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A Modified Nonlocal Continuum Electrostatic Model for Protein in Water and Its Analytical Solutions for Ionic Born Models

Published online by Cambridge University Press:  03 June 2015

Dexuan Xie  and
Hans W. Volkmer
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Abstract

A nonlocal continuum electrostatic model, defined as integro-differential equations, can significantly improve the classic Poisson dielectric model, but is too costly to be applied to large protein simulations. To sharply reduce the model’s complexity, a modified nonlocal continuum electrostatic model is presented in this paper for a protein immersed in water solvent, and then transformed equivalently as a system of partial differential equations. By using this new differential equation system, analytical solutions are derived for three different nonlocal ionic Born models, where a monoatomic ion is treated as a dielectric continuum ball with point charge either in the center or uniformly distributed on the surface of the ball. These solutions are analytically verified to satisfy the original integro-differential equations, thereby, validating the new differential equation system.

Keywords

92-0865N30Nonlocal continuum electrostatic modelsPoisson dielectric equationsprotein-water interface problemnonlocal ionic Born models
Type
Research Article
Information
Communications in Computational Physics , Volume 13 , Issue 1 , January 2013 , pp. 174 - 194
Copyright
Copyright © Global Science Press Limited 2013

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References

[1]Baker, N.A.Improving implicit solvent simulations: a Poisson-centric view. Curr. Opin. Struct. Biol., 15: 137143, 2005.Google Scholar
[2]Basilevsky, M.V. and Parsons, D.F.An advanced continuum medium model for treating solvation effects: Nonlocal electrostatics with a cavity. Journal of Chemical Physics, 105(9): 37343746, 1996.Google Scholar
[3]Basilevsky, M.V. and Parsons, D.F.Nonlocal continuum solvation model with exponential susceptibility kernels. Journal of Chemical Physics, 108: 91079113, 1998.Google Scholar
[4]Basilevsky, M.V. and Parsons, D.F.Nonlocal continuum solvation model with oscillating susceptibility kernels: A nonrigid cavity model. Journal of Chemical Physics, 108: 91149123, 1998.Google Scholar
[5]Basilevsky, V. and Chuev, G.N.Nonlocal solvation theories. In Benedetta Mennucci and Roberto Cammi, editors, Continuum Solvation Models in Chemical Physics: From Theory to Applications. Wiley, 2008.Google Scholar
[6]Bopp, P.A., Kornyshev, A.A., and Sutmann, G.Static nonlocal dielectric function of liquid water. Phys. Rev. Lett., 76: 12801283, 1996.Google Scholar
[7]Le Bris, C., editor. Special Volume: Computational Chemistry, volume X of Handbook of Numerical Analysis. Elsvier, North-Holland, 2003.Google Scholar
[8]Dogonadze, R.R., Kálmán, E., Kornyshev, A.A., and Ulstrup, J.The Chemical Physics of Solvation, Part A: Theory of Solvation. Elsevier Science Ltd, 1985.Google Scholar
[9]Fasel, C., Rjasanow, S., and Steinbach, O.A boundary integral formulation for nonlocal elec-trostatics. In Kunisch, Karl, Of, Günther, and Steinbach, Olaf, editors, Numerical Mathematics and Advanced Applications: Proceedings of ENUMATH 2007, Graz, Austria, September 2007, pages 117124, Berlin Heidelberg, 2008. Springer-Verlag.Google Scholar
[10]Feig, M. and Brooks, C.L. IIIRecent advances in the development and application of implicit solvent models in biomolecule simulations. Curr. Opin. Struct. Biol., 14: 217224, 2004.Google Scholar
[11]Gaspari, G. and Cohn, S.E.Construction of correlation functions in two and three dimensions. Quarterly Journal of the Royal Meteorological Society, 125(554): 723757, 1999.Google Scholar
[12]Griffiths, D.J.Introduction to electrodynamics. Prentice Hall, New Jersey, 3 edition, 1999.Google Scholar
[13]Hildebrandt, A., Blossey, R., Rjasanow, S., Kohlbacher, O., and Lenhof, H.-P.Novel formulation of nonlocal electrostatics. Phys. Rev. Lett., 93(10): 108104, 2004.Google Scholar
[14]Hildebrandt, A., Blossey, R., Rjasanow, S., Kohlbacher, O., and Lenhof, H.P.Electrostatic potentials of proteins in water: A structured continuum approach. Bioinformatics, 23(2): e99, 2007.Google Scholar
[15]Hildebrandt, A.Biomolecules in a structured solvent: A novel formulation of nonlocal electrostatics and its numerical solution. PhD thesis, Saarlandes University, Saarbriicken, Germany, February 2005.Google Scholar
[16]Jackson, J.D.Classical electrodynamics. Wiley, New York, 3rd edition, 1999.Google Scholar
[17]Koehl, P.Electrostatics calculations: Latest methodological advances. Current Opinion in Structural Biology, 16(2): 142151, 2006.Google Scholar
[18]Kornyshev, A.A. and Vorotyntsev, M.A.Model non-local electrostatics. III. cylindrical interface. Journal of physics. C. Solid state physics, 12(22): 49394946, 1979.Google Scholar
[19]Kornyshev, A.A. and Sutmann, G.Nonlocal dielectric saturation in liquid water. Phys. Rev. Lett., 79: 34353438, 1997.Google Scholar
[20]Kornyshev, A.A. and Sutmann, G.Nonlocal dielectric function of water: How strong are the effects of intramolecular charge form factors? J. Mol. Liq., 82: 151160, 1999.Google Scholar
[21]Landau, L.D. and Lifshits, E.M.The electrodynamics of continuous media. Moscow Izdatel Nauka Teoreticheskaia Fizika, 8,1982.Google Scholar
[22]Neves-Petersen, M.T. and Petersen, S.B.Protein electrostatics: A review of the equations and methods used to model electrostatic equations in biomolecules-Applications in biotechnology. Biotechnology Annual Review, 9: 315395, 2003.Google Scholar
[23]Paillusson, F. and Blossey, R.Slits, plates, and Poisson-Boltzmann theory in a local formulation of nonlocal electrostatics. Physical Review E, 82(5): 052501,2010.Google Scholar
[24]Roux, B. and Simonson, T.Implicit solvent models. Biophys. Chem., 78: 120, 1999.Google Scholar
[25]Rudin, W.Functional Analysis. International Series in Pure and Applied Mathematics. McGraw-Hill, New York, 2nd edition, 1991.Google Scholar
[26]Scott, L.R., Boland, M., Rogale, K., and Fernandez, A.Continuum equations for dielectric response to macro-molecular assemblies at the nano scale. Journal of Physics A: Math. Gen., 37: 97919803, 2004.Google Scholar
[27]Simonson, T.Electrostatics and dynamics of proteins. Reports on Progress in Physics, 66: 737, 2003.Google Scholar
[28]Tomasi, J., Menucci, B., and Cammi, R.Quantum mechanical continuum solvation models. Chem. Rev., 105: 29993093, 2005.Google Scholar
[29]Vorotyntsev, M.A.Model nonlocal electrostatics. II. Spherical interface. Journal of Physics C: Solid State Physics, 11: 3323, 1978.Google Scholar
[30]Weggler, S., Rutka, V., and Hildebrandt, A.A new numerical method for nonlocal electrostatics in biomolecular simulations. Journal of Computational Physics, 229(11): 40594074, 2010.Google Scholar
[31]Wilson, G.J., Chan, R.K., Davidson, D.W., and Whalley, E.Dielectric properties of ices II, III, V, and VI. Journal of Chemical Physics, 43: 2384, 1965.CrossRefGoogle Scholar
[32]Xie, D., Jiang, Y., Brune, P., and Scott, L.R.A fast solver for a nonlocal dielectric continuum model. SIAM J. Sci. Comput., 34(2): B107B126, 2012.Google Scholar