AbstractThe effect of N‐terminal diproline segment and charged side chains on the stabilization of helical conformation in alanine‐based short peptides are examined using molecular dynamics (MD) simulations. The cationic peptides, Ac–Pro1–Pro2–Ala3–Lys4–Ala5–Lys6–Ala7–Lys8–Ala9–NH2 (Ia) and Ac–DPro1–Pro2–Ala3–Lys4–Ala5–Lys6–Ala7–Lys8–Ala9–NH2 (IIa) are examined for the role of lysine side chains on the inducement of helical conformation in alanine‐based short peptides. To examine the influence of lysine and glutamic acid in the i, i + 4 arrangement on the stabilization of helical conformation, cationic peptides, Ia and IIa, are modified as ion‐pair peptides, Ac–Pro1–Pro2–Glu3–Glu4–Ala5–Ala6–Lys7–Lys8–Ala9–NH2 (Ib) and Ac–DPro1–Pro2–Glu3–Glu4–Ala5–Ala6–Lys7–Lys8–Ala9–NH2 (IIb), respectively. MD simulations manifest enhanced occupancies in the α basin of ϕ, ψ space for ion‐pair peptides as compare to cationic peptides. The radial distribution function (RDF) analysis highlight that large side chain substituents of lysine and glutamic acid assist in helix formation by blocking water molecules from solvating backbone CO and NH groups.
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