A Monte Carlo study of peptide insertion into lipid bilayers: equilibrium conformations and insertion mechanisms.

The membrane insertion behavior of two peptides, Magainin2 and M2 delta, was investigated by applying the Monte Carlo simulation technique to a theoretical model. The model included many novel aspects, such as a new semi-empirical lipid bilayer model and a new set of semi-empirical transfer energies, which reproduced the experimental insertion behavior of Magainin2 and M2 delta without parameter fitting. Additionally, we have taken into account diminished internal (intramolecular) hydrogen bonding at the N- and C-termini of helical peptides. All simulations were carried out at 305 K, above the membrane thermal phase transition temperature, and at pH 7.0. The peptide equilibrium conformations are discussed for a range of bilayers with tail polarities varying from octanol-like to alkane-like. Probability distributions of the individual amino-acid-residue positions show the dynamic nature of these equilibrium conformations. Two different insertion mechanisms for M2 delta, and a translocation mechanism for Magainin2, are described. A study of the effect of bilayer thickness on M2 delta insertion suggests a critical thickness above which insertion is unfavorable. Additionally, we did not need to use an orientational potential or array of hard cylinders to persuade M2 delta to insert perpendicular to the membrane surface. Instead, we found that diminished internal hydrogen bonding in the helical conformation anchored the termini in the headgroups and resulted in a nearly perpendicular orientation.