肌分化因子MyoD向神经源性因子的转变：结合位点特异性决定细胞谱系。

Conversion of MyoD to a neurogenic factor: binding site specificity determines lineage.

作者信息

Fong Abraham P, Yao Zizhen, Zhong Jun Wen, Johnson Nathan M, Farr Gist H, Maves Lisa, Tapscott Stephen J

机构信息

Clinical Research Division, Fred Hutchinson Cancer Research Center, Seattle, WA 98109, USA; Department of Pediatrics, Division of Hematology-Oncology, University of Washington School of Medicine, Seattle, WA 98105, USA.

Human Biology Division, Fred Hutchinson Cancer Research Center, Seattle, WA 98109, USA.

出版信息

Cell Rep. 2015 Mar 31;10(12):1937-46. doi: 10.1016/j.celrep.2015.02.055. Epub 2015 Mar 19.

DOI:10.1016/j.celrep.2015.02.055

PMID:25801030

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4683018/

Abstract

MyoD and NeuroD2, master regulators of myogenesis and neurogenesis, bind to a "shared" E-box sequence (CAGCTG) and a "private" sequence (CAGGTG or CAGATG, respectively). To determine whether private-site recognition is sufficient to confer lineage specification, we generated a MyoD mutant with the DNA-binding specificity of NeuroD2. This chimeric mutant gained binding to NeuroD2 private sites but maintained binding to a subset of MyoD-specific sites, activating part of both the muscle and neuronal programs. Sequence analysis revealed an enrichment for PBX/MEIS motifs at the subset of MyoD-specific sites bound by the chimera, and point mutations that prevent MyoD interaction with PBX/MEIS converted the chimera to a pure neurogenic factor. Therefore, redirecting MyoD binding from MyoD private sites to NeuroD2 private sites, despite preserved binding to the MyoD/NeuroD2 shared sites, is sufficient to change MyoD from a master regulator of myogenesis to a master regulator of neurogenesis.

摘要

成肌和神经发生的主要调节因子MyoD和NeuroD2，分别与一个“共享”的E盒序列（CAGCTG）和一个“专属”序列（分别为CAGGTG或CAGATG）结合。为了确定专属位点识别是否足以赋予细胞谱系特异性，我们生成了一个具有NeuroD2 DNA结合特异性的MyoD突变体。这个嵌合突变体获得了与NeuroD2专属位点的结合能力，但仍保留了与一部分MyoD特异性位点的结合能力，从而激活了肌肉和神经元程序的一部分。序列分析显示，在该嵌合体结合的MyoD特异性位点子集中，PBX/MEIS基序富集，并且阻止MyoD与PBX/MEIS相互作用的点突变将该嵌合体转变为一个纯粹的神经源性因子。因此，尽管保留了与MyoD/NeuroD2共享位点的结合，但将MyoD的结合从MyoD专属位点重定向到NeuroD2专属位点，足以使MyoD从成肌的主要调节因子转变为神经发生的主要调节因子。

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