Force as a single molecule probe of multidimensional protein energy landscapes

Gabriel Žoldák; Matthias Rief

doi:10.1016/j.sbi.2012.11.007

Force as a single molecule probe of multidimensional protein energy landscapes

Gabriel Žoldák, Matthias Rief

Chair of Biophysics

Research output: Contribution to journal › Review article › peer-review

115 Scopus citations

Abstract

Force spectroscopy has developed into an indispensable tool for studying folding and binding of proteins on a single molecule level in real time. Design of the pulling geometry allows tuning the reaction coordinate in a very precise manner. Many recent experiments have taken advantage of this possibility and have provided detailed insight the folding pathways on the complex high dimensional energy landscape. Beyond its potential to provide control over the reaction coordinate, force is also an important physiological parameter that affects protein conformation under in vivo conditions. Single molecule force spectroscopy studies have started to unravel the response and adaptation of force bearing protein structures to mechanical loads.

Original language	English
Pages (from-to)	48-57
Number of pages	10
Journal	Current Opinion in Structural Biology
Volume	23
Issue number	1
DOIs	https://doi.org/10.1016/j.sbi.2012.11.007
State	Published - Feb 2013

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title = "Force as a single molecule probe of multidimensional protein energy landscapes",

abstract = "Force spectroscopy has developed into an indispensable tool for studying folding and binding of proteins on a single molecule level in real time. Design of the pulling geometry allows tuning the reaction coordinate in a very precise manner. Many recent experiments have taken advantage of this possibility and have provided detailed insight the folding pathways on the complex high dimensional energy landscape. Beyond its potential to provide control over the reaction coordinate, force is also an important physiological parameter that affects protein conformation under in vivo conditions. Single molecule force spectroscopy studies have started to unravel the response and adaptation of force bearing protein structures to mechanical loads.",

author = "Gabriel {\v Z}old{\'a}k and Matthias Rief",

note = "Funding Information: We thank Dr. Ziad Ganim for critical reading of the manuscript. This work was supported by the SFB 1035/A5 and ZO 291/1-1 projects of Deutsche Forschungsgemeinschaft .",

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AU - Rief, Matthias

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N2 - Force spectroscopy has developed into an indispensable tool for studying folding and binding of proteins on a single molecule level in real time. Design of the pulling geometry allows tuning the reaction coordinate in a very precise manner. Many recent experiments have taken advantage of this possibility and have provided detailed insight the folding pathways on the complex high dimensional energy landscape. Beyond its potential to provide control over the reaction coordinate, force is also an important physiological parameter that affects protein conformation under in vivo conditions. Single molecule force spectroscopy studies have started to unravel the response and adaptation of force bearing protein structures to mechanical loads.

AB - Force spectroscopy has developed into an indispensable tool for studying folding and binding of proteins on a single molecule level in real time. Design of the pulling geometry allows tuning the reaction coordinate in a very precise manner. Many recent experiments have taken advantage of this possibility and have provided detailed insight the folding pathways on the complex high dimensional energy landscape. Beyond its potential to provide control over the reaction coordinate, force is also an important physiological parameter that affects protein conformation under in vivo conditions. Single molecule force spectroscopy studies have started to unravel the response and adaptation of force bearing protein structures to mechanical loads.

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Force as a single molecule probe of multidimensional protein energy landscapes

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