有丝分裂动粒处 KNL1-BUB3 界面的顺序多位点磷酸化调控。

Sequential multisite phospho-regulation of KNL1-BUB3 interfaces at mitotic kinetochores.

机构信息

Molecular Cancer Research, University Medical Center Utrecht, 3584 CG Utrecht, The Netherlands.

Molecular Cancer Research, University Medical Center Utrecht, 3584 CG Utrecht, The Netherlands; Department of Medical Oncology, University Medical Center Utrecht, 3584 CG Utrecht, The Netherlands.

出版信息

Mol Cell. 2015 Mar 5;57(5):824-835. doi: 10.1016/j.molcel.2014.12.036. Epub 2015 Feb 5.

DOI:10.1016/j.molcel.2014.12.036

PMID:25661489

Abstract

Regulated recruitment of the kinase-adaptor complex BUB1/BUB3 to kinetochores is crucial for correcting faulty chromosome-spindle attachments and for spindle assembly checkpoint (SAC) signaling. BUB1/BUB3 localizes to kinetochores by binding phosphorylated MELT motifs (MELpT) in the kinetochore scaffold KNL1. Human KNL1 has 19 repeats that contain a MELT-like sequence. The repeats are, however, larger than MELT, and repeat sequences can vary significantly. Using systematic screening, we show that only a limited number of repeats is "active." Repeat activity correlates with the presence of a vertebrate-specific SHT motif C-terminal to the MELT sequence. SHT motifs are phosphorylated by MPS1 in a manner that requires prior phosphorylation of MELT. Phospho-SHT (SHpT) synergizes with MELpT in BUB3/BUB1 binding in vitro and in cells, and human BUB3 mutated in a predicted SHpT-binding surface cannot localize to kinetochores. Our data show sequential multisite regulation of the KNL1-BUB1/BUB3 interaction and provide mechanistic insight into evolution of the KNL1-BUB3 interface.

摘要

激酶衔接物复合物 BUB1/BUB3 向动粒的调节募集对于纠正有缺陷的染色体-纺锤体附着以及纺锤体检查点 (SAC) 信号传导至关重要。BUB1/BUB3 通过结合动粒支架 KNL1 中的磷酸化 MELT 基序 (MELpT) 而定位到动粒。人类 KNL1 有 19 个重复序列，其中包含一个 MELT 样序列。然而，这些重复序列比 MELT 大，并且重复序列可能有很大差异。通过系统筛选，我们表明只有有限数量的重复序列是“活跃的”。重复序列的活性与 MELT 序列的 C 末端存在脊椎动物特异性 SHT 基序相关。SHT 基序被 MPS1 磷酸化，其方式需要 MELT 的先前磷酸化。磷酸化的 SHT (SHpT) 在体外和细胞中与 MELpT 协同作用于 BUB3/BUB1 结合，并且在预测的 SHpT 结合表面中突变的人 BUB3 不能定位到动粒。我们的数据显示 KNL1-BUB1/BUB3 相互作用的顺序多位点调节，并为 KNL1-BUB3 界面的进化提供了机制见解。

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有丝分裂动粒处 KNL1-BUB3 界面的顺序多位点磷酸化调控。

Sequential multisite phospho-regulation of KNL1-BUB3 interfaces at mitotic kinetochores.

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