RING蛋白PAR-2的皮质极性通过皮质-细胞质边界处的交换速率动力学得以维持。

Cortical Polarity of the RING Protein PAR-2 Is Maintained by Exchange Rate Kinetics at the Cortical-Cytoplasmic Boundary.

作者信息

Arata Yukinobu, Hiroshima Michio, Pack Chan-Gi, Ramanujam Ravikrishna, Motegi Fumio, Nakazato Kenichi, Shindo Yuki, Wiseman Paul W, Sawa Hitoshi, Kobayashi Tetsuya J, Brandão Hugo B, Shibata Tatsuo, Sako Yasushi

机构信息

Cellular Informatics Laboratory, RIKEN, Wako, Saitama 351-0198, Japan.

Cellular Informatics Laboratory, RIKEN, Wako, Saitama 351-0198, Japan; Laboratory for Cell Signaling Dynamics, Quantitative Biology Center (QBiC), RIKEN, Suita, Osaka 565-0874, Japan.

出版信息

Cell Rep. 2016 Aug 23;16(8):2156-2168. doi: 10.1016/j.celrep.2016.07.047. Epub 2016 Aug 11.

DOI:10.1016/j.celrep.2016.07.047

PMID:27524610

Abstract

Cell polarity arises through the spatial segregation of polarity regulators. PAR proteins are polarity regulators that localize asymmetrically to two opposing cortical domains. However, it is unclear how the spatially segregated PAR proteins interact to maintain their mutually exclusive partitioning. Here, single-molecule detection analysis in Caenorhabditis elegans embryos reveals that cortical PAR-2 diffuses only short distances, and, as a result, most PAR-2 molecules associate and dissociate from the cortex without crossing into the opposing domain. Our results show that cortical PAR-2 asymmetry is maintained by the local exchange reactions that occur at the cortical-cytoplasmic boundary. Additionally, we demonstrate that local exchange reactions are sufficient to maintain cortical asymmetry in a parameter-free mathematical model. These findings suggest that anterior and posterior PAR proteins primarily interact through the cytoplasmic pool and not via cortical diffusion.

摘要

细胞极性通过极性调节因子的空间隔离而产生。PAR蛋白是极性调节因子，它们不对称地定位于两个相对的皮质结构域。然而，尚不清楚空间隔离的PAR蛋白如何相互作用以维持它们相互排斥的分布。在这里，对线虫胚胎进行的单分子检测分析表明，皮质PAR-2仅扩散很短的距离，因此，大多数PAR-2分子在皮质上结合和解离，而不会进入相对的结构域。我们的结果表明，皮质PAR-2的不对称性通过在皮质-细胞质边界发生的局部交换反应得以维持。此外，我们证明在无参数数学模型中局部交换反应足以维持皮质不对称性。这些发现表明，前部和后部PAR蛋白主要通过细胞质池相互作用，而不是通过皮质扩散。

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RING蛋白PAR-2的皮质极性通过皮质-细胞质边界处的交换速率动力学得以维持。

Cortical Polarity of the RING Protein PAR-2 Is Maintained by Exchange Rate Kinetics at the Cortical-Cytoplasmic Boundary.

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