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<span class="tekst1BI">Dig Even Deeper</span><br />
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Introduction - A Universal Biosensor
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With today’s technology and knowledge, ground-breaking drug discoveries are at the forefront of the medical sciences and society. For many diseases, however, the foundation of curing lies not exclusively in the availability of these sophisticated drugs, but rather in an accurate and early diagnosis. For colon cancer, for example, the survival rate of patients diagnosed at the early stage is 90%, whereas the survival rate of patients diagnosed in the critical stage is a mere 13% <a name="reft1" href="#ref1" class="textanchor">[1]</a>. Similar figures hold for many more diseases. <image src="https://static.igem.org/mediawiki/2015/8/87/TU_Eindhoven_Ingeklapt.png" id="spoilerbutton1" class="spoilerbutton" onclick="changeImage(this.id, this.value)" /><br /><div class="spoiler" id="spoiler1">
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Without diving too much in the details, one can see that a simple Google search already yields many reports underlining the importance of an early detection of disease for <a href=' http://www.alz.org/documents_custom/final_world_alz_report_2011_summary.pdf' target='_blank'>Alzheimer’s disease</a> and <a href='http://www.amcp.org/data/jmcp/June04Supplement1.pdf' target='_blank'>Multiple Sclerosis</a>.
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<li>See our <a href="https://2015.igem.org/Team:TU_Eindhoven/Notebook">Notebook</a></li>
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<li>See our <a href="https://2015.igem.org/Team:TU_Eindhoven/Project/Protocols">Protocols</a></li>
Making an early biomedical diagnosis is thus often of vital importance.
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Such diagnoses can be made in multiple ways. Often, they are made using analytical instruments, such as MRI scanners, NMR and mass spectrometry. These instrumentation methods can provide rich information on both the structure as well as the concentration of disease markers <a name="reft2" href="#ref2" class="textanchor">[2]</a>. Even though these instruments can come to a sound diagnosis, they have a profound disadvantage: samples often need to be pre-treated and diagnoses cannot be made on-site, leading to prolonged processing times.
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Due to this disadvantage, biosensors have found their way into society. In contrast to analytical instruments, biosensors can quickly diagnose a disease, can be used on-site and are often easy to use. iGEM TU Eindhoven has devised to develop a universal platform for biosensors. The designed platform is constructed from three major elements, being the recognition element which is used to detect disease markers, the signaling components which translate the detection into a measurable signal and a scaffold which joins the signaling components and recognition elements. An overview of the elements is presented below.
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The Recognition Element – Aptamers
 
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Since the discovery of the nucleic acid structure, nucleic acids were long thought to have a single function – storage of the heredity information as genetic instructions. Our perception on the function of DNA and RNA changed radically, however, as it was discovered that small RNA molecules could fold into a three-dimensional structure, exposing a surface onto which other small molecules could perfectly fit.
 
Soon after the discovery that nucleic acids could have interaction with other molecules, Craig Tuerk and Larry Gold described a procedure, called SELEX, to isolate high-affinity nucleic acid ligands for proteins through a Darwinian-like evolution process carried out in vitro <a name="reft3" href="#ref3" class="textanchor">[3]</a>
 
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<img src="https://static.igem.org/mediawiki/2015/e/ea/TU_Eindhoven_SELEX.png" alt="SELEX" class="spoilerimage">
 
SELEX is an acronym for Systematic Evolution of Ligands by EXponential enrichment. The process is carried out in vitro and requires a very large oligonucleotide library (~10<sup>15</sup> members), which can be generated by combinatorial DNA Synthesis. SELEX starts with incubation of the library with the target molecule. This incubation is followed by a washing step which ensures that only oligonucleotides with higher affinities are selected. Next, the oligonucleotides which are still present in the mixture after the washing step are recovered and amplified. During this amplification step, mutations are introduced into the oligonucleotides, yielding a new library. This library may again be incubated with the target molecule. Typically, these steps are repeated 8-15 times. In the last round of SELEX the oligonucleotides still present in the mixture are identified by sequencing.
 
 
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This procedure enabled researchers to discover oligonucleotides with high affinities and a perfect fit for arbitrary proteins, cells, small molecules and even viruses. After this perfect fit, these synthetic oligonucleotides were called ‘aptamers’ – stemming from the Latin aptus which can be translated into ‘fit’.
 
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The Rise of Aptamers
 
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25 Years after the discovery of Tuerk’s and Gold’s invention of Systemic Evolution of Ligands by Exponential enrichment (SELEX), aptamers have become available for hundreds of ligands, including proteins, viruses, other small molecules and even whole cells
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See how modelling helped us understand our device</span>
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<br />Aptamer sequences have been published for over 500 ligands. These ligands include small molecules, viruses, proteins and whole cells. Among these are some very notable ligands, such as HIV, cancerous cells and ricin, the extremely toxic compound which plays a prominent role in the critically acclaimed Breaking Bad series. These figures were obtained through Aptamer Base, a collaboratively created knowledge base about aptamers and the experiments that produced them, curated and maintained by a team of aptamer researchers. For more information, visit <a href="http://aptamerbase.semanticscience.org/" target="_blank"> Aptamer Base's website</a>
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As such, aptamers have become a viable alternative for biology’s traditional recognition elements, antibodies.
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Aptamers also provide numerous advantages over antibodies. As mentioned, aptamers are oligonucleotides whereas antibodies are proteins. As such, aptamers have a remarkable stability in a wide range of pH and temperatures, have higher shelf lifes, are non-toxic and lack immunogenicity [<a name="reft4" href="#ref4" class="textanchor">4</a>, <a name="reft5" href="#ref5" class="textanchor">5</a>]. Other advantages stem from the fact that aptamers are generated in vitro, whereas antibodies are generated through in vivo enrichment followed by purification through monoclonal cell lines <a name="reft6" href="#ref6" class="textanchor">[6]</a> . As a result, generation of aptamers is less laborious, production costs are lower and reproducibility is higher. Finally, in contrast to antibodies, aptamers can be generated against virtually any molecule, including toxins and poor immunogenic targets <a name="reft7" href="#ref7" class="textanchor">[7]</a> . This places aptamers amongst the most powerful tools in biotechnology <a name="reft8" href="#ref8" class="textanchor">[8]</a> . <br />
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A major limitation of aptamers in comparison with antibodies is their stability in vivo, where nucleic acids are rapidly degraded. Aptamers which have been used as therapeutic agents, for example, suffered from a half-life of 2 minutes <a name="reft9" href="#ref9" class="textanchor">[9]</a> . This problem has, however, partially been overcome by using chemical modifications to the aptamers. An example of these modifications are Spiegelmers <a name="reft8" href="#ref8" class="textanchor">[8]</a> . These oligonucleotides’ backbones contain L-Ribose instead of R-Ribose – “spiegel” means mirror. These mirrored aptamers are more stable in vivo, because they suffer less from degradation.
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Aptamers in Biotechnology
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Since aptamers can be easily modified chemically, they can be attached to numerous surfaces, enabling their way into a wide array of biosensors and drug delivery systems. Generally, the biosensors couple binding of the aptamer to a change in structure in the latter, which generates either a fluorescent or electrical signal. Aptamers have also found their way into drug delivery systems. A particular example of such a system is developed by Wu et al., featuring aptamers targeted at cancer cells with lipid tails. These aptamers could be used as building blocks of micelles, enabling efficient delivery of the micelles to cancerous cells <a name="reft10" href="#ref10" class="textanchor">[10]</a> .
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Aptamers in our Biosensor
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Aptamers constitute the ideal sensor domain for our universal membrane sensor: they can be targeted at virtually any molecule, can easily be attached to the membrane using SPAAC chemistry and offer affinities similar to antibodies. Taking into account their remarkable stability and small size, they are unmatched by the traditional recognition elements of biotechnology, antibodies. An essential requirement for our system which limits the choice of aptamers is bifunctionality: the system relies on bringing two membrane proteins in close proximity by binding the ligand with two different moieties. Conceptually, this bifunctionality can be reached either through the use of dual aptamers or through the use of split aptamers.
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Figure 2: Bifunctionality is required to bring the membrane proteins into close proximity.
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Dual Aptamers
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The first way in which bifunctionality can be reached is through the use of dual aptamers acting on different binding sites, called apitopes. A well-known example of a ligand for which dual aptamers are available is human thrombin. A drawback of the use of dual aptamers is that these are in general not available for small molecules and viruses, significantly reducing the available targets for the aptamers. The main target for dual aptamers are proteins. <br /><br /><br /><br /><br />
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Figure 3: Some ligands have multiple apitopes, such that a dual approach can be taken (see A). Thrombin (yellow) is one of the protein ligands which has two apitopes, allowing different aptamers to bind at different spots
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Split Aptamers
 
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Alternatively, aptamers can be split into two parts. These parts can form heterodimers and thereby self-assemble into the three-dimensional structure required for binding the apitope. A crucial choice in engineering split aptamers is the choice of splitting site <a name="reft11" href="#ref11" class="textanchor">[11]</a> . This choice is often not straightforward and the aptamer often suffers from a significantly decreased affinity. Obtaining split aptamers is, however, still in its infancy: of the approximately 100 small-molecule-binding aptamers, only six have been successfully engineered into split aptamers <a name="reft11" href="#ref11" class="textanchor">[11]</a>. <br /><br /><br />
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    We have designed a universal membrane platform which is inherently modular and can elicit both slow as well as fast responses. To verify the viability of the platform, we devised characterizing the fast cellular responses. In the construction of our device, we planned on conducting a wide range of experiments to verify whether the individual elements of our system worked. These elements include whether the click reaction occurs, verifying whether the signaling components work, whether proximity invokes a response and whether the DBCO-modified aptamers work. An overview of the experiments is given below.
 
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Figure 4: Small molecules generally have only a single apitope. An alternative to the dual approach is the construction
 
of split aptamers (see A). Engineering of split aptamers is complicated, but split-aptamers for three-way junction aptamers could be obtained through the method shown under B. The second image is adapted from Kent et al. <a name="reft11" href="#ref11" class="textanchor">[11]</a>.
 
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The Scaffold - OmpX
 
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To realize conduction of a signal over the cell membrane, the aptamers have to be attached to a membrane protein. A procedure to attach oligonucleotides to membrane proteins has succesfully been tested by iGEM TU Eindhoven 2014. They presented this procedure as a part of their Click Coli project to the iGEM community. The procedure exploits the SPAAC reaction, which is one of the most well-described click chemistry reactions available (see Figure 5). <br /><br /><br />
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Verifying the click reaction
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Figure 5: Strain-promoted Azide-Alkyne Cycloaddition (SPAAC) is a well known click-chemistry reaction.
 
The reaction features two molecules, one functionalized with an azide group (A) and one functionalized
 
with a cyclooctyne group (B). SPAAC is very efficient and selective, no further reagents have to
 
be added to the reaction method and the reaction is completely bio-orthogonal. This image was adapted
 
from last year’s iGEM team’s wiki.
 
 
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As a proof of concept, iGEM TU Eindhoven employed two membrane proteins as anchors, to
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A vital aspect of our device is clicking the aptamers to the membrane proteins. For this click, we made use of the exact same click chemistry used by iGEM TU Eindhoven 2014. The click reaction was used N-terminally by iGEM TU Eindhoven 2014, in order to minimize sterical strain. To analyze whether the localization of the azide-functionalized amino acid within the loops of OmpX impedes the click reaction, we clicked a DBCO-functionalized fluorophore (TAMRA) to the outer membrane proteins (see Figure 1). After some washing steps and spinning down, we expected the cells to remain fluorescent.  
which they anchored DNA. These membrane proteins were CPX and INPNC. CPX in particular
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CPX &amp; OmpX
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CPX is a membrane display protein developed by Rice et al. as an alternative to traditional display
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methodologies, such as yeast display and phage display <a name="reft12" href="#ref12" class="textanchor">[12]</a>. The protein itself is derived from the
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naturally occuring Outer membrane protein X (OmpX) through circular permutation (see Figure
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6). Circular permutation was a necessary step to obtain the termini on the exterior of the bacterial
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Figure 6: CPX (right) is a membrane protein derived from OmpX (left) through circular permutation.
 
OmpX and CPX feature signal sequences (yellow) which ensure that the membrane protein is localized
 
to E.coli’s outer membrane. These signal sequences are cleaved from the peptides after localization. In
 
CPX, an Amber stop codon was introduced to introduce a non-natural azide-functionalized amino acid.
 
 
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iGEM Eindhoven 2014 inserted an Amber stop codon (TAG) at the N-terminus to enable expression
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of an azide-functionalized amino acid. This amino-acid could be used to attach DBCO-functionalized
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molecules to the membrane protein, allowing synthetic biologists to attach virtually
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any molecule to the cell membrane (see Figure 7). The now azide-functionalized CPX-protein was
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Figure 1: To verify whether the click reaction has occured, we incubate the cells with DBCO-functionalized TAMRA. If the outer membrane protein is functionalized with the unnatural amino acid, this TAMRA dye binds to the membrane proteins covalently. In that case, the cells will remain fluorescent after a few washing steps.
dubbed Clicker Outer Membrane Protein x (COMPx) by iGEM TU Eindhoven 2014. <br />
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Figure 7: The azide-functionalized amino acid enables clicking any DBCO-functionalized molecule to
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be attached to the cell membrane through SPAAC-click chemistry. iGEM TU Eindhoven 2014 called this
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To enable signaling over the outer membrane, our system requires intracellular signaling domains.
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Unfortunately, the COMPx developed and characterized by last year’s iGEM team does
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intracellular domains, we devised to revert to go back to the basis and use OmpX rather than CPX
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Figure 8: For our signaling proteins, we revert to the basis: OmpX. We functionalize OmpX by introducing
 
the Amber stop codon into its loops (red). The signaling domains are fused to OmpX C-terminally,
 
since the N-terminus is occupied by the signaling sequence (yellow). The signaling sequence is cleaved
 
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The Loops
 
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The Amber stop codon will be incorporated in the protruding loops of OmpX. We have chosen
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Since the fluorescence of the TAMRA-dye falls within the visible spectrum, we expected to see whether the dye clicked on the outer membrane proteins with the naked eye. To analyze the fluorescence at the single-cell level, we measured cells using the Fluorescence-Activated Cell Sorter (FACS).
to introduce the mutations into the loops since they are easily accesible and are not a part of the
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<img src="https://static.igem.org/mediawiki/2015/8/87/TU_Eindhoven_Ingeklapt.png" id="spoilerbutton1" class="spoilerbutton">
beta-barrel of OmpX [2]. Hence, we believe that mutations in the loops will not disturb the secondary
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structure of OmpX (see Figure 9B). <br />
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<img src="https://static.igem.org/mediawiki/2015/7/7f/TU_Eindhoven2015_FACS.png" alt="FACS" class="spoilerimage" />
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<!-- <div class="spoilerimagetext">Figure B: General overview of the FACS. Lasers are used to detect single cells and characterize their fluorescent properties.</div> -->
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Figure 9: A) The OmpX protein structure has been elucidated through NMR and X-ray crystallography,
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B) the square residues are important for the secondary structure of OmpX. To keep the structure
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intact, we introduce an amber stop codon in one of the protruding loops. Figure 5B is adapted from <a name="reft13" href="#ref13" class="textanchor">[13]</a>.
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A Fluorescence-Activated Cell Sorter (FACS) is a specialized flow cytometer (see Figure B). The FACS can provide information about cell size, complexity and fluorescence.
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The relative cell complexity is measured using size scatter (SSC).
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The relative cell size is measured using forward scatter (FSC).
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The fluorescence can be measured by using a wide range of filters.  
The to be substituted residues in the loops were chosen in such a way that the clicked aptamer would protrude from
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OmpX. Moreover, residues were selected such that the signaling proteins structure closely resembles OmpX natural’s
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structure. The serine residue in loop 2 was chosen since it was the only available residue with side-groups
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pointing outward from OmpX. The tyrosine residue in loop 3 was chosen both because tyrosine closely resembles
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Figure 10: The non-natural azide-functionalized amino acid closely resembles tyrosine
 
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Measuring bioluminiscence & fluorescence
The Signaling Components - NanoLuc &amp; Neongreen
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Quite paradoxically, the number of signaling proteins pales in comparison with the vast amount of
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cellular responses. This signaling paradox can be explained by the fact that cells employ amazingly
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complex signaling pathways, which feature signal amplification, signal integration and cross communication
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<a name="reft14" href="#ref14" class="textanchor">[14]</a>. In addition to the vast amount of effects signaling pathways can have, these pathways
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operate over a staggering range of time scales: some signaling pathways act within less than
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a second, whereas others affect cell behavior only after hours or days.<br />
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An essential aspect of a universal membrane sensor is that it allows for these wide ranges of time
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scales and responses. We believe that the modularity of our membrane sensor and the complexity
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of intracellular cell signaling allows for a wide range of responses. To enable the sensors to act
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upon a wide range of time scales we consider multiple intracellular signaling components. These
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components all respond to a decrease in mutual distance of the membrane proteins as a result of
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ligand binding.
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A crucial element in the sensor system is the reporter system. For our COMBs, we have considered several options for reporter systems. As a proof of concept, we will use the split luciferase (NanoBiT) and BRET reporter systems. Both these reporter systems can easily be followed through the measurement of bioluminescence and fluorescence.
Fast Signaling Components - Exploiting Bioluminiscence
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<br />
 
<br />
 
<br />
<span class="tekst1">
+
The NanoBiT reporter system is a split luciferase system. The system can only generate a response if both parts of the split luciferase system, LgBiT and SmBiT, are available and in close proximity. Moreover, the substrate furimazine has to be present to obtain a signal.
Two well-known principles to translate a close proximity into a measurable signal are Resonance
+
Energy Transfer and the use of split luciferases. Even though these principles are very different,
+
both response elements emit light, yielding a measurable signal. After ligand binding, these signaling
+
components yield an virtually immediate response.
+
 
<br />
 
<br />
 
<br />
 
<br />
</span>
+
The BRET system relies on the presence of a bioluminescent and fluorescent protein. In our system, we have used NanoLuc in combination with mNeonGreen. To verify the presence of NanoLuc, a bioluminescent assay will be conducted. To verify the presence of mNeonGreen, fluorescence will be measured.
  
 
<div id="imageText">
 
<img class="left1" src="https://static.igem.org/mediawiki/2015/1/19/TU_Eindhoven_Design_Signalling.png" />
 
<div class="right1">
 
<span class="caption">
 
<br />
 
<br />
 
<br />
 
Figure 11 - Resonance energy transfer (A) and split luciferases (B) both translate close proximity into a
 
measurable signal in the form of light.
 
 
</span>
 
</span>
</div>
+
<br /><br />
</div>
+
 
+
<br />
+
<br />
+
  
  
<h2>
+
<br /><hr><br />
Fast Signaling Components - Explointing Bioluminiscence
+
<h1 id="h1-3">
</h2>
+
Verifying whether oligonucleotides click</h1><br />
 
<br />
 
<br />
<br />
+
<span class="tekst1">A third verification step is to see whether or not the click reaction takes place and if this click reaction takes place equimolarly. Therefore, oligos will be clicked to the outer membrane proteins and incubated with complementary strands that are fluorescently labeled (see Figure 2). After some washing steps and spinning down, it is expected that the fluorescent strands will remain if and only if the oligos succesfully click. Thereby, fluorescence indicates whether oligonucleotides can be succesfully clicked to the COMBs.
<span class="tekst1">
+
<div class="imageText">
Resonance Energy Transfer is a physical process which can take place between fluorophores light
+
<img class="left1" src="https://static.igem.org/mediawiki/2015/8/8f/TU_Eindhoven_Oligos_Verification.png" alt="Verifying Oligos Click" />
emission when they are in close proximity (1-10nm) [15]. An electron which has been transferred to
+
<div class="right1">
its ‘excited state’ falls back to its ‘ground state’. The energy which is released by the electron falling
+
<span class="caption"><br /><br />
back to its ground state is normally released in the form of light. In the case of Resonance Energy
+
Figure 2: To verify whether the click reaction has occured with DBCO-modified DNA, we incubate the cells with DBCO-functionalized complementary strands. If the DBCO-modified DNA clicks, the fluorescently labeled DBCO-functionalized complementary strands will anneal with the clicked strands. In that case, the cells will remain fluorescent after a few washing steps.
Transfer, however, the energy of the electron falling back to its ground state is not released in the
+
<br /><br />
form of light, but coupled to a transition of an electron in the RET Acceptor to from its ground state
+
</span>
to the excited state (see Figure 12).  
+
</div>
<br />
+
<br />
+
</span>
+
<div id="imageText">
+
<img class="left1" src="https://static.igem.org/mediawiki/2015/7/72/TU_Eindhoven_Design_SignallingFret.png" />
+
<div class="right1">
+
<span class="caption">
+
<br />
+
<br />
+
Figure 12 - Simplified energy-level diagram of RET. Panel A): Normally, an excited electron falls back to
+
its ground state under the emission of light (a radiative transition). Panel B): In the case of Resonance
+
Electron Transfer, an excited electron in the donor falls back to its ground state. This transition is coupled
+
to the excitation of an electron in the acceptor. This excited electron falls back normally under the
+
emission of light.
+
</span>
+
</div>
+
 
</div>
 
</div>
 +
<br /><hr><br />
 +
<h1 id="h1-4">
  
 +
DNA Strand Displacement
 +
</h1>
  
<br />
+
<br /><br />
<br />
+
  
 
<span class="tekst1">
 
<span class="tekst1">
The efficiency of Resonance Energy Transfer is known to be dependent on a few factors, most
+
As we have already touched upon lightly, it has long been thought that nucleic acids had only a single role: carrying hereditary information. As discussed, the discovery that DNA could fold into higher-order structures gave way to SELEX, an evolutionary method of discovering aptamers. The construction of DNA nanostructures, however, was not only carried out through a combinatorial approach; the specificity and predictability of Watson-Crick basepairing enabled rational design for engineering at the nanoscale <a href="#ref1" name="reft1">[1]</a>. Initially, the designed DNA nanostructures were mostly static, but dynamic nanostructures have become available over the years. Most of these dynamic nanostructures share a common feature: they exploit a biophysical phenomenon known as DNA strand displacement.
importantly the relative orientation of the chromophores as well as the mutual distance of the
+
<img src="https://static.igem.org/mediawiki/2015/8/87/TU_Eindhoven_Ingeklapt.png" id="spoilerbutton4" class="spoilerbutton">
chromophores [15]. A decreased mutual distance between the donor and acceptor increases the
+
<div class="spoiler" id="spoiler4">
efficiency very significantly. This feature of Resonance Energy Transfer is exploited in the design
+
DNA strand displacement is the workhorse of dynamic DNA technology, the field which uses DNA’s non-covalent interactions to assemble higher-order structures. It is a process where two strands with partial complementarity are hybridized. These pre-assembled DNA strands have only partial complementary, leaving room for a toehold region. When a DNA sequence with full complementary binds to this region (the input), branch migration takes place (see the figure below). In the end, the sequence with full complementary binds to the sequence, yielding the output.
of our membrane sensor.
+
<img src="https://static.igem.org/mediawiki/2015/7/75/TU_Eindhoven_DNA_Displacement.png" alt="DNA Strand displacement" class="spoilerimagec">
As a result of the reduced distance between the RET-donor and RET-acceptor, Resonance Energy
+
<br />
Transfer is thus more efficient. As a result, relatively more light will be emitted by the acceptor
+
<span class="caption">
when the lgiand is bound. The resulting signal is thus, per definition ratiometric. As a result of
+
Figure C: Schematic overview of DNA strand displacement. DNA Strand displacement is initiated when the input binds to the toehold region of a partially hybridized DNA strand. After the initiation, branch migration takes place and the input fully hybridizes with its perfect match, yielding the output.
ligand binding, intensity of the light emitted by the donor will decrease and intensity of the light
+
</span>
emitted by the acceptor will increase (see Figure 13).
+
</div>
 +
<br />
 +
DNA strand-displacement is a very robust technology; the sequences of the used strands often go unreported as they play a minor role. The robustness of the technology enabled rational design of numerous nanostructures. These nanostructures include DNA walkers, strand displacement cascades and self-assembling dendrimers <a href="#ref1" name="reft1">[1]</a>.
 +
<br /><br />
 +
In our project, we want to bring two membrane proteins in close proximity through aptamers. To test whether a close proximity indeed triggers an intracellular signal, we used DNA to bring the membrane proteins in close proximity. DNA is the ideal probe for this purpose, as its high specificity and predictability allowed us to bring the membrane proteins in vicinity. To make the system with DNA reversible, we designed a simple system exploiting the strand displacement (see Figure 3).
 +
<br />
 
</span>
 
</span>
  
<br />
+
<br /><br />
<br />
+
  
<div id="imageText">
+
<div class="imageText">
<img class="left1" src="https://static.igem.org/mediawiki/2015/c/c7/TU_Eindhoven_Design_SignallingFret2.png" />
+
<img class="left1" src="https://static.igem.org/mediawiki/2015/3/3e/TU_Eindhoven_DNAStrandDisplacement_System.png" />
<div class="right1">
+
<div class="right1">
<span class="caption">
+
<span class="caption">
<br />
+
Figure 3: The membrane proteins can be brought in close proximity by clicking oligonucleotides on the loops and adding a long strand complementary to both oligonucleotides. It is expected that this results in a measurable signal. The longer strand is functionalized with a toehold region. Upon addition of a strand perfectly complementary to the longer strand, the system disassembles and the signal will fade out.
<br />
+
<br /><br />
Figure 13 - Panel A): Efficient energy transfer is not possible since the donor and fluorophore are to remote.
+
</span>
Panel B): Efficient energy transfer is possible due to the proximity of the donor and acceptor. As a
+
</div>
result, light intensity of the donor decreases whereas light intensity of the acceptor increases.
+
</span>
+
</div>
+
 
</div>
 
</div>
  
<h2>
+
<br /><br /><br /><hr><br />
Split Luciferases
+
 
</h2>
+
<div class="references">
<br />
+
<span class="caption">
<br />
+
<a href="#reft1" name="ref1">[1]</a> Zhang D.Y. and Seelig G., “Dynamic DNA nanotechnology using strand-displacement reactions.,” Nat. Chem., vol. 3, no. 2, pp. 103–13, Mar. 2011. <br />
 +
</span>
  
<span class="tekst1">
 
Luciferases are naturally occuring proteins which convert a substrate to a product and light.
 
Many organisms feature luciferases to produce light, such as the sea spansy, fireflies and shrimps.
 
These luciferases have been isolated from these organisms and can be succesfully used in vitro to
 
produce light.
 
Some luciferases have also been succesfully split into two complementary parts. These complementary
 
parts can self-assemble into the functional luciferase, restoring its functionality to emit
 
light by converting the substrate. As such, these split luciferases have become a major tool to
 
study protein-protein interactions: these interactions are coupled to a close proximity of the proteins,
 
allowing the parts to assemble into the functional luciferase and emit light (see Figure 14).
 
We use these split luciferases in addition to BRET as a rapid signaling component.
 
</span>
 
<br />
 
<br />
 
  
<div id="imageText">
 
<img class="right1" src="https://static.igem.org/mediawiki/2015/2/26/TU_Eindhoven_Design_Signalling_split.png" />
 
<div class="left1">
 
<span class="caption">
 
<br />
 
<br />
 
Figure 14 - Panel A): The split parts of the luciferase are too remote to assemble into the functional luciferase,
 
Panel B): Upon ligand binding, the two luciferases can self-assemble into the functional luciferase,
 
restoring its capability to produce light from the substrate, yielding a measurable signal.
 
</span>
 
</div>
 
 
</div>
 
</div>
  
 
<br />
 
<hr>
 
<br />
 
 
<div class="references">
 
<span class="caption">
 
<a href="#reft1" name="ref1">[1]</a> American Cancer Society. Colorectal Cancer Facts & Figures 2011-2013. Atlanta: American Cancer Society, 2011. <br />
 
<a href="#reft2" name="ref2">[2]</a> W. Zhou, P.-J. J. Huang, J. Ding, and J. Liu, “Aptamer-based biosensors for biomedical diagnostics.,” Analyst, vol. 139, no. 11, pp. 2627–40, 2014.<br />
 
<a href="#reft3" name="ref3">[3]</a> C. Tuerk and L. Gold, “Systematic evolution of ligands by exponential enrichment: RNA ligands to bacteriophage T4 DNA polymerase.,” Science, vol. 249, no. 4968, pp. 505–10, Aug. 1990.<br />
 
<a href="#reft4" name="ref4">[4]</a> D. Musumeci and D. Montesarchio, “Polyvalent nucleic acid aptamers and modulation of their activity: A focus on the thrombin binding aptamer,” Pharmacol. Ther., vol. 136, no. 2, pp. 202–215, 2012.<br />
 
<a href="#reft5" name="ref5">[5]</a> A. Cibiel, C. Pestourie, and F. Ducongé, “In vivo uses of aptamers selected against cell surface biomarkers for therapy and molecular imaging,” Biochimie, vol. 94, no. 7, pp. 1595–1606, 2012.<br />
 
<a href="#reft6" name="ref6">[6]</a> L. H. Lauridsen and R. N. Veedu, “Nucleic acid aptamers against biotoxins: a new paradigm toward the treatment and diagnostic approach.,” Nucleic Acid Ther., vol. 22, no. 6, pp. 371–9, 2012.<br />
 
<a href="#reft7" name="ref7">[7]</a> A. Rhouati, C. Yang, A. Hayat, and J. L. Marty, “Aptamers: A promosing tool for ochratoxin a detection in food analysis,” Toxins (Basel)., vol. 5, no. 11, pp. 1988–2008, 2013.<br />
 
<a href="#reft8" name="ref8">[8]</a> F. Radom, P. M. Jurek, M. P. Mazurek, J. Otlewski, and F. Jeleń, “Aptamers: Molecules of great potential,” Biotechnol. Adv., vol. 31, no. 8, pp. 1260–1274, 2013.<br />
 
<a href="#reft9" name="ref9">[9]</a> B. J. Hicke, A. W. Stephens, T. Gould, Y.-F. Chang, C. K. Lynott, J. Heil, S. Borkowski, C.-S. Hilger, G. Cook, S. Warren, and P. G. Schmidt, “Tumor Targeting by an Aptamer,” J. Nucl. Med., vol. 47, no. 4, pp. 668–678, Apr. 2006.<br />
 
<a href="#reft10" name="ref10">[10]</a> Y. Wu, K. Sefah, H. Liu, R. Wang, and W. Tan, “DNA aptamer-micelle as an efficient detection/delivery vehicle toward cancer cells.,” Proc. Natl. Acad. Sci. U. S. A., vol. 107, no. 1, pp. 5–10, 2010.<br />
 
<a href="#reft11" name="ref11">[11]</a> A. D. Kent, N. G. Spiropulos, and J. M. Heemstra, “General approach for engineering small-molecule-binding DNA split aptamers,” Anal. Chem., vol. 85, no. 20, pp. 9916–9923, 2013.<br />
 
<a href="#reft12" name="ref12">[12]</a> J. J. Rice, A. Schohn, P. H. Bessette, K. T. Boulware, and P. S. Daugherty, “Bacterial display using circularly permuted outer membrane protein OmpX yields high affinity peptide ligands.,” Protein Sci., vol. 15, no. 4, pp. 825–36, Apr. 2006.<br />
 
<a href="#reft13" name="ref13">[13]</a> J. Vogt and G. E. Schulz, “The structure of the outer membrane protein OmpX from Escherichia coli reveals possible mechanisms of virulence.,” Structure, vol. 7, no. 10, pp. 1301–9, Oct. 1999.<br />
 
<a href="#reft14" name="ref14">[14]</a> W. Alberts, Johnson, Lewis, Raff, Roberts, Molecular Biology of The Cell. Pearson, 2005.<br />
 
<a href="#reft15" name="ref15">[15]</a> I. Medintz and N. Hildebrandt, Eds., FRET - Förster Resonance Energy Transfer. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2013. <br />
 
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Latest revision as of 03:48, 19 September 2015





Experimental approach



We have designed a universal membrane platform which is inherently modular and can elicit both slow as well as fast responses. To verify the viability of the platform, we devised characterizing the fast cellular responses. In the construction of our device, we planned on conducting a wide range of experiments to verify whether the individual elements of our system worked. These elements include whether the click reaction occurs, verifying whether the signaling components work, whether proximity invokes a response and whether the DBCO-modified aptamers work. An overview of the experiments is given below.




Verifying the click reaction



A vital aspect of our device is clicking the aptamers to the membrane proteins. For this click, we made use of the exact same click chemistry used by iGEM TU Eindhoven 2014. The click reaction was used N-terminally by iGEM TU Eindhoven 2014, in order to minimize sterical strain. To analyze whether the localization of the azide-functionalized amino acid within the loops of OmpX impedes the click reaction, we clicked a DBCO-functionalized fluorophore (TAMRA) to the outer membrane proteins (see Figure 1). After some washing steps and spinning down, we expected the cells to remain fluorescent.

Device Overview


Figure 1: To verify whether the click reaction has occured, we incubate the cells with DBCO-functionalized TAMRA. If the outer membrane protein is functionalized with the unnatural amino acid, this TAMRA dye binds to the membrane proteins covalently. In that case, the cells will remain fluorescent after a few washing steps.



Since the fluorescence of the TAMRA-dye falls within the visible spectrum, we expected to see whether the dye clicked on the outer membrane proteins with the naked eye. To analyze the fluorescence at the single-cell level, we measured cells using the Fluorescence-Activated Cell Sorter (FACS).
FACS A Fluorescence-Activated Cell Sorter (FACS) is a specialized flow cytometer (see Figure B). The FACS can provide information about cell size, complexity and fluorescence. The relative cell complexity is measured using size scatter (SSC). The relative cell size is measured using forward scatter (FSC). The fluorescence can be measured by using a wide range of filters. These cell characteristics can be combined to sort cells.




Measuring bioluminiscence & fluorescence



A crucial element in the sensor system is the reporter system. For our COMBs, we have considered several options for reporter systems. As a proof of concept, we will use the split luciferase (NanoBiT) and BRET reporter systems. Both these reporter systems can easily be followed through the measurement of bioluminescence and fluorescence.

The NanoBiT reporter system is a split luciferase system. The system can only generate a response if both parts of the split luciferase system, LgBiT and SmBiT, are available and in close proximity. Moreover, the substrate furimazine has to be present to obtain a signal.

The BRET system relies on the presence of a bioluminescent and fluorescent protein. In our system, we have used NanoLuc in combination with mNeonGreen. To verify the presence of NanoLuc, a bioluminescent assay will be conducted. To verify the presence of mNeonGreen, fluorescence will be measured.



Verifying whether oligonucleotides click



A third verification step is to see whether or not the click reaction takes place and if this click reaction takes place equimolarly. Therefore, oligos will be clicked to the outer membrane proteins and incubated with complementary strands that are fluorescently labeled (see Figure 2). After some washing steps and spinning down, it is expected that the fluorescent strands will remain if and only if the oligos succesfully click. Thereby, fluorescence indicates whether oligonucleotides can be succesfully clicked to the COMBs.
Verifying Oligos Click


Figure 2: To verify whether the click reaction has occured with DBCO-modified DNA, we incubate the cells with DBCO-functionalized complementary strands. If the DBCO-modified DNA clicks, the fluorescently labeled DBCO-functionalized complementary strands will anneal with the clicked strands. In that case, the cells will remain fluorescent after a few washing steps.



DNA Strand Displacement



As we have already touched upon lightly, it has long been thought that nucleic acids had only a single role: carrying hereditary information. As discussed, the discovery that DNA could fold into higher-order structures gave way to SELEX, an evolutionary method of discovering aptamers. The construction of DNA nanostructures, however, was not only carried out through a combinatorial approach; the specificity and predictability of Watson-Crick basepairing enabled rational design for engineering at the nanoscale [1]. Initially, the designed DNA nanostructures were mostly static, but dynamic nanostructures have become available over the years. Most of these dynamic nanostructures share a common feature: they exploit a biophysical phenomenon known as DNA strand displacement.
DNA strand displacement is the workhorse of dynamic DNA technology, the field which uses DNA’s non-covalent interactions to assemble higher-order structures. It is a process where two strands with partial complementarity are hybridized. These pre-assembled DNA strands have only partial complementary, leaving room for a toehold region. When a DNA sequence with full complementary binds to this region (the input), branch migration takes place (see the figure below). In the end, the sequence with full complementary binds to the sequence, yielding the output. DNA Strand displacement
Figure C: Schematic overview of DNA strand displacement. DNA Strand displacement is initiated when the input binds to the toehold region of a partially hybridized DNA strand. After the initiation, branch migration takes place and the input fully hybridizes with its perfect match, yielding the output.

DNA strand-displacement is a very robust technology; the sequences of the used strands often go unreported as they play a minor role. The robustness of the technology enabled rational design of numerous nanostructures. These nanostructures include DNA walkers, strand displacement cascades and self-assembling dendrimers [1].

In our project, we want to bring two membrane proteins in close proximity through aptamers. To test whether a close proximity indeed triggers an intracellular signal, we used DNA to bring the membrane proteins in close proximity. DNA is the ideal probe for this purpose, as its high specificity and predictability allowed us to bring the membrane proteins in vicinity. To make the system with DNA reversible, we designed a simple system exploiting the strand displacement (see Figure 3).


Figure 3: The membrane proteins can be brought in close proximity by clicking oligonucleotides on the loops and adding a long strand complementary to both oligonucleotides. It is expected that this results in a measurable signal. The longer strand is functionalized with a toehold region. Upon addition of a strand perfectly complementary to the longer strand, the system disassembles and the signal will fade out.





[1] Zhang D.Y. and Seelig G., “Dynamic DNA nanotechnology using strand-displacement reactions.,” Nat. Chem., vol. 3, no. 2, pp. 103–13, Mar. 2011.