Diffusion of a disordered protein on its folded ligand

Felix Wiggers; Samuel Wohl; Artem Dubovetskyi; Gabriel Rosenblum; Wenwei Zheng; Hagen Hofmann

doi:10.1073/pnas.2106690118

Diffusion of a disordered protein on its folded ligand

Felix Wiggers, Samuel Wohl, Artem Dubovetskyi, Gabriel Rosenblum, Wenwei Zheng, Hagen Hofmann

Department of Chemical and Structural Biology

Weizmann Institute of Science

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

Abstract

Intrinsically disordered proteins often form dynamic complexes with their ligands. Yet, the speed and amplitude of these motions are hidden in classical binding kinetics. Here, we directly measure the dynamics in an exceptionally mobile, high-affinity complex. We show that the disordered tail of the cell adhesion protein E-cadherin dynamically samples a large surface area of the protooncogene β-catenin. Single-molecule experiments and molecular simulations resolve these motions with high resolution in space and time. Contacts break and form within hundreds of microseconds without a dissociation of the complex. The energy landscape of this complex is rugged with many small barriers (3 to 4 kBT) and reconciles specificity, high affinity, and extreme disorder. A few persistent contacts provide specificity, whereas unspecific interactions boost affinity.

Original language	English
Article number	e2106690118
Journal	Proceedings of the National Academy of Sciences
Volume	118
Issue number	37
DOIs	https://doi.org/10.1073/pnas.2106690118
State	Published - 14 Sep 2021

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title = "Diffusion of a disordered protein on its folded ligand",

abstract = "Intrinsically disordered proteins often form dynamic complexes with their ligands. Yet, the speed and amplitude of these motions are hidden in classical binding kinetics. Here, we directly measure the dynamics in an exceptionally mobile, high-affinity complex. We show that the disordered tail of the cell adhesion protein E-cadherin dynamically samples a large surface area of the protooncogene β-catenin. Single-molecule experiments and molecular simulations resolve these motions with high resolution in space and time. Contacts break and form within hundreds of microseconds without a dissociation of the complex. The energy landscape of this complex is rugged with many small barriers (3 to 4 kBT) and reconciles specificity, high affinity, and extreme disorder. A few persistent contacts provide specificity, whereas unspecific interactions boost affinity.",

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T1 - Diffusion of a disordered protein on its folded ligand

AU - Wiggers, Felix

AU - Wohl, Samuel

AU - Dubovetskyi, Artem

AU - Rosenblum, Gabriel

AU - Zheng, Wenwei

AU - Hofmann, Hagen

PY - 2021/9/14

Y1 - 2021/9/14

N2 - Intrinsically disordered proteins often form dynamic complexes with their ligands. Yet, the speed and amplitude of these motions are hidden in classical binding kinetics. Here, we directly measure the dynamics in an exceptionally mobile, high-affinity complex. We show that the disordered tail of the cell adhesion protein E-cadherin dynamically samples a large surface area of the protooncogene β-catenin. Single-molecule experiments and molecular simulations resolve these motions with high resolution in space and time. Contacts break and form within hundreds of microseconds without a dissociation of the complex. The energy landscape of this complex is rugged with many small barriers (3 to 4 kBT) and reconciles specificity, high affinity, and extreme disorder. A few persistent contacts provide specificity, whereas unspecific interactions boost affinity.

AB - Intrinsically disordered proteins often form dynamic complexes with their ligands. Yet, the speed and amplitude of these motions are hidden in classical binding kinetics. Here, we directly measure the dynamics in an exceptionally mobile, high-affinity complex. We show that the disordered tail of the cell adhesion protein E-cadherin dynamically samples a large surface area of the protooncogene β-catenin. Single-molecule experiments and molecular simulations resolve these motions with high resolution in space and time. Contacts break and form within hundreds of microseconds without a dissociation of the complex. The energy landscape of this complex is rugged with many small barriers (3 to 4 kBT) and reconciles specificity, high affinity, and extreme disorder. A few persistent contacts provide specificity, whereas unspecific interactions boost affinity.

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U2 - 10.1073/pnas.2106690118

DO - 10.1073/pnas.2106690118

M3 - مقالة

SN - 0027-8424

VL - 118

JO - Proceedings of the National Academy of Sciences

JF - Proceedings of the National Academy of Sciences

IS - 37

M1 - e2106690118

ER -

Diffusion of a disordered protein on its folded ligand

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