Hubert Christopher G, Rivera Maricruz, Spangler Lisa C, Wu Qiulian, Mack Stephen C, Prager Briana C, Couce Marta, McLendon Roger E, Sloan Andrew E, Rich Jeremy N
Department of Stem Cell Biology and Regenerative Medicine, Lerner Research Institute, Cleveland Clinic, Cleveland, Ohio.
Department of Pathology, University Hospitals Case Medical Center, Cleveland, Ohio.
Cancer Res. 2016 Apr 15;76(8):2465-77. doi: 10.1158/0008-5472.CAN-15-2402. Epub 2016 Feb 19.
Many cancers feature cellular hierarchies that are driven by tumor-initiating cancer stem cells (CSC) and rely on complex interactions with the tumor microenvironment. Standard cell culture conditions fail to recapitulate the original tumor architecture or microenvironmental gradients and are not designed to retain the cellular heterogeneity of parental tumors. Here, we describe a three-dimensional culture system that supports the long-term growth and expansion of tumor organoids derived directly from glioblastoma specimens, including patient-derived primary cultures, xenografts, genetically engineered glioma models, or patient samples. Organoids derived from multiple regions of patient tumors retain selective tumorigenic potential. Furthermore, organoids could be established directly from brain metastases not typically amenable to in vitro culture. Once formed, tumor organoids grew for months and displayed regional heterogeneity with a rapidly dividing outer region of SOX2(+), OLIG2(+), and TLX(+) cells surrounding a hypoxic core of primarily non-stem senescent cells and diffuse, quiescent CSCs. Notably, non-stem cells within organoids were sensitive to radiotherapy, whereas adjacent CSCs were radioresistant. Orthotopic transplantation of patient-derived organoids resulted in tumors displaying histologic features, including single-cell invasiveness, that were more representative of the parental tumor compared with those formed from patient-derived sphere cultures. In conclusion, we present a new ex vivo model in which phenotypically diverse stem and non-stem glioblastoma cell populations can be simultaneously cultured to explore new facets of microenvironmental influences and CSC biology. Cancer Res; 76(8); 2465-77. ©2016 AACR.
许多癌症具有由肿瘤起始癌症干细胞(CSC)驱动的细胞层次结构,并依赖于与肿瘤微环境的复杂相互作用。标准细胞培养条件无法重现原始肿瘤结构或微环境梯度,也并非设计用于保留亲代肿瘤的细胞异质性。在此,我们描述了一种三维培养系统,该系统支持直接从胶质母细胞瘤标本中获得的肿瘤类器官的长期生长和扩增,这些标本包括患者来源的原代培养物、异种移植瘤、基因工程胶质瘤模型或患者样本。源自患者肿瘤多个区域的类器官保留了选择性致瘤潜力。此外,类器官可以直接从通常不适于体外培养的脑转移瘤中建立。一旦形成,肿瘤类器官可生长数月,并表现出区域异质性,其快速分裂的外层区域为SOX2(+)、OLIG2(+)和TLX(+)细胞,围绕着主要由非干细胞衰老细胞和弥漫性、静止的CSC组成的缺氧核心。值得注意的是,类器官内的非干细胞对放疗敏感,而相邻的CSC具有放射抗性。患者来源类器官的原位移植导致肿瘤呈现出组织学特征,包括单细胞侵袭性,与患者来源的球形培养物形成的肿瘤相比,这些特征更能代表亲代肿瘤。总之,我们提出了一种新的体外模型,在该模型中可以同时培养表型多样的干细胞和非干细胞胶质母细胞瘤细胞群体,以探索微环境影响和CSC生物学的新方面。《癌症研究》;76(8);2465 - 77。©美国癌症研究协会2016年。