Team:ZJU-China/project s1 2.htm

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<h2>Design</h2>
<h2>Design</h2>
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 +
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">We thought to add another aptamer onto the scaffold and construct an interaction between it and the MS2 aptamer, such that it could disrupt the binding of MS2 protein and the MS2 aptamer.</p>
+
<p align="justify">How could we make RNA scaffold tunable? We thought of riboswitch. <b class="orange">A riboswitch</b> usually consists of <b class="orange">an allosteric aptamer</b> and an expression platform. The <b class="orange">structural interaction</b> between them could inactivate gene expression. However, when a corresponding ligand is added, the interaction disappears with the <b class="orange">structural altering of the aptamer</b> and gene expression platform will be activated. It inspirited us to <b class="orange">fuse an allosteric aptamer to the basic RNA scaffold</b> to achieve the controllability of it. </p>
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">We thought about the well-known theophylline aptamer. The aptamer is a single RNA hairpin that binds theophylline in an inner loop region with high affinity. Previous studies have shown mutations in the loop region were tolerated as long as the loop structure was preserved. This allowed us to mutate the loop of the theophylline aptamer to create an interaction between the theophylline aptamer and the MS2 aptamer. The interaction inhibits the binding function of MS2 aptamer in the absence of theophylline. However, when theophylline is added, the fold of the loop is changed and thus the interaction will disappear, leading to the binding of MS2 aptamer and corresponding protein.</p>
+
<p align="justify">&nbsp;</p>  
<p align="justify">&nbsp;</p>  
-
<p align="justify">Fig.1 The control mechanism of the theophylline aptamer.</p>
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<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/c/cc/Zju_alloscaffold_riboswitch.png" width="500px" />
 +
<p class="fig"><b>Fig.1</b> The mechanism of riboswitch.</p>
 +
</div>
 +
<p align="justify">&nbsp;</p>
 +
<p>We utilized the <b class="orange">well-known theophylline aptamer</b>. The aptamer is a single RNA hairpin that binds theophylline in an inner loop region with high affinity. Previous studies have shown that mutations in the loop region were tolerated as long as the loop structure was preserved. This allowed us to mutate the loop of the theophylline aptamer to create an interaction between the theophylline aptamer and the MS2 aptamer. We <b class="orange">changed the sequence in the mutation region of theophylline aptamer by making it a complementary one of part of MS2 aptermer</b>.</p>
 +
</br>
 +
<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/igem.org/0/0c/CloverandTheophylline.png" width="350px"/>
 +
</div>
 +
<p class="fig"><b>Fig.2</b> The sequence of theophylline aptamer and the structure of theophylline. The sequence in the blue box is mutation region, while the one in the orange box is ligand-binding region.</p>
 +
</br>
 +
<p>In the absence of theophylline, <b class="orange">the interaction prevents MS2 protein from binding to MS2 aptamer</b>, so the scaffold cannot function. When theophylline is added, the interaction disappears as a result of the structural change of theophylline aptamer and the scaffold begins to work. This kind of tunable scaffold contains an allosteric aptamer, so we call them alloscaffolds.</p>
 +
</br>
 +
<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/igem.org/9/9f/Mechanism_ZJU.jpg" width="500px" />
 +
<p class="fig"><b>Fig.3</b> The control mechanism of the theophylline aptamer.</p>
 +
</div>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">Since the reformed scaffolds consist of three aptamers, just like clovers, we call them 'clover'. </p>
+
<p align="justify">We designed a series of alloscaffolds and <b class="orange">named them clovers, because the structure of them resembles a clover</b>. </p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">Fig.2 Our designed scaffolds are named 'clover'.</p>
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<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/igem.org/c/cb/Clover_ZJU.jpg" width="500px" />
 +
<p class="fig"><b>Fig.4</b> The alloscafolds we designed are called ‘clover’.</p>
 +
</div>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">Three versions of 'clover' were designed.</p>
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<p align="justify">At first, we designed two versions of clover.</p>
<p align="justify">&nbsp;</p>  
<p align="justify">&nbsp;</p>  
-
<p align="justify">Fig.3 Three version of clovers. Version one and version two have adjacent MS2 and theophylline aptamer, while vesion three has separated ones.  Version one has an interaction between the loop of theophylline aptamer and the loop of MS2 aptamer, while version two and version three have an interaction between the loop of theophylline aptamer and the stem of MS2 aptamer.</p>
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<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/4/49/Zju_alloscaffold_sequence12.png" width="450px" />
 +
</div>
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<p class="fig" align="justify"><b>Fig.5</b> The sequences of two aptamers in clover version 1and 2. As can be seen, version 1 and 2 have adjacent MS2 and theophylline aptamers. However, version 1 has an interaction between the loop of theophylline aptamer and the loop of MS2 aptamer, while version 2 has an interaction between the loop of theophylline aptamer and the stem of MS2 aptamer.</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<h3>Original scaffold D0:</h3>
+
<p>As our time was limited, we had only synthesized clover version 2 before Regional Jamboree. Although it shows a prominent function of tunable scaffold, some problems remain, for example, in the absence of theophylline, it also shows a remarkable function of a scaffold, which is not desirable for us.</p>
 +
</br>
 +
<p><b class="orange">Then after Regional Jamboree, clover version 3 was designed and synthesized</b>. Unlike clover version 1 and 2, in which MS2 and theophylline aptamers are adjacent, <b class="orange">clover version 3 has separated MS2 and theophylline aptamers in sequence. However, in the tertiary structure, the two aptamers get closer to each other and theophylline aptamer obviously fold towards the MS2 aptamer in the absence of theophylline.</b></p>
 +
</br>
 +
<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/5/56/Zju_alloscaffold_sequence3.png" width="220px"/>
 +
</div>
 +
<p class="fig"><b>Fig.6</b> The sequence and relative position of MS2 and theophylline aptamers in clover version 3.</p>
 +
</br>
 +
<div class="floatC">
 +
<p>
 +
<img src="https://static.igem.org/mediawiki/igem.org/f/f9/Zju_model1_4.png" height="250px" />
 +
<img src="https://static.igem.org/mediawiki/igem.org/0/05/Zju_model1_5.png" height="250px" />
 +
</p>
 +
</div>
 +
<p class="fig"><b>Fig.7</b> A contrast of clover version 3 (left) and a scaffold including a theophyline aptamer without a complementary site of MS2 aptamer (right). It can be easily noticed that in clover version 3, the theophyline aptamer obviously fold towards the MS2 aptamer, which indicates the interaction between the complementary sites in the theophyline and MS2 aptamers. In contrast, the scaffold without complementary sites in the two aptamers shows no approach of the theophyline aptamer to the MS2 aptamer.</p>
 +
</br>
 +
<p>Followed are the sequences and structures of basic RNA scaffold and the series of clovers.</p>
 +
</br>
 +
<h3>Basic scaffold D0</h3>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
<p align="justify">The base sequence of original scaffold D0:</p>
<p align="justify">The base sequence of original scaffold D0:</p>
-
<p align="justify">&nbsp;</p>
+
<p class="seq">GGGAGGACTCCCACAGTCACTGGGGAGTCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGT</br>
-
<p align="justify">GGGAGGACTCCCACAGTCACTGGGGAGTCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGATTCCC</p>
+
TCGCACTTCTCTCGTATTCGATTCCC</p>
-
<p align="justify">&nbsp;</p>
+
<p align="justify">&nbsp;</p>  
-
<p align="justify">Fig.4 The secondary (left) and the tertiary(right) structure of D0.</p>
+
 
 +
<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/c/c1/Zju_pro_allo_d0.png" width="400px" />
 +
</div>
 +
<table align="Center">
 +
<tr>
 +
<td><img src="https://static.igem.org/mediawiki/igem.org/9/99/Zju_riboscaffold_d0.png" width="300px" /></td>
 +
<td><embed src="https://static.igem.org/mediawiki/igem.org/0/0a/D0_roll.swf" width="350px" height="232px" /></td>
 +
</tr>
 +
</table>
 +
 
 +
<p class="fig" align="justify"><b>Fig.8</b> The secondary and the tertiary structures of D0. Color scale in secondary structure denotes positional entropy.</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
<h3>Clover version 1</h3>
<h3>Clover version 1</h3>
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<p align="justify">And the theophylline aptamer is just beside the MS2 apatamer.</p>
<p align="justify">And the theophylline aptamer is just beside the MS2 apatamer.</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">The base sequence of clover version 1:</p>
+
<p align="justify">The base sequence of clover version 1 (complementary parts are shown in <b class="seq">blue</b>):</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
-
<p align="justify">GGGGUCCUCGGUGAUACCAGCAUagugacuAUGCCCUUGGCAGCACCGAGGAGGACTCCCACagtcactGGGGAGTCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC</p>
+
<p class="seq">GGGGUCCUCGGUGAUACCAGCAU<b class="seq">agugacu</b>AUGCCCUUGGCAGCACCGAGGAGGACTCCCAC<b class="seq">agtcact</b>GGGGAG</br>TCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC</p>
-
<p align="justify">&nbsp;</p>  
+
 
-
<p align="justify">Fig.5 The secondary (left) and the tertiary (right) structure of clover version 1.</p>
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<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/5/50/Clover1.png" width="400px" />
 +
</div>
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<table align="Center">
 +
<tr>
 +
<td><img src="https://static.igem.org/mediawiki/igem.org/2/24/Zju_model1_1.png" width="300px" /></td>
 +
<td><embed src="https://static.igem.org/mediawiki/igem.org/5/5c/Clover1_roll.swf" width="350px" height="257px" /></td>
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</tr>
 +
</table>
 +
<div class="floatC">
 +
<p class="fig" align="justify"><b>Fig.9</b> The secondary and the tertiary structure of clover version 1. Color scale in secondary structure denotes positional entropy.</p>
 +
</div>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
<h3>Clover version 2</h3>
<h3>Clover version 2</h3>
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<p align="justify">The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. And the theophylline aptamer is just beside the MS2 apatamer.</p>
<p align="justify">The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. And the theophylline aptamer is just beside the MS2 apatamer.</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
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<p align="justify">The base sequence of clover version 2:</p>
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<p align="justify">The base sequence of clover version 2 (complementary parts are shown in <b class="seq">blue</b>):</p>
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<p align="justify">&nbsp;</p>
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<p class="seq">GGGGUCCUCGGUGAUACCAGC<b class="seq">ugacugugg</b>CCCUUGGCAGCACCGAGGAGGACTC<b class="seq">ccacagtca</b>CTGGGGAG</br>TCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC</p>
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<p align="justify">GGGGUCCUCGGUGAUACCAGCugacuguggCCCUUGGCAGCACCGAGGAGGACTCccacagtcaCTGGGGAGTCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC</p>
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<div class="floatC">
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<p align="justify">&nbsp;</p>
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<img src="https://static.igem.org/mediawiki/2012/2/2e/Clover2_2D.png" width="400px" />
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<p align="justify">Fig.6 The secondary (left) and the tertiary (right) structure of clover version 2.</p>
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</div>
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<table align="Center">
 +
<tr>
 +
<td><img src="https://static.igem.org/mediawiki/igem.org/f/ff/Zju_model1_3.png" width="300px" /></td>
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<td><embed src="https://static.igem.org/mediawiki/igem.org/7/71/Clover2_roll.swf" width="350px" height="239px" /></td>
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</tr>
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</table>
 +
<div class="floatC">
 +
<p class="fig" align="justify"><b>Fig.10</b> The secondary and the tertiary structure of clover version 2. Color scale in secondary structure denotes positional entropy.</p>
 +
</div>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
<h3>Clover version 3</h3>
<h3>Clover version 3</h3>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
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<p align="justify">The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. Although the theophylline and the MS2 apatamer is separated by the PP7 aptamer in the base sequence, they are closed according to the three- dimensional structure prediction.</p>
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<p align="justify">The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. Although the theophylline and the MS2 apatamer is separated by the PP7 aptamer in the base sequence, they are close according to the tertiary structure prediction.</p>
<p align="justify">&nbsp;</p>
<p align="justify">&nbsp;</p>
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<p align="justify">The base sequence of clover version 3:</p>
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<p align="justify">The base sequence of clover version 3 (complementary parts are shown in <b class="seq">blue</b>):</p>
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<p align="justify">&nbsp;</p>
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<p class="seq">GGGGUCCUCGGUGAUACCAGC<b class="seq">ugacugugg</b>CCCUUGGCAGCACCGAGGACUGGGCACAGAAGAUAUGGCUUCGUGCCCAGUCG</br>AAUACGAGGAAGUGUUCGCACUUCACCUGGGACUC<b class="seq">ccacaguca</b>CUGGGGAGUCCCAGGUUCUCGUAUUCGCCCC</p>
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<p align="justify">GGGGUCCUCGGUGAUACCAGCugacuguggCCCUUGGCAGCACCGAGGACUGGGCACAGAAGAUAUGGCUUCGUGCCCAGUCGAAUACGAGGAAGUGUUCGCACUUCACCUGGGACUCccacagucaCUGGGGAGUCCCAGGUUCUCGUAUUCGCCCC</p>
+
-
<p align="justify">&nbsp;</p> 
+
-
<p align="justify">Fig.7 The secondary (left) and the tertiary (right) structure of clover version 3. Although the theophyline and MS2 aptamers are separated as the secondary structure showed, in the tertiary structure, the theophyline aptamer obviously fold towards the MS2 aptamer.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">Fig.8  A contrast between clover version 3 and a scaffold including a theophyline aptamer without a complementary site with MS2 aptamer. It can be easily noticed that in clover version 3, the theophyline aptamer obviously fold towards the MS2 aptamer, which indicates the interaction between the complementary sites in the theophyline and MS2 aptamers. In contrast, the scaffold without complementary sites in the two aptamers shows no approach of the theophyline aptamer to the MS2 aptamer.</p>
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-
<p align="justify">&nbsp;</p>
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-
<p align="justify">Preparation: Characterize parts in registry</p>
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<p align="justify">&nbsp;</p>
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<p align="justify">To make tentative steps in order to fix the theophylline concentration of our clover coexpression experiment, we test some theophylline riboswitches tagged with fluorescent proteins.</p>
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<p align="justify">&nbsp;</p>
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<h3>BioBrick Part K537009:</h3>
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-
<p align="justify">&nbsp;</p>
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<p align="justify">To characterise the theophylline riboswitches (part K537009, iGEM11_WITS_CSIR_SA), we quantified their activation at different theophylline concentrations (0 mM, 1 mM, 5 mM, 10 mM and 20 mM) over 2 hours using fluorometry. </p>
+
-
<p align="justify">&nbsp;</p>
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-
<p align="justify">Competent E. coli (strain DH5a) cells were transformed with plasmid vectors containing the "Promoter-Theophylline riboswitch -Venus-Double terminator". The bacterial colony appeal pink. </p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">Cultured until the mid-log phase of growth, a different concentration of theophylline was added to each culture for induction. The activation of the riboswitch was detected as a fluorescent response as a result of increased translation of the fluorescent protein Venus, in the presence of the activator. Before fluorescence assay, we wash the culture with PBS.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">A Synergy hybrid reader was used to excite the cultures at 505 nm and the intensity of the emission was detected at 535 nm. Empty bacteria were used to correct for auto fluorescence (IGEM11_WITS_CSIR_SA offered exciting at 514nm and emission at 528nm, but 514&528 is too close for our machine to detect.)</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">We have two end points of the OD 630 of each sample.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">"Fluorescence intensity / OD" increases greatly with theophylline concentration.</p>
+
<p align="justify">&nbsp;</p>  
<p align="justify">&nbsp;</p>  
-
<img src="https://static.igem.org/mediawiki/igem.org/d/d4/Riboscaffold_fig_9.jpg" width="700px" />
+
 +
<div class="floatC">
 +
<img src="https://static.igem.org/mediawiki/2012/9/97/Zju_pro_allo_Clover3.png" width="400px" />
 +
</div>
 +
<table align="Center">
 +
<tr>
 +
<td><img src="https://static.igem.org/mediawiki/igem.org/f/f9/Zju_model1_4.png" width="300px" /></td>
 +
<td><embed src="https://static.igem.org/mediawiki/igem.org/6/6c/Clover3_roll.swf" width="350px" height="225px" /></td>
 +
</tr>
 +
</table>
-
<p align="justify">Fig.9 The 5 different concentration of theophylline comparision on part K537009 theophylline  robswitch tagged with venus YFP. Excitation at 505nm and emission at 535nm. Up to 20mM theophylline, cells didn't show side effects and YFP production is proportioned with theophylline concentration, showing that K537009 is an effective riboswitch which can be regulated by theophylline.</p>
+
<p class="fig" align="justify"><b>Fig.11</b> The secondary and the tertiary structure of clover version 3. Color scale in secondary structure denotes positional entropy. Although the theophyline and MS2 aptamers are separated as the secondary structure showed, in the tertiary structure, the theophyline aptamer obviously fold towards the MS2 aptamer. </p>
-
<p align="justify">&nbsp;</p>
+
</br>
-
<p align="justify">Fluorescence Microscope could also show this part work beautifully.</p>
+
 
-
<p align="justify">&nbsp;</p>
+
<h3>References:</h3>
-
<p align="justify">Except for the difference that though K537009 is an YFP, we excite it at 532nm (green light) and it glow red.</p>
+
<p class="ref" align="justify">1. Thodey, K. & Smolke, C.D. Bringing It Together with RNA. Science 333, 412-413 (2011).</br>
-
<p align="justify">&nbsp;</p>
+
2. Delebecque, C.J., Lindner, A.B., Silver, P.A. & Aldaye, F.A. Organization of Intracellular Reactions with Rationally Designed RNA Assemblies. Science 333, 470-474 (2011).</br>
-
<img src="https://static.igem.org/mediawiki/igem.org/4/41/Riboscaffold_fig_10.jpg" width="700px" />
+
3. Qi, L., Lucks, J.B., Liu, C.C., Mutalik, V.K. & Arkin, A.P. Engineering naturally occurring trans-acting non-coding RNAs to sense molecular signals. Nucleic Acids Res 40, 5775-5786 (2012).</p>
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">Fig.10 The 5 different concentration of theophylline comparision on part K537009 theophylline riboswitch tagged with venus YFP. The brightfield (BF) images in the right column depict all bacterial cells. The venus images in the left column depict bacterial cells which emitted fluorescence. We excite it at 532nm (green light) and it glow red, seeing the obvious trend that when adding more theophylline, cells showing Veuns appeal more.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<h3>BioBrick Part K411003:</h3>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">This is a"pLAC promotor,Theophylline-inducible Riboswitch, GFP+Terminator" part made by 2010 NYMU-Taipe. We make similar tests as K537009 at different theophylline concentrations (0 mM, 0.1mM, 0.3mM, 0.5 mM,1mM,5mM,10mM and 20mM) over 2 hours using fluorometry.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">Synergy hybrid reader detects effective effects of theophylline on GFP production.</p>
+
-
<p align="justify">&nbsp;</p>
+
-
<img src="https://static.igem.org/mediawiki/igem.org/4/4c/Riboscaffold_fig_11.jpg" width="700px" />
+
-
<p align="justify">&nbsp;</p>
+
-
<p align="justify">Fig.11 The 8 different concentration of theophylline comparision on part K411003 theophylline  robswitch tagged with GFP. Excitation at 480nm and emission at 535nm. Up to 10mM theophylline, cells didn't show obvious side effects and GFP production is proportioned with theophylline concentration, showing that K411003 is an effective riboswitch which can be regulated by theophylline. When theophylline concentration is beyond a certain degree (about 10 mM), it somewhat affect cell growth and GFP production.</p>
+
-
<p align="justify">&nbsp;</p>
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<p align="justify">Through Fig9 and Fig11 we find that when theophylline concentration scale is 0-1mM (especially 0-0.5mM); the response of fluorescence protein to theophylline is more significant with bigger slope. So we decided to carry out our clover 2 characterization with theophylline concentration scale 0-1mM.</p>
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Latest revision as of 11:05, 26 October 2012

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Design

 

How could we make RNA scaffold tunable? We thought of riboswitch. A riboswitch usually consists of an allosteric aptamer and an expression platform. The structural interaction between them could inactivate gene expression. However, when a corresponding ligand is added, the interaction disappears with the structural altering of the aptamer and gene expression platform will be activated. It inspirited us to fuse an allosteric aptamer to the basic RNA scaffold to achieve the controllability of it.

 

Fig.1 The mechanism of riboswitch.

 

We utilized the well-known theophylline aptamer. The aptamer is a single RNA hairpin that binds theophylline in an inner loop region with high affinity. Previous studies have shown that mutations in the loop region were tolerated as long as the loop structure was preserved. This allowed us to mutate the loop of the theophylline aptamer to create an interaction between the theophylline aptamer and the MS2 aptamer. We changed the sequence in the mutation region of theophylline aptamer by making it a complementary one of part of MS2 aptermer.


Fig.2 The sequence of theophylline aptamer and the structure of theophylline. The sequence in the blue box is mutation region, while the one in the orange box is ligand-binding region.


In the absence of theophylline, the interaction prevents MS2 protein from binding to MS2 aptamer, so the scaffold cannot function. When theophylline is added, the interaction disappears as a result of the structural change of theophylline aptamer and the scaffold begins to work. This kind of tunable scaffold contains an allosteric aptamer, so we call them alloscaffolds.


Fig.3 The control mechanism of the theophylline aptamer.

 

We designed a series of alloscaffolds and named them clovers, because the structure of them resembles a clover.

 

Fig.4 The alloscafolds we designed are called ‘clover’.

 

At first, we designed two versions of clover.

 

Fig.5 The sequences of two aptamers in clover version 1and 2. As can be seen, version 1 and 2 have adjacent MS2 and theophylline aptamers. However, version 1 has an interaction between the loop of theophylline aptamer and the loop of MS2 aptamer, while version 2 has an interaction between the loop of theophylline aptamer and the stem of MS2 aptamer.

 

As our time was limited, we had only synthesized clover version 2 before Regional Jamboree. Although it shows a prominent function of tunable scaffold, some problems remain, for example, in the absence of theophylline, it also shows a remarkable function of a scaffold, which is not desirable for us.


Then after Regional Jamboree, clover version 3 was designed and synthesized. Unlike clover version 1 and 2, in which MS2 and theophylline aptamers are adjacent, clover version 3 has separated MS2 and theophylline aptamers in sequence. However, in the tertiary structure, the two aptamers get closer to each other and theophylline aptamer obviously fold towards the MS2 aptamer in the absence of theophylline.


Fig.6 The sequence and relative position of MS2 and theophylline aptamers in clover version 3.


Fig.7 A contrast of clover version 3 (left) and a scaffold including a theophyline aptamer without a complementary site of MS2 aptamer (right). It can be easily noticed that in clover version 3, the theophyline aptamer obviously fold towards the MS2 aptamer, which indicates the interaction between the complementary sites in the theophyline and MS2 aptamers. In contrast, the scaffold without complementary sites in the two aptamers shows no approach of the theophyline aptamer to the MS2 aptamer.


Followed are the sequences and structures of basic RNA scaffold and the series of clovers.


Basic scaffold D0

 

The base sequence of original scaffold D0:

GGGAGGACTCCCACAGTCACTGGGGAGTCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGT
TCGCACTTCTCTCGTATTCGATTCCC

 

Fig.8 The secondary and the tertiary structures of D0. Color scale in secondary structure denotes positional entropy.

 

Clover version 1

 

The interaction is between the loop of theophylline aptamer and the loop of the MS2 aptamer.

 

And the theophylline aptamer is just beside the MS2 apatamer.

 

The base sequence of clover version 1 (complementary parts are shown in blue):

 

GGGGUCCUCGGUGAUACCAGCAUagugacuAUGCCCUUGGCAGCACCGAGGAGGACTCCCACagtcactGGGGAG
TCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC

Fig.9 The secondary and the tertiary structure of clover version 1. Color scale in secondary structure denotes positional entropy.

 

Clover version 2

 

The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. And the theophylline aptamer is just beside the MS2 apatamer.

 

The base sequence of clover version 2 (complementary parts are shown in blue):

GGGGUCCUCGGUGAUACCAGCugacuguggCCCUUGGCAGCACCGAGGAGGACTCccacagtcaCTGGGGAG
TCCTCGAATACGAGCTGGGCACAGAAGATATGGCTTCGTGCCCAGGAAGTGTTCGCACTTCTCTCGTATTCGCCCC

Fig.10 The secondary and the tertiary structure of clover version 2. Color scale in secondary structure denotes positional entropy.

 

Clover version 3

 

The interaction is between the loop of the theophylline aptamer and the stem of the MS2 apatamer. Although the theophylline and the MS2 apatamer is separated by the PP7 aptamer in the base sequence, they are close according to the tertiary structure prediction.

 

The base sequence of clover version 3 (complementary parts are shown in blue):

GGGGUCCUCGGUGAUACCAGCugacuguggCCCUUGGCAGCACCGAGGACUGGGCACAGAAGAUAUGGCUUCGUGCCCAGUCG
AAUACGAGGAAGUGUUCGCACUUCACCUGGGACUCccacagucaCUGGGGAGUCCCAGGUUCUCGUAUUCGCCCC

 

Fig.11 The secondary and the tertiary structure of clover version 3. Color scale in secondary structure denotes positional entropy. Although the theophyline and MS2 aptamers are separated as the secondary structure showed, in the tertiary structure, the theophyline aptamer obviously fold towards the MS2 aptamer.


References:

1. Thodey, K. & Smolke, C.D. Bringing It Together with RNA. Science 333, 412-413 (2011).
2. Delebecque, C.J., Lindner, A.B., Silver, P.A. & Aldaye, F.A. Organization of Intracellular Reactions with Rationally Designed RNA Assemblies. Science 333, 470-474 (2011).
3. Qi, L., Lucks, J.B., Liu, C.C., Mutalik, V.K. & Arkin, A.P. Engineering naturally occurring trans-acting non-coding RNAs to sense molecular signals. Nucleic Acids Res 40, 5775-5786 (2012).

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