Fluctuations in polymer translocation

P. L. Krapivsky; K. Mallick

doi:10.1088/1742-5468/2010/07/P07007

Fluctuations in polymer translocation

P. L. Krapivsky, K. Mallick

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate a model of chaperone-assisted polymer translocation through a nanopore in a membrane. Translocation is driven by irreversible random sequential absorption of chaperone proteins that bind to the polymer on one side of the membrane. The proteins are larger than the pore and hence the backward motion of the polymer is inhibited. This mechanism rectifies Brownian fluctuations and results in an effective force that drags the polymer in a preferred direction. The translocated polymer undergoes an effective biased random walk and we compute the corresponding diffusion constant. Our methods allow us to determine the large deviation function which, in addition to velocity and diffusion constant, contains the entire statistics of the translocated length.

Original language	English
Article number	P07007
Journal	Journal of Statistical Mechanics: Theory and Experiment
Volume	2010
Issue number	7
DOIs	https://doi.org/10.1088/1742-5468/2010/07/P07007
Publication status	Published - 1 Jan 2010
Externally published	Yes

Keywords

Diffusion
Exact results
Mechanical properties (DNA,RNA, membranes, biopolymers) (theory)
Polymer elasticity and dynamics

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10.1088/1742-5468/2010/07/P07007

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title = "Fluctuations in polymer translocation",

abstract = "We investigate a model of chaperone-assisted polymer translocation through a nanopore in a membrane. Translocation is driven by irreversible random sequential absorption of chaperone proteins that bind to the polymer on one side of the membrane. The proteins are larger than the pore and hence the backward motion of the polymer is inhibited. This mechanism rectifies Brownian fluctuations and results in an effective force that drags the polymer in a preferred direction. The translocated polymer undergoes an effective biased random walk and we compute the corresponding diffusion constant. Our methods allow us to determine the large deviation function which, in addition to velocity and diffusion constant, contains the entire statistics of the translocated length.",

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AB - We investigate a model of chaperone-assisted polymer translocation through a nanopore in a membrane. Translocation is driven by irreversible random sequential absorption of chaperone proteins that bind to the polymer on one side of the membrane. The proteins are larger than the pore and hence the backward motion of the polymer is inhibited. This mechanism rectifies Brownian fluctuations and results in an effective force that drags the polymer in a preferred direction. The translocated polymer undergoes an effective biased random walk and we compute the corresponding diffusion constant. Our methods allow us to determine the large deviation function which, in addition to velocity and diffusion constant, contains the entire statistics of the translocated length.

KW - Diffusion

KW - Exact results

KW - Mechanical properties (DNA,RNA, membranes, biopolymers) (theory)

KW - Polymer elasticity and dynamics

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JO - Journal of Statistical Mechanics: Theory and Experiment

JF - Journal of Statistical Mechanics: Theory and Experiment

IS - 7

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ER -

Fluctuations in polymer translocation

Abstract

Keywords

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