Dipole Strength (DS) of the amides has gained a renewed interest in chemical physics since it provides an important tool to disclose the on-site vibrational energy distributions. Apart from earlier experimental efforts on polypeptides, little is still known about DS in complex proteins. We accurately measured the Fourier Transform Infrared absorption spectra of nine proteins in water solution obtaining their Molar Extinction Coefficient in the amide I and II spectral region. Our results show that the amide I DS value depends on the protein secondary structure, being that of the alpha-rich and unstructured proteins lower by a factor of 2 than that of the beta-rich proteins. The average DS for amino acids in alpha and beta secondary structures confirms this finding. Normal Mode calculation and Molecular Dynamics were performed and used as tools for data analysis and interpretation. The present outcomes corroborate the hypothesis that antiparallel beta-sheet environment is more prone to delocalize the on-site C--O stretching vibration through coupling mechanisms between carbonyl groups, whereas alpha-helix structures are energetically less stable to permit vibrational mode delocalization.
Normal mode calculation and infrared spectroscopy of proteins in water solution: Relationship between amide I transition dipole strength and secondary structure
Luchetti, Nicole;
2021-01-01
Abstract
Dipole Strength (DS) of the amides has gained a renewed interest in chemical physics since it provides an important tool to disclose the on-site vibrational energy distributions. Apart from earlier experimental efforts on polypeptides, little is still known about DS in complex proteins. We accurately measured the Fourier Transform Infrared absorption spectra of nine proteins in water solution obtaining their Molar Extinction Coefficient in the amide I and II spectral region. Our results show that the amide I DS value depends on the protein secondary structure, being that of the alpha-rich and unstructured proteins lower by a factor of 2 than that of the beta-rich proteins. The average DS for amino acids in alpha and beta secondary structures confirms this finding. Normal Mode calculation and Molecular Dynamics were performed and used as tools for data analysis and interpretation. The present outcomes corroborate the hypothesis that antiparallel beta-sheet environment is more prone to delocalize the on-site C--O stretching vibration through coupling mechanisms between carbonyl groups, whereas alpha-helix structures are energetically less stable to permit vibrational mode delocalization.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.