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Molecular control of macroscopic forces drives formation of the vertebrate hindgut

机译:宏观力的分子控制驱动脊椎动物后肠的形成

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摘要

The embryonic gut tube is a cylindrical structure from which the respiratory and gastrointestinal tracts develop(1). Although the early emergence of the endoderm as an epithelial sheet(2,3) and later morphogenesis of the definitive digestive and respiratory organs4-6 have been investigated, the intervening process of gut tube formation remains relatively understudied(7,8). Here we investigate the molecular control of macroscopic forces underlying early morphogenesis of the gut tube in the chick embryo. The gut tube has been described as forming from two endodermal invaginations-the anterior intestinal portal (AIP) towards the rostral end of the embryo and the caudal intestinal portal (CIP) at the caudal end-that migrate towards one another, internalizing the endoderm until they meet at the yolk stalk (umbilicus in mammals)(1,6). Migration of the AIP to form foregut has been descriptively characterized(8,9), but the hindgut is likely to form by a distinct mechanism that has not been fully explained(10). We find that the hindgut is formed by collective cell movements through a stationary CIP, rather than by movement of the CIP itself. Further, combining in vivo imaging, biophysics and mathematical modelling with molecular and embryological approaches, we identify a contractile force gradient that drives cell movements in the hindgut-forming endoderm, enabling tissue-scale posterior extension of the forming hindgut tube. The force gradient, in turn, is established in response to a morphogenic gradient of fibroblast growth factor signalling. As a result, we propose that an important positive feedback arises, whereby contracting cells draw passive cells from low to high fibroblast growth factor levels, recruiting them to contract and pull more cells into the elongating hindgut. In addition to providing insight into the early gut development, these findings illustrate how large-scale tissue level forces can be traced to developmental signals during vertebrate morphogenesis.
机译:胚肠管是一个圆柱状结构,从中发展出呼吸道和胃肠道(1)。尽管已经研究了内胚层作为上皮层的早期出现(2,3)和后来的确定性消化器官和呼吸器官的形态发生4-6,但是仍未充分研究肠管形成的干预过程(7,8)。在这里,我们研究了在雏鸡胚胎中肠道管早期形态发生基础的宏观力的分子控制。肠道管被描述为由两个内胚层内陷形成-前肠门(AIP)朝着胚胎的鼻端和尾端的尾肠门(CIP)-相互迁移,使内胚层内化直到他们在卵黄茎(哺乳动物的脐带)中相遇(1,6)。 AIP迁移到前肠的过程已被描述性地描述了(8,9),但后肠很可能是由一种尚未完全解释的独特机制形成的(10)。我们发现后肠是由通过固定CIP的集体细胞运动形成的,而不是由CIP本身的运动形成的。此外,结合体内成像,生物物理学和数学建模与分子和胚胎学方法,我们确定了收缩力梯度,其驱动后肠形成内胚层中的细胞运动,使形成的后肠管的组织规模向后延伸。继而响应于成纤维细胞生长因子信号传导的形态发生梯度来建立力梯度。结果,我们提出了一种重要的积极反馈,即收缩细胞将被动细胞从低成纤维细胞生长因子水平吸引到高成纤维细胞水平,招募它们进行收缩并将更多的细胞拉入伸长的后肠。除了提供对早期肠道发育的见解之外,这些发现还说明了在脊椎动物形态发生过程中如何将大规模的组织水平力追溯到发育信号。

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  • 来源
    《Nature》 |2019年第7740期|480-484|共5页
  • 作者

    Nerurkar Nandan L.; Lee ChangHee; Mahadevan L.; Tabin Clifford J.;

  • 作者单位

    Harvard Med Sch, Dept Genet, Boston, MA 02115 USA|Columbia Univ, Dept Biomed Engn, New York, NY 10027 USA|Columbia Univ, Dept Genet & Dev, Med Ctr, New York, NY 10027 USA;

    Harvard Med Sch, Dept Genet, Boston, MA 02115 USA;

    Harvard Univ, Sch Engn & Appl Sci, Cambridge, MA 02138 USA|Harvard Univ, Dept Organism & Evolutionary Biol, Cambridge, MA 02138 USA|Harvard Univ, Dept Phys, Cambridge, MA 02138 USA|Harvard Univ, Kavli Inst Bionano Sci & Technol, Cambridge, MA 02138 USA;

    Harvard Med Sch, Dept Genet, Boston, MA 02115 USA;

  • 收录信息 美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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  • 正文语种 eng
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  • 入库时间 2022-08-18 04:10:10

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