Your search keyword '"collective migration"' showing total 685 results

1. Self-extinguishing relay waves enable homeostatic control of human neutrophil swarming.

Author

Strickland, Evelyn, Pan, Deng, Godfrey, Christian, Kim, Julia S., Hopke, Alex, Ji, Wencheng, Degrange, Maureen, Villavicencio, Bryant, Mansour, Michael K., Zerbe, Christa S., Irimia, Daniel, Amir, Ariel, and Weiner, Orion D.

Subjects

*CHRONIC granulomatous disease, *SWARMING (Zoology), *NADPH oxidase, *CELL motility, *WAVENUMBER

Abstract

Neutrophils collectively migrate to sites of injury and infection. How these swarms are coordinated to ensure the proper level of recruitment is unknown. Using an ex vivo model of infection, we show that human neutrophil swarming is organized by multiple pulsatile chemoattractant waves. These waves propagate through active relay in which stimulated neutrophils trigger their neighbors to release additional swarming cues. Unlike canonical active relays, we find these waves to be self-terminating, limiting the spatial range of cell recruitment. We identify an NADPH-oxidase-based negative feedback loop that is needed for this self-terminating behavior. We observe near-constant levels of neutrophil recruitment over a wide range of starting conditions, revealing surprising robustness in the swarming process. This homeostatic control is achieved by larger and more numerous swarming waves at lower cell densities. We link defective wave termination to a broken recruitment homeostat in the context of human chronic granulomatous disease. [Display omitted] • Neutrophil swarming is organized by pulsatile, self-extinguishing waves of LTB4 • NADPH-oxidase activation is critical for relay wave self-extinction • Neutrophils adjust the size and number of waves to homeostatically control recruitment • Chronic granulomatosis disease neutrophils generate undamped relay waves that do not extinguish Strickland et al. find that human neutrophils organize pulsatile, self-extinguishing waves of leukotriene B4 to ensure robust homeostatic recruitment. Self-extinguishing waves are dependent on the activity of NADPH oxidase, and deficiency in this pathway leads to a reduced ability to extinguish relay waves. [ABSTRACT FROM AUTHOR]

Published

2024

2. Multiphoton excited polymerized biomimetic models of collagen fiber morphology to study single cell and collective migration dynamics in pancreatic cancer.

Author

Mancha, Sophie, Horan, Meghan, Pasachhe, Ojaswi, Keikhosravi, Adib, Eliceiri, Kevin W., Matkowskyj, Kristina A., Notbohm, Jacob, Skala, Melissa C., and Campagnola, Paul J.

Subjects

SECOND harmonic generation, CANCER cell migration, BIOMIMETIC polymers, CELL morphology, CYTOLOGY

Abstract

The respective roles of aligned collagen fiber morphology found in the extracellular matrix (ECM) of pancreatic cancer patients and cellular migration dynamics have been gaining attention because of their connection with increased aggressive phenotypes and poor prognosis. To better understand how collagen fiber morphology influences cell-matrix interactions associated with metastasis, we used Second Harmonic Generation (SHG) images from patient biopsies with Pancreatic ductal adenocarcinoma (PDAC) as models to fabricate collagen scaffolds to investigate processes associated with motility. Using the PDAC BxPC-3 metastatic cell line, we investigated single and collective cell dynamics on scaffolds of varying collagen alignment. Collective or clustered cells grown on the scaffolds with the highest collagen fiber alignment had increased E-cadherin expression and larger focal adhesion sites compared to single cells, consistent with metastatic behavior. Analysis of single cell motility revealed that the dynamics were characterized by random walk on all substrates. However, examining collective motility over different time points showed that the migration was super-diffusive and enhanced on highly aligned fibers, whereas it was hindered and sub-diffusive on un-patterned substrates. This was further supported by the more elongated morphology observed in collectively migrating cells on aligned collagen fibers. Overall, this approach allows the decoupling of single and collective cell behavior as a function of collagen alignment and shows the relative importance of collective cell behavior as well as fiber morphology in PDAC metastasis. We suggest these scaffolds can be used for further investigations of PDAC cell biology. Pancreatic ductal adenocarcinoma (PDAC) has a high mortality rate, where aligned collagen has been associated with poor prognosis. Biomimetic models representing this architecture are needed to understand complex cellular interactions. The SHG image-based models based on stromal collagen from human biopsies afford the measurements of cell morphology, cadherin and focal adhesion expression as well as detailed motility dynamics. Using a metastatic cell line, we decoupled the roles of single cell and collective cell behavior as well as that arising from aligned collagen. Our data suggests that metastatic characteristics are enhanced by increased collagen alignment and that collective cell behavior is more relevant to metastatic processes. These scaffolds provide new insight in this disease and can be a platform for further experiments such as testing drug efficacy. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

3. Cellular Energy Cycle Mediates an Advection‐Like Forward Cell Flow to Support Collective Invasion.

Author

Zhang, Jian, Mosier, Jenna A., Wu, Yusheng, Waddle, Logan, Taufalele, Paul V., Wang, Wenjun, Sun, Heng, and Reinhart‐King, Cynthia A.

Subjects

*ADENOSINE triphosphate, *CELL division, *CELL migration, *CELL cycle, *BIOENERGETICS

Abstract

Collective cell migration is a model for nonequilibrium biological dynamics, which is important for morphogenesis, pattern formation, and cancer metastasis. The current understanding of cellular collective dynamics is based primarily on cells moving within a 2D epithelial monolayer. However, solid tumors often invade surrounding tissues in the form of a stream‐like 3D structure, and how biophysical cues are integrated at the cellular level to give rise to this collective streaming remains unclear. Here, it is shown that cell cycle‐mediated bioenergetics drive a forward advective flow of cells and energy to the front to support 3D collective invasion. The cell division cycle mediates a corresponding energy cycle such that cellular adenosine triphosphate (ATP) energy peaks just before division. A reaction–advection–diffusion (RAD) type model coupled with experimental measurements further indicates that most cells enter an active division cycle at rear positions during 3D streaming. Once the cells progress to a later stage toward division, the high intracellular energy allows them to preferentially stream toward the tip and become leader cells. This energy‐driven cellular flow may be a fundamental characteristic of 3D collective dynamics based on thermodynamic principles important for not only cancer invasion but also tissue morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2024

4. Optimal Control of Collective Electrotaxis in Epithelial Monolayers.

Author

Martina-Perez, Simon F., Breinyn, Isaac B., Cohen, Daniel J., and Baker, Ruth E.

Abstract

Epithelial monolayers are some of the best-studied models for collective cell migration due to their abundance in multicellular systems and their tractability. Experimentally, the collective migration of epithelial monolayers can be robustly steered e.g. using electric fields, via a process termed electrotaxis. Theoretically, however, the question of how to design an electric field to achieve a desired spatiotemporal movement pattern is underexplored. In this work, we construct and calibrate an ordinary differential equation model to predict the average velocity of the centre of mass of a cellular monolayer in response to stimulation with an electric field. We use this model, in conjunction with optimal control theory, to derive physically realistic optimal electric field designs to achieve a variety of aims, including maximising the total distance travelled by the monolayer, maximising the monolayer velocity, and keeping the monolayer velocity constant during stimulation. Together, this work is the first to present a unified framework for optimal control of collective monolayer electrotaxis and provides a blueprint to optimally steer collective migration using other external cues. [ABSTRACT FROM AUTHOR]

Published

2024

5. The highly metastatic 4T1 breast carcinoma model possesses features of a hybrid epithelial/mesenchymal phenotype

Author

Mary E. Herndon, Mitchell Ayers, Katherine N. Gibson-Corley, Michael K. Wendt, Lori L. Wallrath, Michael D. Henry, and Christopher S. Stipp

Subjects

e-cadherin, breast cancer, collective migration, epithelial-mesenchymal transition, metastasis, Medicine, Pathology, RB1-214

Published

2024

6. Cellular Energy Cycle Mediates an Advection‐Like Forward Cell Flow to Support Collective Invasion

Author

Jian Zhang, Jenna A. Mosier, Yusheng Wu, Logan Waddle, Paul V. Taufalele, Wenjun Wang, Heng Sun, and Cynthia A. Reinhart‐King

Subjects

bioenergetics, cancer metabolism, cell cycle, collective migration, go or grow, thermodynamics, Science

Abstract

Abstract Collective cell migration is a model for nonequilibrium biological dynamics, which is important for morphogenesis, pattern formation, and cancer metastasis. The current understanding of cellular collective dynamics is based primarily on cells moving within a 2D epithelial monolayer. However, solid tumors often invade surrounding tissues in the form of a stream‐like 3D structure, and how biophysical cues are integrated at the cellular level to give rise to this collective streaming remains unclear. Here, it is shown that cell cycle‐mediated bioenergetics drive a forward advective flow of cells and energy to the front to support 3D collective invasion. The cell division cycle mediates a corresponding energy cycle such that cellular adenosine triphosphate (ATP) energy peaks just before division. A reaction–advection–diffusion (RAD) type model coupled with experimental measurements further indicates that most cells enter an active division cycle at rear positions during 3D streaming. Once the cells progress to a later stage toward division, the high intracellular energy allows them to preferentially stream toward the tip and become leader cells. This energy‐driven cellular flow may be a fundamental characteristic of 3D collective dynamics based on thermodynamic principles important for not only cancer invasion but also tissue morphogenesis.

Published

2024

7. A biased random walk approach for modeling the collective chemotaxis of neural crest cells.

Author

Freingruber, Viktoria, Painter, Kevin J., Ptashnyk, Mariya, and Schumacher, Linus J.

Abstract

Collective cell migration is a multicellular phenomenon that arises in various biological contexts, including cancer and embryo development. ‘Collectiveness’ can be promoted by cell-cell interactions such as co-attraction and contact inhibition of locomotion. These mechanisms act on cell polarity, pivotal for directed cell motility, through influencing the intracellular dynamics of small GTPases such as Rac1. To model these dynamics we introduce a biased random walk model, where the bias depends on the internal state of Rac1, and the Rac1 state is influenced by cell-cell interactions and chemoattractive cues. In an extensive simulation study we demonstrate and explain the scope and applicability of the introduced model in various scenarios. The use of a biased random walk model allows for the derivation of a corresponding partial differential equation for the cell density while still maintaining a certain level of intracellular detail from the individual based setting. [ABSTRACT FROM AUTHOR]

Published

2024

8. A toolbox to analyze collective cell migration, proliferation and cellular organization simultaneously

Author

Urszula Hohmann, Chalid Ghadban, Julian Prell, Christian Strauss, Faramarz Dehghani, and Tim Hohmann

Subjects

Cell migration, collective migration, image analysis, orientation, proliferation, Cytology, QH573-671

Abstract

ABSTRACTBackground Analyses of collective cell migration and orientation phenomena are needed to assess the behavior of multicellular clusters. While some tools to the authors’ knowledge none is capable to analyze collective migration, cellular orientation and proliferation in phase contrast images simultaneously.Methods We provide a tool based to analyze phase contrast images of dense cell layers. PIV is used to calculatevelocity fields, while the structure tensor provides cellular orientation. An artificial neural network is used to identify cell division events, allowing to correlate migratory and organizational phenomena with cell density.Conclusion The presented tool allows the simultaneous analysis of collective cell behavior from phase contrast images in terms of migration, (self-)organization and proliferation.

Published

2023

9. LGL1 binds to Integrin β1 and inhibits downstream signaling to promote epithelial branching in the mammary gland

Author

Ma, Rongze, Gong, Difei, You, Huanyang, Xu, Chongshen, Lu, Yunzhe, Bergers, Gabriele, Werb, Zena, Klein, Ophir D, Petritsch, Claudia K, and Lu, Pengfei

Subjects

Biochemistry and Cell Biology, Biological Sciences, Breast Cancer, Cancer, Animals, Cell Movement, Cell Polarity, Cell Proliferation, Down-Regulation, Epithelial Cells, Epithelium, Female, Gene Expression Regulation, Neoplastic, Glycoproteins, Integrin beta1, Mammary Glands, Animal, Mice, Transgenic, Models, Biological, Morphogenesis, Protein Binding, Signal Transduction, branching morphogenesis, collective migration, epithelial migration, epithelial polarity, extracellular matrix, integrin signaling, tumor-suppressor genes, Medical Physiology, Biological sciences

Abstract

Branching morphogenesis is a fundamental process by which organs in invertebrates and vertebrates form branches to expand their surface areas. The current dogma holds that directional cell migration determines where a new branch forms and thus patterns branching. Here, we asked whether mouse Lgl1, a homolog of the Drosophila tumor suppressor Lgl, regulates epithelial polarity in the mammary gland. Surprisingly, mammary glands lacking Lgl1 have normal epithelial polarity, but they form fewer branches. Moreover, we find that Lgl1 null epithelium is unable to directionally migrate, suggesting that migration is not essential for mammary epithelial branching as expected. We show that LGL1 binds to Integrin β1 and inhibits its downstream signaling, and Integrin β1 overexpression blocks epithelial migration, thus recapitulating the Lgl1 null phenotype. Altogether, we demonstrate that Lgl1 modulation of Integrin β1 signaling is essential for directional migration and that epithelial branching in invertebrates and the mammary gland is fundamentally distinct.

Published

2022

10. Collective directional migration drives the formation of heteroclonal cancer cell clusters

Author

Miriam Palmiero, Isabel Cantarosso, Laura diBlasio, Valentina Monica, Barbara Peracino, Luca Primo, and Alberto Puliafito

Subjects

3D models, collective migration, directional migration, heterogeneity, imaging, protrusions, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Metastasisation occurs through the acquisition of invasive and survival capabilities that allow tumour cells to colonise distant sites. While the role of multicellular aggregates in cancer dissemination is acknowledged, the mechanisms that drive the formation of multiclonal cell aggregates are not fully elucidated. Here, we show that cancer cells of different tissue of origins can perform collective directional migration and can actively form heteroclonal aggregates in 3D, through a proliferation‐independent mechanism. Coalescence of distant cell clusters is mediated by subcellular actin‐rich protrusions and multicellular outgrowths that extend towards neighbouring aggregates. Coherently, perturbation of cytoskeletal dynamics impairs collective migration while myosin II activation is necessary for multicellular movements. We put forward the hypothesis that cluster attraction is mediated by secreted soluble factors. Such a hypothesis is consistent with the abrogation of aggregation by inhibition of PI3K/AKT/mTOR and MEK/ERK, the chemoattracting activity of conditioned culture media and with a wide screening of secreted proteins. Our results present a novel collective migration model and shed light on the mechanisms of formation of heteroclonal aggregates in cancer.

Published

2023

11. Phenotypically sorted highly and weakly migratory triple negative breast cancer cells exhibit migratory and metastatic commensalism

Author

Lauren A. Hapach, Wenjun Wang, Samantha C. Schwager, Devika Pokhriyal, Emily D. Fabiano, and Cynthia A. Reinhart-King

Subjects

Collective migration, Single cell migration, Leader–follower, Spheroid, Metastasis, Intratumor heterogeneity, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Intratumor heterogeneity is a well-established hallmark of cancer that impedes cancer research, diagnosis, and treatment. Previously, we phenotypically sorted human breast cancer cells based on migratory potential. When injected into mice, highly migratory cells were weakly metastatic and weakly migratory cells were highly metastatic. The purpose of this study was to determine whether these weakly and highly migratory cells interact with each other in vitro or in vivo. Methods To assess the relationship between heterogeneity in cancer cell migration and metastatic fitness, MDA-MB-231 and SUM159PT triple negative breast cancer cells were phenotypically sorted into highly migratory and weakly migratory subpopulations and assayed separately and in a 1:1 mixture in vitro and in vivo for metastatic behaviors. Unpaired, two-tailed Student’s t-tests, Mann–Whitney tests, ordinary, one-way ANOVAs, and Kruskal–Wallis H tests were performed as appropriate with p

Published

2023

12. Spatiotemporal dynamics of PIEZO1 localization controls keratinocyte migration during wound healing.

Author

Holt, Jesse R, Zeng, Wei-Zheng, Evans, Elizabeth L, Woo, Seung-Hyun, Ma, Shang, Abuwarda, Hamid, Loud, Meaghan, Patapoutian, Ardem, and Pathak, Medha M

Subjects

cell biology, cell migration, cellular retraction, collective migration, ion channel dynamics, mechanically activated ion channels, mechanotransduction, molecular biophysics, mouse, structural biology, Animals, Cell Movement, Female, Ion Channels, Keratinocytes, Male, Mice, Mice, Transgenic, Signal Transduction, Wound Healing, 1.1 Normal biological development and functioning, Skin, Biochemistry and Cell Biology

Abstract

Keratinocytes, the predominant cell type of the epidermis, migrate to reinstate the epithelial barrier during wound healing. Mechanical cues are known to regulate keratinocyte re-epithelialization and wound healing; however, the underlying molecular transducers and biophysical mechanisms remain elusive. Here, we show through molecular, cellular, and organismal studies that the mechanically activated ion channel PIEZO1 regulates keratinocyte migration and wound healing. Epidermal-specific Piezo1 knockout mice exhibited faster wound closure while gain-of-function mice displayed slower wound closure compared to littermate controls. By imaging the spatiotemporal localization dynamics of endogenous PIEZO1 channels, we find that channel enrichment at some regions of the wound edge induces a localized cellular retraction that slows keratinocyte collective migration. In migrating single keratinocytes, PIEZO1 is enriched at the rear of the cell, where maximal retraction occurs, and we find that chemical activation of PIEZO1 enhances retraction during single as well as collective migration. Our findings uncover novel molecular mechanisms underlying single and collective keratinocyte migration that may suggest a potential pharmacological target for wound treatment. More broadly, we show that nanoscale spatiotemporal dynamics of Piezo1 channels can control tissue-scale events, a finding with implications beyond wound healing to processes as diverse as development, homeostasis, disease, and repair.

Published

2021

13. The myocardium utilizes a platelet-derived growth factor receptor alpha (Pdgfra)–phosphoinositide 3-kinase (PI3K) signaling cascade to steer toward the midline during zebrafish heart tube formation

Author

Rabina Shrestha, Tess McCann, Harini Saravanan, Jaret Lieberth, Prashanna Koirala, and Joshua Bloomekatz

Subjects

heart development, collective migration, signaling, Medicine, Science, Biology (General), QH301-705.5

Abstract

Coordinated cell movement is a fundamental process in organ formation. During heart development, bilateral myocardial precursors collectively move toward the midline (cardiac fusion) to form the primitive heart tube. Extrinsic influences such as the adjacent anterior endoderm are known to be required for cardiac fusion. We previously showed however, that the platelet-derived growth factor receptor alpha (Pdgfra) is also required for cardiac fusion (Bloomekatz et al., 2017). Nevertheless, an intrinsic mechanism that regulates myocardial movement has not been elucidated. Here, we show that the phosphoinositide 3-kinase (PI3K) intracellular signaling pathway has an essential intrinsic role in the myocardium directing movement toward the midline. In vivo imaging further reveals midline-oriented dynamic myocardial membrane protrusions that become unpolarized in PI3K-inhibited zebrafish embryos where myocardial movements are misdirected and slower. Moreover, we find that PI3K activity is dependent on and interacts with Pdgfra to regulate myocardial movement. Together our findings reveal an intrinsic myocardial steering mechanism that responds to extrinsic cues during the initiation of cardiac development.

Published

2023

14. Collective directional migration drives the formation of heteroclonal cancer cell clusters.

Author

Palmiero, Miriam, Cantarosso, Isabel, di Blasio, Laura, Monica, Valentina, Peracino, Barbara, Primo, Luca, and Puliafito, Alberto

Abstract

Metastasisation occurs through the acquisition of invasive and survival capabilities that allow tumour cells to colonise distant sites. While the role of multicellular aggregates in cancer dissemination is acknowledged, the mechanisms that drive the formation of multiclonal cell aggregates are not fully elucidated. Here, we show that cancer cells of different tissue of origins can perform collective directional migration and can actively form heteroclonal aggregates in 3D, through a proliferation‐independent mechanism. Coalescence of distant cell clusters is mediated by subcellular actin‐rich protrusions and multicellular outgrowths that extend towards neighbouring aggregates. Coherently, perturbation of cytoskeletal dynamics impairs collective migration while myosin II activation is necessary for multicellular movements. We put forward the hypothesis that cluster attraction is mediated by secreted soluble factors. Such a hypothesis is consistent with the abrogation of aggregation by inhibition of PI3K/AKT/mTOR and MEK/ERK, the chemoattracting activity of conditioned culture media and with a wide screening of secreted proteins. Our results present a novel collective migration model and shed light on the mechanisms of formation of heteroclonal aggregates in cancer. [ABSTRACT FROM AUTHOR]

Published

2023

15. Phenotypically sorted highly and weakly migratory triple negative breast cancer cells exhibit migratory and metastatic commensalism.

Author

Hapach, Lauren A., Wang, Wenjun, Schwager, Samantha C., Pokhriyal, Devika, Fabiano, Emily D., and Reinhart-King, Cynthia A.

Subjects

TRIPLE-negative breast cancer, CANCER cell migration, CANCER cells, COMMENSALISM, METASTASIS

Abstract

Background: Intratumor heterogeneity is a well-established hallmark of cancer that impedes cancer research, diagnosis, and treatment. Previously, we phenotypically sorted human breast cancer cells based on migratory potential. When injected into mice, highly migratory cells were weakly metastatic and weakly migratory cells were highly metastatic. The purpose of this study was to determine whether these weakly and highly migratory cells interact with each other in vitro or in vivo. Methods: To assess the relationship between heterogeneity in cancer cell migration and metastatic fitness, MDA-MB-231 and SUM159PT triple negative breast cancer cells were phenotypically sorted into highly migratory and weakly migratory subpopulations and assayed separately and in a 1:1 mixture in vitro and in vivo for metastatic behaviors. Unpaired, two-tailed Student's t-tests, Mann–Whitney tests, ordinary, one-way ANOVAs, and Kruskal–Wallis H tests were performed as appropriate with p < 0.05 as the cutoff for statistical significance. Results: When highly and weakly migratory cells are co-seeded in mixed spheroids, the weakly migratory cells migrated farther than weakly migratory only spheroids. In mixed spheroids, leader–follower behavior occurred with highly migratory cells leading the weakly migratory cells in migration strands. When cell suspensions of highly migratory, weakly migratory, or a 1:1 mixture of both subpopulations were injected orthotopically into mice, both the mixed cell suspensions and weakly migratory cells showed significant distal metastasis, but the highly migratory cells did not metastasize significantly to any location. Notably, significantly more distal metastasis was observed in mice injected with the 1:1 mixture compared to either subpopulation alone. Conclusions: This study suggests that weakly migratory cells interact with highly migratory cells in a commensal fashion resulting in increased migration and metastasis. Together, these findings indicate that cancer cell subpopulation migration ability does not correlate with metastatic potential and that cooperation between highly migratory and weakly migratory subpopulations can enhance overall metastatic fitness. [ABSTRACT FROM AUTHOR]

Published

2023

16. Swarm Behavior of Adult-Born Neurons During Migration in a Non-Permissive Environment.

Author

Kaneko, Naoko and Ishimaru, Taisei

Subjects

*SWARM intelligence, *NEUROGLIA, *NEURONS, *CELL migration, *CELL adhesion, *ISCHEMIC stroke

Abstract

Much attention has been provided to autonomous decentralized systems based on swarm intelligence algorithms in robotics because of their resistance to component failure and ability to adapt to new environments. During development, various types of collectively migrating cells contribute to tissue and organ formation and have provided useful models for studying swarm behaviors. In the adult brain under physiological conditions, collective cell migration is almost exclusively observed in the rostral migratory stream, where adult-born new neurons travel long distances in contiguous chain-like formation. After ischemic stroke, some new neurons migrate toward the lesion site. Studies show that the promotion of migration is critical for efficient neuronal rewiring in the post-stroke brain in rodents. The new neurons traverse to injured tissues that are not conducive to migration by forming small chains, clearing a path through glial cells, and interacting with blood vessels. Although processes involved in migratory behavior, including cytoskeletal dynamics, intercellular adhesion, and chain formation, have been separately investigated, the mechanisms underlying neuronal swarm behavior are unclear. Future studies should help further our understanding of swarm intelligence and advance the development of novel strategies for controlling neuronal migration to promote efficient functional repair and rewiring in various pathological conditions. [ABSTRACT FROM AUTHOR]

Published

2023

17. Migration and division in cell monolayers on substrates with topological defects.

Author

Kaiyrbekov, Kurmanbek, Endresen, Kirsten, Sullivan, Kyle, Zhaofei Zheng, Yun Chen, Serra, Francesca, and Camley, Brian A.

Subjects

*CELL migration, *CELL division, *MONOMOLECULAR films, *LIQUID crystals, *LABOR mobility, *WOUND healing

Abstract

Collective movement and organization of cell monolayers are important for wound healing and tissue development. Recent experiments highlighted the importance of liquid crystal order within these layers, suggesting that +1 topological defects have a role in organizing tissue morphogenesis. We study fibroblast organization, motion, and proliferation on a substrate with micron-sized ridges that induce +1 and -1 topological defects using simulation and experiment. We model cells as self-propelled deformable ellipses that interact via a Gay-Berne potential. Unlike earlier work on other cell types, we see that density variation near defects is not explained by collective migration. We propose instead that fibroblasts have different division rates depending on their area and aspect ratio. This model captures key features of our previous experiments: the alignment quality worsens at high cell density and, at the center of the +1 defects, cells can adopt either highly anisotropic or primarily isotropic morphologies. Experiments performed with different ridge heights confirm a prediction of this model: Suppressing migration across ridges promotes higher cell density at the +1 defect. Our work enables a mechanism for tissue patterning using topological defects without relying on cell migration. [ABSTRACT FROM AUTHOR]

Published

2023

18. Artificial patterns in spatially discrete models of cell migration and how to mitigate them.

Author

Manik Nava-Sedeño, Josué, Syga, Simon, and Deutsch, Andreas

Subjects

*CELL migration, *HEAT equation, *CELL communication, *BIOLOGICAL models, *VELOCITY

Abstract

Several discrete models for diffusive motion are known to exhibit checkerboard artifacts, absent in their continuous analogues. We study the origins of the checkerboard artifact in the discrete heat equation and show that this artifact decays exponentially in time when following either of two strategies: considering the present state of each lattice site to determine its own future state (self-contributions), or using non-square lattice geometries. Afterwards, we examine the effects of these strategies on nonlinear models of biological cell migration with two kinds of cell-cell interactions: adhesive and polar velocity alignment. In the case of adhesive interaction, we show that growing modes related to pattern formation overshadow artifacts in the long run; nonetheless, artifacts can still be completely prevented following the same strategies as in the discrete heat equation. On the other hand, for polar velocity alignment we show that artifacts are not only strengthened, but also that new artifacts can arise in this model which were not observed in the previous models. We find that the lattice geometry strategy works well to alleviate artifacts. However, the self-contribution strategy must be applied more carefully: lattice sites should contribute to both their own density and velocity values, and their own velocity contribution should be high enough. With this work, we show that these two strategies are effective for preventing artifacts in spatial models based on the discrete continuity equation. [ABSTRACT FROM AUTHOR]

Published

2023

19. Asymmetric Stratification-Induced Polarity Loss and Coordinated Individual Cell Movements Drive Directional Migration of Vertebrate Epithelium

Author

Lu, Yunzhe, Deng, Ruolan, You, Huanyang, Xu, Yishu, Antos, Christopher, Sun, Jianlong, Klein, Ophir D, and Lu, Pengfei

Subjects

Biochemistry and Cell Biology, Biological Sciences, 1.1 Normal biological development and functioning, Animals, Cell Movement, Cell Polarity, Cell Proliferation, Cell Surface Extensions, Dogs, Epithelial Cells, Epithelium, Female, Fibroblast Growth Factor 10, Green Fluorescent Proteins, Madin Darby Canine Kidney Cells, Mammary Glands, Animal, Mice, Organoids, Signal Transduction, Vertebrates, FGF gradient, apicobasal polarity, branching morphogenesis, cell polarity, chemotaxis, collective migration, epithelial polarity, epithelial stratification, epithelial-mesenchymal transition, front-rear polarity, Medical Physiology, Biological sciences

Abstract

Collective migration is essential for development, wound repair, and cancer metastasis. For most collective systems, "leader cells" determine both the direction and the power of the migration. It has remained unclear, however, how the highly polarized vertebrate epithelium migrates directionally during branching morphogenesis. We show here that, unlike in other systems, front-rear polarity of the mammary epithelium is set up by preferential cell proliferation in the front in response to the FGF10 gradient. This leads to frontal stratification, loss of apicobasal polarity, and leader cell formation. Leader cells are a dynamic population and move faster and more directionally toward the FGF10 signal than do follower cells, partly because of their intraepithelial protrusions toward the signal. Together, our data show that directional migration of the mammary epithelium is a unique multistep process and that, despite sharing remarkable cellular and molecular similarities, vertebrate and invertebrate epithelial branching are fundamentally distinct processes.

Published

2020

20. Purse-string contraction guides mechanical gradient-dictated heterogeneous migration of epithelial monolayer.

Author

Zhang, Haihui, Xu, Hongwei, Sun, Weihao, Fang, Xu, Qin, Peiwu, Huang, Jianyong, Fang, Jing, Lin, Feng, and Xiong, Chunyang

Subjects

CELL migration, EPITHELIUM, CELL communication, MONOMOLECULAR films, COLLECTIVE behavior, F-actin

Abstract

Mechanical heterogeneity has been recognized as an important role in mediating collective cell migration, yet the related mechanism has not been elucidated. Herein, we fabricate heterogeneous stiffness gradients by leveraging microelastically-patterned hydrogels with varying periodic distance. We observe that a decrease in the periodic distance of the mechanical heterogeneity is accompanied by an overall increase in the velocity and directionality of the migrating monolayer. Moreover, inhibition of ROCK- and myosin ⅡA- but not Rac1-mediated contraction reduces monolayer migration on the mechanically heterogeneous substrates. Furthermore, we find that F-actin and myosin ⅡA form purse-string at the leading edge on the mechanically heterogeneous substrates. Together, these findings not only show that the orientational cell–cell contraction promotes collective cell migration under the mechanical heterogeneity, but also demonstrate that the mechanosensation arising from large-scale cell–cell interactions through purse-string formation mediated cell–cell orientational contraction can feed back to regulate the reorganization of epithelial tissues. By detecting the links between heterogenous rigidity and collective cell migration behavior at the molecular level, we reveal that collective cell migration in the mechanical heterogeneity is driven by ROCK- and myosin-ⅡA-dependent cytoskeletal tension. We confirm that cytoskeletal tension across the epithelial tissue is holistically linked through F-actin and myosin-ⅡA, which cooperate to form purse-string structures for modulating collective tissue behavior on the exogenous matrix with mechanical heterogeneity. Mechanical heterogeneity initiates tissue growth, remodelling, and morphogenesis by orientating cell contractility. Therefore, tensional homeostasis across large-scale cell interactions appears to be necessary and sufficient to trigger collective tissue behavior. Overall, these findings shed light on the role of mechanical heterogeneity in tissue microenvironment for reorganization and morphogenesis. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

21. In colon cancer cells fascin1 regulates adherens junction remodeling.

Author

Esmaeilniakooshkghazi, Amin, Pham, Eric, George, Sudeep P., Ahrorov, Afzal, Villagomez, Fabian R., Byington, Michael, Mukhopadhyay, Srijita, Patnaik, Srinivas, Conrad, Jacinta C., Naik, Monali, Ravi, Saathvika, Tebbutt, Niall, Mooi, Jennifer, Reehorst, Camilla M., Mariadason, John M., and Khurana, Seema

Abstract

Adherens junctions (AJs) are a defining feature of all epithelial cells. They regulate epithelial tissue architecture and integrity, and their dysregulation is a key step in tumor metastasis. AJ remodeling is crucial for cancer progression, and it plays a key role in tumor cell survival, growth, and dissemination. Few studies have examined AJ remodeling in cancer cells consequently, it remains poorly understood and unleveraged in the treatment of metastatic carcinomas. Fascin1 is an actin‐bundling protein that is absent from the normal epithelium but its expression in colon cancer is linked to metastasis and increased mortality. Here, we provide the molecular mechanism of AJ remodeling in colon cancer cells and identify for the first time, fascin1's function in AJ remodeling. We show that in colon cancer cells fascin1 remodels junctional actin and actomyosin contractility which makes AJs less stable but more dynamic. By remodeling AJs fascin1 drives mechanoactivation of WNT/β‐catenin signaling and generates "collective plasticity" which influences the behavior of cells during cell migration. The impact of mechanical inputs on WNT/β‐catenin activation in cancer cells remains poorly understood. Our findings highlight the role of AJ remodeling and mechanosensitive WNT/β‐catenin signaling in the growth and dissemination of colorectal carcinomas. [ABSTRACT FROM AUTHOR]

Published

2023

22. Jamming Transitions in Astrocytes and Glioblastoma Are Induced by Cell Density and Tension.

Author

Hohmann, Urszula, von Widdern, Julian Cardinal, Ghadban, Chalid, Giudice, Maria Cristina Lo, Lemahieu, Grégoire, Cavalcanti-Adam, Elisabetta Ada, Dehghani, Faramarz, and Hohmann, Tim

Subjects

*GLIOBLASTOMA multiforme, *ATOMIC force microscopy, *CELL communication, *CELL imaging, *COLLECTIVE behavior

Abstract

Collective behavior of cells emerges from coordination of cell–cell-interactions and is important to wound healing, embryonic and tumor development. Depending on cell density and cell–cell interactions, a transition from a migratory, fluid-like unjammed state to a more static and solid-like jammed state or vice versa can occur. Here, we analyze collective migration dynamics of astrocytes and glioblastoma cells using live cell imaging. Furthermore, atomic force microscopy, traction force microscopy and spheroid generation assays were used to study cell adhesion, traction and mechanics. Perturbations of traction and adhesion were induced via ROCK or myosin II inhibition. Whereas astrocytes resided within a non-migratory, jammed state, glioblastoma were migratory and unjammed. Furthermore, we demonstrated that a switch from an unjammed to a jammed state was induced upon alteration of the equilibrium between cell–cell-adhesion and tension from adhesion to tension dominated, via inhibition of ROCK or myosin II. Such behavior has implications for understanding the infiltration of the brain by glioblastoma cells and may help to identify new strategies to develop anti-migratory drugs and strategies for glioblastoma-treatment. [ABSTRACT FROM AUTHOR]

Published

2023

23. Energetic scaling behavior of patterned epithelium.

Author

Peters, Frank D., Rahman, Tasnif, Zhang, Haokang, and Wan, Leo Q.

Subjects

*MONOMOLECULAR films, *RANGE of motion of joints, *EPITHELIUM, *MORPHOLOGY, *CHIRALITY

Abstract

Cellular monolayers display various degrees of coordinated motion ranging from the small scale of just a few cells to large multi-cellular scales. This collective migration carries important physical cues for creating proper tissue morphology. Previous studies have demonstrated that the energetics of the epithelial monolayer show a linear variation with time in conjunction with an arrest in monolayer motion after confluency. However, little is known about how the energetics of monolayer development are affected by confined geometries. Here, we demonstrate that micropatterned epithelial monolayers display a non-linear change in energetic variables, which coincides with the large-scale coordination of migration. This non-linear scaling behavior was further seen to be associated with the biased alignment of cells and cell–cell adhesion. These findings provide a new understanding of how developing epithelia may be impacted by different conditions in vivo. [ABSTRACT FROM AUTHOR]

Published

2024

24. Controlling periodic long-range signalling to drive a morphogenetic transition

Author

Hugh Z Ford, Angelika Manhart, and Jonathan R Chubb

Subjects

signal relay, frequency coding, collective migration, morphogenesis, spiral wave, excitable media, Medicine, Science, Biology (General), QH301-705.5

Abstract

Cells use signal relay to transmit information across tissue scales. However, the production of information carried by signal relay remains poorly characterised. To determine how the coding features of signal relay are generated, we used the classic system for long-range signalling: the periodic cAMP waves that drive Dictyostelium collective migration. Combining imaging and optogenetic perturbation of cell signalling states, we find that migration is triggered by an increase in wave frequency generated at the signalling centre. Wave frequency is regulated by cAMP wave circulation, which organises the long-range signal. To determine the mechanisms modulating wave circulation, we combined mathematical modelling, the general theory of excitable media, and mechanical perturbations to test competing models. Models in which cell density and spatial patterning modulate the wave frequency cannot explain the temporal evolution of signalling waves. Instead, our evidence leads to a model where wave circulation increases the ability for cells to relay the signal, causing further increase in the circulation rate. This positive feedback between cell state and signalling pattern regulates the long-range signal coding that drives morphogenesis.

Published

2023

25. SCAND1 Reverses Epithelial-to-Mesenchymal Transition (EMT) and Suppresses Prostate Cancer Growth and Migration.

Author

Eguchi, Takanori, Csizmadia, Eva, Kawai, Hotaka, Sheta, Mona, Yoshida, Kunihiro, Prince, Thomas L., Wegiel, Barbara, and Calderwood, Stuart K.

Subjects

*ZINC-finger proteins, *EPITHELIAL-mesenchymal transition, *PROSTATE cancer, *TUMOR growth, *GENE expression, *PANCREATIC cancer, *CELL migration, *CANCER cell migration

Abstract

Epithelial–mesenchymal transition (EMT) is a reversible cellular program that transiently places epithelial (E) cells into pseudo-mesenchymal (M) cell states. The malignant progression and resistance of many carcinomas depend on EMT activation, partial EMT, or hybrid E/M status in neoplastic cells. EMT is activated by tumor microenvironmental TGFβ signal and EMT-inducing transcription factors, such as ZEB1/2, in tumor cells. However, reverse EMT factors are less studied. We demonstrate that prostate epithelial transcription factor SCAND1 can reverse the cancer cell mesenchymal and hybrid E/M phenotypes to a more epithelial, less invasive status and inhibit their proliferation and migration in DU-145 prostate cancer cells. SCAND1 is a SCAN domain-containing protein and hetero-oligomerizes with SCAN-zinc finger transcription factors, such as MZF1, for accessing DNA and the transcriptional co-repression of target genes. We found that SCAND1 expression correlated with maintaining epithelial features, whereas the loss of SCAND1 was associated with mesenchymal phenotypes of tumor cells. SCAND1 and MZF1 were mutually inducible and coordinately included in chromatin with hetero-chromatin protein HP1γ. The overexpression of SCAND1 reversed hybrid E/M status into an epithelial phenotype with E-cadherin and β-catenin relocation. Consistently, the co-expression analysis in TCGA PanCancer Atlas revealed that SCAND1 and MZF1 expression was negatively correlated with EMT driver genes, including CTNNB1, ZEB1, ZEB2 and TGFBRs, in prostate adenocarcinoma specimens. In addition, SCAND1 overexpression suppressed tumor cell proliferation by reducing the MAP3K-MEK-ERK signaling pathway. Of note, in a mouse tumor xenograft model, SCAND1 overexpression significantly reduced Ki-67(+) and Vimentin(+) tumor cells and inhibited migration and lymph node metastasis of prostate cancer. Kaplan–Meier analysis showed high expression of SCAND1 and MZF1 to correlate with better prognoses in pancreatic cancer and head and neck cancers, although with poorer prognosis in kidney cancer. Overall, these data suggest that SCAND1 induces expression and coordinated heterochromatin-binding of MZF1 to reverse the hybrid E/M status into an epithelial phenotype and, inhibits tumor cell proliferation, migration, and metastasis, potentially by repressing the gene expression of EMT drivers and the MAP3K-MEK-ERK signaling pathway. [ABSTRACT FROM AUTHOR]

Published

2022

26. Spatially Guided Construction of Multilayered Epidermal Models Recapturing Structural Hierarchy and Cell–Cell Junctions.

Author

Zhai, Haiwei, Jin, Xiaowei, Minnick, Grayson, Rosenbohm, Jordan, Hafiz, Mohammed Abdul Haleem, Yang, Ruiguo, and Meng, Fanben

Subjects

*BIOPRINTING, *STRUCTURAL models, *PEMPHIGUS vulgaris, *AUTOIMMUNE diseases, *WOUND healing, *FIBRIN, *IMMUNOGLOBULINS, *EPIDERMIS, KERATINOCYTE differentiation

Abstract

A current challenge in 3D bioprinting of skin equivalents is to recreate the distinct basal and suprabasal layers and promote their direct interactions. Such a structural arrangement is essential to establish 3D stratified epidermis disease models, such as for the autoimmune skin disease pemphigus vulgaris (PV), which targets the cell–cell junctions at the interface of the basal and suprabasal layers. Inspired by epithelial regeneration in wound healing, a method that combines 3D bioprinting and spatially guided self‐reorganization of keratinocytes is developed to recapture the fine structural hierarchy that lies in the deep layers of the epidermis. Herein, keratinocyte‐laden fibrin hydrogels are bioprinted to create geographical cues, guiding dynamic self‐reorganization of cells through collective migration, keratinocyte differentiation, and vertical expansion. This process results in a region of self‐organized multilayers (SOMs) that contain the basal‐to‐suprabasal transition, marked by the expressed levels of different types of keratins that indicate differentiation. Finally, the reconstructed skin tissue as an in vitro platform to study the pathogenic effects of PV is demonstrated, illuminating a significant difference in cell–cell junction dissociation induced by PV antibodies in different epidermis layers, which indicates their applications in the preclinical test of possible therapies. [ABSTRACT FROM AUTHOR]

Published

2022

27. PI3K Isoform-Specific Regulation of Leader and Follower Cell Function for Collective Migration and Proliferation in Response to Injury.

Author

Basta, Morgan D., Menko, A. Sue, and Walker, Janice L.

Subjects

*CELL physiology, *PHOSPHATIDYLINOSITOL 3-kinases, *WOUND healing, *CELL migration, *SURGICAL site, *CELL motility

Abstract

To ensure proper wound healing it is important to elucidate the signaling cues that coordinate leader and follower cell behavior to promote collective migration and proliferation for wound healing in response to injury. Using an ex vivo post-cataract surgery wound healing model we investigated the role of class I phosphatidylinositol-3-kinase (PI3K) isoforms in this process. Our findings revealed a specific role for p110α signaling independent of Akt for promoting the collective migration and proliferation of the epithelium for wound closure. In addition, we found an important role for p110α signaling in orchestrating proper polarized cytoskeletal organization within both leader and wounded epithelial follower cells to coordinate their function for wound healing. p110α was necessary to signal the formation and persistence of vimentin rich-lamellipodia extensions by leader cells and the reorganization of actomyosin into stress fibers along the basal domains of the wounded lens epithelial follower cells for movement. Together, our study reveals a critical role for p110α in the collective migration of an epithelium in response to wounding. [ABSTRACT FROM AUTHOR]

Published

2022

28. Quantitative Analysis of Collective Migration by Single-Cell Tracking Aimed at Understanding Cancer Metastasis.

Author

Xin, Zhuohan, Deguchi, Keiko, Suye, Shin-ichiro, and Fujita, Satoshi

Subjects

*METASTASIS, *CANCER cell migration, *CELL migration, *EPITHELIAL-mesenchymal transition, *CELL populations, *QUANTITATIVE research

Abstract

Metastasis is a major complication of cancer treatments. Studies of the migratory behavior of cells are needed to investigate and control metastasis. Metastasis is based on the epithelial–mesenchymal transition, in which epithelial cells acquire mesenchymal properties and the ability to leave the population to invade other regions of the body. In collective migration, highly migratory "leader" cells are found at the front of the cell population, as well as cells that "follow" these leader cells. However, the interactions between these cells are not well understood. We examined the migration properties of leader–follower cells during collective migration at the single-cell level. Different mixed ratios of "leader" and "follower" cell populations were compared. Collective migration was quantitatively analyzed from two perspectives: cell migration within the colony and migration of the entire colony. Analysis of the effect of the cell mixing ratio on migration behavior showed that a small number of highly migratory cells enhanced some of the migratory properties of other cells. The results provide useful insights into the cellular interactions in collective cell migration of cancer cell invasion. [ABSTRACT FROM AUTHOR]

Published

2022

29. Spatially Guided Construction of Multilayered Epidermal Models Recapturing Structural Hierarchy and Cell–Cell Junctions

Author

Haiwei Zhai, Xiaowei Jin, Grayson Minnick, Jordan Rosenbohm, Mohammed Abdul Haleem Hafiz, Ruiguo Yang, and Fanben Meng

Subjects

3D bioprinting, cell junctions, cell self-organization, collective migration, in vitro skin models, keratinocyte differentiation, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

A current challenge in 3D bioprinting of skin equivalents is to recreate the distinct basal and suprabasal layers and promote their direct interactions. Such a structural arrangement is essential to establish 3D stratified epidermis disease models, such as for the autoimmune skin disease pemphigus vulgaris (PV), which targets the cell–cell junctions at the interface of the basal and suprabasal layers. Inspired by epithelial regeneration in wound healing, a method that combines 3D bioprinting and spatially guided self‐reorganization of keratinocytes is developed to recapture the fine structural hierarchy that lies in the deep layers of the epidermis. Herein, keratinocyte‐laden fibrin hydrogels are bioprinted to create geographical cues, guiding dynamic self‐reorganization of cells through collective migration, keratinocyte differentiation, and vertical expansion. This process results in a region of self‐organized multilayers (SOMs) that contain the basal‐to‐suprabasal transition, marked by the expressed levels of different types of keratins that indicate differentiation. Finally, the reconstructed skin tissue as an in vitro platform to study the pathogenic effects of PV is demonstrated, illuminating a significant difference in cell–cell junction dissociation induced by PV antibodies in different epidermis layers, which indicates their applications in the preclinical test of possible therapies.

Published

2022

30. Cell-cell interactions and fluctuations in the direction of motility promote directed migration of osteoblasts in direct current electrotaxis

Author

Jonathan Edward Dawson, Tina Sellmann, Katrin Porath, Rainer Bader, Ursula van Rienen, Revathi Appali, and Rüdiger Köhling

Subjects

cell migration, electrotaxis, osteoblasts, computational modeling, collective migration, particle based approach, Biotechnology, TP248.13-248.65

Abstract

Under both physiological (development, regeneration) and pathological conditions (cancer metastasis), cells migrate while sensing environmental cues in the form of mechanical, chemical or electrical stimuli. In the case of bone tissue, osteoblast migration is essential in bone regeneration. Although it is known that osteoblasts respond to exogenous electric fields, the underlying mechanism of electrotactic collective movement of human osteoblasts is unclear. Here, we present a computational model that describes the osteoblast cell migration in a direct current electric field as the motion of a collection of active self-propelled particles and takes into account fluctuations in the direction of single-cell migration, finite-range cell-cell interactions, and the interaction of a cell with the external electric field. By comparing this model with in vitro experiments in which human primary osteoblasts are exposed to a direct current electric field of different field strengths, we show that cell-cell interactions and fluctuations in the migration direction promote anode-directed collective migration of osteoblasts.

Published

2022

31. Compressive stress drives adhesion-dependent unjamming transitions in breast cancer cell migration

Author

Grace Cai, Anh Nguyen, Yashar Bashirzadeh, Shan-Shan Lin, Dapeng Bi, and Allen P. Liu

Subjects

collective migration, unjamming transition, cell shape, cell–cell adhesion, traction force microscopy, Biology (General), QH301-705.5

Abstract

Cellular unjamming is the collective fluidization of cell motion and has been linked to many biological processes, including development, wound repair, and tumor growth. In tumor growth, the uncontrolled proliferation of cancer cells in a confined space generates mechanical compressive stress. However, because multiple cellular and molecular mechanisms may be operating simultaneously, the role of compressive stress in unjamming transitions during cancer progression remains unknown. Here, we investigate which mechanism dominates in a dense, mechanically stressed monolayer. We find that long-term mechanical compression triggers cell arrest in benign epithelial cells and enhances cancer cell migration in transitions correlated with cell shape, leading us to examine the contributions of cell–cell adhesion and substrate traction in unjamming transitions. We show that cadherin-mediated cell–cell adhesion regulates differential cellular responses to compressive stress and is an important driver of unjamming in stressed monolayers. Importantly, compressive stress does not induce the epithelial–mesenchymal transition in unjammed cells. Furthermore, traction force microscopy reveals the attenuation of traction stresses in compressed cells within the bulk monolayer regardless of cell type and motility. As traction within the bulk monolayer decreases with compressive pressure, cancer cells at the leading edge of the cell layer exhibit sustained traction under compression. Together, strengthened intercellular adhesion and attenuation of traction forces within the bulk cell sheet under compression lead to fluidization of the cell layer and may impact collective cell motion in tumor development and breast cancer progression.

Published

2022

32. P4HA2: A link between tumor-intrinsic hypoxia, partial EMT and collective migration

Author

Vaishali Aggarwal, Sarthak Sahoo, Vera S. Donnenberg, Priyanka Chakraborty, Mohit Kumar Jolly, and Shilpa Sant

Subjects

P4HA2, Tumor-intrinsic hypoxia, Partial EMT, Collective migration, 3D microtumor models, Tumor microenvironment, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Epithelial-to-mesenchymal transition (EMT), a well-established phenomenon studied across pan-cancer types, has long been known to be a major player in driving tumor invasion and metastasis. Recent studies have highlighted the importance of partial EMT phenotypes in metastasis. Initially thought as a transitional state between epithelial and mesenchymal phenotypic states, partial EMT state is now widely recognized as a key driver of intra-tumoral heterogeneity and phenotypic plasticity, further accelerating tumor metastasis and therapeutic resistance. However, how tumor microenvironment regulates partial EMT phenotypes remains unclear. We have developed unique size-controlled three-dimensional microtumor models that recapitulate tumor-intrinsic hypoxia and the emergence of collectively migrating cells. In this study, we further interrogate these microtumor models to understand how tumor-intrinsic hypoxia regulates partial EMT and collective migration in hypoxic large microtumors fabricated from T47D breast cancer cells. We compared global gene expression profiles of hypoxic, migratory microtumors to that of non-hypoxic, non-migratory microtumors at early and late time-points. Using our microtumor models, we identified unique gene signatures for tumor-intrinsic hypoxia (early versus late), partial EMT and migration (pre-migratory versus migratory phenotype). Through differential gene expression analysis between the microtumor models with an overlap of hypoxia, partial EMT and migration signatures, we identified prolyl 4-hydroxylase subunit 2 (P4HA2), a hypoxia responsive gene, as a central regulator common to hypoxia, partial EMT and collective migration. Further, the inhibition of P4HA2 significantly blocked collective migration in hypoxic microtumors. Thus, using the integrated computational-experimental analysis, we identify the key role of P4HA2 in tumor-intrinsic hypoxia-driven partial EMT and collective migration.

Published

2022

33. Mechanical coupling of supracellular stress amplification and tissue fluidization during exit from quiescence.

Author

Lång, Emma, Pedersen, Christian, Lång, Anna, Blicher, Pernille, Klungland, Arne, Carlson, Andreas, and Bøe, Stig Ove

Subjects

*FLUIDIZATION, *CELL cycle, *MITOGENS, *STEM cells, *MONOMOLECULAR films

Abstract

Cellular quiescence is a state of reversible cell cycle arrest that is associated with tissue dormancy. Timely regulated entry into and exit from quiescence is important for processes such as tissue homeostasis, tissue repair, stem cell maintenance, developmental processes, and immunity. However, little is known about processes that control the mechanical adaption to cell behavior changes during the transition from quiescence to proliferation. Here, we show that quiescent human keratinocyte monolayers sustain an actinomyosin-based system that facilitates global cell sheet displacements upon serumstimulated exit from quiescence. Mechanistically, exposure of quiescent cells to serumborne mitogens leads to rapid amplification of preexisting contractile sites, leading to a burst in monolayer tension that subsequently drives large-scale displacements of otherwise motility-restricted monolayers. The stress level after quiescence exit correlates with the level of quiescence depth at the time of activation, and a critical stress magnitude must be reached to overcome the cell sheet displacement barrier. The study shows that static quiescent cell monolayers are mechanically poised for motility, and it identifies global stress amplification as a mechanism for overcoming motility restrictions in confined confluent cell monolayers. [ABSTRACT FROM AUTHOR]

Published

2022

34. Inferring single-cell behaviour from large-scale epithelial sheet migration patterns.

Author

Lee, Rachel, Yue, Haicen, Rappel, Wouter-Jan, and Losert, Wolfgang

Subjects

collective migration, epithelial cells, modelling, Cell Line, Tumor, Cell Movement, Epithelial Cells, Female, Humans, Image Processing, Computer-Assisted, Models, Biological, Rheology

Abstract

Cell migration plays an important role in a wide variety of biological processes and can incorporate both individual cell motion and collective behaviour. The emergent properties of collective migration are receiving increasing attention as collective motions role in diseases such as metastatic cancer becomes clear. Yet, how individual cell behaviour influences large-scale, multi-cell collective motion remains unclear. In this study, we provide insight into the mechanisms behind collective migration by studying cell migration in a spreading monolayer of epithelial MCF10A cells. We quantify migration using particle image velocimetry and find that cell groups have features of motion that span multiple length scales. Comparing our experimental results to a model of collective cell migration, we find that cell migration within the monolayer can be affected in qualitatively different ways by cell motion at the boundary, yet it is not necessary to introduce leader cells at the boundary or specify other large-scale features to recapitulate this large-scale phenotype in simulations. Instead, in our model, collective motion can be enhanced by increasing the overall activity of the cells or by giving the cells a stronger coupling between their motion and polarity. This suggests that investigating the activity and polarity persistence of individual cells will add insight into the collective migration phenotypes observed during development and disease.

Published

2017

35. The epithelial-mesenchymal transition and the cytoskeleton in bioengineered systems

Author

Susan E. Leggett, Alex M. Hruska, Ming Guo, and Ian Y. Wong

Subjects

Actin, Vimentin, Cytoskeleton, Collective migration, Extracellular matrix, Medicine, Cytology, QH573-671

Abstract

Abstract The epithelial-mesenchymal transition (EMT) is intrinsically linked to alterations of the intracellular cytoskeleton and the extracellular matrix. After EMT, cells acquire an elongated morphology with front/back polarity, which can be attributed to actin-driven protrusion formation as well as the gain of vimentin expression. Consequently, cells can deform and remodel the surrounding matrix in order to facilitate local invasion. In this review, we highlight recent bioengineering approaches to elucidate EMT and functional changes in the cytoskeleton. First, we review transitions between multicellular clusters and dispersed individuals on planar surfaces, which often exhibit coordinated behaviors driven by leader cells and EMT. Second, we consider the functional role of vimentin, which can be probed at subcellular length scales and within confined spaces. Third, we discuss the role of topographical patterning and EMT via a contact guidance like mechanism. Finally, we address how multicellular clusters disorganize and disseminate in 3D matrix. These new technologies enable controlled physical microenvironments and higher-resolution spatiotemporal measurements of EMT at the single cell level. In closing, we consider future directions for the field and outstanding questions regarding EMT and the cytoskeleton for human cancer progression. Video Abstract

Published

2021

36. Force and Collective Epithelial Activities

Author

Ferrari, Aldo, Giampietro, Costanza, COHEN, IRUN R., Editorial Board Member, LAJTHA, ABEL, Editorial Board Member, LAMBRIS, JOHN D., Editorial Board Member, PAOLETTI, RODOLFO, Editorial Board Member, REZAEI, NIMA, Editorial Board Member, La Porta, Caterina A. M., editor, and Zapperi, Stefano, editor

Published

2019

37. Trunk Neural Crest Migratory Position and Asymmetric Division Predict Terminal Differentiation

Author

Zain Alhashem, Karen Camargo-Sosa, Robert N. Kelsh, and Claudia Linker

Subjects

neural crest, asymmetric division, leader, collective migration, fate, sympathetic ganglia, Biology (General), QH301-705.5

Abstract

The generation of complex structures during embryogenesis requires the controlled migration and differentiation of cells from distant origins. How these processes are coordinated and impact each other to form functional structures is not fully understood. Neural crest cells migrate extensively giving rise to many cell types. In the trunk, neural crest cells migrate collectively forming chains comprised of cells with distinct migratory identities: one leader cell at the front of the group directs migration, while followers track the leader forming the body of the chain. Herein we analysed the relationship between trunk neural crest migratory identity and terminal differentiation. We found that trunk neural crest migration and fate allocation is coherent. Leader cells that initiate movement give rise to the most distal derivativities. Interestingly, the asymmetric division of leaders separates migratory identity and fate. The distal daughter cell retains the leader identity and clonally forms the Sympathetic Ganglia. The proximal sibling migrates as a follower and gives rise to Schwann cells. The sympathetic neuron transcription factor phox2bb is strongly expressed by leaders from early stages of migration, suggesting that specification and migration occur concomitantly and in coordination. Followers divide symmetrically and their fate correlates with their position in the chain.

Published

2022

38. Traffic Patterns of the Migrating Endothelium: How Force Transmission Regulates Vascular Malformation and Functional Shunting During Angiogenic Remodelling

Author

Lowell T. Edgar, Hyojin Park, Jessica R. Crawshaw, James M. Osborne, Anne Eichmann, and Miguel O. Bernabeu

Subjects

angiogenesis, angiogenic remodelling, endothelial cells, collective migration, flow-migration coupling, force transmission, Biology (General), QH301-705.5

Abstract

Angiogenesis occurs in distinct phases: initial spouting is followed by remodelling in which endothelial cells (ECs) composing blood vessels rearrange by migrating against the direction of flow. Abnormal remodelling can result in vascular malformation. Such is the case in mutation of the Alk1 receptor within the mouse retina which disrupts flow-migration coupling, creating mixed populations of ECs polarised with/against flow which aggregate into arteriovenous malformations (AVMs). The lack of live imaging options in vivo means that the collective EC dynamics that drive AVM and the consequences of mixed populations of polarity remain a mystery. Therefore, our goal is to present a novel agent-based model to provide theoretical insight into EC force transmission and collective dynamics during angiogenic remodelling. Force transmission between neighbouring agents consists of extrusive forces which maintain spacing and cohesive forces which maintain the collective. We performed migration simulations within uniformly polarised populations (against flow) and mixed polarity (with/against flow). Within uniformly polarised populations, extrusive forces stabilised the plexus by facilitating EC intercalation which ensures that cells remained evenly distributed. Excess cohesion disrupts intercalation, resulting in aggregations of cells and functional shunting. Excess cohesion between ECs prevents them from resolving diameter balances within the plexus, leading to prolonged flow reversals which exert a critical behaviour change within the system as they switch the direction of cell migration and traffic patterns at bifurcations. Introducing mixtures of cell polarity dramatically changed the role of extrusive forces within the system. At low extrusion, opposing ECs were able to move past each other; however, at high extrusion the pushing between cells resulted in migration speeds close to zero, forming traffic jams and disrupting migration. In our study, we produced vascular malformations and functional shunting with either excess cohesion between ECs or mixtures of cell polarity. At the centre of both these mechanisms are cell-cell adherens junctions, which are involved in flow sensing/polarity and must remodelling dynamically to allow rearrangements of cells during vascular patterning. Thus, our findings implicate junctional dysfunction as a new target in the treatment and prevention of vascular disease and AVMs.

Published

2022

39. RhoA/ROCK Signaling Regulates Drp1-Mediated Mitochondrial Fission During Collective Cell Migration

Author

Chen Qu, Wen Yang, Yating Kan, Hui Zuo, Mengqi Wu, Qing Zhang, Heng Wang, Dou Wang, and Jiong Chen

Subjects

collective migration, DRP1, RhoA/ROCK signaling, Drosophila border cells, mitochondrial dynamics, actomyosin dynamics, Biology (General), QH301-705.5

Abstract

Collective migration plays critical roles in developmental, physiological and pathological processes, and requires a dynamic actomyosin network for cell shape change, cell adhesion and cell-cell communication. The dynamic network of mitochondria in individual cells is regulated by mitochondrial fission and fusion, and is required for cellular processes including cell metabolism, apoptosis and cell division. But whether mitochondrial dynamics interplays with and regulates actomyosin dynamics during collective migration is not clear. Here, we demonstrate that proper regulation of mitochondrial dynamics is critical for collective migration of Drosophila border cells during oogenesis, and misregulation of fission or fusion results in reduction of ATP levels. Specifically, Drp1 is genetically required for border cell migration, and Drp1-mediated mitochondrial fission promotes formation of leading protrusion, likely through its regulation of ATP levels. Reduction of ATP levels by drug treatment also affects protrusion formation as well as actomyosin dynamics. Importantly, we find that RhoA/ROCK signaling, which is essential for actin and myosin dynamics during border cell migration, could exert its effect on mitochondrial fission through regulating Drp1’s recruitment to mitochondria. These findings suggest that RhoA/ROCK signaling may couple or coordinate actomyosin dynamics with mitochondrial dynamics to achieve optimal actomyosin function, leading to protrusive and migratory behavior.

Published

2022

40. A Drosophila RNAi screen reveals conserved glioblastoma-related adhesion genes that regulate collective cell migration.

Author

Kotian, Nirupama, Troike, Katie M., Curran, Kristen N., Lathia, Justin D., and McDonald, Jocelyn A.

Subjects

*CELL migration, *DROSOPHILA, *REGULATOR genes, *MEDICAL screening, *BRAIN tumors, *TUMOR growth

Abstract

Migrating cell collectives are key to embryonic development but also contribute to invasion and metastasis of a variety of cancers. Cell collectives can invade deep into tissues, leading to tumor progression and resistance to therapies. Collective cell invasion is also observed in the lethal brain tumor glioblastoma (GBM), which infiltrates the surrounding brain parenchyma leading to tumor growth and poor patient outcomes. Drosophila border cells, which migrate as a small cell cluster in the developing ovary, are a well-studied and genetically accessible model used to identify general mechanisms that control collective cell migration within native tissue environments. Most cell collectives remain cohesive through a variety of cell-cell adhesion proteins during their migration through tissues and organs. In this study, we first identified cell adhesion, cell matrix, cell junction, and associated regulatory genes that are expressed in human brain tumors. We performed RNAi knockdown of the Drosophila orthologs in border cells to evaluate if migration and/or cohesion of the cluster was impaired. From this screen, we identified eight adhesion-related genes that disrupted border cell collective migration upon RNAi knockdown. Bioinformatics analyses further demonstrated that subsets of the orthologous genes were elevated in the margin and invasive edge of human GBM patient tumors. These data together show that conserved cell adhesion and adhesion regulatory proteins with potential roles in tumor invasion also modulate collective cell migration. This dual screening approach for adhesion genes linked to GBM and border cell migration thus may reveal conserved mechanisms that drive collective tumor cell invasion. [ABSTRACT FROM AUTHOR]

Published

2022

41. Commentary: The Dynamics of Aerotaxis in a Simple Eukaryotic Model

Author

Jean-Paul Rieu, Olivier Cochet-Escartin, Christophe Anjard, Mete Demircigil, and Vincent Calvez

Subjects

Self-generated gradients, Aerotaxis, Collective migration, Oxygen sensing, Dictyostelium discoideum, Biology (General), QH301-705.5

Published

2022

42. Chemotactic smoothing of collective migration

Author

Tapomoy Bhattacharjee, Daniel B Amchin, Ricard Alert, Jenna Anne Ott, and Sujit Sankar Datta

Subjects

chemotaxis, collective migration, motility, Medicine, Science, Biology (General), QH301-705.5

Abstract

Collective migration—the directed, coordinated motion of many self-propelled agents—is a fascinating emergent behavior exhibited by active matter with functional implications for biological systems. However, how migration can persist when a population is confronted with perturbations is poorly understood. Here, we address this gap in knowledge through studies of bacteria that migrate via directed motion, or chemotaxis, in response to a self-generated nutrient gradient. We find that bacterial populations autonomously smooth out large-scale perturbations in their overall morphology, enabling the cells to continue to migrate together. This smoothing process arises from spatial variations in the ability of cells to sense and respond to the local nutrient gradient—revealing a population-scale consequence of the manner in which individual cells transduce external signals. Altogether, our work provides insights to predict, and potentially control, the collective migration and morphology of cellular populations and diverse other forms of active matter.

Published

2022

43. The highly metastatic 4T1 breast carcinoma model possesses features of a hybrid epithelial/mesenchymal phenotype.

Author

Herndon ME, Ayers M, Gibson-Corley KN, Wendt MK, Wallrath LL, Henry MD, and Stipp CS

Subjects

Animals, Female, Cell Line, Tumor, Mice, Neoplasm Invasiveness, Breast Neoplasms pathology, Breast Neoplasms genetics, Breast Neoplasms metabolism, Mice, Inbred BALB C, Disease Models, Animal, Intercellular Junctions metabolism, Gene Expression Regulation, Neoplastic, Epithelial-Mesenchymal Transition genetics, Cadherins metabolism, Phenotype, Neoplasm Metastasis

Abstract

Epithelial-mesenchymal transitions (EMTs) are thought to promote metastasis via downregulation of E-cadherin (also known as Cdh1) and upregulation of mesenchymal markers such as N-cadherin (Cdh2) and vimentin (Vim). Contrary to this, E-cadherin is retained in many invasive carcinomas and promotes collective cell invasion. To investigate how E-cadherin regulates metastasis, we examined the highly metastatic, E-cadherin-positive murine 4T1 breast cancer model, together with the less metastatic, 4T1-related cell lines 4T07, 168FARN and 67NR. We found that 4T1 cells display a hybrid epithelial/mesenchymal phenotype with co-expression of epithelial and mesenchymal markers, whereas 4T07, 168FARN, and 67NR cells display progressively more mesenchymal phenotypes in vitro that relate inversely to their metastatic capacity in vivo. Using RNA interference and constitutive expression, we demonstrate that the expression level of E-cadherin does not determine 4T1 or 4T07 cell metastatic capacity in mice. Mechanistically, 4T1 cells possess highly dynamic, unstable cell-cell junctions and can undergo collective invasion without E-cadherin downregulation. However, 4T1 orthotopic tumors in vivo also contain subregions of EMT-like loss of E-cadherin. Thus, 4T1 cells function as a model for carcinomas with a hybrid epithelial/mesenchymal phenotype that promotes invasion and metastasis., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

44. New Opportunities for Electric Fields in Promoting Wound Healing: Collective Electrotaxis.

Author

Zhang Y, Huang S, Cao Y, Li L, Yang J, and Zhao M

Abstract

Significance: It has long been hypothesized that naturally occurring electric fields (EFs) aid wound healing by guiding cell migration. Consequently, the application of EFs has significant potential for promoting wound healing. However, the mechanisms underlying the cellular response to EFs remain unclear. Recent Advances: Although the directed migration of isolated single cells under EFs has been studied for decades, only recently has experimental evidence demonstrated the distinct collective migration of large sheets of keratinocytes and corneal epithelial cells in response to applied EFs. Accumulating evidence suggests that the emergent properties of cell groups in response to EF guidance offer new opportunities for EF-assisted directional migration. Critical Issues: In this review, we provide an overview of the field of collective electrotaxis, highlighting key advances made in recent years. We also discuss advanced engineering strategies utilized to manipulate collective electrotaxis. Future Directions: We outline a series of unanswered questions in this field and propose potential applications of collective electrotaxis in developing electrical stimulation technologies for wound healing.

Published

2024

45. Exploring the functional dynamics between PIEZO1 and cell-generated forces

Author

Holt, Jesse Randall

Subjects

Biophysics, Cellular biology, Bioengineering, Cell Migration, Collective Migration, Ion Channel, Mechanobiology, PIEZO1, Traction Forces

Abstract

The conversion of mechanical stimuli into biochemical signals plays an integral role in regulating physiology and homeostasis. Cells utilize several specialized proteins to translate these mechanical forces into intracellular signaling. Of these, the mechanically-activated ion channel PIEZO1 has emerged as a key mechanosensor regulating a range of biological processes occurring in a variety of cell types. Despite the observed importance of PIEZO1, the mechanisms by which PIEZO1 is activated under native cellular contexts and scales to control physiologically important phenomena are largely unknown. Within this dissertation, I describe my efforts to fill this gap within the scientific literature by contributing towards the development of novel microscopy-based techniques and accompanying bioimage analyses which can be implemented to study PIEZO1 activity under endogenous cellular conditions. In Chapter 2, we find that mechanical forces initiated by cell generated, or Myosin II-based, traction forces are able to activate nearby PIEZO1 channels. Given that cell generated forces play a central role during cell migration we then asked whether PIEZO1 may regulate the migration of keratinocytes, the predominant cell type of the epidermis, during wound healing. Within Chapter 3, we show through molecular, cellular and organismal studies that PIEZO1 plays a regulatory role during keratinocyte migration and wound healing. Epidermal-specific Piezo1 knockout mice exhibited faster wound closure while gain-of-function mice displayed slower wound closure compared to littermate controls. By imaging the spatiotemporal localization dynamics of endogenous PIEZO1 channels we find that channel enrichment at regions along the wound edge induces a localized cellular retraction that slows the wound closure process. Efficient wound closure is driven by the formation of specialized cells called leader cells which transmit mechanical and biochemical cues to ensuing follower cells, ensuring their uniform polarization and coordinated direction of migration, or directionality. Despite the observed importance mechanical cues play in regulating both leader cell formation and directionality, the underlying biophysical mechanisms remain elusive. Given that PIEZO1 plays a regulatory role during wound healing, within Chapter 4 we set to elucidate PIEZO1's contributions to collective migration by taking an integrative experimental and mathematical modeling approach. Through numerical simulations and subsequent experimental validation, we found that directionality plays a key role in regulating epithelial sheet migration and is inhibited by PIEZO1 activity. We propose that PIEZO1-mediated retraction suppresses leader cell formation which inhibits the coordination of directionality between cells during collective migration.

Published

2022

46. Mechanics of developmental migration.

Author

Blackley, Deannah G., Cooper, Jack H., Pokorska, Paulina, and Ratheesh, Aparna

Subjects

*HOMEOSTASIS, *TISSUE mechanics, *DISEASE progression, *CELL migration

Abstract

The ability to migrate is a fundamental property of animal cells which is essential for development, homeostasis and disease progression. Migrating cells sense and respond to biochemical and mechanical cues by rapidly modifying their intrinsic repertoire of signalling molecules and by altering their force generating and transducing machinery. We have a wealth of information about the chemical cues and signalling responses that cells use during migration. Our understanding of the role of forces in cell migration is rapidly evolving but is still best understood in the context of cells migrating in 2D and 3D environments in vitro. Advances in live imaging of developing embryos combined with the use of experimental and theoretical tools to quantify and analyse forces in vivo , has begun to shed light on the role of mechanics in driving embryonic cell migration. In this review, we focus on the recent studies uncovering the physical basis of embryonic cell migration in vivo. We look at the physical basis of the classical steps of cell migration such as protrusion formation and cell body translocation and review the recent research on how these processes work in the complex 3D microenvironment of a developing organism. [ABSTRACT FROM AUTHOR]

Published

2021

47. Jamming Transitions in Astrocytes and Glioblastoma Are Induced by Cell Density and Tension

Author

Urszula Hohmann, Julian Cardinal von Widdern, Chalid Ghadban, Maria Cristina Lo Giudice, Grégoire Lemahieu, Elisabetta Ada Cavalcanti-Adam, Faramarz Dehghani, and Tim Hohmann

Subjects

glioblastoma, migration, collective migration, jamming, unjamming, adhesion, Cytology, QH573-671

Abstract

Collective behavior of cells emerges from coordination of cell–cell-interactions and is important to wound healing, embryonic and tumor development. Depending on cell density and cell–cell interactions, a transition from a migratory, fluid-like unjammed state to a more static and solid-like jammed state or vice versa can occur. Here, we analyze collective migration dynamics of astrocytes and glioblastoma cells using live cell imaging. Furthermore, atomic force microscopy, traction force microscopy and spheroid generation assays were used to study cell adhesion, traction and mechanics. Perturbations of traction and adhesion were induced via ROCK or myosin II inhibition. Whereas astrocytes resided within a non-migratory, jammed state, glioblastoma were migratory and unjammed. Furthermore, we demonstrated that a switch from an unjammed to a jammed state was induced upon alteration of the equilibrium between cell–cell-adhesion and tension from adhesion to tension dominated, via inhibition of ROCK or myosin II. Such behavior has implications for understanding the infiltration of the brain by glioblastoma cells and may help to identify new strategies to develop anti-migratory drugs and strategies for glioblastoma-treatment.

Published

2022

48. PI3K Isoform-Specific Regulation of Leader and Follower Cell Function for Collective Migration and Proliferation in Response to Injury

Author

Morgan D. Basta, A. Sue Menko, and Janice L. Walker

Subjects

collective migration, leader cell, follower cell, wound healing, PI3K, p110α, Cytology, QH573-671

Abstract

To ensure proper wound healing it is important to elucidate the signaling cues that coordinate leader and follower cell behavior to promote collective migration and proliferation for wound healing in response to injury. Using an ex vivo post-cataract surgery wound healing model we investigated the role of class I phosphatidylinositol-3-kinase (PI3K) isoforms in this process. Our findings revealed a specific role for p110α signaling independent of Akt for promoting the collective migration and proliferation of the epithelium for wound closure. In addition, we found an important role for p110α signaling in orchestrating proper polarized cytoskeletal organization within both leader and wounded epithelial follower cells to coordinate their function for wound healing. p110α was necessary to signal the formation and persistence of vimentin rich-lamellipodia extensions by leader cells and the reorganization of actomyosin into stress fibers along the basal domains of the wounded lens epithelial follower cells for movement. Together, our study reveals a critical role for p110α in the collective migration of an epithelium in response to wounding.

Published

2022

49. Spatiotemporal dynamics of PIEZO1 localization controls keratinocyte migration during wound healing

Author

Jesse R Holt, Wei-Zheng Zeng, Elizabeth L Evans, Seung-Hyun Woo, Shang Ma, Hamid Abuwarda, Meaghan Loud, Ardem Patapoutian, and Medha M Pathak

Subjects

mechanotransduction, mechanically activated ion channels, ion channel dynamics, cellular retraction, collective migration, cell migration, Medicine, Science, Biology (General), QH301-705.5

Abstract

Keratinocytes, the predominant cell type of the epidermis, migrate to reinstate the epithelial barrier during wound healing. Mechanical cues are known to regulate keratinocyte re-epithelialization and wound healing; however, the underlying molecular transducers and biophysical mechanisms remain elusive. Here, we show through molecular, cellular, and organismal studies that the mechanically activated ion channel PIEZO1 regulates keratinocyte migration and wound healing. Epidermal-specific Piezo1 knockout mice exhibited faster wound closure while gain-of-function mice displayed slower wound closure compared to littermate controls. By imaging the spatiotemporal localization dynamics of endogenous PIEZO1 channels, we find that channel enrichment at some regions of the wound edge induces a localized cellular retraction that slows keratinocyte collective migration. In migrating single keratinocytes, PIEZO1 is enriched at the rear of the cell, where maximal retraction occurs, and we find that chemical activation of PIEZO1 enhances retraction during single as well as collective migration. Our findings uncover novel molecular mechanisms underlying single and collective keratinocyte migration that may suggest a potential pharmacological target for wound treatment. More broadly, we show that nanoscale spatiotemporal dynamics of Piezo1 channels can control tissue-scale events, a finding with implications beyond wound healing to processes as diverse as development, homeostasis, disease, and repair.

Published

2021

50. Born to Run? Diverse Modes of Epithelial Migration

Author

Pengfei Lu and Yunzhe Lu

Subjects

cell polarity, epithelial polarity, apicobasal polarity, collective migration, EMT, extracellular matrix, Biology (General), QH301-705.5

Abstract

Bundled with various kinds of adhesion molecules and anchored to the basement membrane, the epithelium has historically been considered as an immotile tissue and, to migrate, it first needs to undergo epithelial-mesenchymal transition (EMT). Since its initial description more than half a century ago, the EMT process has fascinated generations of developmental biologists and, more recently, cancer biologists as it is believed to be essential for not only embryonic development, organ formation, but cancer metastasis. However, recent progress shows that epithelium is much more motile than previously realized. Here, we examine the emerging themes in epithelial collective migration and how this has impacted our understanding of EMT.

Published

2021