An extended dynamical hydration shell around proteins

Ebbinghaus, Simon; Kim, Seung Joong; Heyden, Matthias; Xin, Yu; Heugen, U.; Gruebele, Martin; Leitner, David M.; Havenith, Martina

doi:10.1073/pnas.0709207104

Cited by 613 publications

(677 citation statements)

References 24 publications

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“…In contrast, by defining reorientationally retarded water as hydration water in our study, we found three to four water layers (~8.5 Å ) from the albumin surface exhibit water dynamics that distinguish it from that of bulk water. This ''global hydration'' view (21,22,(39)(40)(41)(42)(43)(44) is consistent with recent MD simulations, where the perturbation of water's orientational structure induced by the protein was found to be long-ranged, propagating out to three to five hydration shells (21,22).…”

Section: Hydration Statesupporting

confidence: 90%

Hydrogen Bond Network of Water around Protein Investigated with Terahertz and Infrared Spectroscopy

Shiraga

Ogawa

Kondo

2016

Biophysical Journal

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The dynamical and structural properties of water at protein interfaces were characterized on the basis of the broadband complex dielectric constant (0.25 to 400 THz) of albumin aqueous solutions. Our analysis of the dielectric responses between 0.25 and 12 THz first revealed hydration water with retarded reorientational dynamics extending~8.5 Å (corresponding to three to four layers) out from the albumin surface. Second, the number of nonhydrogen-bonded water was decreased in the presence of the albumin solute, indicating protein inhibits the fragmentation of the water hydrogen-bond network. Finally, water molecules at the albumin interface were found to form a distorted hydrogen-bond structure due to topological and energetic disorder of the protein surface. In addition, the intramolecular O-H stretching vibration of water (~100 THz), which is sensitive to hydrogen-bond environment, pointed to a trend that hydration water has a larger population of strongly hydrogen-bonded water molecules compared with that of bulk water. From these experimental results, we concluded that the ''strengthened'' water hydrogen bonds at the protein interface dynamically slow down the reorientational motion of water and form the less-defective hydrogen-bond network by inhibiting the fragmentation of water-water hydrogen bonds. Nevertheless, such a strengthened water hydrogen-bond network is composed of heterogeneous hydrogen-bond distances and angles, and thus characterized as structurally ''distorted.''

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Section: Hydration Statesupporting

confidence: 90%

Hydrogen Bond Network of Water around Protein Investigated with Terahertz and Infrared Spectroscopy

Shiraga

Ogawa

Kondo

2016

Biophysical Journal

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“…Frauenfelder and colleagues have experimentally shown that protein-dominant conformational motions are slaved by the hydration shell and the bulk solvent, 10 whereas the protein molecule itself provides an "active matrix" necessary for guiding the water's dynamics toward biologically relevant conformational changes. The change in water dynamics at the shell of up to almost a dozen water molecule diameters around proteins is found in ref 11. Very recently, a neutron scattering study demonstrated that the interfacial (hydration) water is the main "driving force" of protein dynamics governing both local and large scale motions in proteins.…”

Section: R Ecent Investigations Of Protein Dynamics Indicate Thatmentioning

confidence: 87%

Water–Peptide Dynamics during Conformational Transitions

Nerukh

Karabasov

2013

J. Phys. Chem. Lett.

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Transitions between metastable conformations of a dipeptide are investigated using classical molecular dynamics simulation with explicit water molecules. The distribution of the surrounding water at different moments before the transitions and the dynamical correlations of water with the peptide's configurational motions indicate that the water molecules represent an integral part of the molecular system during the conformational changes, in contrast with the metastable periods when water and peptide dynamics are essentially decoupled. SECTION:Liquids; Chemical and Dynamical Processes in Solution R ecent investigations of protein dynamics indicate that water plays the major role in protein motion. Indeed, there is a large body of experimental and simulation evidence 1−9 showing a close connection between the water dynamics and the protein conformations. Frauenfelder and colleagues have experimentally shown that protein-dominant conformational motions are slaved by the hydration shell and the bulk solvent, 10 whereas the protein molecule itself provides an "active matrix" necessary for guiding the water's dynamics toward biologically relevant conformational changes. The change in water dynamics at the shell of up to almost a dozen water molecule diameters around proteins is found in ref 11. Very recently, a neutron scattering study demonstrated that the interfacial (hydration) water is the main "driving force" of protein dynamics governing both local and large scale motions in proteins. 12 Finally, the critical role of solvating water has been demonstrated for an important applied field of protein− ligand binding. 13 Despite extensive research on protein dynamics, the investigations of elementary conformational motions are rare. The knowledge of specific molecular mechanisms, including the role of water molecules that drive the conformational moves, is highly demanded because these elementary conformational changes ultimately define all rearrangements of proteins as a whole.In this work, we analyze molecular dynamics (MD) simulated peptide focusing on the moments of elementary conformational changes including explicit water molecules. We show that water indeed drives the changes and we elucidate the specific mechanisms of this phenomenon.We study a zwitterion L-alanyl-L-alanine, Figure 1. This is a very convenient model because (i) the conformation of the molecule is completely defined by the two dihedral angles ψ and ϕ; (ii) in water the conformation ψ ≈ 2.5, ϕ ≈ −2.2 radians is prevalent, however, very rare transitions to two other metastable conformations (ψ ≈ −1, ϕ ≈ −2.2 and ψ ≈ 2.5, ϕ ≈ 1) take place, and (iii) the transitions only happen in water because in vacuum the negatively charged COO − group strongly interacts with the positively charged NH 3 + group, excluding all conformations except the one with the groups at the minimal distance from each other.Two different MD models of the system (see the Supporting Information) have been studied. One is the united atom forcefield GROMOS, 14 the othe...

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“…The most marked slowdown was observed for the most hydrophilic protein studied, bovine serum albumin, whereas the most 17 hydrophobic protein, trypsin, had a slightly smaller effect. The terahertz Raman spectra of these protein solutions resemble those of 18 pure water up to a concentration of 5 wt %, above which a new feature appears at ∼80 cm À1 , which is assigned to a bending of the 19 protein amide chain. The time domain data were fitted to the biexponential decay-176 ing function:…”

Section: à12mentioning

confidence: 89%

Water Dynamics at Protein Interfaces: Ultrafast Optical Kerr Effect Study

2011

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water. The most marked slowdown was observed for the most hydrophilic protein studied, bovine serum albumin, whereas the most 17 hydrophobic protein, trypsin, had a slightly smaller effect. The terahertz Raman spectra of these protein solutions resemble those of 18 pure water up to a concentration of 5 wt %, above which a new feature appears at ∼80 cm À1 , which is assigned to a bending of the 19 protein amide chain.

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An extended dynamical hydration shell around proteins

Cited by 613 publications

References 24 publications

Hydrogen Bond Network of Water around Protein Investigated with Terahertz and Infrared Spectroscopy

Hydrogen Bond Network of Water around Protein Investigated with Terahertz and Infrared Spectroscopy

Water–Peptide Dynamics during Conformational Transitions

Water Dynamics at Protein Interfaces: Ultrafast Optical Kerr Effect Study

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