Lateral Subunit Coupling Determines Intermediate Filament Mechanics

Lateral Subunit Coupling Determines Intermediate Filament Mechanics

The cytoskeleton is a composite network of three types of protein filaments, among which intermediate filaments (IFs) are the most extensible ones. Two very important IFs are keratin and vimentin, which have similar molecular architectures but different mechanical behaviors. Here we compare the mech...

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Veröffentlicht in:Physical review letters 2019-11, Vol.123 (18), p.188102-188102, Article 188102
Hauptverfasser: Lorenz, Charlotta, Forsting, Johanna, Schepers, Anna V, Kraxner, Julia, Bauch, Susanne, Witt, Hannes, Klumpp, Stefan, Köster, Sarah
Format: Artikel
Sprache:eng
Schlagworte:
Biomechanical Phenomena
Buffers
Coupling (molecular)
Cytoskeleton - chemistry
Cytoskeleton - metabolism
Filaments
Helices
Keratin
Keratins - chemistry
Keratins - metabolism
Mechanical analysis
Mechanics
Mechanics (physics)
Microscopy, Atomic Force
Models, Biological
Optical Tweezers
Osmolar Concentration
Protein Conformation, alpha-Helical
Vimentin - chemistry
Vimentin - metabolism
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Zusammenfassung:The cytoskeleton is a composite network of three types of protein filaments, among which intermediate filaments (IFs) are the most extensible ones. Two very important IFs are keratin and vimentin, which have similar molecular architectures but different mechanical behaviors. Here we compare the mechanical response of single keratin and vimentin filaments using optical tweezers. We show that the mechanics of vimentin strongly depends on the ionic strength of the buffer and that its force-strain curve suggests a high degree of cooperativity between subunits. Indeed, a computational model indicates that in contrast to keratin, vimentin is characterized by strong lateral subunit coupling of its charged monomers during unfolding of α helices. We conclude that cells can tune their mechanics by differential use of keratin versus vimentin.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.123.188102