Ion pairing in aqueous tetramethylammonium–acetate solutions by neutron scattering and molecular dynamics simulations

Tetramethylammonium (TMA) is a ubiquitous cationic motif in biochemistry, found in the charged choline headgroup of membrane phospholipids and in tri-methylated lysine residues, which modulate histone-DNA interactions and impact epigenetic mechanisms. TMA interactions with anionic species, particularly carboxylate groups of amino acid residues and extracellular sugars, are of substantial biological relevance, as these interactions mediate a wide range of cellular processes. This study investigates the molecular interactions between TMA and acetate, representing carboxylate-containing groups, using neutron scattering experiments complemented by force field and ab initio molecular dynamics (MD) simulations. Neutron diffraction with isotopic substitution reveals specific ion pairing signatures between TMA and acetate, with simulations providing a detailed interpretation of the ion pairing structures. Force fields, notably CHARMM36 with the electronic continuum correction (ECC) (by a factor of 0.85) and AMBER99SB, capture essential pairing characteristics, but only revPBE-based ab initio MD simulations accurately model specific experimental features such as the low Q peak intensity in reciprocal space. Our study delivers a refined molecular model of TMA–carboxylate interactions, guiding the selection of force fields for complex biological systems where such interactions are of a significant importance.