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− | < | + | <p>We both stabilized and optimized the production of liposomes by implementing the obtained parameters of microfluidics variables from our COMSOL model calculations. Synthesized liposomes were biocompatible and capable of encapsulating an in vitro transcription-translation system.</p> |
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<p>The core of our project is liposomes - functional, well-characterized minimal systems for membrane protein research. We have successfully implemented a modified OLA (Octanol-assisted liposome assembly) method<sup>1</sup>1 for high throughput production (Fig. 1) of homogenous and cell-sized (Fig. 2), bilayered (Fig. 3) liposomes that are capable of membrane protein synthesis and integration into the membrane (Fig. 4). To prove that synthesis of proteins is viable, we performed GFP protein synthesis inside our liposomes and recorded measurable fluorescence. Additionally, purified GFP was encapsulated to prove high encapsulation efficiency. To validate membrane protein integration into the membrane, pore forming membrane protein a-hemolysin was inserted into liposomes and the leakage of fluorophore molecule calcein was recorded in the outer solution. </p> | <p>The core of our project is liposomes - functional, well-characterized minimal systems for membrane protein research. We have successfully implemented a modified OLA (Octanol-assisted liposome assembly) method<sup>1</sup>1 for high throughput production (Fig. 1) of homogenous and cell-sized (Fig. 2), bilayered (Fig. 3) liposomes that are capable of membrane protein synthesis and integration into the membrane (Fig. 4). To prove that synthesis of proteins is viable, we performed GFP protein synthesis inside our liposomes and recorded measurable fluorescence. Additionally, purified GFP was encapsulated to prove high encapsulation efficiency. To validate membrane protein integration into the membrane, pore forming membrane protein a-hemolysin was inserted into liposomes and the leakage of fluorophore molecule calcein was recorded in the outer solution. </p> | ||
− | <video width="100% | + | |
+ | <div class="image-container"> | ||
+ | <video width="100%" controls> | ||
<source src="https://static.igem.org/mediawiki/2018/f/fc/T--Vilnius-Lithuania--Fig7_Liposomes_formation_video.mp4" type="video/mp4"> | <source src="https://static.igem.org/mediawiki/2018/f/fc/T--Vilnius-Lithuania--Fig7_Liposomes_formation_video.mp4" type="video/mp4"> | ||
</video> | </video> | ||
− | <strong>Fig. 2</strong> High throughput synthesis of liposomes with customly modified OLA method. The video is 30x slowed down. The width of post-junction channel is 200 µm. | + | <p><strong>Fig. 2</strong> High throughput synthesis of liposomes with customly modified OLA method. The video is 30x slowed down. The width of post-junction channel is 200 µm.</p> |
+ | </div> | ||
<img src="https://static.igem.org/mediawiki/2018/4/4e/T--Vilnius-Lithuania--Fig8_Liposomes.png"> | <img src="https://static.igem.org/mediawiki/2018/4/4e/T--Vilnius-Lithuania--Fig8_Liposomes.png"> |
Revision as of 21:21, 4 November 2018
Proof of Concept
The Composite Proof
We proved that our SynDrop system worked as intended by successfully implementing several critical wet lab and dry lab experiments. First, we have created a model to determine microfluidics variables for optimal liposome synthesis. Second, we synthesized stable biocompatible liposomes and demonstrated an internal transcription and translation of functional proteins. Third, we demonstrated that membrane proteins can successfully integrate into our liposomes. Finally, we constructed working fusion proteins that were able to display a designated tag on the outer membrane.
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