Team:ZJU-China/project.htm

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<p>What is the Library of RNA Scaffold for? Evolution! The variable of RNA structures accommodates a wide application prospect. Though the point mutation reduced uncertainty of selection and the blindness, trying to find a suitable construction is vast project. Various experimental methods, selection and modeling should be used in this part. By analyzing existing mutations, derivation can be made to construct and find an enhanced RNA scaffold. We called this process evolution. </p>
<p>What is the Library of RNA Scaffold for? Evolution! The variable of RNA structures accommodates a wide application prospect. Though the point mutation reduced uncertainty of selection and the blindness, trying to find a suitable construction is vast project. Various experimental methods, selection and modeling should be used in this part. By analyzing existing mutations, derivation can be made to construct and find an enhanced RNA scaffold. We called this process evolution. </p>
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<p>&nbsp;</p>
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<p>The Library may contain changes of self, self-assemble, RNA-RNA interaction, RNA-protein interaction. Some examples are show below.</p>
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<p>The Library may contain changes of self, self-assemble, RNA-RNA interaction, RNA-protein interaction. Some examples are shown below.</p>
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<p>1.1 Mutating arm length: changing the arm length of RNA scaffold D0. As the mechanism of D0 is reducing the distance of two key enzyme of the pathway, in other words, the output and reaction efficiency is depend on the local concentration. The two aptamer binding site in our project is on two hairpin arms witch are designed in the same length. The change of the arm length provides feasibility of distance-efficiency research. We used split GFP experiments. We made some mutations with different arm length, the result of D0M4 and D0M 5 split GFP experiment shows the light decreasing lend by split GFP FA-FB distance. The difference (PD0M4=0.079, PD0M5=0.025) suggests that the mutating arm length scaffold doesn’t provide an on/off switch but a definability one. It characterized the D0 in another way.</p>
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<h2>Categories of mutants</h2>
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<img src="https://static.igem.org/mediawiki/igem.org/d/da/Zju_library_Fig1a.jpg" width="500px" />
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<h3>1. Mutating arm length</h3>
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<p>fig 1a. D0 is the original scaffold. D0 a-d were mutated to the scaffold with different aptamer arm length. </p>
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<p>changing the arm length of RNA scaffold D0. As the mechanism of D0 is reducing the distance of two key enzyme of the pathway, in other words, the output and reaction efficiency is depend on the local concentration. The two aptamer binding site in our project is on two hairpin arms witch are designed in the same length. The change of the arm length provides feasibility of distance-efficiency research. We used split GFP experiments. We made some mutations with different arm length, the result of D0M4 and D0M 5 split GFP experiment shows the light decreasing lend by split GFP FA-FB distance. The difference (PD0M4=0.079, PD0M5=0.025) suggests that the mutating arm length scaffold doesn’t provide an on/off switch but a definability one. It characterized the D0 in another way.</p>
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<img src="https://static.igem.org/mediawiki/igem.org/d/da/Zju_library_Fig1a.jpg" width="400px" />
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<p class="fig"><b>fig 1a.</b> D0 is the original scaffold. D0 a-d were mutated to the scaffold with different aptamer arm length. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/f/f7/Zju_library_fig1b.jpg" width="500px" />
<img src="https://static.igem.org/mediawiki/igem.org/f/f7/Zju_library_fig1b.jpg" width="500px" />
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<p>fig 1b. The result of arm length mutating. Both D0M4 and D0M5 scaffold half-on GEP.</p>
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<p class="fig"><b>fig 1b.</b> The result of arm length mutating. Both D0M4 and D0M5 scaffold half-on GEP.</p>
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<p>1.2 Mutating aptamer binding site: Mutating the PP7 and MS2 binding sites prevented protein scaffolding. Preventing protein scaffolding lead to the key enzyme dissociation and the decrease of enzyme local concentration. By chancing the sequence of MS2 aptamer binding site, the fluorescent light decreased. D0M3 in our project is the molecular with mutated aptamer binding site. Split GFP experiment shows that there is a significant difference between D0 an D0M3(P≦0.05, fig2.c). Camille J. Delebecque has done the same work for the H2 biosynthesis pathway.</p>
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<h3>2. Mutating aptamer binding site</h3>
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<img src="https://static.igem.org/mediawiki/igem.org/a/ad/Zju_library_Fig2a.jpg" width="500px" />
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<p>Mutating the PP7 and MS2 binding sites prevented protein scaffolding. Preventing protein scaffolding lead to the key enzyme dissociation and the decrease of enzyme local concentration. By chancing the sequence of MS2 aptamer binding site, the fluorescent light decreased. D0M3 in our project is the molecular with mutated aptamer binding site. Split GFP experiment shows that there is a significant difference between D0 an D0M3(P≦0.05, fig2.c). Camille J. Delebecque has done the same work for the H2 biosynthesis pathway.</p>
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<p>fig2a. MS2 and PP7 bind to the scaffold and make GFP work. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/a/ad/Zju_library_Fig2a.jpg" width="400px" />
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<p class="fig"><b>Fig2a.</b> MS2 and PP7 bind to the scaffold and make GFP work. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/9/98/Zju_library_Fig2b.jpg" width="500px" />
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<p>fig2b. By mutating aptamer binding site, scaffolding is stop. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/9/98/Zju_library_Fig2b.jpg" width="400px" />
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<p class="fig"><b>Fig2b.</b> By mutating aptamer binding site, scaffolding is stop. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/3/33/Zju_library_fig2c.jpg" width="500px" />
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<p>fig2c. significant difference between D0 an D0M3</p>
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<img src="https://static.igem.org/mediawiki/igem.org/3/33/Zju_library_fig2c.jpg" width="400px" />
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<p class="fig"><b>Fig2c.</b> significant difference between D0 an D0M3</p>
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<p>1.3 Assemblage: adding extra sequence for self-, RNA-, protein-assemblage. The added sequence may be a riboswitch, RNA or protein binding site, self-assemble structure. Regulation molecular search is also wanted synchronously. </p>
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<h3>3. Assemblage</h3>
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<p>adding extra sequence for self-, RNA-, protein-assemblage. The added sequence may be a riboswitch, RNA or protein binding site, self-assemble structure. Regulation molecular search is also wanted synchronously. </p>
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<h3>Applications and outlook</h3>
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<h2>Applications and outlook</h2>
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<p>2.1 sRNA regulation: Simple an direct RNA-RNA interaction change the object RNA  scaffold structure. As a Foundation regulation, it substantially enhances the possibilities of forthcoming experiment. </p>   
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<h3>1. sRNA regulation</h3>
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<img src="https://static.igem.org/mediawiki/igem.org/e/ec/Zju_library_Fig3.jpg" width="600px" />
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<p>Simple an direct RNA-RNA interaction change the object RNA  scaffold structure. As a Foundation regulation, it substantially enhances the possibilities of forthcoming experiment. </p>   
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<img src="https://static.igem.org/mediawiki/igem.org/8/89/Zju_library_Fig3d.jpg" width="600px" />
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<p>fig3 The designed scaffold has a interaction to regulatory sRNA. Same mechanism, regulatory molecule can be changed to mRNA a. Turn off the scaffold by the competitive binding with aptamer binding site (green) b. The RNA scaffold has a secondary structural switch controls accessibility of sRNA-binding sites(blue) witch can change the arm length. Output regulated by arm length change. c. both methods were used. d. bind and release the object molecular.)</p>
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<img src="https://static.igem.org/mediawiki/igem.org/e/ec/Zju_library_Fig3.jpg" width="400px" />
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<img src="https://static.igem.org/mediawiki/igem.org/8/89/Zju_library_Fig3d.jpg" width="400px" />
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<p class="fig" align="justify"><b>Fig3.</b> The designed scaffold has a interaction to regulatory sRNA. Same mechanism, regulatory molecule can be changed to mRNA a. Turn off the scaffold by the competitive binding with aptamer binding site (green) b. The RNA scaffold has a secondary structural switch controls accessibility of sRNA-binding sites(blue) witch can change the arm length. Output regulated by arm length change. c. both methods were used. d. bind and release the object molecular.)</p>
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<p>2.2 Protein expression (mRNA) regulation: RNA scaffold as a free molecular in cell can specific bind mRNA and protein. Binding molecular changes the structure of scaffold to release or combine something. So that oncogene and virogene can be found and controlled by the drug from RNA scaffold. The problem of cancer therapeutic drug side effecting may solved by it. </p>
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<h3>2. Protein expression (mRNA) regulation</h3>
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<p>RNA scaffold as a free molecular in cell can specific bind mRNA and protein. Binding molecular changes the structure of scaffold to release or combine something. So that oncogene and virogene can be found and controlled by the drug from RNA scaffold. The problem of cancer therapeutic drug side effecting may solved by it. </p>
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<p>2.3 Self quenching(Self regulation): Adding self binding site, a balance of “on” and “off” scaffolds is built. The relationship between the binding site size, CG bases, binding form and the rate binding molecular is urgently modeled. Forming dimerization and trimerization, the concentration of working scaffold could be regulated.</p>  
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<h3>3. Self quenching(Self regulation)</h3>
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<p>Adding self binding site, a balance of “on” and “off” scaffolds is built. The relationship between the binding site size, CG bases, binding form and the rate binding molecular is urgently modeled. Forming dimerization and trimerization, the concentration of working scaffold could be regulated.</p>  
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<p>2.4 Polo-scaffold: Scaffold with intermolecular binding component. These scaffolds bind each other or bind through mediate molecular. And this binding mode has been proved both in vitro and vivo. The aggregation of molecular also makes artificial organelle achievable. </p>
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<h3>4. Polo-scaffold</h3>
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<p>Scaffold with intermolecular binding component. These scaffolds bind each other or bind through mediate molecular. And this binding mode has been proved both in vitro and vivo. The aggregation of molecular also makes artificial organelle achievable. </p>
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<img src="https://static.igem.org/mediawiki/igem.org/2/2f/Zju_library_Fig4a.jpg" width="600px" />
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<p>fig4a Dimerization and trimerization. Protein binding site is sealed off by the scaffolds themselves. Too much scaffold molecular lend to the self regulation.
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<img src="https://static.igem.org/mediawiki/igem.org/b/be/Zju_library_Fig4b.jpg" width="600px" />
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<img src="https://static.igem.org/mediawiki/igem.org/2/2f/Zju_library_Fig4a.jpg" width="400px" />
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<p>fig4b Dimerization and trimerization. Protein binding site is sealed off by the scaffolds themselves. Too much scaffold molecular lend to the self regulation.</p>
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<p class="fig" align="justify"><b>Fig4a.</b> Dimerization and trimerization. Protein binding site is sealed off by the scaffolds themselves. Too much scaffold molecular lend to the self regulation.</p>
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<img src="https://static.igem.org/mediawiki/igem.org/8/8d/Zju_library_Fig4c.jpg" width="600px" />
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<p>fig4 c. Polo-scaffold be made by head-tail binding and.</p>
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<img src="https://static.igem.org/mediawiki/igem.org/b/be/Zju_library_Fig4b.jpg" width="400px" />
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<p class="fig" align="justify"><b>Fig4b.</b> Dimerization and trimerization. Protein binding site is sealed off by the scaffolds themselves. Too much scaffold molecular lend to the self regulation.</p>
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<img src="https://static.igem.org/mediawiki/igem.org/8/8d/Zju_library_Fig4c.jpg" width="400px" />
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<p class="fig"><b>Fig4c.</b> Polo-scaffold be made by head-tail binding.</p>
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Revision as of 14:31, 22 October 2012

PROJECT

01 ABSTRACT

02 BACKGROUND

03 S0: BASIC RNA SCAFFOLD

04 S1: RIBOSCAFFOLD

05 S2: SCAFFOLD LIBRARY

06 S3: BIOSYNTHESIS OF IAA

07 PARTS

08 RESULTS

09 PERSPECTIVES