment with other target RNAs and for this we chose the gram positive <i> Bacillus subtilis </i> since it is widely used in microbiological research. Plus we wanted to see if one can detect the difference between the 16s rRNAs of <i> B. subtilis </i>and <i> E. coli </i>. For <i> B. subtilis </i> , we did not perform any <i> in vitro </i> transcription, rather we directly used the bacterial culture for the RNA extraction. However, we did encounter some problems due to the spore forming nature of the <i> Bacillus subtilis </i>. Also, the quality of the extracted RNA was not so good and there were some cellular residues apart from the RNA which caused some problems during the assay.
| + | |
− | </p>
| + | |
− | <div class="captionPicture">
| + | |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| + | |
− | <p>crRNA designed for the <i> Bacillus subtilis </i> 16s RNA</p>
| + | |
− | </div>
| + | |
− | </td>
| + | |
− | </tr>
| + | |
| | | |
| <tr><td colspan=6 align=center valign=center> | | <tr><td colspan=6 align=center valign=center> |
− | <h3>Viral targets used for the experiments</h3> | + | <h1>Overview</h1> |
− | <h4>Noro virus</h4>
| + | |
| <p> | | <p> |
− | Noro virus originally called Norwalk virus, of the family Caliciviridae, is one of the major cause of viral gastroenteritis in humans and it affects patients of all age groups. It is also the cause of high rate of deaths and is associated with hospital infections. For our experiments, we took the 5’ UTR of the Noro virus and also did <i> in vitro </i> transcription to get the target RNA and the crRNA. The 5’ UTR of the viruses are very specific to each individual virus so one can use this part to design the crRNA and detect different viral RNAs using the Cas13a system.
| + | We successfully designed, constructed and characterized each module of our platform: the sample processing, the readout circuit, and the detection of pathogens. <br> |
| + | Although did not fully integrate all parts together in the time frame of our project, we could connect each unit to the next, so that we are confident that our entire platform is functional. For example, we could achieve equally sensitive bulk detection of pathogen RNA from <i>in vitro</i> and <i>in vivo</i> sources, and were later able to detect <i>in vitro</i> RNA with lyophilized Cas13a on paper, therefore we believe RNA from lysed cells can be detected on paper. In this overview, we list our achievements and where we faced issues, and we present a summary of the characterization of each module in the sub-pages. |
| </p> | | </p> |
| <div class="captionPicture"> | | <div class="captionPicture"> |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg"> | + | <img width=600 src="https://static.igem.org/mediawiki/2017/9/9a/T--Munich--Overview_Diagram_Results.png"> |
− | <p>crRNA designed for the Noro virus </p> | + | <p> |
− | </div>
| + | Our modular units and the integration between them are mostly validated. Green ticks indicated full validation, yellow ticks indicated partial validation. |
− | </td>
| + | |
− | </tr>
| + | |
− | | + | |
− | <tr><td colspan=6 align=center valign=center>
| + | |
− | <h4>Hepatitis C virus</h4>
| + | |
− | <p>
| + | |
− | HCV is a small single stranded RNA virus of family Flaviviridae which is the major cause of the Hepatitis C and liver cancer. Common setting for transmission of HCV is also intra-hospital (nosocomial) transmission, when practices of hygiene and sterilization are not correctly followed in the clinic. There are no vaccines for HCV virus. For our experiments, we took the 5’ UTR of the HCV virus and also did <i> in vitro </i> transcription to get the target RNA and the crRNA.
| + | |
| </p> | | </p> |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>crRNA designed for the HCV virus </p>
| |
| </div> | | </div> |
− | <div class="captionPicture"> | + | <h3>What worked</h3> |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg"> | + | <ul class="listResults"> |
− | <p>Gel picture</p> | + | <li><a href="/Team:Munich/Cas13a">Demonstrated the functionality of Cas13a proteins, namely Lbu and Lwa.</a></li> |
− | </div> | + | <li><a href="/Team:Munich/Detection">Constructed a functional fluorescence detector with high sensitivity and low production cost.</a></li> |
− | </td> | + | <li><a href="/Team:Munich/Cas13a">Modeled the detection limit of our circuit and confirmed it experimentally (~10 nM RNA).</a></li> |
− | </tr> | + | <li><a href="/Team:Munich/Cas13a">Detected pathogen RNA sequence from <i> in vitro </i> and <i> in vivo </i> sources.</a></li> |
− | | + | <li><a href="/Team:Munich/Targets">Differentiated viral sequences from bacterial sequences.</a></li> |
− | <tr><td colspan=6 align=center valign=center> | + | <li><a href="/Team:Munich/Readouts">Used the RNase Alert and the Spinach aptamer fluorescence readout circuits.</a></li> |
− | <h3>Cas13a strains used for the experiments</h3> | + | <li><a href="/Team:Munich/Readouts">Used gold nanoparticles to detect general RNase activity.</a></li> |
− | <p> | + | <li><a href="/Team:Munich/Cas13a">Detected pathogen RNA in bulk and on paper, from native and from lyophilized Cas13a.</a></li> |
− | The genus Leptotrichia was one of the first microorganisms to be drawn and described by the Antoni van Leeuwenhoek. The generic name was first used in 1879 for filamentous organisms found in the human mouth. We used the following strains of Cas13a for our experiments.
| + | <li><a href="/Team:Munich/Amplification">Amplified isothermally a target DNA from <i>in vitro</i> and <i>in vivo</i> sources.</a></li> |
− | </p> | + | <li><a href="/Team:Munich/Amplification">Combined isothermal DNA amplification and RNA transcription on paper, producing detectable concentrations of a pathogen RNA.</a></li> |
− | <ul style="text-align:left">
| + | <li><a href="/Team:Munich/Parts">Improved the biobrick BBa_K1319008 by adding a 6x His-tag and provided Cas13a Lwa as three different composite biobricks.</a></li> |
− | <li><i>Leptotrichia buccalis</i> (referred as Lbu in our experiments)</li>
| + | <li><a href="/Team:Munich/Parts">Created and characterized a Lwa Cas13a coding sequence, submitted as BioBrick.</a></li> |
− | <li><i>Leptotrichia wadei</i> (referred as Lwa in our experiments)</li>
| + | <li><a href="/Team:Munich/Part_Collection">Created and characterized a collection of degradation tags, submitted as BioBricks.</a></li> |
− | <li><i>Leptotrichia shahii</i> (referred as Lsh in our experiments)</li>
| + | |
| </ul> | | </ul> |
− | </td>
| |
− | </tr>
| |
− |
| |
| <tr> | | <tr> |
− | <td colspan=4 align=center valign=center> | + | <td align=center valign=center colspan=6> |
− | <p>We expressed our His-tagged proteins in <i>E. coli</i> strains and purified them using a Äkta purification system or Ni-NTA agarose. To cleave off the His-SUMO or His-MBP tags from Cas13a proteins, we incubated them with the SUMO or TEV protease <a class="myLink" href="http://parts.igem.org/Part:BBa_K2323002">(BBa_K2323002)</a> during dialysis overnight, respectively. In some cases, we reloaded the cleaved protein solution again on Ni-NTA agarose to get rid of the thereby binding His-tag. For higher purity, we loaded the proteins on a size exclusion column. Protein purity was always checked by SDS PAGE. </p>
| + | |
− | <p>
| + | |
− | Both the Cas13a Lbu and Lwa are the central component of our diagnostic platform. The TEV Protease is part of our idea to the Intein-Extein readout, but apart from that, served as molecular tool for cleaving off the protein tags. So far, we managed to express and purify all three mentioned Cas13a proteins and the TEV protease as you can see in following chromatograms and SDS gels.
| + | |
− | </p>
| + | |
− | </td>
| + | |
− | <td colspan=2 align=center valing=center>
| + | |
| <div class="captionPicture"> | | <div class="captionPicture"> |
− | <img src="https://static.igem.org/mediawiki/2017/0/04/T--Munich--Description_Cas13a_Mechanism.svg" alt="Diagram for Cas13a's function"> | + | <img width=800 src="https://static.igem.org/mediawiki/2017/5/53/T--Munich--Results_Hardwaretime151.png"> |
− | <p>Cas13a 3D structure</p> | + | <p>Detection of a sequence from <i>E. coli</i> 16S rRNA from Cas13a on paper in our self-built detector</p> |
| </div> | | </div> |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td align=center valign=center colspan=3>
| |
− | <h4>Äkta purification</h4>
| |
− | <div class="captionPicture">
| |
− | <img width=300 src="https://static.igem.org/mediawiki/2017/c/c1/T--Munich--Improve_TEV_SEC.svg">
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− | <p>
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− | His purification Äkta graph Lbu plus gel
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− | </p>
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− | </div>
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− | </td>
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− | <td align=center valign=center colspan=3>
| |
− | <div class="captionPicture">
| |
− | <img width=300 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | His purification Äkta graph Lbu plus gel
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− | </p>
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− | </div>
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− | </td>
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− | </tr>
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− |
| |
− | <tr><td colspan=6 align=center valign=center>
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− | <h4>Nickel NTA purification of Lwa</h4>
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− | <p>
| |
− | HCV is a small single stranded RNA virus of family Flaviviridae which is the major cause of the Hepatitis C and liver cancer. Common setting for transmission of HCV is also intra-hospital (nosocomial) transmission, when practices of hygiene and sterilization are not correctly followed in the clinic. There are no vaccines for HCV virus. For our experiments, we took the 5’ UTR of the HCV virus and also did <i> in vitro </i> transcription to get the target RNA and the crRNA.
| |
− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
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− | <p>Lwa gel from ni nta</p>
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− | </div>
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− | </td>
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− | </tr>
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− |
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− |
| |
− | <tr><td align=center valign=center colspan=3>
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− | <h4>Size exclusion purification</h4>
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− | <div class="captionPicture">
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− | <img width=300 src="https://static.igem.org/mediawiki/2017/c/c1/T--Munich--Improve_TEV_SEC.svg">
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− | <p>
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− | SEC purification Lbu plus gel
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− | </p>
| |
− | </div>
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− | </td>
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− | <td align=center valign=center colspan=3>
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− | <div class="captionPicture">
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− | <img width=300 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | SEC purification Lsh plus gel
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− | </p>
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− | </div>
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− | </td>
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− | </tr>
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− |
| |
− | <tr><td align=center valign=center colspan=4>
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− | <h4>Affinity purification and Size exclusion purification of TEV protease</h4>
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− | <div class="captionPicture">
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− | <img width=620 src="https://static.igem.org/mediawiki/2017/c/c1/T--Munich--Improve_TEV_SEC.svg">
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− | <p>
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− | His purification TEV
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− | </p>
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− | </div>
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− | </td>
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− | <td align=center valign=center colspan=2>
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− | <div class="captionPicture">
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− | <img width=300 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | Gel #1
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− | </p>
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− | </div>
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− | <div class="captionPicture">
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− | <img width=300 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | Gel #2
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− | </p>
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− | </div>
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− | </td>
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− | </tr>
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− |
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− | <tr><td colspan=6 align=center valign=center>
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− | <h3>Assays used for the experiments</h3>
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− | <p>
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− | For our experimental design, we used different fluorescence assays as stated below:
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− | </p>
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− | </td>
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− | </tr>
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− |
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− | <tr><td colspan=3 align=center valign=center>
| |
− | <h4>RNaseAlert Assay</h4>
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− | <p>
| |
− | This is a commercial kit readily available in the markets, which can be used for the detection of the RNase activity and sensitivity in real time. The RNaseAlert® QC System uses a novel RNA substrate tagged with a fluorescent reporter molecule (fluor) on one end and a quencher on the other. In the absence of RNases, the physical proximity of the quencher dampens fluorescence from the Fluor to extremely low levels. When RNases are present, however, the RNA substrate is cleaved, and the Fluor and quencher are spatially separated in solution. This causes the Fluor to emit a bright green signal when excited by light of the appropriate wavelength. Since the fluorescence of the RNaseAlert substrate increases over time when RNase activity is present, results can be easily monitored. For the detection and monitoring of the kinetics of the fluorescence, we used the plate readers in lab and our self-made fluorescence detector.
| |
− | </p>
| |
− | </td>
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− | <td colspan=3 align=center valing=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | RNAase alert
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− | </p>
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− | </div>
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− | </td>
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− | </tr>
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− |
| |
− | <tr><td colspan=3 align=center valign=center>
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− | <div class="captionPicture">
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− | <img width=460 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | Lightbringer
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− | </p>
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− | </div>
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− | </td>
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− | <td colspan=3 align=center valing=center>
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− | <div class="captionPicture">
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− | <img width=460 src="https://static.igem.org/mediawiki/2017/f/f1/T--Munich--Improve_TEV_SEC_SDS.png">
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− | <p>
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− | Clariostar
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− | </p>
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− | </div>
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− | </td>
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− | </tr>
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− |
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− | <tr><td colspan=6 align=center valign=center>
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− | <h4>Spinach Aptamer Assay</h4>
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− | <p>
| |
− | The spinach aptamer assay is based on a fluorophore DMHBI which was the first molecule against which a SELEX experiment was run. However, DFHBI was extracted from eGFP and it exhibits a higher extinction coefficient and lead to a brightness increase of eGFP. In 2012, Paige et al. developed the 24-2 aptamer, mostly known as Spinach due its green fluorescence when bound to DFHBI. The Spinach aptamer exclusively binds the deprotonated variant of eGFP (DFHBI) with a dissociation constant of Kd = 390nM. It increases the quantum yield of DFHBI from 0.0007 when free to 0.72 when bound to the aptamer.
| |
− | Figure (a) Structure of the Spinach aptamer in absence (yellow) and in presence (green) of DFHBI. (b) G-quadruplex motif of the Spinach aptamer in absence (yellow) and in presence (green) of DFHBI.
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− | </p>
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− | <div class="captionPicture">
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− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
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− | <p>Aptamer</p>
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− | </div>
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− | <p>
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− | The aptamer structure is elongated and it folds with two helical stems adjacent to the binding region, which exhibits a G-quadruplex pattern. The Spinach aptamer binds the DFHBI in a planar conformation. Hydrogen bonds are formed between the G-nucleotides and the fluorophore, and the aptamer changes its 3d-structure when bound to the DFHBI. In the absence of the fluorophore, the base triplet formed by the nucleotides A53-U29-A58 collapses on the G-quadruplex site. Spinach shifts the absorbance maximum of the DFHBI by approximately 60 nm comparing with the unbound form, from 405 nm to 469 nm. Spinach has been used for imaging protein and gene expression, and it has been also modified in order to be used as a sensor of biological reactions.
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− | </p>
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− | </td>
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− | </tr>
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− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3>Proof of principle</h3>
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− | <p>
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− | To characterize key protein of our diagnostic device we conducted several experiments.
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− | </p>
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− | <p>
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− | Firstly, we confirmed that Cas13a activity is target dependent. Despite the fact that Cas13a exhibits RNase activity in absence of target RNA, its activity in presence of target RNA is up to 8 times higher. However, this is true at low protein concentrations. At high concentrations of Cas13a presence of target RNA does not have significant effect on enzyme activity as depicted in the Figure 3. Secondly, we verified that enzyme is activated by crRNA. As Figure 4 (this is the only figure with old enzyme, so concentrations are completely off the values of enzyme purified and used later on) shows, enzyme is active only in the presence of crRNA. It can be seen the higher is the concentration of crRNA, the more of enzyme gets activated, which is in accordance with the first step of reaction --link to overall reaction equation--. Besides that, crRNA when forming a complex with Cas13a defines specificity of ribonuclease. This was confirmed by cross-reactivity experiment.
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− | </p>
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− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
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− | <p>please place results of cross-reactivity experiment here</p>
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− | </div>
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− | <p>
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− | And most importantly we determined detection limit of Cas13a-crRNA complex by varying target RNA concentration. Figure 2 shows that target concentrations above two-digits in nanomolar range can be detected.
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− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>1</p>
| |
− | </div>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>2</p>
| |
− | </div>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>3</p>
| |
− | </div>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>4</p>
| |
− | </div>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>5</p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <h3>Crosstalk experiments</h3>
| |
− | <p>
| |
− | To show that the Cas13a is highly specific for a particular target, we tested the CRISPR RNA designed for Noro virus with different targets, namely <i> E. coli </i>, HCV and Noro virus. As observed in the bar graph on the right, the Cas13a activity is visible only there is the presence of the target as Noro virus itself. Whereas in presence of other targets there is very low background fluorescence visible, which is also measurable when no target is present. The results observed showed that there is no crosstalk between the targets and that a particular crRNA is specific for one type of target RNA only. With this we can confirm that our system CascAID can be efficiently used to differentiate different viral and bacterial target RNAs.
| |
− | </p>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=420 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>Bar graph </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3><i>In vivo</i> (chemical lysis)</h3>
| |
− | <p>
| |
− | After the successful experiments with the <i> in vitro </i> transcribed target RNA from E.coli, we decided to extract the 16s RNA from the <i> E.coli </i> culture in the lab and to perform the same RNaseAlert assays with the extracted RNA. At first, we used the chemical lysis using SDS plus heat followed by phenol chloroform purification. However, there was presence of some RNases in the extracted RNA which led to higher fluorescence activity of the RNaseAlert in presence of Cas13a. Therefore, we took the extracted RNA and then conducted a serial dilution to use them for our experimental setup. The extracted target RNA was 40 x concentrated.
| |
− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg">
| |
− | <p>Graph </p>
| |
− | </div>
| |
− | <p>
| |
− | As shown in the graph above, the level of fluorescence activity increases with the increasing target concentration which again verifies the activity and the sensitivity of the Cas13a. Since the RNA was extracted directly from the <i> E. coli </i> culture, we can say that the Cas13a can be easily manipulated to be used not only for <i> in vitro </i> samples but also for <i> in vivo </i> samples, which makes it even more suitable for practical uses.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3>Paperstrips</h3>
| |
− | <p>
| |
− | After the implementation of the working principle of the Cas13a to detect different targets in the plate reader, we decided to go further and do the same experiment by adding the samples to the glass fiber filter paper. We used overnight BSA treated glass fiber filter paper, which was then dried for 20-30 mins at 70C before pipetting the reaction mix. For this, we 3D printed a 96 well plate with 2 upper and lower parts which was suited for placing the paper in between the parts.
| |
− | </p>
| |
| </td> | | </td> |
| </tr> | | </tr> |
| | | |
| <tr> | | <tr> |
− | <td colspan=3 align=center valign=center> | + | <td align=center valign=center colspan=6> |
− | <div class="captionPicture"> | + | <h3>What presented issues</h3> |
− | <img width=420 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg"> | + | <ul class="listResults"> |
− | <p>Graph #1</p> | + | <li><a href="/Team:Munich/Cas13a">Optimizing the purification protocol for Cas13a.</a></li> |
− | </div> | + | <li><a href="/Team:Munich/Cas13a">Demonstrating functionality of Lsh Cas13a.</a></li> |
− | </td> | + | <li><a href="/Team:Munich/Cas13a">Ruling out RNase contamination from heat-lysed <i>in vivo</i> samples.</a></li> |
− | <td colspan=3 align=center valign=center> | + | <li><a href="/Team:Munich/Targets">Detecting <i>Qbeta</i> RNA.</a></li> |
− | <div class="captionPicture"> | + | <li><a href="/Team:Munich/Readouts">Developing colorimetric read-outs.</a></li> |
− | <img width=420 src="https://static.igem.org/mediawiki/2017/3/36/T--Munich--PlateReader.jpg"> | + | <li><a href="/Team:Munich/Detection">Optimizing the lyophilization and stability of Cas13a.</a></li> |
− | <p>Graph #1</p> | + | <li><a href="/Team:Munich/Amplification">Amplifying long sequences with RPA.</a></li> |
− | </div> | + | </ul> |
| </td> | | </td> |
| </tr> | | </tr> |
| | | |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <p>
| |
− | The first figure shown above shows that even in the paper, we can observe the increasing amount of fluorescence with the increasing target concentration. The second linear graph which is time plot showing the amount of fluorescence released, also shows that we can the Cas13a system on the paper to detect the fluorescence activity. Both graphs above thus prove that the Cas13a can be used as an efficient system that can be integrated into the paper for the simple lab on chip detection of viral and bacterial infections.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
| | | |
| <tr><td colspan=6 align=center valign=center> | | <tr><td colspan=6 align=center valign=center> |
− | <h3>Hardware</h3> | + | <h1>Discussion</h1> |
− | <p> | + | <p> |
− | We also designed a simple fluorescence reader with an exchangeable paper-based chip during our project, targeting the areas which do not access to advanced and space consuming machines. We basically tried it out with the Fluorescein in the beginning to see how far could we go with our detection limit. Then we worked on optimizing the device conditions and we could measure concentrations down to 100 nM. Finally, we tried our experimental setting of plate reader on to the fluorescence detector that we assembled along with the positive control containing RNase A and negative control containing RNase inhibitor only.
| + | Our project CascAID is a universal solution for low cost, point of care diagnostics of infectious diseases. Currently, the available diagnostic tools are based on PCR, antibodies or microbiological methods which all need trained personal and lab equipment. Therefore, these methods are cost and time consuming. This gives rise to the need of developing effective, affordable and portable devices.</p><p> |
− | From the given graph, it is clearly visible that we can measure the fluorescence activity of the RNaseAlert substrate over time in the presence of Cas13a using our simple fluorescence detector with a paper based chip. This also shows that our CascAID system has can be developed further for a wide scale production.
| + | In our project, we first successfully replicated the Cas13a-based detection of RNA pathogens that was demonstrated by Gootenberg et al. (2017). We thoroughly characterized the target detection limit for different bacterial and viral targets, from <i> in vitro </i> and <i> in vivo </i> sources, and proved the possibility to discriminate between viruses and bacteria with high specificity. We found that our detection circuit worked robustly across experimental conditions and experimenters, which proves that the readout is adapted for distribution and handling by non-trained users. <br> |
| + | We laid the groundwork for colorimetric read-outs that will add another layer of amplification in our cascade detection (gold nanoparticles, intein-extein and ssDNA amplification). Those readouts should allow for a practical readability of the diagnosis by the user without the need of digital analysis. Additionally, their amplification scheme should also lower the detection limit of the Cas13a without the need for pre-amplification of the target. </p><p> |
| + | However, we developed in parallel a scheme for amplifying the target using isothermal amplification (RPA) and transcription. This was motivated by our modeling work, which determined a detection limit in the range of the one found experimentally (around 10nM), and quantified the improvement we could expect from a cascade amplification, from <i>in vivo</i> DNA to RNA to readout. RPA worked well from <i>in vivo</i> and <i>in vitro</i> DNA sources, and the combination of RPA and transcription on paper was efficient enough to overcome our readout detection limit.</p><p> |
| + | We built a fluorescence detector that is to our knowledge, the cheapest and most sensitive ever built by an iGEM team, and provides a reasonable alternative to commercial plate readers. We used it successfully to detect Cas13a activity on paper, from <i>in vitro</i> transcribed RNA pathogen. However, the product itself may need to be redesigned for market distribution: in general, a fluorescence detector is not necessarily user-friendly, the extraction of the RNA on chip needs to be optimized. </p><p> |
| + | Nevertheless, we are glad to have created a functional platform that allows the detection of nanomolar concentrations of a pathogen's RNA within 30 minutes. With our modular approach, we have shown at least proof-of-concept results for each part, and are confident that no fundamental gap prevents our platform from being fully integrated. |
| </p> | | </p> |
− | <div class="captionPicture">
| |
− | <img src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Time lapse measurement of Cas13a digesting RNaseAlert on paper using our detector. The
| |
− | positive control contains RNaseA and RNaseAlert. The negative control contains only RNaseAlert. Data points are
| |
− | connected with lines for the convenience of the eye. Error bars represent the measurement uncertainties of the detector.
| |
− | </p>
| |
− | </div>
| |
| </td> | | </td> |
| </tr> | | </tr> |
| | | |
| <tr><td colspan=6 align=center valign=center> | | <tr><td colspan=6 align=center valign=center> |
− | <h3>Variety targets</h3> | + | <h1>Outlook</h1> |
− | <p> | + | <p> |
− | We tested different targets apart from <i> E.coli </i> 16s RNA. Our other targets were gram positive B. subtilis, Noro virus and the Hepatitis C virus. | + | We still have some modules that need improvement in the future. We have therefore listed the following points that need to be optimized below. |
− | </p>
| + | |
− | <h4><i>E. coli</i></h4>
| + | |
− | <p>
| + | |
− | In case of <i> E.coli </i> , we took the 16s RNA as our target RNA. We first worked with a part of the 16s RNA sequence ( 161 bp) which was then <i> in vitro </i> transcribed and was used for our assays. Later, we also did the extraction of the RNA from the E.coli overnight culture and performed the same experiments. The results are visible under section <i> in vivo </i> and proof of principle.
| + | |
| </p> | | </p> |
| + | <ul class="listResults"> |
| + | <li>Positive and negative controls in the readout: We occasionally found that high target concentrations led to signals above the positive control (which could be due to the degradation and lesser activity of RNaseA used for this control) and that low target concentrations could lead to signals below negative control (which could be due to noise at low fluorescence intensities) For proper quantification of the percentage of cleaved RNaseAlert, the controls should be standardized.</li> |
| + | <li><i> In vivo </i> heat lysis: During our experiments, we realized that the direct use of the RNA extracted from <i> E. coli </i> using heat lysis can lead to RNase contamination. Although our Cas13a cleavage assays are performed in presence of RNase Inhibitor to suppress the activity of the RNases that could be present, we observed that the heat lysed samples show relatively higher fluorescence activity in comparison to the phenol-chloroform extracted samples.</li> |
| + | <li>RNA extraction and amplification: The RNA extracted from <i> Bacillus subtilis </i> lead to unstable results, giving sometimes higher than positive control signals, sometimes very noisy kinetics. As this is a gram positive bacteria, we think some further characterization must be done on the efficiency of heat lysis of different type of cells. In all cases, the RNA should be amplified after lysis and before detection, as pathogens are often present below our detection limit of 10nM in real samples.</li> |
| + | <li>Cost of the chip: At the moment, the cost of our reusable detection unit is less than 15$ per unit. We could still try to minimize the costs by reducing the chip size and making it fully recyclable. We should characterize the life-time of the detector, to see how its cost is buffered by the number of tests that can be conducted with one detector. However, at the industrial level one could easily reduce the overall cost of CascAID by scaling up of the production. A rough cost estimation for the setup of a 1000 reactions gave us a cost per single test of around 0.85 $.</li> |
| + | <li>Lyophilization of Cas13a: the lyophilization protocol of the Cas13a has to be improved in order to make our paper chip portable and sustainable. We tried drying the Cas13a with the tardigrade intrinsically disordered proteins (TDPs) from Team TU Delft, as a cryoprotectant, but this lead to increased basal activity, rendering the detection less sensitive. Other cryoprotectants should be tried, and the stability of freeze-dried samples over a year should be assessed. </li> |
| + | <li>Readouts with color and amplification: The colorimetric readouts need continued work, and possibly improved design, since we only managed to partially succeed with the assays.</li> |
| + | <li>Handling of real patient samples: Due to the safety restrictions in our lab, and our lack of experience with clinical studies, we did not work with real-world samples. The next step of this project, before thinking of market distribution, would be to test the functionality of our platform outside of the lab and under real point-of-care conditions.</li> |
| + | <li>Integration of all the modules of the platform: Although all our modules parts are functional, and locally integrated, we did not reach full integration into a unique object, which would eliminate the need for a lab environment. It would still need to be accessed that this diagnosis device works in a variety of environments, when handled by non or minimally trained users. However, we believe we only need more time to assemble a fully functional and integrated module system. |
| + | </li> |
| + | </ul> |
| </td> | | </td> |
| </tr> | | </tr> |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <h4><i>B. subtilis</i></h4>
| |
− | <p>
| |
− | For <i> B. subtilis </i>, we did not perform any <i> in vitro </i> transcription. We basically extracted the RNA from the <i> B. subtilis </i> culture and then did the RNaseAlert assay. We had a low-quality RNA after the extraction and the reason could be that since it is a gram-positive spore forming bacteria, the RNA extraction didn’t work so well. However, the results from the RNaseAlert assay are as convincing as in case of <i> E. coli </i>. As seen in the results on the right, although the quality of the extracted RNA is not so good, one can use the Cas13a to detect the RNA present in the extracted sample.
| |
− | </p>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph #1
| |
− | </p>
| |
− | </div>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph #1
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph #1
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <h4>Noro virus</h4>
| |
− | <p>
| |
− | For Noro virus, we took a part of the sequence from its 5’ UTR and designed the crRNA accordingly. The results from the RNaseAlert assay were very promising and showed that Cas13a can be effectively used to detect the viral RNA as well. Since Noro virus is the cause of a very common viral gastroenteritis, Cas13a could be a good option for the detection of this viral infection and this also opens the possibility of using Cas13a as the detection system for other viral infections. As shown in the graph on the left above, the fluorescence activity increases with the increase in the concentration of the viral target.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <h4><i>HCV</i></h4>
| |
− | <p>
| |
− | For the HCV virus, we also took the part of the sequence from its 5’UTR and designed the crRNA accordingly. Also, the kinetics from the RNaseAlert assay using the HCV viral target as shown in the graph below showed the same effect as in case of the Noro virus assay. This again shows that we can detect even viruses like HCV with the help of this simple fluorescence assay.
| |
− | </p>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Comparison of the fluorescence kinetics of different targets
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <p>
| |
− | The following graph shows a comparative plot with all the different targets we used apart from the <i> E.coli </i> and we can see how the kinetics of the fluorescence changes with the increase in the target concentration. This pattern of increase in the activity of Cas13a is similar in all kinds of targets being used in our experiments, hence promoting the fact that Cas13a is a universal system that can be basically used for any RNA targets.
| |
− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3>Variety proteins</h3>
| |
− | <p>
| |
− | We tested variety of Cas13a proteins originating from different species of Leptotrichia and tested their efficiency to detect target RNAs. Both the Cas13a Lbu and the Cas13a Lwa show that this system can be efficiently used in the detection of the variety of target RNAs. We could not properly purify the Cas13a Lsh, which is the reason why there is no activity of Cas13a in case of Lsh.
| |
− | </p>
| |
− | <h4>Lbu results</h4>
| |
− | <p>
| |
− | Cas13a Lbu results: All of the results presented above were done with the Cas13a Lbu. Since the purity of the Cas13a Lbu was the best in our case, we did most of our experiments with this protein.
| |
− | </p>
| |
− | <h4>Lwa results</h4>
| |
− | <p>
| |
− | The Lwa protein also showed the same potential results as in case of Lbu. We were able to purify it only in the later phase of our project, so we didn’t use it for a variety of targets. The following graphs show the activity of the Cas13a Lwa with 16s rRNA of <i> E. coli </i> . The graphs below give us similar results as compared to the Cas13a Lbu . In conclusion we can say that the Cas13a proteins from different Leprotrichia species have similar cleavage activity.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph 1
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph 2
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=3 align=center valign=center>
| |
− | <h4>Lsh results</h4>
| |
− | <p>
| |
− | As mentioned earlier we faced some problems during the purification of the Cas13a from the Lsh. However, we did the RNaseAlert assay with the Elution of the Cas13a Lsh protein we had but in the results we see no activity of the protein as shown in figure on the right.
| |
− | </p>
| |
− | </td>
| |
− | <td colspan=3 align=center valign=center>
| |
− | <div class="captionPicture">
| |
− | <img width=460 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph 1
| |
− | </p>
| |
− | </div>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3>Aptamer</h3>
| |
− | <p>
| |
− | For more validation of our assay, we also tried the spinach aptamer for our experiments in place of RNaseAlert . The spinach aptamer releases green fluorescence when bound with the DFHBI and when the Cas13a is activated, it cleaves the spinach and DFHBI and thus the fluorescence activity decreases with time.
| |
− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph
| |
− | </p>
| |
− | </div>
| |
− | <p>
| |
− | As shown in the figure, we see that the fluorescence activity of the spinach aptamer is decreasing with the increasing concentration of the target RNA. With this result, we can assure that the Cas13a detection can also be integrated and used in other aptamer systems effectively.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− | <tr><td colspan=6 align=center valign=center>
| |
− | <h3><i>In vivo </i> (heat lysis)</h3>
| |
− | <p>
| |
− | To test if we can run the cleavage assay on different bacterial targets with simple heat lysis only, we heated the <i> E.coli </i> culture to 95 C for 10 mins and used the subsequent lysis product for the RNaseAlert assay. We did see that the Cas13a can effectively detect the target RNA and activate itself to successively release the fluorescence. However, we observed very high activity of the Cas13a in these experiments, which can be due to the fact that all the cellular components are still present in the lysis product and there can be some additional Rnases present in the lysate give rise to the activity of the Cas13a.
| |
− | </p>
| |
− | <div class="captionPicture">
| |
− | <img width=940 src="https://static.igem.org/mediawiki/2017/e/e2/T--Munich--Hardware_kinetic.png">
| |
− | <p>
| |
− | Graph
| |
− | </p>
| |
− | </div>
| |
− | <p>
| |
− | As shown in the figure, we see that the fluorescence activity of the spinach aptamer is decreasing with the increasing concentration of the target RNA. With this result, we can assure that the Cas13a detection can also be integrated and used in other aptamer systems effectively.
| |
− | </p>
| |
− | </td>
| |
− | </tr>
| |
− |
| |
− |
| |
− |
| |
− |
| |
| | | |
| | | |