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W2073569277 abstract "The large interest in long-range proton transfer in biomolecules is triggered by its importance for many biochemical processes such as biological energy transduction and drug detoxification. Since long-range proton transfer occurs on a microsecond time scale, simulating this process on a molecular level is still a challenging task and not possible with standard simulation methods. In general, the dynamics of a reactive system can be described by a master equation. A natural way to describe long-range charge transfer in biomolecules is to decompose the process into elementary steps which are transitions between microstates. Each microstate has a defined protonation pattern. Although such a master equation can in principle be solved analytically, it is often too demanding to solve this equation because of the large number of microstates. In this paper, we describe a new method which solves the master equation by a sequential dynamical Monte Carlo algorithm. Starting from one microstate, the evolution of the system is simulated as a stochastic process. The energetic parameters required for these simulations are determined by continuum electrostatic calculations. We apply this method to simulate the proton transfer through gramicidin A, a transmembrane proton channel, in dependence on the applied membrane potential and the pH value of the solution. As elementary steps in our reaction, we consider proton uptake and release, proton transfer along a hydrogen bond, and rotations of water molecules that constitute a proton wire through the channel. A simulation of 8 μs length took about 5 min on an Intel Pentium 4 CPU with 3.2 GHz. We obtained good agreement with experimental data for the proton flux through gramicidin A over a wide range of pH values and membrane potentials. We find that proton desolvation as well as water rotations are equally important for the proton transfer through gramicidin A at physiological membrane potentials. Our method allows to simulate long-range charge transfer in biological systems at time scales, which are not accessible by other methods." @default.
W2073569277 created "2016-06-24" @default.
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W2073569277 date "2008-09-30" @default.
W2073569277 modified "2023-09-23" @default.
W2073569277 title "Simulating the Proton Transfer in Gramicidin A by a Sequential Dynamical Monte Carlo Method" @default.
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W2073569277 cites W1976394766 @default.
W2073569277 cites W1978101105 @default.
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W2073569277 cites W1990208157 @default.
W2073569277 cites W1991838495 @default.
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W2073569277 cites W2018308730 @default.
W2073569277 cites W2024982125 @default.
W2073569277 cites W2027408247 @default.
W2073569277 cites W2030460067 @default.
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W2073569277 cites W2036478269 @default.
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W2073569277 cites W2096973779 @default.
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W2073569277 cites W2137971290 @default.
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W2073569277 cites W2159139672 @default.
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W2073569277 doi "https://doi.org/10.1021/jp801477b" @default.
W2073569277 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/18826179" @default.
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