Minimal Coarse-Grained Modelling Towards Implicit-Solvent Simulation of Generic Bolaamphiphiles

TL;DR

This paper introduces a simple dual-site, coarse-grained model for bolaamphiphiles that captures their self-assembly and membrane behavior in implicit solvent, enabling mesoscopic simulations of their structures and dynamics.

Contribution

The paper presents the first dual-site, solvent-free coarse-grained model for bolas that reproduces key self-assembly and membrane properties, extending simulation capabilities.

Findings

Model bolas self-assemble into micelles, rods, lamellae.

Presence of bolas increases bilayer stability and impermeability.

Rigid bolas form helical rods despite being achiral.

Abstract

A simple, dual-site model of bolaamphiphiles (bolaforms or bipolar amphiphiles) is developed based on an earlier single-site model of (monopolar) amphiphiles [S. Dey, J. Saha, Phys. Rev. E 95, 023315 (2017)]. The model incorporates aqueous environment (both hydrophobic effect and hydration force) in its anisotropic site-site interactions, thus obviating the need to simulate solvent particles explicitly. This economy of sites and the absence of explicit solvent particles enable molecular dynamics simulations of bolaamphiphiles to achieve mesoscopic length and time-scales unattainable by any bead-spring model or explicit solvent computations. The model applies to generic bolas only, since the gain in scale can only be obtained by sacrificing the resolution of detailed molecular structure. Thanks to dual-sites, however, (as opposed to a single-site model) our model can incorporate the essential flexibility of bolas that leads to their U-conformers. The model bolas show successful self-assembly into experimentally observed nano-structures like micelles, rods, lamellae etc. and retain fluidity in very stable monolayers. Presence of membrane-spanning model bolas in bilayers of model monopolar amphiphiles increases the stability and impermeability of the lamellar phase. Model bolas are also seen to be less diffusive and to produce thicker layers compared to their monopolar counterparts. Rigid model bolas, though achiral themselves, show self-assembly into helical rods. As all these observations agree with the well-known key characteristics of archaeal lipids and synthetic bolaamphiphiles, our model promises to be effective for studies of bolas in context of biomimetics, drug-delivery and low molecular weight hydrogelators. To the best of our knowledge, no other single or dual-site, solvent-free model for bolas has been reported thus far.