Isotopically Site-Selected Dynamics of a Three-Stranded -Sheet Peptide Detected with Temperature-Jump IR-Spectroscopy

Infrared detected temperature jump (T-jump) spectroscopy and site-specific isotopic labeling were applied to study a model three-stranded beta-sheet peptide with the goal of individually probing the dynamics of strand and turn structural elements. This peptide had two DPro-Gly (pG) turn sequences to stabilize the two component hairpins, which were labeled with 13C=O on each of the Gly residues to resolve them spectroscopically. Labeling the second turn on the amide preceding the DPro (XxxDPro amide) provided an alternate turn label as a control. Placing 13C=O labels on specific in-strand residues gave shifted modes that overlap the XxxDPro amide I’ modes. Their impact could be separated from the turn dynamics by a novel difference-transient analysis approach. FTIR spectra were modeled with DFTcomputations which showed the local, isotope-selected vibrations were effectively uncoupled from the other amide I modes. Our T-jump dynamics results, combined with NMR structures and equilibrium spectral measurements, showed the first turn to be most stable and best formed with the slowest dynamics, while the second turn and first strand (N-terminus) had similar dynamics, and the third strand (C-terminus) had the fastest dynamics and was the least structured. The relative dynamics of the strands, XxxDPro amides and 13C-labeled Gly residues on the turns also qualitatively corresponded to molecular dynamics (MD) simulations of turn and strand fluctuations. MD trajectories indicated the turns to be bistable, with the first turn being Type I’ and the second turn flipping from I’ to II’. The differences in relaxation times for each turn and the separate strands revealed that the folding process of this turnstabilized beta-sheet structure proceeds in a multi-step process.