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一条右手性信号通路驱动脊椎动物心脏的环化。

A right-handed signalling pathway drives heart looping in vertebrates.

作者信息

Ocaña Oscar H, Coskun Hakan, Minguillón Carolina, Murawala Prayag, Tanaka Elly M, Galcerán Joan, Muñoz-Chápuli Ramón, Nieto M Angela

机构信息

Instituto de Neurociencias (CSIC-UMH), Avenida Ramón y Cajal, s/n, Sant Joan d'Alacant, Alicante, Spain.

Institut de Biologia Molecular de Barcelona, CSIC, Barcelona, Spain.

出版信息

Nature. 2017 Sep 6;549(7670):86-90. doi: 10.1038/nature23454.

DOI:10.1038/nature23454
PMID:28880281
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5590727/
Abstract

Most animals show external bilateral symmetry, which hinders the observation of multiple internal left-right (L/R) asymmetries that are fundamental to organ packaging and function. In vertebrates, left identity is mediated by the left-specific Nodal-Pitx2 axis that is repressed on the right-hand side by the epithelial-mesenchymal transition (EMT) inducer Snail1 (refs 3, 4). Despite some existing evidence, it remains unclear whether an equivalent instructive pathway provides right-hand-specific information to the embryo. Here we show that, in zebrafish, BMP mediates the L/R asymmetric activation of another EMT inducer, Prrx1a, in the lateral plate mesoderm with higher levels on the right. Prrx1a drives L/R differential cell movements towards the midline, leading to a leftward displacement of the cardiac posterior pole through an actomyosin-dependent mechanism. Downregulation of Prrx1a prevents heart looping and leads to mesocardia. Two parallel and mutually repressed pathways, respectively driven by Nodal and BMP on the left and right lateral plate mesoderm, converge on the asymmetric activation of the transcription factors Pitx2 and Prrx1, which integrate left and right information to govern heart morphogenesis. This mechanism is conserved in the chicken embryo, and in the mouse SNAIL1 acts in a similar manner to Prrx1a in zebrafish and PRRX1 in the chick. Thus, a differential L/R EMT produces asymmetric cell movements and forces, more prominent from the right, that drive heart laterality in vertebrates.

摘要

大多数动物表现出外部双侧对称,这阻碍了对多个内部左右(L/R)不对称性的观察,而这些不对称性对于器官的组装和功能至关重要。在脊椎动物中,左侧身份由左侧特异性的Nodal-Pitx2轴介导,该轴在右侧被上皮-间充质转化(EMT)诱导因子Snail1抑制(参考文献3、4)。尽管有一些现有证据,但尚不清楚是否存在等效的指导途径为胚胎提供右侧特异性信息。在这里,我们表明,在斑马鱼中,BMP介导另一种EMT诱导因子Prrx1a在侧板中胚层的L/R不对称激活,右侧水平更高。Prrx1a驱动L/R差异细胞向中线移动,通过肌动球蛋白依赖性机制导致心脏后极向左移位。Prrx1a的下调会阻止心脏环化并导致中位心。分别由左侧和右侧侧板中胚层上的Nodal和BMP驱动的两条平行且相互抑制的途径,汇聚于转录因子Pitx2和Prrx1的不对称激活,它们整合左右信息以控制心脏形态发生。这种机制在鸡胚中是保守的,在小鼠中,SNAIL1的作用方式与斑马鱼中的Prrx1a以及鸡中的PRRX1相似。因此,差异性的L/R EMT产生不对称的细胞运动和力,从右侧更为突出,从而驱动脊椎动物心脏的左右不对称性。

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