Sequential Activation of Apical and Basolateral Contractility Drives Ascidian Endoderm Invagination

Sherrard, Kristin M.; Robin, François; Lemaire, Patrick; Munro, Edwin

doi:10.1016/j.cub.2010.06.075

Cited by 197 publications

(235 citation statements)

References 43 publications

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“…Additionally, Baz and PAR-6/ aPKC regulate distinct phases of the myosin assembly disassembly cycle during amnioserosa apical constriction during Drosophila dorsal closure (David et al 2010). Although, it is possible that apical constriction alone may not be sufficient to induce sheet folding because integration of both circumapical and lateral contraction of the endoderm was required to drive early ascidian gastrulation (Sherrard et al 2010). Because NM-II can be recruited to the cortex by tension and by protein interactions the involvement of polarity proteins in apical constriction is particularly germane (Choi and Sokol 2009;Hava et al 2009;David et al 2010).…”

Section: Cytoskeletal Control Of Tissue Architecturementioning

confidence: 99%

Phosphoinositides in Cell Architecture

Shewan

Eastburn²,

Mostov

2011

Cold Spring Harbor Perspectives in Biology

169

159

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Inositol phospholipids have been implicated in almost all aspects of cellular physiology including spatiotemporal regulation of cellular signaling, acquisition of cellular polarity, specification of membrane identity, cytoskeletal dynamics, and regulation of cellular adhesion, motility, and cytokinesis. In this review, we examine the critical role phosphoinositides play in these processes to execute the establishment and maintenance of cellular architecture. Epithelial tissues perform essential barrier and transport functions in almost all major organs. Key to their development and function is the establishment of epithelial cell polarity. We place a special emphasis on highlighting recent studies demonstrating phosphoinositide regulation of epithelial cell polarity and how individual cells use phosphoinositides to further organize into epithelial tissues.P hosphoinositides (PIs) are essential components of cellular membranes in eukaryotes. Though these specialized lipids comprise less than 1% of the cellular lipid cohort, they play key roles in many fundamental biological processes (Di Paolo and De Camilli 2006;Saarikangas et al. 2010). PIs possess such far ranging roles by serving as specialized membrane docking sites for effectors of numerous cellular signal transduction cascades. PIs also serve as precursors of lipid second messengers. They are concentrated on the cytosolic face of cellular membranes (Fig. 1A) and rapidly diffuse within the plane of the membrane. Reversible phosphorylation of the myo-inositol head group of phosphatidylinositol (PtdIns) at positions 3, 4, and 5 (Fig. 1B) gives rise to the seven PI isoforms identified in eukaryotic cells. PtdIns(4)P and PtdIns(4,5)P 2 are constitutively present in membranes and comprise the largest pool of cellular PIs, whereas PtdIns(3,4,5)P 3 is essentially undetectable in most types of unstimulated cells (Lemmon and Ferguson 2000;Saarikangas et al. 2010).The spatiotemporally regulated production and turnover of phosphoinositides is crucial for localized PI signaling and function. Numerous phosphatidylinositol kinases and phosphatases are involved in regulating the metabolism of the various PI isoforms (Fig. 1)

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Section: Cytoskeletal Control Of Tissue Architecturementioning

confidence: 99%

Phosphoinositides in Cell Architecture

Shewan

Eastburn²,

Mostov

2011

Cold Spring Harbor Perspectives in Biology

169

159

View full text Add to dashboard Cite

show abstract

“…Apical constriction of populations of cells that maintain cell-cell adhesion can bend and fold epithelial tissues, in some cases transforming flat epithelial sheets into threedimensional structures, such as tubes (Lewis, 1947;Hardin and Keller, 1988;Alvarez and Navascués, 1990;Kam et al, 1991;Sweeton et al, 1991;Wallingford et al, 2013). In these cases, changes in the geometry and mechanics of constituent cells appear to impact global tissue shape directly (Odell et al, 1981;Escudero et al, 2007;Sherrard et al, 2010;Eiraku et al, 2011). Apical constriction of individual cells can contribute to cell ingression from epithelial tissues, sometimes as a step in an epithelialmesenchymal transition (EMT) (Anstrom, 1992;Nance and Priess, 2002;Harrell and Goldstein, 2011;Williams et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Apical constriction: themes and variations on a cellular mechanism driving morphogenesis

2014

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Apical constriction is a cell shape change that promotes tissue remodeling in a variety of homeostatic and developmental contexts, including gastrulation in many organisms and neural tube formation in vertebrates. In recent years, progress has been made towards understanding how the distinct cell biological processes that together drive apical constriction are coordinated. These processes include the contraction of actin-myosin networks, which generates force, and the attachment of actin networks to cell-cell junctions, which allows forces to be transmitted between cells. Different cell types regulate contractility and adhesion in unique ways, resulting in apical constriction with varying dynamics and subcellular organizations, as well as a variety of resulting tissue shape changes. Understanding both the common themes and the variations in apical constriction mechanisms promises to provide insight into the mechanics that underlie tissue morphogenesis.

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“…Bao et al, 2006) and ascidian (e.g. Sherrard et al, 2010). Most of these studies have tracked cells over time, relating cell movements to morphogenesis, but very few have associated changes in cell shape with tissue morphogenesis.…”

Section: Introductionmentioning

confidence: 99%

Whole population cell analysis of a landmark-rich mammalian epithelium reveals multiple elongation mechanisms

et al. 2013

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Tissue elongation is a fundamental component of developing and regenerating systems. Although localised proliferation is an important mechanism for tissue elongation, potentially important contributions of other elongation mechanisms, specifically cell shape change, orientated cell division and cell rearrangement, are rarely considered or quantified, particularly in mammalian systems. Their quantification, together with proliferation, provides a rigorous framework for the analysis of elongation. The mammalian palatal epithelium is a landmark-rich tissue, marked by regularly spaced ridges (rugae), making it an excellent model in which to analyse the contributions of cellular processes to directional tissue growth. We captured confocal stacks of entire fixed mouse palate epithelia throughout the midgestation growth period, labelled with membrane, nuclear and cell proliferation markers and segmented all cells (up to ~20,000 per palate), allowing the quantification of cell shape and proliferation. Using the rugae as landmarks, these measures revealed that the socalled growth zone is a region of proliferation that is intermittently elevated at ruga initiation. The distribution of oriented cell division suggests that it is not a driver of tissue elongation, whereas cell shape analysis revealed that both elongation of cells leaving the growth zone and apico-basal cell rearrangements do contribute significantly to directional growth. Quantitative comparison of elongation processes indicated that proliferation contributes most to elongation at the growth zone, but cell shape change and rearrangement contribute as much as 40% of total elongation. We have demonstrated the utility of an approach to analysing the cellular mechanisms underlying tissue elongation in mammalian tissues. It should be broadly applied to higher-resolution analysis of links between genotypes and malformation phenotypes.

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Sequential Activation of Apical and Basolateral Contractility Drives Ascidian Endoderm Invagination

Cited by 197 publications

References 43 publications

Phosphoinositides in Cell Architecture

Phosphoinositides in Cell Architecture

Apical constriction: themes and variations on a cellular mechanism driving morphogenesis

Whole population cell analysis of a landmark-rich mammalian epithelium reveals multiple elongation mechanisms

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