Comparative characterization of human accelerated regions in neurons

Article

Cui, Xiekui; Yang, Han; Cai, Charles; Beaman, Cooper; Yang, Xiaoyu; Liu, Hongjiang; Ren, Xingjie; Amador, Zachary; Jones, Ian R.; Keough, Kathleen C.; Zhang, Meng; Fair, Tyler; Abnousi, Armen; Mishra, Shreya; Ye, Zhen; Hu, Ming; Pollen, Alex A.; Pollard, Katherine S.; Shen, Yin

University of California System; University of California San Francisco; University of California System; University of California San Francisco; University of California System; University of California San Francisco; UCSF Medical Center; UCSF Helen Diller Family Comprehensive Cancer Center; University of California System; University of California San Francisco; University of California System; University of California San Francisco; University of California System; University of California San Francisco; Cleveland Clinic Foundation; University of California System; University of California San Francisco; University of California System; University of California San Francisco; Chan Zuckerberg Initiative (CZI); University of California System; University of California San Francisco

Nature

0028-3433

10.1038/s41586-025-08622-x

2025-04-24

Human accelerated regions (HARs) are conserved genomic loci that have experienced rapid nucleotide substitutions following the divergence from chimpanzees1,2. HARs are enriched in candidate regulatory regions near neurodevelopmental genes, suggesting their roles in gene regulation3. However, their target genes and functional contributions to human brain development remain largely uncharacterized. Here we elucidate the cis-regulatory functions of HARs in human and chimpanzee induced pluripotent stem (iPS) cell-induced excitatory neurons. Using genomic4 and chromatin looping information, we prioritized 20 HARs and their chimpanzee orthologues for functional characterization via single-cell CRISPR interference, and demonstrated their species-specific gene regulatory functions. Our findings reveal diverse functional outcomes of HAR-mediated cis-regulation in human neurons, including attenuated NPAS3 expression by altering the binding affinities of multiple transcription factors in HAR202 and maintaining iPS cell pluripotency and neuronal differentiation capacities through the upregulation of PUM2 by 2xHAR.319. Finally, we used prime editing to demonstrate differential enhancer activity caused by several HAR26;2xHAR.178 variants. In particular, we link one variant in HAR26;2xHAR.178 to elevated SOCS2 expression and increased neurite outgrowth in human neurons. Thus, our study sheds new light on the endogenous gene regulatory functions of HARs and their potential contribution to human brain evolution.