Apical constriction is driven by a pulsatile apical myosin network in delaminating Drosophila neuroblasts

An, Yanru; Xue, Guosheng; Shaobo, Yang; Deng, Mingxi; Zhou, Xiaowei; Yu, Weichuan; Ishibashi, Toyotaka; Zhang, Lei; Yan, Yan

doi:10.1242/dev.150763

Cited by 52 publications

(64 citation statements)

References 46 publications

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“…In 46% of apical constriction phases, the closest maximal accumulation of medial MyoII in time preceded apical reduction within 45 sec ( Fig.2L). Together, these data suggest that pulses of apical-medial MyoII drive apical constriction in epi-NSCs, as previously observed in several other epithelia (Martin et al, 2009;Martin and Goldstein, 2014), including in the embryonic neuroectoderm during NSC delamination (Simões et al, 2017;An et al, 2017).…”

Section: Apical Constriction By Medial Myosin In Epi-nscssupporting

confidence: 83%

“…Each NSC has a unique spatial identity that is provided in part by the segmentation genes (Urbach and Technau, 2003). As neuroectodermal cells become specified as NSCs, they undergo apical constriction driven by a pulsatile actomyosin meshwork (Simões et al, 2017;An et al, 2017;Sawyer et al, 2010;Martin and Goldstein, 2014). Concomitantly, Adherens Junctions (AJ) are disassembled as E-cadherin (E-cad) is removed from the apical-lateral membrane, leading to NSC ingression (Simões et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Neuralized regulates a travelling wave of Epithelium-to-Neural Stem Cell morphogenesis inDrosophila

Shard

Luna-Escalante

Schweisguth

2020

Preprint

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Many tissues are produced during development by specialized progenitor cells emanating from epithelia via an Epithelial-to-Mesenchymal Transition (EMT). Most studies have so far focused on cases involving single or isolated groups of cells. Here we describe an EMT-like process that requires tissue level coordination. This EMT-like process occurs along a continuous front in the Drosophila optic lobe neuroepithelium to produce neural stem cells (NSCs). We find that emerging NSCs remain epithelial and apically constrict before dividing asymmetrically to produce neurons. Apical constriction is associated with contractile myosin pulses and requires the E3 ubiquitin ligase Neuralized and RhoGEF3. Neuralized downregulates the apical protein Crumbs via its interaction with Stardust. Disrupting the regulation of Crumbs by Neuralized led to defects in apical constriction and junctional myosin accumulation, and to imprecision in the integration of emerging NSCs into the transition front. Neuralized therefore appears to mechanically couple NSC fate acquisition with cell-cell rearrangement to promote smooth progression of the differentiation front. excitable reaction-diffusion mechanism. Accordingly, an activator signal, the Epidermal Growth Factor (EGF) Spitz, spreads in the NE by diffusion and self-induction and triggers a negative feed-back via the production of a non-diffusible inhibitor, i.e. the proneural factor Lethal of scute (L'sc) that inhibits the production of active Spitz by promoting NE-to-NSC

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Section: Apical Constriction By Medial Myosin In Epi-nscssupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Neuralized regulates a travelling wave of Epithelium-to-Neural Stem Cell morphogenesis inDrosophila

Shard

Luna-Escalante

Schweisguth

2020

Preprint

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“…NB delamination is driven by a pulsatile, actomyosin network localized apically in NB precursors, with Rho signaling important for medial myosin accumulation (An et al, 2017). This is in contrast to the removal of apoptotic or live cells by non-autonomous Rho signaling and multicellular actomyosin ring assembly (Figure 1).…”

Section: A Force For Good: Cell Extrusion In Development and Tissue Hmentioning

confidence: 99%

Cell Extrusion: A Stress-Responsive Force for Good or Evil in Epithelial Homeostasis

2018

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Epithelial tissues robustly respond to internal and external stressors via dynamic cellular rearrangements. Cell extrusion acts as a key regulator of epithelial homeostasis by removing apoptotic cells, orchestrating morphogenesis, and mediating competitive cellular battles during tumorigenesis. Here, we delineate the diverse functions of cell extrusion during development and disease. We emphasize the expanding role for apoptotic cell extrusion in exerting morphogenetic forces, as well as the strong intersection of cell extrusion with cell competition, a homeostatic mechanism that eliminates aberrant or unfit cells. While cell competition and extrusion can exert potent, tumor-suppressive effects, dysregulation of either critical homeostatic program can fuel cancer progression.

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“…From this we hypothesised that expression of Notch intra not only reduces the number of neuroblasts, but also relieves the ventral epidermis from morphogenetic stress due to reduced neuroblast delamination. It has recently been shown that neuroblast delamination requires increased actomyosin activity ( An et al, 2017 ; Simões et al, 2017 ). In addition, studies from our lab have shown that Crb negatively regulates myosin contractility in the amnioserosa, thereby ensuring, among others, the maintenance of a proper adhesion belt ( Flores-Benitez and Knust, 2015 ).…”

Section: Resultsmentioning

confidence: 99%

A dual role of the extracellular domain ofDrosophilaCrumbs for morphogenesis of the embryonic neuroectoderm

Das

Knust

2018

Biology Open

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Epithelia are highly polarised tissues and several highly conserved polarity protein complexes serve to establish and maintain polarity. The transmembrane protein Crumbs (Crb), the central component of the Crb protein complex, is required, among others, for the maintenance of polarity in most epithelia in the Drosophila embryo. However, different epithelia exhibit different phenotypic severity upon loss of crb. Using a transgenomic approach allowed us to more accurately define the role of crb in different epithelia. In particular, we provide evidence that the loss of epithelial tissue integrity in the ventral epidermis of crb mutant embryos is due to impaired actomyosin activity and an excess number of neuroblasts. We demonstrate that the intracellular domain of Crb could only partially rescue this phenotype, while it is able to completely restore tissue integrity in other epithelia. Based on these results we suggest a dual role of the extracellular domain of Crb in the ventral neuroectoderm. First, it is required for apical enrichment of the Crb protein, which in turn regulates actomyosin activity and thereby ensures tissue integrity; and second, the extracellular domain of Crb stabilises the Notch receptor and thereby ensures proper Notch signalling and specification of the correct number of neuroblasts.

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Apical constriction is driven by a pulsatile apical myosin network in delaminating Drosophila neuroblasts

Cited by 52 publications

References 46 publications

Neuralized regulates a travelling wave of Epithelium-to-Neural Stem Cell morphogenesis inDrosophila

Neuralized regulates a travelling wave of Epithelium-to-Neural Stem Cell morphogenesis inDrosophila

Cell Extrusion: A Stress-Responsive Force for Good or Evil in Epithelial Homeostasis

A dual role of the extracellular domain ofDrosophilaCrumbs for morphogenesis of the embryonic neuroectoderm

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