Abstract
3-dimensional (3D) culture models have the potential to bridge the gap between monolayer cell culture and in vivo studies. To benefit anti-cancer drug discovery from 3D models, new techniques are needed that enable their use in high-throughput (HT) screening amenable formats. We have established miniaturized 3D culture methods robust enough for automated HT screens. We have applied these methods to evaluate the sensitivity of normal and tumorigenic breast epithelial cell lines against a panel of oncology drugs when cultured as monolayers (2D) and spheroids (3D). We have identified two classes of compounds that exhibit preferential cytotoxicity against cancer cells over normal cells when cultured as 3D spheroids: microtubule-targeting agents and epidermal growth factor receptor (EGFR) inhibitors. Further improving upon our 3D model, superior differentiation of EC50 values in the proof-of-concept screens was obtained by co-culturing the breast cancer cells with normal human fibroblasts and endothelial cells. Further, the selective sensitivity of the cancer cells towards chemotherapeutics was observed in 3D co-culture conditions, rather than as 2D co-culture monolayers, highlighting the importance of 3D cultures. Finally, we examined the putative mechanisms that drive the differing potency displayed by EGFR inhibitors. In summary, our studies establish robust 3D culture models of human cells for HT assessment of tumor cell-selective agents. This methodology is anticipated to provide a useful tool for the study of biological differences within 2D and 3D culture conditions in HT format, and an important platform for novel anti-cancer drug discovery.
Highlights
The development and utilization of model systems that recapitulate human solid tumor architecture and biology are essential to better understand the pathophysiology of tumor cells, and to aid in the discovery of novel anticancer therapies
Models have been developed to reflect the microenvironment of solid tumors. 3D spheroid cultures can recapitulate cellcell interactions, cell-matrix interactions, nutrient and oxygen gradients, and cell polarity that is lacking in traditional 2D monolayer culture [1,2]. 3D cultures contain heterogeneous zones of proliferating, quiescent, and dying cells, which are likewise found in human tumor tissue and exhibit differing sensitivities to anti-tumor treatments [1,3]
When cytotoxicity studies against cancer cells are performed, cells are typically cultured as a monolayer, where cell-cell contacts and microenvironment signals are lacking and the culture conditions may not reflect the in vivo situation for cytotoxicity and/or drug resistance
Summary
The development and utilization of model systems that recapitulate human solid tumor architecture and biology are essential to better understand the pathophysiology of tumor cells, and to aid in the discovery of novel anticancer therapies. We compared the sensitivity of normal and tumor breast epithelial cell lines to the 89 clinically-relevant compounds in the National Cancer Institute’s (NCI) Approved oncology Drug Collection (ADC) [18].
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