Proton and carbon magnetic resonance studies of the synthetic polypentapeptide of elastin.

Proton and ¹³C magnetic resonance studies are reported on the synthetic polypentapeptide of elastin, HCO-(Val₍₁₎-Pro₍₂₎-Gly₍₃₎-Val₍₄₎-Gly₍₅₎)_n-Val-OMe, where n ∼- 18. Temperature and solvent dependence of peptide N$\text{H}$ chemical shift and solvent dependence of peptide carbonyl chemical shift were used to delineate these moieties preliminary to identification of secondary structure.Based on these studies it is proposed, for the organic solvents of dimethyl sulfoxide, methanol, and low-temperature trifluoroethanol, that dynamic hydrogen bonds form in order of decreasing frequency of occurrence between the Val₍₁₎$\text{C}$O and the Val₍₄₎ N$\text{H}$ (a β-turn), between the Gly₍₃₎ N$\text{H}$ and the Gly₍₅₎$\text{C}$O (an 11-atom, hydrogen-bonded ring), and a more limited interaction between the Gly₍₃₎$\text{C}$O and the Gly₍₅₎ N$\text{H}$ (a γ-turn).Arguments are presented that relate the conformational features proposed above to the coacervate, which is a filamentous state.