Luminal matrices: An inside view on organ morphogenesis

Luschnig, Stefan; Uv, Anne

doi:10.1016/j.yexcr.2013.09.010

Cited by 44 publications

(55 citation statements)

References 45 publications

(55 reference statements)

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“…It seems that aECM itself plays roles in systemic control and providing global cues for tube growth [42]. Tracheal cell secretion activities driving apical membrane expansion is regulated by a cell autonomous manner [16], suggesting that a mechanism must exist by which these cells sense the mechanical or geometrical state of the lumen and equalize membrane tension in each branch type such that a uniform tube diameter is maintained for the entire length of the tube.…”

Section: Mutual Interaction Of Cell and Aecmmentioning

confidence: 99%

Shaping of biological tubes by mechanical interaction of cell and extracellular matrix

Dong

Hayashi

2015

Current Opinion in Genetics & Development

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Section: Mutual Interaction Of Cell and Aecmmentioning

confidence: 99%

Shaping of biological tubes by mechanical interaction of cell and extracellular matrix

Dong

Hayashi

2015

Current Opinion in Genetics & Development

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“…Importantly, examples can be found in which if one way of lumen formation is blocked, then another mechanism begins to operate, showing the robust drive of epithelia to form lumina [96] (see also [72,73]). The detailed presentation of tubulogenetic mechanisms-additionally including the machinery of cell-cell and cell-extracellular matrix (ECM) interactions, the polarization of cells, cyst formation, luminogenesis, elongation, branching, as well as the role of tip cells or epithelial-mesenchymal and mesenchymal-epithelial transitions-falls beyond the scope of this paper; instead, I refer the reader to some excellent papers and the references therein [71][72][73][74]76,78,79,82,[88][89][90][91][92][93][94]97].…”

Section: Radially Symmetrical Internal Structuresmentioning

confidence: 99%

A new paradigm for animal symmetry

Holló¹

2015

Interface Focus.

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My aim in this article is to soften certain rigid concepts concerning the radial and bilateral symmetry of the animal body plan, and to offer a more flexible framework of thinking for them, based on recent understandings of how morphogenesis is regulated by the mosaically acting gene regulatory networks. Based on general principles of the genetic regulation of morphogenesis, it can be seen that the difference between the symmetry of the whole body and that of minor anatomical structures is only a question of a diverse timing during development. I propose that the animal genome, as such, is capable of expressing both radial and bilateral symmetries, and deploys them according to the functional requirements which must be satisfied by both the anatomical structure and body as a whole. Although it may seem paradoxical, this flexible view of symmetry, together with the idea that symmetry is strongly determined by function, bolsters the concept that the presence of the two main symmetries in the animal world is not due to chance: they are necessary biological patterns emerging in evolution.

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“…Blood pressure was reported to be essential for pushing the apical membranes of anastomosing tip cells towards the fusion point [9]. In Drosophila, the apical extracellular matrix of expanding tracheal tubes contains secreted proteins and a scaffold of chitin fibres, which are crucial for shaping the luminal membrane (reviewed in [80]). Luminal hydrostatic pressure and mechanical forces imposed by the chitin scaffold on the FC apical surface could also contribute to pushing the FC membrane inwards.…”

Section: Pushing and Pulling: Force Generation In Fusion Cellsmentioning

confidence: 99%

Tube fusion: Making connections in branched tubular networks

Caviglia

Luschnig

2014

Seminars in Cell & Developmental Biology

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Organs like the vertebrate vascular system and the insect tracheal system develop from separate primordia that undergo fusion events to form interconnected tubular networks. Although the correct pattern of tubular connections (anastomoses) in these organs is crucial for their normal function, the cellular and molecular mechanisms that govern tube fusion are only beginning to be understood. The process of tube fusion involves tip cell specification, cell-cell recognition and contact formation, selfavoidance, changes in cell shape and topology, lumen formation, and luminal membrane fusion. Significant insights into the underlying cellular machinery have been gained from genetic studies of tracheal tube fusion in Drosophila. Here, we summarize these findings and we highlight similarities and differences between tube fusion processes in the Drosophila tracheae and in the vertebrate vascular system. We integrate the findings from studies in vivo with the important mechanistic insights that have been gained from the analysis of tubulogenesis in cultured cells to propose a mechanistic model of tube fusion, aspects of which are likely to apply to diverse organs and organisms.

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Luminal matrices: An inside view on organ morphogenesis

Cited by 44 publications

References 45 publications

Shaping of biological tubes by mechanical interaction of cell and extracellular matrix

Shaping of biological tubes by mechanical interaction of cell and extracellular matrix

A new paradigm for animal symmetry

Tube fusion: Making connections in branched tubular networks

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