Tension Causes Unfolding of Intracellular Vimentin Intermediate Filaments
Abstract: Intermediate filament (IF) proteins are a class of proteins that constitute different filamentous structures in mammalian cells. As such, IF proteins are part of the load‐bearing cytoskeleton and support the nuclear envelope. Molecular dynamics simulations show that IF proteins undergo secondary structural changes to compensate mechanical loads, which is confirmed by experimental in vitro studies on IF hydrogels. However, the structural response of intracellular IF to mechanical load is yet to be elucidated in cellulo. Here, in situ nonlinear Raman imaging combined with multivariate data analysis is used to quantify the intracellular secondary structure of the IF cytoskeletal protein vimentin under different states of cellular tension. It is found that cells under native cellular tension contain more unfolded vimentin than chemically or physically relaxed specimens. This indicates that the unfolding of IF proteins occurs intracellularly when sufficient forces are applied, suggesting that IF structures act as local force sensors in the cell to mark locations under large mechanical tension.
- Location
-
Deutsche Nationalbibliothek Frankfurt am Main
- Extent
-
Online-Ressource
- Language
-
Englisch
- Bibliographic citation
-
Tension Causes Unfolding of Intracellular Vimentin Intermediate Filaments ; volume:4 ; number:11 ; year:2020 ; extent:12
Advanced biosystems ; 4, Heft 11 (2020) (gesamt 12)
- Creator
-
Fleissner, Frederik
Kumar, Sachin
Klein, Noreen
Wirth, Daniel
Dhiman, Ravi
Schneider, Dirk
Bonn, Mischa
Parekh, Sapun H.
- DOI
-
10.1002/adbi.202000111
- URN
-
urn:nbn:de:101:1-2022062109245198127166
- Rights
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
-
15.08.2025, 7:29 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Fleissner, Frederik
- Kumar, Sachin
- Klein, Noreen
- Wirth, Daniel
- Dhiman, Ravi
- Schneider, Dirk
- Bonn, Mischa
- Parekh, Sapun H.
Other Objects (12)
Probing the Mineral–Water Interface with Nonlinear Optical Spectroscopy
Semiconducting nanocrystals: synthesis, colloidal stability, and charge carrier dynamics
Investigating the water-titanium dioxide interface using sum frequency generation spectroscopy
Untersuchung der Mineral‐Wasser‐Grenzschicht mit nicht‐linearer optischer Spektroskopie
Das hydratisierte Proton besitzt eine deutlich höhere Oberflächenaktivität als das Hydroxidion
The Surface Activity of the Hydrated Proton Is Substantially Higher than That of the Hydroxide Ion
Semiconducting nanocrystals : synthesis, colloidal stability, and charge carrier dynamics
Lateral interactions between adsorbed molecules: Investigations of CO on Ru(001) using nonlinear surface vibrational spectroscopies
The dynamics of vibrational excitations on surfaces: CO on Ru(001)
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes
Comparative Adsorption of Acetone on Water and Ice Surfaces
Probing the Mineral–Water Interface with Nonlinear Optical Spectroscopy
Semiconducting nanocrystals: synthesis, colloidal stability, and charge carrier dynamics
Investigating the water-titanium dioxide interface using sum frequency generation spectroscopy
Untersuchung der Mineral‐Wasser‐Grenzschicht mit nicht‐linearer optischer Spektroskopie
Das hydratisierte Proton besitzt eine deutlich höhere Oberflächenaktivität als das Hydroxidion
The Surface Activity of the Hydrated Proton Is Substantially Higher than That of the Hydroxide Ion
Semiconducting nanocrystals : synthesis, colloidal stability, and charge carrier dynamics
Lateral interactions between adsorbed molecules: Investigations of CO on Ru(001) using nonlinear surface vibrational spectroscopies
The dynamics of vibrational excitations on surfaces: CO on Ru(001)
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes
Comparative Adsorption of Acetone on Water and Ice Surfaces
Probing the Mineral–Water Interface with Nonlinear Optical Spectroscopy
Semiconducting nanocrystals: synthesis, colloidal stability, and charge carrier dynamics
Investigating the water-titanium dioxide interface using sum frequency generation spectroscopy
Untersuchung der Mineral‐Wasser‐Grenzschicht mit nicht‐linearer optischer Spektroskopie
Das hydratisierte Proton besitzt eine deutlich höhere Oberflächenaktivität als das Hydroxidion
The Surface Activity of the Hydrated Proton Is Substantially Higher than That of the Hydroxide Ion
Semiconducting nanocrystals : synthesis, colloidal stability, and charge carrier dynamics
Lateral interactions between adsorbed molecules: Investigations of CO on Ru(001) using nonlinear surface vibrational spectroscopies
The dynamics of vibrational excitations on surfaces: CO on Ru(001)
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes
Nanoscale Distribution of Sulfonic Acid Groups Determines Structure and Binding of Water in Nafion Membranes