Protein packing defects “heat up” interfacial water

Sierra, María Belén; Accordino, Sebastián R.; Rodriguez-Fris, J. Ariel; Morini, Marcela A.; Appignanesi, Gustavo A.; Fernández, Ariel

doi:10.1140/epje/i2013-13062-7

Cited by 10 publications

(47 citation statements)

References 44 publications

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“…protein binding pockets are expected to be dry or to contain easily removable water which should be displaced by a ligand upon association [9,2,13]. M a n u s c r i p t parallel to the surface, but for graphene the O-H bonds tend to point slightly outerwards, forming an angle close to 70…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…In particular, the hydration properties of protein binding sites have been suggested to play a main role in the binding of ligands or in protein-protein association [9,11,13]. From one side, ligands are expected to displace hydration water molecules from their binding site [9,13]. On the other hand, geometrically-induced surface dehydration (by means of water inaccessibly cavities) has been shown to be central for the existence of reactive sites responsible for protein binding [11,13].…”

Section: Introductionmentioning

confidence: 99%

“…From one side, ligands are expected to displace hydration water molecules from their binding site [9,13]. On the other hand, geometrically-induced surface dehydration (by means of water inaccessibly cavities) has been shown to be central for the existence of reactive sites responsible for protein binding [11,13]. In addition, the behavior of water confined in cylindrical pores or tunnels is also important both from the basic and the applied viewpoints.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Hydrophobicity and geometry: Water at curved graphitic-like surfaces and within model pores in self-assembled monolayers

Alarcón

Accordino

et al. 2014

Fluid Phase Equilibria

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Hydrophobicity and geometry: Water at curved graphitic-like surfaces and within model pores in self-assembled monolayers

Alarcón

Accordino

et al. 2014

Fluid Phase Equilibria

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“…However, the picture of (nano) confined water is still far from being complete (Giovambattista et al 2012;Rasaiah et al 2008;Berne et al 2009;Schulz et al 2011;Alarcón et al 2014). This issue is not only crucial from an intrinsic, fundamental level, but also from its far reaching implications (Fernández 2010;Qvist et al 2008;Berne et al 2009;Young et al 2007;Wang et al 2011;Kulp III et al 2011;Accordino et al 2011aAccordino et al , 2012aAccordino et al , b, c, 2013Schulz et al 2011;Sierra et al 2013;Alarcón et al 2014;Bogan and Thorn 1998;Li and Liu 2009). For example, being water the matrix of life, a full understanding of its behavior in the nano and mesoscales would be essential to understand biology at the molecular level.…”

Section: Introductionmentioning

confidence: 99%

Hydration and Nanoconfined Water: Insights from Computer Simulations

Alarcón

Fris

Morini

et al. 2015

Subcellular Biochemistry

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The comprehension of the structure and behavior of water at interfaces and under nanoconfinement represents an issue of major concern in several central research areas like hydration, reaction dynamics and biology. From one side, water is known to play a dominant role in the structuring, the dynamics and the functionality of biological molecules, governing main processes like protein folding, protein binding and biological function. In turn, the same principles that rule biological organization at the molecular level are also operative for materials science processes that take place within a water environment, being responsible for the self-assembly of molecular structures to create synthetic supramolecular nanometrically-sized materials. Thus, the understanding of the principles of water hydration, including the development of a theory of hydrophobicity at the nanoscale, is imperative both from a fundamental and an applied standpoint. In this work we present some molecular dynamics studies of the structure and dynamics of water at different interfaces or confinement conditions, ranging from simple model hydrophobic interfaces with different geometrical constraints (in order to single out curvature effects), to self-assembled monolayers, proteins and phospholipid membranes. The tendency of the water molecules to sacrifice the lowest hydrogen bond (HB) coordination as possible at extended interfaces is revealed. This fact makes the first hydration layers to be highly oriented, in some situations even resembling the structure of hexagonal ice. A similar trend to maximize the number of HBs is shown to hold in cavity filling, with small subnanometric hydrophobic cavities remaining empty while larger cavities display an alternation of filled and dry states with a significant inner HB network. We also study interfaces with complex chemical and geometrical nature in order to determine how different conditions affect the local hydration properties. Thus, we show some results for protein hydration and, particularly, some preliminary studies on membrane hydration. Finally, calculations of a local hydrophobicity measure of relevance for binding and self-assembly are also presented. We then conclude with a few words of further emphasis on the relevance of this kind of knowledge to biology and to the design of new materials by highlighting the context-dependent and non-additive nature of different non-covalent interactions in an aqueous nanoenvironment, an issue that is usually greatly overlooked.

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Non‐Debye frustrated hydration steers biomolecular association: interfacial tension for the drug designer

Fernández

2016

FEBS Letters

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Many cellular functions involve the assembly of biomolecular complexes, a process mediated by water that gets displaced as subunits bind. This process affects water frustration, that is, the number of unmet hydrogen-bonding opportunities at the protein-water interface. By searching for least-frustrated aqueous interfaces, this study delineates the role of frustration in steering molecular assemblage. The search entails a trajectory sampling using a functional that measures the gradient of frustration and computing the resulting non-Debye electrostatics within relaxation times for coupled protein-water systems. The minimal frustration principle is validated against spectroscopic measurements of frustration-dependent dielectric relaxation, affinity scanning of protein-protein interfaces, and NMR-inferred association propensities of protein-complex intermediates. The methods are applied to drug design, revealing the targetable nature of the aqueous interface.

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Protein packing defects “heat up” interfacial water

Cited by 10 publications

References 44 publications

Hydrophobicity and geometry: Water at curved graphitic-like surfaces and within model pores in self-assembled monolayers

Hydrophobicity and geometry: Water at curved graphitic-like surfaces and within model pores in self-assembled monolayers

Hydration and Nanoconfined Water: Insights from Computer Simulations

Non‐Debye frustrated hydration steers biomolecular association: interfacial tension for the drug designer

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