Your search keyword '"Murrell, Michael"' showing total 9 results

1. Substrate geometry and topography induce F-actin reorganization and chiral alignment in an adherent model cortex

Author

Sakamoto, Ryota and Murrell, Michael P.

Published

2024

2. F-actin buckling coordinates contractility and severing in a biomimetic actomyosin cortex

Author

Murrell, Michael P. and Gardel, Margaret L.

Published

2012

3. Membrane tension induces F-actin reorganization and flow in a biomimetic model cortex.

Author

Sakamoto, Ryota, Banerjee, Deb Sankar, Yadav, Vikrant, Chen, Sheng, Gardel, Margaret, Sykes, Cecile, Banerjee, Shiladitya, and Murrell, Michael P.

Subjects

F-actin, STRAINS & stresses (Mechanics), CELL morphology, CELL migration, LIPOSOMES, CELLULAR mechanics, CYTOSKELETON, TISSUE mechanics

Abstract

The accumulation and transmission of mechanical stresses in the cell cortex and membrane determines the mechanics of cell shape and coordinates essential physical behaviors, from cell polarization to cell migration. However, the extent that the membrane and cytoskeleton each contribute to the transmission of mechanical stresses to coordinate diverse behaviors is unclear. Here, we reconstitute a minimal model of the actomyosin cortex within liposomes that adheres, spreads and ultimately ruptures on a surface. During spreading, accumulated adhesion-induced (passive) stresses within the membrane drive changes in the spatial assembly of actin. By contrast, during rupture, accumulated myosin-induced (active) stresses within the cortex determine the rate of pore opening. Thus, in the same system, devoid of biochemical regulation, the membrane and cortex can each play a passive or active role in the generation and transmission of mechanical stress, and their relative roles drive diverse biomimetic physical behaviors. Visualization of F-actin within liposomes during their adhesion, spreading and rupture reveals mechanical interactions of membrane and cytoskeleton can lead to complex cellular assembly in absence of biochemical regulation. [ABSTRACT FROM AUTHOR]

Published

2023

4. Dysregulation of TSP2-Rac1-WAVE2 axis in diabetic cells leads to cytoskeletal disorganization, increased cell stiffness, and dysfunction.

Author

Xing, Hao, Huang, Yaqing, Kunkemoeller, Britta H., Dahl, Peter J., Muraleetharan, Ohvia, Malvankar, Nikhil S., Murrell, Michael P., and Kyriakides, Themis R.

Subjects

CELL populations, WOUND healing, F-actin, FIBROBLASTS, CYTOSKELETON, EXTRACELLULAR matrix

Abstract

Fibroblasts are a major cell population that perform critical functions in the wound healing process. In response to injury, they proliferate and migrate into the wound space, engaging in extracellular matrix (ECM) production, remodeling, and contraction. However, there is limited knowledge of how fibroblast functions are altered in diabetes. To address this gap, several state-of-the-art microscopy techniques were employed to investigate morphology, migration, ECM production, 2D traction, 3D contraction, and cell stiffness. Analysis of cell-derived matrix (CDM) revealed that diabetic fibroblasts produce thickened and less porous ECM that hindered migration of normal fibroblasts. In addition, diabetic fibroblasts were found to lose spindle-like shape, migrate slower, generate less traction force, exert limited 3D contractility, and have increased cell stiffness. These changes were due, in part, to a decreased level of active Rac1 and a lack of co-localization between F-actin and Waskott-Aldrich syndrome protein family verprolin homologous protein 2 (WAVE2). Interestingly, deletion of thrombospondin-2 (TSP2) in diabetic fibroblasts rescued these phenotypes and restored normal levels of active Rac1 and WAVE2-F-actin co-localization. These results provide a comprehensive view of the extent of diabetic fibroblast dysfunction, highlighting the regulatory role of the TSP2-Rac1-WAVE2-actin axis, and describing a new function of TSP2 in regulating cytoskeleton organization. [ABSTRACT FROM AUTHOR]

Published

2022

5. Detailed Balance Broken by Catch Bond Kinetics Enables Mechanical‐Adaptation in Active Materials.

Author

Tabatabai, Alan Pasha, Seara, Daniel S., Tibbs, Joseph, Yadav, Vikrant, Linsmeier, Ian, and Murrell, Michael P.

Subjects

MOLECULAR dynamics, ENERGY dissipation, BIOMATERIALS, CYTOSKELETON

Abstract

Unlike nearly all engineered materials which contain bonds that weaken under load, biological materials contain "catch" bonds which are reinforced under load. Consequently, materials, such as the cell cytoskeleton, can adapt their mechanical properties in response to their state of internal, non‐equilibrium (active) stress. However, how large‐scale material properties vary with the distance from equilibrium is unknown, as are the relative roles of active stress and binding kinetics in establishing this distance. Through course‐grained molecular dynamics simulations, the effect of breaking of detailed balance by catch bonds on the accumulation and dissipation of energy within a model of the actomyosin cytoskeleton is explored. It is found that the extent to which detailed balance is broken uniquely determines a large‐scale fluid‐solid transition with characteristic time‐reversal symmetries. The transition depends critically on the strength of the catch bond, suggesting that active stress is necessary but insufficient to mount an adaptive mechanical response. [ABSTRACT FROM AUTHOR]

Published

2021

6. Liposome adhesion generates traction stress.

Author

Murrell, Michael P., Voituriez, Raphaël, Joanny, Jean-François, Nassoy, Pierre, Sykes, Cécile, and Gardel, Margaret L.

Subjects

*POLARIZATION spectroscopy, *CYTOSKELETON, *LIPOSOMES, *HYDROSTATIC pressure, *CELL adhesion, *CELL membrane chemistry, *PHYSIOLOGY

Abstract

Mechanical forces generated by cells modulate global shape changes required for essential life processes, such as polarization, division and spreading. Although the contribution of the cytoskeleton to cellular force generation is widely recognized, the role of the membrane is considered to be restricted to passively transmitting forces. Therefore, the mechanisms by which the membrane can directly contribute to cell tension are overlooked and poorly understood. To address this, we directly measure the stresses generated during liposome adhesion. We find that liposome spreading generates large traction stresses on compliant substrates. These stresses can be understood as the equilibration of internal, hydrostatic pressures generated by the enhanced membrane tension built up during adhesion. These results underscore the role of membranes in the generation of mechanical stresses on cellular length scales and that the modulation of hydrostatic pressure due to membrane tension and adhesion can be channelled to perform mechanical work on the environment. [ABSTRACT FROM AUTHOR]

Published

2014

7. Distribution of directional change as a signature of complex dynamics.

Author

Burov, Stanislav, Ali Tabei, S. M., Toan Huynh, Murrell, Michael P., Philipson, Louis H., Rice, Stuart A., Gardel, Margaret L., Scherer, Norbert F., and Dinner, Aaron R.

Subjects

RANDOM walks, ANGULAR correlations (Nuclear physics), STOCHASTIC processes, MOLECULAR motor proteins, CYTOSKELETON

Abstract

Analyses of random walks traditionally use the mean square displacement (MSD) as an order parameter characterizing dynamics. We show that the distribution of relative angles of motion between successive time intervals of random walks in two or more dimensions provides information about stochastic processes beyond the MSD. We illustrate the behavior of this measure for common models and apply it to experimental particle tracking data. For a colloidal system, the distribution of relative angles reports sensitively on caging as the density varies. For transport mediated by molecular motors on filament networks in vitro and in vivo, we discover self-similar properties that cannot be described by existing models and discuss possible scenarios that can lead to the elucidated statistical features. [ABSTRACT FROM AUTHOR]

Published

2013

8. Filament Nucleation Tunes Mechanical Memory in Active Polymer Networks.

Author

Yadav, Vikrant, Banerjee, Deb S., Tabatabai, A. Pasha, Kovar, David R., Kim, Taeyoon, Banerjee, Shiladitya, and Murrell, Michael P.

Subjects

POLYMER networks, MICROFILAMENT proteins, NUCLEATION, FIBERS, CELL morphology, CYTOSKELETON

Abstract

Incorporating growth into contemporary material functionality presents a grand challenge in materials design. The F‐actin cytoskeleton is an active polymer network that serves as the mechanical scaffolding for eukaryotic cells, growing and remodeling in order to determine changes in cell shape. Nucleated from the membrane, filaments polymerize and grow into a dense network whose dynamics of assembly and disassembly, or "turnover," coordinates both fluidity and rigidity. Here, the extent of F‐actin nucleation is varied from a membrane surface in a biomimetic model of the cytoskeleton constructed from purified protein. It is found that nucleation of F‐actin mediates the accumulation and dissipation of polymerization‐induced F‐actin bending energy. At high and low nucleation, bending energies are low and easily relaxed yielding an isotropic material. However, at an intermediate critical nucleation, stresses are not relaxed by turnover and the internal energy accumulates 100‐fold. In this case, high filament curvatures template further assembly of F‐actin, driving the formation and stabilization of vortex‐like topological defects. Thus, nucleation coordinates mechanical and chemical timescales to encode shape memory into active materials. [ABSTRACT FROM AUTHOR]

Published

2019

9. Cofilin-mediated actin filament network flexibility facilitates 2D to 3D actomyosin shape change.

Author

Sun, Zachary Gao, Yadav, Vikrant, Amiri, Sorosh, Cao, Wenxiang, De La Cruz, Enrique M., and Murrell, Michael

Subjects

*ACTOMYOSIN, *ACTIN, *STRAINS & stresses (Mechanics), *FIBERS, *CELL morphology, *CONTRACTILE proteins, *MYOSIN, *POLYMER networks

Abstract

The organization of actin filaments (F-actin) into crosslinked networks determines the transmission of mechanical stresses within the cytoskeleton and subsequent changes in cell and tissue shape. Principally mediated by proteins such as α-actinin, F-actin crosslinking increases both network connectivity and rigidity, thereby facilitating stress transmission at low crosslinking yet attenuating transmission at high crosslinker concentration. Here, we engineer a two-dimensional model of the actomyosin cytoskeleton, in which myosin-induced mechanical stresses are controlled by light. We alter the extent of F-actin crosslinking by the introduction of oligomerized cofilin. At pH 6.5, F-actin severing by cofilin is weak, but cofilin bundles and crosslinks filaments. Given its effect of lowering the F-actin bending stiffness, cofilin- crosslinked networks are significantly more flexible and softer in bending than networks crosslinked by α-actinin. Thus, upon local activation of myosin-induced contractile stress, the network bends out-of-plane in contrast to the in-plane compression as observed with networks crosslinked by α-actinin. Here, we demonstrate that local effects on filament mechanics by cofilin introduces novel large-scale network material properties that enable the sculpting of complex shapes in the cell cytoskeleton. • Cofilin under low pH (pH<7) condition crosslinks and bundles F-actin. • Cofilin crosslinks/bundles actin filaments differently than α-actinin. • Under specific α-actinin and cofilin mix crosslinked condition, myosin activation causes cortex out-of-plane deformation. • The cortex deformation is due to competition between bending and compression. • New insights may impact applications to material design and essential biological events. [ABSTRACT FROM AUTHOR]

Published

2024