The Hidden Cost of Fusion: Intrinsic Asymmetry in Vesicle Fusion Restricts Synthetic Cell Growth

Membrane fusion is essential for signaling, cargo delivery, and synthetic cell growth, yet its mechanical consequences remain poorly defined. How fusion-driven membrane growth can be sustained without compromising compartment stability remains an unresolved challenge. Here, we established a minimal reconstituted system where content-loaded small liposomes fuse with single cell-sized giant unilamellar vesicles (GUVs), combining micropipette delivery, electrodeformation, and live imaging. Fusion outcomes were quantified through lipid and content mixing assays, GUV electrodeformation to track area and tension, and phase contrast imaging to monitor leakage. GUVs incorporated lipids and cargo from hundreds of thousands of vesicles at unprecedented efficiency rates, enabling substantial growth. However, accumulation of leaflet asymmetries induced curvature and tension, driving budding, rupture and leakage. Hemifusion amplified these destabilizing effects. Lipid number asymmetries emerge as a dominant mechanical cost of fusion, highlighting how cells may regulate these processes and guiding the design of therapeutic delivery systems and synthetic cells capable of robust and stable growth.