在人类外胚层模型中,管腔扩张最初由顶端肌动蛋白聚合驱动,随后由渗透压驱动

IF 19.8 1区 医学 Q1 CELL & TISSUE ENGINEERING
Dhiraj Indana, Andrei Zakharov, Youngbin Lim, Alexander R. Dunn, Nidhi Bhutani, Vivek B. Shenoy, Ovijit Chaudhuri
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引用次数: 0

摘要

胚胎植入后,人类胚胎的多能上胚层会形成一个中央管腔,为胃形成铺平道路。渗透压梯度被认为是整个发育过程中管腔扩张的驱动力,但它们在人类上胚层中的作用尚不清楚。在这里,我们使用工程水凝胶研究了基于多能干细胞的上胚层模型中的管腔形成。我们发现,渗漏连接阻止了早期上胚泡中的渗透压梯度,相反,顶端肌动蛋白聚合的力量推动了管腔的扩张。一旦管腔半径达到 12 μm,紧密连接就会成熟,渗透压梯度就会形成,从而推动管腔进一步生长。计算模型表明,顶端肌动蛋白聚合成一个坚硬的网络介导了最初的管腔扩张,并预测较大的外胚层会过渡到压力驱动的生长,以避免弯曲。人类外胚层显示出与这些机制一致的转录特征。因此,肌动蛋白聚合推动了人类上胚层的管腔扩张,并可能成为早期管腔形成的一般机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Lumen expansion is initially driven by apical actin polymerization followed by osmotic pressure in a human epiblast model

Lumen expansion is initially driven by apical actin polymerization followed by osmotic pressure in a human epiblast model

Post-implantation, the pluripotent epiblast in a human embryo forms a central lumen, paving the way for gastrulation. Osmotic pressure gradients are considered the drivers of lumen expansion across development, but their role in human epiblasts is unknown. Here, we study lumenogenesis in a pluripotent-stem-cell-based epiblast model using engineered hydrogels. We find that leaky junctions prevent osmotic pressure gradients in early epiblasts and, instead, forces from apical actin polymerization drive lumen expansion. Once the lumen reaches a radius of ∼12 μm, tight junctions mature, and osmotic pressure gradients develop to drive further growth. Computational modeling indicates that apical actin polymerization into a stiff network mediates initial lumen expansion and predicts a transition to pressure-driven growth in larger epiblasts to avoid buckling. Human epiblasts show transcriptional signatures consistent with these mechanisms. Thus, actin polymerization drives lumen expansion in the human epiblast and may serve as a general mechanism of early lumenogenesis.

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来源期刊
Cell stem cell
Cell stem cell 生物-细胞生物学
CiteScore
37.10
自引率
2.50%
发文量
151
审稿时长
42 days
期刊介绍: Cell Stem Cell is a comprehensive journal covering the entire spectrum of stem cell biology. It encompasses various topics, including embryonic stem cells, pluripotency, germline stem cells, tissue-specific stem cells, differentiation, epigenetics, genomics, cancer stem cells, stem cell niches, disease models, nuclear transfer technology, bioengineering, drug discovery, in vivo imaging, therapeutic applications, regenerative medicine, clinical insights, research policies, ethical considerations, and technical innovations. The journal welcomes studies from any model system providing insights into stem cell biology, with a focus on human stem cells. It publishes research reports of significant importance, along with review and analysis articles covering diverse aspects of stem cell research.
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