High-speed AFM images of thermal motion provide stiffness map of interfacial membrane protein moieties

Johannes Preiner; Andreas Horner; Andreas Karner; Nicole Ollinger; Christine Siligan; Peter Pohl; Peter Hinterdorfer

doi:10.1021/nl504478f

High-speed AFM images of thermal motion provide stiffness map of interfacial membrane protein moieties

Johannes Preiner
, Andreas Horner
, Andreas Karner
, Nicole Ollinger
, Christine Siligan
, Peter Pohl
, Peter Hinterdorfer

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

Abstract

The flexibilities of extracellular loops determine ligand binding and activation of membrane receptors. Arising from fluctuations in inter- and intraproteinaceous interactions, flexibility manifests in thermal motion. Here we demonstrate that quantitative flexibility values can be extracted from directly imaging the thermal motion of membrane protein moieties using high-speed atomic force microscopy (HS-AFM). Stiffness maps of the main periplasmic loops of single reconstituted water channels (AqpZ, GlpF) revealed the spatial and temporal organization of loop-stabilizing intraproteinaceous H-bonds and salt bridges.

Original language	English
Pages (from-to)	759-763
Number of pages	5
Journal	Nano Letters
Volume	15
Issue number	1
DOIs	https://doi.org/10.1021/nl504478f
Publication status	Published - 14 Jan 2015

Fields of science

103 Physics, Astronomy

JKU Focus areas

Engineering and Natural Sciences (in general)

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10.1021/nl504478f

Cite this

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abstract = "The flexibilities of extracellular loops determine ligand binding and activation of membrane receptors. Arising from fluctuations in inter- and intraproteinaceous interactions, flexibility manifests in thermal motion. Here we demonstrate that quantitative flexibility values can be extracted from directly imaging the thermal motion of membrane protein moieties using high-speed atomic force microscopy (HS-AFM). Stiffness maps of the main periplasmic loops of single reconstituted water channels (AqpZ, GlpF) revealed the spatial and temporal organization of loop-stabilizing intraproteinaceous H-bonds and salt bridges.",

author = "Johannes Preiner and Andreas Horner and Andreas Karner and Nicole Ollinger and Christine Siligan and Peter Pohl and Peter Hinterdorfer",

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T1 - High-speed AFM images of thermal motion provide stiffness map of interfacial membrane protein moieties

AU - Preiner, Johannes

AU - Horner, Andreas

AU - Karner, Andreas

AU - Ollinger, Nicole

AU - Siligan, Christine

AU - Pohl, Peter

AU - Hinterdorfer, Peter

PY - 2015/1/14

Y1 - 2015/1/14

N2 - The flexibilities of extracellular loops determine ligand binding and activation of membrane receptors. Arising from fluctuations in inter- and intraproteinaceous interactions, flexibility manifests in thermal motion. Here we demonstrate that quantitative flexibility values can be extracted from directly imaging the thermal motion of membrane protein moieties using high-speed atomic force microscopy (HS-AFM). Stiffness maps of the main periplasmic loops of single reconstituted water channels (AqpZ, GlpF) revealed the spatial and temporal organization of loop-stabilizing intraproteinaceous H-bonds and salt bridges.

AB - The flexibilities of extracellular loops determine ligand binding and activation of membrane receptors. Arising from fluctuations in inter- and intraproteinaceous interactions, flexibility manifests in thermal motion. Here we demonstrate that quantitative flexibility values can be extracted from directly imaging the thermal motion of membrane protein moieties using high-speed atomic force microscopy (HS-AFM). Stiffness maps of the main periplasmic loops of single reconstituted water channels (AqpZ, GlpF) revealed the spatial and temporal organization of loop-stabilizing intraproteinaceous H-bonds and salt bridges.

UR - https://www.scopus.com/pages/publications/84920995403

U2 - 10.1021/nl504478f

DO - 10.1021/nl504478f

M3 - Article

C2 - 25516527

SN - 1530-6992

VL - 15

SP - 759

EP - 763

JO - Nano Letters

JF - Nano Letters

IS - 1

ER -

High-speed AFM images of thermal motion provide stiffness map of interfacial membrane protein moieties

Abstract

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