Your search keyword '"Actomyosin genetics"' showing total 170 results

1. MYH10 activation rescues contractile defects in arrhythmogenic cardiomyopathy (ACM).

Author

García-Quintáns N, Sacristán S, Márquez-López C, Sánchez-Ramos C, Martinez-de-Benito F, Siniscalco D, González-Guerra A, Camafeita E, Roche-Molina M, Lytvyn M, Morera D, Guillen MI, Sanguino MA, Sanz-Rosa D, Martín-Pérez D, Garcia R, and Bernal JA

Subjects

Humans, Actomyosin genetics, Mutation, Plakophilins genetics, Plakophilins metabolism, Arrhythmogenic Right Ventricular Dysplasia genetics, Arrhythmogenic Right Ventricular Dysplasia metabolism, Cardiomyopathies genetics

Abstract

The most prevalent genetic form of inherited arrhythmogenic cardiomyopathy (ACM) is caused by mutations in desmosomal plakophilin-2 (PKP2). By studying pathogenic deletion mutations in the desmosomal protein PKP2, here we identify a general mechanism by which PKP2 delocalization restricts actomyosin network organization and cardiac sarcomeric contraction in this untreatable disease. Computational modeling of PKP2 variants reveals that the carboxy-terminal (CT) domain is required for N-terminal domain stabilization, which determines PKP2 cortical localization and function. In mutant PKP2 cells the expression of the interacting protein MYH10 rescues actomyosin disorganization. Conversely, dominant-negative MYH10 mutant expression mimics the pathogenic CT-deletion PKP2 mutant causing actin network abnormalities and right ventricle systolic dysfunction. A chemical activator of non-muscle myosins, 4-hydroxyacetophenone (4-HAP), also restores normal contractility. Our findings demonstrate that activation of MYH10 corrects the deleterious effect of PKP2 mutant over systolic cardiac contraction, with potential implications for ACM therapy., (© 2023. Springer Nature Limited.)

Published

2023

2. Microtubules oppose cortical actomyosin-driven membrane ingression during C. elegans meiosis I polar body extrusion.

Author

Quiogue AR, Sumiyoshi E, Fries A, Chuang CH, and Bowerman B

Subjects

Animals, Caenorhabditis elegans genetics, Caenorhabditis elegans metabolism, Polar Bodies, Cytokinesis genetics, Spindle Apparatus genetics, Spindle Apparatus metabolism, Microtubules genetics, Microtubules metabolism, Meiosis genetics, Oocytes metabolism, Paclitaxel, Microtubule-Associated Proteins genetics, Actomyosin genetics, Actomyosin metabolism, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism

Abstract

During C. elegans oocyte meiosis I cytokinesis and polar body extrusion, cortical actomyosin is locally remodeled to assemble a contractile ring that forms within and remains part of a much larger and actively contractile cortical actomyosin network. This network both mediates contractile ring dynamics and generates shallow ingressions throughout the oocyte cortex during polar body extrusion. Based on our analysis of requirements for CLS-2, a member of the CLASP family of proteins that stabilize microtubules, we recently proposed that a balance of actomyosin-mediated tension and microtubule-mediated stiffness limits membrane ingression throughout the oocyte during meiosis I polar body extrusion. Here, using live cell imaging and fluorescent protein fusions, we show that CLS-2 is part of a group of kinetochore proteins, including the scaffold KNL-1 and the kinase BUB-1, that also co-localize during meiosis I to structures called linear elements, which are present within the assembling oocyte spindle and also are distributed throughout the oocyte in proximity to, but appearing to underlie, the actomyosin cortex. We further show that KNL-1 and BUB-1, like CLS-2, promote the proper organization of sub-cortical microtubules and also limit membrane ingression throughout the oocyte. Moreover, nocodazole or taxol treatment to destabilize or stabilize oocyte microtubules leads to, respectively, excess or decreased membrane ingression throughout the oocyte. Furthermore, taxol treatment, and genetic backgrounds that elevate the levels of cortically associated microtubules, both suppress excess membrane ingression in cls-2 mutant oocytes. We propose that linear elements influence the organization of sub-cortical microtubules to generate a stiffness that limits cortical actomyosin-driven membrane ingression throughout the oocyte during meiosis I polar body extrusion. We discuss the possibility that this regulation of sub-cortical microtubule dynamics facilitates actomyosin contractile ring dynamics during C. elegans oocyte meiosis I cell division., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Quiogue et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

3. Human Endonuclease ANKLE1 Localizes at the Midbody and Processes Chromatin Bridges to Prevent DNA Damage and cGAS-STING Activation.

Author

Jiang H, Kong N, Liu Z, West SC, and Chan YW

Subjects

Animals, Humans, Actomyosin genetics, Actomyosin metabolism, Cell Nucleus metabolism, DNA metabolism, DNA Damage, Caenorhabditis elegans genetics, Caenorhabditis elegans metabolism, Chromatin, Endonucleases chemistry, Endonucleases genetics, Endonucleases metabolism

Abstract

Chromatin bridges connecting the two segregating daughter nuclei arise from chromosome fusion or unresolved interchromosomal linkage. Persistent chromatin bridges are trapped in the cleavage plane, triggering cytokinesis delay. The trapped bridges occasionally break during cytokinesis, inducing DNA damage and chromosomal rearrangements. Recently, Caenorhabditis elegans LEM-3 and human TREX1 nucleases have been shown to process chromatin bridges. Here, it is shown that ANKLE1 endonuclease, the human ortholog of LEM-3, accumulates at the bulge-like structure of the midbody via its N-terminal ankyrin repeats. Importantly, ANKLE1 -/- knockout cells display an elevated level of G1-specific 53BP1 nuclear bodies, prolonged activation of the DNA damage response, and replication stress. Increased DNA damage observed in ANKLE1 -/- cells is rescued by inhibiting actin polymerization or reducing actomyosin contractility. ANKLE1 does not act in conjunction with structure-selective endonucleases, GEN1 and MUS81 in resolving recombination intermediates. Instead, ANKLE1 acts on chromatin bridges by priming TREX1 nucleolytic activity and cleaving bridge DNA to prevent the formation of micronuclei and cytosolic dsDNA that activate the cGAS-STING pathway. It is therefore proposed that ANKLE1 prevents DNA damage and autoimmunity by cleaving chromatin bridges to avoid catastrophic breakage mediated by actomyosin contractile forces., (© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

4. Zyxin contributes to coupling between cell junctions and contractile actomyosin networks during apical constriction.

Author

Slabodnick MM, Tintori SC, Prakash M, Zhang P, Higgins CD, Chen AH, Cupp TD, Wong T, Bowie E, Jug F, and Goldstein B

Subjects

Animals, Zyxin genetics, Zyxin metabolism, Constriction, Proteomics, Intercellular Junctions genetics, Intercellular Junctions metabolism, Morphogenesis genetics, Actomyosin genetics, Actomyosin metabolism, Caenorhabditis elegans metabolism

Abstract

One of the most common cell shape changes driving morphogenesis in diverse animals is the constriction of the apical cell surface. Apical constriction depends on contraction of an actomyosin network in the apical cell cortex, but such actomyosin networks have been shown to undergo continual, conveyor belt-like contractions before the shrinking of an apical surface begins. This finding suggests that apical constriction is not necessarily triggered by the contraction of actomyosin networks, but rather can be triggered by unidentified, temporally-regulated mechanical links between actomyosin and junctions. Here, we used C. elegans gastrulation as a model to seek genes that contribute to such dynamic linkage. We found that α-catenin and β-catenin initially failed to move centripetally with contracting cortical actomyosin networks, suggesting that linkage is regulated between intact cadherin-catenin complexes and actomyosin. We used proteomic and transcriptomic approaches to identify new players, including the candidate linkers AFD-1/afadin and ZYX-1/zyxin, as contributing to C. elegans gastrulation. We found that ZYX-1/zyxin is among a family of LIM domain proteins that have transcripts that become enriched in multiple cells just before they undergo apical constriction. We developed a semi-automated image analysis tool and used it to find that ZYX-1/zyxin contributes to cell-cell junctions' centripetal movement in concert with contracting actomyosin networks. These results identify several new genes that contribute to C. elegans gastrulation, and they identify zyxin as a key protein important for actomyosin networks to effectively pull cell-cell junctions inward during apical constriction. The transcriptional upregulation of ZYX-1/zyxin in specific cells in C. elegans points to one way that developmental patterning spatiotemporally regulates cell biological mechanisms in vivo. Because zyxin and related proteins contribute to membrane-cytoskeleton linkage in other systems, we anticipate that its roles in regulating apical constriction in this manner may be conserved., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Slabodnick et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

5. Novel determinants of cell size homeostasis in the opportunistic yeast Candida albicans.

Author

Chaillot J, Cook MA, and Sellam A

Subjects

Actomyosin genetics, Actomyosin metabolism, Cytokinesis, Cell Size, Fungal Proteins genetics, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Candida albicans, Saccharomyces cerevisiae genetics

Abstract

The basis for commitment to cell division in late G1 phase, called Start in yeast, is a critical but still poorly understood aspect of eukaryotic cell proliferation. Most dividing cells accumulate mass and grow to a critical cell size before traversing the cell cycle. This size threshold couples cell growth to division and thereby establishes long-term size homeostasis. At present, mechanisms involved in cell size homeostasis in fungal pathogens are not well described. Our previous survey of the size phenome in Candida albicans focused on 279 unique mutants enriched mainly in kinases and transcription factors (Sellam et al. PLoS Genet 15:e1008052, 2019). To uncover novel size regulators in C. albicans and highlight potential innovation within cell size control in pathogenic fungi, we expanded our genetic survey of cell size to include 1301 strains from the GRACE (Gene Replacement and Conditional Expression) collection. The current investigation uncovered both known and novel biological processes required for cell size homeostasis in C. albicans. We also confirmed the plasticity of the size control network as few C. albicans size genes overlapped with those of the budding yeast Saccharomyces cerevisiae. Many new size genes of C. albicans were associated with biological processes that were not previously linked to cell size control and offer an opportunity for future investigation. Additional work is needed to understand if mitochondrial activity is a critical element of the metric that dictates cell size in C. albicans and whether modulation of the onset of actomyosin ring constriction is an additional size checkpoint., (© 2022. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2023

6. Muscle LIM Protein Force-Sensing Mediates Sarcomeric Biomechanical Signaling in Human Familial Hypertrophic Cardiomyopathy.

Author

Riaz M, Park J, Sewanan LR, Ren Y, Schwan J, Das SK, Pomianowski PT, Huang Y, Ellis MW, Luo J, Liu J, Song L, Chen IP, Qiu C, Yazawa M, Tellides G, Hwa J, Young LH, Yang L, Marboe CC, Jacoby DL, Campbell SG, and Qyang Y

Subjects

Actomyosin genetics, Humans, LIM Domain Proteins, Mechanotransduction, Cellular, Muscle Proteins, Mutation, Myocytes, Cardiac, Cardiomyopathy, Hypertrophic, Cardiomyopathy, Hypertrophic, Familial

Abstract

Background: Familial hypertrophic cardiomyopathy (HCM) is the most common inherited cardiac disease and is typically caused by mutations in genes encoding sarcomeric proteins that regulate cardiac contractility. HCM manifestations include left ventricular hypertrophy and heart failure, arrythmias, and sudden cardiac death. How dysregulated sarcomeric force production is sensed and leads to pathological remodeling remains poorly understood in HCM, thereby inhibiting the efficient development of new therapeutics., Methods: Our discovery was based on insights from a severe phenotype of an individual with HCM and a second genetic alteration in a sarcomeric mechanosensing protein. We derived cardiomyocytes from patient-specific induced pluripotent stem cells and developed robust engineered heart tissues by seeding induced pluripotent stem cell-derived cardiomyocytes into a laser-cut scaffold possessing native cardiac fiber alignment to study human cardiac mechanobiology at both the cellular and tissue levels. Coupled with computational modeling for muscle contraction and rescue of disease phenotype by gene editing and pharmacological interventions, we have identified a new mechanotransduction pathway in HCM, shown to be essential in modulating the phenotypic expression of HCM in 5 families bearing distinct sarcomeric mutations., Results: Enhanced actomyosin crossbridge formation caused by sarcomeric mutations in cardiac myosin heavy chain ( MYH7 ) led to increased force generation, which, when coupled with slower twitch relaxation, destabilized the MLP (muscle LIM protein) stretch-sensing complex at the Z-disc. Subsequent reduction in the sarcomeric muscle LIM protein level caused disinhibition of calcineurin-nuclear factor of activated T-cells signaling, which promoted cardiac hypertrophy. We demonstrate that the common muscle LIM protein-W4R variant is an important modifier, exacerbating the phenotypic expression of HCM, but alone may not be a disease-causing mutation. By mitigating enhanced actomyosin crossbridge formation through either genetic or pharmacological means, we alleviated stress at the Z-disc, preventing the development of hypertrophy associated with sarcomeric mutations., Conclusions: Our studies have uncovered a novel biomechanical mechanism through which dysregulated sarcomeric force production is sensed and leads to pathological signaling, remodeling, and hypertrophic responses. Together, these establish the foundation for developing innovative mechanism-based treatments for HCM that stabilize the Z-disc MLP-mechanosensory complex.

Published

2022

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

Author

Ready DF and Chang HC

Subjects

Actin Cytoskeleton genetics, Actins metabolism, Actomyosin genetics, Actomyosin metabolism, Animals, Calcium Signaling genetics, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Endoplasmic Reticulum genetics, Pupa, Retina growth & development, Retina metabolism, Actins genetics, Calcium metabolism, Morphogenesis genetics, Stress Fibers genetics

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., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

8. Alveologenesis: What Governs Secondary Septa Formation.

Author

Rippa AL, Alpeeva EV, Vasiliev AV, and Vorotelyak EA

Subjects

Bronchopulmonary Dysplasia genetics, Bronchopulmonary Dysplasia pathology, Cell Lineage genetics, Cytoskeleton genetics, Emphysema genetics, Emphysema pathology, Gases metabolism, Humans, Lung pathology, Mesoderm cytology, Mesoderm metabolism, Myofibroblasts metabolism, Myofibroblasts pathology, Tretinoin metabolism, Actomyosin genetics, Lung growth & development, Organogenesis genetics, Pulmonary Alveoli growth & development

Abstract

The simplification of alveoli leads to various lung pathologies such as bronchopulmonary dysplasia and emphysema. Deep insight into the process of emergence of the secondary septa during development and regeneration after pneumonectomy, and into the contribution of the drivers of alveologenesis and neo-alveolarization is required in an efficient search for therapeutic approaches. In this review, we describe the formation of the gas exchange units of the lung as a multifactorial process, which includes changes in the actomyosin cytoskeleton of alveocytes and myofibroblasts, elastogenesis, retinoic acid signaling, and the contribution of alveolar mesenchymal cells in secondary septation. Knowledge of the mechanistic context of alveologenesis remains incomplete. The characterization of the mechanisms that govern the emergence and depletion of αSMA will allow for an understanding of how the niche of fibroblasts is changing. Taking into account the intense studies that have been performed on the pool of lung mesenchymal cells, we present data on the typing of interstitial fibroblasts and their role in the formation and maintenance of alveoli. On the whole, when identifying cell subpopulations in lung mesenchyme, one has to consider the developmental context, the changing cellular functions, and the lability of gene signatures.

Published

2021

9. Mechanical competition alters the cellular interpretation of an endogenous genetic program.

Author

Bhide S, Gombalova D, Mönke G, Stegmaier J, Zinchenko V, Kreshuk A, Belmonte JM, and Leptin M

Subjects

Actin Cytoskeleton genetics, Actins genetics, Actomyosin genetics, Animals, Cell Shape genetics, Cytoskeleton genetics, Gastrulation genetics, Mesoderm physiology, Drosophila Proteins genetics, Drosophila melanogaster genetics

Abstract

The intrinsic genetic program of a cell is not sufficient to explain all of the cell's activities. External mechanical stimuli are increasingly recognized as determinants of cell behavior. In the epithelial folding event that constitutes the beginning of gastrulation in Drosophila, the genetic program of the future mesoderm leads to the establishment of a contractile actomyosin network that triggers apical constriction of cells and thereby tissue folding. However, some cells do not constrict but instead stretch, even though they share the same genetic program as their constricting neighbors. We show here that tissue-wide interactions force these cells to expand even when an otherwise sufficient amount of apical, active actomyosin is present. Models based on contractile forces and linear stress-strain responses do not reproduce experimental observations, but simulations in which cells behave as ductile materials with nonlinear mechanical properties do. Our models show that this behavior is a general emergent property of actomyosin networks in a supracellular context, in accordance with our experimental observations of actin reorganization within stretching cells., (© 2021 Bhide et al.)

Published

2021

10. Exocytosis by vesicle crumpling maintains apical membrane homeostasis during exocrine secretion.

Author

Kamalesh K, Scher N, Biton T, Schejter ED, Shilo BZ, and Avinoam O

Subjects

Animals, Biological Transport genetics, Cell Membrane genetics, Clathrin genetics, Drosophila melanogaster genetics, Endocytosis genetics, Exocrine Glands metabolism, Homeostasis genetics, Membrane Fusion genetics, Mice, Salivary Glands metabolism, Salivary Glands physiology, Actin Cytoskeleton genetics, Actomyosin genetics, Exocytosis genetics, Secretory Vesicles genetics

Abstract

Exocrine secretion commonly employs micron-scale vesicles that fuse to a limited apical surface, presenting an extreme challenge for maintaining membrane homeostasis. Using Drosophila melanogaster larval salivary glands, we show that the membranes of fused vesicles undergo actomyosin-mediated folding and retention, which prevents them from incorporating into the apical surface. In addition, the diffusion of proteins and lipids between the fused vesicle and the apical surface is limited. Actomyosin contraction and membrane crumpling are essential for recruiting clathrin-mediated endocytosis to clear the retained vesicular membrane. Finally, we also observe membrane crumpling in secretory vesicles of the mouse exocrine pancreas. We conclude that membrane sequestration by crumpling followed by targeted endocytosis of the vesicular membrane, represents a general mechanism of exocytosis that maintains membrane homeostasis in exocrine tissues that employ large secretory vesicles., Competing Interests: Declaration of interests These authors declare no competing interests., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

11. CYK-1/Formin activation in cortical RhoA signaling centers promotes organismal left-right symmetry breaking.

Author

Middelkoop TC, Garcia-Baucells J, Quintero-Cadena P, Pimpale LG, Yazdi S, Sternberg PW, Gross P, and Grill SW

Subjects

Actomyosin genetics, Actomyosin metabolism, Animals, Animals, Genetically Modified, Blastomeres cytology, Blastomeres metabolism, Body Patterning genetics, Caenorhabditis elegans embryology, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Cerebral Cortex embryology, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Formins genetics, Functional Laterality genetics, Functional Laterality physiology, Signal Transduction genetics, Torque, rhoA GTP-Binding Protein genetics, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins metabolism, Cerebral Cortex metabolism, Formins metabolism, Signal Transduction physiology, rhoA GTP-Binding Protein metabolism

Abstract

Proper left-right symmetry breaking is essential for animal development, and in many cases, this process is actomyosin-dependent. In Caenorhabditis elegans embryos active torque generation in the actomyosin layer promotes left-right symmetry breaking by driving chiral counterrotating cortical flows. While both Formins and Myosins have been implicated in left-right symmetry breaking and both can rotate actin filaments in vitro, it remains unclear whether active torques in the actomyosin cortex are generated by Formins, Myosins, or both. We combined the strength of C. elegans genetics with quantitative imaging and thin film, chiral active fluid theory to show that, while Non-Muscle Myosin II activity drives cortical actomyosin flows, it is permissive for chiral counterrotation and dispensable for chiral symmetry breaking of cortical flows. Instead, we find that CYK-1/Formin activation in RhoA foci is instructive for chiral counterrotation and promotes in-plane, active torque generation in the actomyosin cortex. Notably, we observe that artificially generated large active RhoA patches undergo rotations with consistent handedness in a CYK-1/Formin-dependent manner. Altogether, we conclude that CYK-1/Formin-dependent active torque generation facilitates chiral symmetry breaking of actomyosin flows and drives organismal left-right symmetry breaking in the nematode worm., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

12. Adherens junctions are involved in polarized contractile ring formation in dividing epithelial cells of Xenopus laevis embryos.

Author

Hatte G, Prigent C, and Tassan JP

Subjects

Actin Cytoskeleton genetics, Actomyosin genetics, Animals, Cell Division genetics, Cell Polarity genetics, Contractile Proteins genetics, Cytokinesis genetics, Embryo, Nonmammalian, Epithelial Cells cytology, Xenopus laevis growth & development, Adherens Junctions genetics, Embryonic Development genetics, Epithelial Cells metabolism, Xenopus laevis genetics

Abstract

Cells dividing in the plane of epithelial tissues proceed by polarized constriction of the actomyosin contractile ring, leading to asymmetric ingression of the plasma mem brane. Asymmetric cytokinesis results in the apical positioning of the actomyosin contractile ring and ultimately of the midbody. Studies have indicated that the contractile ring is associated with adherens junctions, whose role is to maintain epithelial tissue cohesion. However, it is yet unknown when the contractile ring becomes associated with adherens junctions in epithelial cells. Here, we examined contractile ring formation and activation in the epithelium of Xenopus embryos and explored the implication of adherens junctions in the contractile ring formation. We show that accumulation of proteins involved in contractile ring formation and activation is polarized, starting at apical cell-cell contacts at the presumptive division site and spreading within seconds towards the cell basal side. We also show that adherens junctions are involved in the kinetics of contractile ring formation. Our study reveals that the link between the adherens junctions and the contractile ring is established from the onset of cytokinesis., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

13. Reconstitution of contractile actomyosin rings in vesicles.

Author

Litschel T, Kelley CF, Holz D, Adeli Koudehi M, Vogel SK, Burbaum L, Mizuno N, Vavylonis D, and Schwille P

Subjects

Actomyosin genetics, Actomyosin isolation & purification, Animals, Cell Line, Drosophila, Humans, Intravital Microscopy, Microscopy, Confocal, Models, Molecular, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Actomyosin metabolism, Cell Division physiology, Models, Biological, Synthetic Biology methods, Unilamellar Liposomes metabolism

Abstract

One of the grand challenges of bottom-up synthetic biology is the development of minimal machineries for cell division. The mechanical transformation of large-scale compartments, such as Giant Unilamellar Vesicles (GUVs), requires the geometry-specific coordination of active elements, several orders of magnitude larger than the molecular scale. Of all cytoskeletal structures, large-scale actomyosin rings appear to be the most promising cellular elements to accomplish this task. Here, we have adopted advanced encapsulation methods to study bundled actin filaments in GUVs and compare our results with theoretical modeling. By changing few key parameters, actin polymerization can be differentiated to resemble various types of networks in living cells. Importantly, we find membrane binding to be crucial for the robust condensation into a single actin ring in spherical vesicles, as predicted by theoretical considerations. Upon force generation by ATP-driven myosin motors, these ring-like actin structures contract and locally constrict the vesicle, forming furrow-like deformations. On the other hand, cortex-like actin networks are shown to induce and stabilize deformations from spherical shapes.

Published

2021

14. A mechanogenetic role for the actomyosin complex in branching morphogenesis of epithelial organs.

Author

Kim JM, Jo Y, Jung JW, and Park K

Subjects

Actin Cytoskeleton ultrastructure, Actins genetics, Actins ultrastructure, Actomyosin ultrastructure, Acyltransferases genetics, Adaptor Proteins, Signal Transducing genetics, Animals, Epithelial Cells metabolism, Epithelium growth & development, Epithelium metabolism, Humans, Mechanotransduction, Cellular genetics, Mice, Regeneration genetics, Submandibular Gland metabolism, YAP-Signaling Proteins, Actin Cytoskeleton genetics, Actomyosin genetics, Morphogenesis genetics, Muscle Contraction genetics

Abstract

The actomyosin complex plays crucial roles in various life processes by balancing the forces generated by cellular components. In addition to its physical function, the actomyosin complex participates in mechanotransduction. However, the exact role of actomyosin contractility in force transmission and the related transcriptional changes during morphogenesis are not fully understood. Here, we report a mechanogenetic role of the actomyosin complex in branching morphogenesis using an organotypic culture system of mouse embryonic submandibular glands. We dissected the physical factors arranged by characteristic actin structures in developing epithelial buds and identified the spatial distribution of forces that is essential for buckling mechanism to promote the branching process. Moreover, the crucial genes required for the distribution of epithelial progenitor cells were regulated by YAP and TAZ through a mechanotransduction process in epithelial organs. These findings are important for our understanding of the physical processes involved in the development of epithelial organs and provide a theoretical background for developing new approaches for organ regeneration., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

15. High-Resolution Cryo-EM Structure of the Cardiac Actomyosin Complex.

Author

Risi C, Schäfer LU, Belknap B, Pepper I, White HD, Schröder GF, and Galkin VE

Subjects

Actins chemistry, Actins genetics, Actins metabolism, Actomyosin genetics, Actomyosin metabolism, Animals, Cryoelectron Microscopy standards, Limit of Detection, Molecular Dynamics Simulation, Mutation, Myocardium ultrastructure, Myosins chemistry, Myosins genetics, Myosins metabolism, Protein Domains, Swine, Actomyosin chemistry, Myocardium chemistry

Abstract

Heart contraction depends on a complicated array of interactions between sarcomeric proteins required to convert chemical energy into mechanical force. Cyclic interactions between actin and myosin molecules, controlled by troponin and tropomyosin, generate the sliding force between the actin-based thin and myosin-based thick filaments. Alterations in this sophisticated system due to missense mutations can lead to cardiovascular diseases. Numerous structural studies proposed pathological mechanisms of missense mutations at the myosin-myosin, actin-tropomyosin, and tropomyosin-troponin interfaces. However, despite the central role of actomyosin interactions a detailed structural description of the cardiac actomyosin interface remained unknown. Here, we report a cryo-EM structure of a cardiac actomyosin complex at 3.8 Å resolution. The structure reveals the molecular basis of cardiac diseases caused by missense mutations in myosin and actin proteins., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

16. The function of apolipoproteins L (APOLs): relevance for kidney disease, neurotransmission disorders, cancer and viral infection.

Author

Pays E

Subjects

Actomyosin genetics, Actomyosin metabolism, Animals, Apolipoprotein L1 metabolism, Apolipoproteins L metabolism, Autistic Disorder metabolism, Autistic Disorder pathology, Autophagosomes metabolism, Calcium metabolism, Gene Expression Regulation, Golgi Apparatus metabolism, Humans, Neoplasms metabolism, Neoplasms pathology, Phosphatidylinositol Phosphates metabolism, Phosphotransferases (Alcohol Group Acceptor) genetics, Phosphotransferases (Alcohol Group Acceptor) metabolism, Renal Insufficiency metabolism, Renal Insufficiency pathology, Schizophrenia metabolism, Schizophrenia pathology, Trypanosomiasis, African drug therapy, Trypanosomiasis, African genetics, Trypanosomiasis, African metabolism, Trypanosomiasis, African parasitology, Virus Diseases metabolism, Virus Diseases pathology, Apolipoprotein L1 genetics, Apolipoproteins L genetics, Autistic Disorder genetics, Neoplasms genetics, Renal Insufficiency genetics, Schizophrenia genetics, Virus Diseases genetics

Abstract

The discovery that apolipoprotein L1 (APOL1) is the trypanolytic factor of human serum raised interest about the function of APOLs, especially following the unexpected finding that in addition to their protective action against sleeping sickness, APOL1 C-terminal variants also cause kidney disease. Based on the analysis of the structure and trypanolytic activity of APOL1, it was proposed that APOLs could function as ion channels of intracellular membranes and be involved in mechanisms triggering programmed cell death. In this review, the recent finding that APOL1 and APOL3 inversely control the synthesis of phosphatidylinositol-4-phosphate (PI(4)P) by the Golgi PI(4)-kinase IIIB (PI4KB) is commented. APOL3 promotes Ca 2+ -dependent activation of PI4KB, but due to their increased interaction with APOL3, APOL1 C-terminal variants can inactivate APOL3, leading to reduction of Golgi PI(4)P synthesis. The impact of APOLs on several pathological processes that depend on Golgi PI(4)P levels is discussed. I propose that through their effect on PI4KB activity, APOLs control not only actomyosin activities related to vesicular trafficking, but also the generation and elongation of autophagosomes induced by inflammation., (© 2020 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2021

17. Unraveling a Force-Generating Allosteric Pathway of Actomyosin Communication Associated with ADP and P i Release.

Author

Franz P, Ewert W, Preller M, and Tsiavaliaris G

Subjects

Actomyosin genetics, Adenosine Triphosphate chemistry, Allosteric Regulation, Dictyostelium genetics, Protozoan Proteins genetics, Actomyosin chemistry, Adenosine Diphosphate chemistry, Dictyostelium chemistry, Phosphates chemistry, Protozoan Proteins chemistry

Abstract

The actomyosin system generates mechanical work with the execution of the power stroke, an ATP-driven, two-step rotational swing of the myosin-neck that occurs post ATP hydrolysis during the transition from weakly to strongly actin-bound myosin states concomitant with P i release and prior to ADP dissociation. The activating role of actin on product release and force generation is well documented; however, the communication paths associated with weak-to-strong transitions are poorly characterized. With the aid of mutant analyses based on kinetic investigations and simulations, we identified the W-helix as an important hub coupling the structural changes of switch elements during ATP hydrolysis to temporally controlled interactions with actin that are passed to the central transducer and converter. Disturbing the W-helix/transducer pathway increased actin-activated ATP turnover and reduced motor performance as a consequence of prolonged duration of the strongly actin-attached states. Actin-triggered P i release was accelerated, while ADP release considerably decelerated, both limiting maximum ATPase, thus transforming myosin-2 into a high-duty-ratio motor. This kinetic signature of the mutant allowed us to define the fractional occupancies of intermediate states during the ATPase cycle providing evidence that myosin populates a cleft-closure state of strong actin interaction during the weak-to-strong transition with bound hydrolysis products before accomplishing the power stroke.

Published

2020

18. Ciona embryonic tail bending is driven by asymmetrical notochord contractility and coordinated by epithelial proliferation.

Author

Lu Q, Gao Y, Fu Y, Peng H, Shi W, Li B, Lv Z, Feng XQ, and Dong B

Subjects

Actomyosin metabolism, Animals, Cell Proliferation genetics, Ciona embryology, Ciona genetics, Ciona growth & development, Epithelial Cells metabolism, Muscle Contraction physiology, Notochord embryology, Notochord growth & development, Tail embryology, Actomyosin genetics, Morphogenesis genetics, Tail growth & development

Abstract

Ventral bending of the embryonic tail within the chorion is an evolutionarily conserved morphogenetic event in both invertebrates and vertebrates. However, the complexity of the anatomical structure of vertebrate embryos makes it difficult to experimentally identify the mechanisms underlying embryonic folding. This study investigated the mechanisms underlying embryonic tail bending in chordates. To further understand the mechanical role of each tissue, we also developed a physical model with experimentally measured parameters to simulate embryonic tail bending. Actomyosin asymmetrically accumulated at the ventral side of the notochord, and cell proliferation of the dorsal tail epidermis was faster than that in the ventral counterpart during embryonic tail bending. Genetic disruption of actomyosin activity and inhibition of cell proliferation dorsally caused abnormal tail bending, indicating that both asymmetrical actomyosin contractility in the notochord and the discrepancy of epidermis cell proliferation are required for tail bending. In addition, asymmetrical notochord contractility was sufficient to drive embryonic tail bending, whereas differential epidermis proliferation was a passive response to mechanical forces. These findings showed that asymmetrical notochord contractility coordinates with differential epidermis proliferation mechanisms to drive embryonic tail bending.This article has an associated 'The people behind the papers' interview., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

19. The Aspergillus nidulans IQGAP orthologue SepG is required for constriction of the contractile actomyosin ring.

Author

Hill TW, Wendt KE, Jones DA, Williamson MH, Ugwu UJ, Rowland LB, and Jackson-Hayes L

Subjects

Actin Cytoskeleton genetics, Binding Sites, Calmodulin genetics, Constriction, Cytokinesis genetics, Mutation genetics, Myosin Light Chains genetics, Myosin Type II genetics, Protein Binding genetics, Actomyosin genetics, Aspergillus nidulans genetics, Contractile Proteins genetics, ras GTPase-Activating Proteins genetics

Abstract

In this research we report that the sepG1 mutation in Aspergillus nidulans resides in gene AN9463, which is predicted to encode an IQGAP orthologue. The genetic lesion is predicted to result in a G-to-R substitution at residue 1637 of the 1737-residue protein in a highly conserved region of the RasGAP-C-terminal (RGCT) domain. When grown at restrictive temperature, strains expressing the sepG G1637R (sepG1) allele are aseptate, with reduced colony growth and aberrantly formed conidiophores. The aseptate condition can be replicated by deletion of AN9463 or by downregulating its expression via introduced promoters. The mutation does not prevent assembly of a cortical contractile actomyosin ring (CAR) at putative septation sites, but tight compaction of the rings is impaired and the rings fail to constrict. Both GFP::SepG wild type and the GFP-tagged product of the sepG1 allele localize to the CAR at both permissive and restrictive temperatures. Downregulation of myoB (encoding the A. nidulans type-II myosin heavy chain) does not prevent formation of SepG rings at septation sites, but filamentous actin is required for CAR localization of SepG and MyoB. We identify fourteen probable IQ-motifs (EF-hand protein binding sites) in the predicted SepG sequence. Two of the A. nidulans EF-hand proteins, myosin essential light chain (AnCdc4) and myosin regulatory light chain (MrlC), colocalize with SepG and MyoB at all stages of CAR formation and constriction. However, calmodulin (CamA) appears at septation sites only after the CAR has become fully compacted. When expression of sepG is downregulated, leaving MyoB as the sole IQ-motif protein in the pre-compaction CAR, both MrlC and AnCdc4 continue to associate with the forming CAR. When myoB expression is downregulated, leaving SepG as the sole IQ-motif protein in the CAR, AnCdc4 association with the forming CAR continues but MrlC fails to associate. This supports a model in which the IQ motifs of MyoB bind both MrlC and AnCdc4, while the IQ motifs of SepG bind only AnCdc4. Downregulation of either mrlC or Ancdc4 results in an aseptate phenotype, but has no effect on association of either SepG or MyoB with the CAR., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

20. A novel checkpoint pathway controls actomyosin ring constriction trigger in fission yeast.

Author

Edreira T, Celador R, Manjón E, and Sánchez Y

Subjects

Actomyosin genetics, Cytokinesis, Guanine Nucleotide Exchange Factors genetics, Guanine Nucleotide Exchange Factors metabolism, Mitogen-Activated Protein Kinases genetics, Mitogen-Activated Protein Kinases metabolism, Schizosaccharomyces genetics, Schizosaccharomyces pombe Proteins genetics, Schizosaccharomyces pombe Proteins metabolism, Actomyosin metabolism, Schizosaccharomyces cytology, Schizosaccharomyces metabolism

Abstract

In fission yeast, the septation initiation network (SIN) ensures temporal coordination between actomyosin ring (CAR) constriction with membrane ingression and septum synthesis. However, questions remain about CAR regulation under stress conditions. We show that Rgf1p (Rho1p GEF), participates in a delay of cytokinesis under cell wall stress (blankophor, BP). BP did not interfere with CAR assembly or the rate of CAR constriction, but did delay the onset of constriction in the wild type cells but not in the rgf1 Δ cells. This delay was also abolished in the absence of Pmk1p, the MAPK of the cell integrity pathway (CIP), leading to premature abscission and a multi-septated phenotype. Moreover, cytokinesis delay correlates with maintained SIN signaling and depends on the SIN to be achieved. Thus, we propose that the CIP participates in a checkpoint, capable of triggering a CAR constriction delay through the SIN pathway to ensure that cytokinesis terminates successfully., Competing Interests: TE, RC, EM, YS No competing interests declared, (© 2020, Edreira et al.)

Published

2020

21. E-cadherin focuses protrusion formation at the front of migrating cells by impeding actin flow.

Author

Grimaldi C, Schumacher I, Boquet-Pujadas A, Tarbashevich K, Vos BE, Bandemer J, Schick J, Aalto A, Olivo-Marin JC, Betz T, and Raz E

Subjects

Actins genetics, Actomyosin genetics, Actomyosin metabolism, Animals, Cadherins genetics, Female, Germ Cells metabolism, Male, Pseudopodia genetics, Zebrafish genetics, Zebrafish Proteins genetics, Actins metabolism, Cadherins metabolism, Cell Movement, Germ Cells cytology, Pseudopodia metabolism, Zebrafish metabolism, Zebrafish Proteins metabolism

Abstract

The migration of many cell types relies on the formation of actomyosin-dependent protrusions called blebs, but the mechanisms responsible for focusing this kind of protrusive activity to the cell front are largely unknown. Here, we employ zebrafish primordial germ cells (PGCs) as a model to study the role of cell-cell adhesion in bleb-driven single-cell migration in vivo. Utilizing a range of genetic, reverse genetic and mathematical tools, we define a previously unknown role for E-cadherin in confining bleb-type protrusions to the leading edge of the cell. We show that E-cadherin-mediated frictional forces impede the backwards flow of actomyosin-rich structures that define the domain where protrusions are preferentially generated. In this way, E-cadherin confines the bleb-forming region to a restricted area at the cell front and reinforces the front-rear axis of migrating cells. Accordingly, when E-cadherin activity is reduced, the bleb-forming area expands, thus compromising the directional persistence of the cells.

Published

2020

22. SHROOM3 is downstream of the planar cell polarity pathway and loss-of-function results in congenital heart defects.

Author

Durbin MD, O'Kane J, Lorentz S, Firulli AB, and Ware SM

Subjects

Actomyosin genetics, Actomyosin metabolism, Animals, Dishevelled Proteins genetics, Dishevelled Proteins metabolism, Heart Defects, Congenital genetics, Heart Defects, Congenital pathology, Heart Septum pathology, Mice, Mice, Transgenic, Microfilament Proteins genetics, Myocardium metabolism, Myocardium pathology, Myocytes, Cardiac pathology, Neural Crest metabolism, Neural Crest pathology, Cell Polarity, Heart Defects, Congenital embryology, Heart Septum embryology, Microfilament Proteins metabolism, Myocytes, Cardiac metabolism, Signal Transduction

Abstract

Congenital heart disease (CHD) is the most common birth defect, and the leading cause of death due to birth defects, yet causative molecular mechanisms remain mostly unknown. We previously implicated a novel CHD candidate gene, SHROOM3, in a patient with CHD. Using a Shroom3 gene trap knockout mouse (Shroom3 gt/gt ) we demonstrate that SHROOM3 is downstream of the noncanonical Wnt planar cell polarity signaling pathway (PCP) and loss-of-function causes cardiac defects. We demonstrate Shroom3 expression within cardiomyocytes of the ventricles and interventricular septum from E10.5 onward, as well as within cardiac neural crest cells and second heart field cells that populate the cardiac outflow tract. We demonstrate that Shroom3 gt/gt mice exhibit variable penetrance of a spectrum of CHDs that include ventricular septal defects, double outlet right ventricle, and thin left ventricular myocardium. This CHD spectrum phenocopies what is observed with disrupted PCP. We show that during cardiac development SHROOM3 interacts physically and genetically with, and is downstream of, key PCP signaling component Dishevelled 2. Within Shroom3 gt/gt hearts we demonstrate disrupted terminal PCP components, actomyosin cytoskeleton, cardiomyocyte polarity, organization, proliferation and morphology. Together, these data demonstrate SHROOM3 functions during cardiac development as an actomyosin cytoskeleton effector downstream of PCP signaling, revealing SHROOM3's novel role in cardiac development and CHD., Competing Interests: Declaration of competing interest The authors declare no conflict of interest., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

23. Fission yeast Pak1 phosphorylates anillin-like Mid1 for spatial control of cytokinesis.

Author

Magliozzi JO, Sears J, Cressey L, Brady M, Opalko HE, Kettenbach AN, and Moseley JB

Subjects

Actomyosin genetics, Actomyosin metabolism, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, GTP-Binding Proteins genetics, GTP-Binding Proteins metabolism, Gene Expression Regulation, Fungal, Mutation, Phosphorylation, Schizosaccharomyces genetics, Schizosaccharomyces pombe Proteins genetics, Signal Transduction, Time Factors, p21-Activated Kinases genetics, Cytokinesis, Schizosaccharomyces enzymology, Schizosaccharomyces pombe Proteins metabolism, p21-Activated Kinases metabolism

Abstract

Protein kinases direct polarized growth by regulating the cytoskeleton in time and space and could play similar roles in cell division. We found that the Cdc42-activated polarity kinase Pak1 colocalizes with the assembling contractile actomyosin ring (CAR) and remains at the division site during septation. Mutations in pak1 led to defects in CAR assembly and genetic interactions with cytokinesis mutants. Through a phosphoproteomic screen, we identified novel Pak1 substrates that function in polarized growth and cytokinesis. For cytokinesis, we found that Pak1 regulates the localization of its substrates Mid1 and Cdc15 to the CAR. Mechanistically, Pak1 phosphorylates the Mid1 N-terminus to promote its association with cortical nodes that act as CAR precursors. Defects in Pak1-Mid1 signaling lead to misplaced and defective division planes, but these phenotypes can be rescued by synthetic tethering of Mid1 to cortical nodes. Our work defines a new signaling mechanism driven by a cell polarity kinase that promotes CAR assembly in the correct time and place., (© 2020 Magliozzi et al.)

Published

2020

24. Tug-of-war between actomyosin-driven antagonistic forces determines the positioning symmetry in cell-sized confinement.

Author

Sakamoto R, Tanabe M, Hiraiwa T, Suzuki K, Ishiwata S, Maeda YT, and Miyazaki M

Subjects

Actomyosin genetics, Animals, Biomechanical Phenomena, Cell Membrane chemistry, Cell Membrane genetics, Cell Membrane metabolism, Cell Size, Cytoplasm chemistry, Cytoplasm metabolism, Ovum chemistry, Xenopus, Actomyosin chemistry, Actomyosin metabolism, Cell Division, Ovum cytology

Abstract

Symmetric or asymmetric positioning of intracellular structures including the nucleus and mitotic spindle steers various biological processes such as cell migration, division, and embryogenesis. In typical animal cells, both a sparse actomyosin meshwork in the cytoplasm and a dense actomyosin cortex underneath the cell membrane participate in the intracellular positioning. However, it remains unclear how these coexisting actomyosin structures regulate the positioning symmetry. To reveal the potential mechanism, we construct an in vitro model composed of cytoplasmic extracts and nucleus-like clusters confined in droplets. Here we find that periodic centripetal actomyosin waves contract from the droplet boundary push clusters to the center in large droplets, while network percolation of bulk actomyosin pulls clusters to the edge in small droplets. An active gel model quantitatively reproduces molecular perturbation experiments, which reveals that the tug-of-war between two distinct actomyosin networks with different maturation time-scales determines the positioning symmetry.

Published

2020

25. Targeting Actomyosin Contractility Suppresses Malignant Phenotypes of Acute Myeloid Leukemia Cells.

Author

Chang F, Kong SJ, Wang L, Choi BK, Lee H, Kim C, Kim JM, and Park K

Subjects

Actin Cytoskeleton genetics, Adaptor Proteins, Signal Transducing genetics, Cell Adhesion genetics, Cell Division genetics, Cell Line, Tumor, Cell Movement genetics, Gene Expression Regulation, Neoplastic genetics, Humans, Leukemia, Myeloid, Acute pathology, Mechanotransduction, Cellular genetics, Phosphorylation, Transcription Factors genetics, YAP-Signaling Proteins, Actomyosin genetics, Contractile Proteins genetics, Leukemia, Myeloid, Acute genetics, Myosin Heavy Chains genetics

Abstract

Actomyosin-mediated contractility is required for the majority of force-driven cellular events such as cell division, adhesion, and migration. Under pathological conditions, the role of actomyosin contractility in malignant phenotypes of various solid tumors has been extensively discussed, but the pathophysiological relevance in hematopoietic malignancies has yet to be elucidated. In this study, we found enhanced actomyosin contractility in diverse acute myeloid leukemia (AML) cell lines represented by highly expressed non-muscle myosin heavy chain A (NMIIA) and increased phosphorylation of the myosin regulatory light chain. Genetic and pharmacological inhibition of actomyosin contractility induced multivalent malignancy- suppressive effects in AML cells. In this context, perturbed actomyosin contractility enhances AML cell apoptosis through cytokinesis failure and aryl hydrocarbon receptor activation. Moreover, leukemic oncogenes were downregulated by the YAP/TAZ-mediated mechanotransduction pathway. Our results provide a theoretical background for targeting actomyosin contractility to suppress the malignancy of AML cells.

Published

2020

26. Afadin regulates actomyosin organization through αE-catenin at adherens junctions.

Author

Sakakibara S, Mizutani K, Sugiura A, Sakane A, Sasaki T, Yonemura S, and Takai Y

Subjects

Actin Cytoskeleton genetics, Actin Cytoskeleton ultrastructure, Actins genetics, Actomyosin genetics, Actomyosin ultrastructure, Adherens Junctions ultrastructure, Animals, Humans, Mice, Mice, Knockout, Multiprotein Complexes genetics, Multiprotein Complexes ultrastructure, Protein Binding genetics, Vinculin genetics, alpha Catenin genetics, alpha Catenin ultrastructure, Adherens Junctions genetics, Cadherins genetics, Microfilament Proteins genetics, beta Catenin genetics

Abstract

Actomyosin-undercoated adherens junctions are critical for epithelial cell integrity and remodeling. Actomyosin associates with adherens junctions through αE-catenin complexed with β-catenin and E-cadherin in vivo; however, in vitro biochemical studies in solution showed that αE-catenin complexed with β-catenin binds to F-actin less efficiently than αE-catenin that is not complexed with β-catenin. Although a "catch-bond model" partly explains this inconsistency, the mechanism for this inconsistency between the in vivo and in vitro results remains elusive. We herein demonstrate that afadin binds to αE-catenin complexed with β-catenin and enhances its F-actin-binding activity in a novel mechanism, eventually inducing the proper actomyosin organization through αE-catenin complexed with β-catenin and E-cadherin at adherens junctions., (© 2020 Sakakibara et al.)

Published

2020

27. Radial contractility of actomyosin rings facilitates axonal trafficking and structural stability.

Author

Wang T, Li W, Martin S, Papadopulos A, Joensuu M, Liu C, Jiang A, Shamsollahi G, Amor R, Lanoue V, Padmanabhan P, and Meunier FA

Subjects

Actin Cytoskeleton genetics, Actins genetics, Actins metabolism, Actomyosin metabolism, Animals, Autophagosomes genetics, Axonal Transport genetics, Axons metabolism, Cell Movement genetics, Contractile Proteins genetics, Growth Cones metabolism, Microtubules genetics, Microtubules ultrastructure, Muscle Contraction genetics, Neurons ultrastructure, Protein Transport genetics, Rats, Actin Cytoskeleton ultrastructure, Actomyosin genetics, Autophagosomes ultrastructure, Axons ultrastructure, Neurons metabolism

Abstract

Most mammalian neurons have a narrow axon, which constrains the passage of large cargoes such as autophagosomes that can be larger than the axon diameter. Radial axonal expansion must therefore occur to ensure efficient axonal trafficking. In this study, we reveal that the speed of various large cargoes undergoing axonal transport is significantly slower than that of small ones and that the transit of diverse-sized cargoes causes an acute, albeit transient, axonal radial expansion, which is immediately restored by constitutive axonal contractility. Using live super-resolution microscopy, we demonstrate that actomyosin-II controls axonal radial contractility and local expansion, and that NM-II filaments associate with periodic F-actin rings via their head domains. Pharmacological inhibition of NM-II activity significantly increases axon diameter by detaching the NM-II from F-actin and impacts the trafficking speed, directionality, and overall efficiency of long-range retrograde trafficking. Consequently, prolonged NM-II inactivation leads to disruption of periodic actin rings and formation of focal axonal swellings, a hallmark of axonal degeneration., (© 2020 Wang et al.)

Published

2020

28. LIS1 determines cleavage plane positioning by regulating actomyosin-mediated cell membrane contractility.

Author

Moon HM, Hippenmeyer S, Luo L, and Wynshaw-Boris A

Subjects

1-Alkyl-2-acetylglycerophosphocholine Esterase genetics, Actomyosin genetics, Animals, Cell Death, Cell Membrane, Cells, Cultured, Contractile Proteins genetics, Embryo, Mammalian, Fibroblasts metabolism, Gene Expression Regulation, HEK293 Cells, Humans, Mice, Microtubule-Associated Proteins genetics, Mitosis, Single-Cell Analysis, rhoA GTP-Binding Protein genetics, 1-Alkyl-2-acetylglycerophosphocholine Esterase metabolism, Actomyosin metabolism, Contractile Proteins metabolism, Microtubule-Associated Proteins metabolism, rhoA GTP-Binding Protein metabolism

Abstract

Heterozygous loss of human PAFAH1B1 (coding for LIS1) results in the disruption of neurogenesis and neuronal migration via dysregulation of microtubule (MT) stability and dynein motor function/localization that alters mitotic spindle orientation, chromosomal segregation, and nuclear migration. Recently, human- induced pluripotent stem cell (iPSC) models revealed an important role for LIS1 in controlling the length of terminal cell divisions of outer radial glial (oRG) progenitors, suggesting cellular functions of LIS1 in regulating neural progenitor cell (NPC) daughter cell separation. Here, we examined the late mitotic stages NPCs in vivo and mouse embryonic fibroblasts (MEFs) in vitro from Pafah1b1 -deficient mutants. Pafah1b1 -deficient neocortical NPCs and MEFs similarly exhibited cleavage plane displacement with mislocalization of furrow-associated markers, associated with actomyosin dysfunction and cell membrane hyper-contractility. Thus, it suggests LIS1 acts as a key molecular link connecting MTs/dynein and actomyosin, ensuring that cell membrane contractility is tightly controlled to execute proper daughter cell separation., Competing Interests: HM, SH, LL, AW No competing interests declared, (© 2020, Moon et al.)

Published

2020

29. Trpml controls actomyosin contractility and couples migration to phagocytosis in fly macrophages.

Author

Edwards-Jorquera SS, Bosveld F, Bellaïche YA, Lennon-Duménil AM, and Glavic Á

Subjects

Actomyosin genetics, Animals, Animals, Genetically Modified, Calcium metabolism, Calcium Signaling, Cytoskeleton genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Drosophila melanogaster immunology, Hemocytes immunology, Lysosomes genetics, Macrophages immunology, Myosin Type II genetics, Myosin Type II metabolism, R-SNARE Proteins genetics, R-SNARE Proteins metabolism, Time Factors, Transient Receptor Potential Channels genetics, Actomyosin metabolism, Cell Movement, Cytoskeleton metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Hemocytes metabolism, Lysosomes metabolism, Macrophages metabolism, Phagocytosis, Transient Receptor Potential Channels metabolism

Abstract

Phagocytes use their actomyosin cytoskeleton to migrate as well as to probe their environment by phagocytosis or macropinocytosis. Although migration and extracellular material uptake have been shown to be coupled in some immune cells, the mechanisms involved in such coupling are largely unknown. By combining time-lapse imaging with genetics, we here identify the lysosomal Ca2+ channel Trpml as an essential player in the coupling of cell locomotion and phagocytosis in hemocytes, the Drosophila macrophage-like immune cells. Trpml is needed for both hemocyte migration and phagocytic processing at distinct subcellular localizations: Trpml regulates hemocyte migration by controlling actomyosin contractility at the cell rear, whereas its role in phagocytic processing lies near the phagocytic cup in a myosin-independent fashion. We further highlight that Vamp7 also regulates phagocytic processing and locomotion but uses pathways distinct from those of Trpml. Our results suggest that multiple mechanisms may have emerged during evolution to couple phagocytic processing to cell migration and facilitate space exploration by immune cells., (© 2020 Edwards-Jorquera et al.)

Published

2020

30. Cortical contraction drives the 3D patterning of epithelial cell surfaces.

Author

van Loon AP, Erofeev IS, Maryshev IV, Goryachev AB, and Sagasti A

Subjects

Actin Cytoskeleton genetics, Actomyosin genetics, Animals, Animals, Genetically Modified, Biomechanical Phenomena, Morphogenesis, Myosin Type II genetics, Skin embryology, Surface Tension, Time Factors, Zebrafish embryology, Zebrafish genetics, Zebrafish Proteins genetics, Actin Cytoskeleton metabolism, Actomyosin metabolism, Cell Surface Extensions metabolism, Epithelial Cells metabolism, Myosin Type II metabolism, Skin metabolism, Zebrafish metabolism, Zebrafish Proteins metabolism

Abstract

Cellular protrusions create complex cell surface topographies, but biomechanical mechanisms regulating their formation and arrangement are largely unknown. To study how protrusions form, we focused on the morphogenesis of microridges, elongated actin-based structures that are arranged in maze-like patterns on the apical surfaces of zebrafish skin cells. Microridges form by accreting simple finger-like precursors. Live imaging demonstrated that microridge morphogenesis is linked to apical constriction. A nonmuscle myosin II (NMII) reporter revealed pulsatile contractions of the actomyosin cortex, and inhibiting NMII blocked apical constriction and microridge formation. A biomechanical model suggested that contraction reduces surface tension to permit the fusion of precursors into microridges. Indeed, reducing surface tension with hyperosmolar media promoted microridge formation. In anisotropically stretched cells, microridges formed by precursor fusion along the stretch axis, which computational modeling explained as a consequence of stretch-induced cortical flow. Collectively, our results demonstrate how contraction within the 2D plane of the cortex can pattern 3D cell surfaces., (© 2020 van Loon et al.)

Published

2020

31. Volume Adaptation Controls Stem Cell Mechanotransduction.

Author

Major LG, Holle AW, Young JL, Hepburn MS, Jeong K, Chin IL, Sanderson RW, Jeong JH, Aman ZM, Kennedy BF, Hwang Y, Han DW, Park HW, Guan KL, Spatz JP, and Choi YS

Subjects

Actin Cytoskeleton genetics, Actomyosin genetics, Acyltransferases, Adipogenesis drug effects, Amides pharmacology, Cell Cycle Proteins genetics, Cell Differentiation genetics, Cell Encapsulation methods, Cell Nucleus chemistry, Cell Size drug effects, Core Binding Factor Alpha 1 Subunit genetics, Gelatin chemistry, Heterocyclic Compounds, 4 or More Rings pharmacology, Humans, Hydrogels chemistry, Hydrogels pharmacology, Lamin Type A genetics, Mesenchymal Stem Cells cytology, Myosin Type II genetics, PPAR gamma genetics, Pyridines pharmacology, Trans-Activators genetics, Transcription Factors genetics, rho-Associated Kinases genetics, Adipogenesis genetics, Cell Differentiation drug effects, Mechanotransduction, Cellular genetics, Osteogenesis genetics

Abstract

Recent studies have found discordant mechanosensitive outcomes when comparing 2D and 3D, highlighting the need for tools to study mechanotransduction in 3D across a wide spectrum of stiffness. A gelatin methacryloyl (GelMA) hydrogel with a continuous stiffness gradient ranging from 5 to 38 kPa was developed to recapitulate physiological stiffness conditions. Adipose-derived stem cells (ASCs) were encapsulated in this hydrogel, and their morphological characteristics and expression of both mechanosensitive proteins (Lamin A, YAP, and MRTFa) and differentiation markers (PPARγ and RUNX2) were analyzed. Low-stiffness regions (∼8 kPa) permitted increased cellular and nuclear volume and enhanced mechanosensitive protein localization in the nucleus. This trend was reversed in high stiffness regions (∼30 kPa), where decreased cellular and nuclear volumes and reduced mechanosensitive protein nuclear localization were observed. Interestingly, cells in soft regions exhibited enhanced osteogenic RUNX2 expression, while those in stiff regions upregulated the adipogenic regulator PPARγ, suggesting that volume, not substrate stiffness, is sufficient to drive 3D stem cell differentiation. Inhibition of myosin II (Blebbistatin) and ROCK (Y-27632), both key drivers of actomyosin contractility, resulted in reduced cell volume, especially in low-stiffness regions, causing a decorrelation between volume expansion and mechanosensitive protein localization. Constitutively active and inactive forms of the canonical downstream mechanotransduction effector TAZ were stably transfected into ASCs. Activated TAZ resulted in higher cellular volume despite increasing stiffness and a consistent, stiffness-independent translocation of YAP and MRTFa into the nucleus. Thus, volume adaptation as a function of 3D matrix stiffness can control stem cell mechanotransduction and differentiation.

Published

2019

32. Who Needs a Contractile Actomyosin Ring? The Plethora of Alternative Ways to Divide a Protozoan Parasite.

Author

Hammarton TC

Subjects

Actomyosin genetics, Animals, Cell Cycle, Cell Division genetics, Parasites classification, Parasites ultrastructure, Actomyosin metabolism, Cell Division drug effects, Cytokinesis, Parasites drug effects, Parasites physiology

Abstract

Cytokinesis, or the division of the cytoplasm, following the end of mitosis or meiosis, is accomplished in animal cells, fungi, and amoebae, by the constriction of an actomyosin contractile ring, comprising filamentous actin, myosin II, and associated proteins. However, despite this being the best-studied mode of cytokinesis, it is restricted to the Opisthokonta and Amoebozoa, since members of other evolutionary supergroups lack myosin II and must, therefore, employ different mechanisms. In particular, parasitic protozoa, many of which cause significant morbidity and mortality in humans and animals as well as considerable economic losses, employ a wide diversity of mechanisms to divide, few, if any, of which involve myosin II. In some cases, cell division is not only myosin II-independent, but actin-independent too. Mechanisms employed range from primitive mechanical cell rupture (cytofission), to motility- and/or microtubule remodeling-dependent mechanisms, to budding involving the constriction of divergent contractile rings, to hijacking host cell division machinery, with some species able to utilize multiple mechanisms. Here, I review current knowledge of cytokinesis mechanisms and their molecular control in mammalian-infective parasitic protozoa from the Excavata, Alveolata, and Amoebozoa supergroups, highlighting their often-underappreciated diversity and complexity. Billions of people and animals across the world are at risk from these pathogens, for which vaccines and/or optimal treatments are often not available. Exploiting the divergent cell division machinery in these parasites may provide new avenues for the treatment of protozoal disease., (Copyright © 2019 Hammarton.)

Published

2019

33. Dilated cardiomyopathy mutation in the converter domain of human cardiac myosin alters motor activity and response to omecamtiv mecarbil.

Author

Tang W, Unrath WC, Desetty R, and Yengo CM

Subjects

Actin Cytoskeleton drug effects, Actins genetics, Actins metabolism, Actomyosin genetics, Adenosine Triphosphatases genetics, Cardiomyopathy, Dilated drug therapy, Cardiomyopathy, Dilated pathology, Heart Failure drug therapy, Heart Failure pathology, Humans, Kinetics, Motor Activity genetics, Mutation, Myocardial Contraction drug effects, Protein Domains genetics, Urea pharmacology, Ventricular Myosins chemistry, Ventricular Myosins metabolism, Cardiomyopathy, Dilated genetics, Heart Failure genetics, Urea analogs & derivatives, Ventricular Myosins genetics

Abstract

We investigated a dilated cardiomyopathy (DCM) mutation (F764L) in human β-cardiac myosin by determining its motor properties in the presence and absence of the heart failure drug omecamtive mecarbil (OM). The mutation is located in the converter domain, a key region of communication between the catalytic motor and lever arm in myosins, and is nearby but not directly in the OM-binding site. We expressed and purified human β-cardiac myosin subfragment 1 (M2β-S1) containing the F764L mutation, and compared it to WT with in vitro motility as well as steady-state and transient kinetics measurements. In the absence of OM we demonstrate that the F764L mutation does not significantly change maximum actin-activated ATPase activity but slows actin sliding velocity (15%) and the actomyosin ADP release rate constant (25%). The transient kinetic analysis without OM demonstrates that F764L has a similar duty ratio as WT in unloaded conditions. OM is known to enhance force generation in cardiac muscle while it inhibits the myosin power stroke and enhances actin-attachment duration. We found that OM has a reduced impact on F764L ATPase and sliding velocity compared with WT. Specifically, the EC 50 for OM induced inhibition of in vitro motility was 3-fold weaker in F764L. Also, OM reduces maximum actin-activated ATPase 2-fold in F764L, compared with 4-fold with WT. Overall, our results suggest that F764L attenuates the impact of OM on actin-attachment duration and/or the power stroke. Our work highlights the importance of mutation-specific considerations when pursuing small molecule therapies for cardiomyopathies., (© 2019 Tang et al.)

Published

2019

34. Mechanosensation of Tight Junctions Depends on ZO-1 Phase Separation and Flow.

Author

Schwayer C, Shamipour S, Pranjic-Ferscha K, Schauer A, Balda M, Tada M, Matter K, and Heisenberg CP

Subjects

Actin Cytoskeleton genetics, Actomyosin genetics, Animals, Animals, Genetically Modified genetics, Animals, Genetically Modified growth & development, Embryo, Nonmammalian physiology, Gene Expression Regulation, Developmental genetics, Humans, Membrane Proteins genetics, Mice, Phosphoproteins genetics, Protein Binding, Tight Junctions physiology, Yolk Sac growth & development, Yolk Sac metabolism, Zebrafish genetics, Zebrafish growth & development, Embryonic Development genetics, Mechanotransduction, Cellular genetics, Tight Junctions genetics, Zonula Occludens-1 Protein genetics

Abstract

Cell-cell junctions respond to mechanical forces by changing their organization and function. To gain insight into the mechanochemical basis underlying junction mechanosensitivity, we analyzed tight junction (TJ) formation between the enveloping cell layer (EVL) and the yolk syncytial layer (YSL) in the gastrulating zebrafish embryo. We found that the accumulation of Zonula Occludens-1 (ZO-1) at TJs closely scales with tension of the adjacent actomyosin network, revealing that these junctions are mechanosensitive. Actomyosin tension triggers ZO-1 junctional accumulation by driving retrograde actomyosin flow within the YSL, which transports non-junctional ZO-1 clusters toward the TJ. Non-junctional ZO-1 clusters form by phase separation, and direct actin binding of ZO-1 is required for stable incorporation of retrogradely flowing ZO-1 clusters into TJs. If the formation and/or junctional incorporation of ZO-1 clusters is impaired, then TJs lose their mechanosensitivity, and consequently, EVL-YSL movement is delayed. Thus, phase separation and flow of non-junctional ZO-1 confer mechanosensitivity to TJs., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

35. Actomyosin contractility scales with myoblast elongation and enhances differentiation through YAP nuclear export.

Author

Bruyère C, Versaevel M, Mohammed D, Alaimo L, Luciano M, Vercruysse E, and Gabriele S

Subjects

Actins genetics, Actomyosin metabolism, Animals, Cell Differentiation physiology, Cell Nucleus genetics, Cell Shape genetics, Cell Size, Fibronectins genetics, Hippo Signaling Pathway, Mice, Muscle Contraction genetics, Protein Serine-Threonine Kinases genetics, Signal Transduction genetics, YAP-Signaling Proteins, Actomyosin genetics, Adaptor Proteins, Signal Transducing genetics, Cell Cycle Proteins genetics, Muscle Fibers, Skeletal metabolism, Myoblasts metabolism

Abstract

Skeletal muscle fibers are formed by the fusion of mononucleated myoblasts into long linear myotubes, which differentiate and reorganize into multinucleated myofibers that assemble in bundles to form skeletal muscles. This fundamental process requires the elongation of myoblasts into a bipolar shape, although a complete understanding of the mechanisms governing skeletal muscle fusion is lacking. To address this question, we consider cell aspect ratio, actomyosin contractility and the Hippo pathway member YAP as potential regulators of the fusion of myoblasts into myotubes. Using fibronectin micropatterns of different geometries and traction force microscopy, we investigated how myoblast elongation affects actomyosin contractility. Our findings indicate that cell elongation enhances actomyosin contractility in myoblasts, which regulate their actin network to their spreading area. Interestingly, we found that the contractility of cell pairs increased after their fusion and raise on elongated morphologies. Furthermore, our findings indicate that myoblast elongation modulates nuclear orientation and triggers cytoplasmic localization of YAP, increasing evidence that YAP is a key regulator of mechanotransduction in myoblasts. Taken together, our findings support a mechanical model where actomyosin contractility scales with myoblast elongation and enhances the differentiation of myoblasts into myotubes through YAP nuclear export.

Published

2019

36. The ArfGAP Drongo Promotes Actomyosin Contractility during Collective Cell Migration by Releasing Myosin Phosphatase from the Trailing Edge.

Author

Zeledon C, Sun X, Plutoni C, and Emery G

Subjects

Actomyosin genetics, Animals, Drosophila Proteins genetics, Drosophila melanogaster, Guanine Nucleotide Exchange Factors genetics, Microfilament Proteins genetics, Myosin-Light-Chain Phosphatase genetics, Actomyosin metabolism, Cell Movement, Drosophila Proteins metabolism, Guanine Nucleotide Exchange Factors metabolism, Microfilament Proteins metabolism, Myosin-Light-Chain Phosphatase metabolism

Abstract

Collective cell migration is involved in various developmental and pathological processes, including the dissemination of various cancer cells. During Drosophila melanogaster oogenesis, a group of cells called border cells migrate collectively toward the oocyte. Herein, we show that members of the Arf family of small GTPases and some of their regulators are required for normal border cell migration. Notably, we found that the ArfGAP Drongo and its GTPase-activating function are essential for the initial detachment of the border cell cluster from the basal lamina. We demonstrate through protein localization and genetic interactions that Drongo controls the localization of the myosin phosphatase in order to regulate myosin II activity at the back of the cluster. Moreover, we show that toward the class III Arf, Drongo acts antagonistically to the guanine exchange factor Steppke. Overall, our work describes a mechanistic pathway that promotes the local actomyosin contractility necessary for border cell detachment., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

37. Force-Dependent Regulation of Talin-KANK1 Complex at Focal Adhesions.

Author

Yu M, Le S, Ammon YC, Goult BT, Akhmanova A, and Yan J

Subjects

Actin Cytoskeleton chemistry, Actin Cytoskeleton genetics, Actomyosin chemistry, Actomyosin genetics, Adaptor Proteins, Signal Transducing genetics, Cell Adhesion genetics, Cytoskeletal Proteins genetics, Extracellular Matrix chemistry, Extracellular Matrix genetics, Focal Adhesions genetics, HeLa Cells, Humans, Integrins chemistry, Integrins genetics, Mechanical Phenomena, Mechanotransduction, Cellular genetics, Microtubules chemistry, Microtubules genetics, Multiprotein Complexes genetics, Muscle Contraction genetics, Shear Strength physiology, Talin genetics, Adaptor Proteins, Signal Transducing chemistry, Cytoskeletal Proteins chemistry, Focal Adhesions chemistry, Multiprotein Complexes chemistry, Talin chemistry

Abstract

KANK proteins mediate cross-talk between dynamic microtubules and integrin-based adhesions to the extracellular matrix. KANKs interact with the integrin/actin-binding protein talin and with several components of microtubule-stabilizing cortical complexes. Because of actomyosin contractility, the talin-KANK complex is likely under mechanical force, and its mechanical stability is expected to be a critical determinant of KANK recruitment to focal adhesions. Here, we quantified the lifetime of the complex of the talin rod domain R7 and the KN domain of KANK1 under shear-force geometry and found that it can withstand forces for seconds to minutes over a physiological force range up to 10 pN. Complex stability measurements combined with cell biological experiments suggest that shear-force stretching promotes KANK1 localization to the periphery of focal adhesions. These results indicate that the talin-KANK1 complex is mechanically strong, enabling it to support the cross-talk between microtubule and actin cytoskeleton at focal adhesions.

Published

2019

38. Misshapen coordinates protrusion restriction and actomyosin contractility during collective cell migration.

Author

Plutoni C, Keil S, Zeledon C, Delsin LEA, Decelle B, Roux PP, Carréno S, and Emery G

Subjects

Actin Cytoskeleton metabolism, Actomyosin metabolism, Algorithms, Animals, Animals, Genetically Modified, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Female, Microfilament Proteins genetics, Microfilament Proteins metabolism, Models, Genetic, Protein Serine-Threonine Kinases metabolism, RNA Interference, Actomyosin genetics, Cell Movement genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Gene Expression Regulation, Developmental, Oogenesis genetics, Protein Serine-Threonine Kinases genetics

Abstract

Collective cell migration is involved in development, wound healing and metastasis. In the Drosophila ovary, border cells (BC) form a small cluster that migrates collectively through the egg chamber. To achieve directed motility, the BC cluster coordinates the formation of protrusions in its leader cell and contractility at the rear. Restricting protrusions to leader cells requires the actin and plasma membrane linker Moesin. Herein, we show that the Ste20-like kinase Misshapen phosphorylates Moesin in vitro and in BC. Depletion of Misshapen disrupts protrusion restriction, thereby allowing other cells within the cluster to protrude. In addition, we show that Misshapen is critical to generate contractile forces both at the rear of the cluster and at the base of protrusions. Together, our results indicate that Misshapen is a key regulator of BC migration as it coordinates two independent pathways that restrict protrusion formation to the leader cells and induces contractile forces.

Published

2019

39. Dynamic polyhedral actomyosin lattices remodel micron-scale curved membranes during exocytosis in live mice.

Author

Ebrahim S, Chen D, Weiss M, Malec L, Ng Y, Rebustini I, Krystofiak E, Hu L, Liu J, Masedunskas A, Hardeman E, Gunning P, Kachar B, and Weigert R

Subjects

Actin Cytoskeleton metabolism, Actomyosin genetics, Animals, Cell Membrane metabolism, Exocytosis genetics, Mice, Transgenic, Microscopy, Confocal methods, Myosins genetics, Secretory Vesicles metabolism, Actomyosin metabolism, Exocytosis physiology, Muscle Contraction physiology, Myosins metabolism

Abstract

Actomyosin networks, the cell's major force production machineries, remodel cellular membranes during myriad dynamic processes 1,2 by assembling into various architectures with distinct force generation properties 3,4 . While linear and branched actomyosin architectures are well characterized in cell-culture and cell-free systems 3 , it is not known how actin and myosin networks form and function to remodel membranes in complex three-dimensional mammalian tissues. Here, we use four-dimensional spinning-disc confocal microscopy with image deconvolution to acquire macromolecular-scale detail of dynamic actomyosin networks in exocrine glands of live mice. We address how actin and myosin organize around large membrane-bound secretory vesicles and generate the forces required to complete exocytosis 5-7 . We find that actin and non-muscle myosin II (NMII) assemble into previously undescribed polyhedral-like lattices around the vesicle membrane. The NMII lattice comprises bipolar minifilaments 8-10 as well as non-canonical three-legged configurations. Using photobleaching and pharmacological perturbations in vivo, we show that actomyosin contractility and actin polymerization together push on the underlying vesicle membrane to overcome the energy barrier and complete exocytosis 7 . Our imaging approach thus unveils a force-generating actomyosin lattice that regulates secretion in the exocrine organs of live animals.

Published

2019

40. Polarity signaling ensures epidermal homeostasis by coupling cellular mechanics and genomic integrity.

Author

Dias Gomes M, Letzian S, Saynisch M, and Iden S

Subjects

Actomyosin genetics, Actomyosin metabolism, Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Animals, Animals, Newborn, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Cell Differentiation genetics, Cell Polarity genetics, Cells, Cultured, Keratinocytes cytology, Mice, Inbred C57BL, Mice, Knockout, Mitosis genetics, Signal Transduction genetics, Cell Polarity physiology, Epidermis metabolism, Genomics methods, Homeostasis, Keratinocytes metabolism, Signal Transduction physiology

Abstract

Epithelial homeostasis requires balanced progenitor cell proliferation and differentiation, whereas disrupting this equilibrium fosters degeneration or cancer. Here we studied how cell polarity signaling orchestrates epidermal self-renewal and differentiation. Using genetic ablation, quantitative imaging, mechanochemical reconstitution and atomic force microscopy, we find that mammalian Par3 couples genome integrity and epidermal fate through shaping keratinocyte mechanics, rather than mitotic spindle orientation. Par3 inactivation impairs RhoA activity, actomyosin contractility and viscoelasticity, eliciting mitotic failures that trigger aneuploidy, mitosis-dependent DNA damage responses, p53 stabilization and premature differentiation. Importantly, reconstituting myosin activity is sufficient to restore mitotic fidelity, genome integrity, and balanced differentiation and stratification. Collectively, this study deciphers a mechanical signaling network in which Par3 acts upstream of Rho/actomyosin contractility to promote intrinsic force generation, thereby maintaining mitotic accuracy and cellular fitness at the genomic level. Disturbing this network may compromise not only epidermal homeostasis but potentially also that of other self-renewing epithelia.

Published

2019

41. Actomyosin-driven force patterning controls endocytosis at the immune synapse.

Author

Kumari A, Pineau J, Sáez PJ, Maurin M, Lankar D, San Roman M, Hennig K, Boura VF, Voituriez R, Karlsson MCI, Balland M, Lennon Dumenil AM, and Pierobon P

Subjects

Actomyosin genetics, Animals, Cell Communication, Crosses, Genetic, Integrases genetics, Integrases metabolism, Mice, Mice, Knockout, Mice, Transgenic, Myosin Type II genetics, Receptors, Complement 3d, Actin Cytoskeleton physiology, Actomyosin metabolism, B-Lymphocytes physiology, Endocytosis physiology, Myosin Type II metabolism

Abstract

An important channel of cell-to-cell communication is direct contact. The immune synapse is a paradigmatic example of such type of interaction: it forms upon engagement of antigen receptors in lymphocytes by antigen-presenting cells and allows the local exchange of molecules and information. Although mechanics has been shown to play an important role in this process, how forces organize and impact on synapse function is unknown. We find that mechanical forces are spatio-temporally patterned at the immune synapse: global pulsatile myosin II-driven tangential forces are observed at the synapse periphery while localised forces generated by invadosome-like F-actin protrusions are detected at its centre. Noticeably, we observe that these force-producing actin protrusions constitute the main site of antigen extraction and endocytosis and require myosin II contractility to form. The interplay between global and local forces dictated by the organization of the actomyosin cytoskeleton therefore controls endocytosis at the immune synapse.

Published

2019

42. Spinal neural tube closure depends on regulation of surface ectoderm identity and biomechanics by Grhl2.

Author

Nikolopoulou E, Hirst CS, Galea G, Venturini C, Moulding D, Marshall AR, Rolo A, De Castro SCP, Copp AJ, and Greene NDE

Subjects

Actomyosin genetics, Actomyosin metabolism, Animals, Biomechanical Phenomena, Cadherins metabolism, Ectoderm cytology, Ectoderm embryology, Ectoderm metabolism, Epithelial Cells metabolism, Intercellular Junctions genetics, Intercellular Junctions metabolism, Mice, Neural Tube metabolism, SOXB1 Transcription Factors metabolism, Stress, Mechanical, Transcription Factors metabolism, Embryo, Mammalian metabolism, Gene Expression Regulation, Developmental, Neural Tube embryology, Neuroepithelial Cells metabolism, Neurulation genetics, Transcription Factors genetics

Abstract

Lack or excess expression of the surface ectoderm-expressed transcription factor Grainyhead-like2 (Grhl2), each prevent spinal neural tube closure. Here we investigate the causative mechanisms and find reciprocal dysregulation of epithelial genes, cell junction components and actomyosin properties in Grhl2 null and over-expressing embryos. Grhl2 null surface ectoderm shows a shift from epithelial to neuroepithelial identity (with ectopic expression of N-cadherin and Sox2), actomyosin disorganisation, cell shape changes and diminished resistance to neural fold recoil upon ablation of the closure point. In contrast, excessive abundance of Grhl2 generates a super-epithelial surface ectoderm, in which up-regulation of cell-cell junction proteins is associated with an actomyosin-dependent increase in local mechanical stress. This is compatible with apposition of the neural folds but not with progression of closure, unless myosin activity is inhibited. Overall, our findings suggest that Grhl2 plays a crucial role in regulating biomechanical properties of the surface ectoderm that are essential for spinal neurulation.

Published

2019

43. Aurora-A Breaks Symmetry in Contractile Actomyosin Networks Independently of Its Role in Centrosome Maturation.

Author

Zhao P, Teng X, Tantirimudalige SN, Nishikawa M, Wohland T, Toyama Y, and Motegi F

Subjects

Actomyosin genetics, Animals, Caenorhabditis elegans cytology, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins metabolism, Cell Polarity physiology, Embryo, Nonmammalian cytology, Microtubules metabolism, Spindle Apparatus genetics, Actin Cytoskeleton metabolism, Actomyosin metabolism, Centrosome metabolism, Muscle Contraction physiology

Abstract

Cell polarity is facilitated by a rearrangement of the actin cytoskeleton at the cell cortex. The program triggering the asymmetric remodeling of contractile actomyosin networks remains poorly understood. Here, we show that polarization of Caenorhabditis elegans zygotes is established through sequential downregulation of cortical actomyosin networks by the mitotic kinase, Aurora-A. Aurora-A accumulates around centrosomes to locally disrupt the actomyosin contractile activity at the proximal cortex, thereby promoting cortical flows during symmetry breaking. Aurora-A later mediates global disassembly of cortical actomyosin networks, which facilitates the initial polarization through suppression of centrosome-independent cortical flows. Translocation of Aurora-A from the cytoplasm to the cortex is sufficient to interfere with the cortical actomyosin networks independently of its roles in centrosome maturation and cell-cycle progression. We propose that Aurora-A activity serves as a centrosome-mediated cue that breaks symmetry in actomyosin contractile activity, and facilitates the initial polarization through global suppression of cortical actomyosin networks., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

44. Cadherin mechanotransduction in leader-follower cell specification during collective migration.

Author

Khalil AA and de Rooij J

Subjects

Actomyosin genetics, Animals, Cadherins chemistry, Humans, Intercellular Junctions genetics, Microtubules genetics, Cadherins genetics, Cell Movement genetics, Cell Polarity genetics, Mechanotransduction, Cellular genetics

Abstract

Collective invasion drives the spread of multicellular cancer groups, into the normal tissue surrounding several epithelial tumors. Collective invasion recapitulates various aspects of the multicellular organization and collective migration that take place during normal development and repair. Collective migration starts with the specification of leader cells in which a polarized, migratory phenotype is established. Leader cells initiate and organize the migration of follower cells, to allow the group of cells to move as a cohesive and polarized unit. Leader-follower specification is essential for coordinated and directional collective movement. Forces exerted by cohesive cells represent key signals that dictate multicellular coordination and directionality. Physical forces originate from the contraction of the actomyosin cytoskeleton, which is linked between cells via cadherin-based cell-cell junctions. The cadherin complex senses and transduces fluctuations in forces into biochemical signals that regulate processes like cell proliferation, motility and polarity. With cadherin junctions being maintained in most collective movements the cadherin complex is ideally positioned to integrate mechanical information into the organization of collective cell migration. Here we discuss the potential roles of cadherin mechanotransduction in the diverse aspects of leader versus follower cell specification during collective migration and neoplastic invasion., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

45. Electrostatic interactions in the force-generating region of the human cardiac myosin modulate ADP dissociation from actomyosin.

Author

Gargey A, Ge J, Tkachev YV, and Nesmelov YE

Subjects

Actomyosin genetics, Humans, Kinetics, Molecular Dynamics Simulation, Mutant Proteins metabolism, Mutation, Missense, Protein Binding, Protein Isoforms chemistry, Protein Isoforms metabolism, Actomyosin metabolism, Adenosine Diphosphate metabolism, Cardiac Myosins physiology, Static Electricity

Abstract

Human cardiac myosin has two isoforms, alpha and beta, sharing significant sequence similarity, but different in kinetics: ADP release from actomyosin is an order of magnitude faster in the alpha myosin isoform. Apparently, small differences in the sequence are responsible for distinct local inter-residue interactions within alpha and beta isoforms, leading to such a dramatic difference in the rate of ADP release. Our analysis of structural kinetics of alpha and beta isoforms using molecular dynamics simulations revealed distinct dynamics of SH1:SH2 helix within the force-generation region of myosin head. The simulations showed that the residue R694 of the helix forms two permanent salt bridges in the beta isoform, which are not present in the alpha isoform. We hypothesized that the isoform-specific electrostatic interactions play a role in the difference of kinetic properties of myosin isoforms. We prepared R694N mutant in the beta isoform background to destabilize electrostatic interactions in the force-generating region of the myosin head. Our experimental data confirm faster ADP release from R694N actomyosin mutant, but is not as dramatic as the difference of kinetics of ADP release in the alpha and beta isoforms., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

46. PCP-dependent transcellular regulation of actomyosin oscillation facilitates convergent extension of vertebrate tissue.

Author

Shindo A, Inoue Y, Kinoshita M, and Wallingford JB

Subjects

Actomyosin genetics, Algorithms, Animals, Cell Membrane metabolism, Cell Movement genetics, Cell Polarity genetics, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Gene Expression Regulation, Developmental, Luminescent Proteins genetics, Luminescent Proteins metabolism, Microscopy, Confocal, Models, Biological, Time-Lapse Imaging methods, Xenopus Proteins genetics, Xenopus Proteins metabolism, Xenopus laevis, Actomyosin physiology, Cell Movement physiology, Cell Polarity physiology, Embryo, Nonmammalian cytology

Abstract

Oscillatory flows of actomyosin play a key role in the migration of single cells in culture and in collective cell movements in Drosophila embryos. In vertebrate embryos undergoing convergent extension (CE), the Planar Cell Polarity (PCP) pathway drives the elongation of the body axis and shapes the central nervous system, and mutations of the PCP genes predispose humans to various malformations including neural tube defects. However, the spatiotemporal patterns of oscillatory actomyosin contractions during vertebrate CE and how they are controlled by the PCP signaling remain unknown. Here, we address these outstanding issues using a combination of in vivo imaging and mathematical modeling. We find that effective execution of CE requires alternative oscillations of cortical actomyosin across cell membranes of neighboring cells within an optimal frequency range. Intriguingly, temporal and spatial clustering of the core PCP protein Prickle 2 (Pk2) is correlated to submembranous accumulations of F-actin, and depletion of Pk2 perturbs the oscillation of actomyosin contractions. These findings shed light on the significance of temporal regulation of actomyosin contraction by the PCP pathway during CE, in addition to its well-studied spatial aspects., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2019

47. The N-cadherin interactome in primary cardiomyocytes as defined using quantitative proximity proteomics.

Author

Li Y, Merkel CD, Zeng X, Heier JA, Cantrell PS, Sun M, Stolz DB, Watkins SC, Yates NA, and Kwiatkowski AV

Subjects

Actin Cytoskeleton ultrastructure, Actomyosin metabolism, Adherens Junctions ultrastructure, Animals, Animals, Newborn, Cadherins metabolism, Cell Adhesion, Cell Communication, Gene Expression Regulation, Gene Ontology, Mice, Molecular Sequence Annotation, Myocytes, Cardiac ultrastructure, Primary Cell Culture, Protein Binding, Protein Interaction Mapping, Proteomics methods, Actin Cytoskeleton metabolism, Actomyosin genetics, Adherens Junctions metabolism, Cadherins genetics, Mechanotransduction, Cellular, Myocytes, Cardiac metabolism

Abstract

The junctional complexes that couple cardiomyocytes must transmit the mechanical forces of contraction while maintaining adhesive homeostasis. The adherens junction (AJ) connects the actomyosin networks of neighboring cardiomyocytes and is required for proper heart function. Yet little is known about the molecular composition of the cardiomyocyte AJ or how it is organized to function under mechanical load. Here, we define the architecture, dynamics and proteome of the cardiomyocyte AJ. Mouse neonatal cardiomyocytes assemble stable AJs along intercellular contacts with organizational and structural hallmarks similar to mature contacts. We combine quantitative mass spectrometry with proximity labeling to identify the N-cadherin (CDH2) interactome. We define over 350 proteins in this interactome, nearly 200 of which are unique to CDH2 and not part of the E-cadherin (CDH1) interactome. CDH2-specific interactors comprise primarily adaptor and adhesion proteins that promote junction specialization. Our results provide novel insight into the cardiomyocyte AJ and offer a proteomic atlas for defining the molecular complexes that regulate cardiomyocyte intercellular adhesion. This article has an associated First Person interview with the first authors of the paper., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

48. A cell separation checkpoint that enforces the proper order of late cytokinetic events.

Author

Brace JL, Doerfler MD, and Weiss EL

Subjects

Actomyosin genetics, Actomyosin metabolism, Cell Division drug effects, Cell Division genetics, Cytokinesis drug effects, Exocytosis drug effects, Indoleacetic Acids pharmacology, Intracellular Signaling Peptides and Proteins metabolism, Protein Serine-Threonine Kinases metabolism, Protein Stability drug effects, Proteolysis, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Signal Transduction, mRNA Cleavage and Polyadenylation Factors metabolism, Cytokinesis genetics, Gene Expression Regulation, Fungal, Intracellular Signaling Peptides and Proteins genetics, Protein Serine-Threonine Kinases genetics, Saccharomyces cerevisiae Proteins genetics, mRNA Cleavage and Polyadenylation Factors genetics

Abstract

Eukaryotic cell division requires dependency relationships in which late processes commence only after early ones are appropriately completed. We have discovered a system that blocks late events of cytokinesis until early ones are successfully accomplished. In budding yeast, cytokinetic actomyosin ring contraction and membrane ingression are coupled with deposition of an extracellular septum that is selectively degraded in its primary septum immediately after its completion by secreted enzymes. We find this secretion event is linked to septum completion and forestalled when the process is slowed. Delay of septum degradation requires Fir1, an intrinsically disordered protein localized to the cytokinesis site that is degraded upon septum completion but stabilized when septation is aberrant. Fir1 protects cytokinesis in part by inhibiting a separation-specific exocytosis function of the NDR/LATS kinase Cbk1, a key component of "hippo" signaling that induces mother-daughter separation. We term this system enforcement of cytokinesis order, a checkpoint ensuring proper temporal sequence of mechanistically incompatible processes of cytokinesis., (© 2018 Brace et al.)

Published

2019

49. Optogenetic control of morphogenesis goes 3D.

Author

Thompson BJ

Subjects

Actomyosin genetics, Animals, Drosophila Proteins genetics, Drosophila melanogaster, Embryo, Nonmammalian cytology, Actomyosin metabolism, Drosophila Proteins metabolism, Embryo, Nonmammalian embryology, Morphogenesis physiology, Optogenetics

Published

2018

50. Excitable RhoA dynamics drive pulsed contractions in the early C. elegans embryo.

Author

Michaux JB, Robin FB, McFadden WM, and Munro EM

Subjects

Actins genetics, Actins metabolism, Actomyosin genetics, Actomyosin metabolism, Animals, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism, GTPase-Activating Proteins genetics, GTPase-Activating Proteins metabolism, rhoA GTP-Binding Protein genetics, Caenorhabditis elegans metabolism, Embryo, Nonmammalian metabolism, rhoA GTP-Binding Protein metabolism

Abstract

Pulsed actomyosin contractility underlies diverse modes of tissue morphogenesis, but the underlying mechanisms remain poorly understood. Here, we combined quantitative imaging with genetic perturbations to identify a core mechanism for pulsed contractility in early Caenorhabditis elegans embryos. We show that pulsed accumulation of actomyosin is governed by local control of assembly and disassembly downstream of RhoA. Pulsed activation and inactivation of RhoA precede, respectively, the accumulation and disappearance of actomyosin and persist in the absence of Myosin II. We find that fast (likely indirect) autoactivation of RhoA drives pulse initiation, while delayed, F-actin-dependent accumulation of the RhoA GTPase-activating proteins RGA-3/4 provides negative feedback to terminate each pulse. A mathematical model, constrained by our data, suggests that this combination of feedbacks is tuned to generate locally excitable RhoA dynamics. We propose that excitable RhoA dynamics are a common driver for pulsed contractility that can be tuned or coupled differently to actomyosin dynamics to produce a diversity of morphogenetic outcomes., (© 2018 Michaux et al.)

Published

2018