Tension causes structural unfolding of intracellular intermediate filaments

Fleißner, Frederik; Kumar, Sachin; Klein, Noreen; Wirth, Daniel; Dhiman, Ravi; Schneider, Dirk; Bonn, Mischa; Parekh, Sapun H.

doi:10.1101/2020.04.22.054379

2020

DOI: 10.1101/2020.04.22.054379

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Tension causes structural unfolding of intracellular intermediate filaments

Frederik Fleißner

Sachin Kumar²,

Noreen Klein

et al.

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 have shown that IF proteins undergo secondary structural changes to compensate mechanical loads, which has been confirmed by experimental in vitro studies on IF hydrogels. However, the structural response of intracellular IF to mechanical load has yet to be … Show more

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Intermediate Filaments from Tissue Integrity to Single Molecule Mechanics

Bodegraven

Etienne-Manneville

2021

Cells

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Cytoplasmic intermediate filaments (IFs), which together with actin and microtubules form the cytoskeleton, are composed of a large and diverse family of proteins. Efforts to elucidate the molecular mechanisms responsible for IF-associated diseases increasingly point towards a major contribution of IFs to the cell’s ability to adapt, resist and respond to mechanical challenges. From these observations, which echo the impressive resilience of IFs in vitro, we here discuss the role of IFs as master integrators of cell and tissue mechanics. In this review, we summarize our current understanding of the contribution of IFs to cell and tissue mechanics and explain these results in light of recent in vitro studies that have investigated physical properties of single IFs and IF networks. Finally, we highlight how changes in IF gene expression, network assembly dynamics, and post-translational modifications can tune IF properties to adapt cell and tissue mechanics to changing environments.

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Intermediate Filaments from Tissue Integrity to Single Molecule Mechanics

Bodegraven

Etienne-Manneville

2021

Cells

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Tension causes structural unfolding of intracellular intermediate filaments

Cited by 1 publication

References 82 publications

Intermediate Filaments from Tissue Integrity to Single Molecule Mechanics

Intermediate Filaments from Tissue Integrity to Single Molecule Mechanics

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