Impact of the inner solute structure on the electrostatic mean-field and strong-coupling regimes of macromolecular interactions

TL;DR

This paper investigates how the internal structure of solutes influences electrostatic interactions between charged membranes, revealing that solute size and charge distribution significantly modify membrane forces across different electrostatic regimes.

Contribution

It derives a contact-value identity applicable to general solute structures and electrostatic regimes, highlighting the impact of solute size and dielectric contrast on membrane interactions.

Findings

Inner charge spread enhances membrane repulsion and attraction effects.

Solute size and charge distribution alter membrane forces significantly.

Polarization forces extend the influence of solute structure effects beyond immediate proximity.

Abstract

The structural diversity of the solute molecules involved in biomolecular processes necessitates the characterization of the forces between charged macromolecules beyond the point-ion description. From the field theoretic partition function of an electrolyte confined between two anionic membranes, we derive a contact-value identity valid for general intramolecular solute structure and electrostatic coupling strength. In the electrostatic mean-field (MF) regime, the inner charge spread of the solute particles is shown to induce the twofold enhancement of the short-range Poisson-Boltzmann (PB)-level membrane repulsion, and a longer-range depletion attraction. Our contact theorem indicates that the twofold repulsion enhancement by solute size is equally present in the opposite strong-coupling (SC) regime of linear and spherical solute molecules. Upon the inclusion of the dielectric contrast between the electrolyte and the interacting membranes, the emerging polarization forces substantially amplify the solute specificity of the macromolecular interactions. Namely, the finite size of the solute particles composed of similar terminal charges such as putrescine molecules weaken the intermembrane repulsion. However, the extended structure of the solute molecules carrying opposite elementary charges such as ionized atoms and zwitterionic molecules enhance the membrane repulsion by several factors. We also show that these polarization forces can extend the range of the solute structure effects up to intermembrane distances exceeding the solute size by an order of magnitude. This radical alteration of the intermembrane interactions by the salt structure identifies the solute specificity as a key ingredient of the thermodynamic stability in colloidal systems.