Ahonen Leena J, Kallio Marko J, Daum John R, Bolton Margaret, Manke Isaac A, Yaffe Michael B, Stukenberg P Todd, Gorbsky Gary J
Molecular, Cell and Developmental Biology Research Program, Oklahoma Medical Research Foundation, Oklahoma City, OK 73104, USA.
Curr Biol. 2005 Jun 21;15(12):1078-89. doi: 10.1016/j.cub.2005.05.026.
In mitosis, a mechanochemical system recognizes tension that is generated by bipolar microtubule attachment to sister kinetochores. This is translated into multiple outputs including the stabilization of microtubule attachments, changes in kinetochore protein dynamics, and the silencing of the spindle checkpoint. How kinetochores sense tension and translate this into various signals represent critical unanswered questions. The kinetochores of chromosomes not under tension are specifically phosphorylated at an epitope recognized by the 3F3/2 monoclonal antibody. Determining the kinase that generates the 3F3/2 phosphoepitope at kinetochores should reveal an important component of this system that regulates mitotic progression.
We demonstrate that Polo-like kinase 1 (Plk1) creates the 3F3/2 phosphoepitope on mitotic kinetochores. In a permeabilized in vitro cell system, the depletion of Xenopus Plk1 from M phase extract leads to the loss of 3F3/2 kinase activity. Purified recombinant Plk1 is sufficient to generate the 3F3/2 phosphoepitope in this system. Using siRNA, we show that the reduction of Plk1 protein levels significantly diminishes 3F3/2 phosphoepitope expression at kinetochores. The consensus phosphorylation sites of Plk1 show strong similarity to the 3F3/2 phosphoepitope sequence determined by phosphopeptide mapping. The inhibition of Plk1 by siRNA alters the normal kinetochore association of Mad2, Cenp-E, Hec1/Ndc80, Spc24, and Cdc20 and induces a spindle-checkpoint-mediated mitotic arrest.
Plk1 generates the 3F3/2 phosphoepitope at kinetochores that are not under tension and contributes to the normal kinetochore association of several key proteins important in checkpoint signaling. Mechanical tension regulates Plk1 accumulation at kinetochores and possibly its kinase activity.
在有丝分裂过程中,一个机械化学系统能够识别由双极微管附着于姐妹动粒所产生的张力。这会转化为多种输出,包括微管附着的稳定、动粒蛋白动力学的变化以及纺锤体检查点的沉默。动粒如何感知张力并将其转化为各种信号是尚未解决的关键问题。未受张力作用的染色体动粒在一个可被3F3/2单克隆抗体识别的表位上发生特异性磷酸化。确定在动粒上产生3F3/2磷酸表位的激酶应能揭示该调节有丝分裂进程系统的一个重要组成部分。
我们证明Polo样激酶1(Plk1)在有丝分裂动粒上产生3F3/2磷酸表位。在一个通透的体外细胞系统中,从M期提取物中去除非洲爪蟾Plk1会导致3F3/2激酶活性丧失。纯化的重组Plk1在该系统中足以产生3F3/2磷酸表位。使用小干扰RNA(siRNA),我们表明Plk1蛋白水平的降低显著减少了动粒上3F3/2磷酸表位的表达。Plk1的共有磷酸化位点与通过磷酸肽图谱确定的3F3/2磷酸表位序列具有很强的相似性。通过siRNA抑制Plk1会改变Mad2、Cenp-E、Hec1/Ndc80、Spc24和Cdc20的正常动粒结合,并诱导纺锤体检查点介导的有丝分裂停滞。
Plk1在未受张力的动粒上产生3F3/2磷酸表位,并有助于几种在检查点信号传导中重要的关键蛋白的正常动粒结合。机械张力调节Plk1在动粒上的积累及其可能的激酶活性。
