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Massively parallel disruption of enhancers active in human neural stem cells

Evan Geller, Mark Noble, Matheo Morales, Jake Gockley, Deena Emera, Severin Uebbing, Justin Cotney, James P. Noonan

2024Cell Reports20 citationsDOIOpen Access PDF

Abstract

Changes in gene regulation have been linked to the expansion of the human cerebral cortex and to neurodevelopmental disorders, potentially by altering neural progenitor proliferation. However, the effects of genetic variation within regulatory elements on neural progenitors remain obscure. We use sgRNA-Cas9 screens in human neural stem cells (hNSCs) to disrupt 10,674 genes and 26,385 conserved regions in 2,227 enhancers active in the developing human cortex and determine effects on proliferation. Genes with proliferation phenotypes are associated with neurodevelopmental disorders and show biased expression in specific fetal human brain neural progenitor populations. Although enhancer disruptions overall have weaker effects than gene disruptions, we identify enhancer disruptions that severely alter hNSC self-renewal. Disruptions in human accelerated regions, implicated in human brain evolution, also alter proliferation. Integrating proliferation phenotypes with chromatin interactions reveals regulatory relationships between enhancers and their target genes contributing to neurogenesis and potentially to human cortical evolution.

Topics & Concepts

Massively parallelEnhancerNeural stem cellStem cellBiologyCell biologyComputational biologyComputer scienceNeuroscienceGeneticsGeneTranscription factorParallel computingPluripotent Stem Cells ResearchGenomics and Chromatin DynamicsNeurogenesis and neuroplasticity mechanisms