Abstract
In the field of bottom‐up synthetic biology, lipid vesicles provide an important role in the construction of artificial cells. Giant unilamellar vesicles (GUVs), due to their membrane's similarity to natural biomembranes, have been widely used as cellular mimics. So far, several methods exist for the production of GUVs with the possibility to encapsulate biological macromolecules. The inverted emulsion‐based method is one such technique, which has great potential for rapid production of GUVs with high encapsulation efficiencies for large biomolecules. However, the lack of understanding of various parameters that affect production yields has resulted in sparse adaptation within the membrane and bottom‐up synthetic biology research communities. Here, we optimize various parameters of the inverted emulsion‐based method to maximize the production of GUVs. We demonstrate that the density difference between the emulsion droplets, oil phase, and the outer aqueous phase plays a crucial role in vesicle formation. We also investigated the impact that centrifugation speed/time, lipid concentration, pH, temperature, and emulsion droplet volume has on vesicle yield and size. Compared to conventional electroformation, our preparation method was not found to significantly alter the membrane mechanical properties. Finally, we optimize the parameters to minimize the time from workbench to microscope and in this way open up the possibility of time‐sensitive experiments. In conclusion, our findings will promote the usage of the inverted emulsion method for basic membrane biophysics studies as well as the development of GUVs for use as future artificial cells.
Highlights
Minimal cell research has gained considerable interest in recent years.[1]
The inverted emulsion-based method is relatively a new technique for producing giant vesicles when compared to electroformation or gentle hydration
Our results demonstrate that density gradients by using sugars are vitally important in manipulating the overall yield of the Giant unilamellar vesicles (GUVs)
Summary
Minimal cell research has gained considerable interest in recent years.[1] Successful realization of which could open up the possibilities of a deeper understanding of biological cell complexities and for engineering new artificial cells designed with specific tasks in mind. The “top-down” approach aims to reach this goal through the modification of pre-existing organisms. The construction of a minimal cell from the bottom-up should be possible by mimicking and redesigning what we see in nature using individual components, such as sugars, lipids, proteins, and genetic material.[2] Before these steps can take place, a suitable compartment system to con-
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