Site-specific NMR monitoring of cis-trans isomerization in the folding of the proline-rich collagen triple helix

Understanding the folding of the proline-rich collagen triple helix requires consideration of the effects of proline cis-trans isomerization and may shed light on the misfolding of collagen in connective tissue diseases, Folding was monitored in real time by heteronuclear 2D NMR spectroscopy for the N-15 labeled positions in the triple-helical peptide T1-892 [GPAGPAGPVGPAGARGPAGPOGPOGPOG POGV]. In the equilibrium unfolded monomer form, each labeled residue showed multiple peaks with interconversion rates consistent with cis-trans isomerization of Gly-Pro and Pro-Hyp bonds. Realtime NMR studies on the folding of T1-892 showed slow decay of monomer peaks and a concomitant increase in trimer peaks. Gly25 in the C-terminal rich (Gly-Pro-Hyp)(4) domain folds first, consistent with its being a nucleation domain. Analysis of the kinetics indicates that the folding of Gly25 is biphasic and the slower step represents cis-trans isomerization of imino acids. This illustrates that nucleation is limited by cis-trans isomerization. Monitoring Gly6, Gly10, Ala12, and Gly13 monomer and trimer peaks captures the C- to N-terminal propagation of the triple helix, which is also limited by Gly-Pro cis-trans isomerization events. The zipper-like nature of the propagation process is confirmed by the slower rate of folding of Ala6 compared to Gly13, reflecting the larger number of isomerization events encountered by the more N-terminal Ala6. The cis-trans isomerization events at multiple proline residues is a complex statistical process which can be visualized by these NMR studies.