Dynamically crosslinked semiflexible biopolymers such as the actin cytoskeleton govern the mechanical behavior of living cells. Semiflexible biopolymers nonlinearly stiffen in response to mechanical loads, whereas the crosslinker dynamics allow for stress relaxation over time.Here we show, through rheology and theoretical modeling, that the combined nonlinearity in time and stress leads to an unexpectedly slow stress relaxation, similar to the dynamics of disordered systems close to the glass transition. Our work suggests that transient crosslinking combined with internal stress can explain prior reports of soft glassy rheology of cells, in which the shear modulus increases weakly with frequency.
How do the cells in our body reconfigure their shape to achieve complex tasks like migration and mitosis, yet maintain their shape in response to forces exerted by, for instance, blood flow and muscle action? Cell shape control is defined by a delicate mechanical balance between active force generation and passive material properties of the plasma membrane and the cytoskeleton. The cytoskeleton forms a space-spanning fibrous network comprising three subsystems: actin, microtubules and intermediate filaments. Bottom-up reconstitution of minimal synthetic cells where these cytoskeletal subsystems are encapsulated inside a lipid vesicle provides a powerful avenue to dissect the force balance that governs cell shape control. Although encapsulation is technically demanding, a steady stream of advances in this technique has made the reconstitution of shape-changing minimal cells increasingly feasible. In this topical review we provide a route-map of the recent advances in cytoskeletal encapsulation techniques and outline recent reports that demonstrate shape change phenomena in simple biomimetic vesicle systems. We end with an outlook toward the next steps required to achieve more complex shape changes with the ultimate aim of building a fully functional synthetic cell with the capability to autonomously grow, divide and move.
In viscoelastic materials, individually short-lived bonds collectively result in a mechanical resistance which is long lived but finite as, ultimately, cracks appear. Here, we provide a microscopic mechanism by which a critical crack length emerges from the nonlinear local bond dynamics. Because of this emerging length scale, macroscopic viscoelastic materials fracture in a fundamentally different manner from microscopically small systems considered in previous models. We provide and numerically verify analytical equations for the dependence of the critical crack length on the bond kinetics and applied stress.
We study the role of a biomimetic actin network during the application of electric pulses that induce electroporation or electropermeabilization, using giant unilamellar vesicles (GUVs) as a model system. The actin cortex, a subjacently attached interconnected network of actin filaments, regulates the shape and mechanical properties of the plasma membrane of mammalian cells, and is a major factor influencing the mechanical response of the cell to external physical cues. We demonstrate that the presence of an actin shell inhibits the formation of macropores in the electroporated GUVs. Additionally, experiments on the uptake of dye molecules after electroporation show that the actin network slows down the resealing process of the permeabilized membrane. We further analyze the stability of the actin network inside the GUVs exposed to high electric pulses. We find disruption of the actin layer that is likely due to the electrophoretic forces acting on the actin filaments during the permeabilization of the GUVs. Our findings on the GUVs containing a biomimetic network provide a step towards understanding the discrepancies between the electroporation mechanism of a living cell and its simplified model of the empty GUV.
Molecular catch bonds are ubiquitous in biology and well-studied in the context of leukocyte extravasion 1 , cellular mechanosensing 2,3 , and urinary tract infection 4 . Unlike normal (slip) bonds, catch bonds strengthen under tension.The current paradigm is that this remarkable ability enables cells to increase their adhesion in fast fluid flows 1,4 , and hence provides 'strength-on-demand'.Recently, cytoskeletal crosslinkers have been discovered that also display catch bonding [5][6][7][8] . It has been suggested that they strengthen cells, following the strength-on-demand paradigm 9,10 . However, catch bonds tend to be weaker compared to regular (slip) bonds because they have cryptic binding sites that are often inactive [11][12][13] . Therefore, the role of catch bonding in the cytoskeleton remains unclear. Here we reconstitute cytoskeletal actin networks to show that catch bonds render them both stronger and more deformable than slip bonds, even though the bonds themselves are weaker. We develop a model to show that weak binding allows the catch bonds to mitigate crack initiation by moving from low-to high-tension areas in response to mechanical loading. By contrast, slip bonds remain trapped in stress-free areas. We therefore propose that the mechanism of catch bonding is typified by dissociation-on-demand rather than strength-on-demand. Dissociation-on-demand can explain how both cytolinkers [5][6][7][8]10,14,15 and adhesins 1,2,4,12,[16][17][18][19][20] exploit continuous redistribution to combine mechanical strength with the adaptability required for movement and proliferation 21 . Our findings provide a mechanistic understanding of diseases where catch bonding is compromised 11,12 such as kidney focal segmental glomerulosclerosis 22,23 , caused by the α-actinin-4 mutant studied here. Moreover, catch bonds provide a route towards creating life-like materials that combine strength with deformability 24 .Here we exploit the actin-binding protein α-actinin-4 and its K225E point mutant, associated with the heritable disease kidney focal segmental glomerulosclerosis type 1 22,25 , to identify the role of catch bonds in the mechanical properties of actin networks. Actin networks are key determinants of cell mechanics, together with other cytoskeletal proteins. To isolate the role of catch bonds in actin mechanics, we reconstitute actin networks from purified components. We first characterized the binding affinity of the two protein variants for actin .
By combining rheology and fluorescence recovery after photobleaching with theoretical modeling, we find that the unbinding rate of crosslinkers from only one filament is nearly two orders of magnitude slower than for doubly bound ones. We attribute the increased unbinding rate of doubly bound crosslinkers to the high stiffness of biopolymers, which frustrates crosslinker binding.
Molecular catch bonds are ubiquitous in biology and well-studied in the context of leukocyte extravasion1, cellular mechanosensing2,3, and urinary tract infection4. Unlike normal (slip) bonds, catch bonds strengthen under tension. The current paradigm is that this remarkable ability enables cells to increase their adhesion in fast fluid flows1,4, and hence provides ‘strength-on-demand’. Recently, cytoskeletal crosslinkers have been discovered that also display catch bonding5–8. It has been suggested that they strengthen cells, following the strength-on-demand paradigm9,10. However, catch bonds tend to be weaker compared to regular (slip) bonds because they have cryptic binding sites that are often inactive11–13. Therefore, the role of catch bonding in the cytoskeleton remains unclear. Here we reconstitute cytoskeletal actin networks to show that catch bonds render them both stronger and more deformable than slip bonds, even though the bonds themselves are weaker. We develop a model to show that weak binding allows the catch bonds to mitigate crack initiation by moving from low- to high-tension areas in response to mechanical loading. By contrast, slip bonds remain trapped in stress-free areas. We therefore propose that the mechanism of catch bonding is typified by dissociation-on-demand rather than strength-on-demand. Dissociation-on-demand can explain how both cytolinkers5–8,10,14,15 and adhesins1,2,4,12,16–20 exploit continuous redistribution to combine mechanical strength with the adaptability required for movement and proliferation21. Our findings provide a mechanistic understanding of diseases where catch bonding is compromised11,12 such as kidney focal segmental glomerulosclerosis22,23, caused by the α-actinin-4 mutant studied here. Moreover, catch bonds provide a route towards creating life-like materials that combine strength with deformability24.
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