Roles of Local Non-equilibrium Free Energy in the Description of Biomolecules

Abstract

When a system is in equilibrium, external perturbations yield a time series of non-equilibrium distributions, and recent experimental techniques give access to the non-equilibrium data that may contain critical information. Jinwoo and Tanaka (L. Jinwoo and H. Tanaka, Sci. Rep. 2015, 5, 7832) have provided mathematical proof that such a process's non-equilibrium free energy profile over a system's substates has Jarzynski's work as content, which spontaneously dissipates while molecules perform their tasks. Here we numerically verify this fact and give a practical example where we analyze a computer simulation of RNA translocation by a ring-shaped ATPase motor. By interpreting the cyclic process of substrate translocation as a series of quenching, relaxation, and second quenching, the theory gives how much individual sub-states of the ATPase motor have been energized until the end of the process. It turns out that the efficiency of RNA translocation is 48 60\% for most molecules, but 12\% of molecules achieve 80 100\% efficiency, which is consistent with the literature. This theory would be a valuable tool for extracting quantitative information about molecular non-equilibrium behavior from experimental observations.

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