Department of Biochemistry, Vanderbilt-Ingram Cancer Center, Vanderbilt University School of Medicine, 2200 Pierce Avenue, Nashville, TN 37232, USA.
Breast Cancer Res. 2010;12(3):R41. doi: 10.1186/bcr2595. Epub 2010 Jun 24.
Paclitaxel is a widely used drug in the treatment of patients with locally advanced and metastatic breast cancer. However, only a small portion of patients have a complete response to paclitaxel-based chemotherapy, and many patients are resistant. Strategies that increase sensitivity and limit resistance to paclitaxel would be of clinical use, especially for patients with triple-negative breast cancer (TNBC).
We generated a gene set from overlay of the druggable genome and a collection of genomically deregulated gene transcripts in breast cancer. We used loss-of-function RNA interference (RNAi) to identify gene products in this set that, when targeted, increase paclitaxel sensitivity. Pharmacological agents that targeted the top scoring hits/genes from our RNAi screens were used in combination with paclitaxel, and the effects on the growth of various breast cancer cell lines were determined.
RNAi screens performed herein were validated by identification of genes in pathways that, when previously targeted, enhanced paclitaxel sensitivity in the pre-clinical and clinical settings. When chemical inhibitors, CCT007093 and mithramycin, against two top hits in our screen, PPMID and SP1, respectively, were used in combination with paclitaxel, we observed synergistic growth inhibition in both 2D and 3D breast cancer cell cultures. The transforming growth factor beta (TGFbeta) receptor inhibitor, LY2109761, that targets the signaling pathway of another top scoring hit, TGFbeta1, was synergistic with paclitaxel when used in combination on select breast cancer cell lines grown in 3D culture. We also determined the relative paclitaxel sensitivity of 22 TNBC cell lines and identified 18 drug-sensitive and four drug-resistant cell lines. Of significance, we found that both CCT007093 and mithramycin, when used in combination with paclitaxel, resulted in synergistic inhibition of the four paclitaxel-resistant TNBC cell lines.
RNAi screening can identify druggable targets and novel drug combinations that can sensitize breast cancer cells to paclitaxel. This genomic-based approach can be applied to a multitude of tumor-derived cell lines and drug treatments to generate requisite pre-clinical data for new drug combination therapies to pursue in clinical investigations.
紫杉醇是一种广泛用于治疗局部晚期和转移性乳腺癌患者的药物。然而,只有一小部分患者对紫杉醇为基础的化疗有完全反应,许多患者存在耐药性。增加对紫杉醇的敏感性和限制耐药性的策略将具有临床应用价值,特别是对于三阴性乳腺癌(TNBC)患者。
我们从可药物基因组和乳腺癌中基因组失调基因转录本的集合中生成了一个基因集。我们使用基因敲低 RNA 干扰(RNAi)来鉴定该基因集中的基因产物,当靶向这些基因产物时,可增加紫杉醇的敏感性。针对我们 RNAi 筛选的最高得分命中/基因的药理学药物与紫杉醇联合使用,并确定其对各种乳腺癌细胞系生长的影响。
本文进行的 RNAi 筛选通过鉴定先前靶向的基因得到验证,这些基因在临床前和临床环境中增强了紫杉醇的敏感性。当针对我们筛选中的两个最高得分命中,即 PPMID 和 SP1 的化学抑制剂 CCT007093 和米托霉素,与紫杉醇联合使用时,我们观察到 2D 和 3D 乳腺癌细胞培养中协同的生长抑制。转化生长因子β(TGFβ)受体抑制剂 LY2109761 靶向另一个得分最高命中 TGFβ1 的信号通路,当其与紫杉醇联合使用时,在 3D 培养中生长的选定乳腺癌细胞系中具有协同作用。我们还确定了 22 个 TNBC 细胞系的相对紫杉醇敏感性,并鉴定了 18 个药物敏感和 4 个药物耐药细胞系。值得注意的是,我们发现 CCT007093 和米托霉素与紫杉醇联合使用时,均可协同抑制 4 个紫杉醇耐药的 TNBC 细胞系。
RNAi 筛选可以鉴定可药物靶向和新的药物组合,使乳腺癌细胞对紫杉醇敏感。这种基于基因组的方法可应用于多种肿瘤衍生细胞系和药物治疗,以生成新的药物组合疗法在临床研究中进行所需的临床前数据。
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