Percolation transition prescribes protein size-specific barrier to passive transport through the nuclear pore complex

David Winogradoff; Han Yi Chou; Christopher Maffeo; Aleksei Aksimentiev

doi:10.1038/s41467-022-32857-1

Percolation transition prescribes protein size-specific barrier to passive transport through the nuclear pore complex

David Winogradoff, Han Yi Chou, Christopher Maffeo, Aleksei Aksimentiev

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

Abstract

Nuclear pore complexes (NPCs) control biomolecular transport in and out of the nucleus. Disordered nucleoporins in the complex’s pore form a permeation barrier, preventing unassisted transport of large biomolecules. Here, we combine coarse-grained simulations of experimentally derived NPC structures with a theoretical model to determine the microscopic mechanism of passive transport. Brute-force simulations of protein transport reveal telegraph-like behavior, where prolonged diffusion on one side of the NPC is interrupted by rapid crossings to the other. We rationalize this behavior using a theoretical model that reproduces the energetics and kinetics of permeation solely from statistics of transient voids within the disordered mesh. As the protein size increases, the mesh transforms from a soft to a hard barrier, enabling orders-of-magnitude reduction in permeation rate for proteins beyond the percolation size threshold. Our model enables exploration of alternative NPC architectures and sets the stage for uncovering molecular mechanisms of facilitated nuclear transport.

Original language	English (US)
Article number	5138
Journal	Nature communications
Volume	13
Issue number	1
Early online date	Sep 1 2022
DOIs	https://doi.org/10.1038/s41467-022-32857-1
State	Published - Dec 2022

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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title = "Percolation transition prescribes protein size-specific barrier to passive transport through the nuclear pore complex",

abstract = "Nuclear pore complexes (NPCs) control biomolecular transport in and out of the nucleus. Disordered nucleoporins in the complex{\textquoteright}s pore form a permeation barrier, preventing unassisted transport of large biomolecules. Here, we combine coarse-grained simulations of experimentally derived NPC structures with a theoretical model to determine the microscopic mechanism of passive transport. Brute-force simulations of protein transport reveal telegraph-like behavior, where prolonged diffusion on one side of the NPC is interrupted by rapid crossings to the other. We rationalize this behavior using a theoretical model that reproduces the energetics and kinetics of permeation solely from statistics of transient voids within the disordered mesh. As the protein size increases, the mesh transforms from a soft to a hard barrier, enabling orders-of-magnitude reduction in permeation rate for proteins beyond the percolation size threshold. Our model enables exploration of alternative NPC architectures and sets the stage for uncovering molecular mechanisms of facilitated nuclear transport.",

author = "David Winogradoff and Chou, {Han Yi} and Christopher Maffeo and Aleksei Aksimentiev",

note = "This work was supported by the Center for the Physics of Living Cells through the National Science Foundation grant PHY-1430124 to A.A. and by the National Institutes of Health through grants R01-GM137015 and P41-GM104601 to A.A. The supercomputer time was provided by the Extreme Science and Engineering Discovery Environment (allocation MCA05S028), the Blue Waters petascale supercomputer system (UIUC), and Leadership Resource Allocation MCB20012 on Frontera at the Texas Advanced Computing Center. Frontera is made possible by National Science Foundation award OAC-1818253. We thank Drs. Patrick Onck and Ali Ghavami for sharing files that described potentials of their coarse-grained model. A.A. would like to thank Dr. Cees Dekker for the invitation to join the nuclear transport field. This work was supported by the Center for the Physics of Living Cells through the National Science Foundation grant PHY-1430124 to A.A. and by the National Institutes of Health through grants R01-GM137015 and P41-GM104601 to A.A. The supercomputer time was provided by the Extreme Science and Engineering Discovery Environment (allocation MCA05S028), the Blue Waters petascale supercomputer system (UIUC), and Leadership Resource Allocation MCB20012 on Frontera at the Texas Advanced Computing Center. Frontera is made possible by National Science Foundation award OAC-1818253. We thank Drs. Patrick Onck and Ali Ghavami for sharing files that described potentials of their coarse-grained model. A.A. would like to thank Dr. Cees Dekker for the invitation to join the nuclear transport field.",

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doi = "10.1038/s41467-022-32857-1",

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N1 - This work was supported by the Center for the Physics of Living Cells through the National Science Foundation grant PHY-1430124 to A.A. and by the National Institutes of Health through grants R01-GM137015 and P41-GM104601 to A.A. The supercomputer time was provided by the Extreme Science and Engineering Discovery Environment (allocation MCA05S028), the Blue Waters petascale supercomputer system (UIUC), and Leadership Resource Allocation MCB20012 on Frontera at the Texas Advanced Computing Center. Frontera is made possible by National Science Foundation award OAC-1818253. We thank Drs. Patrick Onck and Ali Ghavami for sharing files that described potentials of their coarse-grained model. A.A. would like to thank Dr. Cees Dekker for the invitation to join the nuclear transport field. This work was supported by the Center for the Physics of Living Cells through the National Science Foundation grant PHY-1430124 to A.A. and by the National Institutes of Health through grants R01-GM137015 and P41-GM104601 to A.A. The supercomputer time was provided by the Extreme Science and Engineering Discovery Environment (allocation MCA05S028), the Blue Waters petascale supercomputer system (UIUC), and Leadership Resource Allocation MCB20012 on Frontera at the Texas Advanced Computing Center. Frontera is made possible by National Science Foundation award OAC-1818253. We thank Drs. Patrick Onck and Ali Ghavami for sharing files that described potentials of their coarse-grained model. A.A. would like to thank Dr. Cees Dekker for the invitation to join the nuclear transport field.

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N2 - Nuclear pore complexes (NPCs) control biomolecular transport in and out of the nucleus. Disordered nucleoporins in the complex’s pore form a permeation barrier, preventing unassisted transport of large biomolecules. Here, we combine coarse-grained simulations of experimentally derived NPC structures with a theoretical model to determine the microscopic mechanism of passive transport. Brute-force simulations of protein transport reveal telegraph-like behavior, where prolonged diffusion on one side of the NPC is interrupted by rapid crossings to the other. We rationalize this behavior using a theoretical model that reproduces the energetics and kinetics of permeation solely from statistics of transient voids within the disordered mesh. As the protein size increases, the mesh transforms from a soft to a hard barrier, enabling orders-of-magnitude reduction in permeation rate for proteins beyond the percolation size threshold. Our model enables exploration of alternative NPC architectures and sets the stage for uncovering molecular mechanisms of facilitated nuclear transport.

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Percolation transition prescribes protein size-specific barrier to passive transport through the nuclear pore complex

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