Exploring the Molecular Dynamics of a Lipid-A Vesicle at the Atom Level: Morphology and Permeation Mechanism

Lipid-A was previouslyshown to spontaneously aggregateinto avesicle via the hybrid particle field approach. Weassess the validity of the proposed vesiculation mechanism by simulatingthe resulting lipid-A vesicle at the atom level. The spatial confinementimposed by the vesicle geometry on the conformation and packing oflipid-A induces significant heterogeneity of physical properties inthe inner and outer leaflets. It also induces tighter molecular packingand lower acyl chain order compared to the lamellar arrangement. Around5% of water molecules passively permeates the vesicle membrane inwardand outward. The permeation is facilitated by interactions with watermolecules that are transported across the membrane by a network ofelectrostatic interactions with the hydrogen bond donors/acceptorsin the N-acetylglucosamine ring and upper regionof the acyl chains of lipid-A. The permeation process takes placeat low rates but still at higher frequencies than observed for thelamellar arrangement of lipid-A. These findings not only substantiatethe proposed lipid-A vesiculation mechanism but also reveal the complexstructural dynamics of an important nonlamellar arrangement of lipid-A. (AU)