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Rotational dynamics and transition mechanisms of surface-adsorbed proteins

Assembly of biomolecules at solid–water interfaces requires molecules to traverse complex orientation-dependent energy landscapes through processes that are poorly understood, largely due to the dearth of in situ single-molecule measurements and statistical analyses of the rotational dynamics that d...

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Autores principales: Zhang, Shuai, Sadre, Robbie, Legg, Benjamin A., Pyles, Harley, Perciano, Talita, Bethel, E. Wes, Baker, David, Rübel, Oliver, De Yoreo, James J.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: National Academy of Sciences 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9169768/
https://www.ncbi.nlm.nih.gov/pubmed/35412902
http://dx.doi.org/10.1073/pnas.2020242119
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author Zhang, Shuai
Sadre, Robbie
Legg, Benjamin A.
Pyles, Harley
Perciano, Talita
Bethel, E. Wes
Baker, David
Rübel, Oliver
De Yoreo, James J.
author_facet Zhang, Shuai
Sadre, Robbie
Legg, Benjamin A.
Pyles, Harley
Perciano, Talita
Bethel, E. Wes
Baker, David
Rübel, Oliver
De Yoreo, James J.
author_sort Zhang, Shuai
collection PubMed
description Assembly of biomolecules at solid–water interfaces requires molecules to traverse complex orientation-dependent energy landscapes through processes that are poorly understood, largely due to the dearth of in situ single-molecule measurements and statistical analyses of the rotational dynamics that define directional selection. Emerging capabilities in high-speed atomic force microscopy and machine learning have allowed us to directly determine the orientational energy landscape and observe and quantify the rotational dynamics for protein nanorods on the surface of muscovite mica under a variety of conditions. Comparisons with kinetic Monte Carlo simulations show that the transition rates between adjacent orientation-specific energetic minima can largely be understood through traditional models of in-plane Brownian rotation across a biased energy landscape, with resulting transition rates that are exponential in the energy barriers between states. However, transitions between more distant angular states are decoupled from barrier height, with jump-size distributions showing a power law decay that is characteristic of a nonclassical Levy-flight random walk, indicating that large jumps are enabled by alternative modes of motion via activated states. The findings provide insights into the dynamics of biomolecules at solid–liquid interfaces that lead to self-assembly, epitaxial matching, and other orientationally anisotropic outcomes and define a general procedure for exploring such dynamics with implications for hybrid biomolecular–inorganic materials design.
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spelling pubmed-91697682022-10-11 Rotational dynamics and transition mechanisms of surface-adsorbed proteins Zhang, Shuai Sadre, Robbie Legg, Benjamin A. Pyles, Harley Perciano, Talita Bethel, E. Wes Baker, David Rübel, Oliver De Yoreo, James J. Proc Natl Acad Sci U S A Physical Sciences Assembly of biomolecules at solid–water interfaces requires molecules to traverse complex orientation-dependent energy landscapes through processes that are poorly understood, largely due to the dearth of in situ single-molecule measurements and statistical analyses of the rotational dynamics that define directional selection. Emerging capabilities in high-speed atomic force microscopy and machine learning have allowed us to directly determine the orientational energy landscape and observe and quantify the rotational dynamics for protein nanorods on the surface of muscovite mica under a variety of conditions. Comparisons with kinetic Monte Carlo simulations show that the transition rates between adjacent orientation-specific energetic minima can largely be understood through traditional models of in-plane Brownian rotation across a biased energy landscape, with resulting transition rates that are exponential in the energy barriers between states. However, transitions between more distant angular states are decoupled from barrier height, with jump-size distributions showing a power law decay that is characteristic of a nonclassical Levy-flight random walk, indicating that large jumps are enabled by alternative modes of motion via activated states. The findings provide insights into the dynamics of biomolecules at solid–liquid interfaces that lead to self-assembly, epitaxial matching, and other orientationally anisotropic outcomes and define a general procedure for exploring such dynamics with implications for hybrid biomolecular–inorganic materials design. National Academy of Sciences 2022-04-11 2022-04-19 /pmc/articles/PMC9169768/ /pubmed/35412902 http://dx.doi.org/10.1073/pnas.2020242119 Text en Copyright © 2022 the Author(s). Published by PNAS. https://creativecommons.org/licenses/by-nc-nd/4.0/This article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND) (https://creativecommons.org/licenses/by-nc-nd/4.0/) .
spellingShingle Physical Sciences
Zhang, Shuai
Sadre, Robbie
Legg, Benjamin A.
Pyles, Harley
Perciano, Talita
Bethel, E. Wes
Baker, David
Rübel, Oliver
De Yoreo, James J.
Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title_full Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title_fullStr Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title_full_unstemmed Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title_short Rotational dynamics and transition mechanisms of surface-adsorbed proteins
title_sort rotational dynamics and transition mechanisms of surface-adsorbed proteins
topic Physical Sciences
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9169768/
https://www.ncbi.nlm.nih.gov/pubmed/35412902
http://dx.doi.org/10.1073/pnas.2020242119
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