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Applied Mathematics and Mechanics >

2015 , Vol. 36 >Issue 12: 1581 - 1592

DOI: https://doi.org/10.1007/s10483-015-2062-6

Articles

Polymer translocation through nanopore under external electric field:dissipative particle dynamics study

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  • 1. Shanghai Institute of Applied Mathematics and Mechanics, Shanghai 200072, China;
    2. College of Sciences, Shanghai University, Shanghai 200444, China;
    3. Shanghai Key Laboratory of Mechanics in Energy Engineering, Shanghai 200072, China

Received date: 2015-07-29

  Revised date: 2015-10-01

  Online published: 2015-12-01

Supported by

Project supported by the National Natural Science Foundation of China(Nos. 11272197 and 11372175) and the Innovation Program of Shanghai Municipality Education Commission, China(No. 14ZZ095)

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Abstract

The DNA sequencing technology has achieved a leapfrog development in recent years. As a new generation of the DNA sequencing technology, nanopore sequencing has shown a broad application prospect and attracted vast research interests since it was proposed. In the present study, the dynamics of the electric-driven translocation of a homopolymer through a nanopore is investigated by the dissipative particle dynamics(DPD), in which the homopolymer is modeled as a worm-like chain(WLC). The DPD simulations show that the polymer chain undergoes conformation changes during the translocation process. The different structures of the polymer in the translocation process, i.e., single-file, double folded, and partially folded, and the induced current blockades are analyzed. It is found that the current blockades have different magnitudes due to the polymer molecules traversing the pore with different folding conformations. The nanoscale vortices caused by the concentration polarization layers(CPLs) in the vicinity of the sheet are also studied. The results indicate that the translocation of the polymer has the effect of eliminating the vortices in the polyelectrolyte solution. These findings are expected to provide the theoretical guide for improving the nanopore sequencing technique.

Key words: dissipative particle dynamics(DPD); nanopore sequencing technology; electric-driven translocation

Cite this article

Jinglin MAO, Yi YAO, Zhewei ZHOU, Guohui HU . Polymer translocation through nanopore under external electric field:dissipative particle dynamics study[J]. Applied Mathematics and Mechanics, 2015 , 36(12) : 1581 -1592 . DOI: 10.1007/s10483-015-2062-6

References

[1] Muthukumar, M. Mechanism of DNA transport through pores. Annual Review of Biophysics and Biomolecular Structure, 36, 435-450(2007)
[2] Rhee, M. and Burns, M. A. Nanopore sequencing technology:research trends and applications. Trends in Biotechnology, 24, 580-586(2006)
[3] Branton, D., Deamer, D. W., Marziali, A., Bayley, H., Benner, S. A., Butler, T., Di Ventra, M., Garaj, S., Hibbs, A., Huang, X. H., Jovanovich, S. B., Krstic, P. S., Lindsay, S., Ling, X. S. S., Mastrangelo, C. H., Meller, A., Oliver, J. S., Pershin, Y. V., Ramsey, J. M., Riehn, R., Soni, G. V., Tabard-Cossa, V., Wanunu, M., Wiggin, M., and Schloss, J. A. The potential and challenges of nanopore sequencing. Nature Biotechnology, 26, 1146-1153(2008)
[4] Venkatesan, B. M. and Bashir, R. Nanopore sensors for nucleic acid analysis. Nature Nanotechnology, 6, 615-624(2011)
[5] Bayley, H. and Cremer, P. S. Stochastic sensors inspired by biology. nature, 413, 226-230(2001)
[6] Butler, T. Z., Gundlach, J. H., and Trolly, M. A. Ionic current blockades from DNA and RNA molecules in the α-hemolysin nanopore. Biophysical Journal, 93, 3229-3240(2007)
[7] Mathé, J., Aksimentiev, A., Nelson, D. R., Schulten, K., and Meller, A. Orientation discrimination of single-stranded DNA inside the α-hemolysin membrane channel. Proceedings of the National Academy of Sciences of the United States of America, 102, 12377-12382(2005)
[8] Kasianowicz, J. J., Brandin, E., and Branton, D. Characterization of individual polynucleotide molecules using a membrane channel. Proceedings of the National Academy of Sciences of the United States of America, 93, 13770-13773(1996)
[9] Meller, A., Nivon, L., and Branton, D. Voltage-driven DNA translocations through a nanopore. Physical Review Letters, 86, 3435-3438(2001)
[10] Heng, J. B., Aksimentiev, A., Ho, C., Marks, P., Grinkova, Y. V., Sligar, S., Schulten, K., and Timp, G. Stretching DNA using the electric field in a synthetic nanopore. Nano Letters, 5, 1883-1888(2005)
[11] Heng, J. B., Aksimentiev, A., Ho, C., Marks, P., Grinkova, Y. V., Sligar, S., Schulten, K., and Timp, G. The electromechanics of DNA in a synthetic nanopore. Biophysical Journal, 90, 1098-1106(2006)
[12] Zhao, Q., Comer, J., Dimitrov, V., Yemenicioglu, S., Aksimentiev, A., and Timp, G. Stretching and unzipping nucleic acid hairpins using a synthetic nanopore. Nucleic Acids Research, 36, 1532-1541(2008)
[13] Fologea, D., Uplinger, J., Thomas, B., McNabb, D. S., and Li, J. Slowing DNA translocation in a solid state nanopore. Nano Letters, 5, 1734-1737(2005)
[14] Chen, P., Gu, J. J., Brandin, E., Kim Y. R., Wang, D., and Branton, D. Probing single DNA molecule transport using fabricated nanopores. Nano Letters, 4, 2293-2298(2004)
[15] Gershow, M. and Golovchenko, J. A. Recapturing and trapping single molecules with a solid-state nanopore. Nature Nanotechnology, 2, 775-779(2007)
[16] Wanunu, M., Sutin, J., McNally, B., Chow, A., and Meller, A. DNA translocation governed by interactions with solid-state nanopores. Biophysical Journal, 95, 4716-4725(2008)
[17] Storm, A. J., Storm, C., Chen, J., Zandbergen, H., Joanny, J. F., and Dekker, C. Fast DNA translocation through a solid-state nanopore. Nano Letters, 5, 1193-1197(2005)
[18] Smeets, R. M. M., Keyser, U. F., Krapf, D., Wu, M. Y., Dekker, N. H., and Dekker, C. Salt dependence of ion transport and DNA translocation through solid-state nanopores. Nano Letters, 6, 89-95(2006)
[19] Cao, Q., Zuo, C., Li, L., Li, Y., and Yang, Y. Translocation of nanoparticles through a polymer brush-modified nanochannel. Biomicrofluidics, 6, 034101(2012)
[20] Gupta, C., Liao, W. C.,Gallego-Perez, D., Castro, C. E., and Lee, L. J. DNA translocation through short nanofluidic channels under asymmetric pulsed electric field. Biomicrofluidics, 8, 024114(2014)
[21] Geim, A. K. Graphene:status and prospects. Science, 324, 1530-1534(2009)
[22] Novoselov, K. S., Geim, A. K., Morozov, S. V., Jiang, D., Zhang, Y., Dubonos, S. V., Grigorieva, I. V., and Firsov, A. A. Electric field effect in atomically thin carbon films. Science, 306, 666-669(2004)
[23] Schneider, G. F., Kowalczyk, S. W., Calado, V. E., Pandraud, G., Zandbergen, H. W., Vandersypen, L. M. K., and Dekker, C. DNA translocation through graphene nanopores. Nano Letters, 10, 3163-3167(2010)
[24] Merchant, C. A., Healy, K., Wanunu, M., Ray, V., Peterman, N., Bartel, J., Fischbein, M. D., Venta, K., Luo, Z., Johnson, A. T. C., and Drndic, M. DNA translocation through graphene nanopores. Nano Letters 10, 2915-2921(2010)
[25] Garaj, S., Hubbard, W., Reina, A., Kong, J., Branton, D., and Golovchenko, J. A. Graphene as a subnanometre trans-electrode membrane. nature, 467, 190-193(2010)
[26] Schlijper, A. G., Hoogerbrugge, P. J., and Manke, C. W. Computer Simulation of dilute polymer solution with the dissipative particle dynamics method. Journal of Rheology, 39, 567(1995)
[27] Spenley, N. A. Scaling laws for polymers in dissipative particle dynamics. Europhysics Letters, 49, 534-540(2000)
[28] Kong, Y., Manke, C. W., Maddenand, W. G., and Schlijper, A. G. Effect of solvent quality on the conformation and relaxation of polymers via dissipative particle dynamics. The Journal of Chemical Physics, 107, 592-602(1997)
[29] Wijmans, C. M. and Smit, B. Simulating tethered polymer layers in shear flow with the dissipative particle dynamics technique. Macromolecules, 35, 7138-7148(2002)
[30] Chen, S., Phan-Thien, N., Fan, X. J., and Khoo, B. C. Dissipative particle dynamics simulation of polymer drops in a periodic shear flow. Journal of Non-Newtonian Fluid Mechanics, 118, 65-81(2004)
[31] Smiatek, J. and Schmid, F. Polyelectrolyte electrophoresis in nanochannels:a dissipative particle dynamics simulation. Journal of Chemical Physics B, 114, 6266-6272(2010)
[32] Hoogerbrugge, P. J. and Koelman, J. Simulating microscopic hydrodynamic phenomena with dissipative particle dynamics. Europhysics Letters, 19, 155-160(1992)
[33] Karplus, M. and Petsko, G. A. Molecular dynamics simulations in biology. nautre, 374, 631-639(1990)
[34] Frish, U., Hasslachcher, B., and Pomeau, Y. Lattice-gas automata for the Navier-Stokes equation. Physical Review Letters, 56, 1505(1986)
[35] Symeonidis, V., Karniadakis, G. E., and Caswell, B. Dissipative particle dynamics simulations of polymer chains:scaling laws and shearing response compared to DNA experiments. Physical Review Letters, 95, 76001(2005)
[36] Espanol, P. and Warren, P. Statistical mechanics of dissipative particle dynamics. Europhysics Letters, 30, 191-196(1995)
[37] Ewald, P. P. Die Berechnung optischer und elektrostatischer Gitterpotentiale. Annalen der Physik, 369, 253-287(1921)
[38] Gonzalez-Melchor, M., Mayoral, E., Velazquez, M. E., and Alejandre, J. Electrostatic interactions in dissipative particle dynamics using the Ewald sums. Journal of Chemical Physics, 125, 224107(2006)
[39] Darden, T., York, D., and Pedersen, L. Particle mesh Ewald:an Nlog(N) method for Ewald sums in large systems. The Journal of Chemical Physics, 98, 10089-10092(1993)
[40] Kratky, O. and Porod, G. Diffuse small-angle scattering of X-rays in colloid systems. Journal of Colloid Science, 4, 35-70(1949)
[41] Marko, J. F. and Siggia, E. D. Stretching DNA. Macromolecules, 28, 8759-8770(1995)
[42] Smith, S. B., Cui, Y. J., and Bustamante, C. Overstretching B-DNA:the elastic response of individual double-stranded and single-stranded DNA molecules. Science, 271, 795-799(1996)
[43] Murphy, M. C., Rasnik, I., Cheng, W., Lohman, T. M., Ha, T. Probing single-stranded DNA conformational flexibility using fluorescence spectroscopy. Biophysical Journal, 86, 2530-2537(2004)
[44] Chi, Q. J., Wang, G. X., and Jiang, J. H. The persistence length and length per base of singlestranded DNA obtained from fluorescence correlation spectroscopy measurements using mean field theory. Physica A:Statistical Mechanics and its Applications, 392, 1072(2013)
[45] Muthukumar, M. Theory of capture rate in polymer translocation. The Journal of Chemical Physics, 132, 195101(2010)
[46] Mihovilovic, M., Hagerty, N., and Stein, D. Statistics of DNA capture by a solid-state nanopore. Physical Review Letters, 110, 028102(2013)
[47] Cannavacciuolo, L., Winkler, R. G., and Gompper, G. Mesoscale simulations of polymer dynamic in microchannel flows. Europhysics Letters, 83, 34007(2008)
[48] Hu, G. H., Mao, M., and Ghosal, S. Ion transport through a graphene nanopore. Nanotechnology, 23, 395501(2012)
[49] Mao, M., Ghosal, S., and Hu, G. H. Hydrodynamic flow in the vicinity of a nanopore induced by an applied voltage. Nanotechnology, 24, 245202(2013)
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