A new method to develop low-energy folding routes for proteins is presented. The novel aspect of the proposed approach is the synergistic use of optimal control theory with Molecular Dynamics (MD). In the first step of the method, optimal control theory is employed to compute the force field and the optimal folding trajectory for the C-alpha atoms of a Coarse-Grained (CG) protein model. The solution of this CG optimization provides an harmonic approximation of the true potential energy surface around the native state. In the next step CG optimization guides the MD simulation by specifying the optimal target positions for the C-alpha atoms. In turn, MD simulation provides an all-atom conformation whose C-alpha positions match closely the ref...
Herein, we present a novel Hamiltonian replica exchange protocol for classical molecular dynamics s...
ABSTRACT: One strategy for reaching the downhill folding regime, primarily exploited for the λ6−85 p...
Computer simulations of biological systems provide novel data while both supporting and challenging ...
A new method to develop low-energy folding routes for proteins is presented. The novel aspect of the...
A new method to develop low-energy folding routes for proteins is presented. The novel aspect of the...
An optimization model is introduced in which proteins try to evade high energy regions of the foldin...
We develop a dynamic optimization technique for determining optimum folding pathways of proteins sta...
Under appropriate physiological conditions, proteins fold into their biologically active native conf...
The investigation of protein folding and its ramifications in biological contexts is at the heart of...
Proteins in solution fold in time scales ranging from microseconds to seconds. A computational appro...
The investigation of protein folding and its ramifications in biological contexts is at the heart o...
AbstractA new method for simulating the folding process of a protein is reported. The method is base...
The mechanism through which a given sequence of amino acids finds its way to a global free energy mi...
Herein, we present a novel Hamiltonian replica exchange protocol for classical molecular dynamics si...
Computer simulation of conformational transitions in biomolecules, such as protein folding, is cons...
Herein, we present a novel Hamiltonian replica exchange protocol for classical molecular dynamics s...
ABSTRACT: One strategy for reaching the downhill folding regime, primarily exploited for the λ6−85 p...
Computer simulations of biological systems provide novel data while both supporting and challenging ...
A new method to develop low-energy folding routes for proteins is presented. The novel aspect of the...
A new method to develop low-energy folding routes for proteins is presented. The novel aspect of the...
An optimization model is introduced in which proteins try to evade high energy regions of the foldin...
We develop a dynamic optimization technique for determining optimum folding pathways of proteins sta...
Under appropriate physiological conditions, proteins fold into their biologically active native conf...
The investigation of protein folding and its ramifications in biological contexts is at the heart of...
Proteins in solution fold in time scales ranging from microseconds to seconds. A computational appro...
The investigation of protein folding and its ramifications in biological contexts is at the heart o...
AbstractA new method for simulating the folding process of a protein is reported. The method is base...
The mechanism through which a given sequence of amino acids finds its way to a global free energy mi...
Herein, we present a novel Hamiltonian replica exchange protocol for classical molecular dynamics si...
Computer simulation of conformational transitions in biomolecules, such as protein folding, is cons...
Herein, we present a novel Hamiltonian replica exchange protocol for classical molecular dynamics s...
ABSTRACT: One strategy for reaching the downhill folding regime, primarily exploited for the λ6−85 p...
Computer simulations of biological systems provide novel data while both supporting and challenging ...