Departments of1Anesthesiology and.
Departments of2Cancer Systems Imaging.
J Neurosurg. 2018 Dec 1;129(6):1446-1455. doi: 10.3171/2017.7.JNS17668. Epub 2018 Jan 12.
OBJECTIVEDexamethasone, a known regulator of mesenchymal programming in glioblastoma (GBM), is routinely used to manage edema in GBM patients. Dexamethasone also activates the expression of genes, such as CEBPB, in GBM stem cells (GSCs). However, the drug's impact on invasion, proliferation, and angiogenesis in GBM remains unclear. To determine whether dexamethasone induces invasion, proliferation, and angiogenesis in GBM, the authors investigated the drug's impact in vitro, in vivo, and in clinical information derived from The Cancer Genome Atlas (TCGA) cohort.METHODSExpression profiles of patients from the TCGA cohort with mesenchymal GBM (n = 155) were compared with patients with proneural GBM by comparative marker selection. To obtain robust data, GSCs with IDH1 wild-type (GSC3) and with IDH1 mutant (GSC6) status were exposed to dexamethasone in vitro and in vivo and analyzed for invasion (Boyden chamber, human-specific nucleolin), proliferation (Ki-67), and angiogenesis (CD31). Ex vivo tumor cells from dexamethasone-treated and control mice were isolated by fluorescence activated cell sorting and profiled using Affymetrix chips for mRNA (HTA 2.0) and microRNAs (miRNA 4.0). A pathway analysis was performed to identify a dexamethasone-regulated gene signature, and its relationship with overall survival (OS) was assessed using Kaplan-Meier analysis in the entire GBM TCGA cohort (n = 520).RESULTSThe mesenchymal subgroup, when compared with the proneural subgroup, had significant upregulation of a dexamethasone-regulated gene network, as well as canonical pathways of proliferation, invasion, and angiogenesis. Dexamethasone-treated GSC3 demonstrated a significant increase in invasion, both in vitro and in vivo, whereas GSC6 demonstrated a modest increase. Furthermore, dexamethasone treatment of both GSC3 and GSC6 lines resulted in significantly elevated cell proliferation and angiogenesis in vivo. Patients with mesenchymal GBM had significant upregulation of dexamethasone-regulated pathways when compared with patients with proneural GBM. A prognostic (p = 0.0007) 33-gene signature was derived from the ex vivo expression profile analyses and used to dichotomize the entire TCGA cohort by high (median OS 12.65 months) or low (median OS 14.91 months) dexamethasone signature.CONCLUSIONSThe authors present evidence that furthers the understanding of the complex effects of dexamethasone on biological characteristics of GBM. The results suggest that the drug increases invasion, proliferation, and angiogenesis in human GSC-derived orthotopic tumors, potentially worsening GBM patients' prognoses. The authors believe that careful investigation is needed to determine how to minimize these deleterious dexamethasone-associated side effects in GBM.
目的
地塞米松是一种已知的胶质母细胞瘤(GBM)间质编程调节剂,常用于治疗 GBM 患者的水肿。地塞米松还能激活 GBM 干细胞(GSCs)中 CEBPB 等基因的表达。然而,地塞米松对 GBM 的侵袭、增殖和血管生成的影响仍不清楚。为了确定地塞米松是否会诱导 GBM 的侵袭、增殖和血管生成,作者研究了该药物在体外、体内和 TCGA 队列的临床信息中的作用。
方法
通过比较标志物选择,比较 TCGA 队列中具有间充质 GBM(n = 155)的患者与具有原神经 GBM 的患者的表达谱。为了获得可靠的数据,用 IDH1 野生型(GSC3)和 IDH1 突变型(GSC6)的 GSCs 进行体外和体内实验,并分析侵袭(Boyden 室,人特异性核仁蛋白)、增殖(Ki-67)和血管生成(CD31)。用荧光激活细胞分选从地塞米松处理和对照小鼠的肿瘤细胞中分离,并使用 Affymetrix 芯片进行 mRNA(HTA 2.0)和 microRNA(miRNA 4.0)分析。进行通路分析以确定地塞米松调控的基因特征,并使用 Kaplan-Meier 分析评估其与整个 GBM TCGA 队列(n = 520)的总生存期(OS)的关系。
结果
与原神经亚组相比,间充质亚组中地塞米松调控的基因网络以及增殖、侵袭和血管生成的经典途径有显著上调。地塞米松处理的 GSC3 无论是在体外还是体内,侵袭能力都显著增加,而 GSC6 则略有增加。此外,地塞米松处理的 GSC3 和 GSC6 系在体内均导致细胞增殖和血管生成显著增加。与原神经 GBM 患者相比,间充质 GBM 患者的地塞米松调控途径有显著上调。从体外表达谱分析中得出了一个预后(p = 0.0007)的 33 基因特征,并用于通过高(中位 OS 12.65 个月)或低(中位 OS 14.91 个月)地塞米松特征对整个 TCGA 队列进行二分法。
结论
作者提供的证据进一步加深了对地塞米松对 GBM 生物学特性的复杂影响的理解。结果表明,该药物增加了人 GSC 来源的原位肿瘤的侵袭、增殖和血管生成,可能使 GBM 患者的预后恶化。作者认为,需要仔细研究如何最小化地塞米松在 GBM 中产生的这些有害的副作用。
