Temperature dependence of membrane viscosity of ternary lipid GUV with L domains.

In the cell membrane, it is considered that saturated lipids and cholesterol organize liquid-ordered (L) domains in a sea of liquid-disordered (L) phases and proteins relevant to cellular functions are localized in the L domains. Since the diffusion of transmembrane proteins is regulated by the membrane viscosity, we investigate the temperature dependence of the membrane viscosity of the ternary giant unilamellar vesicles (GUVs) composed of the saturated lipid 1,2-dipalmitoyl-sn-glycero-3-phosphocholine, the unsaturated lipid 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC), and cholesterol to understand the effect of the phase separation on the membrane viscosity using a microinjection technique. In the microinjection method, membrane viscosity is estimated by comparing the flow pattern induced on a spherical membrane with a hydrodynamic model. For phase-separated GUVs, the flow pattern is visualized by the motion of the domains. In this study, we developed a method to visualize the flow patterns of homogeneous GUVs above the phase separation temperature by using beads attached to the GUVs. We succeeded in measuring the membrane viscosity of ternary GUVs both above phase separation temperature and in the phase-separated region and found that the membrane viscosity decreases dramatically by phase separation. In the phase-separated region, i.e., GUVs with L domains, the membrane viscosity is determined by that of the L phase, η, and shows weak temperature dependence compared to that of the DOPC single-component GUV, which is a main component of the L phase. We revealed that the Moelwyn-Hughest model, which takes into account the effects of the membrane composition, viscosity of the pure component, and interaction between components, well describes the obtained membrane viscosity of the ternary GUV both above the phase separation temperature and in the phase-separated region. The drastic decrease of the membrane viscosity by the phase separation plays an important role in regulating the mobility of constituents in multi-component membranes.