Structural organization of a chain molecule with specific charge distribution: A molecular dynamics study

We report the results of molecular dynamics simulations of a charged bead-monomer chain molecule with charge distribution adopted from immunoglobulin-binding domain B1 of protein-g. The beads of the model are connected by invariable bonds and interact with each other via the Coulomb potential. To study the low-temperature conformational space of the designed model we use standard canonical, microcanonical and multicanonical molecular dynamics simulations. We find that at low temperature T = T c the chain undergoes a continuous freezing transition into one of many low-energy conformations. Below T c the molecule is a compact globule composed of an inner core, containing mostly charged monomers, and an outer corona, consisting of all the rest neutral units. All frozen conformations have almost equal potential energy but differ in structure. The potential energy surface of the model does not posses a pronounced ground-state minimum--an essential feature of protein-like heteropolymers.