Litcius/Paper detail

Neurodevelopmental defects in human cortical organoids with <i>N</i> -acetylneuraminic acid synthase mutation

Qian Bu, Yanping Dai, Huaqin Zhang, Min Li, Haxiaoyu Liu, Yan Huang, Ailing Zeng, Feng Qin, Linhong Jiang, Liang Wang, Yaxing Chen, Hongchun Li, Xiaojie Wang, Yue Zhao, Meng Qin, Ying Zhao, Ni Zhang, Weihong Kuang, Yinglan Zhao, Xiaobo Cen

2023Science Advances13 citationsDOIOpen Access PDF

Abstract

Biallelic genetic variants in N -acetylneuraminic acid synthase ( NANS ), a critical enzyme in endogenous sialic acid biosynthesis, are clinically associated with neurodevelopmental disorders. However, the mechanism underlying the neuropathological consequences has remained elusive. Here, we found that NANS mutation resulted in the absence of both sialic acid and protein polysialylation in the cortical organoids and notably reduced the proliferation and expansion of neural progenitors. NANS mutation dysregulated neural migration and differentiation, disturbed synapse formation, and weakened neuronal activity. Single-cell RNA sequencing revealed that NANS loss of function markedly altered transcriptional programs involved in neuronal differentiation and ribosomal biogenesis in various neuronal cell types. Similarly, Nans heterozygous mice exhibited impaired cortical neurogenesis and neurobehavioral deficits. Collectively, our findings reveal a crucial role of NANS-mediated endogenous sialic acid biosynthesis in regulating multiple features of human cortical development, thus linking NANS mutation with its clinically relevant neurodevelopmental disorders.

Topics & Concepts

MutationBiologyNeurogenesisSialic acidOrganoidCell biologyGeneNeuroscienceGeneticsGlycosylation and Glycoproteins ResearchGenomics and Phylogenetic StudiesCaveolin-1 and cellular processes
Neurodevelopmental defects in human cortical organoids with <i>N</i> -acetylneuraminic acid synthase mutation | Litcius