Your search keyword '"actomyosin contraction"' showing total 24 results

1. Actomyosin contraction in the follicular epithelium provides the major mechanical force for follicle rupture during Drosophila ovulation.

Author

Cho, Stella E., Wei Li, Beard, Andrew M., Jackson, Jonathan A., Kiernan, Risa, Kazunori Hoshino, Martin, Adam C., and Jianjun Sun

Subjects

*SOMATIC cells, *GUANOSINE triphosphate, *PROTEOLYSIS, *ACTOMYOSIN, *OVULATION

Abstract

Ovulation is critical for sexual reproduction and consists of the process of liberating fertilizable oocytes from their somatic follicle capsules, also known as follicle rupture. The mechanical force for oocyte expulsion is largely unknown in many species. Our previous work demonstrated that Drosophila ovulation, as in mammals, requires the proteolytic degradation of the posterior follicle wall and follicle rupture to release the mature oocyte from a layer of somatic follicle cells. Here, we identified actomyosin contraction in somatic follicle cells as the major mechanical force for follicle rupture. Filamentous actin (F-actin) and nonmuscle myosin II (NMII) are highly enriched in the cortex of follicle cells upon stimulation with octopamine (OA), a monoamine critical for Drosophila ovulation. Pharmacological disruption of F-actin polymerization prevented follicle rupture without interfering with the follicle wall breakdown. In addition, we demonstrated that OA induces Rho1 guanosine triphosphate (GTP)ase activation in the follicle cell cortex, which activates Ras homolog (Rho) kinase to promote actomyosin contraction and follicle rupture. All these results led us to conclude that OA signaling induces actomyosin cortex enrichment and contractility, which generates the mechanical force for follicle rupture during Drosophila ovulation. Due to the conserved nature of actomyosin contraction, this work could shed light on the mechanical force required for follicle rupture in other species including humans. [ABSTRACT FROM AUTHOR]

Published

2024

2. Unique osteogenic profile of bone marrow stem cells stimulated in perfusion bioreactor is Rho-ROCK-mediated contractility dependent.

Author

Yamada, Shuntaro, Yassin, Mohammed, Torelli, Francesco, Hansmann, Jan, Green, Jeremy, Schwarz, Thomas, and Mustafa, Kamal

Subjects

Rho GTPase signaling, actomyosin contraction, bioreactor, bone tissue engineering, fluid shear stress, osteogenic differentiation

Abstract

The fate determination of bone marrow mesenchymal stem/stromal cells (BMSC) is tightly regulated by mechanical cues, including fluid shear stress. Knowledge of mechanobiology in 2D culture has allowed researchers in bone tissue engineering to develop 3D dynamic culture systems with the potential for clinical translation in which the fate and growth of BMSC are mechanically controlled. However, due to the complexity of 3D dynamic cell culture compared to the 2D counterpart, the mechanisms of cell regulation in the dynamic environment remain relatively undescribed. In the present study, we analyzed the cytoskeletal modulation and osteogenic profiles of BMSC under fluid stimuli in a 3D culture condition using a perfusion bioreactor. BMSC subjected to fluid shear stress (mean 1.56 mPa) showed increased actomyosin contractility, accompanied by the upregulation of mechanoreceptors, focal adhesions, and Rho GTPase-mediated signaling molecules. Osteogenic gene expression profiling revealed that fluid shear stress promoted the expression of osteogenic markers differently from chemically induced osteogenesis. Osteogenic marker mRNA expression, type 1 collagen formation, ALP activity, and mineralization were promoted in the dynamic condition, even in the absence of chemical supplementation. The inhibition of cell contractility under flow by Rhosin chloride, Y27632, MLCK inhibitor peptide-18, or Blebbistatin revealed that actomyosin contractility was required for maintaining the proliferative status and mechanically induced osteogenic differentiation in the dynamic culture. The study highlights the cytoskeletal response and unique osteogenic profile of BMSC in this type of dynamic cell culture, stepping toward the clinical translation of mechanically stimulated BMCS for bone regeneration.

Published

2023

3. Low-dose albumin-coated gold nanorods induce intercellular gaps on vascular endothelium by causing the contraction of cytoskeletal actin.

Author

Li, Zhengqiang, Liu, Jinyuan, Ballard, Katherine, Liang, Chao, and Wang, Congzhou

Subjects

*VASCULAR endothelium, *NANORODS, *ACTIN, *ATOMIC force microscopy, *CELL morphology, *ENDOTHELIUM, *CARDIOVASCULAR system

Abstract

[Display omitted] Cytotoxicity of nanoparticles, typically evaluated by biochemical-based assays, often overlook the cellular biophysical properties such as cell morphology and cytoskeletal actin, which could serve as more sensitive indicators for cytotoxicity. Here, we demonstrate that low-dose albumin-coated gold nanorods (HSA@AuNRs), although being considered noncytotoxic in multiple biochemical assays, can induce intercellular gaps and enhance the paracellular permeability between human aortic endothelial cells (HAECs). The formation of intercellular gaps can be attributed to the changed cell morphology and cytoskeletal actin structures, as validated at the monolayer and single cell levels using fluorescence staining, atomic force microscopy, and super-resolution imaging. Molecular mechanistic study shows the caveolae-mediated endocytosis of HSA@AuNRs induces the calcium influx and activates actomyosin contraction in HAECs. Considering the important roles of endothelial integrity/dysfunction in various physiological/pathological conditions, this work suggests a potential adverse effect of albumin-coated gold nanorods on the cardiovascular system. On the other hand, this work also offers a feasible way to modulate the endothelial permeability, thus promoting drug and nanoparticle delivery across the endothelium. [ABSTRACT FROM AUTHOR]

Published

2023

4. Unique osteogenic profile of bone marrow stem cells stimulated in perfusion bioreactor is Rho‐ROCK‐mediated contractility dependent

Author

Shuntaro Yamada, Mohammed A. Yassin, Francesco Torelli, Jan Hansmann, Jeremy B. A. Green, Thomas Schwarz, and Kamal Mustafa

Subjects

actomyosin contraction, bioreactor, bone tissue engineering, fluid shear stress, osteogenic differentiation, Rho GTPase signaling, Chemical engineering, TP155-156, Biotechnology, TP248.13-248.65, Therapeutics. Pharmacology, RM1-950

Abstract

Abstract The fate determination of bone marrow mesenchymal stem/stromal cells (BMSC) is tightly regulated by mechanical cues, including fluid shear stress. Knowledge of mechanobiology in 2D culture has allowed researchers in bone tissue engineering to develop 3D dynamic culture systems with the potential for clinical translation in which the fate and growth of BMSC are mechanically controlled. However, due to the complexity of 3D dynamic cell culture compared to the 2D counterpart, the mechanisms of cell regulation in the dynamic environment remain relatively undescribed. In the present study, we analyzed the cytoskeletal modulation and osteogenic profiles of BMSC under fluid stimuli in a 3D culture condition using a perfusion bioreactor. BMSC subjected to fluid shear stress (mean 1.56 mPa) showed increased actomyosin contractility, accompanied by the upregulation of mechanoreceptors, focal adhesions, and Rho GTPase‐mediated signaling molecules. Osteogenic gene expression profiling revealed that fluid shear stress promoted the expression of osteogenic markers differently from chemically induced osteogenesis. Osteogenic marker mRNA expression, type 1 collagen formation, ALP activity, and mineralization were promoted in the dynamic condition, even in the absence of chemical supplementation. The inhibition of cell contractility under flow by Rhosin chloride, Y27632, MLCK inhibitor peptide‐18, or Blebbistatin revealed that actomyosin contractility was required for maintaining the proliferative status and mechanically induced osteogenic differentiation in the dynamic culture. The study highlights the cytoskeletal response and unique osteogenic profile of BMSC in this type of dynamic cell culture, stepping toward the clinical translation of mechanically stimulated BMCS for bone regeneration.

Published

2023

5. Differences in creep response of GBM cells migrating in confinement

Author

Ishan Khan, Loan Bui, Robert Bachoo, Young-Tae Kim, and Cheng-Jen Chuong

Subjects

cancer cell, glioblastoma, viscoelastic properties, creep, actomyosin contraction, Biotechnology, TP248.13-248.65, Physiology, QP1-981

Abstract

Using a microfluidic platform to apply negative aspiration pressure (–20, –25, –30, –35 and –40 cm H2O), we compared the differences in creep responses of Glioblastoma Multiforme (GBM) cells while migrating in confinement and at a stationary state on a 2D substrate. Cells were either migrating in a channel of 5 x 5 μm cross-section or stationary at the entrance to the channel. In response to aspiration pressure, we found actively migrating GBM cells exhibited a higher stiffness than stationary cells. Additionally, migrating cells absorbed more energy elastically with a relatively small dissipative energy loss. At elevated negative pressure loads up to – 30 cm H2O, we observed a linear increase in elastic deformation and a higher distribution in elastic storage than energy loss, and the response plateaued at further increasing negative pressure loads. To explore the underlying cause, we carried out immuno-cytochemical studies of these cells and found a polarized actin and myosin distribution at the front and posterior ends of the migrating cells, whereas the distribution of the stationary group demonstrated no specific regional differences. These differences in creep response and cytoskeletal protein distribution demonstrate the importance of a migrating cell’s kinematic state to the mechanism of cell migration.

Published

2020

6. Calcium waves facilitate and coordinate the contraction of endfeet actin stress fibers in Drosophila interommatidial cells.

Author

Ready, Donald F. and Chang, Henry C.

Subjects

*DROSOPHILA, *ACTIN, *FIBERS, *STRESS waves, *CALCIUM, *PHOTORECEPTORS

Abstract

Actomyosin contraction shapes the Drosophila eye's panoramic view. The convex curvature of the retinal epithelium, organized in ~800 close-packed ommatidia, depends upon a fourfold condensation of the retinal floor mediated by contraction of actin stress fibers in the endfeet of interommatidial cells (IOCs). How these tensile forces are coordinated is not known. Here, we discover a previously unobserved phenomenon: Ca2+ waves regularly propagate across the IOC network in pupal and adult eyes. Genetic evidence demonstrates that IOC waves are independent of phototransduction, but require the inositol 1,4,5-triphosphate receptor (IP3R), suggesting that these waves are mediated by Ca2+ releases from endoplasmic reticulum stores. Removal of IP3R disrupts stress fibers in IOC endfeet and increases the basal retinal surface by ~40%, linking IOC waves to facilitation of stress fiber contraction and floor morphogenesis. Furthermore, IP3R loss disrupts the organization of a collagen IV network underneath the IOC endfeet, implicating the extracellular matrix and its interaction with stress fibers in eye morphogenesis. We propose that coordinated cytosolic Ca2+ increases in IOC waves promote stress fiber contractions, ensuring an organized application of the planar tensile forces that condense the retinal floor. This article has an associated 'The people behind the papers' interview. [ABSTRACT FROM AUTHOR]

Published

2021

7. Homophilic and heterophilic cadherin bond rupture forces in homo- or hetero-cellular systems measured by AFM-based single-cell force spectroscopy.

Author

Viji Babu, Prem Kumar, Mirastschijski, Ursula, Belge, Ganzanfer, and Radmacher, Manfred

Subjects

*ADHERENS junctions, *CELL junctions, *SINGLE molecules, *ATOMIC force microscopy, *CARRIER proteins, *CADHERINS, *PROTEIN conformation

Abstract

Cadherins enable intercellular adherens junctions to withstand tensile forces in tissues, e.g. generated by intracellular actomyosin contraction. In-vitro single molecule force spectroscopy experiments can reveal cadherin–cadherin extracellular region binding dynamics such as bond formation and strength. However, characterization of cadherin-presenting cell homophilic and heterophilic binding in the proteins' native conformational and functional states in living cells has rarely been done. Here, we used atomic force microscopy (AFM) based single-cell force spectroscopy (SCFS) to measure rupture forces of homophilic and heterophilic bond formation of N- (neural), OB- (osteoblast) and E- (epithelial) cadherins in living fibroblast and epithelial cells in homo- and hetero-cellular arrangements, i.e., between cells and cadherins of the same and different types. In addition, we used indirect immunofluorescence labelling to study and correlate the expression of these cadherins in intercellular adherens junctions. We showed that N/N and E/E-cadherin homophilic binding events are stronger than N/OB heterophilic binding events. Disassembly of intracellular actin filaments affects the cadherin bond rupture forces suggesting a contribution of actin filaments in cadherin extracellular binding. Inactivation of myosin did not affect the cadherin rupture force in both homo- and hetero-cellular arrangements, but particularly strengthened the N/OB heterophilic bond and reinforced the other cadherins' homophilic bonds. [ABSTRACT FROM AUTHOR]

Published

2021

8. Kindlin-2 promotes rear focal adhesion disassembly and directional persistence during cell migration.

Author

Jie Liu, Zhongzhen Liu, Keng Chen, Wei Chen, Xiyuan Fang, Meng Li, Xuening Zhou, Ning Ding, Huan Lei, Chen Guo, Tao Qian, Yilin Wang, Lin Liu, Yonglong Chen, Hui Zhao, Ying Sun, Yi Deng, and Chuanyue Wu

Subjects

*FOCAL adhesions, *MYOSIN light chain kinase, *CELL migration, *AMINO acid residues, *CONTRACTILITY (Biology)

Abstract

Cell migration involves front-to-rear asymmetric focal adhesion (FA) dynamics, which facilitates trailing edge detachment and directional persistence. Here, we show that kindlin-2 is crucial for FA sliding and disassembly in migrating cells. Loss of kindlin-2 markedly reduced FA number and selectively impaired rear FA sliding and disassembly, resulting in defective rear retraction and reduced directional persistence during cell migration. Kindlin-2-deficient cells failed to develop seruminduced actomyosin-dependent tension at FAs. At the molecular level, kindlin-2 directly interacted with myosin light chain kinase (MYLK, hereafter referred to as MLCK), which was enhanced in response to serum stimulation. Serum deprivation inhibited rear FA disassembly, which was released in response to serum stimulation. Overexpression of the MLCK-binding kindlin-2 F0F1 fragment (amino acid residues 1–167), which inhibits the interaction of endogenous kindlin-2 with MLCK, phenocopied kindlin-2 deficiency-induced migration defects. Inhibition of MLCK, like loss of kindlin-2, also impaired trailing-edge detachment, rear FA disassembly and directional persistence. These results suggest a role of kindlin-2 in promoting actomyosin contractility at FAs, leading to increased rear FA sliding and disassembly, and directional persistence during cell migration. [ABSTRACT FROM AUTHOR]

Published

2021

9. Differences in creep response of GBM cells migrating in confinement.

Author

Khan, Ishan, Bui, Loan, Bachoo, Robert, Kim, Young-Tae, and Chuong, Cheng-Jen

Subjects

GLIOBLASTOMA multiforme, CYTOSKELETAL proteins, CELL migration, ELASTIC deformation, MYOSIN, ENERGY storage

Abstract

Using a microfluidic platform to apply negative aspiration pressure (–20, –25, –30, –35 and –40 cm H2O), we compared the differences in creep responses of Glioblastoma Multiforme (GBM) cells while migrating in confinement and at a stationary state on a 2D substrate. Cells were either migrating in a channel of 5 x 5 μm cross-section or stationary at the entrance to the channel. In response to aspiration pressure, we found actively migrating GBM cells exhibited a higher stiffness than stationary cells. Additionally, migrating cells absorbed more energy elastically with a relatively small dissipative energy loss. At elevated negative pressure loads up to – 30 cm H2O, we observed a linear increase in elastic deformation and a higher distribution in elastic storage than energy loss, and the response plateaued at further increasing negative pressure loads. To explore the underlying cause, we carried out immuno-cytochemical studies of these cells and found a polarized actin and myosin distribution at the front and posterior ends of the migrating cells, whereas the distribution of the stationary group demonstrated no specific regional differences. These differences in creep response and cytoskeletal protein distribution demonstrate the importance of a migrating cell's kinematic state to the mechanism of cell migration. [ABSTRACT FROM AUTHOR]

Published

2020

10. Centering and symmetry breaking in confined contracting actomyosin networks

Author

Niv Ierushalmi, Maya Malik-Garbi, Angelika Manhart, Enas Abu Shah, Bruce L Goode, Alex Mogilner, and Kinneret Keren

Subjects

actomyosin contraction, artificial cell, subcellular localization, centering, symmetry breaking, Medicine, Science, Biology (General), QH301-705.5

Abstract

Centering and decentering of cellular components is essential for internal organization of cells and their ability to perform basic cellular functions such as division and motility. How cells achieve proper localization of their organelles is still not well-understood, especially in large cells such as oocytes. Here, we study actin-based positioning mechanisms in artificial cells with persistently contracting actomyosin networks, generated by encapsulating cytoplasmic Xenopus egg extracts into cell-sized ‘water-in-oil’ droplets. We observe size-dependent localization of the contraction center, with a symmetric configuration in larger cells and a polar one in smaller cells. Centering is achieved via a hydrodynamic mechanism based on Darcy friction between the contracting network and the surrounding cytoplasm. During symmetry breaking, transient attachments to the cell boundary drive the contraction center to a polar location. The centering mechanism is cell-cycle dependent and weakens considerably during interphase. Our findings demonstrate a robust, yet tunable, mechanism for subcellular localization.

Published

2020

11. The Role of Actomyosin Contraction Force in Heart Morphogenesis of Xenopus Tadpole Larvae

Subjects

heart morphogenesis, tadpole larva, Xenopus laevis, actomyosin contraction

Abstract

Many researchers have long been investigating the mechanism of actomyosin contraction. Actomyosin is an interesting macromolecular complex, which enables energy conversion that generates mechanical force very efficiently at a temperature compatible for animals. Vertebrate embryos gradually develop striated muscles, and the embryos can make various body movements by muscular contraction as early as at the late embryonic stage before hatching. In lower vertebrates, pulsation of the heart is also observable in late stage embryos. Here, we examined whether active contraction of actomyosin is necessary for normal morphogenesis of the embryonic/larval heart. Xenopus early larvae are very transparent, so they are suitable to observe the heart morphology and its contractile activities non-invasively. From such a viewpoint, the Xenopus larva is an ideal model organism. Thus, we first administered Blebbistatin, an inhibitor of actomyosin contraction, to Xenopus late stage embryos, and reared them until the early larval stage. As the results, hypoplasia of heart morphogenesis was frequently induced. As a next step, we intended to perform a comparable experiment; we administered Omecamtiv, a cardiotonic reagent, to potentiate the actomyosin contraction of the developing heart. Unexpectedly, Omecamtiv also induced a dwarf heart at a high frequency. Immunostaining using the antibody for muscles revealed that both Blebbistatin and Omecamtiv caused changes of fine structures of the heart. Based on these complementary experiments, we concluded that moderate contraction of actomyosin is essential for the normal asymmetric morphogenesis of the heart. Finally we report that Phenylhydrazine significantly induced hyperplasia of the heart, and fasciculation of the ventricular muscles was disordered after Phenylhydrazine treatment., 原著

Published

2022

12. Differences in creep response of GBM cells migrating in confinement

Author

Ishan Khan, Cheng Jen Chuong, Loan Bui, Robert Bachoo, and Young Tae Kim

Subjects

Energy loss, Physiology, Biomedical Engineering, Gene Expression, Physical Therapy, Sports Therapy and Rehabilitation, Cancer cell, Myosins, Suction, actomyosin contraction, creep, Cell Movement, Cell Line, Tumor, Lab-On-A-Chip Devices, Myosin, medicine, QP1-981, Humans, Orthopedics and Sports Medicine, Cytoskeleton, Chemistry, Rehabilitation, glioblastoma, viscoelastic properties, Cell migration, medicine.disease, Actins, Elasticity, Computer Science Applications, Biomechanical Phenomena, Creep, Biophysics, Thermodynamics, Neuroglia, TP248.13-248.65, Stationary state, Biomarkers, Biotechnology, Glioblastoma, Research Article

Abstract

Using a microfluidic platform to apply negative aspiration pressure (–20, –25, –30, –35 and –40 cm H2O), we compared the differences in creep responses of Glioblastoma Multiforme (GBM) cells while migrating in confinement and at a stationary state on a 2D substrate. Cells were either migrating in a channel of 5 x 5 μm cross-section or stationary at the entrance to the channel. In response to aspiration pressure, we found actively migrating GBM cells exhibited a higher stiffness than stationary cells. Additionally, migrating cells absorbed more energy elastically with a relatively small dissipative energy loss. At elevated negative pressure loads up to – 30 cm H2O, we observed a linear increase in elastic deformation and a higher distribution in elastic storage than energy loss, and the response plateaued at further increasing negative pressure loads. To explore the underlying cause, we carried out immuno-cytochemical studies of these cells and found a polarized actin and myosin distribution at the front and posterior ends of the migrating cells, whereas the distribution of the stationary group demonstrated no specific regional differences. These differences in creep response and cytoskeletal protein distribution demonstrate the importance of a migrating cell’s kinematic state to the mechanism of cell migration.

Published

2021

13. Multiphasic stress relaxation response of freshly isolated and cultured vascular smooth muscle cells measured by quasi-in situ tensile test.

Author

Kazuaki Nagayama, Shunsuke Saito, and Takeo Matsumoto

Subjects

*STRESS relaxation (Mechanics), *VASCULAR smooth muscle, *TENSILE tests, *VISCOELASTICITY, *CYTOSKELETON

Abstract

Vascular smooth muscle cells (SMCs) undergo a phenotypic change from a contractile to a synthetic state under pathological conditions, such as atherogenesis and restenosis. Although the viscoelastic properties of SMCs are of particular interest because of their role in the development of these vascular diseases, the effects of phenotypic changes on their viscoelastic properties are unclear at this stage. We performed the stress relaxation test at constant strain (ε = 30%) for the freshly isolated contractile SMCs (FSMCs) and the cultured synthetic SMCs (CSMCs) maintaining in situ cell shape and cytoskeletal integrity. We also investigated the effect of extracellular Ca2+on their viscoelastic behaviors. FSMCs and CSMCs exhibited multiphasic stress relaxation, which consisted of rapid relaxation, occurring on a time scale of several seconds and several 10 seconds, and slow relaxation occurring on a time scale of 1000 seconds. The estimated elastic modulus of CSMCs was less than one-half that of FSMCs, that was associated with a decreased of amount of actin stress fibers (SFs) during the transition from contractile to synthetic phenotypes. FSMCs showed a conservation of tension with extracellular Ca2+following rapid stress relaxation. In contrast, CSMCs showed a consecutive decrease in tension independent of Ca2+. This suggests that the decrease in tension in a long time scale may be involved in mechanical remodeling of SFs induced through a Rho-dependent pathway, which is Ca2+-independent and become predominant in the transition from contractile to synthetic phenotypes. [ABSTRACT FROM AUTHOR]

Published

2015

14. Regulation of actomyosin contraction as a driving force of invasive lobular breast cancer

Author

Schipper, K., Jonkers, J.M.M., Nethe, M., Irth, H., Water, B. van de, Danen, E.H.J., Dijke, P. ten, Neefjes, J.J.C., Visser, K.E. de, Sonnenberg, A., Derksen, P.W.B., and Leiden University

Subjects

MYH9, Tumor development, Mouse models of cancer, Actomyosin contraction, Invasive lobular carcinoma (ILC), Cell adhesion, E-cadherin, In vivo insertional mutagenesis, MYPT1, ASPP2

Abstract

In this thesis, we used genetically engineered mouse models and a variety of cell-culture based assays to identify genes and pathways that are involved in the development and treatment of invasive lobular carcinoma (ILC). To identify novel genes and pathways involved in the development of ILCs we employed a Sleeping Beauty (SB)-based insertional mutagenesis screen in conditional Cdh1 knockout mice. We show that active transposon mutagenesis drives ILC formation and analysis of common insertion sites in SB-induced tumors identified a mutually exclusive group of four genes (MYH9, MYPT1/2 and ASPP2), three of which are frequently altered in human ILCs. We then went on to show that these hits not only drive ILC development but also do so through a shared mechanism. We identified that all four hits result in actomyosin relaxation which enables E-cadherin deficient mammary epithelial cells to invade into the mammary stroma and initiate tumor development. In addition, we show that mammary epithelial cells that lose E-cadherin expression can survive in the fibrous stroma directly surrounding the mammary ducts through interactions with components of the basement membrane. Lastly, we used active mobilization of transposons to identify resistance mechanisms to the FGFR inhibitor AZD4547.

Published

2020

15. Homophilic and heterophilic cadherin bond rupture forces in homo- or hetero-cellular systems measured by AFM-based single-cell force spectroscopy

Author

Manfred Radmacher, Ganzanfer Belge, Prem Kumar Viji Babu, and Ursula Mirastschijski

Subjects

0301 basic medicine, Biophysics, Microscopy, Atomic Force, Adherens junction, 03 medical and health sciences, Atomic force microscopy, 0302 clinical medicine, Myosin, Extracellular, medicine, Cell Adhesion, Actomyosin contraction, Fibroblast, Actin, Mechanical Phenomena, Cadherin, Chemistry, Spectrum Analysis, Force spectroscopy, Single-cell force spectroscopy, General Medicine, Cadherins, Epithelial cell, 030104 developmental biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Original Article, Intracellular, Protein Binding

Abstract

Cadherins enable intercellular adherens junctions to withstand tensile forces in tissues, e.g. generated by intracellular actomyosin contraction. In-vitro single molecule force spectroscopy experiments can reveal cadherin–cadherin extracellular region binding dynamics such as bond formation and strength. However, characterization of cadherin-presenting cell homophilic and heterophilic binding in the proteins’ native conformational and functional states in living cells has rarely been done. Here, we used atomic force microscopy (AFM) based single-cell force spectroscopy (SCFS) to measure rupture forces of homophilic and heterophilic bond formation of N- (neural), OB- (osteoblast) and E- (epithelial) cadherins in living fibroblast and epithelial cells in homo- and hetero-cellular arrangements, i.e., between cells and cadherins of the same and different types. In addition, we used indirect immunofluorescence labelling to study and correlate the expression of these cadherins in intercellular adherens junctions. We showed that N/N and E/E-cadherin homophilic binding events are stronger than N/OB heterophilic binding events. Disassembly of intracellular actin filaments affects the cadherin bond rupture forces suggesting a contribution of actin filaments in cadherin extracellular binding. Inactivation of myosin did not affect the cadherin rupture force in both homo- and hetero-cellular arrangements, but particularly strengthened the N/OB heterophilic bond and reinforced the other cadherins’ homophilic bonds. Supplementary Information The online version contains supplementary material available at 10.1007/s00249-021-01536-2.

Published

2020

16. Centering and symmetry breaking in confined contracting actomyosin networks

Author

Angelika Manhart, Maya Malik-Garbi, Bruce L. Goode, Alex Mogilner, Niv Ierushalmi, Kinneret Keren, and Enas Abu Shah

Subjects

artificial cell, QH301-705.5, Xenopus, Science, Cell, FOS: Physical sciences, Physics of Living Systems, actomyosin contraction, symmetry breaking, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, subcellular localization, medicine, Molecular motor, Animals, Physics - Biological Physics, Symmetry breaking, Biology (General), Actin, 030304 developmental biology, Physics, 0303 health sciences, centering, General Immunology and Microbiology, Artificial cell, General Neuroscience, A protein, Cell Polarity, General Medicine, Cell Biology, Actomyosin, Actin Cytoskeleton, medicine.anatomical_structure, Biological Physics (physics.bio-ph), Biophysics, Oocytes, Medicine, Female, Nucleus, 030217 neurology & neurosurgery, Research Article

Abstract

Centering and decentering of cellular components is essential for internal organization of cells and their ability to perform basic cellular functions such as division and motility. How cells achieve proper localization of their organelles is still not well-understood, especially in large cells such as oocytes. Here, we study actin-based positioning mechanisms in artificial cells with persistently contracting actomyosin networks, generated by encapsulating cytoplasmic Xenopus egg extracts into cell-sized ‘water-in-oil’ droplets. We observe size-dependent localization of the contraction center, with a symmetric configuration in larger cells and a polar one in smaller cells. Centering is achieved via a hydrodynamic mechanism based on Darcy friction between the contracting network and the surrounding cytoplasm. During symmetry breaking, transient attachments to the cell boundary drive the contraction center to a polar location. The centering mechanism is cell-cycle dependent and weakens considerably during interphase. Our findings demonstrate a robust, yet tunable, mechanism for subcellular localization., eLife digest In order to survive, cells need to react to their environment and change their shape or the localization of their internal components. For example, the nucleus – the compartment that contains the genetic information – is often localized at the center of the cell, but it can also be positioned at the side, for instance when cells move or divide asymmetrically. Cells use multiple positioning mechanisms to move their internal components, including a process that relies on networks of filaments made of a protein known as actin. These networks are constantly remodeled as actin proteins are added and removed from the network. Embedded molecular motors can cause the network of actin filaments to contract and push or pull on the compartments. Yet, the exact way these networks localize components in the cell remains unclear, especially in eggs and other large cells. To investigate this question, Ierushalmi et al. studied the actin networks in artificial cells that they created by enclosing the contents of frog eggs in small droplets surrounded by oil. This showed that the networks contracted either to the center of the cell or to its side. Friction between the contracting actin network and the fluid in the cell generated a force that tends to push the contraction center towards the middle of the cell. In larger cells, this led to the centering of the actin network. In smaller cells however, the network transiently attached to the boundary of the cell, leading the contraction center to be pulled to one side. By developing simpler artificial cells that mimic the positioning processes seen in real-life cells, Ierushalmi et al. discovered new mechanisms for how cells may center or de-center their components. This knowledge may be useful to understand diseases that can emerge when the nucleus or other compartments fail to move to the right location, and which are associated with certain organs developing incorrectly.

Published

2020

17. Cell signaling in regulation of the barrier integrity of the corneal endothelium

Author

Srinivas, Sangly P.

Subjects

*CORNEA, *ENDOTHELIUM, *CELLULAR signal transduction, *AQUEOUS humor, *CYTOSKELETON, *MICROTUBULES, *GUANOSINE triphosphatase

Abstract

Abstract: The barrier integrity of the corneal endothelium, which is conferred by its tight and adherens junctions, is critical for the maintenance of deturgescence of the corneal stroma. Although characteristically leaky, the barrier integrity restricts fluid leakage into the stroma such that the rate of leak does not exceed the rate of the endothelial active fluid transport directed toward the aqueous humor. At a molecular level, the barrier integrity is influenced by the actin cytoskeleton and microtubules, which are coupled to tight and adherens junctions via a variety of linker proteins. Since the cytoskeleton is affected by Rho family small GTPases and p38 MAP kinase, among others, many pathophysiological stimuli induce plasticity to the cytoskeleton and thereby elicit dynamic regulation of the barrier integrity. This review presents an overview of the impact of several bioactive factors on the barrier integrity of the corneal endothelium through altered actin cytoskeleton and/or disassembly of microtubules. The main focus is on the effect of TNF-α (tumor necrosis factor-α) which is a pro-inflammatory molecule found in the intraocular milieu during allograft rejection and anterior uveitis. This cytokine elicits acute activation of p38 MAP kinase, induces disassembly of microtubules, disrupts the peri-junctional actomyosin ring, and concomitantly breaks down the barrier integrity. These effects of TNF-α could be inhibited by stabilizing the microtubules, co-treating with a selective p38 MAP kinase inhibitor, and elevating intracellular cAMP via A2B receptors or direct exposure to forskolin. Overall, the corneal edema following a potential breakdown of the endothelial barrier integrity can be rescued pharmacologically by inhibiting specific cell-signaling mechanisms. [Copyright &y& Elsevier]

Published

2012

18. Estimation of single stress fiber stiffness in cultured aortic smooth muscle cells under relaxed and contracted states: Its relation to dynamic rearrangement of stress fibers

Author

Nagayama, Kazuaki and Matsumoto, Takeo

Subjects

*ESTIMATION theory, *CELL culture, *SMOOTH muscle, *CELLULAR mechanics, *MUSCLE contraction, *ACTIN, *FIBERS, *MICROPIPETTES, *MUSCLE cells

Abstract

Abstract: For a quantitative analysis of intracellular mechanotransduction, it is crucial to know the mechanical properties of actin stress fibers in situ. Here we measured tensile properties of cultured aortic smooth muscle cells (SMCs) in a quasi-in situ tensile test in relaxed and activated states to estimate stiffness of their single stress fibers (SFs). An SMC cultured on substrates was held using a pair of micropipettes and detached from the substrate while maintaining its in situ cell shape and cytoskeletal integrity. Stretching up to ∼15% followed by unloading was repeated three times to stabilize their tension–strain curves in the untreated (relaxed) and 10μM-serotonin-treated (activated) condition. Cell stiffness defined as the average slope of the loading limb of the stable loops was ∼25 and ∼40nN/% in relaxed and activated states, respectively. It decreased to ∼10nN/% following SF disruption with cytochalasin D in both states. The number of SFs in each cell measured with confocal microscopy decreased significantly upon serotonin activation from 21.5±3.8 (mean±SD, n=80) to 17.5±3.9 (n=77). The dynamics of focal adhesions (FAs) were observed in adherent cells using surface reflective interference contrast microscopy. FAs aligned and elongated along the cell major axis following activation and then merged with each other, suggesting that the decrease in SFs was caused by their fusion. Average stiffness of single SFs estimated by the average decrease in whole-cell stiffness following SF disruption divided by the average number of SFs in each cell was ∼0.7 and ∼1.6nN/% in the relaxed and activated states, respectively. Stiffening of single SFs following SF activation was remarkably higher than stiffening at the whole-cell level. Results indicate that SFs stiffen not only due to activation of the actomyosin interaction, but also due to their fusion, a finding which would not be obtained from analysis of isolated SFs. [Copyright &y& Elsevier]

Published

2010

19. Fundamental issues, recent advances, and future directions in myodynamics

Author

Hatze, H.

Subjects

*MUSCLES, *MUSCULOSKELETAL system, *ELBOW physiology, *ADENOSINE triphosphate metabolism, *SKELETAL muscle physiology, *BIOLOGICAL models, *FORECASTING, *MATHEMATICAL models, *MUSCLE contraction, *MYOSIN, *THEORY, *MOLECULAR motor proteins

Abstract

A state-of-the-art report is presented on recent progress in selected areas of myodynamics, but also on problems that severely hamper the further development of the discipline. Significant advances have been made in elucidating the force-producing interaction between actin and the myosin-S1-subunit, including the localization of the most probable molecular site of power stroke initiation. Concerning the architecture of the myostructures, strong experimental evidence has accumulated for numerous intra-, inter-, and extramuscular pathways for lateral force transmission in addition to the serial sarcomere-to-sarcomere myotendinous path.It is shown that contemporary muscle models are inadequate in most respects and lag far behind the requirements an appropriate myodynamic model should fulfil. A similar comment applies to the current approaches designed to solve the myoskeletal indeterminacy problem. These formulations neglect myodynamic properties and do not allow for the implementation of biologically realistic objective functions. The solutions currently obtained are highly unsatisfactory. New research directions to rectify these situations are suggested, also with regard to the identification of subject-specific myodynamic parameters. [Copyright &y& Elsevier]

Published

2002

20. Kindlin-2 promotes rear focal adhesion disassembly and directional persistence during cell migration.

Author

Liu J, Liu Z, Chen K, Chen W, Fang X, Li M, Zhou X, Ding N, Lei H, Guo C, Qian T, Wang Y, Liu L, Chen Y, Zhao H, Sun Y, Deng Y, and Wu C

Subjects

Cell Adhesion, Cell Movement genetics, Phosphorylation, Focal Adhesions metabolism, Myosin-Light-Chain Kinase metabolism

Abstract

Cell migration involves front-to-rear asymmetric focal adhesion (FA) dynamics, which facilitates trailing edge detachment and directional persistence. Here, we show that kindlin-2 is crucial for FA sliding and disassembly in migrating cells. Loss of kindlin-2 markedly reduced FA number and selectively impaired rear FA sliding and disassembly, resulting in defective rear retraction and reduced directional persistence during cell migration. Kindlin-2-deficient cells failed to develop serum-induced actomyosin-dependent tension at FAs. At the molecular level, kindlin-2 directly interacted with myosin light chain kinase (MYLK, hereafter referred to as MLCK), which was enhanced in response to serum stimulation. Serum deprivation inhibited rear FA disassembly, which was released in response to serum stimulation. Overexpression of the MLCK-binding kindlin-2 F0F1 fragment (amino acid residues 1-167), which inhibits the interaction of endogenous kindlin-2 with MLCK, phenocopied kindlin-2 deficiency-induced migration defects. Inhibition of MLCK, like loss of kindlin-2, also impaired trailing-edge detachment, rear FA disassembly and directional persistence. These results suggest a role of kindlin-2 in promoting actomyosin contractility at FAs, leading to increased rear FA sliding and disassembly, and directional persistence during cell migration., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

21. Drosophila egg chamber elongation

Author

Gates, Julie

Subjects

extracellular matrix, Review, Actomyosin, actomyosin contraction, basal lamina, Actins, Oogenesis, Cell Movement, global tissue rotation, Animals, Drosophila Proteins, Drosophila, actin, Cell Shape

Abstract

As tissues and organs are formed, they acquire a specific shape that plays an integral role in their ability to function properly. A relatively simple system that has been used to examine how tissues and organs are shaped is the formation of an elongated Drosophila egg. While it has been known for some time that Drosophila egg elongation requires interactions between a polarized intracellular basal actin network and a polarized extracellular network of basal lamina proteins, how these interactions contribute to egg elongation remained unclear. Recent studies using live imaging have revealed two novel processes, global tissue rotation and oscillating basal actomyosin contractions, which have provided significant insight into how the two polarized protein networks cooperate to produce an elongated egg. This review summarizes the proteins involved in Drosophila egg elongation and how this recent work has contributed to our current understanding of how egg elongation is achieved.

Published

2012

22. Centering and symmetry breaking in confined contracting actomyosin networks.

Author

Ierushalmi N, Malik-Garbi M, Manhart A, Abu Shah E, Goode BL, Mogilner A, and Keren K

Subjects

Animals, Female, Oocytes cytology, Oocytes metabolism, Xenopus, Actin Cytoskeleton physiology, Actomyosin metabolism, Cell Polarity physiology

Abstract

Centering and decentering of cellular components is essential for internal organization of cells and their ability to perform basic cellular functions such as division and motility. How cells achieve proper localization of their organelles is still not well-understood, especially in large cells such as oocytes. Here, we study actin-based positioning mechanisms in artificial cells with persistently contracting actomyosin networks, generated by encapsulating cytoplasmic Xenopus egg extracts into cell-sized 'water-in-oil' droplets. We observe size-dependent localization of the contraction center, with a symmetric configuration in larger cells and a polar one in smaller cells. Centering is achieved via a hydrodynamic mechanism based on Darcy friction between the contracting network and the surrounding cytoplasm. During symmetry breaking, transient attachments to the cell boundary drive the contraction center to a polar location. The centering mechanism is cell-cycle dependent and weakens considerably during interphase. Our findings demonstrate a robust, yet tunable, mechanism for subcellular localization., Competing Interests: NI, MM, AM, EA, BG, AM, KK No competing interests declared, (© 2020, Ierushalmi et al.)

Published

2020

23. Multiphasic stress relaxation response of freshly isolated and cultured vascular smooth muscle cells measured by quasi-in situ tensile test.

Author

Nagayama K, Saito S, and Matsumoto T

Subjects

Animals, Calcium Signaling physiology, Cell Separation methods, Elastic Modulus physiology, Equipment Design, Equipment Failure Analysis, Male, Micromanipulation methods, Myocytes, Smooth Muscle cytology, Physical Stimulation instrumentation, Rats, Rats, Wistar, Reproducibility of Results, Sensitivity and Specificity, Stress, Mechanical, Tensile Strength physiology, Viscosity, Cell Separation instrumentation, Micromanipulation instrumentation, Muscle Contraction physiology, Muscle, Smooth, Vascular cytology, Muscle, Smooth, Vascular physiology, Myocytes, Smooth Muscle physiology

Abstract

Vascular smooth muscle cells (SMCs) undergo a phenotypic change from a contractile to a synthetic state under pathological conditions, such as atherogenesis and restenosis. Although the viscoelastic properties of SMCs are of particular interest because of their role in the development of these vascular diseases, the effects of phenotypic changes on their viscoelastic properties are unclear at this stage. We performed the stress relaxation test at constant strain (ε=30%) for the freshly isolated contractile SMCs (FSMCs) and the cultured synthetic SMCs (CSMCs) maintaining in situ cell shape and cytoskeletal integrity. We also investigated the effect of extracellular Ca2+ on their viscoelastic behaviors. FSMCs and CSMCs exhibited multiphasic stress relaxation, which consisted of rapid relaxation, occurring on a time scale of several seconds and several 10 seconds, and slow relaxation occurring on a time scale of 1000 seconds. The estimated elastic modulus of CSMCs was less than one-half that of FSMCs, that was associated with a decreased of amount of actin stress fibers (SFs) during the transition from contractile to synthetic phenotypes. FSMCs showed a conservation of tension with extracellular Ca2+ following rapid stress relaxation. In contrast, CSMCs showed a consecutive decrease in tension independent of Ca2+. This suggests that the decrease in tension in a long time scale may be involved in mechanical remodeling of SFs induced through a Rho-dependent pathway, which is Ca2+-independent and become predominant in the transition from contractile to synthetic phenotypes.

Published

2015

24. PGE2-mediated podosome loss in dendritic cells is dependent on actomyosin contraction downstream of the RhoA--Rho-kinase axis.

Author

Van Helden, Suzanne F. G., Oud, Machteld M., Joosten, Ben, Peterse, Niels, Figdor, Carl G., and Van Leeuwen, Frank N.

Subjects

*DENDRITIC cells, *CONTRACTILITY (Biology), *ACTOMYOSIN, *RHO GTPases, *INFLAMMATORY mediators

Abstract

Podosomes are dynamic adhesion structures found in dendritic cells (DCs) and other cells of the myeloid lineage. We previously showed that prostaglandin E2 (PGE2), an important proinflammatory mediator produced during DC maturation, induces podosome disassembly within minutes after stimulation. Here, we demonstrate that this response is mediated by cAMP elevation, occurs downstream of Rho kinase and is dependent on myosin II. Whereas PGE2 stimulation leads to activation of the small GTPase RhoA, decreased levels of Rac1-GTP and Cdc42-GTP are observed. These results show that PGE2 stimulation leads to activation of the RhoA Rho-kinase axis to promote actomyosin-based contraction and subsequent podosome dissolution. Because podosome disassembly is accompanied by de novo formation of focal adhesions, we propose that the disassembly/formation of these two different adhesion structures is oppositely regulated by actomyosin contractility and relative activities of RhoA, Rac1 and Cdc42. [ABSTRACT FROM AUTHOR]

Published

2008