Abstract
We report on the temperature dependence, at microwave (mw) frequency, of the imaginary part of the dielectric constant (ε″) in myoglobin powder samples with different hydration levels (h). The measurements have been performed by the cavity perturbation technique, in the range of temperature 80–345 K. The sample is located inside a glass capillary along the axis of a cylindrical copper cavity, resonating in the TE011mode at 9.6 GHz, where the mw electric field has a node. By measuring the variation of the quality factor of the resonant cavity, one can extract the imaginary part of the dielectric constant. At temperatures higher than 230 K we observe an evident increase of the dielectric losses with increasing temperature; the effect scales almost linearly with hydration, indicating that it must be attributed to a relaxation of water in the hydration shell of the protein. Furthermore, ath≥0.18, we observe a clear peak in the ε″ vs.Tcurve, that shifts towards lower temperatures upon increasing hydration; this shows that the activation enthalpy of the hydration water relaxation decreases with hydration. More in general, our data show that the technique of microwave cavity perturbation allows one to study the dynamics of water molecules in the hydration shell of proteins and to extend information obtained with dielectric techniques to the mw frequencies.
Highlights
The physiological function of proteins is strongly correlated to their interaction with the surrounding environment
Interaction with the protein surface changes the dynamics of water molecules: structural water is tightly bound to the protein and it is almost impossible to remove it without damaging the protein, while water in the first hydration shell exhibits slower relaxations with respect to bound water
It is well known that free water molecules show a dielectric relaxation, due to rotational motions, at room temperature at ∼10 GHz [3]; at the same time, it is expected that bound water exhibits relaxation rates slower than free-water’s one
Summary
The physiological function of proteins is strongly correlated to their interaction with the surrounding environment. The method has important advantages over E-field cavity perturbation measurements, especially for high dielectric constant (water containing samples); since the working frequency is inside the region of dispersion of water molecules, the experimental technique is expected to enable one to investigate the dynamics of water in the hydration shell of proteins.
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