Commitment to cytokinetic furrowing requires the coordinate activity of microtubules and Plk1

Charles A. Day, Alyssa Langfald, Tana Lukes, Hanna Middlebrook, Kevin T. Vaughan, David J. Daniels, Edward H. Hinchcliffe
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Abstract

At anaphase, spindle microtubules (MTs) position the cleavage furrow and trigger actomyosin assembly by localizing the small GTPase RhoA and the scaffolding protein anillin to a narrow band along the equatorial cortex. Using vertebrate somatic cells we examined the temporal control of furrow assembly. Although its positioning commences at anaphase onset, furrow maturation is not complete until ~10-11 min later. The maintenance of the RhoA/anillin scaffold initially requires continuous signaling from the spindle; loss of either MTs or polo-like kinase 1 (Plk1) activity prevents proper RhoA/anillin localization to the equator, thereby disrupting furrowing. However, we find that at ~6 min post-anaphase, the cortex becomes committed to furrowing; loss of either MTs or Plk1 after this stage does not prevent eventual furrowing, even though at this point the contractile apparatus has not fully matured. Also at this stage, the RhoA/anillin scaffold at the equator becomes permanent. Surprisingly, concurrent loss of both MTs and Plk1 activity following the commitment to furrowing stage results in persistent, asymmetric half-furrows, with only one cortical hemisphere retaining RhoA/anillin, and undergoing regression. This phenotype is reminiscent of asymmetric furrows caused by a physical block between spindle and cortex, or by acentric spindle positioning. The formation of these persistent half-furrows suggests a potential feedback mechanism between the spindle and the cortex that maintains cortical competency along the presumptive equatorial region prior to the commitment to furrowing stage of cytokinesis, thereby ensuring the eventual ingression of a symmetric cleavage furrow.
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细胞动沟槽的形成需要微管和 Plk1 的协调活动
在无丝分裂期,纺锤体微管(MT)定位裂沟,并通过将小 GTP 酶 RhoA 和支架蛋白 anillin 定位于赤道皮层的一个狭窄带而触发肌动蛋白组装。我们利用脊椎动物体细胞研究了犁沟组装的时间控制。虽然沟的定位始于无丝分裂开始时,但沟的成熟直到约10-11分钟后才完成。RhoA/anillin支架的维持最初需要来自纺锤体的持续信号;MT或Polo-like激酶1(Plk1)活性的丧失会阻止RhoA/anillin正确定位到赤道,从而破坏沟的形成。然而,我们发现,在无丝分裂后约 6 分钟时,皮层开始致力于犁沟;在此阶段之后,MT 或 Plk1 的缺失并不会阻止最终的犁沟,尽管此时收缩装置尚未完全成熟。也是在这一阶段,赤道上的 RhoA/anillin 支架变得永久性。令人惊奇的是,在进入犁沟阶段后,MT 和 Plk1 活性的同时丧失会导致持续的不对称半犁沟,只有一个皮层半球保留 RhoA/anillin 并发生退行。这种表型让人联想到纺锤体和皮层之间的物理阻滞或纺锤体定位偏心导致的不对称沟。这些持续存在的半沟的形成表明纺锤体和皮层之间存在一种潜在的反馈机制,即在细胞分裂进入犁沟阶段之前,维持皮层在推定赤道区的能力,从而确保最终形成对称的裂沟。
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