Folding Thermodynamics of Model Four-Strand Antiparallel β-Sheet Proteins

Abstract

The thermodynamic properties for three different types of off-lattice four-strand antiparallel β-strand protein models interacting via a hybrid Go-type potential have been investigated. Discontinuous molecular dynamic simulations have been performed for different sizes of the bias gap g, an artificial measure of a model protein’s preference for its native state. The thermodynamic transition temperatures are obtained by calculating the squared radius of gyration R g 2, the root-mean-squared pair separation fluctuation Δ B, the specific heat C v, the internal energy of the system E, and the Lindemann disorder parameter Δ L. Despite these models’ simplicity, they exhibit a complex set of protein transitions, consistent with those observed in experimental studies on real proteins. Starting from high temperature, these transitions include a collapse transition, a disordered-to-ordered globule transition, a folding transition, and a liquid-to-solid transition. The high temperature transitions, i.e., the collapse transition and the disordered-to-ordered globule transition, exist for all three β-strand proteins, although the native-state geometry of the three model proteins is different. However the low temperature transitions, i.e., the folding transition and the liquid-to-solid transition, strongly depend on the native-state geometry of the model proteins and the size of the bias gap.