Abstract

In the protein secretory pathway of the cell, the Coat Protein Complex II (COPII) is a crucial molecular machine that transports protein payloads from the Endoplasmic Reticulum (ER) to the Golgi Body. Sar1, a COPII component protein, initiates the protein transport mechanism by budding vesicles on the subdomains of ER after being activated by GDP/GTP exchange. Based on crystallographic and cryo-EM study, the conformational change of Sar1's amino terminal amphipathic helix following GTP binding is considered to be a critical factor in the initiation of the vesicle budding step. However, such GTP triggered conformational switch mechanism remains incomplete without the explicit molecular details of the penetration of the amino terminus of GDP and GTP bound state into the membrane. We perform all-atom, explicit solvent Molecular Dynamics simulation to capture atomistic insights into the differential membrane binding and bending ability of GDP and GTP bound Sar1. We demonstrate that in the GDP-bound state, Sar1 partially inserts its amino terminus into the membrane (residues 1-12), whereas in the GTP-bound state, the whole amino terminus stays horizontally buried inside the membrane (residues 1-23). Thus, GTP bound Sar1 triggers strong inter-leaflet stress due to excess volume insertion in the membrane leading to ∼10-20 fold enhancement in positive curvature induction compared to that due to GDP bound form. We reveal that the magnitude of membrane curvature formation is further amplified by the dimerization of the GTP bound state. Although amphipathic helices are known to generate positive curvature on membranes our simulations reinforce the dominance of the amount of volume inclusion over its penetration depth inside the membrane in this process. Together, we propose a thorough molecular basis for the activity of Sar1-mediated membrane remodeling activity.

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