Buckenmeyer Michael J, Brooks Elizabeth A, Taylor Madison S, Orenuga Ireolu K, Yang Liping, Holewinski Ronald J, Meyer Thomas J, Galloux Melissa, Garmendia-Cedillos Marcial, Pohida Thomas J, Andresson Thorkell, St Croix Brad, Wolf Matthew T
Cancer Biomaterials Engineering Laboratory, Cancer Innovation Laboratory, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Frederick, Maryland.
Tumor Angiogenesis Unit, Mouse Cancer Genetics Program, National Cancer Institute, National Institutes of Health, Frederick, Maryland.
Cancer Res. 2025 May 2;85(9):1577-1595. doi: 10.1158/0008-5472.CAN-24-1954.
Three-dimensional (3D) in vitro cell culture models are invaluable tools for investigating the tumor microenvironment. However, analyzing the impact of critical stromal elements, such as extracellular matrix (ECM), remains a challenge. In this study, we developed a hydrogel-free self-assembly platform to establish ECM-rich 3D "MatriSpheres" to deconvolute cancer cell-ECM interactions. Mouse and human colorectal cancer MatriSpheres actively incorporated microgram quantities of decellularized small intestine submucosa ECM, which proteomically mimicked colorectal cancer tumor ECM compared with traditional formulations like Matrigel. Solubilized ECM, at subgelation concentrations, was organized by colorectal cancer cells into intercellular stroma-like regions within 5 days, displaying morphologic similarity to colorectal cancer clinical pathology. MatriSpheres featured ECM-dependent transcriptional and cytokine profiles associated with malignancy, lipid metabolism, and immunoregulation. Model benchmarking with single-cell RNA sequencing demonstrated that MatriSpheres enhanced correlation with in vivo tumor cells over traditional ECM-poor spheroids. This facile approach enables tumor-specific tissue morphogenesis, promoting cell-ECM communication to improve fidelity for disease modeling applications. Significance: MatriSpheres provide a hydrogel-free 3D platform for decoupling the influence of heterogeneous extracellular matrix components on tumor biology and can broadly facilitate high-throughput drug discovery and screening applications. See related commentary by Ernst and De Wever, p. 1568.
三维(3D)体外细胞培养模型是研究肿瘤微环境的宝贵工具。然而,分析关键基质成分(如细胞外基质(ECM))的影响仍然是一项挑战。在本研究中,我们开发了一种无凝胶自组装平台,以建立富含ECM的3D“基质球”来解析癌细胞与ECM的相互作用。小鼠和人类结直肠癌基质球积极掺入微克量的脱细胞小肠黏膜下层ECM,与基质胶等传统制剂相比,其蛋白质组学上模拟了结直肠癌肿瘤ECM。在亚凝胶浓度下,可溶解的ECM在5天内被结直肠癌细胞组织成细胞间基质样区域,显示出与结直肠癌临床病理学的形态相似性。基质球具有与恶性肿瘤、脂质代谢和免疫调节相关的ECM依赖性转录和细胞因子谱。用单细胞RNA测序进行的模型基准测试表明,与传统的低ECM球体相比,基质球增强了与体内肿瘤细胞的相关性。这种简便的方法能够实现肿瘤特异性组织形态发生,促进细胞与ECM的通讯,以提高疾病建模应用的保真度。意义:基质球提供了一个无凝胶的3D平台,用于分离异质细胞外基质成分对肿瘤生物学的影响,并可广泛促进高通量药物发现和筛选应用。见恩斯特和德韦弗的相关评论,第1568页。
