Protein conformational entropy is not slaved to water. Academic Article

abstract

• Conformational entropy can be an important element of the thermodynamics of protein functions such as the binding of ligands. The observed role for conformational entropy in modulating molecular recognition by proteins is in opposition to an often-invoked theory for the interaction of protein molecules with solvent water. The "solvent slaving" model predicts that protein motion is strongly coupled to various aspects of water such as bulk solvent viscosity and local hydration shell dynamics. Changes in conformational entropy are manifested in alterations of fast internal side chain motion that is detectable by NMR relaxation. We show here that the fast-internal side chain dynamics of several proteins are unaffected by changes to the hydration layer and bulk water. These observations indicate that the participation of conformational entropy in protein function is not dictated by the interaction of protein molecules and solvent water under the range of conditions normally encountered.

authors

• Wand, Joshua

published proceedings

• Sci Rep

altmetric score

• 2.25

author list (cited authors)

• Marques, B. S., Stetz, M. A., Jorge, C., Valentine, K. G., Wand, A. J., & Nucci, N. V.

citation count

• 4

complete list of authors

• Marques, Bryan S||Stetz, Matthew A||Jorge, Christine||Valentine, Kathleen G||Wand, A Joshua||Nucci, Nathaniel V

publication date

• October 2020

publisher

• Springer Nature  Publisher

published in

• Scientific Reports  Journal

keywords

• Biophysical Phenomena
• Entropy
• Ligands
• Magnetic Resonance Spectroscopy
• Protein Conformation
• Proteins
• Solvents
• Thermodynamics
• Ubiquitin
• Viscosity
• Water

PubMed Central ID

• 33067552

Digital Object Identifier (DOI)

• 10.1038/s41598-020-74382-5

start page

• 17587

volume

• 10

issue

• 1

URL

• http://dx.doi.org/10.1038/s41598-020-74382-5