Tween-20 induces the structural remodelling of single lipid vesicles

The interaction of Tween-20 with lipid membranes is crucial for a number of biotechnological applications including viral inactivation and membrane protein extraction, but the underlying mechanistic details have remained elusive. Evidence from ensemble assays supports a global model of Tween-20 induced membrane disruption that broadly encompasses association of the surfactant with the membrane surface, membrane fragmentation and the release of mixed micelles to solution, but whether this process involves intermediate and dynamic transitions between regimes is an open question. In search of the mechanistic origins of membrane disruption, increasing focus is put on identifying Tween-20 interactions with highly controllable model membranes. In light of this, and to unveil quantitative mechanistic details, we employed highly interdisciplinary biophysical approaches, including quartz-crystal microbalance with dissipation monitoring, steady-state and time-resolved fluorescence and FRET spectroscopy, dynamic light scattering, fluorescence correlation spectroscopy, wide-field single-vesicle imaging and scanning electron microscopy, to interrogate the interactions between Tween-20 and both freely-diffusing and surface-immobilized model-membrane vesicles. Using ultrasensitive sensing approaches, we discovered that Tween-20 leads to a stepwise and phase-dependent structural remodelling of sub-micron sized vesicles that includes permeabilization and swelling, even at detergent concentrations below the critical micellar concentration. These insights into the structural perturbation of lipid vesicles upon Tween-20 interaction highlight the impact on vesicle conformation prior to complete solubilization, and the tools presented may have general relevance for probing the interaction between lipid vesicles and a wide variety of disruptive agents.