Influence of Hydration on Protein Dynamics: Combining Dielectric and Neutron Scattering Spectroscopy Data

Influence of Hydration on Protein Dynamics: Combining Dielectric and Neutron Scattering Spectroscopy Data

Combining dielectric spectroscopy and neutron scattering data for hydrated lysozyme powders, we were able to identify several relaxation processes and follow protein dynamics at different hydration levels over a broad frequency and temperature range. We ascribe the main dielectric process to protein...

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Bibliographic Details
Published in:The journal of physical chemistry. B Vol. 112; no. 45; pp. 14273 - 14280
Main Authors: Khodadadi, S, Pawlus, S, Sokolov, A. P
Format: Journal Article
Language:English
Published: United States American Chemical Society 13-11-2008
Subjects:
Animals
B: Biophysical Chemistry
Electric Impedance
Muramidase - chemistry
Muramidase - metabolism
Neutron Diffraction
Spectrum Analysis
Temperature
Time Factors
Water - chemistry
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Summary:Combining dielectric spectroscopy and neutron scattering data for hydrated lysozyme powders, we were able to identify several relaxation processes and follow protein dynamics at different hydration levels over a broad frequency and temperature range. We ascribe the main dielectric process to protein’s structural relaxation coupled to hydration water and the slowest dielectric process to a larger scale protein’s motions. Both relaxations exhibit a smooth, slightly super-Arrhenius temperature dependence between 300 and 180 K. The temperature dependence of the slowest process follows the main dielectric relaxation, emphasizing that the same friction mechanism might control both processes. No signs of a proposed sharp fragile-to-strong crossover at T ∼ 220 K are observed in temperature dependences of these processes. Both processes show strong dependence on hydration: the main dielectric process slows down by six orders with a decrease in hydration from h ∼ 0.37 (grams of water per grams of protein) to h ∼ 0.05. The slowest process shows even stronger dependence on hydration. The third (fastest) dielectric relaxation process has been detected only in samples with high hydration (h ∼ 0.3 and higher). We ascribe it to a secondary relaxation of hydration water. The mechanism of the protein dynamic transition and a general picture of the protein dynamics are discussed.
Bibliography:istex:5FF9EFB62E5D58392D12DE1C586099163CECD352
ark:/67375/TPS-T930V7LG-M
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ISSN:1520-6106
1520-5207
DOI:10.1021/jp8059807