Abstract
Solid-state NMR studies of collagen samples of various origins confirm that the amplitude of collagen backbone and sidechain motions increases significantly on increasing the water content. This conclusion is supported by the changes observed in three different NMR observables: (i) the linewidth dependence on the 1H decoupling frequency; (ii) 13C CSA changes for the peptide carbonyl groups, and (iii) dephasing rates of 1H-13C dipolar couplings. In particular, a nearly threefold increase in motional amplitudes of the backbone librations about C-Cα or N-Cα bonds was found on increasing the added water content up to 47 wt%D2 O. On the basis of the frequencies of NMR observables involved, the timescale of the protein motions dependent on the added water content is estimated to be of the order of microseconds. This estimate agrees with that from wideline T2(1)H NMR measurements. Also, our wideline 1H NMR measurements revealed that the timescale of the microsecond motions in proteins reduces significantly on increasing the added water content, i.e., an ∼15-fold increase in protein motional frequencies is observed on increasing the added water content to 45 wt% D2 O. The observed changes in collagen dynamics is attributed to the increase in water translational diffusion on increasing the amount of added water, which leads to more frequent "bound water/free water" exchange on the protein surface, accompanied by the breakage and formation of new hydrogen bonds with polar functionalities of protein.
Highlights
Collagen (“glue forming” in Greek) is one of the most abundant proteins in Nature.[1]
The measured line widths of the peak at 25 ppm due to c-CH2 of Pro at 7=8th of its height were 67 Hz at mD 5 64 kHz and 54 Hz at mD 5 96 kHz. These preliminary observations are indicative of the dependence of collagen dynamics on its water content, they are not conclusive
Despite the simplicity of the model considto those measured by Reichert et al.[17] for collagen from bovine Achilles tendon (CBAT) may be caused ered, these results suggest that the increase of the water conby the higher water content in parchments
Summary
Collagen (“glue forming” in Greek) is one of the most abundant proteins in Nature.[1]. Solid-state 13C crosspolarization (CP) and magic angle spinning (MAS) NMR spectra will be measured to derive anisotropic chemical shift values, which will be used to estimate changes in the motional amplitudes depending on temperature and water content.
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