A robust, flow-based, microfluidic device for siRNA-mediated gene knockdown in glioblastoma spheroids

IF 2.4 Q2 ENGINEERING, MULTIDISCIPLINARY
Ines Hosni, Alex Iles, John Greenman, Mark A. Wade
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Abstract

Glioblastoma (GBM) is a deadly disease with a poor prognosis, there is therefore a crucial need for novel therapeutic targets. Current preclinical models of GBM fail to predict clinical outcomes, thus, new translationally relevant models are urgently needed for reliable therapeutic target validation. 3D spheroid culture of cancer cells has been shown to better reflect tumour biology than 2D monolayer culture, as has culturing cells in flow-based microfluidic devices, which mimic key aspects of the tumour microenvironment. Gene knockdown by siRNA is a key preclinical target validation tool, however, siRNA-mediated knockdown of cancer spheroids in microfluidic culture has not yet been demonstrated. Here we describe a simple and robust microfluidic device that can maintain GBM spheroids (U87 cells) for at least 7 days. Via RNA sequencing analysis, we demonstrate that spheroids grown in microfluidic culture are more proliferative than spheroids grown in static plate culture and downregulate genes associated with cell adhesion, potentially offering insights into the metastatic process. Comparison of target gene (PRMT2 and RAB21) knockdown using siRNA between 2D monolayer cultured cells, static spheroid culture and spheroids maintained in the microfluidic device showed that gene expression (as measured by quantitative-PCR) was significantly reduced in all culture systems. Knockdown was most efficient in cells grown in 2D monolayer culture followed by static spheroid culture, but we also demonstrate [Formula: see text] knockdown efficiency using the microfluidic device. In summary, this study describes an easy-to-use microfluidic culture platform and provides evidence that pre-clinical siRNA-mediated target validation studies will be possible in flow systems that mimic tumour physiology.
一个强大的、基于流动的、用于胶质母细胞瘤球体中sirna介导的基因敲除的微流控装置
胶质母细胞瘤(GBM)是一种预后不良的致命疾病,因此迫切需要新的治疗靶点。目前的GBM临床前模型无法预测临床结果,因此迫切需要新的翻译相关模型来可靠的治疗靶点验证。癌细胞的三维球形培养已被证明比二维单层培养更能反映肿瘤生物学,在模拟肿瘤微环境关键方面的基于流动的微流体装置中培养细胞也是如此。通过siRNA敲低基因是一种关键的临床前靶点验证工具,然而,在微流体培养中,siRNA介导的癌球体敲低尚未得到证实。在这里,我们描述了一个简单而坚固的微流体装置,可以维持GBM球体(U87细胞)至少7天。通过RNA测序分析,我们证明在微流体培养中生长的球体比在静态平板培养中生长的球体更具增殖能力,并且下调与细胞粘附相关的基因,可能为转移过程提供见解。通过比较siRNA在二维单层培养细胞、静态球形培养细胞和微流控装置中维持的球形细胞中敲除目的基因(PRMT2和RAB21)的结果表明,在所有培养系统中,基因表达(通过定量pcr检测)均显著降低。在二维单层培养的细胞中,敲除效率最高,然后是静态球形培养,但我们也证明了使用微流体装置的敲除效率[公式:见文本]。总之,本研究描述了一个易于使用的微流体培养平台,并提供了证据,证明临床前sirna介导的靶标验证研究将有可能在模拟肿瘤生理学的流动系统中进行。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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