Kinetochore-microtube attachments in cancer therapy

D. Del Bufalo, F. Degrassi
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In this scenario, kinetochores (KTs) represent an attractive therapeutic target in light of their fundamental role in driving chromosome segregation and controlling chromosome segregation errors. Indeed, cells require a fine regulation of the kinetochore-microtubule (KT-MT) attachment stability to prevent chromosome instability, and KT-MT attachment dynamics is often deregulated in tumour cells [2]. Chromosome instability is commonly accepted as a driving force in the development of cancer, but more recent work has demonstrated that extensive chromosome missegregation may be detrimental to cancer cells and act as a tumor suppression mechanism [3]. In light of this double role of chromosome instability in cancer, we have explored the hypothesis that interfering with KT-MT attachment dynamics could drive massive chromosome missegregation and kill tumor cells. Highly Expressed in Cancer protein 1 (Hec1) is a constituent of the evolutionary conserved Ndc80 complex, the molecular connector between KTs and MTs. Among the subunits of the Ndc80 complex, Hec1 directly interacts with MTs and regulates KT-MT dynamics and attachment stability [3]. Importantly, Hec1 is frequently overexpressed in cancer. We previously demonstrated that expression of Hec1 fused with the enhanced green fluorescent protein (EGFP) tag at its N-terminus (EGFP-Hec1), the protein domain that regulates MT attachment dynamics, led to a strong accumulation of this modified protein, which acted as a dominant negative mutant over the endogenous Hec1. Mitotic cells expressing a N-terminus tagged Hec1 accumulated lateral KT-MT attachments and underwent a spindle assembly checkpoint (SAC) dependent mitotic arrest associated with the formation of multipolar spindles [4]. We further showed that expression of an inducible N-terminus modified Hec1 completely abolished in vitro growth of EGFP-Hec1 expressing HeLa cells but had no effects on untransformed human fibroblasts or epithelial cells [5]. These in vitro cell-based data were validated in vivo by showing that inducible EGFP-Hec1 expression strongly inhibited tumor growth in a HeLa xenograft mouse model [5]. Strikingly, in both in vitro and in vivo models, EGFP-Hec1 expressing cells were permanently arrested in mitosis and produced multipolar spindles. Live imaging of EGFP-Hec1 expressing cells demonstrated that impaired chromosome segregation within multipolar spindles induced mitotic catastrophe, identified by the induction of apoptotic death from mitosis, or cytokinesis failure and multinucleation. Finally, measurements of MT flux rates and turnover at KT demonstrated that EGFP-Hec1 increased KT-MT attachment stability, suggesting that stabilizing KT-MT attachment dynamics represents a promising therapeutic approach [5]. Consistent with KT-MT attachment dynamics being the molecular target of the anticancer effect, expression of Hec1 fused with EGFP at its C-terminus, which does not affect KT-MT attachment dynamics, did not significantly affect cancer cell proliferation [5]. Collectively, our results demonstrate that massive chromosome missegregation within multipolar spindles can be used to kill tumor cells by activating a mitotic catastrophe process. In our experimental model, induction of multipolarity is caused by the extended time cells spend in prometaphase, which promotes cohesion fatigue (uncoordinated centromeric cohesion release) and concomitant centriole disengagement by leaky separase activation as depicted in Figure ​Figure11 [6,7]. Cancer cell death induced by cohesion fatigue-dependent multipolarity has been demonstrated following depletion of proteins controlling SAC silencing or after inhibition of the Anaphase Promoting Complex/cdc20 (APC/C) activity (Figure ​(Figure1)1) and some of these treatments have been found more efficient than MT inhibitors in avoiding mitotic slippage and producing cancer cell death (7,8). These studies, together with our work, demonstrate that stimulation of spindle multipolarity can be used as an anti-cancer strategy through the activation of mitotic catastrophe after a multipolar mitosis. Moreover, they indicate that targeting the machineries involved in the regulation of KT-MT attachment dynamics, in the correction of KT-MT misattachments or in the silencing of the spindle assembly checkpoint may be a new frontier in the development of anticancer strategies.","PeriodicalId":94164,"journal":{"name":"Oncoscience","volume":"43 1","pages":"902 - 903"},"PeriodicalIF":0.0000,"publicationDate":"2015-11-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Oncoscience","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.18632/ONCOSCIENCE.265","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

Abstract

The process of cell division represents an extraordinary target to develop antitumor therapies. Indeed, a large number of clinically relevant anti-cancer drugs, such as taxanes and vinca alkaloids, target mitosis by stimulating or inhibiting microtubule (MT) polymerization. During the past decades anti-tubulin drugs have proven very effective against a wide range of tumors. However, collateral effects, such as myelosuppression and MT disruption in non-dividing tissues, including brain, are common. Recently, the increased understanding of the cell division process and the identification of several signaling pathways controlling mitosis have provided novel opportunities for cancer drug discovery. Consequently, mitotic proteins have become attractive targets to develop molecular cancer therapeutics. In this scenario, kinetochores (KTs) represent an attractive therapeutic target in light of their fundamental role in driving chromosome segregation and controlling chromosome segregation errors. Indeed, cells require a fine regulation of the kinetochore-microtubule (KT-MT) attachment stability to prevent chromosome instability, and KT-MT attachment dynamics is often deregulated in tumour cells [2]. Chromosome instability is commonly accepted as a driving force in the development of cancer, but more recent work has demonstrated that extensive chromosome missegregation may be detrimental to cancer cells and act as a tumor suppression mechanism [3]. In light of this double role of chromosome instability in cancer, we have explored the hypothesis that interfering with KT-MT attachment dynamics could drive massive chromosome missegregation and kill tumor cells. Highly Expressed in Cancer protein 1 (Hec1) is a constituent of the evolutionary conserved Ndc80 complex, the molecular connector between KTs and MTs. Among the subunits of the Ndc80 complex, Hec1 directly interacts with MTs and regulates KT-MT dynamics and attachment stability [3]. Importantly, Hec1 is frequently overexpressed in cancer. We previously demonstrated that expression of Hec1 fused with the enhanced green fluorescent protein (EGFP) tag at its N-terminus (EGFP-Hec1), the protein domain that regulates MT attachment dynamics, led to a strong accumulation of this modified protein, which acted as a dominant negative mutant over the endogenous Hec1. Mitotic cells expressing a N-terminus tagged Hec1 accumulated lateral KT-MT attachments and underwent a spindle assembly checkpoint (SAC) dependent mitotic arrest associated with the formation of multipolar spindles [4]. We further showed that expression of an inducible N-terminus modified Hec1 completely abolished in vitro growth of EGFP-Hec1 expressing HeLa cells but had no effects on untransformed human fibroblasts or epithelial cells [5]. These in vitro cell-based data were validated in vivo by showing that inducible EGFP-Hec1 expression strongly inhibited tumor growth in a HeLa xenograft mouse model [5]. Strikingly, in both in vitro and in vivo models, EGFP-Hec1 expressing cells were permanently arrested in mitosis and produced multipolar spindles. Live imaging of EGFP-Hec1 expressing cells demonstrated that impaired chromosome segregation within multipolar spindles induced mitotic catastrophe, identified by the induction of apoptotic death from mitosis, or cytokinesis failure and multinucleation. Finally, measurements of MT flux rates and turnover at KT demonstrated that EGFP-Hec1 increased KT-MT attachment stability, suggesting that stabilizing KT-MT attachment dynamics represents a promising therapeutic approach [5]. Consistent with KT-MT attachment dynamics being the molecular target of the anticancer effect, expression of Hec1 fused with EGFP at its C-terminus, which does not affect KT-MT attachment dynamics, did not significantly affect cancer cell proliferation [5]. Collectively, our results demonstrate that massive chromosome missegregation within multipolar spindles can be used to kill tumor cells by activating a mitotic catastrophe process. In our experimental model, induction of multipolarity is caused by the extended time cells spend in prometaphase, which promotes cohesion fatigue (uncoordinated centromeric cohesion release) and concomitant centriole disengagement by leaky separase activation as depicted in Figure ​Figure11 [6,7]. Cancer cell death induced by cohesion fatigue-dependent multipolarity has been demonstrated following depletion of proteins controlling SAC silencing or after inhibition of the Anaphase Promoting Complex/cdc20 (APC/C) activity (Figure ​(Figure1)1) and some of these treatments have been found more efficient than MT inhibitors in avoiding mitotic slippage and producing cancer cell death (7,8). These studies, together with our work, demonstrate that stimulation of spindle multipolarity can be used as an anti-cancer strategy through the activation of mitotic catastrophe after a multipolar mitosis. Moreover, they indicate that targeting the machineries involved in the regulation of KT-MT attachment dynamics, in the correction of KT-MT misattachments or in the silencing of the spindle assembly checkpoint may be a new frontier in the development of anticancer strategies.
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着丝细胞-微管附件在癌症治疗中的应用
细胞分裂过程是开发抗肿瘤疗法的重要靶点。事实上,大量临床相关的抗癌药物,如紫杉烷和长春花生物碱,都是通过刺激或抑制微管(MT)聚合来靶向有丝分裂的。在过去的几十年里,抗微管蛋白药物已被证明对多种肿瘤非常有效。然而,附带效应,如骨髓抑制和MT破坏非分裂组织,包括脑,是常见的。最近,对细胞分裂过程的进一步了解和控制有丝分裂的几个信号通路的鉴定为癌症药物的发现提供了新的机会。因此,有丝分裂蛋白已成为开发分子癌症治疗的有吸引力的靶点。在这种情况下,着丝点(KTs)代表了一个有吸引力的治疗靶点,因为它们在驱动染色体分离和控制染色体分离错误方面起着基本作用。事实上,细胞需要对着丝点-微管(KT-MT)的附着稳定性进行精细调节,以防止染色体不稳定,而在肿瘤细胞中,KT-MT的附着动力学通常是不受调节的[2]。染色体不稳定被普遍认为是癌症发展的驱动力,但最近的研究表明,广泛的染色体错分离可能对癌细胞有害,并起到肿瘤抑制机制的作用[3]。鉴于染色体不稳定性在癌症中的双重作用,我们探索了干扰KT-MT附着动力学可能导致大量染色体错分离并杀死肿瘤细胞的假设。在Cancer protein 1 (Hec1)中高表达,是进化保守的Ndc80复合物的一个组成部分,Ndc80复合物是kt和mt之间的分子连接物,在Ndc80复合物的亚基中,Hec1直接与mt相互作用,调节KT-MT动力学和附着稳定性[3]。重要的是,Hec1在癌症中经常过表达。我们之前已经证明,Hec1在其n端与增强型绿色荧光蛋白(EGFP)标签(EGFP-Hec1)(调节MT附着动力学的蛋白质结构域)融合的表达导致这种修饰蛋白的强烈积累,作为内源性Hec1的显性负突变体。表达n端标记Hec1的有丝分裂细胞积累了侧向KT-MT附着,并经历了与多极纺锤体形成相关的纺锤体组装检查点(SAC)依赖的有丝分裂停滞[4]。我们进一步发现,诱导型n端修饰的Hec1的表达完全抑制了表达HeLa细胞的EGFP-Hec1的体外生长,但对未转化的人成纤维细胞或上皮细胞没有影响[5]。这些基于体外细胞的数据在体内得到验证,表明可诱导的EGFP-Hec1表达强烈抑制HeLa异种移植小鼠模型中的肿瘤生长[5]。引人注目的是,在体外和体内模型中,表达EGFP-Hec1的细胞在有丝分裂中永久停止并产生多极纺锤体。表达EGFP-Hec1的细胞的实时成像显示,多极纺锤体内染色体分离受损诱导有丝分裂灾难,通过诱导有丝分裂引起的凋亡死亡,或细胞分裂失败和多核来鉴定。最后,对MT通量率和KT周转率的测量表明,EGFP-Hec1增加了KT-MT附着的稳定性,这表明稳定KT-MT附着动力学是一种很有前途的治疗方法[5]。与KT-MT附着动力学是抗癌作用的分子靶点一致,在c端表达he1与EGFP融合,不影响KT-MT附着动力学,对癌细胞增殖没有显著影响[5]。总的来说,我们的研究结果表明,多极纺锤体内大量的染色体错分离可以通过激活有丝分裂突变过程来杀死肿瘤细胞。在我们的实验模型中,多极性的诱导是由细胞在前期的时间延长引起的,这促进了内聚疲劳(不协调的着丝粒内聚释放),并通过泄漏分离酶激活导致中心粒脱离,如图11所示[6,7]。在控制SAC沉默的蛋白质耗尽或抑制后期促进复合物/cdc20 (APC/C)活性后,内聚疲劳依赖性多极性诱导的癌细胞死亡已被证明(图(图1)),其中一些治疗方法被发现在避免有丝分裂滑移和产生癌细胞死亡方面比MT抑制剂更有效(7,8)。这些研究和我们的工作表明,刺激纺锤体多极可以作为一种抗癌策略,通过激活多极有丝分裂后的有丝分裂灾难。 此外,他们指出,靶向参与调节KT-MT附着动力学,纠正KT-MT错误附着或沉默纺锤体组装检查点的机制可能是抗癌策略发展的新前沿。
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