用ER-Hoxb8条件永生化巨噬细胞替代小胶质细胞可深入了解艾卡迪-古蒂耶尔综合征神经病理学

Kelsey M Nemec, Genevieve Uy, V. Sai Chaluvadi, Freddy S Purnell, Bilal Elfayoumi, Carleigh O'Brien, William H Aisenberg, Sonia I Lombroso, Xinfeng Guo, Niklas Blank, Chet Huan Oon, Fazeela Yaqoob, Brian Temsamrit, Priyanka Rawat, Christoph Thaiss, Qingde Wang, Mariko L Bennett, F. Chris Bennett
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引用次数: 0

摘要

小胶质细胞是大脑中的常驻巨噬细胞,可以通过代用细胞重建--这一过程被称为 "小胶质细胞替代"。为了扩展小胶质细胞替代工具包,我们在这里引入了雌激素调控(ER)同源染色体 B8(Hoxb8)条件永生化巨噬细胞--一种从小鼠骨髓中生成免疫细胞的细胞模型--作为小胶质细胞替代的多功能模型。我们发现,ER-Hoxb8 巨噬细胞在体外与原发性骨髓来源(BMD)巨噬细胞高度相似,当移植到无小胶质细胞的大脑中时,能吞噬实质细胞并分化成小胶质细胞样细胞。此外,ER-Hoxb8 祖细胞很容易被病毒转导,并容易储存为稳定的基因操作细胞系。为了证明该系统在研究疾病突变对体内小胶质细胞的影响方面的强大功能,我们利用 CRISPR-Cas9 技术创建了稳定的 Adar1 突变 ER-Hoxb8 株系,以研究巨噬细胞对艾卡迪-古蒂耶尔综合征(AGS)的内在贡献,AGS 是一种遗传性干扰素病,主要影响大脑和免疫系统。我们发现 Adar1 基因敲除会引起体外干扰素分泌和巨噬细胞生成受损,同时阻碍体内脑巨噬细胞的移植--这些表型可以通过同时突变体外的 Ifih1 (MDA5) 而得到挽救,但在体内却不能。最后,我们通过从携带患者特异性 Adar1 突变(D1113H)的小鼠体内产生 ER-Hoxb8 祖细胞,扩展了这些发现。我们证明了小胶质细胞特异性 D1113H 突变在体内驱动干扰素产生的能力,这表明小胶质细胞驱动了 AGS 神经病理学。总之,我们引入了 ER-Hoxb8 方法来建立小胶质细胞替代模型,并用它来阐明巨噬细胞对 AGS 的贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microglia replacement by ER-Hoxb8 conditionally immortalized macrophages provides insight into Aicardi-Goutières Syndrome neuropathology
Microglia, the brain’s resident macrophages, can be reconstituted by surrogate cells - a process termed “microglia replacement.” To expand the microglia replacement toolkit, we here introduce estrogen-regulated (ER) homeobox B8 (Hoxb8) conditionally immortalized macrophages, a cell model for generation of immune cells from murine bone marrow, as a versatile model for microglia replacement. We find that ER-Hoxb8 macrophages are highly comparable to primary bone marrow-derived (BMD) macrophages in vitro, and, when transplanted into a microglia-free brain, engraft the parenchyma and differentiate into microglia-like cells. Furthermore, ER-Hoxb8 progenitors are readily transducible by virus and easily stored as stable, genetically manipulated cell lines. As a demonstration of this system’s power for studying the effects of disease mutations on microglia in vivo, we created stable, Adar1-mutated ER-Hoxb8 lines using CRISPR-Cas9 to study the intrinsic contribution of macrophages to Aicardi-Goutières Syndrome (AGS), an inherited interferonopathy that primarily affects the brain and immune system. We find that Adar1 knockout elicited interferon secretion and impaired macrophage production in vitro, while preventing brain macrophage engraftment in vivo - phenotypes that can be rescued with concurrent mutation of Ifih1 (MDA5) in vitro, but not in vivo. Lastly, we extended these findings by generating ER-Hoxb8 progenitors from mice harboring a patient-specific Adar1 mutation (D1113H). We demonstrated the ability of microglia-specific D1113H mutation to drive interferon production in vivo, suggesting microglia drive AGS neuropathology. In sum, we introduce the ER-Hoxb8 approach to model microglia replacement and use it to clarify macrophage contributions to AGS.
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