Abstract
Raman optical activity (ROA) spectroscopy is a promising analytical method for studying the structure and conformation of polypeptides and proteins in solution. However, the structural information obtained from such vibrational spectra is only indirect and theoretical studies are often necessary to identify how the structure determines the observed spectra. One particular target is the identification and discrimination of different helical secondary structure elements. Herein, a theoretical investigation of the ROA spectra of a series of 3(10)-helical polypeptides is presented. In particular, the effect of chain length, C(α)-substitution pattern, the introduction of larger aliphatic side chains, and the variation of their conformation on the ROA spectra is studied. To extract general principles from these calculations, the positions, intensities, and shapes of the ROA bands are analyzed in terms of localized modes, which makes it possible to identify possible ROA signatures of 3(10) -helical structures, but also provides fundamental insight into the generation of ROA signals in complex polypeptides. Finally, the calculated spectra can be compared to the previously reported ROA spectrum of a specifically designed 3(10) -helical heptapeptide. This allows most of the features in the experimental spectrum to be assigned.
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