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使用CDK4/6抑制剂帕博西尼靶向癌症干细胞增殖:端粒酶驱动肿瘤细胞异质性。

Targeting cancer stem cell propagation with palbociclib, a CDK4/6 inhibitor: Telomerase drives tumor cell heterogeneity.

作者信息

Bonuccelli Gloria, Peiris-Pages Maria, Ozsvari Bela, Martinez-Outschoorn Ubaldo E, Sotgia Federica, Lisanti Michael P

机构信息

Paterson Building, University of Manchester, Manchester M20 4BX, United Kingdom.

The Sidney Kimmel Cancer Center, Thomas Jefferson University, Philadelphia, Pennsylvania 19107, USA.

出版信息

Oncotarget. 2017 Feb 7;8(6):9868-9884. doi: 10.18632/oncotarget.14196.

DOI:10.18632/oncotarget.14196
PMID:28039467
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5354777/
Abstract

In this report, we systematically examined the role of telomerase activity in lung and ovarian cancer stem cell (CSC) propagation. For this purpose, we indirectly gauged telomerase activity, by linking the hTERT-promoter to eGFP. Using lung (A549) and ovarian (SKOV3) cancer cells, transduced with the hTERT-GFP reporter, we then employed GFP-expression levels to fractionate these cell lines into GFP-high and GFP-low populations. We functionally compared the phenotype of these GFP-high and GFP-low populations. More specifically, we now show that the cancer cells with higher telomerase activity (GFP-high) are more energetically activated, with increased mitochondrial mass and function, as well as increased glycolytic activity. This was further validated and confirmed by unbiased proteomics analysis. Cells with high telomerase activity also showed an increased capacity for stem cell activity (as measured using the 3D-spheroid assay) and cell migration (as measured using a Boyden chamber approach). These enhanced biological phenotypes were effectively inhibited by classical modulators of energy metabolism, which target either i) mitochondrial metabolism (i.e., oligomycin) or ii) glycolysis (i.e., 2-deoxy-glucose), or iii) by using the FDA-approved antibiotic doxycycline, which inhibits mitochondrial biogenesis. Finally, the level of telomerase activity also determined the ability of hTERT-high cells to proliferate, as assessed by measuring DNA synthesis via EdU incorporation. Consistent with these observations, treatment with an FDA-approved CDK4/6 inhibitor (PD-0332991/palbociclib) specifically blocked the propagation of both lung and ovarian CSCs. Virtually identical results were obtained with breast CSCs, which were also highly sensitive to palbociclib at concentrations in the nanomolar range. In summary, CSCs with high telomerase activity are among the most energetically activated, migratory and proliferative cell sub-populations. These observations may provide a mechanistic explanation for tumor metabolic heterogeneity, based on telomerase activity. FDA-approved drugs, such as doxycycline and palbociclib, were both effective at curtailing CSC propagation. Thus, these FDA-approved drugs could be used to target telomerase-high proliferative CSCs, in multiple cancer types. Finally, our experiments also allowed us to distinguish two different cellular populations of hTERT-high cells, one that was proliferative (i.e., replicative immortality) and the other that was non-proliferative (i.e., quiescent). We speculate that the non-proliferative population of hTERT-high cells that we identified could be mechanistically involved in tumor dormancy.

摘要

在本报告中,我们系统地研究了端粒酶活性在肺癌和卵巢癌干细胞(CSC)增殖中的作用。为此,我们通过将hTERT启动子与eGFP连接来间接测量端粒酶活性。利用转导了hTERT-GFP报告基因的肺癌(A549)和卵巢癌(SKOV3)细胞,我们随后利用GFP表达水平将这些细胞系分为GFP高表达和GFP低表达群体。我们对这些GFP高表达和GFP低表达群体的表型进行了功能比较。更具体地说,我们现在表明,端粒酶活性较高的癌细胞(GFP高表达)能量代谢更活跃,线粒体质量和功能增加,糖酵解活性也增加。这通过无偏蛋白质组学分析得到了进一步验证和确认。端粒酶活性高的细胞还表现出干细胞活性(使用3D球体测定法测量)和细胞迁移能力(使用博伊登室法测量)增强。这些增强的生物学表型被能量代谢的经典调节剂有效抑制,这些调节剂要么靶向i)线粒体代谢(即寡霉素),要么靶向ii)糖酵解(即2-脱氧葡萄糖),要么iii)使用FDA批准的抗生素强力霉素,它抑制线粒体生物发生。最后,端粒酶活性水平还决定了hTERT高表达细胞的增殖能力,这通过测量EdU掺入来评估DNA合成来确定。与这些观察结果一致,用FDA批准的CDK4/6抑制剂(PD-0332991/帕博西尼)治疗可特异性阻断肺癌和卵巢癌CSC的增殖。在乳腺癌CSC中也获得了几乎相同的结果,它们在纳摩尔浓度下对帕博西尼也高度敏感。总之,端粒酶活性高的CSC是能量代谢最活跃、迁移和增殖能力最强的细胞亚群之一。这些观察结果可能为基于端粒酶活性的肿瘤代谢异质性提供一个机制解释。FDA批准的药物,如强力霉素和帕博西尼,在抑制CSC增殖方面都很有效。因此,这些FDA批准的药物可用于靶向多种癌症类型中端粒酶高表达的增殖性CSC。最后,我们的实验还使我们能够区分hTERT高表达细胞的两种不同细胞群体,一种是增殖性的(即复制性永生),另一种是非增殖性的(即静止的)。我们推测,我们鉴定出的hTERT高表达细胞的非增殖群体可能在肿瘤休眠中发挥机制性作用。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0b85/5354777/304cfe2c2429/oncotarget-08-9868-g008.jpg
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