Your search keyword '"Zaidel-Bar, Ronen"' showing total 16 results

1. Active nuclear positioning and actomyosin contractility maintain leader cell integrity during gonadogenesis.

Author

Agarwal P, Berger S, Shemesh T, and Zaidel-Bar R

Subjects

Animals, Microtubules metabolism, Morphogenesis, Kinesins metabolism, Kinesins genetics, Cell Movement, Actomyosin metabolism, Gonads metabolism, Gonads growth & development, Caenorhabditis elegans growth & development, Caenorhabditis elegans physiology, Cell Nucleus metabolism, Caenorhabditis elegans Proteins metabolism, Caenorhabditis elegans Proteins genetics

Abstract

Proper distribution of organelles can play an important role in a moving cell's performance. During C. elegans gonad morphogenesis, the nucleus of the leading distal tip cell (DTC) is always found at the front, yet the significance of this localization is unknown. Here, we identified the molecular mechanism that keeps the nucleus at the front, despite a frictional force that pushes it backward. The Klarsicht/ANC-1/Syne homology (KASH) domain protein UNC-83 links the nucleus to the motor protein kinesin-1 that moves along a polarized acentrosomal microtubule network. Interestingly, disrupting nuclear positioning on its own did not affect gonad morphogenesis. However, reducing actomyosin contractility on top of nuclear mispositioning led to a dramatic phenotype: DTC splitting and gonad bifurcation. Long-term live imaging of the double knockdown revealed that, while the gonad attempted to perform a planned U-turn, the DTC was stretched due to the lagging nucleus until it fragmented into a nucleated cell and an enucleated cytoplast, each leading an independent gonadal arm. Remarkably, the enucleated cytoplast had polarity and invaded, but it could only temporarily support germ cell proliferation. Based on a qualitative biophysical model, we conclude that the leader cell employs two complementary mechanical approaches to preserve its integrity and ensure proper organ morphogenesis while navigating through a complex 3D environment: active nuclear positioning by microtubule motors and actomyosin-driven cortical contractility., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

2. Actin-capping protein regulates actomyosin contractility to maintain germline architecture in C. elegans.

Author

Ray S, Agarwal P, Nitzan A, Nédélec F, and Zaidel-Bar R

Subjects

Animals, Actins metabolism, Actin Capping Proteins metabolism, Actin Cytoskeleton metabolism, Myosins metabolism, Germ Cells metabolism, Actomyosin metabolism, Caenorhabditis elegans genetics, Caenorhabditis elegans metabolism

Abstract

Actin dynamics play an important role in tissue morphogenesis, yet the control of actin filament growth takes place at the molecular level. A challenge in the field is to link the molecular function of actin regulators with their physiological function. Here, we report an in vivo role of the actin-capping protein CAP-1 in the Caenorhabditis elegans germline. We show that CAP-1 is associated with actomyosin structures in the cortex and rachis, and its depletion or overexpression led to severe structural defects in the syncytial germline and oocytes. A 60% reduction in the level of CAP-1 caused a twofold increase in F-actin and non-muscle myosin II activity, and laser incision experiments revealed an increase in rachis contractility. Cytosim simulations pointed to increased myosin as the main driver of increased contractility following loss of actin-capping protein. Double depletion of CAP-1 and myosin or Rho kinase demonstrated that the rachis architecture defects associated with CAP-1 depletion require contractility of the rachis actomyosin corset. Thus, we uncovered a physiological role for actin-capping protein in regulating actomyosin contractility to maintain reproductive tissue architecture., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2023. Published by The Company of Biologists Ltd.)

Published

2023

3. Reciprocal regulation of actomyosin organization and contractility in nonmuscle cells by tropomyosins and alpha-actinins.

Author

Hu S, Grobe H, Guo Z, Wang YH, Doss BL, Pan M, Ladoux B, Bershadsky AD, and Zaidel-Bar R

Subjects

Actin Cytoskeleton metabolism, Animals, Biomechanical Phenomena, Fibroblasts metabolism, Focal Adhesions metabolism, Models, Biological, Myosin Type II metabolism, Rats, Stress Fibers metabolism, Actinin metabolism, Actomyosin metabolism, Muscle Contraction, Tropomyosin metabolism

Abstract

Contractile arrays of actin and myosin II filaments drive many essential processes in nonmuscle cells, including migration and adhesion. Sequential organization of actin and myosin along one dimension is followed by expansion into a two-dimensional network of parallel actomyosin fibers, in which myosin filaments are aligned to form stacks. The process of stack formation has been studied in detail. However, factors that oppose myosin stack formation have not yet been described. Here, we show that tropomyosins act as negative regulators of myosin stack formation. Knockdown of any or all tropomyosin isoforms in rat embryonic fibroblasts resulted in longer and more numerous myosin stacks and a highly ordered actomyosin organization. The molecular basis for this, we found, is the competition between tropomyosin and alpha-actinin for binding actin. Surprisingly, excessive order in the actomyosin network resulted in smaller focal adhesions, lower tension within the network, and smaller traction forces. Conversely, disordered actomyosin bundles induced by alpha-actinin knockdown led to higher than normal tension and traction forces. Thus, tropomyosin acts as a check on alpha-actinin to achieve intermediate levels of myosin stacks matching the force requirements of the cell.

Published

2019

4. Principles of Actomyosin Regulation In Vivo.

Author

Agarwal P and Zaidel-Bar R

Subjects

Actins metabolism, Animals, Humans, Models, Biological, Myosins metabolism, Actin Cytoskeleton metabolism, Actomyosin metabolism, Microtubules metabolism, Muscle Contraction

Abstract

The actomyosin cytoskeleton is responsible for most force-driven processes in cells and tissues. How it assembles into the necessary structures at the right time and place is an important question. Here, we focus on molecular mechanisms of actomyosin regulation recently elucidated in animal models, and highlight several common principles that emerge. The architecture of the actomyosin network - an important determinant of its function - results from actin polymerization, crosslinking and turnover, localized myosin activation, and contractility-driven self-organization. Spatiotemporal regulation is achieved by tissue-specific expression and subcellular localization of Rho GTPase regulators. Subcellular anchor points of actomyosin structures control the outcome of their contraction, and molecular feedback mechanisms dictate whether they are transient, cyclic, or persistent., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

5. Syncytial germline architecture is actively maintained by contraction of an internal actomyosin corset.

Author

Priti A, Ong HT, Toyama Y, Padmanabhan A, Dasgupta S, Krajnc M, and Zaidel-Bar R

Subjects

Animals, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins metabolism, Cytoplasmic Streaming, Gonads metabolism, Models, Biological, Myosins metabolism, Actomyosin metabolism, Germ Cells metabolism, Giant Cells metabolism

Abstract

Syncytial architecture is an evolutionarily-conserved feature of the germline of many species and plays a crucial role in their fertility. However, the mechanism supporting syncytial organization is largely unknown. Here, we identify a corset-like actomyosin structure within the syncytial germline of Caenorhabditis elegans, surrounding the common rachis. Using laser microsurgery, we demonstrate that actomyosin contractility within this structure generates tension both in the plane of the rachis surface and perpendicular to it, opposing membrane tension. Genetic and pharmacological perturbations, as well as mathematical modeling, reveal a balance of forces within the gonad and show how changing the tension within the actomyosin corset impinges on syncytial germline structure, leading, in extreme cases, to sterility. Thus, our work highlights a unique tissue-level cytoskeletal structure, and explains the critical role of actomyosin contractility in the preservation of a functional germline.

Published

2018

6. The myosin light-chain kinase MLCK-1 relocalizes during Caenorhabditis elegans ovulation to promote actomyosin bundle assembly and drive contraction.

Author

Kelley CA, Wirshing ACE, Zaidel-Bar R, and Cram EJ

Subjects

Amino Acid Sequence, Animals, Caenorhabditis elegans cytology, Caenorhabditis elegans Proteins chemistry, Female, Fertility, Humans, Myosins metabolism, Phosphorylation, Structural Homology, Protein, Actomyosin metabolism, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins metabolism, Ovulation

Abstract

We identify the Caenorhabditis elegans myosin light-chain kinase, MLCK-1, required for contraction of spermathecae. During contraction, MLCK-1 moves from the apical cell boundaries to the basal actomyosin bundles, where it stabilizes myosin downstream of calcium signaling. MLCK and ROCK act in distinct subsets of cells to coordinate the timing of contraction.

Published

2018

7. Stretch-induced actomyosin contraction in epithelial tubes: Mechanotransduction pathways for tubular homeostasis.

Author

Sethi K, Cram EJ, and Zaidel-Bar R

Subjects

Animals, Biomechanical Phenomena, Humans, Integrins metabolism, Signal Transduction, Actomyosin metabolism, Epithelial Cells metabolism, Homeostasis

Abstract

Many tissues in our body have a tubular shape and are constantly exposed to various stresses. Luminal pressure imposes tension on the epithelial and myoepithelial or smooth muscle cells surrounding the lumen of the tubes. Contractile forces generated by actomyosin assemblies within these cells oppose the luminal pressure and must be calibrated to maintain tube diameter homeostasis and tissue integrity. In this review, we discuss mechanotransduction pathways that can lead from sensation of cell stretch to activation of actomyosin contractility, providing rapid mechanochemical feedback for proper tubular tissue function., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

8. Long-range self-organization of cytoskeletal myosin II filament stacks.

Author

Hu S, Dasbiswas K, Guo Z, Tee YH, Thiagarajan V, Hersen P, Chew TL, Safran SA, Zaidel-Bar R, and Bershadsky AD

Subjects

Actin Cytoskeleton metabolism, Half-Life, Humans, Models, Biological, Actomyosin metabolism, Cytoskeleton metabolism, Muscle Contraction physiology, Myosin Type II metabolism

Abstract

Although myosin II filaments are known to exist in non-muscle cells, their dynamics and organization are incompletely understood. Here, we combined structured illumination microscopy with pharmacological and genetic perturbations, to study the process of actomyosin cytoskeleton self-organization into arcs and stress fibres. A striking feature of the myosin II filament organization was their 'registered' alignment into stacks, spanning up to several micrometres in the direction orthogonal to the parallel actin bundles. While turnover of individual myosin II filaments was fast (characteristic half-life time 60 s) and independent of actin filament turnover, the process of stack formation lasted a longer time (in the range of several minutes) and required myosin II contractility, as well as actin filament assembly/disassembly and crosslinking (dependent on formin Fmnl3, cofilin1 and α-actinin-4). Furthermore, myosin filament stack formation involved long-range movements of individual myosin filaments towards each other suggesting the existence of attractive forces between myosin II filaments. These forces, possibly transmitted via mechanical deformations of the intervening actin filament network, may in turn remodel the actomyosin cytoskeleton and drive its self-organization.

Published

2017

9. Non-junctional E-Cadherin Clusters Regulate the Actomyosin Cortex in the C. elegans Zygote.

Author

Padmanabhan A, Ong HT, and Zaidel-Bar R

Subjects

Actins metabolism, Actomyosin genetics, Animals, Cadherins genetics, Caenorhabditis elegans genetics, Caenorhabditis elegans growth & development, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism, Cell Adhesion, Cytokinesis, Gene Expression Regulation, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, rho GTP-Binding Proteins genetics, rho GTP-Binding Proteins metabolism, Actomyosin metabolism, Cadherins metabolism, Caenorhabditis elegans cytology, Caenorhabditis elegans metabolism, Zygote metabolism

Abstract

Classical cadherins are well known for their essential function in mediating cell-cell adhesion via their extra-cellular cadherin domains and intra-cellular connections to the actin cytoskeleton [1-3]. There is evidence, however, of adhesion-independent cadherin clusters existing outside of cell-cell junctions [4-6]. What function, if any, these clusters have is not known. HMR-1, the sole classical cadherin in Caenorhabditis elegans, plays essential roles during gastrulation, blastomere polarity establishment, and epidermal morphogenesis [7-11]. To elucidate the physiological roles of non-junctional cadherin, we analyzed HMR-1 in the C. elegans zygote, which is devoid of neighbors. We show that non-junctional clusters of HMR-1 form during the one-cell polarization stage and associate with F-actin at the cortex during episodes of cortical flow. Non-junctional HMR-1 clusters downregulate RHO-1 activity and inhibit accumulation of non-muscle myosin II (NMY-2) at the anterior cortex. We found that HMR-1 clusters impede cortical flows and play a role in preserving the integrity of the actomyosin cortex, preventing it from splitting in two. Importantly, we uncovered an inverse relationship between the amount of HMR-1 at the cell surface and the rate of cytokinesis. The effect of HMR-1 clusters on cytokinesis is independent of their effect on NMY-2 levels, and is also independent of their extra-cellular domains. Thus, in addition to their canonical role in inter-cellular adhesion, HMR-1 clusters regulate RHO-1 activity and NMY-2 level at the cell surface, reinforce the stability of the actomyosin cortex, and resist its movement to influence cell-shape dynamics., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

10. The contractome--a systems view of actomyosin contractility in non-muscle cells.

Author

Zaidel-Bar R, Zhenhuan G, and Luxenburg C

Subjects

Actomyosin genetics, Humans, Phosphorylation, Signal Transduction, Actin Cytoskeleton physiology, Actomyosin metabolism, Cell Movement physiology, Gene Regulatory Networks, Protein Interaction Maps

Abstract

Actomyosin contractility is a highly regulated process that affects many fundamental biological processes in each and every cell in our body. In this Cell Science at a Glance article and the accompanying poster, we mined the literature and databases to map the contractome of non-muscle cells. Actomyosin contractility is involved in at least 49 distinct cellular functions that range from providing cell architecture to signal transduction and nuclear activity. Containing over 100 scaffolding and regulatory proteins, the contractome forms a highly complex network with more than 230 direct interactions between its components, 86 of them involving phosphorylation. Mapping these interactions, we identify the key regulatory pathways involved in the assembly of actomyosin structures and in activating myosin to produce contractile forces within non-muscle cells at the exact time and place necessary for cellular function., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

11. Transient membrane localization of SPV-1 drives cyclical actomyosin contractions in the C. elegans spermatheca.

Author

Tan PY and Zaidel-Bar R

Subjects

Animals, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins metabolism, GTPase-Activating Proteins metabolism, Genitalia, Male metabolism, Male, rho GTP-Binding Proteins metabolism, Actomyosin metabolism, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, GTPase-Activating Proteins genetics, Mechanotransduction, Cellular, rho GTP-Binding Proteins genetics

Abstract

Background: Actomyosin contractility is the major cellular force driving changes in cell and tissue shape. A principal regulator of contractility is the small GTPase RhoA. External mechanical forces have been shown to impact RhoA activity and cellular contractility. However, the mechanotransduction pathway from external forces to actomyosin contractility is poorly understood., Results: Here, we show that actomyosin contractility in the C. elegans spermatheca is under control of RHO-1/RhoA, which, in turn, is regulated by the F-BAR and RhoGAP protein SPV-1. In the relaxed spermatheca, SPV-1 localizes through its F-BAR domain to the apical membrane, where it inhibits RHO-1/RhoA activity through its RhoGAP domain. Oocyte entry forces the spermatheca cells to stretch, and subsequently SPV-1 detaches from the membrane, permitting RHO-1 activity to increase. The increase in RHO-1 activity facilitates spermatheca contraction and expulsion of the newly fertilized embryo into the uterus, leading to relaxation of the spermatheca, SPV-1 membrane localization, and initiation of a new cycle., Conclusions: Our results demonstrate how transient membrane localization of a novel F-BAR domain, likely via specific binding to curved membranes, coupled to a RhoGAP domain, can provide feedback between a mechanical signal (membrane stretching) and actomyosin contractility. We anticipate this to be a widely utilized feedback mechanism used to balance actomyosin forces in the face of externally applied forces, as well as intrinsic processes involving cell deformation, from single-cell migration to tissue morphogenesis., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

12. Plastin increases cortical connectivity to facilitate robust polarization and timely cytokinesis

Author

Ding, Wei Yung, Ong, Hui Ting, Hara, Yusuke, Wongsantichon, Jantana, Toyama, Yusuke, Robinson, Robert C, Nédélec, François, Zaidel-Bar, Ronen, Hara, Yusuke [0000-0002-2005-7704], Wongsantichon, Jantana [0000-0002-4134-2248], Toyama, Yusuke [0000-0003-3230-1062], Nédélec, François [0000-0002-8141-5288], Zaidel-Bar, Ronen [0000-0002-1374-5007], and Apollo - University of Cambridge Repository

Subjects

Membrane Glycoproteins, Time Factors, Zygote, Microfilament Proteins, Morphogenesis, Animals, Cell Polarity, Actomyosin, Caenorhabditis elegans, Cell Shape, Actins, Cytokinesis

Abstract

The cell cortex is essential to maintain animal cell shape, and contractile forces generated within it by nonmuscle myosin II (NMY-2) drive cellular morphogenetic processes such as cytokinesis. The role of actin cross-linking proteins in cortical dynamics is still incompletely understood. Here, we show that the evolutionarily conserved actin bundling/cross-linking protein plastin is instrumental for the generation of potent cortical actomyosin contractility in the Caenorhabditis elegans zygote. PLST-1 was enriched in contractile structures and was required for effective coalescence of NMY-2 filaments into large contractile foci and for long-range coordinated contractility in the cortex. In the absence of PLST-1, polarization was compromised, cytokinesis was delayed or failed, and 50% of embryos died during development. Moreover, mathematical modeling showed that an optimal amount of bundling agents enhanced the ability of a network to contract. We propose that by increasing the connectivity of the F-actin meshwork, plastin enables the cortex to generate stronger and more coordinated forces to accomplish cellular morphogenesis.

Published

2017

13. The actin-bundling protein plastin increases cortical connectivity to promote robust polarization and timely cytokinesis in early C.elegans embryogenesis.

Author

Ding, Wei Yung and Zaidel-Bar, Ronen

Subjects

*ACTIN, *CAENORHABDITIS elegans, *CYTOKINESIS, *ACTOMYOSIN, *CELL membranes, *REPRODUCTION

Published

2017

14. Non-junctional E-Cadherin Clusters Regulate the Actomyosin Cortex in the C. elegans Zygote.

Author

Padmanabhan, Anup and Zaidel-Bar, Ronen

Subjects

*CADHERINS, *CAENORHABDITIS elegans, *ACTOMYOSIN, *CELL adhesion, *CYTOKINESIS

Published

2017

15. Actin-capping protein regulates actomyosin contractility to maintain germline architecture in C. elegans

Author

Shinjini Ray, Priti Agarwal, Anat Nitzan, François Nédélec, Ronen Zaidel-Bar, Zaidel-Bar, Ronen [0000-0002-1374-5007], and Apollo - University of Cambridge Repository

Subjects

Actin Capping Proteins, Formins, Actomyosin, Myosins, Contractility, Rachis, Capping protein, Actins, Actin Cytoskeleton, Fertility, Germ Cells, Morphogenesis, Animals, Arp2/3 complex, Cytosim, Actin dynamics, Syncytial germline, Caenorhabditis elegans, Molecular Biology, Cytoskeleton, Developmental Biology

Abstract

Peer reviewed: True, Acknowledgements: We thank Edwin Munro and David Kovar (University of Chicago) for illuminating discussions. We thank Noy Basonn for quantification of phenotypes shown in Fig. 9. Some strains were provided by the CGC, which is funded by NIH Office of Research Infrastructure Programs (P40 OD010440)., Funder: Mechanobiology Institute, Singapore; Id: http://dx.doi.org/10.13039/501100007672, Funder: Council for Higher Education; Id: http://dx.doi.org/10.13039/501100005385, Funder: Tel Aviv University; Id: http://dx.doi.org/10.13039/501100004375, Actin dynamics play an important role in tissue morphogenesis, yet the control of actin filament growth takes place at the molecular level. A challenge in the field is to link the molecular function of actin regulators with their physiological function. Here, we report an in vivo role of the actin-capping protein CAP-1 in the Caenorhabditis elegans germline. We show that CAP-1 is associated with actomyosin structures in the cortex and rachis, and its depletion or overexpression led to severe structural defects in the syncytial germline and oocytes. A 60% reduction in the level of CAP-1 caused a twofold increase in F-actin and non-muscle myosin II activity, and laser incision experiments revealed an increase in rachis contractility. Cytosim simulations pointed to increased myosin as the main driver of increased contractility following loss of actin-capping protein. Double depletion of CAP-1 and myosin or Rho kinase demonstrated that the rachis architecture defects associated with CAP-1 depletion require contractility of the rachis actomyosin corset. Thus, we uncovered a physiological role for actin-capping protein in regulating actomyosin contractility to maintain reproductive tissue architecture.

Published

2023

16. Jack of all trades: functional modularity in the adherens junction.

Author

Padmanabhan, Anup, Rao, Megha Vaman, Wu, Yao, and Zaidel-Bar, Ronen

Subjects

*ADHERENS junctions, *CYTOSKELETON, *CELLULAR signal transduction, *CELL communication, *ACTOMYOSIN, *CELL physiology, *CELL differentiation

Abstract

Adherens junctions, broadly defined as attachment sites in which cadherin adhesion receptors connect the actin cytoskeletons of neighboring animal cells, are multi-tasking by nature. In addition to mediating cell–cell adhesion and providing the tissue with mechanical continuity and barrier function, they maintain polarity, are sites of mechanosensing and signaling, and they regulate actomyosin dynamics and can thus generate forces to drive morphogenesis. Here we propose that the key to performing such diverse tasks is the integration within the cadherin adhesome of functional modules that evolved independently to perform other duties within the cell, and we discuss three such functional modules: force transmission, actin dynamics regulation, and contractile force generation. We compare each module to a more ancient cellular structure with similar function, identify shared components, and speculate on how the module was integrated into the cadherin adhesome. [ABSTRACT FROM AUTHOR]

Published

2015