NR2F1 regulates regional progenitor dynamics in the mouse neocortex and cortical gyrification in BBSOAS patients.

Michele Bertacchi,Christophe Philippe,Agnès Loubat,Carolina Frassoni,Salvatore Oliviero,Laurence Faivre,Aurore Garde,Marjolaine Willems,Silvia Cappello,Arthur Sorlin,Rossella Di Giaimo,Paul Kuentz,Francesco Neri,Michèle Studer,Philippe Khau Van Kien,Françoise Devillard,Anna Lisa Romano,Laurence Perrin,Ludovico D’incerti ,Frédéric Tran Mau-Them

doi:10.15252/embj.2019104163

Abstract

The relationships between impaired cortical development and consequent malformations in neurodevelopmental disorders, as well as the genes implicated in these processes, are not fully elucidated to date. In this study, we report six novel cases of patients affected by BBSOAS (Boonstra‐Bosch‐Schaff optic atrophy syndrome), a newly emerging rare neurodevelopmental disorder, caused by loss‐of‐function mutations of the transcriptional regulator NR2F1. Young patients with NR2F1 haploinsufficiency display mild to moderate intellectual disability and show reproducible polymicrogyria‐like brain malformations in the parietal and occipital cortex. Using a recently established BBSOAS mouse model, we found that Nr2f1 regionally controls long‐term self‐renewal of neural progenitor cells via modulation of cell cycle genes and key cortical development master genes, such as Pax6. In the human fetal cortex, distinct NR2F1 expression levels encompass gyri and sulci and correlate with local degrees of neurogenic activity. In addition, reduced NR2F1 levels in cerebral organoids affect neurogenesis and PAX6 expression. We propose NR2F1 as an area‐specific regulator of mouse and human brain morphology and a novel causative gene of abnormal gyrification.

Highlights

During development, neural progenitor (NP) cells shape the cerebral cortex by means of a delicate balance between neurogenesis and progenitor maintenance (Florio & Huttner, 2014)
Different NP subtypes concur to produce neurons in a direct or indirect way; differentiating neurons migrate to the cortical plate (CP), where they settle down to mature into distinct neuronal subtypes radially organized into layers and circuits (Dehay & Kennedy, 2007; Kumamoto & Hanashima, 2014)
We describe for the first time abnormal folding in six new patients with de novo point variants within the start codon for translation, the DNA-binding Domain (DBD) or the ligand-binding domain (LBD) of NR2F1

Summary

Introduction

Neural progenitor (NP) cells shape the cerebral cortex by means of a delicate balance between neurogenesis (differentiation) and progenitor maintenance (self-renewal) (Florio & Huttner, 2014). Different NP subtypes concur to produce neurons in a direct or indirect (via intermediate progenitor—IP) way; differentiating neurons migrate to the cortical plate (CP), where they settle down to mature into distinct neuronal subtypes radially organized into layers and circuits (Dehay & Kennedy, 2007; Kumamoto & Hanashima, 2014). It is well accepted that presumptive areas, called proto-areas, get specified during early development (Cadwell et al, 2019), the underlying molecular and cellular mechanisms are still not fully elucidated. It is not well known whether abnormal area-specific development in humans can lead to particular brain malformations

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