Cancer Institute, Department of Biochemistry, University of Mississippi Medical Center, Jackson, 39216, USA.
Breast Cancer Res. 2011 May 19;13(3):R53. doi: 10.1186/bcr2884.
The nuclear enzyme topoisomerase IIα (TopoIIα) is able to cleave DNA in a reversible manner, making it a valuable target for agents such as etoposide that trap the enzyme in a covalent bond with the 5' DNA end to which it cleaves. This prevents DNA religation and triggers cell death in cancer cells. However, development of resistance to these agents limits their therapeutic use. In this study, we examined the therapeutic targeting of geminin for improving the therapeutic potential of TopoIIα agents.
Human mammary epithelial (HME) cells and several breast cancer cell lines were used in this study. Geminin, TopoIIα and cell division cycle 7 (Cdc7) silencing were done using specific small interfering RNA. Transit or stable inducible overexpression of these proteins and casein kinase Iε (CKIε) were also used, as well as several pharmacological inhibitors that target TopoIIα, Cdc7 or CKIε. We manipulated HME cells that expressed H2B-GFP, or did not, to detect chromosome bridges. Immunoprecipitation and direct Western blot analysis were used to detect interactions between these proteins and their total expression, respectively, whereas interactions on chromosomal arms were detected using a trapped in agarose DNA immunostaining assay. TopoIIα phosphorylation by Cdc7 or CKIε was done using an in vitro kinase assay. The TopoGen decatenation kit was used to measure TopoIIα decatenation activity. Finally, a comet assay and metaphase chromosome spread were used to detect chromosome breakage and changes in chromosome condensation or numbers, respectively.
We found that geminin and TopoIIα interact primarily in G2/M/early G1 cells on chromosomes, that geminin recruits TopoIIα to chromosomal decatenation sites or vice versa and that geminin silencing in HME cells triggers the formation of chromosome bridges by suppressing TopoIIα access to chromosomal arms. CKIε kinase phosphorylates and positively regulates TopoIIα chromosome localization and function. CKIε kinase overexpression or Cdc7 kinase silencing, which we show phosphorylates TopoIIα in vitro, restored DNA decatenation and chromosome segregation in geminin-silenced cells before triggering cell death. In vivo, at normal concentration, geminin recruits the deSUMOylating sentrin-specific proteases SENP1 and SENP2 enzymes to deSUMOylate chromosome-bound TopoIIα and promote its release from chromosomes following completion of DNA decatenation. In cells overexpressing geminin, premature departure of TopoIIα from chromosomes is thought to be due to the fact that geminin recruits more of these deSUMOylating enzymes, or recruits them earlier, to bound TopoIIα. This triggers premature release of TopoIIα from chromosomes, which we propose induces aneuploidy in HME cells, since chromosome breakage generated through this mechanism were not sensed and/or repaired and the cell cycle was not arrested. Expression of mitosis-inducing proteins such as cyclin A and cell division kinase 1 was also increased in these cells because of the overexpression of geminin.
TopoIIα recruitment and its chromosome decatenation function require a normal level of geminin. Geminin silencing induces a cytokinetic checkpoint in which Cdc7 phosphorylates TopoIIα and inhibits its chromosomal recruitment and decatenation and/or segregation function. Geminin overexpression prematurely deSUMOylates TopoIIα, triggering its premature departure from chromosomes and leading to chromosomal abnormalities and the formation of aneuploid, drug-resistant cancer cells. On the basis of our findings, we propose that therapeutic targeting of geminin is essential for improving the therapeutic potential of TopoIIα agents.
核酶拓扑异构酶 IIα(TopoIIα)能够以可逆的方式切割 DNA,使其成为依托泊苷等药物的有价值的靶点,这些药物将酶与它切割的 5' DNA 末端共价结合,从而阻止 DNA 再连接并在癌细胞中引发细胞死亡。然而,这些药物的耐药性的发展限制了它们的治疗用途。在这项研究中,我们研究了 geminin 的治疗靶向作用,以提高 TopoIIα 药物的治疗潜力。
本研究使用人乳腺上皮(HME)细胞和几种乳腺癌细胞系。使用特定的小干扰 RNA 进行 geminin、TopoIIα 和细胞分裂周期 7(Cdc7)沉默。还使用了这些蛋白质的瞬时或稳定的诱导过表达以及几种靶向 TopoIIα、Cdc7 或 CKIε 的药理学抑制剂。我们操纵表达 H2B-GFP 的 HME 细胞或不表达 H2B-GFP 的 HME 细胞,以检测染色体桥。免疫沉淀和直接 Western blot 分析分别用于检测这些蛋白质之间的相互作用及其总表达,而在染色体臂上的相互作用则使用在琼脂糖中捕获的 DNA 免疫染色测定来检测。使用体外激酶测定法检测 Cdc7 或 CKIε 对 TopoIIα 的磷酸化。使用 TopoGen 解连环试剂盒测量 TopoIIα 的解连环活性。最后,使用彗星试验和中期染色体铺片分别检测染色体断裂以及染色体凝聚或数量的变化。
我们发现 geminin 和 TopoIIα 主要在 G2/M/早期 G1 细胞的染色体上相互作用,geminin 将 TopoIIα 募集到染色体解连环位点或反之亦然,并且 geminin 在 HME 细胞中的沉默通过抑制 TopoIIα 进入染色体臂来触发染色体桥的形成。CKIε 激酶磷酸化并正向调节 TopoIIα 的染色体定位和功能。我们证明 CKIε 激酶在体外磷酸化 TopoIIα,在触发细胞死亡之前,过表达 CKIε 激酶或沉默 Cdc7 激酶,可恢复 geminin 沉默细胞中的 DNA 解连环和染色体分离。在体内,在正常浓度下,geminin 将去 SUMO 基特异蛋白酶 SENP1 和 SENP2 酶募集到染色体结合的 TopoIIα 上,并在完成 DNA 解连环后促进其从染色体上释放。在 geminin 过表达的细胞中,TopoIIα 过早离开染色体被认为是由于 geminin 募集了更多的这些去 SUMO 基酶,或者更早地募集它们,以结合 TopoIIα。这会触发 TopoIIα 从染色体过早释放,我们认为这会在 HME 细胞中诱导非整倍体,因为通过这种机制产生的染色体断裂没有被感知和/或修复,细胞周期没有被阻止。由于 geminin 的过表达,细胞周期蛋白 A 和细胞分裂激酶 1 等有丝分裂诱导蛋白的表达也增加了。
TopoIIα 的募集及其染色体解连环功能需要正常水平的 geminin。geminin 沉默诱导细胞有丝分裂检查点,其中 Cdc7 磷酸化 TopoIIα 并抑制其染色体募集和解连环和/或分离功能。geminin 过表达会过早地使 TopoIIα 去 SUMO 化,从而触发其过早离开染色体,导致染色体异常和形成非整倍体、耐药性癌细胞。基于我们的发现,我们提出靶向 geminin 是提高 TopoIIα 药物治疗潜力的关键。
