Team:Calgary/Project/OurSensor/Linker

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<h1>Linker</h1>
<h1>Linker</h1>
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<h2>Introduction</h2>
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<p><img style="float: right;" src="https://static.igem.org/mediawiki/2013/b/b6/2013igemcalgaryfigurefortheLinkerpage.png" width="301"></p>
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<p>In order to design a functional sensor, we needed to be able to link the detector to the reporter. We considered a direct linkage between the reporter and the detector, which we decided to pursue for the beta-lactamase as a reporter. We have also built and submitted a construct with the a direct linkage between the TALEs and the ferritin. However, due to the massive size of the finished product (~1300 kDa) we needed another system, a system which allows <i> in vitro </i> assembly of the reporter and the detector. This is why we looked into the use of E and K coiled-coils in our system. The addition of the coiled-coils gives us flexibility in our system to disassembly of the target-specific detector from the reporter in order to switch in another detector for a different application. In other words, the coiled-coils add re-usability to the system making it a great <a href="https://2013.igem.org/Team:Calgary/Project/HumanPractices/Platform">platform technology</a>.
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In addition, ferritin serves as a great scaffolding protein, allowing us to stick multiple different detectors on it. We can also scale up the reporter response by adding reporters on ferritin, depending on the requirements of the system where the sensor is applied. Therefore, the ability to scale up and down allows us to incorporate informed design in our <a href="https://2013.igem.org/Team:Calgary/Project/HumanPractices/Platform">platform</a> technology application.
<h2>What are E/K Coils?</h2>
<h2>What are E/K Coils?</h2>
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<p>E/K coils are synthetic coiled-coil domains designed specifically to bind to each other with high affinity and specificity (Litowski and Hodges, 2002) (Figure 1).  They are composed of a heptad repeat that forms a coil structures that are able to interact with each other. These coils are able to interact with each other in an anti-parallel fashion that makes them useful for applications such as peptide capture, protein purification and in biosensors. For our project we decided to make use of the IAAL E3/K3 coils (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189010">BBa_K1189010.</a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189011">BBa_K1189011.</a>) due to the balance they offer between affinity and specificity (Table 1). </p>
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<p>E/K coils are synthetic coiled-coil domains designed to bind specifically to each other with high affinity and specificity (Litowski and Hodges, 2002) (Figure 1).  They are composed of a heptad repeat of amino acids that form a coil structure that is able to interact with each other. These coils are able to interact with each other in an anti-parallel fashion, making them useful for applications such as peptide capture, protein purification and biosensors. For our project we decided to make use of the IAAL E3/K3 coils (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189010">BBa_K1189010</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189011">BBa_K1189011</span></a>) due to the balance they offer between affinity and specificity (Table 1, Figure 2). These parts were already in the registry, however the DNA was never received, so we built, sequenced and re-submitted them. </p>
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<img src="https://static.igem.org/mediawiki/2013/a/a9/UCalgary2013TRCoilrenderpng.png" alt="Coiled-coils" width="193" height="300">
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<img src="https://static.igem.org/mediawiki/2013/a/a9/UCalgary2013TRCoilrenderpng.png" alt="Coiled-coils" width="150" height="250">
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<figcaption>
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<figcaption><p><b>Figure 1.</b> Ribbon visualization of the E3/K3 IAAL coiled-coils. </p>
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<p><b>Figure 1.</b> Ribbon visualization of the E3/K3 IAAL coiled-coils.</p>
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</figcaption>
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<br>
<center><b>Table 1. Coil Peptide Sequences</b></center>
<center><b>Table 1. Coil Peptide Sequences</b></center>
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<h2>How do these Coils Work?</h2>
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<p>These E3/K3 coils are able to form heterodimers due to the hydrophobic residues contained within the heptad repeat. In our case these are isoleucine and leucine residues. Designated by empty arrows in the helical wheel diagram below (Figure 2) these residues form the core of the binding domain of the coils. In order to prevent the homodimerization of these coils charged residues are included in the design. The electrostatic interactions between glutamic acid and lysine residues prevent an E-coil from binding with an E-coil for example. We selected the use of E3/K3 coiled-coils over other synthetic E/K coils as the isoleucine residue present shows a significant increase in the heterodimer over valine found in other coils. The alpha-helical propensity of the residues outside of the core interacting residues is also increased by utilizing an alanine residue instead of the serine residue found in ISAL and VSAL E/K coils. This selection maximizes the stability and specificity of the coils used in our system.  </p>
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<img src="https://static.igem.org/mediawiki/igem.org/5/53/UCalgary2013TRcoildiagramcroptransparent.png" alt="IAAL E3/K3 Coil Helical Wheel Diagram" width="800" height="449">
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<img src="https://static.igem.org/mediawiki/2013/thumb/6/60/Ucalgary2013ecolihis.png/800px-Ucalgary2013ecolihis.png" alt="Coiled-coils" width="200" height="60">
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<img src="https://static.igem.org/mediawiki/2013/7/74/K_coil-His_-_Copy.png" alt="Coiled-coils" width="200" height="60">
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<p><b>Figure 2.</b> A helical wheel representation of the IAAL E3/K3 coiled-coil heterodimer viewed as a cross-section based off of a similar figure created by Litowski and Hodges (2002). The peptide chain propagates into the page from the N to the C terminus. Hydrophobic interactions between the coils are indicated by the clear wide arrows. The intermolecular electrostatic interactions between the coils are displayed by the thin curved arrow (eg. Between Glu<sup>15</sup> and Lys<sup>20</sup>)Letters a, b, c,and d designate the positions of IAAL repeat in the heptapeptide. THe e and g positions are occupied by the charged residues.</p>
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<p><b>Figure 2.</b> The two constructs used for the E coil (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189012">BBa_K1189012</span></a>) and K coil (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189013">BBa_K1189013</span></a>). </p>
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<h2>So do these Coils Actually Bind?</h2>
 
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<p>After putting in gratuitous effort to build parts containing these coils and successfully purifying these proteins it was necessary to determine if the coils could actually bind to each other. For this purpose we prepared a preliminary qualitative blot assay that we could use as a foundation to gather more quantitative data in other assays in the future. In the case of the coils were were interested to see if the K-coil on a TALE protein (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189029">BBa_K1189029.</a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030.</a>) could bind to the E-coil found on one of our Prussian blue ferritin constructs (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018.</a>). To complete this task we placed the TALE on the membrane, washed and blocked the membrane. The ferritin protein with the complimentary coil was then added to the membrane. If this coil successfully binds the other coil then the ferritin will not be washed off during the next wash step. We can then see if Prussian blue ferritin is bound by adding a TMB substrate solution that will cause a colour change. To this extent we saw a blue ring in this trial indicating a positive result. This suggests that our coils are actually binding in an <i>in vitro</i> system.</p>
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<h2>How do These Coils Work?</h2>
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<p>Another interesting element of this assay that is interesting is why we used two variants of the TALE K-coil negative control. A blue ring on our TALE negative control confirmed our fear that during the second protein application and wash step that some of the ferritin with coil proteins would drift over and bind to the TALE K-coils on the nitrocellulose. This did not occur for our separate negative control. Another element of our assay was testing the binding of TALEs to DNA. This did not yield any results and will be investigated in the future. </p>
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<p>These E3/K3 coils are able to form heterodimers due to the hydrophobic residues contained within the heptad repeat. In our case these heptad repeats are composed of isoleucine and leucine residues. These hydrophobic residues form the core of the binding domain of the coils, indicated in Figure 3 by the empty arrows. In order to prevent the homodimerization of these coils, charged residues are included in the design. For example, the electrostatic interactions between glutamic acid and lysine residues prevent an E coil from binding with an E coil. We selected the use of E3/K3 coiled-coils over other synthetic E/K coils, as the isoleucine residue present shows a significant increase in the heterodimerization over valine found in other coils. The alpha-helical propensity of the residues outside of the core interacting residues is also increased by utilizing an alanine residue instead of the serine residue found in ISAL and VSAL E/K coils. This selection maximizes the stability and specificity of the coils used in our system. </p>
<figure>
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<img src="https://static.igem.org/mediawiki/2013/e/e3/UCalgary2013TRCoilbindingpreliminary.png" alt="Preliminary Coil Binding" width="757" height="751">
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<img src="https://static.igem.org/mediawiki/2013/3/37/UCalgary2013TRCoildiagramtransparent2.png" alt="IAAL E3/K3 Coil Helical Wheel Diagram" width="600" height="350">
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<p><b>Figure 3.</b> This basic qualitative assay was used to inform us whether certain elements of our system are able to bind to each other. Our TALE proteins were mounted to the membrane along with positive controls of three Prussian blue variants; two recombinant ferritins and one commercial protein. The membranes were then washed and blocked. Prussian blue ferritin with a coil was added to our TALE protein containing a coil. Prussian blue ferritin with a TALE that could bind to the DNA held by another TALE on the membrane was also added. A TMB substrate solution was added to cause a colourimetric change over 5 minutes. Positive results are indicated by dark rings of colour. Negative controls include a TALE with a coil on the same membrane and the same TALE and bovine serum albumin on separate membranes that were treated separately. Image contras was altered to make the results more clear on a digital monitor; the same changes were applied to each element of the figure.</p>
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<p><b>Figure 3.</b> A helical wheel representation of the IAAL E3/K3 coiled-coil heterodimer viewed as a cross-section based off of a similar figure created by Litowski and Hodges (2002). The peptide chain propagates into the page from the N- to the C- terminus. Hydrophobic interactions between the coils are indicated by the clear wide arrows. The intermolecular electrostatic interactions between the coils are displayed by the thin curved arrow (eg. Between Glu<sup>15</sup> and Lys<sup>20</sup>) Letters a, b, c,and d designate the positions of IAAL repeat in the heptapeptide. The e and g positions are occupied by the charged residues.</p>
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<h2>Ferritin Scaffold </h2>
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<h2>What did we construct? </h2>
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<p>The first construct we created involved attaching the previously mentioned E coil biobrick to the fusion of heavy and light chains of ferritin. (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189037">BBa_K1189037</span></a>) (Figure 4). This construct would assemble to form a 12-subunit nanoparticle with E coils on the outside that would each bind a protein containing the respective K coil. This means we can simply attach the K coil to a protein of choice, such as a TALE in order to bind it to the ferritin scaffold (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189037">BBa_K1189037</span></a>) Therefore we constructed the respective K coil-TALE fusion constructs, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189029">BBa_K1189029</span></a> and <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</span></a> (Figure 5 & 6). The ideal result of this system is that <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189029">BBa_K1189029</span></a> and <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</span></a> will be bound to ferritin, resulting in a protein complex containing 12 TALE proteins bound to the ferritin scaffold through E/K coils. This system then allows the proteins to properly fold while at the same time allowing the ferritin nanoparticle to assemble without interference.
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<p>One of the previously mentioned coils, the E coil, will be attached to ferritin a ubiquitous 24-subunit iron storage protein to form <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018.</a>. By attaching a K coil to our protein of choice, TALE, we can fuse this protein to our ferritin scaffold. This method then allows us to bind multiple reporter proteins to the ferritin in order to amplify our output signal. The use of these coils for fusions avoids the possibility of our large fusion protein causing problems in protein folding and nanoparticle assembly. The ideal result of this system is the DNA-binding protein, TALE, will be bound to ferritin, resulting in a protein complex containing 12 TALE proteins boudn to the ferritin scaffold through E/K-coils (figure 4). This system then allows the proteins to properly fold while at the same time allowing the ferritin nanoparticle to assemble without interference.
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<figure>
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<img src="https://static.igem.org/mediawiki/2013/a/a9/UCalgary2013TRCoilrenderpng.png" alt="Coiled-coils" width="193" height="300">
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<img src="https://static.igem.org/mediawiki/2013/thumb/8/83/Ucalgary2013construct2.png/800px-Ucalgary2013construct2.png" alt="FerriTALE" width="436" height="80">
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<p><b>Figure 4.</b> Ribbon visualization of the the final construct, composed of the ferritin-E-coil scaffold bound to TAL-K-coil detector.</p>
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<p><b>Figure 4.</b> Schematic for the ferritin disubunit-E coil fusion protein (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>).</p>
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<p>Upon further thought into this system, we determined the ferritin-coiled-coil system could be used for more than the detection of our <i>E.coli</i> sequence. We can use this system to detect other sequences of DNA by exploiting the ability of the TALE system to be easily engineered and modified, along with the interchangeability of the coiled-coil system. Thus by attaching K coils to TALEs that target alternative sequences, we can use this system as a platform for any variety of DNA sequences. Furthermore, we can expand this system towards proteins and other molecules as well by replacing the TALEs with antibodies or other binding proteins. This system shows the potential to bind a large number of ligands, only being restricted by the number of binding proteins that are currently known.
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<img src="https://static.igem.org/mediawiki/2013/thumb/6/69/Ucalgary2013kcoiltala.png/800px-Ucalgary2013kcoiltala.png" alt="FerriTALE" width="365" height="80">
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<p><b>Figure 5.</b> Schematic of the TALE A fused to the K coil (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189029">BBa_K1189029</span></a>).</p>
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<img src="https://static.igem.org/mediawiki/2013/thumb/1/1b/Calgary2013K_coilHis-TALE_BPlacI.png/800px-Calgary2013K_coilHis-TALE_BPlacI.png" width="365" height="80">
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<p><b>Figure 6.</b> Schematic of the TALE B fused to the K coil (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</b></a>).</p>
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<h2>So do These Coils Actually Bind?</h2>
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<p> After putting in gratuitous effort to build parts containing these coils and successfully purifying these proteins we wanted to determine if the E and K coils interacted with each other. In order to characterize coil-coil interaction we performed an immunoprecipitation (IP) assay. We built a GFP with an E coil (<a href=” http://parts.igem.org/wiki/index.php?title=Part:BBa_K1189014”> BBa_K1189014</a>) and we also built TALE-B with a K coil (<a href=” http://parts.igem.org/wiki/index.php?title=Part:BBa_K1189014”>BBa_K1189030</a>). To characterize the binding of the coils we pulled down with either an immunoglobulin G antibody (IgG) that serves as a negative control or with GFP antibody. The idea behind this experiment is to pull down the E coil which is fused to GFP with a GFP antibody and then probe with a anti-his antibody which recognizes the his tag on the TALE fused to the K coil. Upon interaction between the E and K coils we will see an output at approximately 86 kDa when probed with a His-antibody as seen in Figure 7. Our test groups included the coils by themselves and both the E and K coils put together in solution. As seen in Figure 7 a band appears only when we pull E and K coil with a GFP and probe with an anti-his antibody indicating the presence of both GFP and TALE in the elution solution indicating that the coils interact with each other. </p>
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<img src="https://static.igem.org/mediawiki/2013/a/a6/HimikaIP_Ucalgary.png">
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<figcaption><p><b>Figure 7.</b> Immunoprecipitation assay showing that the E and K coils interact with each other. The first three lanes show E coil, K coil and E coil with K coil pulled down with IgG (control) antibody. The last three lanes were pulled down with a anti-GFP antibody and probed with a anti-his antibody. The E coil is fused to GFP <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1189014">BBa_K1189014</a> and the K coil is fused to TALE with a his tag <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</a>. Therefore, if we pull down with GFP and probe with his-antibody a band would appear the size of TALE. This indicates that both the GFP and the TALE are present and that is possible upon coil-coil interaction.</p>
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<h2>Ferritin Scaffold</h2>
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<img src="https://static.igem.org/mediawiki/2013/4/4a/2013igemcalgaryforthelinkerpageRecolorFerriTALE.png" alt="FerriTALE" width="500" height="500">
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<figcaption><p><b>Figure 8.</b> Ribbon visualization of the the final construct, composed of the ferritin-E coil scaffold (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189037">BBa_K1189037</span></a>) bound to TALE-K coil detector (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</span></a>).</p>
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<p> The ferritin scaffold we chose to use, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>, allows us to modulate our system as we wish. We determined the ferritin-coiled-coil system could be used for more than the detection of our <i>E.coli</i> sequence. The ferritin scaffold can detect other sequences of DNA by exploiting the ability of the TALE system to be easily engineered and modified, along with the interchangeability of the coiled-coil system. Thus by attaching K coils to TALEs that target alternative sequences, we can use this system as a <a href="https://2013.igem.org/Team:Calgary/Project/HumanPractices/Platform">platform</a> for any variety of DNA sequences. In our system, we utilized two TALE proteins, TALE A and TALE B (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189029">BBa_K1189029</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189030">BBa_K1189030</span></a>). These two parts were both created with the K coil, allowing us to use the same ferritin scaffold (<a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189018">BBa_K1189018</span></a>, <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_K1189037">BBa_K1189037</span></a>) to anchor our proteins. This proved to be incredibly useful in binding the TALE proteins to nitrocellulose, a process that typically requires chemical modifications and specialized proteins in order to ensure the active site of these proteins are functional. Instead, we could interchange TALE A for TALE B on the ferritin scaffold due to our coiled-coil system. The protein complex can then simply be blotted onto our nitrocellulose strip, ensuring at minimum, the upwards-facing TALEs will be able to bind DNA. Furthermore, we can expand this system towards proteins and other molecules as well by replacing the TALEs with antibodies or other binding proteins. The use of coils on the ferritin scaffold also proves useful to prevent the TALE proteins in our FerriTALE from interrupting the self-assembly of ferritin due to our large size. An experiment which can be viewed on our <a href="https://2013.igem.org/Team:Calgary/Project/OurSensor/Reporter/PrussianBlueFerritin">Prussian blue ferritin page</a> was used to demonstrate the viability of these coils for bringing our FerriTALE together. By examining the catalytic activity of our Prussian blue ferritin we could evaluate whether the direct fusion of TALEs or the use of coils was more effective for our system. The results of this experiment showed that using coils to bind our TALEs is the most effective route.
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Another aspect of the ferritin nanoparticle that can be exploited is its composition, being composed of 24 subunits, as well as its potential as a novel reporter. Ferritin is typically composed of two chains, heavy and light. In our system, each one of these subunits can be bound to a reporter, effectively amplifying our catalytic activity by 24 due to the increased number of bound reporter proteins. But this activity can be scaled down through previously reported heavy-light chain fusions (Huh and Kim, 2003). Rather than 24 subunits the nanoparticle would be reduced to 12 subunits, as in our system, and thus the number of reporter proteins would decrease accordingly. We can scale this down even further due to our ability to transform the iron core of the protein into a catalytic active substance called Prussian Blue (Zhang <i>et al.</i>, 2013). Thus, instead of multiple bound reporter proteins we can further scale down the output of our system to a system with essentially one reporter. The ability of our system to scale up and down according to the need of detection means this system is applicable in areas ranging from low sensitivity to high sensitivity.
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Another aspect of the ferritin nanoparticle that can be exploited is its composition, being composed of 24 subunits, as well as its potential as a novel reporter. Ferritin is typically composed of two chains, heavy and light. In our system, each one of these subunits can be bound to a reporter, effectively amplifying our catalytic activity by 24 due to the increased number of bound reporter proteins. But this activity can be scaled down through previously reported heavy-light chain fusions (Huh and Kim, 2003). Rather than 24 subunits the nanoparticle would be reduced to 12 subunits, as in our system, and thus the number of reporter proteins would decrease accordingly. We can scale this down even further due to our ability to transform the iron core of the protein into a catalytic active substance called Prussian Blue (Zhang <i>et al.</i>, 2013). Thus, instead of multiple bound reporter proteins we can further scale down the output of our system to one with essentially one reporter. The ability of our system to scale up and down according to the need of detection means this system is applicable in areas ranging from low sensitivity to high sensitivity.
</p>
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Latest revision as of 03:59, 29 October 2013

Linker

Introduction

In order to design a functional sensor, we needed to be able to link the detector to the reporter. We considered a direct linkage between the reporter and the detector, which we decided to pursue for the beta-lactamase as a reporter. We have also built and submitted a construct with the a direct linkage between the TALEs and the ferritin. However, due to the massive size of the finished product (~1300 kDa) we needed another system, a system which allows in vitro assembly of the reporter and the detector. This is why we looked into the use of E and K coiled-coils in our system. The addition of the coiled-coils gives us flexibility in our system to disassembly of the target-specific detector from the reporter in order to switch in another detector for a different application. In other words, the coiled-coils add re-usability to the system making it a great platform technology. In addition, ferritin serves as a great scaffolding protein, allowing us to stick multiple different detectors on it. We can also scale up the reporter response by adding reporters on ferritin, depending on the requirements of the system where the sensor is applied. Therefore, the ability to scale up and down allows us to incorporate informed design in our platform technology application.

What are E/K Coils?

E/K coils are synthetic coiled-coil domains designed to bind specifically to each other with high affinity and specificity (Litowski and Hodges, 2002) (Figure 1). They are composed of a heptad repeat of amino acids that form a coil structure that is able to interact with each other. These coils are able to interact with each other in an anti-parallel fashion, making them useful for applications such as peptide capture, protein purification and biosensors. For our project we decided to make use of the IAAL E3/K3 coils (BBa_K1189010, BBa_K1189011) due to the balance they offer between affinity and specificity (Table 1, Figure 2). These parts were already in the registry, however the DNA was never received, so we built, sequenced and re-submitted them.

Coiled-coils

Figure 1. Ribbon visualization of the E3/K3 IAAL coiled-coils.


Table 1. Coil Peptide Sequences
Coil Name Peptide Sequence
IAAL E3 NH2-EIAALEKEIAALEKEIAALEK-COOH
IAAL K3 NH2-KIAALKEKIAALKEKIAALKE-COOH

Coiled-coils Coiled-coils

Figure 2. The two constructs used for the E coil (BBa_K1189012) and K coil (BBa_K1189013).

How do These Coils Work?

These E3/K3 coils are able to form heterodimers due to the hydrophobic residues contained within the heptad repeat. In our case these heptad repeats are composed of isoleucine and leucine residues. These hydrophobic residues form the core of the binding domain of the coils, indicated in Figure 3 by the empty arrows. In order to prevent the homodimerization of these coils, charged residues are included in the design. For example, the electrostatic interactions between glutamic acid and lysine residues prevent an E coil from binding with an E coil. We selected the use of E3/K3 coiled-coils over other synthetic E/K coils, as the isoleucine residue present shows a significant increase in the heterodimerization over valine found in other coils. The alpha-helical propensity of the residues outside of the core interacting residues is also increased by utilizing an alanine residue instead of the serine residue found in ISAL and VSAL E/K coils. This selection maximizes the stability and specificity of the coils used in our system.

IAAL E3/K3 Coil Helical Wheel Diagram

Figure 3. A helical wheel representation of the IAAL E3/K3 coiled-coil heterodimer viewed as a cross-section based off of a similar figure created by Litowski and Hodges (2002). The peptide chain propagates into the page from the N- to the C- terminus. Hydrophobic interactions between the coils are indicated by the clear wide arrows. The intermolecular electrostatic interactions between the coils are displayed by the thin curved arrow (eg. Between Glu15 and Lys20) Letters a, b, c,and d designate the positions of IAAL repeat in the heptapeptide. The e and g positions are occupied by the charged residues.

What did we construct?

The first construct we created involved attaching the previously mentioned E coil biobrick to the fusion of heavy and light chains of ferritin. (BBa_K1189018, BBa_K1189037) (Figure 4). This construct would assemble to form a 12-subunit nanoparticle with E coils on the outside that would each bind a protein containing the respective K coil. This means we can simply attach the K coil to a protein of choice, such as a TALE in order to bind it to the ferritin scaffold (BBa_K1189018, BBa_K1189037) Therefore we constructed the respective K coil-TALE fusion constructs, BBa_K1189029 and BBa_K1189030 (Figure 5 & 6). The ideal result of this system is that BBa_K1189029 and BBa_K1189030 will be bound to ferritin, resulting in a protein complex containing 12 TALE proteins bound to the ferritin scaffold through E/K coils. This system then allows the proteins to properly fold while at the same time allowing the ferritin nanoparticle to assemble without interference.

FerriTALE

Figure 4. Schematic for the ferritin disubunit-E coil fusion protein (BBa_K1189018).

FerriTALE

Figure 5. Schematic of the TALE A fused to the K coil (BBa_K1189029).

Figure 6. Schematic of the TALE B fused to the K coil (BBa_K1189030).

So do These Coils Actually Bind?

After putting in gratuitous effort to build parts containing these coils and successfully purifying these proteins we wanted to determine if the E and K coils interacted with each other. In order to characterize coil-coil interaction we performed an immunoprecipitation (IP) assay. We built a GFP with an E coil ( BBa_K1189014) and we also built TALE-B with a K coil (BBa_K1189030). To characterize the binding of the coils we pulled down with either an immunoglobulin G antibody (IgG) that serves as a negative control or with GFP antibody. The idea behind this experiment is to pull down the E coil which is fused to GFP with a GFP antibody and then probe with a anti-his antibody which recognizes the his tag on the TALE fused to the K coil. Upon interaction between the E and K coils we will see an output at approximately 86 kDa when probed with a His-antibody as seen in Figure 7. Our test groups included the coils by themselves and both the E and K coils put together in solution. As seen in Figure 7 a band appears only when we pull E and K coil with a GFP and probe with an anti-his antibody indicating the presence of both GFP and TALE in the elution solution indicating that the coils interact with each other.

Figure 7. Immunoprecipitation assay showing that the E and K coils interact with each other. The first three lanes show E coil, K coil and E coil with K coil pulled down with IgG (control) antibody. The last three lanes were pulled down with a anti-GFP antibody and probed with a anti-his antibody. The E coil is fused to GFP BBa_K1189014 and the K coil is fused to TALE with a his tag BBa_K1189030. Therefore, if we pull down with GFP and probe with his-antibody a band would appear the size of TALE. This indicates that both the GFP and the TALE are present and that is possible upon coil-coil interaction.

Ferritin Scaffold

FerriTALE

Figure 8. Ribbon visualization of the the final construct, composed of the ferritin-E coil scaffold (BBa_K1189018, BBa_K1189037) bound to TALE-K coil detector (BBa_K1189030).

The ferritin scaffold we chose to use, BBa_K1189018, allows us to modulate our system as we wish. We determined the ferritin-coiled-coil system could be used for more than the detection of our E.coli sequence. The ferritin scaffold can detect other sequences of DNA by exploiting the ability of the TALE system to be easily engineered and modified, along with the interchangeability of the coiled-coil system. Thus by attaching K coils to TALEs that target alternative sequences, we can use this system as a platform for any variety of DNA sequences. In our system, we utilized two TALE proteins, TALE A and TALE B (BBa_K1189029, BBa_K1189030). These two parts were both created with the K coil, allowing us to use the same ferritin scaffold (BBa_K1189018, BBa_K1189037) to anchor our proteins. This proved to be incredibly useful in binding the TALE proteins to nitrocellulose, a process that typically requires chemical modifications and specialized proteins in order to ensure the active site of these proteins are functional. Instead, we could interchange TALE A for TALE B on the ferritin scaffold due to our coiled-coil system. The protein complex can then simply be blotted onto our nitrocellulose strip, ensuring at minimum, the upwards-facing TALEs will be able to bind DNA. Furthermore, we can expand this system towards proteins and other molecules as well by replacing the TALEs with antibodies or other binding proteins. The use of coils on the ferritin scaffold also proves useful to prevent the TALE proteins in our FerriTALE from interrupting the self-assembly of ferritin due to our large size. An experiment which can be viewed on our Prussian blue ferritin page was used to demonstrate the viability of these coils for bringing our FerriTALE together. By examining the catalytic activity of our Prussian blue ferritin we could evaluate whether the direct fusion of TALEs or the use of coils was more effective for our system. The results of this experiment showed that using coils to bind our TALEs is the most effective route.

Another aspect of the ferritin nanoparticle that can be exploited is its composition, being composed of 24 subunits, as well as its potential as a novel reporter. Ferritin is typically composed of two chains, heavy and light. In our system, each one of these subunits can be bound to a reporter, effectively amplifying our catalytic activity by 24 due to the increased number of bound reporter proteins. But this activity can be scaled down through previously reported heavy-light chain fusions (Huh and Kim, 2003). Rather than 24 subunits the nanoparticle would be reduced to 12 subunits, as in our system, and thus the number of reporter proteins would decrease accordingly. We can scale this down even further due to our ability to transform the iron core of the protein into a catalytic active substance called Prussian Blue (Zhang et al., 2013). Thus, instead of multiple bound reporter proteins we can further scale down the output of our system to one with essentially one reporter. The ability of our system to scale up and down according to the need of detection means this system is applicable in areas ranging from low sensitivity to high sensitivity.