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Grudinin, S. [Author]; Büldt, G. [Author]; Gordeliy, I. L. [Author]; Baumgaertner, A. [Author]

Water Molecules and Hydrogen-Bonded Networks in Bacteriorhodopsin-Molecular Dynamics Simulations of the Ground State and the M-Intermediate

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  • Media type: E-Article
  • Title: Water Molecules and Hydrogen-Bonded Networks in Bacteriorhodopsin-Molecular Dynamics Simulations of the Ground State and the M-Intermediate
  • Contributor: Grudinin, S. [Author]; Büldt, G. [Author]; Gordeliy, I. L. [Author]; Baumgaertner, A. [Author]
  • Published: Rockefeller Univ. Press, 2005
  • Published in: Biophysical journal 88, 3252 - 3261 (2005). doi:10.1529/biophysj.104.047993
  • Language: English
  • DOI: https://doi.org/10.1529/biophysj.104.047993
  • ISSN: 0006-3495
  • Keywords: Dimerization ; Biophysics: methods ; Time Factors ; Statistical ; Hydrogen Bonding ; 1-palmitoyl-2-oleoylphosphatidylcholine ; Protein Structure ; Halobacterium: metabolism ; Bacteriorhodopsins: chemistry ; Software ; Water ; Models ; Computer Simulation ; X-Ray ; Bacteriorhodopsins ; Tertiary ; Biological Transport ; Water: chemistry ; Phosphatidylcholines ; Diffusion ; Crystallography ; Molecular ; Protons ; [...]
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  • Description: Protein crystallography provides the structure of a protein, averaged over all elementary cells during data collection time. Thus, it has only a limited access to diffusive processes. This article demonstrates how molecular dynamics simulations can elucidate structure-function relationships in bacteriorhodopsin (bR) involving water molecules. The spatial distribution of water molecules and their corresponding hydrogen-bonded networks inside bR in its ground state (G) and late M intermediate conformations were investigated by molecular dynamics simulations. The simulations reveal a much higher average number of internal water molecules per monomer (28 in the G and 36 in the M) than observed in crystal structures (18 and 22, respectively). We found nine water molecules trapped and 19 diffusive inside the G-monomer, and 13 trapped and 23 diffusive inside the M-monomer. The exchange of a set of diffusive internal water molecules follows an exponential decay with a 1/e time in the order of 340 ps for the G state and 460 ps for the M state. The average residence time of a diffusive water molecule inside the protein is approximately 95 ps for the G state and 110 ps for the M state. We have used the Grotthuss model to describe the possible proton transport through the hydrogen-bonded networks inside the protein, which is built up in the picosecond-to-nanosecond time domains. Comparing the water distribution and hydrogen-bonded networks of the two different states, we suggest possible pathways for proton hopping and water movement inside bR.
  • Access State: Open Access