Your search keyword '"Daiki Umetsu"' showing total 14 results

1. Cell mechanics and cell-cell recognition controls by Toll-like receptors in tissue morphogenesis and homeostasis

Author

Daiki Umetsu

Subjects

Insect Science, Toll-Like Receptors, Morphogenesis, Animals, Homeostasis, Drosophila, Immunity, Innate, Signal Transduction

Abstract

Signal transduction by the Toll-like receptors (TLRs) is conserved and essential for innate immunity in metazoans. The founding member of the TLR family

Published

2022

2. Sample Preparation and Imaging of the Pupal Drosophila Abdominal Epidermis

Author

Daiki, Umetsu

Subjects

Epidermal Cells, Morphogenesis, Pupa, Animals, Cell Polarity, Drosophila Proteins, Drosophila, Epidermis, Epithelium

Abstract

The epithelium is one of the best studied tissues for morphogenesis, pattern formation, cell polarity, cell division, cell competition, tumorigenesis, and metastatic behaviors. However, it has been challenging to analyze real-time cell interactions or cell dynamics within the epithelia under physiological conditions. The Drosophila pupal abdominal epidermis is a model system that allows to combine long-term real-time imaging under physiological conditions with the use of powerful Drosophila genetics tools. The abdominal epidermis displays a wide range of stereotypical characteristics of the epithelia and cellular behaviors including cell division, cell death, cell rearrangement, apical constriction, and apicobasal/planar polarity, making this tissue a first choice for the study of epithelial morphogenesis and relevant phenomena. In this chapter, I describe the staging and mounting of pupae and the live imaging of the abdominal epidermis. Moreover, methods to combine live imaging with mosaic analysis or drug injection will be presented. The long-term live imaging of the pupal abdominal epidermis is straightforward and opens up the possibility to analyze cell dynamics during epithelial morphogenesis at an unprecedented resolution.

Published

2022

3. Planar polarized contractile actomyosin networks in dynamic tissue morphogenesis

Author

Erina Kuranaga and Daiki Umetsu

Subjects

0301 basic medicine, Force generation, Tissue deformation, Collective behavior, Shape change, Morphogenesis, Actomyosin, Biology, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Planar, Genetics, Animals, Drosophila, 030217 neurology & neurosurgery, Body Patterning, Developmental Biology

Abstract

The complex shapes of animal bodies are constructed through a sequence of simple physical interactions of constituent cells. Mechanical forces generated by cellular activities, such as division, death, shape change and rearrangement, drive tissue morphogenesis. By confining assembly or disassembly of actomyosin networks within the three-dimensional space of the cell, cells can localize forces to induce tissue deformation. Tissue-scale morphogenesis emerges from a collective behavior of cells that coordinates the force generation in space and time. Thus, the molecular mechanisms that govern the temporal and spatial regulation of forces in individual cells are elemental to organogenesis, and the tissue-scale coordination of forces generated by individual cells is key to determining the final shape of organs.

Published

2017

4. Reduction of endocytic activity accelerates cell elimination during tissue remodeling of the

Author

Shinichiro, Hoshika, Xiaofei, Sun, Erina, Kuranaga, and Daiki, Umetsu

Subjects

Gene Editing, Myosin Type II, Embryo, Nonmammalian, Cell Death, Metamorphosis, Biological, Gene Expression Regulation, Developmental, Adherens Junctions, Cadherins, Endocytosis, Epithelium, Animals, Genetically Modified, Caspases, Animals, Drosophila, CRISPR-Cas Systems, Epidermis

Abstract

Epithelial tissues undergo cell turnover both during development and for homeostatic maintenance. Cells that are no longer needed are quickly removed without compromising the barrier function of the tissue. During metamorphosis, insects undergo developmentally programmed tissue remodeling. However, the mechanisms that regulate this rapid tissue remodeling are not precisely understood. Here, we show that the temporal dynamics of endocytosis modulate physiological cell properties to prime larval epidermal cells for cell elimination. Endocytic activity gradually reduces as tissue remodeling progresses. This reduced endocytic activity accelerates cell elimination through the regulation of Myosin II subcellular reorganization, junctional E-cadherin levels, and caspase activation. Whereas the increased Myosin II dynamics accelerates cell elimination, E-cadherin plays a protective role against cell elimination. Reduced E-cadherin is involved in the amplification of caspase activation by forming a positive-feedback loop with caspase. These findings reveal the role of endocytosis in preventing cell elimination and in the cell-property switching initiated by the temporal dynamics of endocytic activity to achieve rapid cell elimination during tissue remodeling.

Published

2019

5. A local difference in Hedgehog signal transduction increases mechanical cell bond tension and biases cell intercalations along the Drosophila anteroposterior compartment boundary

Author

Maryam Aliee, Christian Dahmann, Frank Jülicher, Katrin Rudolf, Daiki Umetsu, and Liyuan Sui

Subjects

Cell signaling, Microscopy, Confocal, Tension (physics), Morphogenesis, Cell Communication, Anatomy, Biology, Cell sorting, engrailed, Biomechanical Phenomena, Living matter, Image Processing, Computer-Assisted, Biophysics, Animals, Drosophila Proteins, Wings, Animal, Compartment (development), Drosophila, Hedgehog Proteins, Signal transduction, Molecular Biology, Hedgehog, Signal Transduction, Developmental Biology

Abstract

Tissue organization requires the interplay between biochemical signaling and cellular force generation. The formation of straight boundaries separating cells with different fates into compartments is important for growth and patterning during tissue development. In the developing Drosophila wing disc, maintenance of the straight anteroposterior (AP) compartment boundary involves a local increase in mechanical tension at cell bonds along the boundary. The biochemical signals that regulate mechanical tension along the AP boundary, however, remain unknown. Here, we show that a local difference in Hedgehog signal transduction activity between anterior and posterior cells is necessary and sufficient to increase mechanical tension along the AP boundary. This difference in Hedgehog signal transduction is also required to bias cell rearrangements during cell intercalations to keep the characteristic straight shape of the AP boundary. Moreover, severing cell bonds along the AP boundary does not reduce tension at neighboring bonds, implying that active mechanical tension is upregulated, cell bond by cell bond. Finally, differences in the expression of the homeodomain-containing protein Engrailed also contribute to the straight shape of the AP boundary, independently of Hedgehog signal transduction and without modulating cell bond tension. Our data reveal a novel link between local differences in Hedgehog signal transduction and a local increase in active mechanical tension of cell bonds that biases junctional rearrangements. The large-scale shape of the AP boundary thus emerges from biochemical signals inducing patterns of active tension on cell bonds.

Published

2015

6. Inference of Cell Mechanics in Heterogeneous Epithelial Tissue Based on Multivariate Clone Shape Quantification

Author

Koichi Fujimoto, Daiki Umetsu, Alice Tsuboi, and Erina Kuranaga

Subjects

0301 basic medicine, tumor, vertex model, Cell, Clone (cell biology), Computational biology, Biology, medicine.disease_cause, 03 medical and health sciences, Cell and Developmental Biology, 0302 clinical medicine, cell mechanics, RNA interference, medicine, cell sorting, lcsh:QH301-705.5, cell mixing, Original Research, Genetics, PCA, Erythropoietin-producing hepatocellular (Eph) receptor, Cell Biology, Cell sorting, Multicellular organism, Imaginal disc, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), Drosophila, heterogeneity, Carcinogenesis, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Cell populations in multicellular organisms show genetic and non-genetic heterogeneity, even in undifferentiated tissues of multipotent cells during development and tumorigenesis. The heterogeneity causes difference of mechanical properties, such as, cell bond tension or adhesion, at the cell–cell interface, which determine the shape of clonal population boundaries via cell sorting or mixing. The boundary shape could alter the degree of cell–cell contacts and thus influence the physiological consequences of sorting or mixing at the boundary (e.g., tumor suppression or progression), suggesting that the cell mechanics could help clarify the physiology of heterogeneous tissues. While precise inference of mechanical tension loaded at each cell–cell contacts has been extensively developed, there has been little progress on how to distinguish the population-boundary geometry and identify the cause of geometry in heterogeneous tissues. We developed a pipeline by combining multivariate analysis of clone shape with tissue mechanical simulations. We examined clones with four different genotypes within Drosophila wing imaginal discs: wild-type, tartan (trn) overexpression, hibris (hbs) overexpression, and Eph RNAi. Although the clones were previously known to exhibit smoothed or convoluted morphologies, their mechanical properties were unknown. By applying a multivariate analysis to multiple criteria used to quantify the clone shapes based on individual cell shapes, we found the optimal criteria to distinguish not only among the four genotypes, but also non-genetic heterogeneity from genetic one. The efficient segregation of clone shape enabled us to quantitatively compare experimental data with tissue mechanical simulations. As a result, we identified the mechanical basis contributed to clone shape of distinct genotypes. The present pipeline will promote the understanding of the functions of mechanical interactions in heterogeneous tissue in a non-invasive manner.

Published

2017

7. Reduction of endocytic activity accelerates cell elimination during tissue remodeling of the Drosophila epidermal epithelium.

Author

Shinichiro Hoshika, Xiaofei Sun, Erina Kuranaga, and Daiki Umetsu

Subjects

TISSUE remodeling, ENDOCYTOSIS, DROSOPHILA, EPITHELIUM, CELLS, MYOSIN

Abstract

Epithelial tissues undergo cell turnover both during development and for homeostatic maintenance. Cells that are no longer needed are quickly removed without compromising the barrier function of the tissue. Duringmetamorphosis, insects undergo developmentally programmed tissue remodeling. However, the mechanisms that regulate this rapid tissue remodeling are not precisely understood. Here, we show that the temporal dynamics of endocytosis modulate physiological cell properties to prime larval epidermal cells for cell elimination. Endocytic activity gradually reduces as tissue remodeling progresses. This reduced endocytic activity accelerates cell elimination through the regulation of Myosin II subcellular reorganization, junctional E-cadherin levels, and caspase activation. Whereas the increased Myosin II dynamics accelerates cell elimination, E-cadherin plays a protective role against cell elimination. Reduced E-cadherin is involved in the amplification of caspase activation by forming a positive-feedback loop with caspase. These findings reveal the role of endocytosis in preventing cell elimination and in the cell-property switching initiated by the temporal dynamics of endocytic activity to achieve rapid cell elimination during tissue remodeling. [ABSTRACT FROM AUTHOR]

Published

2020

8. Compartment boundaries

Author

Christian Dahmann and Daiki Umetsu

Subjects

Extra View, Muscle Proteins, Pattern formation, Animal development, Biology, Mechanical tension, Cell biology, Imaginal Discs, Insect Science, Tension (geology), Animals, Compartment (development), Drosophila, Stress, Mechanical, Signal transduction, Process (anatomy)

Abstract

The subdivision of proliferating tissues into groups of non-intermingling sets of cells, termed compartments, is a common process of animal development. Signaling between adjacent compartments induces the local expression of morphogens that pattern the surrounding tissue. Sharp and straight boundaries between compartments stabilize the source of such morphogens during tissue growth and, thus, are of crucial importance for pattern formation. Signaling pathways required to maintain compartment boundaries have been identified, yet the physical mechanisms that maintain compartment boundaries remained elusive. Recent data now show that a local increase in actomyosin-based mechanical tension on cell bonds is vital for maintaining compartment boundaries in Drosophila.

Published

2010

9. Drosophilaoptic lobe neuroblasts triggered by a wave of proneural gene expression that is negatively regulated by JAK/STAT

Author

Tetsuya Tabata, Tetsuo Yasugi, Satoshi Murakami, Daiki Umetsu, and Makoto Sato

Subjects

Topographic map (neuroanatomy), Models, Neurological, Central nervous system, Genes, Insect, Biology, Animals, Genetically Modified, Neuroblast, medicine, Animals, Drosophila Proteins, Molecular Biology, Embryonic Stem Cells, Medulla, Janus Kinases, Neurons, Gene Expression Regulation, Developmental, food and beverages, JAK-STAT signaling pathway, Cell Differentiation, Optic Nerve, Anatomy, Neural stem cell, Cell biology, Neuroepithelial cell, STAT Transcription Factors, medicine.anatomical_structure, embryonic structures, Drosophila, Neuron, Signal Transduction, Developmental Biology

Abstract

Neural stem cells called neuroblasts (NBs) generate a variety of neuronal and glial cells in the central nervous system of the Drosophilaembryo. These NBs, few in number, are selected from a field of neuroepithelial(NE) cells. In the optic lobe of the third instar larva, all NE cells of the outer optic anlage (OOA) develop into either NBs that generate the medulla neurons or lamina neuron precursors of the adult visual system. The number of lamina and medulla neurons must be precisely regulated because photoreceptor neurons project their axons directly to corresponding lamina or medulla neurons. Here, we show that expression of the proneural protein Lethal of scute [L(1)sc] signals the transition of NE cells to NBs in the OOA. L(1)sc expression is transient, progressing in a synchronized and ordered `proneural wave' that sweeps toward more lateral NEs. l(1)sc expression is sufficient to induce NBs and is necessary for timely onset of NB differentiation. Thus, proneural wave precedes and induces transition of NE cells to NBs. Unpaired (Upd), the ligand for the JAK/STAT signaling pathway,is expressed in the most lateral NE cells. JAK/STAT signaling negatively regulates proneural wave progression and controls the number of NBs in the optic lobe. Our findings suggest that NBs might be balanced with the number of lamina neurons by JAK/STAT regulation of proneural wave progression, thereby providing the developmental basis for the formation of a precise topographic map in the visual center.

Published

2008

10. Focal adhesion kinase controls morphogenesis of the Drosophilaoptic stalk

Author

Daiki Umetsu, Satoshi Murakami, Tetsuya Tabata, Yuko Maeyama, Makoto Sato, and Shoko Yoshida

Subjects

Male, Integrin beta Chains, Integrin, Morphogenesis, Retina, Photoreceptor cell, Focal adhesion, Cell Movement, medicine, Animals, Drosophila Proteins, Optic stalk, Axon, Molecular Biology, Focal Adhesions, biology, Cell morphogenesis, GTPase-Activating Proteins, Cell migration, Axons, Protein Structure, Tertiary, Cell biology, medicine.anatomical_structure, Focal Adhesion Kinase 1, Larva, Mutation, biology.protein, Drosophila, Photoreceptor Cells, Invertebrate, Neuroglia, Signal Transduction, Developmental Biology

Abstract

Photoreceptor cell axons (R axons) innervate optic ganglia in the Drosophila brain through the tubular optic stalk. This structure consists of surface glia (SG) and forms independently of R axon projection. In a screen for genes involved in optic stalk formation, we identified Fak56D encoding a Drosophila homolog of mammalian focal adhesion kinase (FAK). FAK is a main component of the focal adhesion signaling that regulates various cellular events, including cell migration and morphology. We show that Fak56D mutation causes severe disruption of the optic stalk structure. These phenotypes were completely rescued by Fak56D transgene expression in the SG cells but not in photoreceptor cells. Moreover, Fak56D genetically interacts with myospheroid, which encodes an integrin β subunit. In addition,we found that CdGAPr is also required for optic stalk formation and genetically interacts with Fak56D. CdGAPr encodes a GTPase-activating domain that is homologous to that of mammalian CdGAP, which functions in focal adhesion signaling. Hence the optic stalk is a simple monolayered structure that can serve as an ideal system for studying glial cell morphogenesis and the developmental role(s) of focal adhesion signaling.

Published

2007

11. Signals and mechanics shaping compartment boundaries in Drosophila

Author

Daiki, Umetsu and Christian, Dahmann

Subjects

Intercellular Junctions, Animals, Drosophila, Models, Biological, Biomechanical Phenomena, Body Patterning, Cell Proliferation, Signal Transduction

Abstract

During animal development groups of cells with similar fates and functions often stay together and separate from cells with different fates. An example for this cellular behavior is the formation of compartments, groups of cells with similar fates that are separated by sharp boundaries from neighboring groups of cells. Compartments play important roles during patterning by serving as units of growth and gene expression. Boundaries between compartments are associated with organizers that secrete signaling molecules instructing growth and differentiation throughout the tissue. The straight shape of the boundary between compartments is important for maintaining the position and shape of the organizer and thus for precise patterning. The straight shape of compartment boundaries, however, is challenged by cell divisions and cell intercalations that take place in many developing tissues. Early work established a role for selector genes and signaling pathways in setting up and keeping boundaries straight. Recent work in Drosophila has now begun to further unravel the physical and cellular mechanisms that maintain compartment boundaries. Key to the separation of compartments is a local increase of actomyosin-dependent mechanical tension at cell junctions along the boundary. Increased mechanical tension acts as a barrier to cell mixing during cell division and influences cell rearrangements during cell intercalations along the compartment boundary in a way that the straight shape of the boundary is maintained. An important question for the future is how the signaling pathways that maintain the straight shape of compartment boundaries control mechanical tension along these boundaries.

Published

2014

12. Increased cell bond tension governs cell sorting at the Drosophila anteroposterior compartment boundary

Author

Thomas J. Widmann, Jonas Ranft, Katharina P. Landsberg, Christian Dahmann, Thomas Bittig, Daiki Umetsu, Reza Farhadifar, Frank Jülicher, and Amani Said

Subjects

Cell division, Agricultural and Biological Sciences(all), Effector, Tension (physics), Biochemistry, Genetics and Molecular Biology(all), Cell, DEVBIO, Anatomy, Cell sorting, Biology, Cell morphology, General Biochemistry, Genetics and Molecular Biology, medicine.anatomical_structure, Myosin, medicine, Biophysics, Compartment (development), Animals, Wings, Animal, CELLBIO, Drosophila, General Agricultural and Biological Sciences, Body Patterning

Abstract

Summary Subdividing proliferating tissues into compartments is an evolutionarily conserved strategy of animal development [1–6]. Signals across boundaries between compartments can result in local expression of secreted proteins organizing growth and patterning of tissues [1–6]. Sharp and straight interfaces between compartments are crucial for stabilizing the position of such organizers and therefore for precise implementation of body plans. Maintaining boundaries in proliferating tissues requires mechanisms to counteract cell rearrangements caused by cell division; however, the nature of such mechanisms remains unclear. Here we quantitatively analyzed cell morphology and the response to the laser ablation of cell bonds in the vicinity of the anteroposterior compartment boundary in developing Drosophila wings. We found that mechanical tension is approximately 2.5-fold increased on cell bonds along this compartment boundary as compared to the remaining tissue. Cell bond tension is decreased in the presence of Y-27632 [7], an inhibitor of Rho-kinase whose main effector is Myosin II [8]. Simulations using a vertex model [9] demonstrate that a 2.5-fold increase in local cell bond tension suffices to guide the rearrangement of cells after cell division to maintain compartment boundaries. Our results provide a physical mechanism in which the local increase in Myosin II-dependent cell bond tension directs cell sorting at compartment boundaries.

Published

2009

13. The highly ordered assembly of retinal axons and their synaptic partners is regulated by Hedgehog/Single-minded in the Drosophila visual system

Author

Tetsuya Tabata, Satoshi Murakami, Daiki Umetsu, and Makoto Sato

Subjects

Retinal Ganglion Cells, Lamina, Biology, chemistry.chemical_compound, Postsynaptic potential, medicine, Basic Helix-Loop-Helix Transcription Factors, Animals, Drosophila Proteins, Hedgehog Proteins, Receptors, Invertebrate Peptide, Molecular Biology, Transcription factor, Hedgehog, Nuclear Proteins, Retinal, Anatomy, Axons, Ganglion, ErbB Receptors, medicine.anatomical_structure, nervous system, chemistry, Cell bodies, Larva, Mutation, Synapses, Drosophila, Photoreceptor Cells, Invertebrate, Neuroscience, Protein Kinases, Developmental Biology

Abstract

During development of the Drosophila visual center, photoreceptor cells extend their axons (R axons) to the lamina ganglion layer, and trigger proliferation and differentiation of synaptic partners (lamina neurons) by delivering the inductive signal Hedgehog (Hh). This inductive mechanism helps to establish an orderly arrangement of connections between the R axons and lamina neurons, termed a retinotopic map because it results in positioning the lamina neurons in close vicinity to the corresponding R axons. We found that the bHLH-PAS transcription factor Single-minded (Sim) is induced by Hh in the lamina neurons and is required for the association of lamina neurons with R axons. In sim mutant brains, lamina neurons undergo the first step of differentiation but fail to associate with R axons. As a result, lamina neurons are set aside from R axons. The data reveal a novel mechanism for regulation of the interaction between axons and neuronal cell bodies that establishes precise neuronal networks.

Published

2006

14. A local difference in Hedgehog signal transduction increases mechanical cell bond tension and biases cell intercalations along the Drosophila anteroposterior compartment boundary.

Author

Rudolf, Katrin, Daiki Umetsu, Aliee, Maryam, Liyuan Sui, Jülicher, Frank, and Dahmann, Christian

Subjects

*CELLULAR signal transduction, *HEDGEHOG signaling proteins, *CELLULAR mechanics, *HEDGEHOG genetics, *INTERCALATION reactions, *DROSOPHILA genetics, *INSECTS

Abstract

Tissue organization requires the interplay between biochemical signaling and cellular force generation. The formation of straight boundaries separating cells with different fates into compartments is important for growth and patterning during tissue development. In the developing Drosophila wing disc, maintenance of the straight anteroposterior (AP) compartment boundary involves a local increase in mechanical tension at cell bonds along the boundary. The biochemical signals that regulate mechanical tension along the AP boundary, however, remain unknown. Here, we show that a local difference in Hedgehog signal transduction activity between anterior and posterior cells is necessary and sufficient to increase mechanical tension along the AP boundary. This difference in Hedgehog signal transduction is also required to bias cell rearrangements during cell intercalations to keep the characteristic straight shape of the AP boundary. Moreover, severing cell bonds along the AP boundary does not reduce tension at neighboring bonds, implying that active mechanical tension is upregulated, cell bond by cell bond. Finally, differences in the expression of the homeodomain-containing protein Engrailed also contribute to the straight shape of the AP boundary, independently of Hedgehog signal transduction and without modulating cell bond tension. Our data reveal a novel link between local differences in Hedgehog signal transduction and a local increase in active mechanical tension of cell bonds that biases junctional rearrangements. The large-scale shape of the AP boundary thus emerges from biochemical signals inducing patterns of active tension on cell bonds. [ABSTRACT FROM AUTHOR]

Published

2015