Transport dynamics of molecular motors that switch between an active and inactive state

I. Pinkoviezky; Nir Gov

doi:10.1103/PhysRevE.88.022714

Transport dynamics of molecular motors that switch between an active and inactive state

I. Pinkoviezky, Nir Gov

Department of Chemical and Biological Physics

Weizmann Institute of Science

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

Abstract

Molecular motors are involved in key transport processes in the cell. Many of these motors can switch from an active to a nonactive state, either spontaneously or depending on their interaction with other molecules. When active, the motors move processively along the filaments, while when inactive they are stationary. We treat here the simple case of spontaneously switching motors, between the active and inactive states, along an open linear track. We use our recent analogy with vehicular traffic, where we go beyond the mean-field description. We map the phase diagram of this system, and find that it clearly breaks the symmetry between the different phases, as compared to the standard total asymmetric exclusion process. We make several predictions that may be testable using molecular motors in vitro and in living cells.

Original language	English
Article number	022714
Journal	Physical Review E
Volume	88
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.88.022714
State	Published - 20 Aug 2013

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Statistical and Nonlinear Physics
Statistics and Probability

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10.1103/PhysRevE.88.022714

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title = "Transport dynamics of molecular motors that switch between an active and inactive state",

abstract = "Molecular motors are involved in key transport processes in the cell. Many of these motors can switch from an active to a nonactive state, either spontaneously or depending on their interaction with other molecules. When active, the motors move processively along the filaments, while when inactive they are stationary. We treat here the simple case of spontaneously switching motors, between the active and inactive states, along an open linear track. We use our recent analogy with vehicular traffic, where we go beyond the mean-field description. We map the phase diagram of this system, and find that it clearly breaks the symmetry between the different phases, as compared to the standard total asymmetric exclusion process. We make several predictions that may be testable using molecular motors in vitro and in living cells.",

author = "I. Pinkoviezky and Nir Gov",

note = "ISF [580/12]We gratefully acknowledge funding from the ISF (Grant No. 580/12). This research is made possible in part by the historic generosity of the Harold Perlman Family.",

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N2 - Molecular motors are involved in key transport processes in the cell. Many of these motors can switch from an active to a nonactive state, either spontaneously or depending on their interaction with other molecules. When active, the motors move processively along the filaments, while when inactive they are stationary. We treat here the simple case of spontaneously switching motors, between the active and inactive states, along an open linear track. We use our recent analogy with vehicular traffic, where we go beyond the mean-field description. We map the phase diagram of this system, and find that it clearly breaks the symmetry between the different phases, as compared to the standard total asymmetric exclusion process. We make several predictions that may be testable using molecular motors in vitro and in living cells.

AB - Molecular motors are involved in key transport processes in the cell. Many of these motors can switch from an active to a nonactive state, either spontaneously or depending on their interaction with other molecules. When active, the motors move processively along the filaments, while when inactive they are stationary. We treat here the simple case of spontaneously switching motors, between the active and inactive states, along an open linear track. We use our recent analogy with vehicular traffic, where we go beyond the mean-field description. We map the phase diagram of this system, and find that it clearly breaks the symmetry between the different phases, as compared to the standard total asymmetric exclusion process. We make several predictions that may be testable using molecular motors in vitro and in living cells.

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M3 - مقالة

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JO - Physical Review E

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ER -

Transport dynamics of molecular motors that switch between an active and inactive state

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