Cell Reports (Apr 2017)

An Organoid-Based Model of Cortical Development Identifies Non-Cell-Autonomous Defects in Wnt Signaling Contributing to Miller-Dieker Syndrome

  • Vira Iefremova,
  • George Manikakis,
  • Olivia Krefft,
  • Ammar Jabali,
  • Kevin Weynans,
  • Ruven Wilkens,
  • Fabio Marsoner,
  • Björn Brändl,
  • Franz-Josef Müller,
  • Philipp Koch,
  • Julia Ladewig

DOI
https://doi.org/10.1016/j.celrep.2017.03.047
Journal volume & issue
Vol. 19, no. 1
pp. 50 – 59

Abstract

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Miller-Dieker syndrome (MDS) is caused by a heterozygous deletion of chromosome 17p13.3 involving the genes LIS1 and YWHAE (coding for 14.3.3ε) and leads to malformations during cortical development. Here, we used patient-specific forebrain-type organoids to investigate pathological changes associated with MDS. Patient-derived organoids are significantly reduced in size, a change accompanied by a switch from symmetric to asymmetric cell division of ventricular zone radial glia cells (vRGCs). Alterations in microtubule network organization in vRGCs and a disruption of cortical niche architecture, including altered expression of cell adhesion molecules, are also observed. These phenotypic changes lead to a non-cell-autonomous disturbance of the N-cadherin/β-catenin signaling axis. Reinstalling active β-catenin signaling rescues division modes and ameliorates growth defects. Our data define the role of LIS1 and 14.3.3ε in maintaining the cortical niche and highlight the utility of organoid-based systems for modeling complex cell-cell interactions in vitro.

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