Deconstructing Stepwise Fate Conversion of Human Fibroblasts to Neurons by MicroRNAs.

Kitra Cates, M. McCoy, J. Kwon, Yangjian Liu, Daniel G. Abernathy, Bo Zhang, Shaopeng Liu, P. Gontarz, W. K. Kim, Shawei Chen, Wenjun Kong, Joshua N. Ho, Kyle F. Burbach, Harrison W. Gabel, Samantha A. Morris, A. Yoo
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引用次数: 28

Abstract

Cell-fate conversion generally requires reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal insights into the activity of microRNAs miR-9/9∗ and miR-124 (miR-9/9∗-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts into motor neurons by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. We identify KLF-family transcription factors as direct target genes for miR-9/9∗-124 and show their repression is critical for erasing fibroblast fate. Subsequent gain of neuronal identity requires upregulation of a small nuclear RNA, RN7SK, which induces accessibilities of chromatin regions and neuronal gene activation to push cells to a neuronal state. Our study defines deterministic components in the microRNA-mediated reprogramming cascade.
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通过微小RNA解构人类成纤维细胞向神经元的逐步命运转化。
细胞命运转换通常需要重编程效应器来引入靶细胞类型的命运程序并消除起始细胞群体的身份。在这里,我们揭示了微小RNA miR-9/9*和miR-124(miR-9/9*-124)作为重编程剂的活性,它们通过首先消除成纤维细胞的身份并促进序列中向神经元状态的均匀过渡,来协调人类成纤维细胞向运动神经元的直接转化。我们确定KLF家族转录因子是miR-9/9*-124的直接靶基因,并表明它们的抑制对消除成纤维细胞的命运至关重要。随后获得神经元身份需要上调小核RNA RN7SK,其诱导染色质区域的可及性和神经元基因激活,以将细胞推向神经元状态。我们的研究定义了微小RNA介导的重编程级联中的确定性成分。
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