ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.

There is considerable evidence for the essential role of surface water in protein function and structure. However, it is unclear to what extent the hydration water and protein are coupled and interact with each other. Here, we show by ESR experiments (cw, DEER, ESEEM, and ESE techniques) with spin-l...

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Main Authors: Yei-Chen Lai, Yi-Fan Chen, Yun-Wei Chiang
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2013-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC3695931?pdf=render
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spelling doaj-6d545453f3554f71a7f593c2ed1703352020-11-24T21:51:07ZengPublic Library of Science (PLoS)PLoS ONE1932-62032013-01-0186e6826410.1371/journal.pone.0068264ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.Yei-Chen LaiYi-Fan ChenYun-Wei ChiangThere is considerable evidence for the essential role of surface water in protein function and structure. However, it is unclear to what extent the hydration water and protein are coupled and interact with each other. Here, we show by ESR experiments (cw, DEER, ESEEM, and ESE techniques) with spin-labeling and nanoconfinement techniques that the vitrified hydration layers can be evidently recognized in the ESR spectra, providing nanoscale understanding for the biological interfacial water. Two peptides of different secondary structures and lengths are studied in vitrified bulk solvents and in water-filled nanochannels of different pore diameter (6.1~7.6 nm). The existence of surface hydration and bulk shells are demonstrated. Water in the immediate vicinity of the nitroxide label (within the van der Waals contacts, ~0.35 nm) at the water-peptide interface is verified to be non-crystalline at 50 K, and the water accessibility changes little with the nanochannel dimension. Nevertheless, this water accessibility for the nanochannel cases is only half the value for the bulk solvent, even though the peptide structures remain largely the same as those immersed in the bulk solvents. On the other hand, the hydration density in the range of ~2 nm from the nitroxide spin increases substantially with decreasing pore size, as the density for the largest pore size (7.6 nm) is comparable to that for the bulk solvent. The results demonstrate that while the peptides are confined but structurally unaltered in the nanochannels, their surrounding water exhibits density heterogeneity along the peptide surface normal. The causes and implications, especially those involving the interactions between the first hydration water and peptides, of these observations are discussed. Spin-label ESR techniques are proven useful for studying the structure and influences of interfacial hydration.http://europepmc.org/articles/PMC3695931?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Yei-Chen Lai
Yi-Fan Chen
Yun-Wei Chiang
spellingShingle Yei-Chen Lai
Yi-Fan Chen
Yun-Wei Chiang
ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
PLoS ONE
author_facet Yei-Chen Lai
Yi-Fan Chen
Yun-Wei Chiang
author_sort Yei-Chen Lai
title ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
title_short ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
title_full ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
title_fullStr ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
title_full_unstemmed ESR study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
title_sort esr study of interfacial hydration layers of polypeptides in water-filled nanochannels and in vitrified bulk solvents.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2013-01-01
description There is considerable evidence for the essential role of surface water in protein function and structure. However, it is unclear to what extent the hydration water and protein are coupled and interact with each other. Here, we show by ESR experiments (cw, DEER, ESEEM, and ESE techniques) with spin-labeling and nanoconfinement techniques that the vitrified hydration layers can be evidently recognized in the ESR spectra, providing nanoscale understanding for the biological interfacial water. Two peptides of different secondary structures and lengths are studied in vitrified bulk solvents and in water-filled nanochannels of different pore diameter (6.1~7.6 nm). The existence of surface hydration and bulk shells are demonstrated. Water in the immediate vicinity of the nitroxide label (within the van der Waals contacts, ~0.35 nm) at the water-peptide interface is verified to be non-crystalline at 50 K, and the water accessibility changes little with the nanochannel dimension. Nevertheless, this water accessibility for the nanochannel cases is only half the value for the bulk solvent, even though the peptide structures remain largely the same as those immersed in the bulk solvents. On the other hand, the hydration density in the range of ~2 nm from the nitroxide spin increases substantially with decreasing pore size, as the density for the largest pore size (7.6 nm) is comparable to that for the bulk solvent. The results demonstrate that while the peptides are confined but structurally unaltered in the nanochannels, their surrounding water exhibits density heterogeneity along the peptide surface normal. The causes and implications, especially those involving the interactions between the first hydration water and peptides, of these observations are discussed. Spin-label ESR techniques are proven useful for studying the structure and influences of interfacial hydration.
url http://europepmc.org/articles/PMC3695931?pdf=render
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AT yunweichiang esrstudyofinterfacialhydrationlayersofpolypeptidesinwaterfillednanochannelsandinvitrifiedbulksolvents
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