PIP5K-Ras 双稳态性引发质膜对称性破坏,从而调节细胞极性和迁移

Yu Deng, Tatsat Banerjee, Dhiman Sankar Pal, Parijat Banerjee, Huiwang David Zhan, Jane Borleis, Pablo A Iglesias, Peter Devreotes
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摘要

对称性打破、极性建立和自发性细胞突起的形成是细胞的基本行为,但却鲜有解释。在这里,我们证明了一个生化网络支配着这些过程,其中 PIP5K 和 Ras 活性的相互抑制定位起着核心作用。首先,在没有细胞骨架活动的静息细胞中,PIP5K 在质膜上均匀升高,而 Ras 的活性保持最低。PIP5K 的自发局部位移打破了对称性,同时激活了 Ras 和下游信号事件,包括 PI3K 激活。其次,敲除 PIP5K 会显著增加 Ras-PI3K 激活斑块的发生率和大小,并伴随着 F-肌动蛋白的分枝组装。这导致皮质波形成增强、突起活动增加以及迁移模式的转变。第三,PIP5K 的高度诱导性过表达几乎消除了 Ras-PI3K 信号、细胞骨架活性和细胞迁移,而细胞膜 PIP5K 的急性招募诱导了癌细胞的收缩和出血点。降低肌球蛋白 II 的活性可逆转这些停滞表型,这表明肌球蛋白 II 参与了以 PIP5K-Ras 为中心的调控网络。值得注意的是,PIP5K 的低诱导性过表达出乎意料地促进了极性的建立,这突出表明 PIP5K 是这些过程中高度敏感的主调控因子。结合可兴奋系统、细胞骨架环路和 PIP5K 动态分配的计算模型模拟再现了实验观察结果。综上所述,我们的研究结果表明,质膜上 PIP5K 和活性 Ras 的双稳态、互斥定位触发了最初的对称性破缺。肌动蛋白减少和肌动蛋白聚合增加的耦合作用导致间歇性延伸突起,在细胞骨架的反馈下,PIP5K 和 Ras 的自组织互补梯度陡峭化,在后部提高网络阈值,在前部降低阈值,从而产生细胞迁移的极性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
PIP5K-Ras bistability initiates plasma membrane symmetry breaking to regulate cell polarity and migration
Symmetry breaking, polarity establishment, and spontaneous cell protrusion formation are fundamental but poorly explained cell behaviors. Here, we demonstrate that a biochemical network, where the mutually inhibitory localization of PIP5K and Ras activities plays a central role, governs these processes. First, in resting cells devoid of cytoskeletal activity, PIP5K is uniformly elevated on the plasma membrane, while Ras activity remains minimal. Symmetry is broken by spontaneous local displacements of PIP5K, coupled with simultaneous activations of Ras and downstream signaling events, including PI3K activation. Second, knockout of PIP5K dramatically increases both the incidence and size of Ras-PI3K activation patches, accompanied by branched F-actin assembly. This leads to enhanced cortical wave formation, increased protrusive activity, and a shift in migration mode. Third, high inducible overexpression of PIP5K virtually eliminates Ras-PI3K signaling, cytoskeletal activity, and cell migration, while acute recruitment of cytosolic PIP5K to the membrane induces contraction and blebs in cancer cells. These arrested phenotypes are reversed by reducing myosin II activity, indicating myosin II involvement in the PIP5K-Ras-centered regulatory network. Remarkably, low inducible overexpression of PIP5K unexpectedly facilitates polarity establishment, highlighting PIP5K as a highly sensitive master regulator of these processes. Simulations of a computational model combining an excitable system, cytoskeletal loops, and dynamic partitioning of PIP5K recreates the experimental observations. Taken together, our results reveal that a bistable, mutually exclusive localization of PIP5K and active Ras on the plasma membrane triggers the initial symmetry breaking. Coupled actomyosin reduction and increased actin polymerization lead to intermittently extended protrusions and, with feedback from the cytoskeleton, self-organizing, complementary gradients of PIP5K versus Ras steepen, raising the threshold of the networks at the rear and lowering it at the front to generate polarity for cell migration.
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