Alwyn Dady scite author profile

Background: During embryonic development, cadherin switches are correlated with tissue remodelings, such as epithelium-to-mesenchyme transition (EMT). An E-to N-cadherin switch also occurs during neurogenesis, but this is not accompanied with EMT. The biological significance of this switch is currently unknown. Results: We analyzed the timing and kinetics of the E-to N-cadherin switch during early neural induction and neurulation in the chick embryo, in relation to the patterns of their transcriptional regulators. We found that deployment of the E-to N-cadherin switch program varies considerably along the embryonic axis. Rostrally in regions of primary neurulation, it occurs progressively both in time and space in a manner that appears neither in connection with morphological transformation of neural epithelial cells nor in synchrony with movements of neurulation. Caudally, in regions of secondary neurulation, neurogenesis was not associated with cadherin switch as N-cadherin pre-existed before formation of the neural tube. We also found that, during neural development, cadherin switch is orchestrated by a set of transcriptional regulators distinct from those involved in EMT. Conclusions: Our results indicate that cadherin switch correlates with the partition of the neurectoderm into its three main populations: ectoderm, neural crest, and neural tube.

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Neural differentiation, selection and transcriptomic profiling of human neuromesodermal progenitors-like cells in vitro

Verrier

Davidson

Gierliński

et al. 2018

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Robust protocols for directed differentiation of human pluripotent cells are required to determine whether mechanisms operating in model organisms are relevant to our own development. Recent work in vertebrate embryos has identified neuromesodermal progenitors as a bipotent cell population that contributes to paraxial mesoderm and spinal cord. However, precise protocols for in vitro differentiation of human spinal cord progenitors are lacking. Informed by signalling in amniote embryos, we show here that transient dual-SMAD inhibition, together with retinoic acid (dSMADi-RA), provides rapid and reproducible induction of human spinal cord progenitors from neuromesodermal progenitor-like cells. Using CRISPR-Cas9 to engineer human embryonic stem cells with a GFP-reporter for neuromesodermal progenitor-associated gene Nkx1.2 we facilitate selection of this cell population. RNA-sequencing was then used to identify human and conserved neuromesodermal progenitor transcriptional signatures, to validate this differentiation protocol and to reveal new pathways/processes in human neural differentiation. This optimised protocol, novel reporter line and transcriptomic data are useful resources with which to dissect molecular mechanisms regulating human spinal cord generation and allow the scaling-up of distinct cell populations for global analyses, including proteomic, biochemical and chromatin interrogation.

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Junctional Neurulation: A Unique Developmental Program Shaping a Discrete Region of the Spinal Cord Highly Susceptible to Neural Tube Defects

et al. 2014

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In higher vertebrates, the primordium of the nervous system, the neural tube, is shaped along the rostrocaudal axis through two consecutive, radically different processes referred to as primary and secondary neurulation. Failures in neurulation lead to severe anomalies of the nervous system, called neural tube defects (NTDs), which are among the most common congenital malformations in humans. Mechanisms causing NTDs in humans remain ill-defined. Of particular interest, the thoracolumbar region, which encompasses many NTD cases in the spine, corresponds to the junction between primary and secondary neurulations. Elucidating which developmental processes operate during neurulation in this region is therefore pivotal to unraveling the etiology of NTDs. Here, using the chick embryo as a model, we show that, at the junction, the neural tube is elaborated by a unique developmental program involving concerted movements of elevation and folding combined with local cell ingression and accretion. This process ensures the topological continuity between the primary and secondary neural tubes while supplying all neural progenitors of both the junctional and secondary neural tubes. Because it is distinct from the other neurulation events, we term this phenomenon junctional neurulation. Moreover, the planarcell-polarity member, Prickle-1, is recruited specifically during junctional neurulation and its misexpression within a limited time period suffices to cause anomalies that phenocopy lower spine NTDs in human. Our study thus provides a molecular and cellular basis for understanding the causality of NTD prevalence in humans and ascribes to Prickle-1 a critical role in lower spinal cord formation.

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Alwyn Dady

Timing and kinetics of E‐ to N‐cadherin switch during neurulation in the avian embryo

Neural differentiation, selection and transcriptomic profiling of human neuromesodermal progenitors-like cells in vitro

Junctional Neurulation: A Unique Developmental Program Shaping a Discrete Region of the Spinal Cord Highly Susceptible to Neural Tube Defects

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