Cux2在Notch信号下游发挥作用,以调节脊髓中背侧中间神经元的形成。
Cux2 functions downstream of Notch signaling to regulate dorsal interneuron formation in the spinal cord.
作者信息
Iulianella Angelo, Sharma Madhulika, Vanden Heuvel Greg B, Trainor Paul A
机构信息
Stowers Institute for Medical Research, 1000 E. 50th Street, Kansas City, MO 64110, USA.
出版信息
Development. 2009 Jul;136(14):2329-34. doi: 10.1242/dev.032128.
Abstract
Obtaining the diversity of interneuron subtypes in their appropriate numbers requires the orchestrated integration of progenitor proliferation with the regulation of differentiation. Here we demonstrate through loss-of-function studies in mice that the Cut homeodomain transcription factor Cux2 (Cutl2) plays an important role in regulating the formation of dorsal spinal cord interneurons. Furthermore, we show that Notch regulates Cux2 expression. Although Notch signaling can be inhibitory to the expression of proneural genes, it is also required for interneuron formation during spinal cord development. Our findings suggest that Cux2 might mediate some of the effects of Notch signaling on interneuron formation. Together with the requirement for Cux2 in cell cycle progression, our work highlights the mechanistic complexity in balancing neural progenitor maintenance and differentiation during spinal cord neurogenesis.
摘要
要获得数量合适的中间神经元亚型的多样性,需要将祖细胞增殖与分化调控进行精心整合。在此,我们通过对小鼠进行功能缺失研究证明,Cut同源结构域转录因子Cux2(Cutl2)在调节脊髓背侧中间神经元的形成中发挥重要作用。此外,我们表明Notch调节Cux2的表达。虽然Notch信号传导可能抑制神经前体基因的表达,但它在脊髓发育过程中对中间神经元的形成也是必需的。我们的研究结果表明,Cux2可能介导Notch信号传导对中间神经元形成的一些影响。连同Cux2在细胞周期进程中的需求,我们的工作突出了脊髓神经发生过程中平衡神经祖细胞维持和分化的机制复杂性。
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