小胶质细胞
表观遗传学
自闭症
疾病
生物
MEF2C公司
神经科学
计算生物学
医学
生物信息学
遗传学
免疫学
炎症
基因
转录因子
精神科
病理
作者
Celina T. Nguyen,Emily H. Broersma,Anna S. Warden,Cristina Mora,Claudia Z. Han,Zahara Keulen,Nathanael J. Spann,Jing Wang,Gabriela Ramírez,Sht Mak,Samantha Trescott,Mohammadparsa Khakpour,Avalon Johnson,Fatir Qureshi,Michael R. La Frano,Kiana Mohajeri,Michael E. Talkowski,Olivia Corradin,Marie‐Ève Tremblay,Christopher K. Glass
出处
期刊:Nature Immunology
[Nature Portfolio]
日期:2025-10-22
卷期号:26 (11): 1989-2003
被引量:4
标识
DOI:10.1038/s41590-025-02299-0
摘要
Abstract MEF2C encodes a transcription factor that is critical in nervous system development. Here, to examine disease-associated functions of MEF2C in human microglia, we profiled microglia differentiated from isogenic MEF2C -haploinsufficient and MEF2C -knockout induced pluripotent stem cell lines. Complementary transcriptomic and functional analyses revealed that loss of MEF2C led to a hyperinflammatory phenotype with broad phagocytic impairment, lipid accumulation, lysosomal dysfunction and elevated basal inflammatory cytokine secretion. Genome-wide profiling of MEF2C-bound sites coupled with the active regulatory landscape enabled inference of its transcriptional functions and potential mechanisms for MEF2C-associated cellular functions. Transcriptomic and epigenetic approaches identified substantial overlap with idiopathic autism datasets, suggesting a broader role of human microglial MEF2C dysregulation in idiopathic autism. In a mouse xenotransplantation model, loss of MEF2C led to morphological, lysosomal and lipid abnormalities in human microglia in vivo. Together, these studies reveal mechanisms by which reduced microglial MEF2C could contribute to the development of neurological diseases.
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