Hydrophobicity of proteins and nanostructured solutes is governed by topographical and chemical context

Xi, Erte; Venkateshwaran, Vasudevan; Li, Lijuan; Rego, Nicholas B.; Patel, Amish J.; Garde, Shekhar

doi:10.1073/pnas.1700092114

Cited by 98 publications

(151 citation statements)

References 66 publications

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“…Our findings are consistent with those of Pettitt and co-workers, who showed that the conformation of alkane chains and peptides can influence their hydration free energies substantially [66][67][68]. Our results also lend further support to the notion that surface-area models, which are commonly used to estimate the driving force of hydrophobic assembly, but are incapable of capturing subtle but important differences between the rigid and flexible solutes, are not appropriate for a quantitative treatment of hydrophobic hydration and interactions [66,69].…”

Section: B Hard-sphere Alkanesupporting

confidence: 91%

Characterizing Solvent Density Fluctuations in Dynamical Observation Volumes

et al. 2019

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Hydrophobic effects drive diverse aqueous assemblies, such as micelle formation or protein folding, wherein the solvent plays an important role. Consequently, characterizing the free energetics of solvent density fluctuations can lead to important insights into these processes. Although techniques such as the indirect umbrella sampling (INDUS) method (Patel et al. J. Stat. Phys. 2011, 145, 265-275) can be used to characterize solvent fluctuations in static observation volumes of various sizes and shapes, characterizing how the solvent mediates inherently dynamic processes, such as self-assembly or conformational change, remains a challenge. In this work, we generalize the INDUS method to facilitate the enhanced sampling of solvent fluctuations in dynamical observation volumes, whose positions and shapes can evolve. We illustrate the usefulness of this generalization by characterizing water density fluctuations in dynamic volumes pertaining to the hydration of flexible solutes, the assembly of small hydrophobes, and conformational transitions in a model peptide. We also use the method to probe the dynamics of hard spheres.

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Section: B Hard-sphere Alkanesupporting

confidence: 91%

Characterizing Solvent Density Fluctuations in Dynamical Observation Volumes

et al. 2019

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“…19,22,[26][27][28][29][30][31][32][33][34][35] In contrast with simple hydrophobic or hydrophilic surfaces, proteins display nanoscopic chemical and topographical patterns, which influence their interactions with water in nontrivial ways. 20,[36][37][38][39][40][41][42][43][44][45][46] By interrogating how protein hydration waters respond to an unfavorable potential, here we find that the hydration shells of diverse proteins are also situated at the edge of a dewetting transition. Such a resemblance of protein hydration shells to extended hydrophobic surfaces appears to arise from the fact that -even for protein surfaces that are enriched in polar and charged residues -roughly half the surface consists of hydrophobic atoms.…”

Section: Introductionmentioning

confidence: 78%

Protein Hydration Waters Are Susceptible to Unfavorable Perturbations

Rego

Patel

2019

J. Am. Chem. Soc.

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The interactions of a protein, its phase behavior, and ultimately, its ability to function, are all influenced by the interactions between the protein and its hydration waters. Here we study proteins with a variety of sizes, shapes, chemistries, and biological functions, and characterize their interactions with their hydration waters using molecular simulation and enhanced sampling techniques. We find that akin to extended hydrophobic surfaces, proteins situate their hydration waters at the edge of a dewetting transition, making them susceptible to unfavorable perturbations. We also find that the strength of the unfavorable potential needed to trigger dewetting is roughly the same, regardless of the protein being studied, and depends only the width of the hydration shell being perturbed. Our findings establish a framework for systematically classifying protein patches according to how favorably they interact with water.

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“…[11][12][13] Common implicit solvation models describe water-mediated interactions based on a context-independent classification of molecular surfaces as either hydrophobic or hydrophilic. While such approaches provide qualitative insights, experiments 14 and explicit solvent simulations [15][16][17] show that the atomistic detail of molecular surfaces significantly affects interactions with an aqueous solvent. This is particularly the case in the context of chemically and topologically heterogeneous surfaces of biomolecules, where microscopic features ultimately determine whether solvent/water-mediated interactions between two interfaces are attractive or repulsive.…”

Section: Introductionmentioning

confidence: 99%

“…Useful insights into local hydrophobic or hydrophilic properties of a molecular surface can be obtained from local water density fluctuations that are easily analyzed in explicit solvent computer simulations. [15][16][17][18] The latter are increased in the case of hydrophobic surfaces, while attractive interactions of water with a polar surface suppress fluctuations. 15 As an alternative to the analysis of density fluctuations, explicit solvent simulations in the presence of small hydrophobic probe particles show directly where attractive water-mediated interactions result in an increase in the local concentration of the probe particles.…”

Section: Introductionmentioning

confidence: 99%

Disassembling solvation free energies into local contributions—Toward a microscopic understanding of solvation processes

Heyden

2018

WIREs Comput Mol Sci

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Solvation free energies contribute to the driving force of molecular processes in solution and play a significant role for the relative stability of biomolecular conformations or the formation of complexes. Changes in solvation free energy are the origin of solvent‐mediated interactions such as the hydrophobic effect in water. However, an accurate description of solvation free energies, specifically in aqueous solution, without explicit representation of the solvent is a challenging task in computer simulations. To improve existing models detailed microscopic information on solute–solvent interactions is required, which is not directly accessible from experiments. Explicit solvent simulations include solvent‐mediated effects, however, at a considerable computational cost. Computational tools have been proposed in recent years to extract information on solvation free energies and solute–solvent interactions from explicit solvent simulations. The latter includes spatial decompositions of the solvation enthalpy and entropy, which may eventually lead to an improved theoretical understanding of solvation thermodynamics. This article is categorized under: Molecular and Statistical Mechanics> Free Energy Methods Theoretical and Physical Chemistry > Statistical Mechanics Structure and Mechanism > Computational Biochemistry and Biophysics

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Hydrophobicity of proteins and nanostructured solutes is governed by topographical and chemical context

Cited by 98 publications

References 66 publications

Characterizing Solvent Density Fluctuations in Dynamical Observation Volumes

Characterizing Solvent Density Fluctuations in Dynamical Observation Volumes

Protein Hydration Waters Are Susceptible to Unfavorable Perturbations

Disassembling solvation free energies into local contributions—Toward a microscopic understanding of solvation processes

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