Your search keyword '"Rodrigo Fernandez-Gonzalez"' showing total 72 results

1. Integrin-based adhesions promote cell-cell junction remodelling and cytoskeletal rearrangements to drive embryonic wound healing

Author

Michelle Ly, Clara Schimmer, Ray Hawkins, Katheryn Rothenberg, and Rodrigo Fernandez-Gonzalez

Abstract

Embryos have a remarkable ability to repair wounds rapidly, with no inflammation or scarring. Embryonic wound healing is driven by the collective movement of the surrounding cells to seal the lesion. During embryonic wound closure, the cells adjacent to the wound polarize the cytoskeletal protein actin and the molecular motor non-muscle myosin II, which accumulate at the wound edge forming a supracellular cable around the wound. Adherens junction proteins including E-cadherin are internalized from the interface with the lesion and localize to former tricellular junctions at the wound margin, in a process necessary for cytoskeletal polarity. Using quantitative live microscopy, we found that the cells adjacent to wounds in theDrosophilaepidermis also polarized Talin, a core component of cell-extracellular matrix (ECM) adhesions that links integrins to the actin cytoskeleton. Integrin knock-down and inhibition of integrin binding delayed wound closure and were associated with a reduction in actin levels around the wound. Additionally, disrupting integrins caused a defect in E-cadherin reinforcement at tricellular junctions along the wound edge, suggesting crosstalk between integrin-based and cadherin-based adhesions. Together, our results show that cell-ECM adhesion contributes to embryonic wound repair and reveal an interplay between cell-cell and cell-ECM adhesion in the collective cell movements that drive rapid wound healing.

Published

2023

2. Contractile and expansive actin networks in Drosophila: Developmental cell biology controlled by network polarization and higher-order interactions

Author

Rodrigo Fernandez-Gonzalez and Tony J.C. Harris

Published

2023

3. The α-Catenin mechanosensing M region is required for cell adhesion during tissue morphogenesis

Author

Luka Sheppard, David G. Green, Gerald Lerchbaumer, Katheryn E. Rothenberg, Rodrigo Fernandez-Gonzalez, and Ulrich Tepass

Subjects

Cell Biology

Abstract

α-Catenin couples the cadherin–catenin complex to the actin cytoskeleton. The mechanosensitive α-Catenin M region undergoes conformational changes upon application of force to recruit interaction partners. Here, we took advantage of the tension landscape in the Drosophila embryo to define three different states of α-Catenin mechanosensing in support of cell adhesion. Low-, medium-, and high-tension contacts showed a corresponding recruitment of Vinculin and Ajuba, which was dependent on the α-Catenin M region. In contrast, the Afadin homolog Canoe acts in parallel to α-Catenin at bicellular low- and medium-tension junctions but requires an interaction with α-Catenin for its tension-sensitive enrichment at high-tension tricellular junctions. Individual M region domains make complex contributions to cell adhesion through their impact on interaction partner recruitment, and redundancies with the function of Canoe. Our data argue that α-Catenin and its interaction partners are part of a cooperative and partially redundant mechanoresponsive network that supports AJs remodeling during morphogenesis.

Published

2022

4. Rap1 coordinates cell-cell adhesion and cytoskeletal reorganization to drive collective cell migration in vivo

Author

Katheryn E. Rothenberg, Yujun Chen, Jocelyn McDonald, and Rodrigo Fernandez-Gonzalez

Subjects

General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology

Abstract

Collective cell movements contribute to tissue development and repair, and spread metastatic disease. In epithelia, cohesive cell movements require reorganization of adherens junctions and the actomyosin cytoskeleton. However, the mechanisms that coordinate cell-cell adhesion and cytoskeletal remodelling during collective cell migration in vivo are unclear. We investigated the mechanisms of collective cell migration during wound healing in the Drosophila embryonic epidermis. Upon wounding, the cells adjacent to the wound internalize cell-cell adhesion molecules and polarize actin and the motor protein myosin II to form a supracellular cable around the wound that coordinates cell movements. The cable anchors at former tricellular junctions (TCJs) along the wound edge, and TCJs are reinforced during wound closure. We found that the small GTPase Rap1 was both necessary and sufficient for rapid wound repair. Rap1 promoted actomyosin polarization to the wound edge and E-cadherin accumulation at TCJs. Using embryos expressing a mutant form of the Rap1 effector Canoe/Afadin that cannot bind Rap1, we found that Rap1 signals through Canoe for adherens junction remodelling, but not for actomyosin cable assembly. Rap1 was necessary and sufficient for RhoA/Rho1 activation at the wound edge. Consistent with this, the RhoGEF Ephexin localized to the wound edge in a Rap1-dependent manner, and Ephexin was necessary for myosin polarization and rapid wound repair, but not for E-cadherin redistribution. Together, our data show that Rap1 coordinates the molecular rearrangements that drive embryonic wound healing and independently drives actomyosin cable assembly through Ephexin-Rho1, and E-cadherin redistribution through Canoe, thus enabling rapid collective cell migration in vivo.

Published

2022

5. Powering morphogenesis: multiscale challenges at the interface of cell adhesion and the cytoskeleton

Author

Rodrigo Fernandez-Gonzalez and Mark Peifer

Subjects

Cell Adhesion, Morphogenesis, Animals, Cell Biology, Actomyosin, Adherens Junctions, Cadherins, Molecular Biology, Cytoskeleton

Abstract

Among the defining features of the animal kingdom is the ability of cells to change shape and move. This underlies embryonic and postembryonic development, tissue homeostasis, regeneration, and wound healing. Cell shape change and motility require linkage of the cell’s force-generating machinery to the plasma membrane at cell–cell and cell–extracellular matrix junctions. Connections of the actomyosin cytoskeleton to cell–cell adherens junctions need to be both resilient and dynamic, preventing tissue disruption during the dramatic events of embryonic morphogenesis. In the past decade, new insights radically altered the earlier simple paradigm that suggested simple linear linkage via the cadherin–catenin complex as the molecular mechanism of junction–cytoskeleton interaction. In this Perspective we provide a brief overview of our current state of knowledge and then focus on selected examples highlighting what we view as the major unanswered questions in our field and the approaches that offer exciting new insights at multiple scales from atomic structure to tissue mechanics.

Published

2022

6. Correction: The recycling endosome protein Rab25 coordinates collective cell movements in the zebrafish surface epithelium

Author

Patrick Morley Willoughby, Molly Allen, Jessica Yu, Roman Korytnikov, Tianhui Chen, Yupeng Liu, Isis So, Haoyu Wan, Neil Macpherson, Jennifer A Mitchell, Rodrigo Fernandez-Gonzalez, and Ashley EE Bruce

Subjects

General Immunology and Microbiology, General Neuroscience, General Medicine, General Biochemistry, Genetics and Molecular Biology

Published

2022

7. Septate junction proteins are required for cell shape changes, actomyosin reorganization and cell adhesion during dorsal closure in

Author

Oindrila De, Clinton Rice, Teresa Zulueta-Coarasa, Rodrigo Fernandez-Gonzalez, and Robert E. Ward

Subjects

Cell Biology, Developmental Biology

Abstract

Septate junctions (SJs) serve as occluding barriers in invertebrate epithelia. In Drosophila, at least 30 genes are required for the formation or maintenance of SJs. Interestingly, loss-of-function mutations in core SJ components are embryonic lethal, with defects in developmental events such as head involution and dorsal closure (DC) that occur prior to the formation of a mature SJ, indicating a role for these proteins in mid-embryogenesis independent of their occluding function. To understand this novel function in development, we examined loss-of-function mutations in three core SJ proteins during the process of DC. DC occurs during mid-embryogenesis to seal a dorsal gap in the epidermis following germ band retraction. Closure is driven by contraction of the extraembryonic amnioserosa cells that temporarily cover the dorsal surface and by cell shape changes (elongation) of lateral epidermal cells that bring the contralateral sheets together at the dorsal midline. Using live imaging and examination of fixed tissues, we show that early events in DC occur normally in SJ mutant embryos, but during later closure, coracle, Macroglobulin complement-related and Neurexin-IV mutant embryos exhibit slower rates of closure and display aberrant cells shapes in the dorsolateral epidermis, including dorsoventral length and apical surface area. SJ mutant embryos also show mild defects in actomyosin structures along the leading edge, but laser cutting experiments suggest similar tension and viscoelastic properties in SJ mutant versus wild type epidermis. In a high percentage of SJ mutant embryos, the epidermis tears free from the amnioserosa near the end of DC and live imaging and immunostaining reveal reduced levels of E-cadherin, suggesting that defective adhesion may be responsible for these tears. Supporting this notion, reducing E-cadherin by half significantly enhances the penetrance of DC defects in coracle mutant embryos.

Published

2022

8. DDR1 (Discoidin Domain Receptor-1)-RhoA (Ras Homolog Family Member A) Axis Senses Matrix Stiffness to Promote Vascular Calcification

Author

Michelle P. Bendeck, Craig A. Simmons, Marsel Lino, Rodrigo Fernandez-Gonzalez, Katheryn E. Rothenberg, and David Ngai

Subjects

RHOA, transdifferentiation, Myocytes, Smooth Muscle, Core Binding Factor Alpha 1 Subunit, discoidin domain receptor, Mechanotransduction, Cellular, Muscle, Smooth, Vascular, Discoidin Domain Receptor 1, Osteogenesis, Animals, Medicine, Phosphorylation, Proto-Oncogene Proteins c-vav, Vascular Calcification, Receptor, Vascular calcification, Cells, Cultured, Mice, Knockout, DDR1, biology, Basic Sciences, actomyosin, business.industry, Transdifferentiation, Atherosclerosis, musculoskeletal system, Extracellular Matrix, Cell biology, Disease Models, Animal, Family member, Cell Transdifferentiation, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, biology.protein, rhoA GTP-Binding Protein, Cardiology and Cardiovascular Medicine, business, Discoidin domain

Abstract

Supplemental Digital Content is available in the text., Objective: Vascular calcification is a pathology characterized by arterial mineralization, which is a common late-term complication of atherosclerosis that independently increases the risk of adverse cardiovascular events by fourfold. A major source of calcifying cells is transdifferentiating vascular smooth muscle cells (VSMCs). Previous studies showed that deletion of the collagen-binding receptor, DDR1 (discoidin domain receptor-1), attenuated VSMC calcification. Increased matrix stiffness drives osteogenesis, and DDR1 has been implicated in stiffness sensing in other cell types; however, the role of DDR1 as a mechanosensor in VSMCs has not been investigated. Here, we test the hypothesis that DDR1 senses increased matrix stiffness and promotes VSMC transdifferentiation and calcification. Approach and Results: Primary VSMCs isolated from Ddr1+/+ (wild-type) and Ddr1−/− (knockout) mice were studied on collagen-I–coated silicon substrates of varying stiffness, culturing in normal or calcifying medium. DDR1 expression and phosphorylation increased with increasing stiffness, as did in vitro calcification, nuclear localization of Runx2 (Runt-related transcription factor 2), and expression of other osteochondrocytic markers. By contrast, DDR1 deficient VSMCs were not responsive to stiffness and did not undergo transdifferentiation. DDR1 regulated stress fiber formation and RhoA (ras homolog family member A) activation through the RhoGEF (rho guanine nucleotide exchange factor), Vav2. Inhibition of actomyosin contractility reduced Runx2 activation and attenuated in vitro calcification in wild-type VSMCs. Finally, a novel positive feedforward loop was uncovered between DDR1 and actomyosin contractility, important in regulating DDR1 expression, clustering, and activation. Conclusions: This study provides mechanistic insights into DDR1 mechanosignaling and shows that DDR1 activity and actomyosin contractility are interdependent in mediating stiffness-dependent increases in VSMC calcification.

Published

2020

9. Myosin waves and a mechanical asymmetry guide the oscillatory migration of Drosophila cardiac progenitors

Author

Negar Balaghi, Gonca Erdemci-Tandogan, Christopher McFaul, and Rodrigo Fernandez-Gonzalez

Abstract

Heart development begins with the formation of a tube, as cardiac progenitors migrate from opposite sides of the embryo and meet medially. Defective cardiac progenitor movements cause congenital heart defects. However, the mechanisms of cell migration during early heart development remain poorly understood. We investigated the mechanisms of movement of the Drosophila cardiac progenitors, the cardioblasts. Using quantitative time-lapse microscopy, we found that cardioblasts did not advance monotonically. Instead, cardioblasts took periodic forward and backward steps as they migrated. The forward steps were greater in both amplitude and duration, resulting in net forward movement of the cells. The molecular motor non-muscle myosin II displayed an alternating pattern of localization between the leading and trailing ends of migrating cardioblasts, forming oscillatory waves that traversed the cells. The alternating pattern of myosin polarity was associated with the alternative contraction and relaxation of the leading and trailing edges of the cell. Mathematical modelling predicted that forward migration requires the presence of a stiff boundary at the trailing edge of the cardioblasts. Consistent with this, we found a supracellular actin cable at the trailing edge of the cardioblasts. When we reduced the tension sustained by the actin cable, the amplitude of the backward steps of cardioblasts increased, thus reducing the net forward speed of migration. Together, our results indicate that periodic cell shape changes coupled with a polarized actin cable produce asymmetrical forces that guide cardioblast migration.

Published

2022

10. Actin and myosin dynamics are independent duringDrosophilaembryonic wound repair

Author

Katheryn E. Rothenberg, Anna B. Kobb, and Rodrigo Fernandez-Gonzalez

Subjects

0303 health sciences, integumentary system, Cell, Cell migration, macromolecular substances, Cell Biology, Biology, Embryonic stem cell, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Myosin, Molecular motor, medicine, Wound healing, Cytoskeleton, Molecular Biology, 030217 neurology & neurosurgery, Actin, 030304 developmental biology

Abstract

Collective cell movements play a central role in embryonic development, tissue repair, and metastatic disease. Cell movements are often coordinated by supracellular networks formed by the cytoskeletal protein actin and the molecular motor nonmuscle myosin II. During wound closure in the embryonic epidermis, the cells around the wound migrate collectively into the damaged region. In Drosophila embryos, mechanical tension stabilizes myosin at the wound edge, facilitating the assembly of a supracellular myosin cable around the wound that coordinates cell migration. Here, we show that actin is also stabilized at the wound edge. However, loss of tension or myosin activity does not affect the dynamics of actin at the wound margin. Conversely, pharmacological stabilization of actin does not affect myosin levels or dynamics around the wound. Together, our data suggest that actin and myosin are independently regulated during embryonic wound closure, thus conferring robustness to the embryonic wound healing response.

Published

2019

11. The Crk adapter protein is essential forDrosophilaembryogenesis, where it regulates multiple actin-dependent morphogenic events

Author

Alison N. Bonner, Andrew J. Spracklen, Rodrigo Fernandez-Gonzalez, Alexandru Florea, Mark Peifer, Emma M. Thornton-Kolbe, and Peter J. Compton

Subjects

0303 health sciences, animal structures, Pseudocleavage, Cellular differentiation, Drosophila embryogenesis, Cell migration, Cell Biology, Biology, Cell fate determination, Actin cytoskeleton, Filamentous actin, Cell biology, 03 medical and health sciences, Adapter molecule crk, 0302 clinical medicine, embryonic structures, Cytoskeleton, Mitosis, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Small Src homology domain 2 (SH2) and 3 (SH3) adapter proteins regulate cell fate and behavior by mediating interactions between cell surface receptors and downstream signaling effectors in many signal transduction pathways. The CT10 regulator of kinase (Crk) family has tissue-specific roles in phagocytosis, cell migration, and neuronal development and mediates oncogenic signaling in pathways like that of Abelson kinase. However, redundancy among the two mammalian family members and the position of the Drosophila gene on the fourth chromosome precluded assessment of Crk’s full role in embryogenesis. We circumvented these limitations with short hairpin RNA and CRISPR technology to assess Crk’s function in Drosophila morphogenesis. We found that Crk is essential beginning in the first few hours of development, where it ensures accurate mitosis by regulating orchestrated dynamics of the actin cytoskeleton to keep mitotic spindles in syncytial embryos from colliding. In this role, it positively regulates cortical localization of the actin-related protein 2/3 complex (Arp2/3), its regulator suppressor of cAMP receptor (SCAR), and filamentous actin to actin caps and pseudocleavage furrows. Crk loss leads to the loss of nuclei and formation of multinucleate cells. We also found roles for Crk in embryonic wound healing and in axon patterning in the nervous system, where it localizes to the axons and midline glia. Thus, Crk regulates diverse events in embryogenesis that require orchestrated cytoskeletal dynamics.

Published

2019

12. Forceful closure: cytoskeletal networks in embryonic wound repair

Author

Rodrigo Fernandez-Gonzalez and Katheryn E. Rothenberg

Subjects

Embryo, Nonmammalian, Biology, Septin, Epithelium, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Animals, Humans, Intermediate filament, Cytoskeleton, Molecular Biology, Actin, 030304 developmental biology, Wound Healing, 0303 health sciences, integumentary system, Actomyosin, Cell Biology, Embryonic stem cell, Actins, Cell biology, Perspective, Cancer cell, Wound healing, 030217 neurology & neurosurgery

Abstract

Embryonic tissues heal wounds rapidly and without scarring, in a process conserved across species and driven by collective cell movements. The mechanisms of coordinated cell movement during embryonic wound closure also drive tissue development and cancer metastasis; therefore, embryonic wound repair has received considerable attention as a model of collective cell migration. During wound closure, a supracellular actomyosin cable at the wound edge coordinates cells, while actin-based protrusions contribute to cell crawling and seamless wound healing. Other cytoskeletal networks are reorganized during wound repair: microtubules extend into protrusions and along cell–cell boundaries as cells stretch into damaged regions, septins accumulate at the wound margin, and intermediate filaments become polarized in the cells adjacent to the wound. Thus, diverse cytoskeletal networks work in concert to maintain tissue structure, while also driving and organizing cell movements to promote rapid repair. Understanding the signals that coordinate the dynamics of different cytoskeletal networks, and how adhesions between cells or with the extracellular matrix integrate forces across cells, will be important to elucidate the mechanisms of efficient embryonic wound healing and may have far-reaching implications for developmental and cancer cell biology.

Published

2019

13. Author response: Pak1 and PP2A antagonize aPKC function to support cortical tension induced by the Crumbs-Yurt complex

Author

Rodrigo Fernandez-Gonzalez, Patrick Laprise, Katheryn E. Rothenberg, Helori-Mael Gaude, Cornélia Biehler, and Alexandra Jetté

Subjects

PAK1, Chemistry, Tension (physics), Protein phosphatase 2, Neuroscience, Function (biology)

Published

2021

14. Author response: The recycling endosome protein Rab25 coordinates collective cell movements in the zebrafish surface epithelium

Author

Patrick Morley Willoughby, Molly Allen, Jessica Yu, Roman Korytnikov, Tianhui Chen, Yupeng Liu, Isis So, Haoyu Wan, Neil Macpherson, Jennifer A Mitchell, Rodrigo Fernandez-Gonzalez, and Ashley EE Bruce

Subjects

Recycling endosome, medicine.anatomical_structure, biology, Chemistry, Cell, medicine, biology.organism_classification, Zebrafish, Epithelium, Cell biology

Published

2021

15. Myosin cables control the timing of tissue internalization in the Drosophila embryo

Author

Veronica Castle, Gonca Erdemci-Tandogan, Negar Balaghi, Jessica C. Yu, and Rodrigo Fernandez-Gonzalez

Subjects

Myosin Type II, Mesoderm, Chemistry, media_common.quotation_subject, Fluorescence recovery after photobleaching, Ectoderm, Myosins, Cell biology, medicine.anatomical_structure, Drosophila melanogaster, Myosin, Cell polarity, medicine, Compartment (development), Animals, Drosophila Proteins, Drosophila, Internalization, Axis elongation, Developmental Biology, media_common

Abstract

Compartment boundaries prevent cell mixing during animal development. In the early Drosophila embryo, the mesectoderm is a group of glial precursors that separate ectoderm and mesoderm, forming the ventral midline. Mesectoderm cells undergo one round of oriented divisions during axis elongation and are eventually internalized 6 h later. Using spinning disk confocal microscopy and image analysis, we found that after dividing, mesectoderm cells reversed their planar polarity. The polarity factor Bazooka was redistributed to mesectoderm-mesectoderm cell interfaces, and the molecular motor non-muscle Myosin II and its upstream activator Rho-kinase (Rok) accumulated at mesectoderm-ectoderm (ME) interfaces, forming supracellular cables flanking the mesectoderm on either side of the tissue. Laser ablation revealed the presence of increased tension at ME cables, where Myosin was stabilized, as shown by fluorescence recovery after photobleaching. We used laser nanosurgery to reduce tension at the ME boundary, and we found that Myosin fluorescence decreased rapidly, suggesting a role for tension in ME boundary maintenance. Mathematical modelling predicted that increased tension at the ME boundary was necessary to prevent the premature establishment of contacts between the two ectodermal sheets on opposite sides of the mesectoderm, thus controlling the timing of mesectoderm internalization. We validated the model in vivo: Myosin inhibition disrupted the linearity of the ME boundary and resulted in early internalization of the mesectoderm. Our results suggest that the redistribution of Rok polarizes Myosin and Bazooka within the mesectoderm to establish tissue boundaries, and that ME boundaries control the timely internalization of the mesectoderm as embryos develop.

Published

2021

16. Multiscale In Vivo Imaging of Collective Cell Migration in Drosophila Embryos

Author

Gordana Scepanovic, Alexandru Florea, and Rodrigo Fernandez-Gonzalez

Subjects

biology, Cell, biology.organism_classification, Embryonic stem cell, Cell biology, law.invention, medicine.anatomical_structure, Confocal microscopy, law, Live cell imaging, Quantitative Microscopy, Microscopy, medicine, Drosophila melanogaster, Preclinical imaging

Abstract

Coordinated cell movements drive embryonic development and tissue repair, and can also spread disease. Time-lapse microscopy is an integral part in the study of the cell biology of collective cell movements. Advances in imaging techniques enable monitoring dynamic cellular and molecular events in real time within living animals. Here, we demonstrate the use of spinning disk confocal microscopy to investigate coordinated cell movements and epithelial-to-mesenchymal-like transitions during embryonic wound closure in Drosophila. We describe image-based metrics to quantify the efficiency of collective cell migration. Finally, we show the application of super-resolution radial fluctuation microscopy to obtain multidimensional, super-resolution images of protrusive activity in collectively moving cells in vivo. Together, the methods presented here constitute a toolkit for the modern analysis of collective cell migration in living animals.

Published

2020

17. Multiscale In Vivo Imaging of Collective Cell Migration in Drosophila Embryos

Author

Gordana, Scepanovic, Alexandru, Florea, and Rodrigo, Fernandez-Gonzalez

Subjects

Drosophila melanogaster, Embryo, Nonmammalian, Epithelial-Mesenchymal Transition, Imaging, Three-Dimensional, Microscopy, Confocal, Cell Movement, Cell Tracking, Limit of Detection, Animals

Abstract

Coordinated cell movements drive embryonic development and tissue repair, and can also spread disease. Time-lapse microscopy is an integral part in the study of the cell biology of collective cell movements. Advances in imaging techniques enable monitoring dynamic cellular and molecular events in real time within living animals. Here, we demonstrate the use of spinning disk confocal microscopy to investigate coordinated cell movements and epithelial-to-mesenchymal-like transitions during embryonic wound closure in Drosophila. We describe image-based metrics to quantify the efficiency of collective cell migration. Finally, we show the application of super-resolution radial fluctuation microscopy to obtain multidimensional, super-resolution images of protrusive activity in collectively moving cells in vivo. Together, the methods presented here constitute a toolkit for the modern analysis of collective cell migration in living animals.

Published

2020

18. Dynamic force patterns promote collective cell movements during embryonic wound repair

Author

Teresa Zulueta-Coarasa and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Physics, integumentary system, Cell, General Physics and Astronomy, macromolecular substances, Embryonic stem cell, Cell biology, Motor protein, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Myosin, medicine, Molecular motor, Wound closure, Ion channel, Actin

Abstract

Embryonic wounds heal rapidly, in a process driven by coordinated cell movements. Polarization of actin and the molecular motor non-muscle myosin II in the cells adjacent to the wound results in the formation of a supracellular cable around the wound that drives repair. In Drosophila embryos, the distribution of actin around wounds is heterogeneous, with regions of high and low actin density, and actin heterogeneity is necessary for rapid repair. Here, we demonstrate that actin and myosin display stochastic patterns around embryonic wounds, and that contractile forces around wounds are heterogeneous. Mathematical modelling suggests that actomyosin heterogeneity favours wound closure if myosin is regulated by tension and strain, a hypothesis that we validate experimentally. We show that inhibition of stretch-activated ion channels disrupts myosin dynamics and tissue repair. Together, our results indicate that staggered contractile events, mechanical signals and force-regulated myosin dynamics coordinate cell behaviours to drive efficient wound closure. The motor proteins and contractile forces involved in wound closure are both shown to be heterogeneously distributed around a wound. Theory suggests that this heterogeneity speeds up wound closure, as long as the proteins are mechanically regulated.

Published

2018

19. Introduction: CANFLY XV 2019

Author

Amanda J. Moehring, Rodrigo Fernandez-Gonzalez, Thomas J.S. Merritt, and Andrew J. Simmonds

Subjects

Genetics, Library science, General Medicine, Biology, Molecular Biology, Biotechnology

Published

2021

20. (Machine-)Learning to analyze in vivo microscopy: Support vector machines

Author

Michael F.Z. Wang and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Embryo, Nonmammalian, Support Vector Machine, Intravital Microscopy, Biophysics, Cell segmentation, High resolution, Context (language use), Biology, Machine learning, computer.software_genre, Biochemistry, Analytical Chemistry, Image (mathematics), Machine Learning, 03 medical and health sciences, 0302 clinical medicine, Lineage tracing, Animals, In vivo microscopy, Molecular Biology, Developmental stage, business.industry, Support vector machine, Drosophila melanogaster, 030104 developmental biology, Artificial intelligence, business, computer, 030217 neurology & neurosurgery

Abstract

The development of new microscopy techniques for super-resolved, long-term monitoring of cellular and subcellular dynamics in living organisms is revealing new fundamental aspects of tissue development and repair. However, new microscopy approaches present several challenges. In addition to unprecedented requirements for data storage, the analysis of high resolution, time-lapse images is too complex to be done manually. Machine learning techniques are ideally suited for the (semi-)automated analysis of multidimensional image data. In particular, support vector machines (SVMs), have emerged as an efficient method to analyze microscopy images obtained from animals. Here, we discuss the use of SVMs to analyze in vivo microscopy data. We introduce the mathematical framework behind SVMs, and we describe the metrics used by SVMs and other machine learning approaches to classify image data. We discuss the influence of different SVM parameters in the context of an algorithm for cell segmentation and tracking. Finally, we describe how the application of SVMs has been critical to study protein localization in yeast screens, for lineage tracing in C. elegans, or to determine the developmental stage of Drosophila embryos to investigate gene expression dynamics. We propose that SVMs will become central tools in the analysis of the complex image data that novel microscopy modalities have made possible. This article is part of a Special Issue entitled: Biophysics in Canada, edited by Lewis Kay, John Baenziger, Albert Berghuis and Peter Tieleman.

Published

2017

21. Quantitative modelling of epithelial morphogenesis: integrating cell mechanics and molecular dynamics

Author

Rodrigo Fernandez-Gonzalez and Jessica C. Yu

Subjects

0301 basic medicine, Vertex (computer graphics), Embryo, Nonmammalian, Process (engineering), Morphogenesis, Computational biology, Biology, Mechanotransduction, Cellular, Models, Biological, Tight Junctions, Biomechanical Phenomena, 03 medical and health sciences, Molecular dynamics, Animals, Drosophila Proteins, Humans, Cytoskeleton, Computational model, Epithelial Cells, Cell Biology, Cadherins, Dorsal closure, Extracellular Matrix, Cell biology, Drosophila melanogaster, 030104 developmental biology, Gene Expression Regulation, Stress, Mechanical, Developmental biology, Developmental Biology

Abstract

Epithelial tissues form and repair in complex processes influenced by molecular and physical factors. Recent years have witnessed the development of new microscopy modalities that push the limits of spatial resolution, and enable long-term monitoring of developing animals. Increasingly, methods from the physical sciences are used to investigate the role of mechanical forces in living organisms. The application of these new technologies to developmental biology has led to ever-expanding volumes of data that must be interpreted and integrated. For these reasons, computer models are being applied to investigate tissue morphogenesis. Here, we discuss the use of vertex models to study the morphogenesis of epithelial tissues. We motivate the use of computational models and consider their advantages and limitations. We provide an introduction to the theoretical foundation of vertex models and describe how they can integrate mechanical and biochemical dynamics. Finally, we review recent advances in the application of vertex models to investigate dorsal closure, a morphogenetic process in the Drosophila embryo with parallels to both embryonic development and wound repair in vertebrate organisms.

Published

2017

22. Cell–cell and cell–extracellular matrix adhesions cooperate to organize actomyosin networks and maintain force transmission during dorsal closure

Author

Teresa Zulueta-Coarasa, Guy Tanentzapf, Emily Lostchuck, Kaitlyn M. L. Cramb, Katharine Goodwin, and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Morphogenesis, Embryonic Development, Myosins, Matrix (biology), Biology, Cell-Matrix Junctions, Extracellular matrix, 03 medical and health sciences, Cell Movement, Myosin, Cell Adhesion, Animals, Drosophila Proteins, Cell Interactions, Cell adhesion, Molecular Biology, Actin, Actomyosin, Articles, Cell Biology, Cadherins, Actin cytoskeleton, Actins, Dorsal closure, Extracellular Matrix, Cell biology, Actin Cytoskeleton, 030104 developmental biology, Drosophila, Epidermis

Abstract

Cell–extracellular matrix (ECM) and cell–cell adhesion are interdependent during dorsal closure in the fly. Cell–ECM adhesion is required for normal myosin dynamics and organization of both cell–cell adhesions and actin networks during dorsal closure. Loss of cell–cell adhesion affects cell–ECM adhesion and tissue biomechanics., Tissue morphogenesis relies on the coordinated action of actin networks, cell–cell adhesions, and cell–extracellular matrix (ECM) adhesions. Such coordination can be achieved through cross-talk between cell–cell and cell–ECM adhesions. Drosophila dorsal closure (DC), a morphogenetic process in which an extraembryonic tissue called the amnioserosa contracts and ingresses to close a discontinuity in the dorsal epidermis of the embryo, requires both cell–cell and cell–ECM adhesions. However, whether the functions of these two types of adhesions are coordinated during DC is not known. Here we analyzed possible interdependence between cell–cell and cell–ECM adhesions during DC and its effect on the actomyosin network. We find that loss of cell–ECM adhesion results in aberrant distributions of cadherin-mediated adhesions and actin networks in the amnioserosa and subsequent disruption of myosin recruitment and dynamics. Moreover, loss of cell–cell adhesion caused up-regulation of cell–ECM adhesion, leading to reduced cell deformation and force transmission across amnioserosa cells. Our results show how interdependence between cell–cell and cell–ECM adhesions is important in regulating cell behaviors, force generation, and force transmission critical for tissue morphogenesis.

Published

2017

23. Myosin II promotes the anisotropic loss of the apical domain during Drosophila neuroblast ingression

Author

Youjin Oh, Michael F.Z. Wang, Rodrigo Fernandez-Gonzalez, Sérgio Simões, and Ulrich Tepass

Subjects

0301 basic medicine, animal structures, Ingression, Article, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, Neuroblast, Live cell imaging, Myosin, Animals, Cell adhesion, reproductive and urinary physiology, Research Articles, Epithelial polarity, Myosin Type II, biology, fungi, Apical constriction, Cell Biology, biology.organism_classification, Cell biology, Drosophila melanogaster, 030104 developmental biology, nervous system, embryonic structures, Anisotropy, 030217 neurology & neurosurgery

Abstract

Drosophila neural stem cells, or neuroblasts, ingress from the neuroepithelium in an EMT-like process, during which the apical cell domain is lost. Apical constriction of neuroblasts and the serial loss of cell–cell contacts require periodic pulses of actomyosin that cause progressively stronger ratcheted contractions of the neuroblast apical cortex., Epithelial–mesenchymal transitions play key roles in development and cancer and entail the loss of epithelial polarity and cell adhesion. In this study, we use quantitative live imaging of ingressing neuroblasts (NBs) in Drosophila melanogaster embryos to assess apical domain loss and junctional disassembly. Ingression is independent of the Snail family of transcriptional repressors and down-regulation of Drosophila E-cadherin (DEcad) transcription. Instead, the posttranscriptionally regulated decrease in DEcad coincides with the reduction of cell contact length and depends on tension anisotropy between NBs and their neighbors. A major driver of apical constriction and junctional disassembly are periodic pulses of junctional and medial myosin II that result in progressively stronger cortical contractions during ingression. Effective contractions require the molecular coupling between myosin and junctions and apical relaxation of neighboring cells. Moreover, planar polarization of myosin leads to the loss of anterior–posterior junctions before the loss of dorsal–ventral junctions. We conclude that planar-polarized dynamic actomyosin networks drive apical constriction and the anisotropic loss of cell contacts during NB ingression.

Published

2017

24. Supracellular Actin Cables and Actomyosin-based Contraction in Cardiac Morphogenesis

Author

Christopher McFaul, Christopher M. Yip, Rodrigo Fernandez-Gonzalez, and Negar Balaghi

Subjects

Contraction (grammar), Chemistry, Biophysics, Cardiac morphogenesis, Actin, Cell biology

Published

2020

25. Basal Cell-Extracellular Matrix Adhesion Regulates Force Transmission during Tissue Morphogenesis

Author

Katharine Goodwin, Teresa Zulueta-Coarasa, Guy Tanentzapf, Rodrigo Fernandez-Gonzalez, Emily Lostchuck, and Stephanie J. Ellis

Subjects

0301 basic medicine, Integrins, Integrin, Morphogenesis, Matrix (biology), Models, Biological, Biophysical Phenomena, General Biochemistry, Genetics and Molecular Biology, Animals, Genetically Modified, Focal adhesion, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Cell Adhesion, medicine, Animals, Drosophila Proteins, Molecular Biology, Focal Adhesions, biology, Cell Biology, Adhesion, Dorsal closure, Epithelium, Extracellular Matrix, Cell biology, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Drosophila, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Tissue morphogenesis requires force-generating mechanisms to organize cells into complex structures. Although many such mechanisms have been characterized, we know little about how forces are integrated across developing tissues. We provide evidence that integrin-mediated cell-extracellular matrix (ECM) adhesion modulates the transmission of apically generated tension during dorsal closure (DC) in Drosophila. Integrin-containing adhesive structures resembling focal adhesions were identified on the basal surface of the amnioserosa (AS), an extraembryonic epithelium essential for DC. Genetic modulation of integrin-mediated adhesion results in defective DC. Quantitative image analysis and laser ablation experiments reveal that basal cell-ECM adhesions provide resistance to apical cell displacements and force transmission between neighboring cells in the AS. Finally, we provide evidence for integrin-dependent force transmission to the AS substrate. Overall, we find that integrins regulate force transmission within and between cells, thereby playing an essential role in transmitting tension in developing tissues.

Published

2016

26. Force-dependent allostery of the α-catenin actin-binding domain controls adherens junction dynamics and functions

Author

Shigenobu Yonemura, Noboru Ishiyama, Anna B. Kobb, Rodrigo Fernandez-Gonzalez, Ulrich Tepass, Mitsuhiko Ikura, Annette S. Flozak, Deborah E. Leckband, Samantha K. Barrick, Alexander Yemelyanov, Megan N. Wood, Tadateru Nishikawa, Ritu Sarpal, Cara J. Gottardi, and Hanako Hayashi

Subjects

0301 basic medicine, Science, Allosteric regulation, General Physics and Astronomy, macromolecular substances, Article, Protein Structure, Secondary, General Biochemistry, Genetics and Molecular Biology, Adherens junction, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Animals, Humans, lcsh:Science, Cell adhesion, Actin, Multidisciplinary, Cadherin, Chemistry, Adherens Junctions, General Chemistry, Cadherins, Actin cytoskeleton, Actins, 3. Good health, Cell biology, Actin Cytoskeleton, 030104 developmental biology, lcsh:Q, alpha Catenin, 030217 neurology & neurosurgery, Binding domain

Abstract

α-catenin is a key mechanosensor that forms force-dependent interactions with F-actin, thereby coupling the cadherin-catenin complex to the actin cytoskeleton at adherens junctions (AJs). However, the molecular mechanisms by which α-catenin engages F-actin under tension remained elusive. Here we show that the α1-helix of the α-catenin actin-binding domain (αcat-ABD) is a mechanosensing motif that regulates tension-dependent F-actin binding and bundling. αcat-ABD containing an α1-helix-unfolding mutation (H1) shows enhanced binding to F-actin in vitro. Although full-length α-catenin-H1 can generate epithelial monolayers that resist mechanical disruption, it fails to support normal AJ regulation in vivo. Structural and simulation analyses suggest that α1-helix allosterically controls the actin-binding residue V796 dynamics. Crystal structures of αcat-ABD-H1 homodimer suggest that α-catenin can facilitate actin bundling while it remains bound to E-cadherin. We propose that force-dependent allosteric regulation of αcat-ABD promotes dynamic interactions with F-actin involved in actin bundling, cadherin clustering, and AJ remodeling during tissue morphogenesis., Cell-cell adhesion mediated by catenin-cadherin complexes plays a critical role in translating the mechanical forces into physiological responses. Here the authors define a mechanism of force-dependent cadherin-actin linkage dynamically regulated through the actin-binding domain of α-catenin.

Published

2018

27. Oxidative Stress Orchestrates Cell Polarity to Promote Embryonic Wound Healing

Author

Patrick Morley Willoughby, Rodrigo Fernandez-Gonzalez, Ashley E.E. Bruce, and Miranda V. Hunter

Subjects

0301 basic medicine, Embryo, Nonmammalian, Proto-Oncogene Proteins pp60(c-src), Biology, Myosins, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, Adherens junction, 03 medical and health sciences, 0302 clinical medicine, Myosin, Cell polarity, medicine, Animals, Drosophila Proteins, Cytoskeleton, Molecular Biology, Zebrafish, Wound Healing, integumentary system, Cell Polarity, Cell Biology, Actomyosin, Adherens Junctions, Cadherins, Embryonic stem cell, Actins, Cell biology, Oxidative Stress, 030104 developmental biology, Drosophila melanogaster, Intercellular Junctions, Wound healing, Reactive Oxygen Species, 030217 neurology & neurosurgery, Oxidative stress, Developmental Biology, Proto-oncogene tyrosine-protein kinase Src

Abstract

Summary Embryos have a striking ability to heal wounds rapidly and without scarring. Embryonic wound repair is a conserved process, driven by polarization of cell-cell junctions and the actomyosin cytoskeleton in the cells around the wound. However, the upstream signals that trigger cell polarization around wounds are unknown. We used quantitative in vivo microscopy in Drosophila and zebrafish embryos to identify reactive oxygen species (ROS) as a critical signal that orchestrates cell polarity around wounds. ROS promote trafficking of adherens junctions and accumulation of actin and myosin at the wound edge and are necessary for wound closure. We show that, in Drosophila, ROS drive wound healing in part through an ortholog of Src kinase, Src42A, which we identify as a redox sensor that promotes polarization of junctions and the cytoskeleton around wounds. We propose that ROS are a reparative signal that drives rapid embryonic wound healing in vertebrate and invertebrate species.

Published

2018

28. Polarized E-cadherin endocytosis directs actomyosin remodeling during embryonic wound repair

Author

Miranda V. Hunter, Dong-Hoon Lee, Rodrigo Fernandez-Gonzalez, and Tony J. C. Harris

Subjects

Dynamins, animal structures, Green Fluorescent Proteins, Endocytic cycle, macromolecular substances, Endocytosis, Time-Lapse Imaging, Clathrin, Article, Epithelium, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, Animals, Calcium Signaling, Research Articles, Actin, 030304 developmental biology, Dynamin, Wound Healing, 0303 health sciences, Microscopy, Video, integumentary system, biology, ADP-Ribosylation Factors, Cadherin, Actomyosin, Cell Biology, musculoskeletal system, Cadherins, Actin cytoskeleton, Cell biology, Actin Cytoskeleton, Drosophila melanogaster, ADP-Ribosylation Factor 6, biology.protein, Wound healing, 030217 neurology & neurosurgery

Abstract

Clathrin, dynamin, and ARF6 accumulate around wounds in Drosophila embryos in a calcium- and actomyosin-dependent manner and drive polarized E-cadherin endocytosis, which is necessary for actomyosin remodeling during wound repair., Embryonic epithelia have a remarkable ability to rapidly repair wounds. A supracellular actomyosin cable around the wound coordinates cellular movements and promotes wound closure. Actomyosin cable formation is accompanied by junctional rearrangements at the wound margin. We used in vivo time-lapse quantitative microscopy to show that clathrin, dynamin, and the ADP-ribosylation factor 6, three components of the endocytic machinery, accumulate around wounds in Drosophila melanogaster embryos in a process that requires calcium signaling and actomyosin contractility. Blocking endocytosis with pharmacological or genetic approaches disrupted wound repair. The defect in wound closure was accompanied by impaired removal of E-cadherin from the wound edge and defective actomyosin cable assembly. E-cadherin overexpression also resulted in reduced actin accumulation around wounds and slower wound closure. Reducing E-cadherin levels in embryos in which endocytosis was blocked rescued actin localization to the wound margin. Our results demonstrate a central role for endocytosis in wound healing and indicate that polarized E-cadherin endocytosis is necessary for actomyosin remodeling during embryonic wound repair.

Published

2015

29. An in vitro model of tissue boundary formation for dissecting the contribution of different boundary forming mechanisms

Author

Sahar Javaherian, Benjamin Slater, Teresa Zulueta-Coarasa, Rodrigo Fernandez-Gonzalez, Alison P. McGuigan, and Elisa D'Arcangelo

Subjects

Membrane Fluidity, Biophysics, Boundary (topology), Cell Enlargement, Biology, Mechanical tension, Models, Biological, Biochemistry, Cell Line, Cell size, In vitro model, Cell Movement, Cell Adhesion, Morphogenesis, Cell separation, Humans, Cell adhesion, Cell Size, Focal Adhesions, Epithelial Cells, Anatomy, Coculture Techniques, Stress, Mechanical, Boundary formation, Biological system, Function (biology)

Abstract

During development and in adult tissues separation of phenotypically distinct cell populations is necessary to ensure proper organization and function of tissues and organs. Various phenomena, such as differential adhesion, differential mechanical tension and cell-cell repulsion, are proposed to cause boundary formation. Moreover, emerging evidence suggests that interplay between multiple such phenomena can underlie boundary formation. Boundary-forming mechanisms are commonly studied in vivo in complex embryo models or in vitro using simple model systems not reflective of in vivo boundary complexity. To better elucidate the interplay between multiple boundary formation mechanism, there is therefore a need for more relevant in vitro model systems that allow quantitative and concomitant studies of the multiple changes in cell/tissue behaviour that lead to boundary establishment. Here, we develop such a model using patterned co-cultures of two cell populations. Using a set of quantitative tools, we demonstrate that our approach allows us to study the mechanisms underlying boundary formation. We demonstrate that in our specific system differential mechanical tension and modulation of migratory behavior of cells accompany boundary formation. The design of our in vitro model system will allow researchers to obtain quantitative, integrative mechanistic data facilitating a faster and more thorough understanding of the fundamental principles underlying boundary formation.

Published

2015

30. Shape of my heart: Cell-cell adhesion and cytoskeletal dynamics during Drosophila cardiac morphogenesis

Author

Christopher McFaul and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Heart morphogenesis, animal structures, Heart development, Organogenesis, fungi, Embryo, Heart, Cell Biology, Biology, biology.organism_classification, Cell biology, Adherens junction, 03 medical and health sciences, 030104 developmental biology, Cell Adhesion, Morphogenesis, Animals, Drosophila Proteins, Humans, Drosophila melanogaster, Cytoskeleton, Cell adhesion, Drosophila

Abstract

The fruit fly Drosophila melanogaster has recently emerged as an excellent system to investigate the genetics of cardiovascular development and disease. Drosophila provides an inexpensive and genetically-tractable in vivo system with a large number of conserved features. In addition, the Drosophila embryo is transparent, and thus amenable to time-lapse fluorescence microscopy, as well as biophysical and pharmacological manipulations. One of the conserved aspects of heart development from Drosophila to humans is the initial assembly of a tube. Here, we review the cellular behaviours and molecular dynamics important for the initial steps of heart morphogenesis in Drosophila, with particular emphasis on the cell-cell adhesion and cytoskeletal networks that cardiac precursors use to move, coordinate their migration, interact with other tissues and eventually sculpt a beating heart.

Published

2017

31. Coordinating cell movements in vivo: junctional and cytoskeletal dynamics lead the way

Author

Miranda V. Hunter and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Wound Healing, Cell, Morphogenesis, Motility, Apical constriction, Cell Biology, Actomyosin, Biology, Microtubules, Cell biology, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Microtubule, Cell Movement, medicine, Cell Adhesion, Animals, Humans, Cell adhesion, Cytoskeleton, Wound healing

Abstract

Collective cell movements drive embryonic development and tissue repair, and can cause disease. However, the mechanisms that coordinate the migration of groups of cells in vivo are unclear. Cells generate, transmit and sense mechanical forces to align their movements. Therefore, the machinery used by cells to generate force (cytoskeleton) and to transmit and sense mechanical signals (cell-cell adhesion) is critical for collective movement. Here, we review the components and organization of the cytoskeletal and cell-cell adhesive machineries, and how they are organized to promote collective cell movements in living animals. We discuss the signals that orchestrate molecular rearrangements necessary for coordinated cell motility, and we provide specific examples of movements both in the plane of the tissue (wound healing) and perpendicular to that plane (apical constriction).

Published

2017

32. Automated multidimensional image analysis reveals a role for Abl in embryonic wound repair

Author

Teresa Zulueta-Coarasa, Eun J. Lee, Masako Tamada, and Rodrigo Fernandez-Gonzalez

Subjects

Embryo, Nonmammalian, Biology, Models, Biological, Filamentous actin, Automation, Image Processing, Computer-Assisted, Animals, Pseudopodia, Proto-Oncogene Proteins c-abl, Cytoskeleton, Molecular Biology, beta Catenin, Actin, Wound Healing, Microscopy, Confocal, ABL, integumentary system, Reproducibility of Results, Embryonic stem cell, Actins, Cell biology, Multicellular organism, Drosophila melanogaster, Cell Tracking, Wound healing, Algorithms, Developmental Biology, Genetic screen

Abstract

The embryonic epidermis displays a remarkable ability to repair wounds rapidly. Embryonic wound repair is driven by the evolutionary conserved redistribution of cytoskeletal and junctional proteins around the wound. Drosophila has emerged as a model to screen for factors implicated in wound closure. However, genetic screens have been limited by the use of manual analysis methods. We introduce MEDUSA, a novel image-analysis tool for the automated quantification of multicellular and molecular dynamics from time-lapse confocal microscopy data. We validate MEDUSA by quantifying wound closure in Drosophila embryos, and we show that the results of our automated analysis are comparable to analysis by manual delineation and tracking of the wounds, while significantly reducing the processing time. We demonstrate that MEDUSA can also be applied to the investigation of cellular behaviors in three and four dimensions. Using MEDUSA, we find that the conserved nonreceptor tyrosine kinase Abelson (Abl) contributes to rapid embryonic wound closure. We demonstrate that Abl plays a role in the organization of filamentous actin and the redistribution of the junctional protein β-catenin at the wound margin during embryonic wound repair. Finally, we discuss different models for the role of Abl in the regulation of actin architecture and adhesion dynamics at the wound margin.

Published

2014

33. Oriented Cell Division: The Pull of the Pole

Author

Gordana Scepanovic and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, Cell division, Developmental cell, Cell Biology, Orientation (graph theory), Biology, General Biochemistry, Genetics and Molecular Biology, Spindle apparatus, 03 medical and health sciences, 030104 developmental biology, Biophysics, book.journal, Cell shape, Molecular Biology, book, Developmental Biology

Abstract

Cells are thought to divide along their longest axis. Now, two studies in Developmental Cell (Scarpa et al., 2018) and EMBO Journal (Finegan et al., 2018) reveal that in many instances, cell division orientation in vivo is not determined by cell shape, but rather by local anisotropies in cell mechanics.

Published

2018

34. Wounded cells drive rapid epidermal repair in the earlyDrosophilaembryo

Author

Jennifer A. Zallen and Rodrigo Fernandez-Gonzalez

Subjects

Force generation, Embryo, Nonmammalian, animal structures, Medial cortex, macromolecular substances, Biology, Epithelium, Re-Epithelialization, Nonmuscle myosin, medicine, Animals, Molecular Biology, Cytoskeleton, Actin, Myosin Type II, Wound Healing, integumentary system, Embryo, Actomyosin, Articles, Cell Biology, Anatomy, musculoskeletal system, Protein subcellular localization prediction, Actins, Cell biology, Drosophila melanogaster, medicine.anatomical_structure, Epidermis, Wound healing

Abstract

In early Drosophila embryos, wound closure is driven by the apical constriction of the wounded cells, which assemble actomyosin networks that lose actin and myosin as they contract. In late embryos, wound closure is mediated by the cells around the wound, which assemble an actomyosin purse string that contracts with constant actomyosin levels., Epithelial tissues are protective barriers that display a remarkable ability to repair wounds. Wound repair is often associated with an accumulation of actin and nonmuscle myosin II around the wound, forming a purse string. The role of actomyosin networks in generating mechanical force during wound repair is not well understood. Here we investigate the mechanisms of force generation during wound repair in the epidermis of early and late Drosophila embryos. We find that wound closure is faster in early embryos, where, in addition to a purse string around the wound, actomyosin networks at the medial cortex of the wounded cells contribute to rapid wound repair. Laser ablation demonstrates that both medial and purse-string actomyosin networks generate contractile force. Quantitative analysis of protein localization dynamics during wound closure indicates that the rapid contraction of medial actomyosin structures during wound repair in early embryos involves disassembly of the actomyosin network. By contrast, actomyosin purse strings in late embryos contract more slowly in a mechanism that involves network condensation. We propose that the combined action of two force-generating structures—a medial actomyosin network and an actomyosin purse string—contributes to the increased efficiency of wound repair in the early embryo.

Published

2013

35. Gastrulation: Cell Polarity Comes Full Circle

Author

Miranda V. Hunter and Rodrigo Fernandez-Gonzalez

Subjects

Mesoderm, animal structures, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), health care facilities, manpower, and services, media_common.quotation_subject, education, Embryogenesis, Biology, General Biochemistry, Genetics and Molecular Biology, Cell biology, Gastrulation, medicine.anatomical_structure, Cell polarity, medicine, Spatial localization, General Agricultural and Biological Sciences, Internalization, health care economics and organizations, media_common

Abstract

SummaryThe bending and internalization of tissues during embryonic development is a conserved process driven by dramatic cell-shape changes. A recent study details the molecules required for mesoderm internalization in Drosophila and their unique spatial localization pattern.

Published

2013

36. Automated cell tracking identifies mechanically-oriented cell divisions during Drosophila axis elongation

Author

Gang Wang, Christopher McFaul, Christopher M. Yip, Miranda V. Hunter, Rodrigo Fernandez-Gonzalez, and Michael F.Z. Wang

Subjects

0301 basic medicine, animal structures, Cell division, Cell, Morphogenesis, Embryo, Anatomy, Biology, Time-lapse microscopy, law.invention, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Confocal microscopy, law, medicine, Molecular Biology, Process (anatomy), Axis elongation, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Embryos extend their anterior-posterior (AP) axis in a conserved process known as axis elongation. Drosophila axis elongation occurs in an epithelial monolayer, the germband, and is driven by cell intercalation, cell shape changes, and oriented cell divisions at the posterior germband. Anterior germband cells also divide during axis elongation. We developed image analysis and pattern-recognition methods to track dividing cells from confocal microscopy movies in a generally applicable approach. Mesectoderm cells, forming the ventral midline, divided parallel to the AP axis, while lateral cells displayed a uniform distribution of division orientations. Mesectoderm cells did not intercalate and sustained increased AP strain before cell division. After division, mesectoderm cell density increased along the AP axis, thus relieving strain. We used laser ablation to isolate mesectoderm cells from the influence of other tissues. Uncoupling the mesectoderm from intercalating cells did not affect cell division orientation. Conversely, separating the mesectoderm from the anterior and posterior poles of the embryo resulted in uniformly oriented divisions. Our data suggest that mesectoderm cells align their division angle to reduce strain caused by mechanical forces along the AP axis of the embryo.

Published

2017

37. Tension regulates myosin dynamics during

Author

Anna B, Kobb, Teresa, Zulueta-Coarasa, and Rodrigo, Fernandez-Gonzalez

Subjects

Myosin Type II, Wound Healing, Drosophila melanogaster, Embryo, Nonmammalian, Protein Stability, Animals, Drosophila Proteins, Phosphorylation, Biomechanical Phenomena

Abstract

Embryos repair epithelial wounds rapidly in a process driven by collective cell movements. Upon wounding, actin and the molecular motor non-muscle myosin II are redistributed in the cells adjacent to the wound, forming a supracellular purse string around the lesion. Purse string contraction coordinates cell movements and drives rapid wound closure. By using fluorescence recovery after photobleaching in

Published

2016

38. Automated cell tracking identifies mechanically oriented cell divisions during

Author

Michael F Z, Wang, Miranda V, Hunter, Gang, Wang, Christopher, McFaul, Christopher M, Yip, and Rodrigo, Fernandez-Gonzalez

Subjects

Mesoderm, Automation, Drosophila melanogaster, Cell Tracking, Ectoderm, Animals, Cell Count, Cell Shape, Cell Division, Biomechanical Phenomena, Body Patterning

Abstract

Embryos extend their anterior-posterior (AP) axis in a conserved process known as axis elongation.

Published

2016

39. Modeling cell intercalation duringDrosophilagermband extension

Author

Lim C. Siang, James J. Feng, and Rodrigo Fernandez-Gonzalez

Subjects

Models, Molecular, 0301 basic medicine, Embryo, Nonmammalian, Intercalation (chemistry), Cell, Biophysics, Myosins, Cell junction, 03 medical and health sciences, Structural Biology, Posterior midgut invagination, Cell polarity, Planar cell polarity, Myosin, medicine, Animals, Molecular Biology, Deformation (mechanics), Chemistry, Cell Polarity, Epithelial Cells, Cell Biology, Biomechanical Phenomena, Drosophila melanogaster, 030104 developmental biology, medicine.anatomical_structure

Abstract

Germband extension during Drosophila development is primarily driven by cell intercalation, which involves three key components: planar cell polarity, anisotropic myosin contractile forces on cellular junctions, and cellular deformation and movement. Prior experimental work probed each of these factors in depth, but the connection between them remains unclear. This paper presents an integrated chemomechanical model that combines the three factors into a coherent mathematical framework for studying cell intercalation in the germband tissue. The model produces the planar cell polarization of key proteins, including Rho-kinase, Bazooka and myosin, the development of anisotropic contractile forces, and subsequent cell deformation and rearrangement. Cell intercalation occurs through T1 transitions among four neighboring cells and rosettes involving six cells. Such six-cell rosettes entail stronger myosin-based contractile forces, and on average produce a moderately larger amount of germband extension than the T1 transitions. The resolution of T1 and rosettes is driven by contractile forces on junctions anterior and posterior to the assembly as well as the pulling force of the medial myosin in the anterior and posterior cells. The global stretching due to posterior midgut invagination also plays a minor role. These model predictions are in reasonable agreement with experimental observations.

Published

2018

40. Rho-Kinase Directs Bazooka/Par-3 Planar Polarity during Drosophila Axis Elongation

Author

Dene L. Farrell, Sérgio Simões, Ori Weitz, Rodrigo Fernandez-Gonzalez, Jennifer A. Zallen, Masako Tamada, and J. Todd Blankenship

Subjects

Male, Embryo, Nonmammalian, animal structures, Membrane lipids, Blotting, Western, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Animals, Genetically Modified, Immunoenzyme Techniques, Adherens junction, Cell polarity, Myosin, Cell cortex, Animals, Drosophila Proteins, RNA, Messenger, Transgenes, Phosphorylation, Molecular Biology, Rho-associated protein kinase, Axis elongation, Protein Kinase C, Body Patterning, Cell Nucleus, Myosin Type II, rho-Associated Kinases, Reverse Transcriptase Polymerase Chain Reaction, Intracellular Signaling Peptides and Proteins, Cell Polarity, Gene Expression Regulation, Developmental, Cell Biology, Molecular biology, Cell biology, Drosophila melanogaster, Female, Drosophila Protein, Developmental Biology

Abstract

SummaryCell rearrangements shape the Drosophila embryo via spatially regulated changes in cell shape and adhesion. We show that Bazooka/Par-3 (Baz) is required for the planar polarized distribution of myosin II and adherens junction proteins and polarized intercalary behavior is disrupted in baz mutants. The myosin II activator Rho-kinase is asymmetrically enriched at the anterior and posterior borders of intercalating cells in a pattern complementary to Baz. Loss of Rho-kinase results in expansion of the Baz domain, and activated Rho-kinase is sufficient to exclude Baz from the cortex. The planar polarized distribution of Baz requires its C-terminal domain. Rho-kinase can phosphorylate this domain and inhibit its interaction with phosphoinositide membrane lipids, suggesting a mechanism by which Rho-kinase could regulate Baz association with the cell cortex. These results demonstrate that Rho-kinase plays an instructive role in planar polarity by targeting Baz/Par-3 and myosin II to complementary cortical domains.

Published

2010

41. Collision of Expanding Actin Caps with Actomyosin Borders for Cortical Bending and Mitotic Rounding in a Syncytium

Author

Yixie Zhang, Tony J. C. Harris, Rodrigo Fernandez-Gonzalez, Tao Jiang, and Jessica C. Yu

Subjects

0301 basic medicine, Embryo, Nonmammalian, animal structures, Spindle Apparatus, macromolecular substances, Biology, Ingression, Giant Cells, Microtubules, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Myosin, medicine, Animals, Drosophila Proteins, Molecular Biology, Metaphase, Mitosis, Actin, Syncytium, Cell Membrane, Actomyosin, Cell Biology, Actins, Drosophila melanogaster, 030104 developmental biology, medicine.anatomical_structure, Cytoplasm, Biophysics, Nucleus, Developmental Biology

Abstract

The early Drosophila embryo is a large syncytial cell that compartmentalizes mitotic spindles with furrows. Before furrow ingression, an Arp2/3 actin cap forms above each nucleus and is encircled by actomyosin. We investigated how these networks transform a flat cortex into a honeycomb-like compartmental array. The growing caps circularize and ingress upon meeting their actomyosin borders, which become the furrow base. Genetic perturbations indicate that the caps physically displace their borders and, reciprocally, that the borders resist and circularize their caps. These interactions create an actomyosin cortex arrayed with circular caps. The Rac-GEF Sponge, Rac-GTP, Arp3, and actin coat the caps as a growing material that can drive cortical bending for initial furrow ingression. Additionally, laser ablations indicate that actomyosin contraction squeezes the cytoplasm, producing counterforces that swell the caps. Thus, Arp2/3 caps form clearances of the actomyosin cortex and control buckling and swelling of these clearances for metaphase compartmentalization.

Published

2018

42. Myosin II Dynamics Are Regulated by Tension in Intercalating Cells

Author

Jens-Christian Röper, Jennifer A. Zallen, Sérgio Simões, Rodrigo Fernandez-Gonzalez, and Suzanne Eaton

Subjects

Embryo, Nonmammalian, Morphogenesis, DEVBIO, macromolecular substances, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Contractility, Myosin head, Myosin, Molecular motor, Animals, Molecular Biology, Axis elongation, Genetics, Myosin Type II, Fluorescence recovery after photobleaching, Gene Expression Regulation, Developmental, Cell Biology, Actomyosin, Drosophila melanogaster, Muscle Tonus, Biophysics, CELLBIO, Elongation, Developmental Biology

Abstract

SummaryAxis elongation in Drosophila occurs through polarized cell rearrangements driven by actomyosin contractility. Myosin II promotes neighbor exchange through the contraction of single cell boundaries, while the contraction of myosin II structures spanning multiple pairs of cells leads to rosette formation. Here we show that multicellular actomyosin cables form at a higher frequency than expected by chance, indicating that cable assembly is an active process. Multicellular cables are sites of increased mechanical tension as measured by laser ablation. Fluorescence recovery after photobleaching experiments show that myosin II is stabilized at the cortex in regions of increased tension. Myosin II is recruited in response to an ectopic force and relieving tension leads to a rapid loss of myosin, indicating that tension is necessary and sufficient for cortical myosin localization. These results demonstrate that myosin II dynamics are regulated by tension in a positive feedback loop that leads to multicellular actomyosin cable formation and efficient tissue elongation.

Published

2009

43. Author response: Local mechanical forces promote polarized junctional assembly and axis elongation in Drosophila

Author

Jessica C. Yu and Rodrigo Fernandez-Gonzalez

Subjects

Physics, biology, Drosophila (subgenus), biology.organism_classification, Axis elongation, Cell biology

Published

2015

44. Laser ablation to investigate cell and tissue mechanics in vivo

Author

Teresa Zulueta-Coarasa and Rodrigo Fernandez-Gonzalez

Subjects

Mechanobiology, Materials science, medicine.anatomical_structure, Laser ablation, In vivo, Cell, medicine, Nanotechnology, Tissue mechanics, Tissue formation, Cell mechanics, Axis elongation, Biomedical engineering

Published

2015

45. High-throughput analysis of multispectral images of breast cancer tissue

Author

U. Adiga, C.O. de Solorzano, Ravi Malladi, and Rodrigo Fernandez-Gonzalez

Subjects

Pathology, medicine.medical_specialty, Information Storage and Retrieval, Breast Neoplasms, Biology, Bioinformatics, Sensitivity and Specificity, Pattern Recognition, Automated, Breast cancer, Artificial Intelligence, Image Interpretation, Computer-Assisted, Tumor Cells, Cultured, medicine, Animals, Humans, Segmentation, Image analysis, Ultrasonography, Cell Nucleus, Reproducibility of Results, Cancer, Image segmentation, Ductal carcinoma, Image Enhancement, medicine.disease, Computer Graphics and Computer-Aided Design, Primary tumor, Spectrometry, Fluorescence, Microscopy, Fluorescence, Breast disease, Algorithms, Software

Abstract

Statistical analysis of genetic changes within cell nuclei that are far from the primary tumor would help determine whether such changes have occurred prior to tumor invasion. To determine whether the gene amplification in cells is morphologically and/or genetically related to the primary tumor requires quantitative evaluation of a large number of cell nuclei from continuous meaningful structures such as milk-ducts, tumors, etc., located relatively far from the primary tumor. To address this issue, we have designed an integrated image analysis software system for high-throughput segmentation of nuclei. Filters such as Beltrami flow-based reaction-diffusion, directional diffusion, etc., were used to pre-process the images resulting in a better segmentation. The accurate shape of the segmented nucleus was recovered using an iterative "shrink-wrap" operation. The study of two cases of ductal carcinoma in situ in breast tissue supports the biological observation regarding the existence of a preferential intraductal invasion, and therefore a common origin, between the primary tumor and the gene amplification in the cell-nuclei lining the ductal structures in the breast.

Published

2006

46. A tool for the quantitative spatial analysis of complex cellular systems

Author

Mary Helen Barcellos-Hoff, Rodrigo Fernandez-Gonzalez, and Carlos Ortiz-de-Solorzano

Subjects

Relative neighborhood graph, Population, Complex system, Information Storage and Retrieval, Spatial distribution, Bioinformatics, Models, Biological, Sensitivity and Specificity, Pattern Recognition, Automated, Mice, Imaging, Three-Dimensional, Mammary Glands, Animal, Artificial Intelligence, Image Interpretation, Computer-Assisted, Animals, Humans, Computer Simulation, Mammary Glands, Human, education, Cells, Cultured, Topology (chemistry), education.field_of_study, Microscopy, Confocal, Reproducibility of Results, Graph theory, Image Enhancement, Computer Graphics and Computer-Aided Design, Quantitative analysis (finance), Spatial ecology, Biological system, Algorithms, Software

Abstract

Spatial events largely determine the biology of cells, tissues, and organs. In this paper, we present a tool for the quantitative spatial analysis of heterogeneous cell populations, and we show experimental validation of this tool using both artificial and real (mammary gland tissue) data, in two and three dimensions. We present the refined relative neighborhood graph as a means to establish neighborhood between cells in an image while modeling the topology of the tissue. Then, we introduce the M function as a method to quantitatively evaluate the existence of spatial patterns within one cell population or the relationship between the spatial distributions of multiple cell populations. Finally, we show a number of examples that demonstrate the feasibility of our approach.

Published

2005

47. Automated Image Analysis Reveals Spatially-Regulated Cell Division Dynamics during Drosophila Axis Elongation

Author

Rodrigo Fernandez-Gonzalez and Michael F.Z. Wang

Subjects

Cell division, Cell, Biophysics, Embryo, Anatomy, Biology, Rotation, law.invention, Cell biology, medicine.anatomical_structure, Confocal microscopy, law, medicine, Equidistant, Process (anatomy), Axis elongation

Abstract

Axis elongation is a conserved process in which embryos extend their head-to-tail or anterior-posterior (AP) axis. Defective axis elongation results in developmental malformations, including spina bifida and anencephaly. In Drosophila, axis elongation occurs in an epithelial monolayer known as the germband. Cells on the anterior end of the germband divide, but the contribution of anterior cell divisions to axis elongation is unknown. We used spinning disk confocal microscopy to investigate anterior cell divisions during germband extension in Drosophila embryos expressing fluorescently-tagged proteins that label cell outlines. To automate the quantification of cell division dynamics, we developed an image analysis algorithm to segment and track cells from confocal microscopy sequences. One seed point was identified per cell in the first image of the sequence using an adaptive threshold. Seeds were interactively edited when necessary. The watershed algorithm was used to expand seeds until they delineated cells. Seeds were automatically transferred to the next image in the sequence, correcting for cell movement by using the local cross-correlation maximum between consecutive images to shift the seeds. Dividing cells were automatically detected based on their increased area and circularity, and final dumbbell morphology. Seeds corresponding to dividing cells were split into two equidistant seeds along the longest cell axis. We found that 84.3±4.0% of anterior cells immediately adjacent to the ventral midline (ventral cells) divided within 45° of the AP axis. In contrast, anterior cells away from the midline (lateral cells) divided at random orientations. Cell shape analysis revealed that ventral cells rotated 32.5±3.0° before cell division to align their longest axis with the AP axis, while lateral cells did not undergo a similar rotation. Together, our data strongly suggest that the mechanisms that promote oriented cell division are spatially regulated.

Published

2016

48. Feeling the Squeeze: Live-Cell Extrusion Limits Cell Density in Epithelia

Author

Jennifer A. Zallen and Rodrigo Fernandez-Gonzalez

Subjects

medicine.anatomical_structure, Biochemistry, Genetics and Molecular Biology(all), Cell density, Cell, medicine, Extrusion, Biology, Bioinformatics, General Biochemistry, Genetics and Molecular Biology, Homeostasis, Epithelium, Cell deformation, Cell biology

Abstract

Tissues develop in confined volumes that can impose mechanical constraints on their growth, but it is unclear how cells respond to these limits to regulate tissue size and shape. Two papers show that overcrowding and cell deformation lead to the shedding of live cells to maintain homeostasis in epithelial cell sheets.

Published

2012

49. An Actomyosin-Arf-GEF Negative Feedback Loop for Tissue Elongation under Stress

Author

Dong-Hoon Lee, Teresa Zulueta-Coarasa, Rodrigo Fernandez-Gonzalez, Ashley E.E. Bruce, Janna A. Maier, Tony J. C. Harris, and Junior J. West

Subjects

0301 basic medicine, Embryo, Nonmammalian, Epiboly, Small G Protein, Biology, General Biochemistry, Genetics and Molecular Biology, Adherens junction, 03 medical and health sciences, GTP-Binding Protein Regulators, Live cell imaging, Animals, Drosophila Proteins, Guanine Nucleotide Exchange Factors, Zebrafish, Anatomy, Zebrafish Proteins, biology.organism_classification, Protein subcellular localization prediction, Dorsal closure, Drosophila melanogaster, 030104 developmental biology, Biophysics, Elongation, General Agricultural and Biological Sciences, Signal Transduction

Abstract

Summary In response to a pulling force, a material can elongate, hold fast, or fracture. During animal development, multi-cellular contraction of one region often stretches neighboring tissue. Such local contraction occurs by induced actomyosin activity, but molecular mechanisms are unknown for regulating the physical properties of connected tissue for elongation under stress. We show that cytohesins, and their Arf small G protein guanine nucleotide exchange activity, are required for tissues to elongate under stress during both Drosophila dorsal closure (DC) and zebrafish epiboly. In Drosophila , protein localization, laser ablation, and genetic interaction studies indicate that the cytohesin Steppke reduces tissue tension by inhibiting actomyosin activity at adherens junctions. Without Steppke, embryogenesis fails, with epidermal distortions and tears resulting from myosin misregulation. Remarkably, actomyosin network assembly is necessary and sufficient for local Steppke accumulation, where live imaging shows Steppke recruitment within minutes. This rapid negative feedback loop provides a molecular mechanism for attenuating the main tension generator of animal tissues. Such attenuation relaxes tissues and allows orderly elongation under stress.

Published

2017

50. Automated cell tracking identifies mechanically oriented cell divisions during Drosophila axis elongation

Author

Miranda V. Hunter, Michael F.Z. Wang, Gang Wang, Christopher McFaul, Christopher M. Yip, and Rodrigo Fernandez-Gonzalez

Subjects

0301 basic medicine, animal structures, Strain (chemistry), Cell division, Cell, Embryo, Cell Biology, Anatomy, Biology, Cell biology, law.invention, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Confocal microscopy, law, medicine, Cell tracking, Axis elongation, Process (anatomy)

Abstract

Embryos extend their anterior-posterior (AP) axis in a conserved process known as axis elongation. Drosophila axis elongation occurs in an epithelial monolayer, the germband, and is driven by cell intercalation, cell shape changes, and oriented cell divisions at the posterior germband. Anterior germband cells also divide during axis elongation. We developed image analysis and pattern-recognition methods to track dividing cells from confocal microscopy movies in a generally applicable approach. Mesectoderm cells, forming the ventral midline, divided parallel to the AP axis, while lateral cells displayed a uniform distribution of division orientations. Mesectoderm cells did not intercalate and sustained increased AP strain before cell division. After division, mesectoderm cell density increased along the AP axis, thus relieving strain. We used laser ablation to isolate mesectoderm cells from the influence of other tissues. Uncoupling the mesectoderm from intercalating cells did not affect cell division orientation. Conversely, separating the mesectoderm from the anterior and posterior poles of the embryo resulted in uniformly oriented divisions. Our data suggest that mesectoderm cells align their division angle to reduce strain caused by mechanical forces along the AP axis of the embryo.

Published

2017