Tip-Cell Migration Controls Stalk-Cell Intercalation during Drosophila Tracheal Tube Elongation

AbstractThe Drosophila tracheal system consists of an interconnected network of monolayered epithelial tubes that ensures oxygen transport in the larval and adult body. During tracheal dorsal branch (DB) development, individual DBs elongate as a cluster of cells, led by tip cells at the front and trailing cells in the rear. Branch elongation is accompanied by extensive cell intercalation and cell lengthening of the trailing stalk cells. While cell intercalation is governed by Myosin II (MyoII)-dependent forces during tissue elongation in the Drosophila embryo leading to germ-band extension, it remained unclear whether MyoII plays a similar active role during tracheal branch elongation and intercalation. Here, we use a nanobody-based approach to selectively knock-down MyoII in tracheal cells. Our data shows that despite the depletion of MyoII function, tip cells migration and stalk cell intercalation (SCI) proceeds at a normal rate. Therefore, our data confirms a model in which DB elongation and SCI in the trachea occurs as a consequence of tip cell migration, which produces the necessary forces for the branching process.Summary statementBranch elongation during Drosophila tracheal development mechanistically resembles MyoII-independent collective cell migration; tensile forces resulting from tip cell migration are reduced by cell elongation and passive stalk cell intercalation.AbbreviationsDBDorsal branchDCDorsal closureE-CadE-CadherinGBEGerm-band extensionMRLCMyosin regulatory light chainMyoIIMyosin IISCIstalk cell intercalationSqhSpaghetti squashSxllSex lethalTCTip cellTrTracheomere

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Convergent extension: using collective cell migration and cell intercalation to shape embryos

Development ◽

10.1242/dev.073007 ◽

2012 ◽

Vol 139 (21) ◽

pp. 3897-3904 ◽

Cited By ~ 128

Author(s):

M. Tada ◽

C.-P. Heisenberg

Keyword(s):

Cell Migration ◽

Collective Cell Migration ◽

Convergent Extension ◽

Cell Intercalation

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Identification and functional analysis of endothelial tip cell–enriched genes

Blood ◽

10.1182/blood-2010-02-270819 ◽

2010 ◽

Vol 116 (19) ◽

pp. 4025-4033 ◽

Cited By ~ 231

Author(s):

Raquel del Toro ◽

Claudia Prahst ◽

Thomas Mathivet ◽

Geraldine Siegfried ◽

Joshua S. Kaminker ◽

...

Keyword(s):

Endothelial Cells ◽

Basement Membrane ◽

Cell Fate ◽

Stalk Cell ◽

Matrix Remodeling ◽

Retinal Endothelial Cells ◽

Tip Cell ◽

Mouse Mutants ◽

Membrane Components ◽

Tip Cells

Abstract Sprouting of developing blood vessels is mediated by specialized motile endothelial cells localized at the tips of growing capillaries. Following behind the tip cells, endothelial stalk cells form the capillary lumen and proliferate. Expression of the Notch ligand Delta-like-4 (Dll4) in tip cells suppresses tip cell fate in neighboring stalk cells via Notch signaling. In DLL4+/− mouse mutants, most retinal endothelial cells display morphologic features of tip cells. We hypothesized that these mouse mutants could be used to isolate tip cells and so to determine their genetic repertoire. Using transcriptome analysis of retinal endothelial cells isolated from DLL4+/− and wild-type mice, we identified 3 clusters of tip cell–enriched genes, encoding extracellular matrix degrading enzymes, basement membrane components, and secreted molecules. Secreted molecules endothelial-specific molecule 1, angiopoietin 2, and apelin bind to cognate receptors on endothelial stalk cells. Knockout mice and zebrafish morpholino knockdown of apelin showed delayed angiogenesis and reduced proliferation of stalk cells expressing the apelin receptor APJ. Thus, tip cells may regulate angiogenesis via matrix remodeling, production of basement membrane, and release of secreted molecules, some of which regulate stalk cell behavior.

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Tracheal tube fusion in Drosophila involves release of luminal exosomes from multivesicular bodies

10.1101/2021.08.22.457102 ◽

2021 ◽

Author(s):

Carolina Camelo ◽

Anna Koerte ◽

Thea Jacobs ◽

Peter Robin Hiesinger ◽

Stefan Luschnig

Keyword(s):

Tracheal Tube ◽

Extracellular Vesicles ◽

Multivesicular Bodies ◽

Tracheal Lumen ◽

Tracheal System ◽

Tip Cell ◽

Luminal Membrane ◽

Lysosome Related Organelles ◽

Tip Cells ◽

Development Of Organs

Fusion of endothelial or epithelial tubes is essential for the development of organs like the vertebrate vasculature or the insect tracheal system, but the mechanisms underlying the formation of tubular connections (anastomoses) are not well understood. Tracheal tube fusion in Drosophila is mediated by tip cells that transform into lumenized toroids to connect adjacent tubes. This process depends on the Munc13-4 orthologue Staccato (Stac), which localizes to tip-cell-specific lysosome-related organelles (LROs). We show that tracheal LROs display features of multivesicular bodies (MVBs) and that the tracheal lumen contains membranous extracellular vesicles (EVs), a subset of which carries Stac/Munc13-4 and is associated with tracheal anastomosis sites. The presence of LROs and luminal Stac-EVs depends on the tip-cell-specific GTPase Arl3, suggesting that Stac-EVs derive from fusion of MVBs with the luminal membrane in tip cells during anastomosis formation. The GTPases Rab27 and Rab35 cooperate downstream of Arl3 to promote Stac-MVB formation and tube fusion. We propose that Stac-MVBs act as membrane reservoirs that facilitate lumen fusion in tip cells, in a process regulated by Arl3, Rab27, Rab35, and Stac/Munc13-4.

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Faculty Opinions recommendation of YAP/TAZ-CDC42 signaling regulates vascular tip cell migration.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.731737114.793537584 ◽

2017 ◽

Author(s):

Jonathan Chernoff

Keyword(s):

Cell Migration ◽

Tip Cell

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Formation and anatomy of the prestalk zone of Dictyostelium

Development ◽

10.1242/dev.107.supplement.91 ◽

1989 ◽

Vol 107 (Supplement) ◽

pp. 91-97 ◽

Cited By ~ 2

Author(s):

J. G. Williams ◽

K. A. Jermyn ◽

K. T. Duffy

Keyword(s):

Extracellular Matrix ◽

Cell Migration ◽

Cell Types ◽

Matrix Proteins ◽

Anterior Region ◽

Stalk Cell ◽

Directed Cell Migration ◽

Pattern Forming ◽

Different Parts ◽

Primary Pattern

The pDd63 and pDd56 genes encode extracellular matrix proteins which, respectively, surround the migratory slug and mature stalk cells. Both genes are dependent for their expression upon, and rapidly induced by, DIF, the stalk cell inducer. Using these genes as cell-autonomous markers, we have defined three distinct kinds of ‘prestalk’ cells localized to different parts of the anterior region of the slug. At least one, and probably both, prestalk cell types initially differentiates at the base of the aggregate. The most abundant of the two prestalk cell types then migrates into the tip, the precursor of the prestalk zone which arises at the apex of the aggregate. Thus we believe that morphogenesis of the prestalk zone, the primary pattern-forming event in Dictyostelium development, involves a combination of positionally localized differentiation and directed cell migration. To account for the positionally localized differentiation of prestalk cells, we invoke the existence of gradients of the known antagonists of DIF — cAMP and NH3. We further suggest that differences in the motility of pstA and pstB cells might result from differences in their chemotactic responsiveness to cAMP signals propagated from the tip.

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The roles of cell migration and myofiber intercalation in patterning formation of the postmitotic myotome

Development ◽

10.1242/dev.129.11.2675 ◽

2002 ◽

Vol 129 (11) ◽

pp. 2675-2687 ◽

Cited By ~ 4

Author(s):

Nitza Kahane ◽

Yuval Cinnamon ◽

Chaya Kalcheim

Keyword(s):

Cell Migration ◽

Mesenchymal Cells ◽

Multiple Sources ◽

Lateral Direction ◽

Medial Side ◽

Cell Intercalation ◽

First Time ◽

New Evidence ◽

Second Wave

We have previously found that the postmitotic myotome is formed by two successive waves of myoblasts. A first wave of pioneer cells is generated from the dorsomedial region of epithelial somites. A second wave originates from all four edges of the dermomyotome but cells enter the myotome only from the rostral and caudal lips. We provide new evidence for the existence of these distinctive waves. We show for the first time that when the somite dissociates, pioneer myotomal progenitors migrate as mesenchymal cells from the medial side towards the rostral edge of the segment. Subsequently, they generate myofibers that elongate caudally. Pioneer myofiber differentiation then progresses in a medial-to-lateral direction with fibers reaching the lateralmost region of each segment. At later stages, pioneers participate in the formation of multinucleated fibers during secondary myogenesis by fusing with younger cells. We also demonstrate that subsequent to primary myotome formation by pioneers, growth occurs by uniform cell addition along the dorsoventral myotome. At this stage, the contributing cells arise from multiple sources as the myotome keeps growing even in the absence of the dorsomedial lip. Moreover, as opposed to suggestions that myotome growth is driven primarily and directly by the medial and lateral edges, we demonstrate that there is no direct fiber generation from the dorsomedial lip. Instead, we find that added fibers elongate from the extreme edges. Altogether, the integration between both myogenic waves results in an even pattern of dorsoventral growth of the myotome which is accounted for by progressive cell intercalation of second wave cells between preexisting pioneer fibers.

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