Competitive membrane wetting of polymer blends in artificial cells initiates phase separation and promotes fractionation

Abstract

AbstractBiomolecular condensates driven by liquid–liquid phase separation (LLPS) have received attention as novel activity regulators of living organisms. In intracellular LLPS, an important question is what type of biomolecules form condensates under what conditions. In this regard, possible interactions between biomolecules have been investigated. Recently, LLPS condensates have been reported to regulate the membrane structure upon wetting. However, the possibility of membrane wetting, in which the membrane conversely regulates the LLPS, remains unexplored. Using droplets of short polyethylene glycol and long dextran blends encapsulated with a lipid membrane, we demonstrate that membrane wetting regulates LLPS in cell-size spaces and alters the equilibrium state. In smaller droplets, the two-phase region expands beyond the bulk system, and the fractionation degree increases, particularly during the separation between short PEG and long dextran. We explain the space-size dependent LLPS based on the competitive membrane wetting between the polymers. Smaller droplets promote the membrane wetting of short PEG, which enhances the depletion force between long dextran molecules and finally induces LLPS. This shows that competition for membrane wettability among various molecules can regulate LLPS in cell-size spaces, rendering this LLPS principle feasible in living cells.