Difference between revisions of "Team:Vilnius-Lithuania/Description"

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             However designing complex, several layered circuitries resembling the behavior of a natural cell is still an overwhelming challenge due to many limitations like crosstalk, mutations, ambiguous intracellular and extracellular conditions, and biological noise. Therefore we propose to start from something simpler and more minimal.. Although the journey of creating a synthetic minimal cell has already begun, we hoped to contribute to this ultimate goal as well by investing our time and effort. This year we are engineering liposomes, lipid-coated vesicles, that are perfect models to study the initial steps for creating synthetic cells. Liposomes can offer a system with fully controllable experimental parameters and only the exact elements for our custom circuit design without the need to ever worry about the crosstalk and noise. We believe that most of the future synthetic biology applications will rely on bottom-up engineering solutions. Having mastered some hard-core bottom-up liposome engineering, we won’t take long to create the first synthetic cell.
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             However designing complex, several layered circuitries resembling the behavior of a natural cell is still an overwhelming challenge due to many limitations like crosstalk, mutations, ambiguous intracellular and extracellular conditions, and biological noise. Therefore we propose to start from something simpler and more minimal.. Although the journey of creating a synthetic minimal cell has already begun, we hoped to contribute to this ultimate goal as well by investing our time and effort. This year we are engineering liposomes, lipid-coated vesicles, that are perfect models to study the initial steps for creating synthetic cells. Liposomes can offer a system with fully controllable experimental parameters and only the exact elements for our custom circuit design without the need to ever worry about the crosstalk and noise. We believe that most of the future synthetic biology a
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pplications will rely on bottom-up engineering solutions. Having mastered some hard-core bottom-up liposome engineering, we won’t take long to create the first synthetic cell.
 
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     <h1>Applications</h1>
 
     <h1>Applications</h1>
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<img style='max-width:100%' src='https://static.igem.org/mediawiki/2018/e/eb/T--Vilnius-Lithuania--Bendra_apl.png'/>
 
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     <p>As our project focuses on a novel platform for membrane protein research it offers various future applications.
 
     <p>As our project focuses on a novel platform for membrane protein research it offers various future applications.

Revision as of 03:42, 18 October 2018

Description

Describe the Impossible

Cell-free systems are becoming an increasingly popular in vitro tool to study biological processes as it is accompanied by less intrinsic and extrinsic noise. Relying on fundamental concepts of synthetic biology, we apply a bottom-up forward engineering approach to create a novel cell-free system for unorthodox protein-evolution. The core of this system is cell-sized liposomes that serve as excellent artificial membrane models. By encapsulating genetic material and full in vitro protein transcription and translation systems within the liposomes, we create reliable and incredibly efficient nanofactories for the production of target proteins. Even though there are many alternative proteins that can be synthesized, our main focus is directed towards membrane proteins, which occupy approximately one third of living-cells’ genomes. Considering their significance, membrane proteins are spectacularly understudied since synthesis and thus characterization of them remain prevailing obstacles to this day. We aim to utilize liposomes as nanofactories for directed evolution of membrane proteins. Furthermore, by means of directed membrane protein-evolution, a universal exposition system will be designed in order to display any protein of interest on the surface of the liposome. This way, a system is built where a phenotype of a particular protein is expressed on the outside while containing its genotype within the liposome. To prove the concept, small antibody fragments will be displayed to create a single-chain variable fragment (scFv) library for rapid screening of any designated target.

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