Actin filament alignment causes mechanical hysteresis in cross-linked networks

Abstract: Cells dynamically control their material properties through remodeling of the actin cytoskeleton, an assembly of cross-linked networks and bundles formed from the biopolymer actin. We recently found that cross-linked networks of actin filaments reconstituted in vitro can exhibit adaptive behavior and thus serve as a model system to understand the underlying mechanisms of mechanical adaptation of the cytoskeleton. In these networks, training, in the form of applied shear stress, can induce asymmetry in the nonl… Show more

“…Such situations are predominantly transient as the microtubules can change their gliding direction. The intriguing, nevertheless, rare observation of quasi-oscillatory microtubule movement indicates elastic coupling ( 42 ) to actin by local strains in the actin mesh ( 43 ). In the future, direct force measurements shall help resolve this question in greater detail.…”

Actin architecture steers microtubules in active cytoskeletal composite

“…Such situations are predominantly transient as the microtubules can change their gliding direction. The intriguing, nevertheless, rare observation of quasi-oscillatory microtubule movement indicates elastic coupling ( 42 ) to actin by local strains in the actin mesh ( 43 ). In the future, direct force measurements shall help resolve this question in greater detail.…”

Actin architecture steers microtubules in active cytoskeletal composite