An inappropriate decline in ribosome levels drives a diverse set of neurodevelopmental disorders

Author:

Ni Chunyang,Yu Leqian,Vona Barbara,Park Dayea,Wei Yulei,Schmitz Daniel A,Wei Yudong,Ding Yi,Sakurai Masahiro,Ballard Emily,Liu Yan,Kumar Ashwani,Xing Chao,Kim Hyung-Goo,Ekmekci Cumhur,Karimiani Ehsan Ghayoor,Imannezhad Shima,Eghbal Fatemeh,Badv Reza Shervin,Schwaibold Eva Maria Christina,Dehghani Mohammadreza,Mehrjardi Mohammad Yahya Vahidi,Metanat Zahra,Eslamiyeh Hosein,Khouj Ebtissal,Alhajj Saleh Mohammed Nasser,Chedrawi Aziza,Alves César Augusto Pinheiro Ferreira,Houlden Henry,Kruer Michael,Alkuraya Fowzan S.,Cenik Can,Maroofian Reza,Wu Jun,Buszczak MichaelORCID

Abstract

SummaryMany neurodevelopmental defects are linked to perturbations in genes involved in housekeeping functions, such as those encoding ribosome biogenesis factors. However, how reductions in ribosome biogenesis can result in tissue and developmental specific defects remains a mystery. Here we describe new allelic variants in the ribosome biogenesis factorAIRIMprimarily associated with neurodevelopmental disorders. Using human cerebral organoids in combination with proteomic analysis, single-cell transcriptome analysis across multiple developmental stages, and single organoid translatome analysis, we identify a previously unappreciated mechanism linking changes in ribosome levels and the timing of cell fate specification during early brain development. We find ribosome levels decrease during neuroepithelial differentiation, making differentiating cells particularly vulnerable to perturbations in ribosome biogenesis during this time. Reduced ribosome availability more profoundly impacts the translation of specific transcripts, disrupting both survival and cell fate commitment of transitioning neuroepithelia. Enhancing mTOR activity by both genetic and pharmacologic approaches ameliorates the growth and developmental defects associated with intellectual disability linked variants, identifying potential treatment options for specific brain ribosomopathies. This work reveals the cellular and molecular origins of protein synthesis defect-related disorders of human brain development.HighlightsAIRIMvariants reduce ribosome levels specifically in neural progenitor cells.Inappropriately low ribosome levels cause a transient delay in radial glia fate commitment.Reduced ribosome levels impair translation of a selected subset of mRNAs.Genetic and pharmacologic activation of mTORC1 suppresses AIRIM-linked phenotypes.

Publisher

Cold Spring Harbor Laboratory

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