Structure and thermodynamics of aqueous urea solutions from ambient to kilobar pressures: From thermodynamic modeling, experiments, and first principles simulations to an accurate force field description

Molecular simulations based on classical force fields are a powerful method for shedding light on the complex behavior of biomolecules in solution. When cosolutes are present in addition to water and biomolecules, subtle balances of weak intermolecular forces have to be accounted for. This imposes h...

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Published in:Biophysical chemistry 2019-11, Vol.254, p.106260-106260, Article 106260
Main Authors: Hölzl, Christoph, Kibies, Patrick, Imoto, Sho, Noetzel, Jan, Knierbein, Michael, Salmen, Paul, Paulus, Michael, Nase, Julia, Held, Christoph, Sadowski, Gabriele, Marx, Dominik, Kast, Stefan M., Horinek, Dominik
Format: Article
Language:English
Subjects:
Molecular Dynamics Simulation
Pressure
Solutions - chemistry
Thermodynamics
Urea - chemistry
Water - chemistry
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Summary:Molecular simulations based on classical force fields are a powerful method for shedding light on the complex behavior of biomolecules in solution. When cosolutes are present in addition to water and biomolecules, subtle balances of weak intermolecular forces have to be accounted for. This imposes high demands on the quality of the underlying force fields, and therefore force field development for small cosolutes is still an active field. Here, we present the development of a new urea force field from studies of urea solutions at ambient and elevated hydrostatic pressures based on a combination of experimental and theoretical approaches. Experimental densities and solvation shell properties from ab initio molecular dynamics simulations at ambient conditions served as the target properties for the force field optimization. Since urea is present in many marine life forms, elevated hydrostatic pressure was rigorously addressed: densities at high pressure were measured by vibrating tube densitometry up to 500 bar and by X-ray absorption up to 5 kbar. Densities were determined by the perturbed-chain statistical associating fluid theory equation of state. Solvation properties were determined by embedded cluster integral equation theory and ab initio molecular dynamics. Our new force field is able to capture the properties of urea solutions at high pressures without further high-pressure adaption, unlike trimethylamine-N-oxide, for which a high-pressure adaption is necessary. [Display omitted] •Experimental densities of urea solutions are determined up to 5 kbar.•Aqueous urea solutions are studied by theoretical methods up to 10 kbar•A new nonpolarizable force field for urea in aqueous solutions is developed.
ISSN:0301-4622
1873-4200
DOI:10.1016/j.bpc.2019.106260