Your search keyword '"cell cortex"' showing total 1,825 results

1. Ezrin, radixin, and moesin are dispensable for macrophage migration and cellular cortex mechanics.

Author

Verdys, Perrine, Rey Barroso, Javier, Girel, Adeline, Vermeil, Joseph, Bergert, Martin, Sanchez, Thibaut, Métais, Arnaud, Mangeat, Thomas, Bellard, Elisabeth, Bigot, Claire, Astarie-Dequeker, Catherine, Labrousse, Arnaud, Girard, Jean-Philippe, Maridonneau-Parini, Isabelle, Vérollet, Christel, Lagarrigue, Frédéric, Diz-Muñoz, Alba, Heuvingh, Julien, Piel, Matthieu, and du Roure, Olivia

Subjects

*CELL migration, *CYTOSKELETAL proteins, *CELL anatomy, *CYTOSKELETON, *EZRIN

Abstract

The cellular cortex provides crucial mechanical support and plays critical roles during cell division and migration. The proteins of the ERM family, comprised of ezrin, radixin, and moesin, are central to these processes by linking the plasma membrane to the actin cytoskeleton. To investigate the contributions of the ERM proteins to leukocyte migration, we generated single and triple ERM knockout macrophages. Surprisingly, we found that even in the absence of ERM proteins, macrophages still form the different actin structures promoting cell migration, such as filopodia, lamellipodia, podosomes, and ruffles. Furthermore, we discovered that, unlike every other cell type previously investigated, the single or triple knockout of ERM proteins does not affect macrophage migration in diverse contexts. Finally, we demonstrated that the loss of ERMs in macrophages does not affect the mechanical properties of their cortex. These findings challenge the notion that ERMs are universally essential for cortex mechanics and cell migration and support the notion that the macrophage cortex may have diverged from that of other cells to allow for their uniquely adaptive cortical plasticity. Synopsis: Ezrin, radixin, and moesin (collectively known as ERM proteins) serve as crucial cytoskeletal linker proteins connecting the actin cytoskeleton to the plasma membrane. This study shows that a complete loss of ERM proteins in macrophages does not affect the mechanics of their actin cortex and their capacity to migrate. Macrophage actin structures are still correctly formed in the absence of ERM proteins. Macrophage migration in vitro, ex vivo and in vivo is not affected by ERM depletion. The mechanical properties of the macrophage cortex are independent of ERM proteins. Macrophages do not require the ERM family proteins for phagocytosis and cell migration, suggesting divergence of macrophage cortical properties. [ABSTRACT FROM AUTHOR]

Published

2024

2. Spatiotemporal regulation of MELK during mitosis.

Author

Majumdar, Sreemita and Song-Tao Liu

Subjects

LEUCINE zippers, PHOSPHOPROTEIN phosphatases, CYTOLOGY, ANAPHASE, MITOSIS, PROTEIN kinases

Abstract

Maternal Embryonic Leucine Zipper Kinase (MELK) has been studied intensively in recent years due to its overexpression in multiple cancers. However, the cell biology of MELK remains less characterized despite its well-documented association with mitosis. Here we report a distinctive pattern of human MELK that translocates from the cytoplasm to cell cortex within 3 min of anaphase onset. The cortex association lasts about 30 min till telophase. The spatiotemporal specific localization of MELK depends on the interaction between its Threonine-Proline (TP) rich domain and kinase associated 1 (KA1) domain, which is regulated by CDK1 kinase and PP4 protein phosphatase. KA1 domains are known to regulate kinase activities through various intramolecular interactions. Our results revealed a new role for KA1 domain to control subcellular localization of a protein kinase. [ABSTRACT FROM AUTHOR]

Published

2024

3. Role of CYP311A1 in wing development of Drosophila melanogaster.

Author

Zhang, Xubo, Liu, Mengqi, Cheng, Andi, Moussian, Bernard, Zhang, Jianzhen, and Dong, Wei

Subjects

*DROSOPHILA melanogaster, *STAINS & staining (Microscopy), *CELL morphology, *LIPID metabolism, *CYTOCHROME P-450, *CADHERINS, *MORPHOGENESIS

Abstract

Lipid homeostasis is crucial for growth and development of organisms. Several cytochrome P450 monooxygenases (CYPs) are involved in lipid metabolism. The function of Cyp311a1 in the anterior midgut as a regulator of phosphatidylethanolamine (PE) metabolism in Drosophila melanogaster has been demonstrated, as depletion of Cyp311a1 caused larval growth arrest that was partially rescued by supplying PE. In this study, we investigated the role of CYP311A1 in wing morphogenesis in Drosophila. Using the GAL4‐UAS system, Cyp311a1 was selectively knocked down in the wing disc. A deformed wing phenotype was observed in flies with reduced Cyp311a1 transcripts. BODIPY and oil red O staining revealed a reduction of neutral lipids in the wing disc after the depletion of Cyp311a1. In addition, we observed an enhanced sensitivity to Eosin Y penetration in the wings of Cyp311a1 knocked‐down flies. Moreover, the reduction of CYP311A1 function in developing wings does not affect cell proliferation and apoptosis, but entails disordered Phalloidin or Cadherin distribution, suggesting an abnormal cell morphology and cell cortex structure in wing epithelial cells. Taken together, our results suggest that Cyp311a1 is needed for wing morphogenesis by participating in lipid assembly and cell homeostasis. [ABSTRACT FROM AUTHOR]

Published

2024

4. Cell protrusions and contractions generate long-range membrane tension propagation

Author

De Belly, Henry, Yan, Shannon, Borja da Rocha, Hudson, Ichbiah, Sacha, Town, Jason P, Zager, Patrick J, Estrada, Dorothy C, Meyer, Kirstin, Turlier, Hervé, Bustamante, Carlos, and Weiner, Orion D

Subjects

Biochemistry and Cell Biology, Biological Sciences, Generic health relevance, Actins, Actomyosin, Actin Cytoskeleton, Cell Membrane, Cell Movement, actin cytoskeleton, actomyosin contractility, cell cortex, cell mechanics, cell migration, cell polarity, cell protrusion, membrane tension, optical tweezers, optogenetics, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Membrane tension is thought to be a long-range integrator of cell physiology. Membrane tension has been proposed to enable cell polarity during migration through front-back coordination and long-range protrusion competition. These roles necessitate effective tension transmission across the cell. However, conflicting observations have left the field divided as to whether cell membranes support or resist tension propagation. This discrepancy likely originates from the use of exogenous forces that may not accurately mimic endogenous forces. We overcome this complication by leveraging optogenetics to directly control localized actin-based protrusions or actomyosin contractions while simultaneously monitoring the propagation of membrane tension using dual-trap optical tweezers. Surprisingly, actin-driven protrusions and actomyosin contractions both elicit rapid global membrane tension propagation, whereas forces applied to cell membranes alone do not. We present a simple unifying mechanical model in which mechanical forces that engage the actin cortex drive rapid, robust membrane tension propagation through long-range membrane flows.

Published

2023

5. Spatiotemporal regulation of MELK during mitosis

Author

Sreemita Majumdar and Song-Tao Liu

Subjects

MELK, KA1 domain, cell cortex, Cdk1, anaphase, PP4, Biology (General), QH301-705.5

Abstract

Maternal Embryonic Leucine Zipper Kinase (MELK) has been studied intensively in recent years due to its overexpression in multiple cancers. However, the cell biology of MELK remains less characterized despite its well-documented association with mitosis. Here we report a distinctive pattern of human MELK that translocates from the cytoplasm to cell cortex within 3 min of anaphase onset. The cortex association lasts about 30 min till telophase. The spatiotemporal specific localization of MELK depends on the interaction between its Threonine-Proline (TP) rich domain and kinase associated 1 (KA1) domain, which is regulated by CDK1 kinase and PP4 protein phosphatase. KA1 domains are known to regulate kinase activities through various intramolecular interactions. Our results revealed a new role for KA1 domain to control subcellular localization of a protein kinase.

Published

2024

6. An EpCAM/Trop2 mechanostat differentially regulates collective behaviour of human carcinoma cells

Author

Aslemarz, Azam, Fagotto-Kaufmann, Marie, Ruppel, Artur, Fagotto-Kaufmann, Christine, Balland, Martial, Lasko, Paul, and Fagotto, François

Published

2024

7. Collective dynamics of actin and microtubule and its crosstalk mediated by FHDC1.

Author

Chee San Tong, Maohan Su, He Sun, Xiang Le Chua, Ding Xiong, Su Guo, Raj, Ravin, Wen Pei Ong, Nicole, Ann Gie Lee, Yansong Miao, and Min Wu

Subjects

ACTIN, MICROTUBULES, TUBULINS, MAST cells, CELL cycle proteins, CELL migration

Abstract

The coordination between actin and microtubule network is crucial, yet this remains a challenging problem to dissect and our understanding of the underlying mechanisms remains limited. In this study, we used travelling waves in the cell cortex to characterize the collective dynamics of cytoskeletal networks. Our findings show that Cdc42 and F-BAR-dependent actin waves in mast cells are mainly driven by formin-mediated actin polymerization, with the microtubule-binding formin FH2 domain-containing protein 1 (FHDC1) as an early regulator. Knocking down FHDC1 inhibits actin wave formation, and this inhibition require FHDC1's interaction with both microtubule and actin. The phase of microtubule depolymerization coincides with the nucleation of actin waves and microtubule stabilization inhibit actin waves, leading us to propose that microtubule shrinking and the concurrent release of FHDC1 locally regulate actin nucleation. Lastly, we show that FHDC1 is crucial for multiple cellular processes such as cell division and migration. Our data provided molecular insights into the nucleation mechanisms of actin waves and uncover an antagonistic interplay between microtubule and actin polymerization in their collective dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

8. Global and local functions of the Fused kinase ortholog CdaH in intracellular patterning in Tetrahymena.

Author

Chinkyu Lee, Maier, Wolfgang, Yu-Yang Jiang, Kentaro Nakano, Lechtreck, Karl F., and Gaertig, Jacek

Subjects

*TETRAHYMENA, *CYTOKINESIS, *CILIATA, *CYCLINS, *DAUGHTERS

Abstract

Ciliates assemble numerous microtubular structures into complex cortical patterns. During ciliate division, the pattern is duplicated by intracellular segmentation that produces a tandem of daughter cells. In Tetrahymena thermophila, the induction and positioning of the division boundary involves two mutually antagonistic factors: posterior CdaA (cyclin E) and anterior CdaI (Hippo kinase). Here, we characterized the related cdaH-1 allele, which confers a pleiotropic patterning phenotype including an absence of the division boundary and an anterior-posterior mispositioning of the new oral apparatus. CdaH is a Fused or Stk36 kinase ortholog that localizes to multiple sites that correlate with the effects of its loss, including the division boundary and the new oral apparatus. CdaH acts downstream of CdaA to induce the division boundary and drives asymmetric cytokinesis at the tip of the posterior daughter. CdaH both maintains the anterior-posterior position of the new oral apparatus and interacts with CdaI to pattern ciliary rows within the oral apparatus. Thus, CdaH acts at multiple scales, from induction and positioning of structures on the cell-wide polarity axis to local organelle-level patterning. [ABSTRACT FROM AUTHOR]

Published

2024

9. Plasma Membrane Blebbing Is Controlled by Subcellular Distribution of Vimentin Intermediate Filaments.

Author

Chikina, Aleksandra S., Zholudeva, Anna O., Lomakina, Maria E., Kireev, Igor I., Dayal, Alexander A., Minin, Alexander A., Maurin, Mathieu, Svitkina, Tatyana M., and Alexandrova, Antonina Y.

Subjects

*CYTOPLASMIC filaments, *CELL membranes, *VIMENTIN, *CELL physiology, *CELL migration

Abstract

The formation of specific cellular protrusions, plasma membrane blebs, underlies the amoeboid mode of cell motility, which is characteristic for free-living amoebae and leukocytes, and can also be adopted by stem and tumor cells to bypass unfavorable migration conditions and thus facilitate their long-distance migration. Not all cells are equally prone to bleb formation. We have previously shown that membrane blebbing can be experimentally induced in a subset of HT1080 fibrosarcoma cells, whereas other cells in the same culture under the same conditions retain non-blebbing mesenchymal morphology. Here we show that this heterogeneity is associated with the distribution of vimentin intermediate filaments (VIFs). Using different approaches to alter the VIF organization, we show that blebbing activity is biased toward cell edges lacking abundant VIFs, whereas the VIF-rich regions of the cell periphery exhibit low blebbing activity. This pattern is observed both in interphase fibroblasts, with and without experimentally induced blebbing, and during mitosis-associated blebbing. Moreover, the downregulation of vimentin expression or displacement of VIFs away from the cell periphery promotes blebbing even in cells resistant to bleb-inducing treatments. Thus, we reveal a new important function of VIFs in cell physiology that involves the regulation of non-apoptotic blebbing essential for amoeboid cell migration and mitosis. [ABSTRACT FROM AUTHOR]

Published

2024

10. Nuclear shapes are geometrically determined by the excess surface area of the nuclear lamina

Author

Richard B. Dickinson and Tanmay P. Lele

Subjects

nuclear shape, nuclear morphology and function, mechanotranduction, cell shape, cell cortex, nuclear lamina, Biology (General), QH301-705.5

Abstract

Introduction: Nuclei have characteristic shapes dependent on cell type, which are critical for proper cell function, and nuclei lose their distinct shapes in multiple diseases including cancer, laminopathies, and progeria. Nuclear shapes result from deformations of the sub-nuclear components—nuclear lamina and chromatin. How these structures respond to cytoskeletal forces to form the nuclear shape remains unresolved. Although the mechanisms regulating nuclear shape in human tissues are not fully understood, it is known that different nuclear shapes arise from cumulative nuclear deformations post-mitosis, ranging from the rounded morphologies that develop immediately after mitosis to the various nuclear shapes that roughly correspond to cell shape (e.g., elongated nuclei in elongated cells, flat nuclei in flat cells).Methods: We formulated a mathematical model to predict nuclear shapes of cells in various contexts under the geometric constraints of fixed cell volume, nuclear volume and lamina surface area. Nuclear shapes were predicted and compared to experiments for cells in various geometries, including isolated on a flat surface, on patterned rectangles and lines, within a monolayer, isolated in a well, or when the nucleus is impinging against a slender obstacle.Results and Discussion: The close agreement between predicted and experimental shapes demonstrates a simple geometric principle of nuclear shaping: the excess surface area of the nuclear lamina (relative to that of a sphere of the same volume) permits a wide range of highly deformed nuclear shapes under the constraints of constant surface area and constant volume. When the lamina is smooth (tensed), the nuclear shape can be predicted entirely from these geometric constraints alone for a given cell shape. This principle explains why flattened nuclear shapes in fully spread cells are insensitive to the magnitude of the cytoskeletal forces. Also, the surface tension in the nuclear lamina and nuclear pressure can be estimated from the predicted cell and nuclear shapes when the cell cortical tension is known, and the predictions are consistent with measured forces. These results show that excess surface area of the nuclear lamina is the key determinant of nuclear shapes. When the lamina is smooth (tensed), the nuclear shape can be determined purely by the geometric constraints of constant (but excess) nuclear surface area, nuclear volume, and cell volume, for a given cell adhesion footprint, independent of the magnitude of the cytoskeletal forces involved.

Published

2023

11. Plasma Membrane Blebbing Is Controlled by Subcellular Distribution of Vimentin Intermediate Filaments

Author

Aleksandra S. Chikina, Anna O. Zholudeva, Maria E. Lomakina, Igor I. Kireev, Alexander A. Dayal, Alexander A. Minin, Mathieu Maurin, Tatyana M. Svitkina, and Antonina Y. Alexandrova

Subjects

vimentin intermediate filaments, cell cortex, blebbing, mesenchymal-to-amoeboid transition, Cytology, QH573-671

Abstract

The formation of specific cellular protrusions, plasma membrane blebs, underlies the amoeboid mode of cell motility, which is characteristic for free-living amoebae and leukocytes, and can also be adopted by stem and tumor cells to bypass unfavorable migration conditions and thus facilitate their long-distance migration. Not all cells are equally prone to bleb formation. We have previously shown that membrane blebbing can be experimentally induced in a subset of HT1080 fibrosarcoma cells, whereas other cells in the same culture under the same conditions retain non-blebbing mesenchymal morphology. Here we show that this heterogeneity is associated with the distribution of vimentin intermediate filaments (VIFs). Using different approaches to alter the VIF organization, we show that blebbing activity is biased toward cell edges lacking abundant VIFs, whereas the VIF-rich regions of the cell periphery exhibit low blebbing activity. This pattern is observed both in interphase fibroblasts, with and without experimentally induced blebbing, and during mitosis-associated blebbing. Moreover, the downregulation of vimentin expression or displacement of VIFs away from the cell periphery promotes blebbing even in cells resistant to bleb-inducing treatments. Thus, we reveal a new important function of VIFs in cell physiology that involves the regulation of non-apoptotic blebbing essential for amoeboid cell migration and mitosis.

Published

2024

12. The effects of internal forces and membrane heterogeneity on three-dimensional cell shapes.

Author

Stotsky, Jay A. and Othmer, Hans G.

Subjects

*CELL morphology, *CELL division, *MODE shapes, *HETEROGENEITY, *CELL adhesion, *EXOCYTOSIS

Abstract

The shape of cells and the control thereof plays a central role in a variety of cellular processes, including endo- and exocytosis, cell division and cell movement. Intra- and extracellular forces control the shapes, and while the shape changes in some processes such as exocytosis are intracellularly-controlled and localized in the cell, movement requires force transmission to the environment, and the feedback from it can affect the cell shape and mode of movement used. The shape of a cell is determined by its cytoskeleton (CSK), and thus shape changes involved in various processes involve controlled remodeling of the CSK. While much is known about individual components involved in these processes, an integrated understanding of how intra- and extracellular signals are coupled to the control of the mechanical changes involved is not at hand for any of them. As a first step toward understanding the interaction between intracellular forces imposed on the membrane and cell shape, we investigate the role of distributed surrogates for cortical forces in producing the observed three-dimensional shapes. We show how different balances of applied forces lead to such shapes, that there are different routes to the same end state, and that state transitions between axisymmetric shapes need not all be axisymmetric. Examples of the force distributions that lead to protrusions are given, and the shape changes induced by adhesion of a cell to a surface are studied. The results provide a reference framework for developing detailed models of intracellular force distributions observed experimentally, and provide a basis for studying how movement of a cell in a tissue or fluid is influenced by its shape. [ABSTRACT FROM AUTHOR]

Published

2023

13. Self-Organization in the Cell

Author

Maly, Ivan and Maly, Ivan

Published

2021

14. Membrane Tension and the Role of Ezrin During Phagocytosis

Author

Roberts, Rhiannon E., Dewitt, Sharon, Hallett, Maurice B., Crusio, Wim E., Series Editor, Lambris, John D., Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, and Hallett, Maurice B., editor

Published

2020

15. Proteomic analysis of the actin cortex in interphase and mitosis.

Author

Vadnjal, Neza, Nourreddine, Sami, Lavoie, Geneviève, Serres, Murielle, Roux, Philippe P., and Paluch, Ewa K.

Subjects

*PROTEOMICS, *INTERPHASE, *ACTIN, *CELL morphology, *CELLULAR control mechanisms

Abstract

Many animal cell shape changes are driven by gradients in the contractile tension of the actomyosin cortex, a thin cytoskeletal network supporting the plasmamembrane. Elucidating cortical tension control is thus essential for understanding cell morphogenesis. Increasing evidence shows that alongside myosin activity, actin network organisation and composition are key to cortex tension regulation. However, owing to a poor understanding of how cortex composition changes when tension changes, which cortical components are important remains unclear. In this article, we compared cortices from cells with low and high cortex tensions. We purified cortex-enriched fractions fromcells in interphase andmitosis, asmitosis is characterised by high cortical tension. Mass spectrometry analysis identified 922 proteins consistently represented in both interphase and mitotic cortices. Focusing on actin-related proteins narrowed down the list to 238 candidate regulators of themitotic cortical tension increase. Among these candidates, we found that there is a role for septins in mitotic cell rounding control. Overall, our study provides a comprehensive dataset of candidate cortex regulators, paving the way for systematic investigations of the regulation of cell surface mechanics. [ABSTRACT FROM AUTHOR]

Published

2022

16. The mechanosensor Filamin A/Cheerio promotes tumourigenesis via specific interactions with components of the cell cortex.

Author

Külshammer, Eva, Kilinc, Merve, Csordás, Gábor, Bresser, Tina, Nolte, Hendrik, and Uhlirova, Mirka

Subjects

*CELL anatomy, *SCAFFOLD proteins, *IMAGINAL disks, *PROTEIN crosslinking, *SPECTRIN, *CONTRACTILE proteins, *MYOSIN

Abstract

Cancer development has been linked to aberrant sensing and interpretation of mechanical cues and force‐generating properties. Here, we show that upregulation of the actin crosslinking protein Cheerio (Cher), the fly ortholog of Filamin A (FLNA), and the conformation of its mechanosensitive region (MSR) are instrumental to the malignancy of polarity‐deficient, Ras‐driven tumours in Drosophila epithelia. We demonstrate that impaired growth and cytoskeletal contractility of tumours devoid of cher can be rescued by stimulating myosin activity. Profiling the Cher interactome in tumour‐bearing imaginal discs identified several components of the cell cortex, including the β‐heavy Spectrin Karst (Kst), the scaffolding protein Big bang (Bbg), and 14‐3‐3ε. We show that Cher binds Bbg through the MSR while the interaction with 14‐3‐3ε and Kst is MSR‐independent. Importantly, our genetic studies define Bbg, Kst, and 14‐3‐3ε as tumour suppressors. The tumour‐promoting function of Cher thus relies on its capacity to control the contractile state of the cytoskeleton through interactions with myosin and specific components of the cell cortex. [ABSTRACT FROM AUTHOR]

Published

2022

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

Author

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

Subjects

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

Abstract

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

Published

2022

18. Symmetry-breaking of animal cytokinesis.

Author

Sugioka, Kenji

Abstract

Cytokinesis is a mechanism that separates dividing cells via constriction of a supramolecular structure, the contractile ring. In animal cells, three modes of symmetry-breaking of cytokinesis result in unilateral cytokinesis, asymmetric cell division, and oriented cell division. Each mode of cytokinesis plays a significant role in tissue patterning and morphogenesis by the mechanisms that control the orientation and position of the contractile ring relative to the body axis. Despite its significance, the mechanisms involved in the symmetry-breaking of cytokinesis remain unclear in many cell types. Classical embryologists have identified that the geometric relationship between the mitotic spindle and cell cortex induces cytokinesis asymmetry; however, emerging evidence suggests that a concerted flow of compressional cell-cortex materials (cortical flow) is a spindle-independent driving force in spatial cytokinesis control. This review provides an overview of both classical and emerging mechanisms of cytokinesis asymmetry and their roles in animal development. • Mitotic spindle-dependent and -independent mechanisms underlie cytokinesis asymmetry. • Symmetry-breaking of cytokinesis contributes to animal morphogenesis. • Cortical flow may be a master regulator of spindle-independent cytokinesis control. [ABSTRACT FROM AUTHOR]

Published

2022

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

Author

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

Subjects

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

Abstract

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

Published

2022

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

Author

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

Subjects

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

Abstract

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

Published

2022

21. The Cdc42 GTPase-activating protein Rga6 promotes the cortical localization of septin.

Author

Shengnan Zheng, Biyu Zheng, Zhenbang Liu, Xiaopeng Ma, Xing Liu, Xuebiao Yao, Wenfan Wei, and Chuanhai Fu

Subjects

*GTPASE-activating protein, *CELL cycle proteins, *SCHIZOSACCHAROMYCES pombe, *CELL polarity, *G proteins

Abstract

Septins are a family of filament-forming GTP-binding proteins that regulate fundamental cellular activities, such as cytokinesis and cell polarity. In general, septin filaments function as barriers and scaffolds on the cell cortex. However, little is known about the mechanism that governs the recruitment and localization of the septin complex to the cell cortex. Here, we identified the Cdc42 GTPase-activating protein Rga6 as a key protein involved in promoting the localization of the septin complex to the cell cortex in the fission yeast Schizosaccharomyces pombe. Rga6 interacts with the septin complex and partially colocalizes with the septin complex on the cell cortex. Live-cell microscopy analysis further showed septin enrichment at the cortical regions adjacent to the growing cell tip. The septin enrichment likely plays a crucial role in confining active Cdc42 to the growing cell tip. Hence, our findings support a model whereby Rga6 regulates polarized cell growth partly through promoting targeted localization of the septin complex on the cell cortex. [ABSTRACT FROM AUTHOR]

Published

2022

22. Organization and dynamics of the cortical complexes controlling insulin secretion in β-cells.

Author

Noordstra, Ivar, van den Berg, Cyntha M., Boot, Fransje W. J., Katrukha, Eugene A., Ka Lou Yu, Tas, Roderick P., Portegies, Sybren, Viergever, Bastiaan J., de Graaff, Esther, Hoogenraad, Casper C., de Koning, Eelco J. P., Carlotti, Françoise, Kapitein, Lukas C., and Akhmanova, Anna

Subjects

*INSULIN, *FOCAL adhesions, *PHASE separation, *PANCREATIC secretions, *EXTRACELLULAR matrix, *ISLANDS of Langerhans, *SECRETION, *ULTRACOLD molecules

Abstract

Insulin secretion in pancreatic β-cells is regulated by cortical complexes that are enriched at the sites of adhesion to extracellular matrix facing the vasculature. Many components of these complexes, including bassoon, RIM, ELKS and liprins, are shared with neuronal synapses. Here, we show that insulin secretion sites also contain the non-neuronal proteins LL5β (also known as PHLDB2) and KANK1, which, in migrating cells, organize exocytotic machinery in the vicinity of integrin-based adhesions. Depletion of LL5β or focal adhesion disassembly triggered by myosin II inhibition perturbed the clustering of secretory complexes and attenuated the first wave of insulin release. Although previous analyses in vitro and in neurons have suggested that secretory machinery might assemble through liquid--liquid phase separation, analysis of endogenously labeled ELKS in pancreatic islets indicated that its dynamics is inconsistent with such a scenario. Instead, fluorescence recovery after photobleaching and single-molecule imaging showed that ELKS turnover is driven by binding and unbinding to low-mobility scaffolds. Both the scaffold movements and ELKS exchangewere stimulated by glucose treatment. Our findings help to explain how integrin-based adhesions control spatial organization of glucose-stimulated insulin release. [ABSTRACT FROM AUTHOR]

Published

2022

23. Fluid flow dynamics in cellular patterning.

Author

Kimura, Kenji and Motegi, Fumio

Subjects

*FLUID dynamics, *CELL physiology, *PROPERTIES of fluids, *CELL membranes, *FLUID flow

Abstract

The development of complex forms of multicellular organisms depends on the spatial arrangement of cellular architecture and functions. The interior design of the cell is patterned by spatially biased distributions of molecules and biochemical reactions in the cytoplasm and/or on the plasma membrane. In recent years, a dynamic change in the cytoplasmic fluid flow has emerged as a key physical process of driving long-range transport of molecules to particular destinations within the cell. Here, recent experimental advances in the understanding of the generation of the various types of cytoplasmic flows and contributions to intracellular patterning are reviewed with a particular focus on feedback mechanisms between the mechanical properties of fluid flow and biochemical signaling during animal cell polarization. [ABSTRACT FROM AUTHOR]

Published

2021

24. Chiral flows can induce neck formation in viscoelastic surfaces

Author

E M de Kinkelder, E Fischer-Friedrich, and S Aland

Subjects

viscoelastic surface dynamics, chiral flows, cell cortex, numerical simulation, Science, Physics, QC1-999

Abstract

The cell cortex is an active viscoelastic self-deforming sheet at the periphery of animal cells. It constricts animal cells during cell division. For some egg cells, the actomyosin cortex was shown to exhibit counter-rotating chiral flows along the axis of division. Such chiral surface flows were shown to contribute to spatial rearrangements and left-right symmetry breaking in developing organisms. In spite of this prospective biological importance, the effect of chiral forces on the flows and emergent shape dynamics of a deformable surface are completely unknown. To shed a first light on that matter, we present here a numerical study of an axisymmetric viscoelastic surface embedded in a viscous fluid. We impose a generic counter-rotating force field on this surface and study the resulting chiral flow field and shape dynamics for various surface mechanical parameters. Notably, we find that the building of a neck, as is observed during cell division, occurs if the surface contains a strong shear elastic component. Furthermore, we find that a large areal relaxation time results in flows towards the equator of the surface. These flows assist the transport of a surface concentration during the formation of a contractile ring. Accordingly, we show that chiral forces by themselves can drive pattern formation and stabilise contractile rings at the equator. These results provide first mechanistic evidence that chiral flows can play a significant role to orchestrate cell division.

Published

2023

25. Dia- and Rok-dependent enrichment of capping proteins in a cortical region.

Author

Schmidt, Anja, Long Li, Zhiyi Lv, Shuling Yan, and Großhans, Jörg

Subjects

*CAPPING proteins, *MYOSIN, *CYTOSKELETON, *F-actin, *PROTEIN binding, *DISTRIBUTION (Probability theory)

Abstract

Rho signaling with its major targets the formin Dia, Rho kinase (Rok) and non-muscle myosin II (MyoII, encoded by zip in flies) control turnover, amount and contractility of actomyosin. Much less investigated has been a potential function for the distribution of Factin plus and minus ends. In syncytial Drosophila embryos, Rho1 signaling is high between actin caps, i.e. the cortical intercap region. Capping protein binds to free plus ends of F-actin to prevent elongation of the filament. Capping protein has served as a marker to visualize the distribution of F-actin plus ends in cells and in vitro. In the present study, we probed the distribution of plus ends with capping protein in syncytial Drosophila embryos. We found that capping proteins are specifically enriched in the intercap region similar to Dia and MyoII but distinct from overall F-actin. The intercap enrichment of Capping protein was impaired in dia mutants and embryos, in which Rok and MyoII activation was inhibited. Our observations reveal that Dia and Rok-MyoII control Capping protein enrichment and support a model that Dia and Rok-MyoII control the organization of cortical actin cytoskeleton downstream of Rho1 signaling. This article has an associated First Person interview with the first authors of the paper. [ABSTRACT FROM AUTHOR]

Published

2021

26. A Three-Dimensional Numerical Model of an Active Cell Cortex in the Viscous Limit

Author

Christian Bächer, Diana Khoromskaia, Guillaume Salbreux, and Stephan Gekle

Subjects

active membranes, viscus membranes, cell cortex, cell mechanics, computational fluid dynamics, biological physics, Physics, QC1-999

Abstract

The cell cortex is a highly dynamic network of cytoskeletal filaments in which motor proteins induce active cortical stresses which in turn drive dynamic cellular processes such as cell motility, furrow formation or cytokinesis during cell division. Here, we develop a three-dimensional computational model of a cell cortex in the viscous limit including active cortical flows. Combining active gel and thin shell theory, we base our computational tool directly on the force balance equations for the velocity field on a discretized and arbitrarily deforming cortex. Since our method is based on the general force balance equations, it can easily be extended to more complex biological dependencies in terms of the constitutive laws or a dynamic coupling to a suspending fluid. We validate our algorithm by investigating the formation of a cleavage furrow on a biological cell immersed in a passive outer fluid, where we successfully compare our results to axi-symmetric simulations. We then apply our fully three-dimensional algorithm to fold formation and to study furrow formation under the influence of non-axisymmetric disturbances such as external shear. We report a reorientation mechanism by which the cell autonomously realigns its axis perpendicular to the furrow plane thus contributing to the robustness of cell division under realistic environmental conditions.

Published

2021

27. Differential Roles of Actin Crosslinking Proteins Filamin and α-Actinin in Shear Flow-Induced Migration of Dictyostelium discoideum

Author

Aaron Cole, Sarah Buckler, Jack Marcucci, and Yulia Artemenko

Subjects

directed migration, mechanotransduction, signal transduction network, mechanical perturbation, shear stress, cell cortex, Biology (General), QH301-705.5

Abstract

Shear flow-induced migration is an important physiological phenomenon experienced by multiple cell types, including leukocytes and cancer cells. However, molecular mechanisms by which cells sense and directionally migrate in response to mechanical perturbation are not well understood. Dictyostelium discoideum social amoeba, a well-established model for studying amoeboid-type migration, also exhibits directional motility when exposed to shear flow, and this behavior is preceded by rapid and transient activation of the same signal transduction network that is activated by chemoattractants. The initial response, which can also be observed following brief 2 s stimulation with shear flow, requires an intact actin cytoskeleton; however, what aspect of the cytoskeletal network is responsible for sensing and/or transmitting the signal is unclear. We investigated the role of actin crosslinkers filamin and α-actinin by analyzing initial shear flow-stimulated responses in cells with or without these proteins. Both filamin and α-actinin showed rapid and transient relocalization from the cytosol to the cortex following shear flow stimulation. Using spatiotemporal analysis of Ras GTPase activation as a readout of signal transduction network activity, we demonstrated that lack of α-actinin did not reduce, and, in fact, slightly improved the response to acute mechanical stimulation compared to cells expressing α-actinin. In contrast, shear flow-induced Ras activation was significantly more robust in filamin-null cells rescued with filamin compared to cells expressing empty vector. Reduced responsiveness appeared to be specific to mechanical stimuli and was not due to a change in the basal activity since response to global stimulation with a chemoattractant and random migration was comparable between cells with or without filamin. Finally, while filamin-null cells rescued with filamin efficiently migrated upstream when presented with continuous flow, cells lacking filamin were defective in directional migration. Overall, our study suggests that filamin, but not α-actinin, is involved in sensing and/or transmitting mechanical stimuli that drive directed migration; however, other components of the actin cytoskeleton likely also contribute to the initial response since filamin-null cells were still able to activate the signal transduction network. These findings could have implications for our fundamental understanding of shear flow-induced migration of leukocytes, cancer cells and other amoeboid-type cells.

Published

2021

28. Emergence of a smooth interface from growth of a dendritic network against a mechanosensitive contractile material

Author

Medha Sharma, Tao Jiang, Zi Chen Jiang, Carlos E Moguel-Lehmer, and Tony JC Harris

Subjects

cell cortex, actomyosin, Arp2/3, mechanosensitivity, pattern formation, drosophila embryo pseudo-cleavage, Medicine, Science, Biology (General), QH301-705.5

Abstract

Structures and machines require smoothening of raw materials. Self-organized smoothening guides cell and tissue morphogenesis and is relevant to advanced manufacturing. Across the syncytial Drosophila embryo surface, smooth interfaces form between expanding Arp2/3-based actin caps and surrounding actomyosin networks, demarcating the circumferences of nascent dome-like compartments used for pseudocleavage. We found that forming a smooth and circular boundary of the surrounding actomyosin domain requires Arp2/3 in vivo. To dissect the physical basis of this requirement, we reconstituted the interacting networks using node-based models. In simulations of actomyosin networks with local clearances in place of Arp2/3 domains, rough boundaries persisted when myosin contractility was low. With addition of expanding Arp2/3 network domains, myosin domain boundaries failed to smoothen, but accumulated myosin nodes and tension. After incorporating actomyosin mechanosensitivity, Arp2/3 network growth locally induced a surrounding contractile actomyosin ring that smoothened the interface between the cytoskeletal domains, an effect also evident in vivo. In this way, a smooth structure can emerge from the lateral interaction of irregular active materials.

Published

2021

29. Symmetry Does not Come for Free: Cellular Mechanisms to Achieve a Symmetric Cell Division

Author

Dudka, Damian, Meraldi, Patrick, Kubiak, Jacek Z., Series editor, Kloc, Malgorzata, Series editor, and Tassan, Jean-Pierre, editor

Published

2017

30. Generation of stress fibers through myosin-driven reorganization of the actin cortex

Author

Jaakko I Lehtimäki, Eeva Kaisa Rajakylä, Sari Tojkander, and Pekka Lappalainen

Subjects

actin, myosin, stress fiber, mechanosensing, cell adhesion, cell cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

Contractile actomyosin bundles, stress fibers, govern key cellular processes including migration, adhesion, and mechanosensing. Stress fibers are thus critical for developmental morphogenesis. The most prominent actomyosin bundles, ventral stress fibers, are generated through coalescence of pre-existing stress fiber precursors. However, whether stress fibers can assemble through other mechanisms has remained elusive. We report that stress fibers can also form without requirement of pre-existing actomyosin bundles. These structures, which we named cortical stress fibers, are embedded in the cell cortex and assemble preferentially underneath the nucleus. In this process, non-muscle myosin II pulses orchestrate the reorganization of cortical actin meshwork into regular bundles, which promote reinforcement of nascent focal adhesions, and subsequent stabilization of the cortical stress fibers. These results identify a new mechanism by which stress fibers can be generated de novo from the actin cortex and establish role for stochastic myosin pulses in the assembly of functional actomyosin bundles.

Published

2021

31. Collective dynamics of actin and microtubule and its crosstalk mediated by FHDC1.

Author

Tong CS, Su M, Sun H, Chua XL, Xiong D, Guo S, Raj R, Ong NWP, Lee AG, Miao Y, and Wu M

Abstract

The coordination between actin and microtubule network is crucial, yet this remains a challenging problem to dissect and our understanding of the underlying mechanisms remains limited. In this study, we used travelling waves in the cell cortex to characterize the collective dynamics of cytoskeletal networks. Our findings show that Cdc42 and F-BAR-dependent actin waves in mast cells are mainly driven by formin-mediated actin polymerization, with the microtubule-binding formin FH2 domain-containing protein 1 (FHDC1) as an early regulator. Knocking down FHDC1 inhibits actin wave formation, and this inhibition require FHDC1's interaction with both microtubule and actin. The phase of microtubule depolymerization coincides with the nucleation of actin waves and microtubule stabilization inhibit actin waves, leading us to propose that microtubule shrinking and the concurrent release of FHDC1 locally regulate actin nucleation. Lastly, we show that FHDC1 is crucial for multiple cellular processes such as cell division and migration. Our data provided molecular insights into the nucleation mechanisms of actin waves and uncover an antagonistic interplay between microtubule and actin polymerization in their collective dynamics., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Tong, Su, Sun, Chua, Xiong, Guo, Raj, Ong, Lee, Miao and Wu.)

Published

2024

32. Global and local functions of the Fused kinase ortholog CdaH in intracellular patterning in Tetrahymena.

Author

Lee C, Maier W, Jiang YY, Nakano K, Lechtreck KF, and Gaertig J

Subjects

Cell Division genetics, Acetamides, Cytoskeleton, Tetrahymena genetics, Tetrahymena thermophila genetics

Abstract

Ciliates assemble numerous microtubular structures into complex cortical patterns. During ciliate division, the pattern is duplicated by intracellular segmentation that produces a tandem of daughter cells. In Tetrahymena thermophila, the induction and positioning of the division boundary involves two mutually antagonistic factors: posterior CdaA (cyclin E) and anterior CdaI (Hippo kinase). Here, we characterized the related cdaH-1 allele, which confers a pleiotropic patterning phenotype including an absence of the division boundary and an anterior-posterior mispositioning of the new oral apparatus. CdaH is a Fused or Stk36 kinase ortholog that localizes to multiple sites that correlate with the effects of its loss, including the division boundary and the new oral apparatus. CdaH acts downstream of CdaA to induce the division boundary and drives asymmetric cytokinesis at the tip of the posterior daughter. CdaH both maintains the anterior-posterior position of the new oral apparatus and interacts with CdaI to pattern ciliary rows within the oral apparatus. Thus, CdaH acts at multiple scales, from induction and positioning of structures on the cell-wide polarity axis to local organelle-level patterning., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2023. Published by The Company of Biologists Ltd.)

Published

2024

33. Cellular Membranes, a Versatile Adaptive Composite Material

Author

Lucas Lamparter and Milos Galic

Subjects

composite material, adaptive material, lipid bilayer, plasma membrane, cell cortex, Biology (General), QH301-705.5

Abstract

Cellular membranes belong to the most vital yet least understood biomaterials of live matter. For instance, its biomechanical requirements substantially vary across species and subcellular sites, raising the question how membranes manage to adjust to such dramatic changes. Central to its adaptability at the cell surface is the interplay between the plasma membrane and the adjacent cell cortex, forming an adaptive composite material that dynamically adjusts its mechanical properties. Using a hypothetical composite material, we identify core challenges, and discuss how cellular membranes solved these tasks. We further muse how pathological changes in material properties affect membrane mechanics and cell function, before closing with open questions and future challenges arising when studying cellular membranes.

Published

2020

34. Tissue segregation in the early vertebrate embryo.

Author

Fagotto, François

Subjects

*EMBRYOS, *EPIBLAST, *CELL populations, *EPITHELIAL cells

Abstract

This chapter discusses our current knowledge on the major segregation events that lead to the individualization of the building blocks of vertebrate organisms, starting with the segregation between "outer" and "inner" cells, the separation of the germ layers and the maintenance of their boundaries during gastrulation, and finally the emergence of the primary axial structure, the notochord. The amphibian embryo is used as the prototypical model, to which fish and mouse development are compared. This comparison highlights a striking conservation of the basic processes. It suggests that simple principles may account for the formation of divergent structures. One of them is based on the non-adhesive nature of the apical domain of epithelial cells, exploited to segregate superficial and deep cell populations as a result of asymmetric division. The other principle involves differential expression of contact cues, such as ephrins and protocadherins, to build up high tension along adhesive interfaces, which efficiently creates sharp boundaries. [ABSTRACT FROM AUTHOR]

Published

2020

35. Actin Cell Cortex: Structure and Molecular Organization.

Author

Svitkina, Tatyana M.

Subjects

*MOLECULAR structure, *ACTIN, *CELL anatomy, *CELLULAR mechanics, *CELL membranes, *CYTOSKELETON

Abstract

The actin cytoskeleton consists of structurally and biochemically different actin filament arrays. Among them, the actin cortex is thought to have key roles in cell mechanics, but remains a poorly characterized part of the actin cytoskeleton. The cell cortex is typically defined as a thin layer of actin meshwork that uniformly underlies the plasma membrane of the entire cell. However, this definition applies only to specific cases. In general, the cortex structure and subcellular distribution vary significantly across cell types and physiological states of the cell. In this review, I focus on our current knowledge of the structure and molecular composition of the cell cortex. Actin cell cortex is a heterogeneous and nonubiquitous actin cytoskeleton component. Diverse actin filament arrays can mix and match within the cortex in different combinations. Contractile and protrusive actin machineries cooperate and compete within the cell cortex. [ABSTRACT FROM AUTHOR]

Published

2020

36. From Molecules to Cells: Machines, Symmetries, and Feedbacks

Author

Beloussov, Lev V. and Beloussov, Lev V.

Published

2015

37. A theory that predicts behaviors of disordered cytoskeletal networks

Author

Julio M Belmonte, Maria Leptin, and François Nédélec

Subjects

actin, active gel, cell cortex, contractility, morphogenesis, Biology (General), QH301-705.5, Medicine (General), R5-920

Abstract

Abstract Morphogenesis in animal tissues is largely driven by actomyosin networks, through tensions generated by an active contractile process. Although the network components and their properties are known, and networks can be reconstituted in vitro, the requirements for contractility are still poorly understood. Here, we describe a theory that predicts whether an isotropic network will contract, expand, or conserve its dimensions. This analytical theory correctly predicts the behavior of simulated networks, consisting of filaments with varying combinations of connectors, and reveals conditions under which networks of rigid filaments are either contractile or expansile. Our results suggest that pulsatility is an intrinsic behavior of contractile networks if the filaments are not stable but turn over. The theory offers a unifying framework to think about mechanisms of contractions or expansion. It provides the foundation for studying a broad range of processes involving cytoskeletal networks and a basis for designing synthetic networks.

Published

2017

38. Actin dynamics during Ca2+-dependent exocytosis of endothelial Weibel-Palade bodies.

Author

Mietkowska, Magdalena, Schuberth, Christian, Wedlich-Söldner, Roland, and Gerke, Volker

Subjects

*ACTIN, *EXOCYTOSIS, *INTRACELLULAR calcium, *CYTOSKELETON, *ORGANELLES, *ENDOPLASMIC reticulum

Abstract

Abstract Weibel-Palade bodies (WPBs) are specialized secretory organelles of endothelial cells that serve important functions in the response to inflammation and vascular injury. WPBs actively respond to different stimuli by regulated exocytosis leading to full or selective release of their contents. Cellular conditions and mechanisms that distinguish between these possibilities are only beginning to emerge. To address this we analyzed dynamic rearrangements of the actin cytoskeleton during histamine-stimulated, Ca2+-dependent WPB exocytosis. We show that most WPB fusion events are followed by a rapid release of von-Willebrand factor (VWF), the large WPB cargo, and that this occurs concomitant with a softening of the actin cortex by the recently described Ca2+-dependent actin reset (CaAR). However, a considerable fraction of WPB fusion events is characterized by a delayed release of VWF and observed after the CaAR reaction peak. These delayed VWF secretions are accompanied by an assembly of actin rings or coats around the WPB post-fusion structures and are also seen following direct elevation of intracellular Ca2+ by plasma membrane wounding. Actin ring/coat assembly at WPB post-fusion structures requires Rho GTPase activity and is significantly reduced upon expression of a dominant-active mutant of the formin INF2 that triggers a permanent CaAR peak-like sequestration of actin to the endoplasmic reticulum. These findings suggest that a rigid actin cortex correlates with a higher proportion of fused WPB which assemble actin rings/coats most likely required for efficient VWF expulsion and/or stabilization of a WPB post-fusion structure. This article is part of a Special Issue entitled: ECS Meeting edited by Claus Heizmann, Joachim Krebs and Jacques Haiech. Highlights • Ca2+-dependent exocytosis of Weibel-Palade bodies (WPBs) is characterized by different post-fusion morphologies. • Actin is recruited in the form of rings/coats to a subset of WPB fusion sites. • This actin recruitment is Rho dependent. • The actin recruitment is inhibited by expression of a dominant-active inverted formin 2. [ABSTRACT FROM AUTHOR]

Published

2019

39. Polarity sorting drives remodeling of actin-myosin networks.

Author

Wollrab, Viktoria, Belmonte, Julio M., Baldauf, Lucia, Leptin, Maria, Ne'dele'c, François, and Koenderink, Gijsje H.

Subjects

*CYTOSKELETAL proteins, *MUSCLE contraction, *BIPOLAR cells

Abstract

Cytoskeletal networks of actin filaments and myosin motors drive many dynamic cell processes. A key characteristic of these networks is their contractility. Despite intense experimental and theoretical efforts, it is not clear what mechanism favors network contraction over expansion. Recent work points to a dominant role for the nonlinear mechanical response of actin filaments, which can withstand stretching but buckle upon compression. Here, we present an alternative mechanism. We study how interactions between actin and myosin-2 at the single-filament level translate into contraction at the network scale by performing time-lapse imaging on reconstituted quasi-2D networks mimicking the cell cortex. We observe myosin end-dwelling after it runs processively along actin filaments. This leads to transport and clustering of actin filament ends and the formation of transiently stable bipolar structures. Further, we show that myosin-driven polarity sorting produces polar actin asters, which act as contractile nodes that drive contraction in crosslinked networks. Computer simulations comparing the roles of the end-dwelling mechanism and a buckling-dependent mechanism show that the relative contribution of end-dwelling contraction increases as the network mesh-size decreases. [ABSTRACT FROM AUTHOR]

Published

2019

40. Cortical tension drug screen links mitotic spindle integrity to Rho pathway.

Author

Wang, Dejiang, Wang, Yao, Di, Xiangjun, Wang, Fan, Wanninayaka, Amanda, Carnell, Michael, Hardeman, Edna C., Jin, Dayong, and Gunning, Peter W.

Subjects

*SPINDLE apparatus, *CELL morphology, *MYOSIN, *CELL physiology, *SMALL molecules, *DRUG target

Abstract

Mechanical force generation plays an essential role in many cellular functions, including mitosis. Actomyosin contractile forces mediate changes in cell shape in mitosis and are implicated in mitotic spindle integrity via cortical tension. An unbiased screen of 150 small molecules that impact actin organization and 32 anti-mitotic drugs identified two molecular targets, Rho kinase (ROCK) and tropomyosin 3.1/2 (Tpm3.1/2), whose inhibition has the greatest impact on mitotic cortical tension. The converse was found for compounds that depolymerize microtubules. Tpm3.1/2 forms a co-polymer with mitotic cortical actin filaments, and its inhibition prevents rescue of multipolar spindles induced by anti-microtubule chemotherapeutics. We examined the role of mitotic cortical tension in this rescue mechanism. Inhibition of ROCK and Tpm3.1/2 and knockdown (KD) of cortical nonmuscle myosin 2A (NM2A), all of which reduce cortical tension, inhibited rescue of multipolar mitotic spindles, further implicating cortical tension in the rescue mechanism. GEF-H1 released from microtubules by depolymerization increased cortical tension through the RhoA pathway, and its KD also inhibited rescue of multipolar mitotic spindles. We conclude that microtubule depolymerization by anti-cancer drugs induces cortical-tension-based rescue to ensure integrity of the mitotic bipolar spindle mediated via the RhoA pathway. Central to this mechanism is the dependence of NM2A on Tpm3.1/2 to produce the functional engagement of actin filaments responsible for cortical tension. • Rho kinase and tropomyosin Tpm3.1 are key determinants of mitotic cortical tension • Cortical tension mediates rescue of the bipolar spindle from microtubule asters • Agents that compromise mitotic cortical tension inhibit bipolar spindle rescue • Microtubule depolymerization releases active GEF-H1 to promote cortical tension Mitotic cortical tension is mediated by Rho kinase, Tpm3.1/actin filaments, nonmuscle myosin 2A, and GEF-H1. Wang et al. demonstrate that agents that compromise any one of these mediators collaborate with microtubule depolymerizers to promote microtubule aster formation and inhibit generation of a bipolar mitotic spindle. [ABSTRACT FROM AUTHOR]

Published

2023

41. Actin and Myosin in Non-Neuronal Exocytosis

Author

Pika Miklavc and Manfred Frick

Subjects

secretion, vesicle trafficking, cell cortex, actin coat, Cytology, QH573-671

Abstract

Cellular secretion depends on exocytosis of secretory vesicles and discharge of vesicle contents. Actin and myosin are essential for pre-fusion and post-fusion stages of exocytosis. Secretory vesicles depend on actin for transport to and attachment at the cell cortex during the pre-fusion phase. Actin coats on fused vesicles contribute to stabilization of large vesicles, active vesicle contraction and/or retrieval of excess membrane during the post-fusion phase. Myosin molecular motors complement the role of actin. Myosin V is required for vesicle trafficking and attachment to cortical actin. Myosin I and II members engage in local remodeling of cortical actin to allow vesicles to get access to the plasma membrane for membrane fusion. Myosins stabilize open fusion pores and contribute to anchoring and contraction of actin coats to facilitate vesicle content release. Actin and myosin function in secretion is regulated by a plethora of interacting regulatory lipids and proteins. Some of these processes have been first described in non-neuronal cells and reflect adaptations to exocytosis of large secretory vesicles and/or secretion of bulky vesicle cargoes. Here we collate the current knowledge and highlight the role of actomyosin during distinct phases of exocytosis in an attempt to identify unifying molecular mechanisms in non-neuronal secretory cells.

Published

2020

42. Mechanical Counterbalance of Kinesin and Dynein Motors in a Microtubular Network Regulates Cell Mechanics, 3D Architecture, and Mechanosensing

Author

Rakesh K. Singh, Dylan T. Burnette, Erdem Tabdanov, James. B. Hayes, Alexis Manning, Chynna Smith, Nikolay V. Dokholyan, Alexander Zhovmer, Jing Wang, and Alexander X. Cartagena-Rivera

Subjects

Chemistry, Dynein, General Engineering, Dyneins, Kinesins, General Physics and Astronomy, macromolecular substances, Microtubules, Actins, Contact guidance, Motor protein, Mechanobiology, Microtubule, Cell cortex, Biophysics, Kinesin, General Materials Science, Cell adhesion, Septins

Abstract

Microtubules (MTs) and MT motor proteins form active 3D networks made of unstretchable cables with rod-like bending mechanics that provide cells with a dynamically changing structural scaffold. In this study, we report an antagonistic mechanical balance within the dynein-kinesin microtubular motor system. Dynein activity drives the microtubular network inward compaction, while isolated activity of kinesins bundles and expands MTs into giant circular bands that deform the cell cortex into discoids. Furthermore, we show that dyneins recruit MTs to sites of cell adhesion, increasing the topographic contact guidance of cells, while kinesins antagonize it via retraction of MTs from sites of cell adhesion. Actin-to-microtubule translocation of septin-9 enhances kinesin-MT interactions, outbalances the activity of kinesins over that of dyneins, and induces the discoid architecture of cells. These orthogonal mechanisms of MT network reorganization highlight the existence of an intricate mechanical balance between motor activities of kinesins and dyneins that controls cell 3D architecture, mechanics, and cell-microenvironment interactions.

Published

2021

43. Intracellular softening and increased viscoelastic fluidity during division

Author

Sebastian Hurst, Bart Vos, M. Brandt, and Timo Betz

Subjects

Microrheology, Physics, Cell division, Cytoplasm, Cell cortex, Biophysics, General Physics and Astronomy, Softening, Mitosis, Intracellular, Actin

Abstract

The life and death of an organism rely on correct cell division, which occurs through the process of mitosis. Although the biochemical signalling and morphogenetic processes during mitosis are well understood, the importance of mechanical forces and material properties is only just starting to be discovered. Recent studies have revealed that the layer of proteins beneath the cell membrane—the so-called cell cortex—stiffens during mitosis, but it is as yet unclear whether mechanical changes occur in the rest of the material in the cell, contained in the cytoplasm. Here we show that, in contrast to the cortical stiffening, the interior of the cell undergoes a softening and an increase in dissipative timescale, similar to viscoelastic relaxation. These mechanical changes are accompanied by a decrease in the active forces that drive particle mobility. Using optical tweezers to perform microrheology measurements, we capture the complex active and passive material states of the cytoplasm using six relevant parameters, of which only two vary considerably during mitosis. We demonstrate a role switch between microtubules and actin that could contribute to the observed softening. The cell cortex stiffens during cell division, facilitating the necessary shape changes. Microrheology measurements now reveal that the rest of the cell interior actually softens, in a process that probably involves two key biomolecules trading roles.

Published

2021

44. A proteomic study of mitotic phase-specific interactors of EB1 reveals a role for SXIP-mediated protein interactions in anaphase onset

Author

Naoka Tamura, Judith E. Simon, Arnab Nayak, Rajesh Shenoy, Noriko Hiroi, Viviane Boilot, Akira Funahashi, and Viji M. Draviam

Subjects

Cell cortex, Kinetochore, Microtubule, Mitosis, Plus-end, Science, Biology (General), QH301-705.5

Abstract

Microtubules execute diverse mitotic events that are spatially and temporally separated; the underlying regulation is poorly understood. By combining drug treatments, large-scale immunoprecipitation and mass spectrometry, we report the first comprehensive map of mitotic phase-specific protein interactions of the microtubule-end binding protein, EB1. EB1 interacts with some, but not all, of its partners throughout mitosis. We show that the interaction of EB1 with Astrin-SKAP complex, a key regulator of chromosome segregation, is enhanced during prometaphase, compared to anaphase. We find that EB1 and EB3, another EB family member, can interact directly with SKAP, in an SXIP-motif dependent manner. Using an SXIP defective mutant that cannot interact with EB, we uncover two distinct pools of SKAP at spindle microtubules and kinetochores. We demonstrate the importance of SKAP's SXIP-motif in controlling microtubule growth rates and anaphase onset, without grossly disrupting spindle function. Thus, we provide the first comprehensive map of temporal changes in EB1 interactors during mitosis and highlight the importance of EB protein interactions in ensuring normal mitosis.

Published

2015

45. Disrupting actin filaments enhances glucose-stimulated insulin secretion independent of the cortical actin cytoskeleton.

Author

Polino AJ, Ng XW, Rooks R, and Piston DW

Subjects

Animals, Glucose pharmacology, Insulin metabolism, Actin Cytoskeleton metabolism, Actins metabolism, Insulin Secretion, Insulin-Secreting Cells metabolism

Abstract

Just under the plasma membrane of most animal cells lies a dense meshwork of actin filaments called the cortical cytoskeleton. In insulin-secreting pancreatic β cells, a long-standing model posits that the cortical actin layer primarily acts to restrict access of insulin granules to the plasma membrane. Here we test this model and find that stimulating β cells with pro-secretory stimuli (glucose and/or KCl) has little impact on the cortical actin layer. Chemical perturbations of actin polymerization, by either disrupting or enhancing filamentation, dramatically enhance glucose-stimulated insulin secretion. Using scanning electron microscopy, we directly visualize the cortical cytoskeleton, allowing us to validate the effect of these filament-disrupting chemicals. We find the state of the cortical actin layer does not correlate with levels of insulin secretion, suggesting filament disruptors act on insulin secretion independently of the cortical cytoskeleton., Competing Interests: Conflict of interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

46. Modeling the dynamics of actin and myosin during bleb stabilization.

Author

Asante-Asamani E, Dalton M, Brazill D, and Strychalski W

Abstract

The actin cortex is very dynamic during migration of eukaryotes. In cells that use blebs as leading-edge protrusions, the cortex reforms beneath the cell membrane (bleb cortex) and completely disassembles at the site of bleb initiation. Remnants of the actin cortex at the site of bleb nucleation are referred to as the actin scar. We refer to the combined process of cortex reformation along with the degradation of the actin scar during bleb-based cell migration as bleb stabilization . The molecular factors that regulate the dynamic reorganization of the cortex are not fully understood. Myosin motor protein activity has been shown to be necessary for blebbing, with its major role associated with pressure generation to drive bleb expansion. Here, we examine the role of myosin in regulating cortex dynamics during bleb stabilization. Analysis of microscopy data from protein localization experiments in Dictyostelium discoideum cells reveals a rapid formation of the bleb's cortex with a delay in myosin accumulation. In the degrading actin scar, myosin is observed to accumulate before active degradation of the cortex begins. Through a combination of mathematical modeling and data fitting, we identify that myosin helps regulate the equilibrium concentration of actin in the bleb cortex during its reformation by increasing its dissasembly rate. Our modeling and analysis also suggests that cortex degradation is driven primarily by an exponential decrease in actin assembly rate rather than increased myosin activity. We attribute the decrease in actin assembly to the separation of the cell membrane from the cortex after bleb nucleation., Competing Interests: Declaration of interests The authors declare no competing interests

Published

2023

47. Pattern formation in development in which shell-related mechanisms are implicated

Author

Meinhardt, Hans and Meinhardt, Hans

Published

2009

48. Cytokinesis in vertebrate cells initiates by contraction of an equatorial actomyosin network composed of randomly oriented filaments

Author

Felix Spira, Sara Cuylen-Haering, Shalin Mehta, Matthias Samwer, Anne Reversat, Amitabh Verma, Rudolf Oldenbourg, Michael Sixt, and Daniel W Gerlich

Subjects

cytokinesis, actomyosin ring, cell division, actin, fluorescence polarization microscopy, cell cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

The actomyosin ring generates force to ingress the cytokinetic cleavage furrow in animal cells, yet its filament organization and the mechanism of contractility is not well understood. We quantified actin filament order in human cells using fluorescence polarization microscopy and found that cleavage furrow ingression initiates by contraction of an equatorial actin network with randomly oriented filaments. The network subsequently gradually reoriented actin filaments along the cell equator. This strictly depended on myosin II activity, suggesting local network reorganization by mechanical forces. Cortical laser microsurgery revealed that during cytokinesis progression, mechanical tension increased substantially along the direction of the cell equator, while the network contracted laterally along the pole-to-pole axis without a detectable increase in tension. Our data suggest that an asymmetric increase in cortical tension promotes filament reorientation along the cytokinetic cleavage furrow, which might have implications for diverse other biological processes involving actomyosin rings.

Published

2017

49. Extraction of accurate cytoskeletal actin velocity distributions from noisy measurements

Author

Alexander R. Dunn, Cayla M. Miller, and Elgin Korkmazhan

Subjects

Physics, Fluorescence-lifetime imaging microscopy, Multidisciplinary, Dynamics (mechanics), Endothelial Cells, General Physics and Astronomy, Bayes Theorem, macromolecular substances, General Chemistry, Actin cytoskeleton, Actins, General Biochemistry, Genetics and Molecular Biology, Quantitative Biology::Cell Behavior, Quantitative Biology::Subcellular Processes, Protein filament, Actin Cytoskeleton, Cell cortex, Cytoskeleton, Biological system, Jump process, Actin

Abstract

Dynamic remodeling of the actin cytoskeleton allows cells to migrate, change shape, and exert mechanical forces on their surroundings. How the complex dynamical behavior of the cytoskeleton arises from the interactions of its molecular components remains incompletely understood. Tracking the movement of individual actin filaments in living cells can in principle provide a powerful means of addressing this question. However, single-molecule fluorescence imaging measurements that could provide this information are limited by low signal-to-noise ratios, with the result that the localization errors for individual fluorophore fiducials attached to filamentous (F)-actin are comparable to the distances traveled by actin filaments between measurements. In this study we tracked the movement F-actin labeled with single-molecule densities of the fluorogenic label SiR-actin in primary fibroblasts and endothelial cells. We then used a Bayesian statistical approach to estimate true, underlying actin filament velocity distributions from the tracks of individual actin-associated fluorophores along with quantified localization uncertainties. This analysis approach is broadly applicable to inferring statistical pairwise distance distributions arising from noisy point localization measurements such as occur in superresolution microscopy. We found that F-actin velocity distributions were better described by a statistical jump process, in which filaments exist in mechanical equilibria punctuated by abrupt, jump-like movements, than by models incorporating combinations of diffusive motion and drift. A model with exponentially distributed time- and length-scales for filament jumps recapitulated F-actin velocity distributions measured for the cell cortex, integrin-based adhesions, and actin stress fibers, indicating that a common physical model can potentially describe F-actin dynamics in a variety of cellular contexts.

Published

2022

50. Segmentation and 3D Reconstruction of Microtubules in Total Internal Reflection Fluorescence Microscopy (TIRFM)

Author

Hadjidemetriou, Stathis, Toomre, Derek, Duncan, James S., Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Dough, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Duncan, James S., editor, and Gerig, Guido, editor

Published

2005