Deficient adaptation to centrosome duplication defects in neural progenitors causes microcephaly and subcortical heterotopias
José González-Martínez, Andrzej W. Cwetsch, Diego Martínez-Alonso, Luis R. López-Sainz, Jorge Almagro, Anna Melati, Jesús Gómez, Manuel Pérez-Martínez, Diego Megías, Jasminka Boskovic, Javier Gilabert-Juan, Osvaldo Graña-Castro, Alessandra Pierani, Axel Behrens, Sagrario Ortega, Marcos Malumbres
José González-Martínez, Andrzej W. Cwetsch, Diego Martínez-Alonso, Luis R. López-Sainz, Jorge Almagro, Anna Melati, Jesús Gómez, Manuel Pérez-Martínez, Diego Megías, Jasminka Boskovic, Javier Gilabert-Juan, Osvaldo Graña-Castro, Alessandra Pierani, Axel Behrens, Sagrario Ortega, Marcos Malumbres
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Research Article Cell biology Development

Deficient adaptation to centrosome duplication defects in neural progenitors causes microcephaly and subcortical heterotopias

Abstract

Congenital microcephaly (MCPH) is a neurodevelopmental disease associated with mutations in genes encoding proteins involved in centrosomal and chromosomal dynamics during mitosis. Detailed MCPH pathogenesis at the cellular level is still elusive, given the diversity of MCPH genes and lack of comparative in vivo studies. By generating a series of CRISPR/Cas9-mediated genetic KOs, we report here that — whereas defects in spindle pole proteins (ASPM, MCPH5) result in mild MCPH during development — lack of centrosome (CDK5RAP2, MCPH3) or centriole (CEP135, MCPH8) regulators induces delayed chromosome segregation and chromosomal instability in neural progenitors (NPs). Our mouse model of MCPH8 suggests that loss of CEP135 results in centriole duplication defects, TP53 activation, and cell death of NPs. Trp53 ablation in a Cep135-deficient background prevents cell death but not MCPH, and it leads to subcortical heterotopias, a malformation seen in MCPH8 patients. These results suggest that MCPH in some MCPH patients can arise from the lack of adaptation to centriole defects in NPs and may lead to architectural defects if chromosomally unstable cells are not eliminated during brain development.

Authors

José González-Martínez, Andrzej W. Cwetsch, Diego Martínez-Alonso, Luis R. López-Sainz, Jorge Almagro, Anna Melati, Jesús Gómez, Manuel Pérez-Martínez, Diego Megías, Jasminka Boskovic, Javier Gilabert-Juan, Osvaldo Graña-Castro, Alessandra Pierani, Axel Behrens, Sagrario Ortega, Marcos Malumbres

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Figure 4

TP53-mediated response to lack of Cep135 in developing brains and cultured neurospheres.

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TP53-mediated response to lack of Cep135 in developing brains and cultur...
(A) Schematic representation of the Cep135(+/+) and Cep135(Δ8/Δ8) samples selected for RNA sequencing analysis, including E11.5 and E14.5 brains, as well as neurospheres from E14.5 brains cultured for 12 and 24 hours. (B) Principal component analysis of the transcriptomic profiles from the indicated samples. Values in PC labels show the percentage of explained variance for principal component 1 (PC1) and PC2. (C) Major pathways deregulated and enrichment in transcription factor (TF) targets in E11.5 samples. The enrichment in transcripts involved in the TP53 pathway is shown to the right. (D) Major pathways deregulated and enrichment in TF targets in E14.5 samples cultured during 24 hours to form neurospheres. The enrichment in transcripts involved in the TP53 pathway is shown to the right. See Supplemental Tables 1–9 for additional details. (E) Immunostaining of primary neurospheres from E14.5 embryos with SOX2 and TP53 antibodies. The percentage of TP53+ cells is shown to the right. (F) Confocal imaging of primary neurospheres stained with antibodies against active caspase 3 (AC3, green). DAPI (DNA) is shown in blue. Scale bars: 10 μm (E and F). Yellow arrowheads indicate TP53+ (E) and CC3+ cells (F). In E, data are mean ± SEM. ****P < 0.0001 (1-way ANOVA with Tukey’s multiple-comparison test).