O'Duibhir Eoghan, Carragher Neil O, Pollard Steven M
MRC Centre for Regenerative Medicine, University of Edinburgh, Edinburgh, UK; Institute of Genetics and Molecular Medicine, CRUK Edinburgh Centre, University of Edinburgh, UK.
Institute of Genetics and Molecular Medicine, CRUK Edinburgh Centre, University of Edinburgh, UK.
Mol Cell Neurosci. 2017 Apr;80:198-207. doi: 10.1016/j.mcn.2016.11.001. Epub 2016 Nov 4.
Patients diagnosed with glioblastoma (GBM) continue to face a bleak prognosis. It is critical that new effective therapeutic strategies are developed. GBM stem cells have molecular hallmarks of neural stem and progenitor cells and it is possible to propagate both non-transformed normal neural stem cells and GBM stem cells, in defined, feeder-free, adherent culture. These primary stem cell lines provide an experimental model that is ideally suited to cell-based drug discovery or genetic screens in order to identify tumour-specific vulnerabilities. For many solid tumours, including GBM, the genetic disruptions that drive tumour initiation and growth have now been catalogued. CRISPR/Cas-based genome editing technologies have recently emerged, transforming our ability to functionally annotate the human genome. Genome editing opens prospects for engineering precise genetic changes in normal and GBM-derived neural stem cells, which will provide more defined and reliable genetic models, with critical matched pairs of isogenic cell lines. Generation of more complex alleles such as knock in tags or fluorescent reporters is also now possible. These new cellular models can be deployed in cell-based phenotypic drug discovery (PDD). Here we discuss the convergence of these advanced technologies (iPS cells, neural stem cell culture, genome editing and high content phenotypic screening) and how they herald a new era in human cellular genetics that should have a major impact in accelerating glioblastoma drug discovery.
被诊断患有胶质母细胞瘤(GBM)的患者预后仍然不佳。开发新的有效治疗策略至关重要。GBM干细胞具有神经干细胞和祖细胞的分子特征,并且有可能在特定的、无饲养层的贴壁培养中培养未转化的正常神经干细胞和GBM干细胞。这些原代干细胞系提供了一个实验模型,非常适合基于细胞的药物发现或基因筛选,以识别肿瘤特异性弱点。对于许多实体瘤,包括GBM,驱动肿瘤发生和生长的基因破坏现在已经被编目。基于CRISPR/Cas的基因组编辑技术最近出现,改变了我们对人类基因组进行功能注释的能力。基因组编辑为在正常和GBM衍生的神经干细胞中设计精确的基因变化开辟了前景,这将提供更明确和可靠的遗传模型,以及关键的同基因细胞系匹配对。现在也有可能产生更复杂的等位基因,如敲入标签或荧光报告基因。这些新的细胞模型可用于基于细胞的表型药物发现(PDD)。在这里,我们讨论这些先进技术(诱导多能干细胞、神经干细胞培养、基因组编辑和高内涵表型筛选)的融合,以及它们如何预示着人类细胞遗传学的一个新时代,这应该会对加速胶质母细胞瘤药物发现产生重大影响。