Your search keyword '"cell cortex"' showing total 19 results

1. Self-construction of actin networks through phase separation-induced abLIM1 condensates.

Author

Sen Yang, Chunxia Liu, Yuting Guo, Guoqing Li, Dong Li, Xiumin Yan, and Xueliang Zhu

Subjects

*ACTIN, *CARRIER proteins, *PLASMA stability, *F-actin, *PLASMA interactions

Abstract

The abLIM1 is a nonerythroid actin binding protein critical for stable plasma membrane-cortex interactions under mechanical tension. Its depletion by RNA interference results in sparse, poorly interconnected cortical actin networks and severe blebbing of migrating cells. Its isoforms, abLIM-L, abLIM-M, and abLIM-S, contain, respectively four, three, and no LIM domains, followed by a C terminus entirely homologous to erythroid cortex protein dematin. How abLIM1 functions, however, remains unclear. Here we show that abLIM1 is a liquid-liquid phase separation (LLPS)-dependent self-organizer of actin networks. Phase-separated condensates of abLIM-S-mimicking ΔLIM or the major isoform abLIM-M nucleated, flew along, and cross-linked together actin filaments (F-actin) to produce unique aster-like radial arrays and interconnected webs of F-actin bundles. Interestingly, ΔLIM condensates facilitated actin nucleation and network formation even in the absence of Mg2+. Our results suggest that abLIM1 functions as an LLPSdependent actin nucleator and cross-linker and provide insights into how LLPS-induced condensates could self-construct intracellular architectures of high connectivity and plasticity. [ABSTRACT FROM AUTHOR]

Published

2022

2. Spindle reorientation in response to mechanical stress is an emergent property of the spindle positioning mechanisms.

Author

Kelkar, Manasi, Bohec, Pierre, Smith, Matthew B., Sreenivasan, Varun, Lisica, Ana, Valon, Léo, Ferber, Emma, Baum, Buzz, Salbreux, Guillaume, and Charras, Guillaume

Subjects

*STRAINS & stresses (Mechanics), *SPINDLE apparatus, *ACTOMYOSIN, *OPTOGENETICS, *MICROTUBULES

Abstract

Proper orientation of the mitotic spindle plays a crucial role in embryos, during tissue development, and in adults, where it functions to dissipate mechanical stress to maintain tissue integrity and homeostasis. While mitotic spindles have been shown to reorient in response to external mechanical stresses, the subcellular cues that mediate spindle reorientation remain unclear. Here, we used a combination of optogenetics and computational modeling to investigate how mitotic spindles respond to inhomogeneous tension within the actomyosin cortex. Strikingly, we found that the optogenetic activation of RhoA only influences spindle orientation when it is induced at both poles of the cell. Under these conditions, the sudden local increase in cortical tension induced by RhoA activation reduces pulling forces exerted by cortical regulators on astral microtubules. This leads to a perturbation of the balance of torques exerted on the spindle, which causes it to rotate. Thus, spindle rotation in response to mechanical stress is an emergent phenomenon arising from the interaction between the spindle positioning machinery and the cell cortex. [ABSTRACT FROM AUTHOR]

Published

2022

3. Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortex.

Author

Huayin Wu, Yinan Shen, Sivagurunathan, Suganya, Weber, Miriam Sarah, Adam, Stephen A., Shin, Jennifer H., Fredberg, Jeffrey J., Medalia, Ohad, Goldman, Robert, and Weitz, David A.

Subjects

*CYTOPLASMIC filaments, *VIMENTIN, *ACTIN, *CELL morphology, *CELL polarity, *COMMERCIAL products

Abstract

The cytoskeleton of eukaryotic cells is primarily composed of networks of filamentous proteins, F-actin, microtubules, and intermediate filaments. Interactions among the cytoskeletal components are important in determining cell structure and in regulating cell functions. For example, F-actin and microtubules work together to control cell shape and polarity, while the subcellular organization and transport of vimentin intermediate filament (VIF) networks depend on their interactions with microtubules. However, it is generally thought that F-actin and VIFs form two coexisting but separate networks that are independent due to observed differences in their spatial distribution and functions. In this paper, we present a closer investigation of both the structural and functional interplay between the F-actin and VIF cytoskeletal networks. We characterize the structure of VIFs and F-actin networks within the cell cortex using structured illumination microscopy and cryoelectron tomography. We find that VIFs and F-actin form an interpenetrating network (IPN) with interactions at multiple length scales, and VIFs are integral components of F-actin stress fibers. From measurements of recovery of cell contractility after transient stretching, we find that the IPN structure results in enhanced contractile forces and contributes to cell resilience. Studies of reconstituted networks and dynamic measurements in cells suggest direct and specific associations between VIFs and F-actin. From these results, we conclude that VIFs and F-actin work synergistically, both in their structure and in their function. These results profoundly alter our understanding of the contributions of the components of the cytoskeleton, particularly the interactions between intermediate filaments and F-actin. [ABSTRACT FROM AUTHOR]

Published

2022

4. Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortex

Author

Stephen A. Adam, Yinan Shen, David A. Weitz, Suganya Sivagurunathan, Huayin Wu, Jennifer Hyunjong Shin, Ohad Medalia, Jeffrey J. Fredberg, Robert D. Goldman, Miriam Weber, University of Zurich, and Weitz, David A

Subjects

Cytoplasm, Electron Microscope Tomography, Cell, Intermediate Filaments, 610 Medicine & health, Vimentin, macromolecular substances, Filamentous actin, Mice, Biopolymers, Cell cortex, 10019 Department of Biochemistry, medicine, Animals, Intermediate filament, Cytoskeleton, Actin, Cells, Cultured, 1000 Multidisciplinary, Multidisciplinary, biology, Chemistry, Actins, Actin Cytoskeleton, medicine.anatomical_structure, Biophysics, biology.protein, 570 Life sciences

Abstract

The cytoskeleton of eukaryotic cells is primarily composed of networks of filamentous proteins, F-actin, microtubules, and intermediate filaments. Interactions among the cytoskeletal components are important in determining cell structure and in regulating cell functions. For example, F-actin and microtubules work together to control cell shape and polarity, while the subcellular organization and transport of vimentin intermediate filament (VIF) networks depend on their interactions with microtubules. However, it is generally thought that F-actin and VIFs form two coexisting but separate networks that are independent due to observed differences in their spatial distribution and functions. In this paper, we present a closer investigation of both the structural and functional interplay between the F-actin and VIF cytoskeletal networks. We characterize the structure of VIFs and F-actin networks within the cell cortex using structured illumination microscopy and cryo-electron tomography. We find that VIFs and F-actin form an interpenetrating network (IPN) with interactions at multiple length scales, and VIFs are integral components of F-actin stress fibers. From measurements of recovery of cell contractility after transient stretching, we find that the IPN structure results in enhanced contractile forces and contributes to cell resilience. Studies of reconstituted networks and dynamic measurements in cells suggest direct and specific associations between VIFs and F-actin. From these results, we conclude that VIFs and F-actin work synergistically, both in their structure and in their function. These results profoundly alter our understanding of the contributions of the components of the cytoskeleton, particularly the interactions between intermediate filaments and F-actin.

Published

2022

5. CYLD regulates spindle orientation by stabilizing astral microtubules and promoting dishevelled-NuMA-dynein/dynactin complex formation.

Author

Yunfan Yang, Min Liu, Dengwen Li, Jie Ran, Jinmin Gao, Shaojun Suo, Shao-Cong Sun, and Jun Zhou

Subjects

*CELL cycle, *UBIQUITIN, *CELL culture, *KNOCKOUT mice, *HOMEOSTASIS

Abstract

Oriented cell division is critical for cell fate specification, tissue organization, and tissue homeostasis, and relies on proper orientation of the mitotic spindle. The molecular mechanisms underlying the regulation of spindle orientation remain largely unknown. Herein, we identify a critical role for cylindromatosis (CYLD), a deubiquitinase and regulator of microtubule dynamics, in the control of spindle orientation. CYLD is highly expressed in mitosis and promotes spindle orientation by stabilizing astral microtubules and deubiquitinating the cortical polarity protein dishevelled. The deubiquitination of dishevelled enhances its interaction with nuclear mitotic apparatus, stimulating the cortical localization of nuclear mitotic apparatus and the dynein/dynactin motor complex, a requirement for generating pulling forces on astral microtubules. These findings uncover CYLD as an important player in the orientation of the mitotic spindle and cell division and have important implications in health and disease. [ABSTRACT FROM AUTHOR]

Published

2014

6. Self-construction of actin networks through phase separation-induced abLIM1 condensates.

Author

Yang S, Liu C, Guo Y, Li G, Li D, Yan X, and Zhu X

Subjects

Actin Cytoskeleton metabolism, Humans, Protein Isoforms genetics, Protein Isoforms metabolism, RNA Interference, Actins metabolism, LIM Domain Proteins genetics, LIM Domain Proteins metabolism, Microfilament Proteins genetics, Microfilament Proteins metabolism

Abstract

The abLIM1 is a nonerythroid actin-binding protein critical for stable plasma membrane-cortex interactions under mechanical tension. Its depletion by RNA interference results in sparse, poorly interconnected cortical actin networks and severe blebbing of migrating cells. Its isoforms, abLIM-L, abLIM-M, and abLIM-S, contain, respectively four, three, and no LIM domains, followed by a C terminus entirely homologous to erythroid cortex protein dematin. How abLIM1 functions, however, remains unclear. Here we show that abLIM1 is a liquid-liquid phase separation (LLPS)-dependent self-organizer of actin networks. Phase-separated condensates of abLIM-S-mimicking ΔLIM or the major isoform abLIM-M nucleated, flew along, and cross-linked together actin filaments (F-actin) to produce unique aster-like radial arrays and interconnected webs of F-actin bundles. Interestingly, ΔLIM condensates facilitated actin nucleation and network formation even in the absence of Mg 2+ . Our results suggest that abLIM1 functions as an LLPS-dependent actin nucleator and cross-linker and provide insights into how LLPS-induced condensates could self-construct intracellular architectures of high connectivity and plasticity.

Published

2022

7. Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortex.

Author

Wu H, Shen Y, Sivagurunathan S, Weber MS, Adam SA, Shin JH, Fredberg JJ, Medalia O, Goldman R, and Weitz DA

Subjects

Actin Cytoskeleton metabolism, Actins chemistry, Actins metabolism, Animals, Biopolymers metabolism, Cells, Cultured, Electron Microscope Tomography methods, Intermediate Filaments chemistry, Mice, Vimentin chemistry, Cytoplasm metabolism, Intermediate Filaments metabolism, Vimentin metabolism

Abstract

The cytoskeleton of eukaryotic cells is primarily composed of networks of filamentous proteins, F-actin, microtubules, and intermediate filaments. Interactions among the cytoskeletal components are important in determining cell structure and in regulating cell functions. For example, F-actin and microtubules work together to control cell shape and polarity, while the subcellular organization and transport of vimentin intermediate filament (VIF) networks depend on their interactions with microtubules. However, it is generally thought that F-actin and VIFs form two coexisting but separate networks that are independent due to observed differences in their spatial distribution and functions. In this paper, we present a closer investigation of both the structural and functional interplay between the F-actin and VIF cytoskeletal networks. We characterize the structure of VIFs and F-actin networks within the cell cortex using structured illumination microscopy and cryo-electron tomography. We find that VIFs and F-actin form an interpenetrating network (IPN) with interactions at multiple length scales, and VIFs are integral components of F-actin stress fibers. From measurements of recovery of cell contractility after transient stretching, we find that the IPN structure results in enhanced contractile forces and contributes to cell resilience. Studies of reconstituted networks and dynamic measurements in cells suggest direct and specific associations between VIFs and F-actin. From these results, we conclude that VIFs and F-actin work synergistically, both in their structure and in their function. These results profoundly alter our understanding of the contributions of the components of the cytoskeleton, particularly the interactions between intermediate filaments and F-actin.

Published

2022

8. Mechanical control of mitotic progression in single animal cells

Author

Cedric J. Cattin, Christoph Gerber, Daniel J. Müller, Martin P. Stewart, Marcel Düggelin, and David Martinez-Martin

Subjects

Cell, Mitosis, Spindle Apparatus, Biology, Microscopy, Atomic Force, Microtubules, Histones, Single-cell analysis, Microtubule, Cell cortex, medicine, Animals, Humans, Cell Shape, Multidisciplinary, Myosin Heavy Chains, Cell growth, Molecular Motor Proteins, Reproducibility of Results, Actomyosin, Biological Sciences, Spindle apparatus, Cell biology, Luminescent Proteins, medicine.anatomical_structure, Microscopy, Electron, Scanning, Single-Cell Analysis, Intracellular, HeLa Cells

Abstract

Despite the importance of mitotic cell rounding in tissue development and cell proliferation, there remains a paucity of approaches to investigate the mechanical robustness of cell rounding. Here we introduce ion beam-sculpted microcantilevers that enable precise force-feedback-controlled confinement of single cells while characterizing their progression through mitosis. We identify three force regimes according to the cell response: small forces (∼5 nN) that accelerate mitotic progression, intermediate forces where cells resist confinement (50-100 nN), and yield forces (>100 nN) where a significant decline in cell height impinges on microtubule spindle function, thereby inhibiting mitotic progression. Yield forces are coincident with a nonlinear drop in cell height potentiated by persistent blebbing and loss of cortical F-actin homogeneity. Our results suggest that a buildup of actomyosin-dependent cortical tension and intracellular pressure precedes mechanical failure, or herniation, of the cell cortex at the yield force. Thus, we reveal how the mechanical properties of mitotic cells and their response to external forces are linked to mitotic progression under conditions of mechanical confinement.

Published

2015

9. Fission yeast myosin Myo2 is down-regulated in actin affinity by light chain phosphorylation

Author

Susan Lowey, Elena B. Krementsova, Luther W. Pollard, Kathleen M. Trybus, Qing Tang, and Carol S. Bookwalter

Subjects

0301 basic medicine, Myosin Type V, Down-Regulation, Sf9, macromolecular substances, Biology, Myosins, 03 medical and health sciences, Contractile Proteins, Cell cortex, Myosin, Schizosaccharomyces, Amino Acid Sequence, Phosphorylation, Actin, Cytokinesis, Myosin Type II, Multidisciplinary, Myosin Heavy Chains, Microfilament Proteins, biology.organism_classification, Actins, Cell biology, Actin Cytoskeleton, Cytoskeletal Proteins, 030104 developmental biology, PNAS Plus, Chaperone (protein), Schizosaccharomyces pombe, biology.protein, Schizosaccharomyces pombe Proteins, Cell Division

Abstract

Studies in fission yeast Schizosaccharomyces pombe have provided the basis for the most advanced models of the dynamics of the cytokinetic contractile ring. Myo2, a class-II myosin, is the major source of tension in the contractile ring, but how Myo2 is anchored and regulated to produce force is poorly understood. To enable more detailed biochemical/biophysical studies, Myo2 was expressed in the baculovirus/Sf9 insect cell system with its two native light chains, Rlc1 and Cdc4. Milligram yields of soluble, unphosphorylated Myo2 were obtained that exhibited high actin-activated ATPase activity and in vitro actin filament motility. The fission yeast specific chaperone Rng3 was thus not required for expression or activity. In contrast to nonmuscle myosins from animal cells that require phosphorylation of the regulatory light chain for activation, phosphorylation of Rlc1 markedly reduced the affinity of Myo2 for actin. Another unusual feature of Myo2 was that, unlike class-II myosins, which generally form bipolar filamentous structures, Myo2 showed no inclination to self-assemble at approximately physiological salt concentrations, as analyzed by sedimentation velocity ultracentrifugation. This lack of assembly supports the hypothesis that clusters of Myo2 depend on interactions at the cell cortex in structural units called nodes for force production during cytokinesis.

Published

2017

10. A RhoA and Rnd3 cycle regulates actin reassembly during membrane blebbing

Author

Kana Aoki, Tomoya Nagasako, Junichi Ikenouchi, Yuki Mochizuki, Fumiyo Maeda, and Seiichi Uchida

Subjects

0301 basic medicine, rho GTP-Binding Proteins, genetic structures, Green Fluorescent Proteins, Arp2/3 complex, macromolecular substances, Cell Line, 03 medical and health sciences, Actin remodeling of neurons, Ezrin, Cell cortex, Humans, Bleb (cell biology), Cytoskeleton, Adaptor Proteins, Signal Transducing, Feedback, Physiological, rho-Associated Kinases, Multidisciplinary, biology, Cell Membrane, Actin remodeling, Actin cytoskeleton, eye diseases, Cell biology, Actin Cytoskeleton, Cytoskeletal Proteins, 030104 developmental biology, Microscopy, Fluorescence, PNAS Plus, biology.protein, sense organs, rhoA GTP-Binding Protein

Abstract

The actin cytoskeleton usually lies beneath the plasma membrane. When the membrane-associated actin cytoskeleton is transiently disrupted or the intracellular pressure is increased, the plasma membrane detaches from the cortex and protrudes. Such protruded membrane regions are called blebs. However, the molecular mechanisms underlying membrane blebbing are poorly understood. This study revealed that epidermal growth factor receptor kinase substrate 8 (Eps8) and ezrin are important regulators of rapid actin reassembly for the initiation and retraction of protruded blebs. Live-cell imaging of membrane blebbing revealed that local reassembly of actin filaments occurred at Eps8- and activated ezrin-positive foci of membrane blebs. Furthermore, we found that a RhoA-ROCK-Rnd3 feedback loop determined the local reassembly sites of the actin cortex during membrane blebbing.

Published

2016

11. Cell-sized liposomes reveal how actomyosin cortical tension drives shape change

Author

Raphaël Voituriez, Feng-Ching Tsai, Edouard Lees, Kevin Carvalho, Cécile Sykes, and Gijsje H. Koenderink

Subjects

Multidisciplinary, Molecular Motor Proteins, macromolecular substances, Actomyosin, Biology, Biological Sciences, Cell biology, Cell membrane, medicine.anatomical_structure, Microscopy, Fluorescence, Cell polarity, Myosin, Cell cortex, Liposomes, Molecular motor, medicine, Animals, Rabbits, Cytoskeleton, Cell Shape, Cytokinesis, Actin

Abstract

Animal cells actively generate contractile stress in the actin cortex, a thin actin network beneath the cell membrane, to facilitate shape changes during processes like cytokinesis and motility. On the microscopic scale, this stress is generated by myosin molecular motors, which bind to actin cytoskeletal filaments and use chemical energy to exert pulling forces. To decipher the physical basis for the regulation of cell shape changes, here, we use a cell-like system with a cortex anchored to the outside or inside of a liposome membrane. This system enables us to dissect the interplay between motor pulling forces, cortex–membrane anchoring, and network connectivity. We show that cortices on the outside of liposomes either spontaneously rupture and relax built-up mechanical stress by peeling away around the liposome or actively compress and crush the liposome. The decision between peeling and crushing depends on the cortical tension determined by the amount of motors and also on the connectivity of the cortex and its attachment to the membrane. Membrane anchoring strongly affects the morphology of cortex contraction inside liposomes: cortices contract inward when weakly attached, whereas they contract toward the membrane when strongly attached. We propose a physical model based on a balance of active tension and mechanical resistance to rupture. Our findings show how membrane attachment and network connectivity are able to regulate actin cortex remodeling and membrane-shape changes for cell polarization.

Published

2013

12. Calcium oscillations-coupled conversion of actin travelling waves to standing oscillations

Author

Xudong Wu, Min Wu, and Pietro De Camilli

Subjects

Arp2/3 complex, Actin remodeling of neurons, Phosphatidylinositol Phosphates, Cell Line, Tumor, Cell cortex, Animals, Calcium Signaling, Mast Cells, Antigens, Cytoskeleton, cdc42 GTP-Binding Protein, Feedback, Physiological, Multidisciplinary, Microscopy, Video, biology, Actin remodeling, Biological Sciences, Actin cytoskeleton, Actins, Cell biology, Rats, Actin Cytoskeleton, Profilin, Microscopy, Fluorescence, biology.protein, MDia1, Carrier Proteins

Abstract

Dynamic spatial patterns of signaling factors or macromolecular assemblies in the form of oscillations or traveling waves have emerged as important themes in cell physiology. Feedback mechanisms underlying these processes and their modulation by signaling events and reciprocal cross-talks remain poorly understood. Here we show that antigen stimulation of mast cells triggers cyclic changes in the concentration of actin regulatory proteins and actin in the cell cortex that can be manifested in either spatial pattern. Recruitment of FBP17 and active Cdc42 at the plasma membrane, leading to actin polymerization, are involved in both events, whereas calcium oscillations, which correlate with global fluctuations of plasma membrane PI(4,5)P 2 , are tightly linked to standing oscillations and counteract wave propagation. These findings demonstrate the occurrence of a calcium-independent oscillator that controls the collective dynamics of factors linking the actin cytoskeleton to the plasma membrane. Coupling between this oscillator and the one underlying global plasma membrane PI(4,5)P2 and calcium oscillations spatially regulates actin dynamics, revealing an unexpected pattern-rendering mechanism underlying plastic changes occurring in the cortical region of the cell.

Published

2013

13. Control of cell membrane tension by myosin-I

Author

Rajalakshmi Nambiar, Matthew J. Tyska, and Russell E. McConnell

Subjects

Optical Tweezers, Cell Survival, Recombinant Fusion Proteins, Green Fluorescent Proteins, Biology, Endocytosis, Transfection, Exocytosis, Motor protein, Cell membrane, Mice, Cell cortex, medicine, Cell Adhesion, Animals, Cytoskeleton, Mice, Knockout, Multidisciplinary, Microscopy, Confocal, Microvilli, Myosin Heavy Chains, Cell Membrane, Epithelial Cells, Membrane transport, Fibroblasts, Biological Sciences, Actin cytoskeleton, Cell biology, Biomechanical Phenomena, medicine.anatomical_structure, NIH 3T3 Cells

Abstract

All cell functions that involve membrane deformation or a change in cell shape (e.g., endocytosis, exocytosis, cell motility, and cytokinesis) are regulated by membrane tension. While molecular contacts between the plasma membrane and the underlying actin cytoskeleton are known to make significant contributions to membrane tension, little is known about the molecules that mediate these interactions. We used an optical trap to directly probe the molecular determinants of membrane tension in isolated organelles and in living cells. Here, we show that class I myosins, a family of membrane-binding, actin-based motor proteins, mediate membrane/cytoskeleton adhesion and thus, make major contributions to membrane tension. These studies show that class I myosins directly control the mechanical properties of the cell membrane; they also position these motor proteins as master regulators of cellular events involving membrane deformation.

Published

2009

14. Endosomal recycling controls plasma membrane area during mitosis

Author

Emmanuel Boucrot and Tomas Kirchhausen

Subjects

Multidisciplinary, Cell division, Cell Membrane, Golgi Apparatus, Mitosis, Cell plate, Endosomes, Biology, Biological Sciences, Exocytosis, Clathrin, Endocytosis, Cell biology, Cell membrane, medicine.anatomical_structure, Cell cortex, medicine, Humans, Cell Shape, Cytokinesis, Secretory pathway, Cell Size, HeLa Cells

Abstract

The shape and total surface of a cell and its daughters change during mitosis. Many cells round up during prophase and metaphase and reacquire their extended and flattened shape during cytokinesis. How does the total area of plasma membrane change to accommodate these morphological changes and by what mechanism is control of total membrane area achieved? Using single-cell imaging methods, we have found that the amount of plasma membrane in attached cells in culture decreases at the beginning of mitosis and recovers rapidly by the end. Clathrin-based endocytosis is normal throughout all phases of cell division, whereas recycling of internalized membranes back to the cell surface slows considerably during the rounding up period and resumes at the time at which recovery of cell membrane begins. Interference with either one of these processes by genetic or chemical means impairs cell division. The total cell-membrane area recovers even in the absence of a functional Golgi apparatus, which would be needed for export of newly synthesized membrane lipids and proteins. We propose a mechanism by which modulation of endosomal recycling controls cell area and surface expression of membrane-bound proteins during cell division.

Published

2007

15. Dictyostelium myosin II mechanochemistry promotes active behavior of the cortex on long time scales

Author

Scot C. Kuo, Douglas N. Robinson, and Kristine D. Girard

Subjects

Myosin Type II, Multidisciplinary, biology, Motility, Anatomy, macromolecular substances, Biological Sciences, Microfilament, biology.organism_classification, Dictyostelium, Biomechanical Phenomena, medicine.anatomical_structure, Cell Movement, Cortex (anatomy), Cell cortex, Myosin, medicine, Biophysics, Animals, Cytokinesis, Actin

Abstract

Cell cortices rearrange dynamically to complete cytokinesis, crawlin response to chemoattractant, build tissues, and make neuronal connections. Highly enriched in the cell cortex, actin, myosin II, and actin crosslinkers facilitate cortical movements. Because cortical behavior is the consequence of nanoscale biochemical events, it is essential to probe the cortex at this level. Here, we use high-resolution laser-based particle tracking to examine how myosin II mechanochemistry and dynacortin-mediated actin crosslinking control cortex dynamics in Dictyostelium . Consistent with its low duty ratio, myosin II does not directly drive active bead motility. Instead, myosin II and dynacortin antagonistically regulate other active processes in the living cortex.

Published

2006

16. Distinct pathways control recruitment and maintenance of myosin II at the cleavage furrow during cytokinesis

Author

James A. Spudich, Stephen L. Rogers, Nico Stuurman, Ronald D. Vale, and Sara O. Dean

Subjects

Myosin Type II, Multidisciplinary, Myosin light-chain kinase, macromolecular substances, Centralspindlin complex, Biology, Biological Sciences, Cell biology, Cell Line, Cell cortex, Myosin, Animals, Drosophila Proteins, Cleavage furrow, Drosophila, Phosphorylation, Mitosis, Protein Processing, Post-Translational, Cytokinesis, Actin nucleation, Signal Transduction

Abstract

The correct localization of myosin II to the equatorial cortex is crucial for proper cell division. Here, we examine a collection of genes that cause defects in cytokinesis and reveal with live cell imaging two distinct phases of myosin II localization. Three genes in the rho1 signaling pathway, pebble (a Rho guanidine nucleotide exchange factor), rho1 , and rho kinase , are required for the initial recruitment of myosin II to the equatorial cortex. This initial localization mechanism does not require F-actin or the two components of the centralspindlin complex, the mitotic kinesin pavarotti/MKLP1 and racGAP50c/CYK-4. However, F-actin, the centralspindlin complex, formin ( diaphanous ), and profilin ( chickadee ) are required to stably maintain myosin II at the furrow. In the absence of these latter genes, myosin II delocalizes from the equatorial cortex and undergoes highly dynamic appearances and disappearances around the entire cell cortex, sometimes associated with abnormal contractions or blebbing. Our findings support a model in which a rho kinase-dependent event, possibly myosin II regulatory light chain phosphorylation, is required for the initial recruitment to the furrow, whereas the assembly of parallel, unbranched actin filaments, generated by formin-mediated actin nucleation, is required for maintaining myosin II exclusively at the equatorial cortex.

Published

2005

17. Mechanical control of mitotic progression in single animal cells.

Author

Cattin CJ, Düggelin M, Martinez-Martin D, Gerber C, Müller DJ, and Stewart MP

Subjects

Actomyosin metabolism, Animals, Cell Shape, HeLa Cells, Histones genetics, Histones metabolism, Humans, Luminescent Proteins genetics, Luminescent Proteins metabolism, Microscopy, Atomic Force, Microscopy, Electron, Scanning, Microtubules metabolism, Molecular Motor Proteins genetics, Molecular Motor Proteins metabolism, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Reproducibility of Results, Mitosis, Single-Cell Analysis instrumentation, Single-Cell Analysis methods, Spindle Apparatus metabolism

Abstract

Despite the importance of mitotic cell rounding in tissue development and cell proliferation, there remains a paucity of approaches to investigate the mechanical robustness of cell rounding. Here we introduce ion beam-sculpted microcantilevers that enable precise force-feedback-controlled confinement of single cells while characterizing their progression through mitosis. We identify three force regimes according to the cell response: small forces (∼5 nN) that accelerate mitotic progression, intermediate forces where cells resist confinement (50-100 nN), and yield forces (>100 nN) where a significant decline in cell height impinges on microtubule spindle function, thereby inhibiting mitotic progression. Yield forces are coincident with a nonlinear drop in cell height potentiated by persistent blebbing and loss of cortical F-actin homogeneity. Our results suggest that a buildup of actomyosin-dependent cortical tension and intracellular pressure precedes mechanical failure, or herniation, of the cell cortex at the yield force. Thus, we reveal how the mechanical properties of mitotic cells and their response to external forces are linked to mitotic progression under conditions of mechanical confinement.

Published

2015

18. CYLD regulates spindle orientation by stabilizing astral microtubules and promoting dishevelled-NuMA-dynein/dynactin complex formation.

Author

Yang Y, Liu M, Li D, Ran J, Gao J, Suo S, Sun SC, and Zhou J

Subjects

Animals, Cell Cycle Proteins, Deubiquitinating Enzyme CYLD, Dynactin Complex, HeLa Cells, Humans, Mice, Mice, Knockout, Microscopy, Fluorescence, Antigens, Nuclear metabolism, Dyneins metabolism, Microtubule-Associated Proteins metabolism, Microtubules metabolism, Nuclear Matrix-Associated Proteins metabolism, Spindle Apparatus physiology, Tumor Suppressor Proteins physiology

Abstract

Oriented cell division is critical for cell fate specification, tissue organization, and tissue homeostasis, and relies on proper orientation of the mitotic spindle. The molecular mechanisms underlying the regulation of spindle orientation remain largely unknown. Herein, we identify a critical role for cylindromatosis (CYLD), a deubiquitinase and regulator of microtubule dynamics, in the control of spindle orientation. CYLD is highly expressed in mitosis and promotes spindle orientation by stabilizing astral microtubules and deubiquitinating the cortical polarity protein dishevelled. The deubiquitination of dishevelled enhances its interaction with nuclear mitotic apparatus, stimulating the cortical localization of nuclear mitotic apparatus and the dynein/dynactin motor complex, a requirement for generating pulling forces on astral microtubules. These findings uncover CYLD as an important player in the orientation of the mitotic spindle and cell division and have important implications in health and disease.

Published

2014

19. Transit of pp60v-src to the plasma membrane

Author

Sara A. Courtneidge and J M Bishop

Subjects

Vesicle-associated membrane protein 8, animal structures, Macromolecular Substances, Chick Embryo, Biology, Avian sarcoma virus, Oncogene Protein pp60(v-src), Cell membrane, Viral Proteins, Cell cortex, medicine, Animals, Kinase activity, Protein kinase A, Cells, Cultured, Multidisciplinary, Cell Membrane, Biological Transport, Phosphoproteins, Cell biology, Cell Compartmentation, Molecular Weight, medicine.anatomical_structure, Avian Sarcoma Viruses, Solubility, Cytoplasm, Polyribosomes, Mutation, Protein Kinases, Proto-oncogene tyrosine-protein kinase Src, Research Article

Abstract

The protein kinase (pp60v-src) encoded by the transforming gene (v-src) of Rous sarcoma virus is synthesized on free polyribosomes and then translocated to the plasma membrane of infected cells. Neither the mechanism of the translocation nor the physiological significance of the membrane localization has been elucidated. We have explored these problems by pursuing previous observations of a complex between pp60v-src and two cellular proteins with molecular weights of 50,000 and 89,000. We found the complex located entirely in the cytoplasm, where it appears to form immediately after the synthesis of pp60v-src. While in the complex, pp60v-src has little detectable kinase activity and is phosphorylated predominantly on serine. After transfer from the complex to the plasma membrane, pp60v-src becomes phosphorylated on tyrosine as well as serine and acquires kinase activity. Under restrictive conditions, temperature-sensitive pp60v-src is produced in normal quantities, but translocation to the plasma membrane is diminished. As an apparent consequence, the cytoplasmic complex accumulates to abnormal abundance. Alternatively, temperature-sensitive pp60v-src that has been synthesized and translocated to the plasma membrane under permissive conditions appears to be released from the membrane and returns to the cytoplasmic complex when the infected cells are shifted to the restrictive temperature. We conclude that the cytoplasmic complex may be the vehicle by which pp60v-src reaches the plasma membrane. It is possible that other proteins may follow a similar route to the membrane. Binding to plasma membrane appears to be a discrete step in the biogenesis of pp60v-src and may be essential to the function of the protein.

Published

1982