Dehydration of main-chain amides in the final folding step of single-chain monellin revealed by time-resolved infrared spectroscopy.

Kinetic IR spectroscopy was used to reveal beta-sheet formation and water expulsion in the folding of single-chain monellin (SMN) composed of a five-stranded beta-sheet and an alpha-helix. The time-resolved IR spectra between 100 mus and 10 s were analyzed based on two consecutive intermediates, I(1) and I(2), appearing within 100 mus and with a time constant of approximately 100 ms, respectively. The initial unfolded state showed broad amide I' corresponded to a fluctuating conformation. In contrast, I(1) possessed a feature at 1,636 cm(-1) for solvated helix and weak features assignable to turns, demonstrating the rapid formation of helix and turns. I(2) possessed a line for solvated helix at 1,637 cm(-1) and major and minor lines for beta-sheet at 1,625 and 1,680 cm(-1), respectively. The splitting of the major and minor lines is smaller than that of the native state, implying an incomplete formation of the beta-sheet. Furthermore, both major and minor lines demonstrated a low-frequency shift compared to those of the native state, which was interpreted to be caused by hydration of the C O group in the beta-sheet. Together with the identification of solvated helix, the core domain of I(2) was interpreted as being hydrated. Finally, slow conversion of the water-penetrated core of I(2) to the dehydrated core of the native state was observed. We propose that both the expulsion of water, hydrogen-bonded to main-chain amides, and the completion of the secondary structure formation contribute to the energetic barrier of the rate-limiting step in SMN folding.