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Abstract
One of the applications of Molecular Dynamics (MD) simulations is to explore the energetic barriers to mechanical unfolding of proteins such as occurs in response to the mechanical pulling of single molecules in Atomic Force Microscopy (AFM) experiments. Although Steered Molecular Dynamics simulations have provided microscopic details of the unfolding process during the pulling, the simulated forces required for unfolding are typically far in excess of the measured values. To rectify this, we have developed the Pulsed Unconstrained Fluctuating Forces (PUFF) method, which induces constant-momentum motions by applying forces directly to the instantaneous velocity of selected atoms in a protein system. The driving forces are applied in pulses, which allows the system to relax between pulses, resulting in more accurate unfolding force estimations than in previous methods. In the cases of titin, ubiquitin and e2lip3, the PUFF trajectories produce force fluctuations that agree quantitatively with AFM experiments. Another useful property of PUFF is that simulations get trapped if the target momentum is too low, simplifying the discovery and analysis of unfolding intermediates.
Highlights
Many crucial biological processes occur through large conformational changes in proteins, such as the unfolding of titin in the muscle sarcomere
In order to overcome the problem of generating forces with harmonic restraints, we have developed a force-inducing protocol that is conceptually different than Steered Molecular Dynamics (MD)
Using the Pulsed Unconstrained Fluctuating Forces (PUFF) protocol on the I27 domain of titin, we show that it is possible to generate unfolding trajectories with unfolding forces that compare well with the Atomic Force Microscopy (AFM) measurements and that are much lower than those deduced from standard simulations
Summary
Many crucial biological processes occur through large conformational changes in proteins, such as the unfolding of titin in the muscle sarcomere. RMSD potentials can be used to generate low energy pathways away from the starting state by using increasing RMSD as a driving force [6,7,8]. In processes such as the unfolding of titin by mechanical stress, where there is an obvious force to be applied to the starting conformation, Steered MD can generate new trajectories by setting pre-defined moving harmonic distance restraints to force the system away from the starting configuration along a defined vector [9]. Steered MD has been used to explore systems such as the rotation of the gammasubunit of ATPase [10,11], and the unfolding of fibronectin [12]
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