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Temperature and timescale dependence of protein dynamics in methanol : water mixtures

Abstract
Experimental and computer simulation studies have suggested the presence of a transition in the dynamics of hydrated proteins at around 180–220 K. This transition is manifested by nonlinear behaviour in the temperature dependence of the average atomic mean-square displacement which increases at high temperature. Here, we present results of a dynamic neutron scattering analysis of the transition for a simple enzyme: xylanase in water : methanol solutions of varying methanol concentrations. In order to investigate motions on different timescales, two different instruments were used: one sensitive to 100 ps timescale motions and the other to ns timescale motions. The results reveal distinctly different behaviour on the two timescales examined. On the shorter timescale the dynamics are dictated by the properties of the surrounding solvent: the temperature of the dynamical transition lowers with increasing methanol concentration closely following the melting behaviour of the corresponding water : methanol solution. This contrasts with the longer (ns) timescale results in which the dynamical transition appears at temperatures lower than the corresponding melting point of the cryosolvent. These results are suggested to arise from a collaborative effect between the protein surface and the solvent which lowers the effective melting temperature of the protein hydration layer. Taken together, the results suggest that the protein solvation shell may play a major role in the temperature dependence of protein solution dynamics.
Type
Journal Article
Type of thesis
Series
Citation
Tournier, A.L., Reat, V., Dunn, R., Daniel, R., Smith, J. & Finney, J. (2005). Temperature and timescale dependence of protein dynamics in methanol : water mixtures. Physical Chemistry Chemical Physics, 7, 1388-1393.
Date
2005
Publisher
Royal Society of Chemistry
Degree
Supervisors
Rights
This article has been published in the journal: Physical Chemistry Chemical Physics. © 2005 Royal Society of Chemistry.