Polymorphism of Collagen Triple Helix Revealed by super(19)F NMR of Model Peptide [Pro-4(R)-Hydroxyprolyl-Gly] sub(3)-[Pro-4(R)-Fluo roprolyl-Gly]-[Pro-4(R)-Hydroxyprolyl-Gly] sub(3)

Polymorphism of Collagen Triple Helix Revealed by super(19)F NMR of Model Peptide [Pro-4(R)-Hydroxyprolyl-Gly] sub(3)-[Pro-4(R)-Fluo roprolyl-Gly]-[Pro-4(R)-Hydroxyprolyl-Gly] sub(3)

We have characterized various structures of (Pro-Hyp super(R)-Gly) sub(3)-P ro-fPro super(R)-Gly-(Pro-Hyp super(R)-Gly) sub(3) in the process of cis-trans isomerization and helix-coil transition by exploiting the sole super(19)F NMR probe in 4(R)-fluoroproline (fPro super(R)). Around the transition...

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Published in:The journal of physical chemistry. B Vol. 116; no. 23; pp. 6908 - 6915-6908-6915
Main Authors: Kawahara, Kazuki, Nemoto, Nobuaki, Motooka, Daisuke, Nishi, Yoshinori, Doi, Masamitsu, Uchiyama, Susumu, Nakazawa, Takashi, Nishiuchi, Yuji, Yoshida, Takuya, Ohkubo, Tadayasu, Kobayashi, Yuji
Format: Journal Article
Language:English
Published: 04-06-2012
Subjects:
Collagens
Helices
Mathematical models
Monomers
Nuclear magnetic resonance
Peptides
Sole
Strands
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Summary:We have characterized various structures of (Pro-Hyp super(R)-Gly) sub(3)-P ro-fPro super(R)-Gly-(Pro-Hyp super(R)-Gly) sub(3) in the process of cis-trans isomerization and helix-coil transition by exploiting the sole super(19)F NMR probe in 4(R)-fluoroproline (fPro super(R)). Around the transition temperature (T sub(m)), we detected a species with a triple helical structure distinct from the ordinary one concerning the alignment of three strands. The super(19)F- super(19) F exchange spectroscopy showed that this misaligned and that the ordinary triple helices were interchangeable only indirectly via an extended monomer strand with all-trans peptide bonds at Pro-fPro super(R), Pro-Hyp super(R), and Gly-Pro in the central segment. This finding demonstrates that the helix-coil transition of collagen peptides is not described with a simple two-state model. We thus elaborated a scheme for the transition mechanism of (Pro-Hyp super(R)-Gly) sub(n) that the most extended monomer strand can be the sole source both to the misaligned and correctly folded triple-helices. The staggered ends could help misaligned triple helices to self-assemble to higher-order structures. We have also discussed the possible relationship between the misaligned triple helix accumulating maximally at T sub(m) and the kinetic hysteresis associated with the helix-coil transition of collagen.
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ISSN:1520-6106
1520-5207
DOI:10.1021/jp212631q