Rho-regulated Myosin phosphatase establishes the level of protrusive activity required for cell movements during zebrafish gastrulation

Weiser, Douglas C.; Row, Richard H.; Kimelman, David

doi:10.1242/dev.034892

Cited by 70 publications

(112 citation statements)

References 63 publications

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“…Another possibility is that wild-type cells must be fully connected through junctions in the epithelial sheet in order to undergo correct shape change. Interestingly, a similar duality of cell-autonomous and non-autonomous phenotype has also been observed for mypt1 function during convergent extension (Weiser et al, 2009).…”

Section: Regulation Of Neuroepithelial Cell Shape Via Apical Modulatisupporting

confidence: 65%

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Epithelial relaxation mediated by the myosin phosphatase regulator Mypt1 is required for brain ventricle lumen expansion and hindbrain morphogenesis

Gutzman

Sive

2010

Development

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SUMMARYWe demonstrate that in the zebrafish hindbrain, cell shape, rhombomere morphogenesis and, unexpectedly, brain ventricle lumen expansion depend on the contractile state of the neuroepithelium. The hindbrain neural tube opens in a specific sequence, with initial separation along the midline at rhombomere boundaries, subsequent openings within rhombomeres and eventual coalescence of openings into the hindbrain ventricle lumen. A mutation in the myosin phosphatase regulator mypt1 results in a small ventricle due to impaired stretching of the surrounding neuroepithelium. Although initial hindbrain opening remains normal, mypt1 mutant rhombomeres do not undergo normal morphological progression. Three-dimensional reconstruction demonstrates cell shapes within rhombomeres and at rhombomere boundaries are abnormal in mypt1 mutants. Wild-type cell shape requires that surrounding cells are also wild type, whereas mutant cell shape is autonomously regulated. Supporting the requirement for regulation of myosin function during hindbrain morphogenesis, wild-type embryos show dynamic levels of phosphorylated myosin regulatory light chain (pMRLC). By contrast, mutants show continuously high pMRLC levels, with concentration of pMRLC and myosin II at the apical side of the epithelium, and myosin II and actin concentration at rhombomere boundaries. Brain ventricle lumen expansion, rhombomere morphology and cell shape are rescued by inhibition of myosin II function, indicating that each defect is a consequence of overactive myosin. We suggest that the epithelium must 'relax', via activity of myosin phosphatase, to allow for normal hindbrain morphogenesis and expansion of the brain ventricular lumen. Epithelial relaxation might be a widespread strategy to facilitate tube inflation in many organs.

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Section: Regulation Of Neuroepithelial Cell Shape Via Apical Modulatisupporting

confidence: 65%

“…Myosin II is required for proper sheet movement and cell shape during Drosophila dorsal closure (Mizuno et al, 2002;Tan et al, 2003). In zebrafish, Mypt1 is important for kidney formation and for convergent extension during gastrulation (Huang et al, 2008;Weiser et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Epithelial relaxation mediated by the myosin phosphatase regulator Mypt1 is required for brain ventricle lumen expansion and hindbrain morphogenesis

Gutzman

Sive

2010

Development

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“…Net1 specifically interacts with both GTP-and GDP-bound RhoA and catalyzes GDP exchange on RhoA, but not Rac1 or Cdc42 [34,68]. Moreover, our results, as well as those from previous genetic studies, indicate that RhoA mediates cell movements during zebrafish gastrulation but not cell fate determination [41,92,93]. Conversely, intracellular GTP-Rac1 and GTP-cdc42, but not activated RhoA, are known to disrupt PAK1 dimerization, thereby controlling β-catenin S675 phosphorylation and Wnt signal transduction [23,65].…”

Section: Discussionsupporting

confidence: 74%

The guanine nucleotide exchange factor Net1 facilitates the specification of dorsal cell fates in zebrafish embryos by promoting maternal β-catenin activation

et al. 2016

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Wnt/β-catenin signaling is essential for the initiation of dorsal-ventral patterning during vertebrate embryogenesis. Maternal β-catenin accumulates in dorsal marginal nuclei during cleavage stages, but its critical target genes essential for dorsalization are silent until mid-blastula transition (MBT). Here, we find that zebrafish net1, a guanine nucleotide exchange factor, is specifically expressed in dorsal marginal blastomeres after MBT, and acts as a zygotic factor to promote the specification of dorsal cell fates. Loss-and gain-of-function experiments show that the GEF activity of Net1 is required for the activation of Wnt/β-catenin signaling in zebrafish embryos and mammalian cells. Net1 dissociates and activates PAK1 dimers, and PAK1 kinase activation causes phosphorylation of S675 of β-catenin after MBT, which ultimately leads to the transcription of downstream target genes. In summary, our results reveal that Net1-regulated β-catenin activation plays a crucial role in the dorsal axis formation during zebrafish development.

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“…Cell Migration Analysis by UV-mediated PhotoactivationEmbryos were injected and imaged at bud stage for analysis of convergence and extension as described (30).…”

Section: Methodsmentioning

confidence: 99%

ApoA-II Directs Morphogenetic Movements of Zebrafish Embryo by Preventing Chromosome Fusion during Nuclear Division in Yolk Syncytial Layer

Zhang

Yao

Wang

et al. 2011

Journal of Biological Chemistry

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The high density lipoprotein (HDL) represents a class of lipidand protein-containing particles and consists of two major apolipoproteins apoA-I and apoA-II. ApoA-II has been shown to be involved in the pathogenesis of insulin resistance, adiposity, diabetes, and metabolic syndrome. In embryo, apoa2 mRNAs are abundant in the liver, brain, lung, placenta, and in fish yolk syncytial layer (YSL), suggesting that apoa2 may perform a function during embryonic development. Here we find out that apoa2 modulates zebrafish embryonic development by regulating the organization of YSL. Disruption of apoa2 function in zebrafish caused chromosome fusing, which strongly blocked YSL nuclear division, inducing disorders in YSL organization and finally disturbing the embryonic epiboly. Purified native human apoA-II was able specifically to rescue the defects and induced nuclear division in zebrafish embryos and in human HeLa cells. The C terminus of apoA-II was required for the proper chromosome separation during nuclear division of YSL in zebrafish embryos and in human HeLa cells. Our data indicate that organization of YSL is required for blastoderm patterning and morphogenesis and suggest that apolipoprotein apoA-II is a novel factor of nuclear division in YSL involved in the regulation of early zebrafish embryonic morphogenesis and in mammalian cells for proliferation.Apolipoproteins, including apoA-I, apoA-II, apoA-IV, apoB, apoC-I, apoC-II, apoC-III, apoC-IV, and apoE, are macromolecular complexes synthesized mainly in liver and intestine and play essential roles in lipid uptake and transport in vertebrates (1-3). They bind to lipids to form chylomicrons, very low density lipoprotein (VLDL), low density lipoprotein (LDL), and high density lipoprotein (HDL) 3 and transport lipid to various tissues through the circulation system. In addition to their function in lipid metabolism, several apolipoproteins play critical roles in embryonic and ontogenic development and tissue regeneration (4, 5).The fish lipoprotein HDL is highly similar to most mammalian HDLs and contain two major apolipoproteins: the 28 kDa apolipoprotein and 14 kDa apolipoprotein (6 -8). The 14 kDa apolipoprotein is identified as a second major component of HDL from Japanese eel, common carp, pufferfish, orange-spotted grouper, grass carp, and fathead minnow (9). Recent data show that fish 14 kDa apolipoprotein is orthologous to mammalian HDL apoA-II (10), which has been shown to involve pathogenesis of insulin resistance, adiposity, diabetes, and metabolic syndrome. The apoa2 mRNAs are abundant in the liver, lung, placenta, brain (6, 11, 12) in embryos. In some fish species, apoa2 also expresses in heart. In addition, apoa2 has been found to express in YSL in embryos (9), suggesting that apoa2 may perform functions during embryonic gastrulation. The previous data indicate that yolk lipids are taken up by the fish YSL, where they are assembled into lipoproteins for releasing into the perisyncytial space (13). Apolipoprotein gene expression and lipoprotein secr...

show abstract

Rho-regulated Myosin phosphatase establishes the level of protrusive activity required for cell movements during zebrafish gastrulation

Cited by 70 publications

References 63 publications

Epithelial relaxation mediated by the myosin phosphatase regulator Mypt1 is required for brain ventricle lumen expansion and hindbrain morphogenesis

Epithelial relaxation mediated by the myosin phosphatase regulator Mypt1 is required for brain ventricle lumen expansion and hindbrain morphogenesis

The guanine nucleotide exchange factor Net1 facilitates the specification of dorsal cell fates in zebrafish embryos by promoting maternal β-catenin activation

ApoA-II Directs Morphogenetic Movements of Zebrafish Embryo by Preventing Chromosome Fusion during Nuclear Division in Yolk Syncytial Layer

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