Reversal of Proliferation Deficits Caused by Chromosome 16p13.11 Microduplication Through Targeting NFκB Signaling: an Integrated Study of Patient-derived Neuronal Precursor Cells, Cerebral Organoids and in Vivo Brain Imaging

Overview

Journal Mol Psychiatry

Specialties Molecular Biology
Psychiatry

Date 2018 Nov 8

PMID 30401811

Citations 24

Authors

Mandy Johnstone

Navneet A Vasistha

Miruna C Barbu

Owen Dando

Karen Burr

Edward Christopher

Sophie Glen

Christelle Robert

Rana Fetit

Kenneth G Macleod

Matthew R Livesey

David St Clair

Douglas H R Blackwood

Kirsty Millar

Neil O Carragher

Giles E Hardingham

David J A Wyllie

Eve C Johnstone

Heather C Whalley

Andrew M McIntosh

Stephen M Lawrie

Siddharthan Chandran

Affiliations

Soon will be listed here.

Abstract

The molecular basis of how chromosome 16p13.11 microduplication leads to major psychiatric disorders is unknown. Here we have undertaken brain imaging of patients carrying microduplications in chromosome 16p13.11 and unaffected family controls, in parallel with iPS cell-derived cerebral organoid studies of the same patients. Patient MRI revealed reduced cortical volume, and corresponding iPSC studies showed neural precursor cell (NPC) proliferation abnormalities and reduced organoid size, with the NPCs therein displaying altered planes of cell division. Transcriptomic analyses of NPCs uncovered a deficit in the NFκB p65 pathway, confirmed by proteomics. Moreover, both pharmacological and genetic correction of this deficit rescued the proliferation abnormality. Thus, chromosome 16p13.11 microduplication disturbs the normal programme of NPC proliferation to reduce cortical thickness due to a correctable deficit in the NFκB signalling pathway. This is the first study demonstrating a biologically relevant, potentially ameliorable, signalling pathway underlying chromosome 16p13.11 microduplication syndrome in patient-derived neuronal precursor cells.

Citing Articles

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