Stimuli-driven cyclical content exchange in a composite synthetic cell

Engineering sophisticated behaviours in synthetic cells lacking complex biomolecular machinery remains a central challenge in synthetic biology. Here, we introduce a protein-free approach for dynamic content modulation in liposome-based synthetic cells using an internal gelation strategy. By crosslinking a polymer hydrogel within the lumen of giant vesicles and tethering it to the inner membrane leaflet, we create a composite architecture that enables controlled and reversible membrane permeabilisation via osmotic swelling and shrinking, facilitating externally gated material exchange without reconstituted protein pores or electroporation. Simultaneously, the hydrogel matrix affords control over membrane fluidity and the diffusion of cytoplasmic clients. We deploy the transport-regulation platform to construct a synthetic-cell bioreactor whereby reversible membrane permeabilisation enables content supplementation and fuels a biocatalytic reaction. The composite gel-GUV chassis provides an adaptive, robust and expandable solution for engineering increasingly modular and functional synthetic cellular systems. These findings may echo how primordial cells harnessed environmental fluctuations for content exchange through chemically distinct pathways.