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− | <img id="TopPicture" width="960" src="https://static.igem.org/mediawiki/2017/b/be/T--Munich--FrontPagePictures_Attributions.jpg">
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− | <tr><td colspan=6 align=left valign=center> | + | <tr id="hardwareFrontPage"> |
− | <font size=7 color=#51a7f9><b style="color: #51a7f9">Hardware</b></font> | + | <td colspan=2> |
| + | <table width=320> |
| + | |
| + | <tr> |
| + | <td> |
| + | <a href="/Team:Munich/Hardware/QuakeValve"><img class="picture1" src="https://static.igem.org/mediawiki/2017/0/08/T--Munich--Overlay.png"></a> |
| </td> | | </td> |
− | </tr>
| + | <td> |
− | <tr>
| + | |
− | <td colspan = 6 align="left">
| + | |
− | <p class="introduction">
| + | |
− | Our pathogen detection approach relies on Cas13a digesting RNA. A common way of monitoring RNase activityis using commercially available RNaseAlert consisting of a fluorescent RNA beacon. This is impractical for in-fieldapplications because commercial fluorescence detectors are expensive and inconveniently large. We therefore makeour pathogen detection system fit for in-field applications by developing a cheap and handy fluorescence detector. Al-though many previous iGEM teams constructed fluorescence detectors, we could not find any that had a high enoughsensitivity or the ability to measure fluorescence quantitatively. We therefore constructed a detector matching ourrequirements and compared it to others in a cost vs sensitivity diagram.
| + | |
− | </p>
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− | <p class="introduction">
| + | |
− | Our detector is paper-based and can detect fluorescein concentrations down to 200 nM. The detector is able to automatically
| + | |
− | measure fluorescence in units of equivalent fluorescein concentrations. It fits in a pipette box and costs less
| + | |
− | than 15 $. We were able to measure a time trace of Cas13a digesting RNaseAlert with our detector. For comparison
| + | |
− | we also measured a positive control containing RNase A and a negative control containing only RNaseAlert. The
| + | |
− | data are displayed in the figure bellow.
| + | |
− | </p>
| + | |
− | <p class="introduction">
| + | |
− | The time traces show an enzymatic reaction taking place on filter paper. This proves that our detector is sensitive
| + | |
− | enough and meets our requirements. However the detector is not limited to our specific application but can be used
| + | |
− | for the detection of any fluorescence signal in biological or chemical systems. We therefore think that our detector
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− | can benefit other iGEM teams and research groups that want to make fluorescence based detection fit for in-field
| + | |
− | applications.
| + | |
− | </p>
| + | |
− | | + | |
− | </td>
| + | |
− | </tr>
| + | |
− | | + | |
− | | + | |
− | | + | |
− | | + | |
− | | + | |
− | | + | |
− | <tr><td colspan=6 align=center valign=center>
| + | |
− | <h3>Overall Design</h3>
| + | |
− | <p>
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− | Light from a blue LED is filtered by a blue filter foil and excites fluorophores on a filter paper. The excitation light
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− | is blocked by an orange filter foil while the emission light from the fluoroscopes passes through the orange filter foil
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− | and illuminates a light dependent resistor (LDR). The LDR changes its resistance corresponding to the intensity
| + | |
− | of the fluorescence light.Finally an Arduino Nano measures the resistance via a voltage divider and calculates the
| + | |
− | fluorophore concentration. The two figures bellow show this overall design and the operational detector.</p>
| + | |
| </td> | | </td> |
| </tr> | | </tr> |
| + | </table> |
| | | |
− | <tr><td colspan=6 align=center valign=center> | + | <a href="/Team:Munich/Hardware/SampleProcessing"><img id="picture3" src="https://static.igem.org/mediawiki/2017/0/08/T--Munich--Overlay.png"></a> |
− | <h3>Components</h3></td></tr> | + | <a href="/Team:Munich/Hardware/Paperstrip"><img id="picture2" src="https://static.igem.org/mediawiki/2017/0/08/T--Munich--Overlay.png"></a> |
− | <tr><td colspan=6 align=center valign=center> | + | </td> |
− | <h4>Micro Controller</h4> | + | <td colspan=4> |
− | <p> | + | <a href="/Team:Munich/Hardware/Detector"><img id="picture4" src="https://static.igem.org/mediawiki/2017/0/08/T--Munich--Overlay.png"></a> |
− | We used an Arduino Nano for automatized data collection. This micro controller has analog pins that can measure
| + | |
− | voltages from 0 to 5 V and gives an integer from 0 to 1023 as output. The micro controller is connected via an USB port with a computer or smart-phone where the data can be processed further.</p>
| + | |
| </td> | | </td> |
| </tr> | | </tr> |
| | | |
− | <tr><td colspan=6 align=center valign=center> | + | <tr> |
− | <h4>Light dependent resistor (LDR)</h4>
| + | <td colspan=6> |
− | <p>
| + | <div class="captionPicture"> |
− | For the detection of fluorescence light we used a light depending resistor (LDR). A LDR decreases its resistance RLDR
| + | |
− | with increasing light intensity I. The dependence of the resistance RLDR on the light intensity I is</p>
| + | |
− | <div class="equationDiv"><img src="https://static.igem.org/mediawiki/2017/3/33/T--Munich--Hardware_equation1.png"><span>(1)</span></div> | + | |
| <p> | | <p> |
− | where γ is a parameter depending on the type of resistor being used and can even differ for LDRs with the same type | + | Complete overview of all modular hardware parts in our pathogen detection system. Shown are counterclockwise and starting in in the upper left corner: The Quake valve that controls fluid flow, our sample processing device, the paper strip where a reaction mix is stored and the readout reaction takes place and finally our low-cost fluorescence detector "Lightbringer" that performs the readout measurement. Images are clickable and linked to the corresponding wiki subsection. |
− | designation.
| + | |
| </p> | | </p> |
− | </td> | + | </div></td> |
| </tr> | | </tr> |
| | | |
− | | + | <tr><td colspan=6 align=left valign=center> |
− | | + | <font size=7 color=#51a7f9><b style="color: #51a7f9">Hardware</b></font> |
− | | + | |
− | | + | |
− | <tr><td align=center valign=center colspan=4> | + | |
− | <p>
| + | |
− | We wanted to start our project by showing that Cas13a's collateral activity could be used to detect the presence of specific RNA. For this, we used the RNAse alert system, as done in a recent publication<sup><a class="myLink" href="#ref_11">11</a></sup>, to detect RNA digestion. In this assay, the presence of RNAse-like activity is detected by an increase in green fluorescence. Our experiments yielded a convincing proof-of-principle which we went on to model. Moreover, CascAID can be used to detect a wide spectrum of pathogens, as our experiments with gram-positive and viral targets suggested. As we wanted to make CascAID available for everyone, we focused on building an inexpensive fluorescence detector to measure the presence of the target. Our detector “Lightbringer” was designed to be able to detect the fluorescence produced by the fluorescein in the Rnase alert system<sup><a class="myLink" href="#ref_12">12</a></sup>, but we theorize that changing the filters allows detection of other fluorophores. In addition, we experimented with freeze-drying on paper to make CascAID durable and easily portable.
| + | |
− | </p>
| + | |
− | </td>
| + | |
− | <td align=center valign=center colspan=2>
| + | |
− | <img src="https://static.igem.org/mediawiki/2017/7/7f/T--Munich--Description_Cas13a_Readout_Comparision.svg"> | + | |
− | <p>Cas13a can be used to detect specific RNA sequences</p>
| + | |
− | </td>
| + | |
− | </tr>
| + | |
− | | + | |
− | <tr class="lastRow">
| + | |
− | <td align=center valign=center colspan=2>
| + | |
− | <a href="http://www.uni-muenchen.de/studium/lehre_at_lmu/index.html"><img src="https://static.igem.org/mediawiki/2017/9/9a/T--Munich--Logo_LehreLMU.gif" width="200"></a> | + | |
− | <p>Picture of the Thermocycler</p>
| + | |
− | </td>
| + | |
− | <td align=center valign=center colspan=4>
| + | |
− | <p>
| + | |
− | For RNA extraction from the samples we tested three methods: extraction with silica beads, extraction with silica membrane and heat lysis. We custom-built an affordable thermocycler for signal amplification by RT-PCR to improve the detection limit. We explored recombinase polymerase amplification (RPA), an isothermal amplification procedure, to use over more conventional PCR methods as its simplicity makes it the more attractive option.
| + | |
− | </p>
| + | |
− | </td>
| + | |
− | </tr>
| + | |
− | | + | |
− | <tr><td colspan=6 align=center valign=center>
| + | |
− | <h3>Colorimetric read-outs</h3>
| + | |
− | <p>
| + | |
− | To couple CascAID with an easy read-out method we explored three colorimetric read-outs:
| + | |
− | </p>
| + | |
| </td> | | </td> |
| </tr> | | </tr> |
| + | <tr> |
| + | <td colspan = 6 align=center valign=center> |
| + | <p class="introduction"> |
| + | |
| + | The liberation of diagnostic tests from expensive lab infrastructure requires innovative ways of sample processing and measuring. We therefore developed a set of portable hardware tools with the goal of providing an automated sample-to-answer solution. The heart of our system is <a class="myLink" href="https://2017.igem.org/Team:Munich/Hardware/Detector">‘Lightbringer’</a>, our fluorescence detector, which is capable of measuring kinetics of biological or chemical reactions on <a class="myLink" href= "https://2017.igem.org/Team:Munich/Hardware/Paperstrip" >paper.</a> Built from 3D–printed parts and standard electronic components, it can be assembled for less than 15$, while offering a sensitivity competitive to commercial fluorescence readers. Additionally, tackling the challenge of sample pre-processing in field, we developed a portable <a class="myLink" href="https://2017.igem.org/Team:Munich/Hardware/SampleProcessing"> fluidic system</a>, featuring a temperature control unit for lysis and isothermal PCR. Conceiving a platform independent of lab infrastructure, we demonstrate the feasibility of <a class="myLink" href="https://2017.igem.org/Team:Munich/Hardware/QuakeValve"> controlling fluid flow</a> with bike tires and air balloons. All hardware components are designed and documented with the aim of enabling the community to reproduce and extend our set of tools. |
| + | </p> |
| | | |
− | <tr><td colspan=2 align=center valign=center> | + | <div class="captionPicture"> |
− | <p> | + | <img width=960 src="https://static.igem.org/mediawiki/2017/2/26/Schema_final_lowres.png"> |
− | <b>AeBlue</b>: The RNA strand in a specially designed RNA/DNA dimer is cut by Cas13a's collateral
| + | <p> |
− | activity. After digestion, the interaction between the two strands is too weak to hold the dimer and it
| + | |
− | decays. We can then use the DNA-strand as template to translate the chromoprotein <a href="http://parts.igem.org/Part:BBa_K864401">aeBlue</a>.
| + | |
| </p> | | </p> |
− | </td> | + | </div> |
− | <td colspan=4 align=center valign=center>
| + | |
− | <img src="https://static.igem.org/mediawiki/2017/9/90/T--Munich--Description_aeBlue.svg">
| + | |
− | <p>Diagram of aeBlue</p>
| + | |
− | </td>
| + | |
− | </tr>
| + | |
| | | |
− | <tr><td colspan=2 align=center valign=center>
| |
− | <p>
| |
− | <b>Intein-Extein</b>: By binding TEV-protease with a RNA-linker we can use Cas13a's collateral activity
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− | to regulate the protease's diffusion and use it to cleave a TEV tag separating the intein regions of a
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− | modified chromophore. After the first cleavage, the intein segment excises itself<sup><a class="myLink" href="#13">13</a></sup>, bringing together the
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− | halves of the chromophore. Only then is the chromophore functional and produces the colorimetric
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− | read-out.
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− | </p>
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− | </td>
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− | <td colspan=4 align=center valign=center>
| |
− | <a href="http://www.uni-muenchen.de/studium/lehre_at_lmu/index.html"><img src="https://static.igem.org/mediawiki/2017/9/9a/T--Munich--Logo_LehreLMU.gif" width="200"></a>
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− | <p>Diagram of Intein-Extein</p>
| |
− | </td>
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− | </tr>
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− |
| |
− | <tr class="lastRow"><td colspan=2 align=center valign=center>
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− | <p>
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− | <b>Gold nanoparticles</b>: Gold nanoparticles coated with short DNA sequences are held closely
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− | together by a complementary linker RNA, which makes the solution intense blue<sup><a class="myLink" href="#14">14</a></sup>. Activated Cas13a cuts
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− | the linker RNA, causing the nanoparticles to diffuse away from each other. This increase in distance
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− | causes a color change to intense red.
| |
− | </p>
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− | </td>
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− | <td colspan=4 align=center valign=center>
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− | <img src="https://static.igem.org/mediawiki/2017/b/b3/T--Munich--Description_Goldnanoparticles.svg">
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− | <p>Gold nanoparticles</p>
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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>Software</h3>
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− | <p>
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− | To help facilitate the design of crRNA, the sequences that give CascAID its specificity, we developed a
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− | software tool that checks crRNA for unwanted secondary structures. This gives valuable insight on
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− | whether the sequence is suited to use with Cas13a or whether some modifications are needed.
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− | Together with Team Delft's software tool which designs the corresponding crRNA based on the target,
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− | we collaborated to develop a powerful tool that suggests crRNA sequences and checks their usability
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− | </p>
| |
| </td> | | </td> |
| </tr> | | </tr> |
− |
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− | <tr><td colspan=6 align=center valign=center>
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− | <h3>References</h3>
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− | <p>
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− | <ol style="text-align: left">
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− | <li id="ref_1">Cohen, Limor, and David R. Walt. "Single-Molecule Arrays for Protein and Nucleic Acid Analysis." Annual Review of Analytical Chemistry 0 (2017).</li>
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− | <li id="ref_2">Nakano, Michihiko, et al. "Single-molecule PCR using water-in-oil emulsion." Journal of biotechnology 102.2 (2003): 117-124.</li>
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− | <li id="ref_3">Taniguchi, Yuichi, et al. "Quantifying E. coli proteome and transcriptome with single-molecule sensitivity in single cells." science 329.5991 (2010): 533-538.</li>
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− | <li id="ref_4">Rissin, David M., et al. "Single-molecule enzyme-linked immunosorbent assay detects serum proteins at subfemtomolar concentrations." Nature biotechnology 28.6 (2010): 595-599.</li>
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− | <li id="ref_5">Pardee, Keith, et al. "Rapid, low-cost detection of Zika virus using programmable biomolecular components." Cell 165.5 (2016): 1255-1266.</li>
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− | <li id="ref_6">Slomovic, Shimyn, Keith Pardee, and James J. Collins. "Synthetic biology devices for in vitro and in vivo diagnostics." Proceedings of the National Academy of Sciences 112.47 (2015): 14429-14435.</li>
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− | <li id="ref_7">Tang, Ruihua, et al. "A fully disposable and integrated paper-based device for nucleic acid extraction, amplification and detection." Lab on a Chip 17.7 (2017): 1270-1279.</li>
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− | <li id="ref_8">Vashist, Sandeep Kumar, et al. "Emerging technologies for next-generation point-of-care testing." Trends in biotechnology 33.11 (2015): 692-705.</li>
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− | <li id="ref_9">Gubala, Vladimir, et al. "Point of care diagnostics: status and future." Analytical chemistry 84.2 (2011): 487-515.</li>
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− | <li id="ref_10">Abudayyeh, Omar O., et al. "C2c2 is a single-component programmable RNA-guided RNA-targeting CRISPR effector." Science 353.6299 (2016): aaf5573.</li>
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− | <li id="ref_11">Gootenberg, Jonathan S., et al. "Nucleic acid detection with CRISPR-Cas13a/C2c2." Science (2017): eaam9321.</li>
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− | <li id="ref_12">https://www.idtdna.com/pages/docs/technical-reports/in_vitro_nuclease_detectionD325FDB69855.pdf (retrieved: 13.10.17)</li>
| |
− | <li id="ref_13"> Anraku, Yasuhiro, Ryuta Mizutani, and Yoshinori Satow. "Protein splicing: its discovery and structural insight into novel chemical mechanisms." IUBMB life 57.8 (2005): 563-574.</li>
| |
− | <li id="ref_14">Link, Stephan, and Mostafa A. El-Sayed. "Size and temperature dependence of the plasmon absorption of colloidal gold nanoparticles." The Journal of Physical Chemistry B 103.21 (1999): 4212-4217.</li>
| |
− | </ol>
| |
− | </p>
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− | </td>
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− | </tr>
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− |
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