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LGN 中的分子内相互作用,一种调节有丝分裂纺锤体取向的衔接蛋白。

Intramolecular interaction in LGN, an adaptor protein that regulates mitotic spindle orientation.

机构信息

Department of Biochemistry, Kyushu University Graduate School of Medical Sciences, Fukuoka 812-8582, Japan.

Department of Biochemistry, Kyushu University Graduate School of Medical Sciences, Fukuoka 812-8582, Japan

出版信息

J Biol Chem. 2019 Dec 20;294(51):19655-19666. doi: 10.1074/jbc.RA119.011457. Epub 2019 Nov 15.

Abstract

Proper mitotic spindle orientation requires that astral microtubules are connected to the cell cortex by the microtubule-binding protein NuMA, which is recruited from the cytoplasm. Cortical recruitment of NuMA is at least partially mediated via direct binding to the adaptor protein LGN. LGN normally adopts a closed conformation via an intramolecular interaction between its N-terminal NuMA-binding domain and its C-terminal region that contains four GoLoco (GL) motifs, each capable of binding to the membrane-anchored Gα subunit of heterotrimeric G protein. Here we show that the intramolecular association with the N-terminal domain in LGN involves GL3, GL4, and a region between GL2 and GL3, whereas GL1 and GL2 do not play a major role. This conformation renders GL1 but not the other GL motifs in a state easily accessible to Gα To interact with full-length LGN in a closed state, NuMA requires the presence of Gα; both NuMA and Gα are essential for cortical recruitment of LGN in mitotic cells. In contrast, mInsc, a protein that competes with NuMA for binding to LGN and regulates mitotic spindle orientation in asymmetric cell division, efficiently binds to full-length LGN without Gα and induces its conformational change, enhancing its association with Gα In nonpolarized symmetrically dividing HeLa cells, disruption of the LGN-NuMA interaction by ectopic expression of mInsc results in a loss of cortical localization of NuMA during metaphase and anaphase and promotes mitotic spindle misorientation and a delayed anaphase progression. These findings highlight a specific role for LGN-mediated cell cortex recruitment of NuMA.

摘要

正确的有丝分裂纺锤体定向需要星体微管通过微管结合蛋白 NuMA 与细胞皮层连接,NuMA 从细胞质中募集。NuMA 向皮层募集至少部分通过与衔接蛋白 LGN 的直接结合介导。LGN 通常通过其 N 端 NuMA 结合域与其包含四个 GoLoco (GL) 基序的 C 端区域之间的分子内相互作用采用封闭构象,每个 GL 基序都能够与异源三聚体 G 蛋白的膜锚定 Gα 亚基结合。在这里,我们表明 LGN 中的分子内与 N 端结构域的关联涉及 GL3、GL4 和 GL2 与 GL3 之间的区域,而 GL1 和 GL2 不发挥主要作用。这种构象使 GL1 但不是其他 GL 基序处于易于与 Gα 相互作用的状态。为了以封闭状态与全长 LGN 相互作用,NuMA 需要 Gα 的存在;NuMA 和 Gα 对于有丝分裂细胞中 LGN 的皮层募集都是必不可少的。相比之下,mInsc,一种与 NuMA 竞争与 LGN 结合并调节不对称细胞分裂中纺锤体定向的蛋白质,在没有 Gα 的情况下有效地与全长 LGN 结合并诱导其构象变化,增强与 Gα 的结合。在非极化对称分裂的 HeLa 细胞中,通过异位表达 mInsc 破坏 LGN-NuMA 相互作用导致中期和后期的 NuMA 皮层定位丧失,并促进有丝分裂纺锤体错位和后期进展延迟。这些发现突出了 LGN 介导的 NuMA 细胞皮层募集的特定作用。

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