Mediator MED23 controls oligodendrogenesis and myelination by modulating Sp1/P300-directed gene programs.

IF 13 1区生物学 Q1 CELL BIOLOGY

Cell Discovery Pub Date : 2024-10-15 DOI:10.1038/s41421-024-00730-8

Shuai Zhang, Xue Feng, Chong-Hui Li, Yuan-Ming Zheng, Meng-Ya Wang, Jun-Jie Li, Yun-Peng Dai, Naihe Jing, Jia-Wei Zhou, Gang Wang

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Abstract

Gaining the molecular understanding for myelination development and regeneration has been a long-standing goal in neurological research. Mutations in the transcription cofactor Mediator Med23 subunit are often associated with intellectual disability and white matter defects, although the precise functions and mechanisms of Mediator in myelination remain unclear. In this study, we generated a mouse model carrying an Med23^Q649R mutation that has been identified in a patient with hypomyelination features. The MED23^Q649R mouse model develops white matter thinning and cognitive decline, mimicking common clinical phenotypes. Further, oligodendrocyte-lineage specific Med23 knockout mice verified the important function of MED23 in regulating central nervous system myelination and postinjury remyelination. Utilizing the in vitro cellular differentiation assay, we found that the oligodendrocyte progenitor cells, either carrying the Q649R mutation or lacking Med23, exhibit significant deficits in their capacity to differentiate into mature oligodendrocytes. Gene profiling combined with reporter assays demonstrated that Mediator Med23 controls Sp1-directed gene programs related to oligodendrocyte differentiation and cholesterol metabolism. Integrative analysis demonstrated that Med23 modulates the P300 binding to Sp1-targeted genes, thus orchestrating the H3K27 acetylation and enhancer activation for the oligodendrocyte lineage progression. Collectively, our findings identified the critical role for the Mediator Med23 in oligodendrocyte fate determination and provide mechanistic insights into the myelination pathogenesis associated with MED23 mutations.

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介导因子 MED23 通过调节 Sp1/P300 引导的基因程序控制少突形成和髓鞘化。

了解髓鞘发育和再生的分子机制一直是神经学研究的长期目标。转录辅助因子 Mediator Med23 亚基的突变通常与智力障碍和白质缺陷有关，但 Mediator 在髓鞘形成中的确切功能和机制仍不清楚。在这项研究中，我们生成了一个携带 Med23Q649R 突变的小鼠模型，该突变已在一名具有髓鞘功能减退特征的患者身上发现。MED23Q649R 小鼠模型会出现白质变薄和认知能力下降，模仿了常见的临床表型。此外，少突胶质细胞系特异性 Med23 基因敲除小鼠验证了 MED23 在调节中枢神经系统髓鞘化和损伤后再髓鞘化方面的重要功能。利用体外细胞分化试验，我们发现无论是携带 Q649R 突变还是缺乏 Med23 的少突胶质细胞祖细胞，其分化为成熟少突胶质细胞的能力都存在显著缺陷。基因图谱分析与报告实验相结合证明，调解因子 Med23 控制着与少突胶质细胞分化和胆固醇代谢有关的 Sp1 主导基因程序。综合分析表明，Med23 可调节 P300 与 Sp1 靶向基因的结合，从而协调 H3K27 乙酰化和增强子激活，促进少突胶质细胞系的发展。总之，我们的研究结果确定了 Mediator Med23 在少突胶质细胞命运决定中的关键作用，并为 MED23 基因突变相关的髓鞘化发病机制提供了机理上的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cell Discovery Biochemistry, Genetics and Molecular Biology-Molecular Biology

CiteScore

24.20

自引率

0.60%

发文量

120

审稿时长

20 weeks

期刊介绍： Cell Discovery is a cutting-edge, open access journal published by Springer Nature in collaboration with the Center for Excellence in Molecular Cell Science, Chinese Academy of Sciences (CAS). Our aim is to provide a dynamic and accessible platform for scientists to showcase their exceptional original research. Cell Discovery covers a wide range of topics within the fields of molecular and cell biology. We eagerly publish results of great significance and that are of broad interest to the scientific community. With an international authorship and a focus on basic life sciences, our journal is a valued member of Springer Nature's prestigious Molecular Cell Biology journals. In summary, Cell Discovery offers a fresh approach to scholarly publishing, enabling scientists from around the world to share their exceptional findings in molecular and cell biology.