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                                     <p>The aim of our project is to build a synthetic organelle based on phase separation as a multifunctional platform. Based on the principle of multivalence and interaction, we fused interactional modules into homo-oligomeric tags (HOtags) to form granules in S. cerevisiae. (Click to see more about Background and Design)<a href="https://2018.igem.org/Team:Peking"/>(Learn more)</a></p>
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                                     <p>The aim of our project is to build a synthetic organelle based on phase separation as a multifunctional platform. Based on the principle of multivalence and interaction, we fused interactional modules into homo-oligomeric tags (HOtags) to form granules in S. cerevisiae.</p>
 
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                                     <p>Searched for methods and the best conditions for the extraction of each protein. <a href="https://2016.igem.org/Team:Peking/Notebook/Protocol:purification_of_recombinant_proteins"/>(Learn more)</a> </p>
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                                     <p>We have built spontaneous and induced synthetic organelles by specific interaction modules, so that we can control the formation process by different ways for demands in biological engineering. Then we characterized the kinetics and properties of synthetic organelles theoretically and experimentally. These results confirm the potential of synthetic organelles in synthetic biology.</p>
 
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                                     <p>Demonstrated a quick and stable crosslinking process of Triple SpyTag-SUP and Triple SpyTag-mSA with Triple SpyCatcher via covalent bonds. We also optimized this reaction concerning the relevant parameters such as temperature, pH, etc.. <a href="https://2016.igem.org/Team:Peking/Crosslinking"/>(Learn more)</a> </p>
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                                     <p>It inspired us to propose some specific applications of our synthetic organelles, including organization hub, sensor, and metabolism regulator. We have verified the feasibility of them by loading GFP-nanobody module, NAD+ sensor module and carotene production module to the whole system.</p>
 
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                                    <p>Demonstrated effective adsorption of uranyl ions by monomeric Triple SpyTag-SUP or polymer network containing the SUP module under a number of conditions. The adsorption was highly efficient and fast, not only under experimental conditions but also in simulated seawater or lake water containing uranium pollution. <a href="https://2016.igem.org/Team:Peking/Uranyl-adsorption"/>(Learn more)</a> </p>
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                                    <p>Attached biotin to amino-coated magnetic beads and achieved clearance of the polymer network formed via the crosslinking of Triple SpyTag-SUP and Triple SpyTag-mSA with Triple SpyCatcher with a magnet. <a href="https://2016.igem.org/Team:Peking/Clearance"/>(Learn more)</a> </p>
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                                    <p>Set up a signal peptide library and screened for optimally suited signal peptides in order to efficiently secrete the proteins of interest. We found two signal peptides of high efficiency - those derived from OmpA and LtIIb. <a href="https://2016.igem.org/Team:Peking/Secretion"/>(Learn more)</a> </p>
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                                    <p>Used all the above-mentioned experiments together to demonstrate that the complete Uranium Reaper system, consisting of Triple SpyTag-SUP, Triple SpyTag-mSA, Triple SpyCatcher and biotin-coated magnetic beads, could effectively handle uranium pollution under simulated real-life conditions in about 2 hours. We aimed to optimize this strategy and hoped it could be implemented as a uranyl removal kit. <a href="https://2016.igem.org/Team:Peking/Proof"/>(Learn more)</a> </p>
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                                     <p>We exchanged the Triple SpyTag-SUP monomer for Triple SpyTag-LBP or Triple SpyTag-CBP, and tried using the same strategy to adsorb lead and cadmium. The results were remarkable, clearly demonstrating that the Uranium Reaper strategy has much potential to be expanded to other heavy metals. <a href="https://2016.igem.org/Team:Peking/Demonstrate"/>(Learn more)</a> </p>
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                                     <p>We believe that our work has reached the medal requirements of demonstration as we have confirmed that our synthetic organelles can be formed in vivo and deliver a range of functions both for engineering and research due to their amazing properties. The concrete demonstration of the whole platform is shown below. You can see more details of experiments and modeling in our <a href="https://2018.igem.org/Team:Peking/Data_Page"/>Data_Page</a> and <a href="https://2018.igem.org/Team:Peking/Model"/>Modeling</a></p>
 
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Revision as of 07:36, 14 October 2018

Demonstrate

In this section, you could see the demonstration.

Overview

The aim of our project is to build a synthetic organelle based on phase separation as a multifunctional platform. Based on the principle of multivalence and interaction, we fused interactional modules into homo-oligomeric tags (HOtags) to form granules in S. cerevisiae.

We have built spontaneous and induced synthetic organelles by specific interaction modules, so that we can control the formation process by different ways for demands in biological engineering. Then we characterized the kinetics and properties of synthetic organelles theoretically and experimentally. These results confirm the potential of synthetic organelles in synthetic biology.

It inspired us to propose some specific applications of our synthetic organelles, including organization hub, sensor, and metabolism regulator. We have verified the feasibility of them by loading GFP-nanobody module, NAD+ sensor module and carotene production module to the whole system.

We believe that our work has reached the medal requirements of demonstration as we have confirmed that our synthetic organelles can be formed in vivo and deliver a range of functions both for engineering and research due to their amazing properties. The concrete demonstration of the whole platform is shown below. You can see more details of experiments and modeling in our Data_Page and Modeling

 

 

Even though the efficiency of the Uranium Reaper system may be somewhat lower than current methods, it could certainly be optimized through further development work. Importantly, Uranium Reaper is much better in other aspects. In the future, we plan to optimize the entire Uranium Reaper strategy in order to enhance the adsorption efficiency.

 

For an overall view of our project, please redirect to Overview Page or Design Page. Links to detailed lab results could also be found on these pages.

 

Beyond Experiment

1.

We submitted 53 high-quality and well-characterized Standard BioBricks, including a set of derivatives of Triple SpyTag and Triple SpyCatcher, such as the Triple SpyTag-SUP and Triple SpyTag-mSA. (Learn more)

2.

We developed a special software which could be used to calculate the molecular weight distribution of protein polymers using Flory’s theory. The results of testing have demonstrated that the software is accurate and useful. (Learn more)

3.

We visited experts from the College of Chemistry and Molecular Engineering and School of Physics of Peking University, respectively, to learn about the current situation surrounding uranium pollution in the real world and how people could control the situation. After finishing the main work, we presented them with the achievements of the project and got their feedback. (Learn more)

4.

We did an interview with the Hunan Nuclear Geology 311 Brigade and gained thorough insights into the treatment of uranyl pollution used by the people on the firing line. This way we could compare the methods they were using with the Uranium Reaper strategy. (Learn more)

5.

We helped and collaborated with other iGEM teams by guiding a new team (BHU_China), as well as discussing about project design and technical skills and sharing DNA materials (OUC-China, BIT-China, Tianjin, UCAS, Jinlin_China and BNU-China). (Learn more)

6.

We attended the CCiC (Central China iGEM Consortium), which is a large-scale competition-free jamboree of about 50 teams, providing participants with an opportunity for meaningful exchanges of ideas and problem solving. (Learn more)

 

Our future plan

1.

We should reproduce all of the experiments that we have done this summer to make sure the results are credible.

2.

We will optimize the whole strategy to enhance the adsorption efficiency by changing pH, temperature, reaction time of crosslinking and clearance. (The efficiency is only about 60% without further optimization)

3.

According to the results for the adsorption of 13nM uranyl, the polymer network exhibited a good ability in a simulated seawater environment. We could thus also look into other usage scenarios of Uranium Reaper, such as bio-mining and uranium enrichment.

4.

Exchange of the SUP module for other functional proteins. For example, we could integrate proteins which could bind other heavy metals such as mercury so that the polymer network could be used to treat other kinds of pollution as well.

5.

We could assemble enzyme systems behind the SpyTag backbone to create a production plant in vitro. In the protein polymeric network, the concentration of enzymes could be increased and the efficiency of biocatalysis may consequently also be enhanced.

6.

If we optimize the number of SpyTag or SpyCatcher modules per protein monomer, as well as the working concentrations of proteins, we may make protein-3D printing using the Spy Crosslinking Network come true.