Mimicking Cellular Metabolism in Artificial Cells: Universal Molecule Transport across the Membrane through Vesicle Fusion

Abstract: Mass transport across cell membranes is a primary process for cellular metabolism. For this purpose, electrostatically mediated membrane fusion is exploited to transport various small molecules including glucose-6-phosphate, isopropyl β-D-thiogalactoside, and macromolecules such as DNA plasmids from negatively charged large unilamellar vesicles (LUVs) to positively charged giant unilamellar vesicles (GUVs). After membrane fusion between these oppositely charged vesicles, molecules are transported into GUVs to … Show more

“…The thylakoid‐containing artificial cells were prepared using the water‐in‐oil (W/O) emulsion transfer method. [ 15 ] The cartoon is the representation of a thylakoid‐containing artificial cell (Figure 2b, left image). The typical fluorescence image of GUVs containing thylakoids is presented in Figure 2b (right image), where the red dots are thylakoids.…”

Light‐Harvesting Artificial Cells for the Generation of ATP and NADPH^†

“…The thylakoid‐containing artificial cells were prepared using the water‐in‐oil (W/O) emulsion transfer method. [ 15 ] The cartoon is the representation of a thylakoid‐containing artificial cell (Figure 2b, left image). The typical fluorescence image of GUVs containing thylakoids is presented in Figure 2b (right image), where the red dots are thylakoids.…”

Light‐Harvesting Artificial Cells for the Generation of ATP and NADPH^†

“…Phospholipids are double-chained amphiphiles, which possess a hydrophilic phosphate ester head (in their thick membrane) and two hydrophobic acyl tails (in their internal aqueous reservoir) . Due to the biocompatibility of phospholipids, phospholipid vesicles , are one of the most common artificial cells; in addition, the size distribution of phospholipid vesicles is wide, ranging from nanometers to micrometers . Similar to phospholipids, fatty acids also have hydrophilic and hydrophobic groups, allowing them to form bilayers, vesicles, and micelles in water as well, but with a much simpler structure.…”

Synthetic Intracellular Environments: From Basic Science to Applications

“…Within the past several decades, the field of synthetic biology has exploded, allowing for construction of synthetic cells that resemble and model aspects of natural biological life. Modeling cellular pathways and behaviors in synthetic cells offers many advantages over live cells such as a more simplified and defined reaction environment, complete control over the proteomic and chemical makeup of the cell, the ability to compartmentalize interfering biological pathways and processes, as well as maintaining important biological systems that are absent in in vitro reaction systems. , These unique assets of synthetic cell technologies have already allowed for simulation of biological conditions and pathways within a life-like in vitro bioreactor (synthetic cell) and brought a better understanding to many areas of study, including molecular crowding, lipid–protein dynamics, minimal metabolism, and many other critical aspects of biological life . These life-like synthetic cells with their unique assets are rapidly becoming better models and shedding more light into the mysterious inner workings of cellular life. , …”

Parasites, Infections, and Inoculation in Synthetic Minimal Cells