Physics
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Item Simulation source code for "Myosin and α-actinin regulation of stress fiber contractility under tensile stress"(2023) Ni, Haoran; Ni, Qin; Papoian, Garegin A.; Trache, Andreea; Jiang, Yi; Jiang, YiStress fibers are actomyosin bundles that regulate cellular mechanosensation and force transduction. Connecting to extracellular matrix through focal adhesion complexes, stress fibers actively generate contractile forces with myosin motors and crosslinking proteins. Under external mechanical stimuli such as tensile forces, the stress fiber remodels its architectures to adapt to the external cues, displaying properties of viscoelastic materials. How the structural remodeling of stress fibers is related to the generation of contractile force is not well understood. In this work, we simulate mechanochemical dynamics and force generation of stress fibers using the molecular simulation platform MEDYAN. We model stress fiber as two connecting bipolar bundles attached at the ends to focal adhesion complexes. The simulated stress fibers generate contractile force that is regulated by myosin motors and α-actinin crosslinkers. We find that stress fibers are able to enhance contractility by reducing the distance between actin filaments to increase crosslinker binding, while this structural remodeling ability depends on the crosslinker turnover rate. Under tensile pulling, the stress fiber shows an instantaneous increase of the contractile forces followed by a slow relaxation into a new steady state. While the new steady state contractility after pulling only depends on the overlap between actin bundles, the short term contractility enhancement is sensitive to the tensile pulling distance. We further show that this mechanical response is sensitive to the crosslinker turnover rate. Our results provide insights into the stress fiber mechanics that have significant implications for understanding the cellular adaptation to mechanical signaling.Item Data for "A tug of war between filament treadmilling and myosin induced contractility generates actin ring"(2022-06-23) Ni, Qin; Wagh, Kaustubh; Pathni, Aashli; Ni, Haoran; Vashisht, Vishavdeep; Upadhyaya, Arpita; Papoian, Garegin A.; Upadhyaya, Arpita; Papoian, Garegin A.In most eukaryotic cells, actin filaments assemble into a shell-like actin cortex under the plasma membrane, controlling cellular morphology, mechanics, and signaling. The actin cortex is highly polymorphic, adopting diverse forms such as the ring-like structures found in podosomes, axonal rings, and immune synapses. The biophysical principles that underlie the formation of actin rings and cortices remain unknown. Using a molecular simulation platform, called MEDYAN, we discovered that varying the filament treadmilling rate and myosin concentration induces a finite size phase transition in actomyosin network structures. We found that actomyosin networks condense into clusters at low treadmilling rates or high myosin concentration but form ring-like or cortex-like structures at high treadmilling rates and low myosin concentration. This mechanism is supported by our corroborating experiments on live T cells, which exhibit ring-like actin networks upon activation by stimulatory antibody. Upon disruption of filament treadmilling or enhancement of myosin activity, the pre-existing actin rings are disrupted into actin clusters or collapse towards the network center respectively. Our analyses suggest that the ring-like actin structure is a preferred state of low mechanical energy, which is, importantly, only reachable at sufficiently high treadmilling rates.