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直接重编程的脆性X综合征背侧前脑前体细胞产生表现出神经元成熟受损的皮质神经元。

Directly reprogrammed fragile X syndrome dorsal forebrain precursor cells generate cortical neurons exhibiting impaired neuronal maturation.

作者信息

Edwards Nicole, Combrinck Catharina, McCaughey-Chapman Amy, Connor Bronwen

机构信息

Department of Pharmacology and Clinical Pharmacology, Centre for Brain Research, School of Medical Science, Faculty of Medical and Health Sciences, University of Auckland, Auckland, New Zealand.

出版信息

Front Cell Neurosci. 2023 Sep 21;17:1254412. doi: 10.3389/fncel.2023.1254412. eCollection 2023.

DOI:10.3389/fncel.2023.1254412
PMID:37810261
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10552551/
Abstract

INTRODUCTION

The neurodevelopmental disorder fragile X syndrome (FXS) is the most common monogenic cause of intellectual disability associated with autism spectrum disorder. Inaccessibility to developing human brain cells is a major barrier to studying FXS. Direct-to-neural precursor reprogramming provides a unique platform to investigate the developmental profile of FXS-associated phenotypes throughout neural precursor and neuron generation, at a temporal resolution not afforded by post-mortem tissue and in a patient-specific context not represented in rodent models. Direct reprogramming also circumvents the protracted culture times and low efficiency of current induced pluripotent stem cell strategies.

METHODS

We have developed a chemically modified mRNA (cmRNA) -based direct reprogramming protocol to generate dorsal forebrain precursors (hiDFPs) from FXS patient-derived fibroblasts, with subsequent differentiation to glutamatergic cortical neurons and astrocytes.

RESULTS

We observed differential expression of mature neuronal markers suggesting impaired neuronal development and maturation in FXS- hiDFP-derived neurons compared to controls. FXS- hiDFP-derived cortical neurons exhibited dendritic growth and arborization deficits characterized by reduced neurite length and branching consistent with impaired neuronal maturation. Furthermore, FXS- hiDFP-derived neurons exhibited a significant decrease in the density of pre- and post- synaptic proteins and reduced glutamate-induced calcium activity, suggesting impaired excitatory synapse development and functional maturation. We also observed a reduced yield of FXS- hiDFP-derived neurons with a significant increase in FXS-affected astrocytes.

DISCUSSION

This study represents the first reported derivation of FXS-affected cortical neurons following direct reprogramming of patient fibroblasts to dorsal forebrain precursors and subsequently neurons that recapitulate the key molecular hallmarks of FXS as it occurs in human tissue. We propose that direct to hiDFP reprogramming provides a unique platform for further study into the pathogenesis of FXS as well as the identification and screening of new drug targets for the treatment of FXS.

摘要

引言

神经发育障碍脆性X综合征(FXS)是与自闭症谱系障碍相关的最常见的单基因智力残疾病因。无法获取发育中的人类脑细胞是研究FXS的主要障碍。直接重编程为神经前体细胞提供了一个独特的平台,可在整个神经前体细胞和神经元生成过程中,以死后组织无法提供的时间分辨率,在啮齿动物模型中未体现的患者特异性背景下,研究FXS相关表型的发育概况。直接重编程还规避了当前诱导多能干细胞策略中漫长的培养时间和低效率问题。

方法

我们开发了一种基于化学修饰mRNA(cmRNA)的直接重编程方案,从FXS患者来源的成纤维细胞中生成背侧前脑前体细胞(hiDFP),随后将其分化为谷氨酸能皮质神经元和星形胶质细胞。

结果

我们观察到成熟神经元标志物的差异表达,表明与对照组相比,FXS-hiDFP来源的神经元中神经元发育和成熟受损。FXS-hiDFP来源的皮质神经元表现出树突生长和分支缺陷,其特征是神经突长度和分支减少,这与神经元成熟受损一致。此外,FXS-hiDFP来源的神经元在突触前和突触后蛋白密度上显著降低,谷氨酸诱导的钙活性降低,表明兴奋性突触发育和功能成熟受损。我们还观察到FXS-hiDFP来源的神经元产量降低,而受FXS影响的星形胶质细胞显著增加。

讨论

本研究首次报道了将患者成纤维细胞直接重编程为背侧前脑前体细胞,随后重编程为神经元,这些神经元概括了人类组织中发生的FXS的关键分子特征。我们认为,直接重编程为hiDFP为进一步研究FXS的发病机制以及识别和筛选治疗FXS的新药物靶点提供了一个独特的平台。

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本文引用的文献

1
Aberrant astrocyte protein secretion contributes to altered neuronal development in multiple models of neurodevelopmental disorders.异常的星形胶质细胞蛋白分泌导致多种神经发育障碍模型中神经元发育异常。
Nat Neurosci. 2022 Sep;25(9):1163-1178. doi: 10.1038/s41593-022-01150-1. Epub 2022 Aug 30.
2
Comment on Herring et al. The Use of "Retardation" in FRAXA, FMRP, FMR1 and Other Designations. 2022, , 1044.评 Herring 等人的《脆性 X 智力低下蛋白、FMRP、FMR1 及其他命名中“迟钝”一词的使用》。2022 年, ,1044 页。
Cells. 2022 Jun 16;11(12):1937. doi: 10.3390/cells11121937.
3
Small Molecules Enhance Reprogramming of Adult Human Dermal Fibroblasts to Dorsal Forebrain Precursor Cells.
小分子增强成人人类皮肤成纤维细胞重编程为背侧前脑前体细胞的过程。
Stem Cells Dev. 2022 Feb;31(3-4):78-89. doi: 10.1089/scd.2021.0130. Epub 2022 Jan 21.
4
FMRP and MOV10 regulate Dicer1 expression and dendrite development.脆性 X 智力低下蛋白(FMRP)和 MOV10 调节 Dicer1 的表达和树突发育。
PLoS One. 2021 Nov 30;16(11):e0260005. doi: 10.1371/journal.pone.0260005. eCollection 2021.
5
A human forebrain organoid model of fragile X syndrome exhibits altered neurogenesis and highlights new treatment strategies.脆性 X 综合征的人类大脑器官模型表现出神经发生改变,并突出了新的治疗策略。
Nat Neurosci. 2021 Oct;24(10):1377-1391. doi: 10.1038/s41593-021-00913-6. Epub 2021 Aug 19.
6
Novel fragile X syndrome 2D and 3D brain models based on human isogenic FMRP-KO iPSCs.基于人类同源性 FMRP-KO iPSCs 的新型脆性 X 综合征 2D 和 3D 脑模型。
Cell Death Dis. 2021 May 15;12(5):498. doi: 10.1038/s41419-021-03776-8.
7
Cell-type-specific profiling of human cellular models of fragile X syndrome reveal PI3K-dependent defects in translation and neurogenesis.脆性 X 综合征人类细胞模型的细胞类型特异性分析揭示了 PI3K 依赖性翻译和神经发生缺陷。
Cell Rep. 2021 Apr 13;35(2):108991. doi: 10.1016/j.celrep.2021.108991.
8
Channelopathies in fragile X syndrome.脆性 X 综合征中的通道病。
Nat Rev Neurosci. 2021 May;22(5):275-289. doi: 10.1038/s41583-021-00445-9. Epub 2021 Apr 7.
9
SNT: a unifying toolbox for quantification of neuronal anatomy.SNT:神经元解剖结构定量分析的统一工具包。
Nat Methods. 2021 Apr;18(4):374-377. doi: 10.1038/s41592-021-01105-7. Epub 2021 Apr 1.
10
The molecular biology of FMRP: new insights into fragile X syndrome.脆性 X 综合征的 FMRP 分子生物学:新见解。
Nat Rev Neurosci. 2021 Apr;22(4):209-222. doi: 10.1038/s41583-021-00432-0. Epub 2021 Feb 19.