Global analysis of cell behavior and protein dynamics reveals region-specific roles for Shroom3 and N-cadherin during neural tube closure

Baldwin, Austin T.; Kim, Juliana H; Seo, Hyemin; Wallingford, John B.

doi:10.7554/elife.66704

Cited by 13 publications

(22 citation statements)

References 77 publications

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“…High-resolution imaging of NP morphogenesis revealed that the anterior and posterior regions of the NP display distinct morphogenetic behaviour. This is an agreement with a recent study that also detected distinct patterns of behaviour at the posterior and anterior NP (Baldwin et al, 2022). Specifically, here we show that whereas the NP narrows and elongates, the anterior part of the tissue displays a polarized anterior movement.…”

Section: Discussionsupporting

confidence: 94%

“…S6B,C). In agreement with our data, Crispr/Casmediated knock out of Shroom3 in Xenopus embryos leads to a mild effect on the polarity of T1 transitions, but does not affect the number of T1 transitions and CE-mediated tissue deformation (Baldwin et al, 2022). Altogether, our data show that NTC is clearly biphasic with an early CE-driven phase that is spatially restricted to the posterior NP, followed by a second phase driven by generalized AC across the entire NP (Fig.…”

Section: Spatiotemporal Contribution Of Ap During Ntcsupporting

confidence: 92%

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Distinct spatiotemporal contribution of morphogenetic events and mechanical tissue coupling during Xenopus neural tube closure

Christodoulou

Skourides

2022

Development

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Neural tube closure (NTC) is a fundamental process during vertebrate development and is indispensable for the formation of the central nervous system. Here, using Xenopus laevis embryos, live imaging, single-cell tracking, optogenetics and loss of function experiments we examine the roles of convergent extension and apical constriction, and define the role of the surface ectoderm during NTC. We show that NTC is a two-stage process with distinct spatiotemporal contributions of convergent extension and apical constriction at each stage. Convergent extension takes place during the first stage and is spatially restricted at the posterior tissue, while apical constriction occurs during the second stage throughout the neural plate. We go on to show that the surface ectoderm is mechanically coupled with the neural plate and its movement during NTC is driven by neural plate morphogenesis. Last, we show that increase of surface ectoderm resistive forces is detrimental for neural plate morphogenesis.

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Section: Discussionsupporting

confidence: 94%

Section: Spatiotemporal Contribution Of Ap During Ntcsupporting

confidence: 92%

Distinct spatiotemporal contribution of morphogenetic events and mechanical tissue coupling during Xenopus neural tube closure

Christodoulou

Skourides

2022

Development

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“…The transformation of the flat neuroepithelium to the neural tube is primarily driven by forces generated by intrinsic morphogenetic events. Convergent extension and apical constriction are the two main morphogenetic movements taking place within the neuroepithelium during neural tube closure ( Keller et al, 1992 ; Davidson and Keller, 1999 ; Hildebrand and Soriano, 1999 ; Haigo et al, 2003 ; Nishimura et al, 2012 ; Zanardelli et al, 2013 ; Christodoulou and Skourides, 2015 ; Baldwin et al, 2022 ). In addition to neural plate generated forces, it has been suggested that extrinsic forces stemming from the adjacent surface ectoderm and the underlying somitic mesoderm actively contribute to neural tube closure ( Schroeder, 1970 ; Karfunkel, 1974 ; Jacobson and Gordon, 1976 ; Moury and Schoenwolf, 1995 ).…”

Section: Introductionmentioning

confidence: 99%

Somitic mesoderm morphogenesis is necessary for neural tube closure during Xenopus development

Christodoulou

Skourides

2023

Front. Cell Dev. Biol.

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Neural tube closure is a fundamental process during vertebrate embryogenesis, which leads to the formation of the central nervous system. Defective neural tube closure leads to neural tube defects which are some of the most common human birth defects. While the intrinsic morphogenetic events shaping the neuroepithelium have been studied extensively, how tissues mechanically coupled with the neural plate influence neural tube closure remains poorly understood. Here, using Xenopus laevis embryos, live imaging in combination with loss of function experiments and morphometric analysis of fixed samples we explore the reciprocal mechanical communication between the neural plate and the somitic mesoderm and its impact on tissue morphogenesis. We show that although somitic mesoderm convergent extension occurs independently from neural plate morphogenesis neural tube closure depends on somitic mesoderm morphogenesis. Specifically, impaired somitic mesoderm remodelling results in defective apical constriction within the neuroepithelium and failure of neural tube closure. Last, our data reveal that mild abnormalities in somitic mesoderm and neural plate morphogenesis have a synergistic effect during neurulation, leading to severe neural tube closure defects. Overall, our data reveal that defective morphogenesis of tissues mechanically coupled with the neural plate can not only drastically exacerbate mild neural tube defects that may arise from abnormalities within the neural tissue but can also elicit neural tube defects even when the neural plate is itself free of inherent defects.

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“…For example, formin homology domain-containing (Fhod)3 is selectively expressed in apically convex regions of the anterior neuroepithelium overlying the rhombomeres and its deletion prevents apical constriction, causing exencephaly in mice (Sulistomo et al, 2019). In Xenopus , simultaneous accumulation of F-actin and N-cadherin (CDH2) parallels apical constriction anteriorly, whereas N-cadherin does not increase in the constricting posterior neuroepithelium (Baldwin et al, 2022). Important differences between Xenopus and amniotes include the lack of a pseudostratified neuroepithelium and brevity of neural tube closure relative to cell cycle progression in the former (Nikolopoulou et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…Both apicomedial and cell junction actomyosin can contribute to apical shrinkage. In the stratified neuroepithelium of Xenopus , apicomedial F-actin accumulation is associated with apical shrinkage in the presumptive brain, whereas both apicomedial and cortical accumulation can correlate with apical shrinkage in the spinal region (Baldwin et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Synchronisation of apical constriction and cell cycle progression is a conserved behaviour of pseudostratified neuroepithelia informed by their tissue geometry

Ampartzidis

Efstathiou

Paonessa

et al. 2022

Preprint

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Neuroepithelial cells multitask, balancing tissue growth with the morphogenetic imperative of closing the neural tube. They apically constrict to generate mechanical forces which elevate the neural folds, but are thought to apically dilate during mitosis. However, we previously reported that mitotic neuroepithelial cells in the mouse posterior neuropore have smaller apical surfaces than non-mitotic cells. Here, we document progressive apical enrichment of non-muscle myosin-II in mitotic, but not non-mitotic, neuroepithelial cells with smaller apical areas. Live-imaging of the chick posterior neuropore confirms apical constriction synchronised with mitosis, reaching maximal constriction by anaphase, before division and re-dilation. Mitotic apical constriction amplitude is significantly greater than interphase constrictions. To investigate conservation in humans, we characterised early stages of iPSC differentiation through dual SMAD-inhibition to robustly produce pseudostratified neuroepithelia with apically enriched actomyosin. These cultured neuroepithelial cells achieve an equivalent apical area to those in mouse embryos. iPSC-derived neuroepithelial cells have large apical areas in G2 which constrict in M phase and retain this constriction in G1/S. Given that this differentiation method produces anterior neural identities, we studied the anterior neuroepithelium of the elevating mouse mid-brain neural tube. Instead of constricting, mid-brain mitotic neuroepithelial cells have larger apical areas than interphase cells. Tissue geometry differs between the apically convex early midbrain and concave posterior neuropore. Culturing human neuroepithelia on equivalently convex surfaces prevents mitotic apical constriction. Thus, synchronisation of apical constriction with the cell cycle is a geometry-dependent behaviour which reverses prior dilation in mitotic neuroepithelial cells of the closing vertebrate neural tube.

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Global analysis of cell behavior and protein dynamics reveals region-specific roles for Shroom3 and N-cadherin during neural tube closure

Cited by 13 publications

References 77 publications

Distinct spatiotemporal contribution of morphogenetic events and mechanical tissue coupling during Xenopus neural tube closure

Distinct spatiotemporal contribution of morphogenetic events and mechanical tissue coupling during Xenopus neural tube closure

Somitic mesoderm morphogenesis is necessary for neural tube closure during Xenopus development

Synchronisation of apical constriction and cell cycle progression is a conserved behaviour of pseudostratified neuroepithelia informed by their tissue geometry

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