果蝇酪蛋白激酶 1g gilgamesh 是肌球蛋白依赖性连接强化和上皮折叠的必要条件

Lingkun Gu, Reina Benefiel, Jasneet Brar, Mo Weng
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摘要

粘连接头是细胞之间的主要物理连接,在张力作用下会发生重塑,以保持组织的完整性并促进组织形状的改变。然而,驱动这一过程的体内机制仍然鲜为人知。在这里,我们发现了 Gilgamesh(Gish),它是酪蛋白激酶 1g 的保守同源物,是果蝇中胚层顶端收缩过程中肌球蛋白依赖性连接强化和组织折叠的关键。我们的研究表明,Gish 是以肌球蛋白依赖性收缩的方式被招募到粘连连接点的。在顶端收缩过程中,Gish需要通过促进小连接点的生长和合并以及稳定细胞边缘的连接点来加强连接。在缺失 Gish 的中胚层中,连接缺陷导致组织规模的顶端肌动蛋白网络在顶端收缩过程中断裂,最终导致中胚层折叠失败。我们的数据表明,Gish 是一种机械敏感激酶,在顶端收缩过程中对粘连接头的完整性是必需的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
gilgamesh, Drosophila casein kinase 1g, is required for myosin-dependent junction strengthening and epithelial folding
Adherens junctions, which serve as the primary physical link between cells, undergo remodeling in response to tension forces to maintain tissue integrity and promote tissue shape changes. However, the in vivo mechanisms driving this process remain poorly understood. Here, we identified Gilgamesh (Gish), the conserved fly homolog of casein kinase 1g as essential for myosin-dependent junction strengthening and tissue folding during apical constriction of Drosophila mesoderm. We show that Gish is recruited to spot adherens junctions in a contractile myosin-dependent manner. During apical constriction, Gish is required for junction strengthening by promoting growth and merging of small junction puncta, as well as stabilizing junction puncta at cell edges. The junction defects in Gish-depleted mesoderm result in breakage of the tissue-scale apical actomyosin network during apical constriction, and ultimately failure in mesoderm infolding. Our data show that Gish is a mechanosensitive kinase required for the integrity of adherens junctions during apical constriction.
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