Leader-cell-driven epithelial sheet fingering

A culture method for neural crest cells of mouse embryo is described. Trunk neural tubes were dissected from 9-day mouse embryos and explanted in culture dishes. The developmental potential of mouse neural crest in vitro was shown to be essentially similar to that of avian neural crest. In the mouse, however, melanocytes always appeared in association with the epithelial sheet close to the explant. Neural crest cells surrounding the epithelial sheet, which probably migrated from the neural tubes in the early culture phase, never differentiated into melanocytes. The bimodal behaviour of mouse crest cells seems to be due to the heterogenous potency of the crest cells and the interaction of these cells with the surrounding microenvironment. This culture system is well suited for various experiments including the analysis of gene control on the differentiation of neural crest cells.

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Hydra regeneration from recombined ectodermal and endodermal tissue. I. Epibolic ectodermal spreading is driven by cell intercalation

Journal of Cell Science ◽

10.1242/jcs.109.4.763 ◽

1996 ◽

Vol 109 (4) ◽

pp. 763-772 ◽

Cited By ~ 1

Author(s):

Y. Kishimoto ◽

M. Murate ◽

T. Sugiyama

Keyword(s):

Contact Surface ◽

Single Cells ◽

Cell Interaction ◽

Inhibitory Effect ◽

Cell Aggregates ◽

Signaling Mechanism ◽

Initial Adhesion ◽

Radial Cell ◽

Epithelial Sheet ◽

Cell Intercalation

Cell-cell interaction and cell rearrangement were examined in the process of epithelial sheet formation during regeneration from hydra cell aggregates. The ectodermal and endodermal epithelial cell layers of Hydra magnipapillata were separated by procaine treatment. Each of the separated layers was then dissociated into single cells and reaggregated to produce ectodermal or endodermal cell aggregates. When the two aggregate types were recombined, a firm adhesion was quickly established between them. This was followed by a vigorous spreading of the ectodermal epithelial cells as a thin layer over the endoderm in a manner similar to the ‘epiboly’ in some developing embryos. Cell movement in this spreading process was examined using fluorescent dyestaining. It revealed that cells initially located in the inside of the aggregate migrated to intercalate themselves among the cells originally present in the contact surface. This radial cell intercalation took place continuously in the contact surface of both the ectodermal and endodermal aggregates, and produced a rapid growth of the contact surface, eventually leading to complete envelopment of the entire endoderm by the ectoderm. The resulting structure was a small sphere having a two-layered epithelial organization as in normal hydra. This sphere regenerated into a complete hydra a few days later. A tryptic extract of hydra membrane fraction specifically inhibited the ectodermal spreading over the endoderm, but not the initial adhesion or the later regeneration processes. These observations suggest that radial cell intercalation at the contact surface plays a crucial role in producing ectodermal spreading and establishing epithelial sheet organization in the recombined aggregates. The intercalation is presumably activated by a signal exchange through the contact surface. The inhibitory effect of the membrane extract suggests that it contains a factor that is involved in some way in this signaling mechanism.

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Hydra regeneration from recombined ectodermal and endodermal tissue. II. Differential stability in the ectodermal and endodermal epithelial organization

Journal of Cell Science ◽

10.1242/jcs.110.16.1919 ◽

1997 ◽

Vol 110 (16) ◽

pp. 1919-1934

Author(s):

M. Murate ◽

Y. Kishimoto ◽

T. Sugiyama ◽

T. Fujisawa ◽

H. Takahashi-Iwanaga ◽

...

Keyword(s):

Epithelial Cells ◽

Structural Changes ◽

Light And Electron Microscopy ◽

Single Layer ◽

Strong Interactions ◽

High Plasticity ◽

Spherical Structure ◽

Epithelial Sheet ◽

Differential Stability ◽

Tissue Recombination

Hydra tissue consists of the ectodermal and the endodermal layers. When the two layers were separated by procaine treatment and then recombined, the ectodermal epithelial cells spread as a single cell layer over the endoderm as in epiboly in vertebrate embryogenesis, and the resultant spherical structure subsequently regenerated into a complete hydra. In this study, light and electron microscopy were used to examine the structural changes which took place in the cells and tissue during this epibolic ectodermal spreading process. Within a few hours after tissue recombination, the endoderm underwent dramatic changes; it lost its epithelial sheet organization, and turned into a mass of irregularly shaped cells without the apical-basal cell polarity initially present. In contrast, the ectoderm maintained its basic epithelial sheet organization as it spread over the endoderm. Later, the endodermal epithelial cells reorganized themselves into a single-layered epithelial sheet underneath the spreading ectodermal layer. The resultant spherical structure consisted of a single layer of ectodermal epithelial cells outside, a single layer of endodermal epithelial cells inside, and an empty cavity in the center as in normal hydra tissue. This structure regenerated into hydra in the following days. These and other observations demonstrate that the two-layered epithelial sheet organization is highly dynamic, and that its stability is maintained by strong interactions between the two layers in normal hydra. It is suggested that this dynamic nature of the hydra tissue, particularly the high plasticity of the endodermal epithelial sheet organization, may be an important element for the high regenerative capacity of this organism.

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Neurulation and the cortical tractor model for epithelial folding

Development ◽

10.1242/dev.96.1.19 ◽

1986 ◽

Vol 96 (1) ◽

pp. 19-49

Author(s):

Antone G. Jacobson ◽

George F. Oster ◽

Garrett M. Odell ◽

Louis Y. Cheng

Keyword(s):

Epithelial Cells ◽

Computer Simulations ◽

Dynamic Structure ◽

Mesenchymal Cells ◽

Epithelial Morphogenesis ◽

Apical Region ◽

New Model ◽

Epithelial Sheet ◽

Epithelial Sheets ◽

Placode Formation

We present here a new model for epithelial morphogenesis, which we call the ‘cortical tractor model’. This model assumes that the motile activities of epithelial cells are similar to those of mesenchymal cells, with the added constraint that the cells in an epithelial sheet remain attached at their apical circumference. In particular, we assert that there is a time-averaged motion of cortical cytoplasm which flows from the basal and lateral surfaces to the apical region. This cortical flow carries with it membrane and adhesive structures that are inserted basally and resorbed apically. Thus the apical seal that characterizes epithelial sheets is a dynamic structure: it is continuously created by the cortical flow which piles up components near where they are recycled in the apical region. By use of mechanical analyses and computer simulations we demonstrate that the cortical tractor motion can reproduce a variety of epithelial motions, including columnarization (placode formation), imagination and rolling. It also provides a mechanism for driving active cell rearrangements within an epithelial sheet, while maintaining the integrity of the apical seal. Active repacking of epithelial cells appears to drive a number of morphogenetic processes. Neurulation in amphibians provides an example of a process in which all four of the above morphogenetic movements appear to play a role. Here we reexamine the process of neurulation in amphibians in light of the cortical tractor model, and find that it provides an integrated view of this important morphogenetic process.

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Leader cell PLCγ1 activation during keratinocyte collective migration is induced by EGFR localization and clustering

Bioengineering & Translational Medicine ◽

10.1002/btm2.10138 ◽

2019 ◽

Vol 4 (3) ◽

Cited By ~ 1

Author(s):

Chloe S. Kim ◽

Xinhai Yang ◽

Sarah Jacobsen ◽

Kristyn S. Masters ◽

Pamela K. Kreeger

Keyword(s):

Collective Migration ◽

Leader Cell

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The Drosophila Shark tyrosine kinase is required for embryonic dorsal closure

Genes & Development ◽

10.1101/gad.14.5.604 ◽

2000 ◽

Vol 14 (5) ◽

pp. 604-614

Author(s):

Rafael Fernandez ◽

Fumitaka Takahashi ◽

Zhao Liu ◽

Ruth Steward ◽

David Stein ◽

...

Keyword(s):

Tyrosine Kinase ◽

Leading Edge ◽

Dorsal Closure ◽

Kinase Gene ◽

Dorsal Midline ◽

Jnk Signaling ◽

Amino Terminal ◽

Tyrosine Kinase Gene ◽

Epithelial Sheet ◽

Jnk Signaling Pathway

Dorsal closure (DC) in the Drosophila embryo requires the coordinated interaction of two different functional domains of the epidermal cell layer—the leading edge (LE) and the lateral epidermis. In response to activation of a conserved c-Jun amino-terminal kinase (JNK) signaling module, the dorsal-most layer of cells, which constitute the LE of the stretching epithelial sheet, secrete Dpp, a member of the TGFβ superfamily. Dpp and other LE cell-derived signaling molecules stimulate the bilateral dorsal elongation of cells of the dorsolateral epidermis over the underlaying amnioserosa and the eventual fusion of their LEs along the dorsal midline. We have found that flies bearing a Shark tyrosine kinase gene mutation,shark1, exhibit a DC-defective phenotype. Dpp fails to be expressed in shark1 mutant LE cells. Consistent with these observations, epidermal-specific reconstitution ofshark function or overexpression of an activated form of c-Jun in the shark1 mutant background, rescues the DC defect. Thus, Shark regulates the JNK signaling pathway leading to Dpp expression in LE cells. Furthermore, constitutive activation of the Dpp pathway throughout the epidermis fails to rescue theshark1 DC defect, suggesting that Shark may function in additional pathways in the LE and/or lateral epithelium.

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