Molecular dynamics simulations of polypeptide conformations in water: A comparison of ?, ?, and poly(pro)II conformations

Abstract

A significant fraction of the so-called "random coil" residues in globular proteins exists in the left-handed poly(Pro)II conformation. In order to compare the behavior of this secondary structure with that of the other regular secondary structures, molecular dynamics simulations, with the GROMOS suite of programs, of an alanine octapeptide in water, in alpha-helix, beta-strand, and left-handed poly(Pro)II conformations, have been performed. Our results indicate a limited flexibility for the alpha-helix conformation and a relatively larger flexibility for the beta-strand and poly(Pro)II conformations. The behavior of oligopeptides with a starting configuration of beta-strand and poly(Pro)II conformations, both lacking interchain hydrogen bonds, were similar. The (phi, psi) angles reflect a continuum of structures including both beta and P(II) conformations, but with a preference for local P(II) regions. Differences in the network of water molecules involved in hydrogen bonding with the backbone of the polypeptide were observed in local regions of beta and P(II) conformations. Such water bridges help stabilize the P(II) conformation relative to the beta conformation. Proteins 1999;36:400-406.