A Sustainable and Efficient Artificial Microgel System: Toward Creating a Configurable Synthetic Cell

Artificial cells are a powerful platform in the study of synthetic biology and other valuable fields. They share a great potential in defining and utilizing the superiority of the living system. Here, a protein synthesis system based on thermal responsive hydrogels with porous structure is reported. The hydrogels can immobilize plasmids on the surface inside their porous structure through a volume phase transition upon 34 °C, forming an aggregation state of DNAs as in nature conditions. The artificial microgels can carry out bioreactions in cell-free systems and exhibit a sustainable and efficient performance for protein translation. The protein synthesis level reaches a maximum of twice more than that in a conventional solution system when the plasmid concentration is 10–20 ng µL⁻¹, along with a doubled effective interval. This is perhaps attributed to confined transcription and translation processes in the near-surface area of hydrogels. Summarily, the research provides an easy-handling approach in fabricating effective microgels for cell-free synthesis and also inspirations for constructing a configurable artificial cell.