Terminally blocked (L-Pro-Aib)(n) and Aib-(L-Pro-Aib)(n) sequential oligopeptides are known to form right-handed beta-bend ribbon spirals under a variety of experimental conditions. Here we describe the results of a complete CD and ir characterization of this subtype of 3(10)-helical structure. The electronic CD spectra were obtained in solvents of different polarity in the 260-180 nm region. The vibrational CD and Fourier transform ir (FTIR) spectra were measured in deuterochloroform solution in the amide I and amide II (1750-1500 cm(-1)) regions. The critical chain length for full development of the beta-bend ribbon spiral structure is found to be five to six residues. Spectral effects related to concentration-induced stabilization of the structures of the longer peptides were seen in the resolution-enhanced FTIR spectra. Comparison to previous studies of (Aib)(n) and (Pro)(n) oligomers indicate that the low frequency of the amide I mode is due to the interaction of secondary and tertiary amide bonds and not to a strong difference in conformation from a regular 3(10)-helix. (C) 1995 John Wiley and Sons, Inc.
Characterization of Beta-bend Ribbon Spiral Forming Peptides Using Electronic and Vibrational Cd
FORMAGGIO, FERNANDO;TONIOLO, CLAUDIO
1995
Abstract
Terminally blocked (L-Pro-Aib)(n) and Aib-(L-Pro-Aib)(n) sequential oligopeptides are known to form right-handed beta-bend ribbon spirals under a variety of experimental conditions. Here we describe the results of a complete CD and ir characterization of this subtype of 3(10)-helical structure. The electronic CD spectra were obtained in solvents of different polarity in the 260-180 nm region. The vibrational CD and Fourier transform ir (FTIR) spectra were measured in deuterochloroform solution in the amide I and amide II (1750-1500 cm(-1)) regions. The critical chain length for full development of the beta-bend ribbon spiral structure is found to be five to six residues. Spectral effects related to concentration-induced stabilization of the structures of the longer peptides were seen in the resolution-enhanced FTIR spectra. Comparison to previous studies of (Aib)(n) and (Pro)(n) oligomers indicate that the low frequency of the amide I mode is due to the interaction of secondary and tertiary amide bonds and not to a strong difference in conformation from a regular 3(10)-helix. (C) 1995 John Wiley and Sons, Inc.Pubblicazioni consigliate
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