Abstract
The development of an independent blood supply by a tumor is essential for maintaining growth beyond a certain limited size and for providing a portal for metastatic dissemination. Host-derived endothelial cells (ECs) residing in and compromising the tumor vasculature originate via distinct processes known as sprouting angiogenesis and vasculogenesis. More recently ECs originating directly from the tumor cells themselves have been described although the basis for this phenomenon remains poorly understood. Here we describe in vitro conditions that allow lung and ovarian cancer cells to undergo a rapid and efficient transition into ECs that are indistinguishable from those obtained in vivo. A variety of methods were used to establish that the acquired phenotypes and behaviors of these tumor-derived ECs (TDECs) closely resemble those of authentic ECs. Xenografts arising from co-inoculated in vitro-derived TDECs and tumor cells were also more highly vascularized than control tumors; moreover, their blood vessels were on average larger and frequently contained admixtures of host-derived ECs and TDECs derived from the initial inoculum. These results demonstrate that cancer cells can be manipulated under well-defined in vitro conditions to initiate a tumor cell-to-EC transition that is largely cell-autonomous, highly efficient and closely mimics the in vivo process. These studies provide a suitable means by which to identify and perhaps modify the earliest steps in TDEC generation. © 2013 Elster et al.
Figures
![Figure 1. Immunofluorescent staining of tumor cells grown under standard conditions and under optimal conditions to induce TDECs. (A) H460 cells were grown for 5 d under condition 3. (B) OVCAR3 cells were grown for 5 d under condition 4. Antibody staining for the EC-specific markers vWF, VEGFR1, VEGFR2, VE-cadhherin, ESAM, binding of E-lectin and uptake of acetylated AcLDL were performed on both sets of cells as previously described [24,25]. Epithelial marker staining was performed for CK7 and CK19. Counterstaining with DAPI was performed to visualize nuclei. Bright field images of tumor cells and TDECs are also included. Images were obtained at either 40-60X magnification (confocal) or 10X magnification (bright field). Numbers in the upper right hand corner of each panel indicate the percentage of each population that demonstrated any evidence of staining, irrespective of its intensity. Similar results were obtained in at least three independent experiments. Scale bar = 25 um.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/e2125261-11be-3785-aac9-09032d5dd1f3/thumbnail-62c69212-8d86-44e0-ba7c-08470da84af0-0.png)
![Figure 2. Tube formation by TDECs. (A) H460 tumor cells were induced to form TDECs by 5 d of exposure to the indicated conditions. 2 x 104 cells from each group were then plated on Matrigel in a tube formation assay under normoxic conditions for 5 d, as previously described [24,25]. Untreated H460 cells grown under standard conditions served as controls. Typical light microscopic fields are shown. All photos are shown at identical magnifications. (B) The results shown in (A) are graphically depicted as the mean number of completely enclosed tubes per field ± SEM. p values were obtained using one-way ANOVA (**: p < 0.01). (C) H460 tumor cells were grown under standard conditions or condition 3 for the indicated times. Half the cells were then immediately plated on Matrigel and grown under normoxic conditions for an additional 6 d. The remainder of the cells were returned to standard conditions for 7 d prior to being plated in Matrigel for 6 d to assess the persistence of tube-forming potential. HUVECs were used as a positive control for tube formation. Brightfield photographs were taken at 10X magnification. Similar results were obtained in four independent experiments (A) and two independent experiments (C). Scale bar = 100 um.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/e2125261-11be-3785-aac9-09032d5dd1f3/thumbnail-b393883b-47e9-4456-b7af-5dd308668ef7-1.png)
![Figure 3. Hypoxia, EC-specific growth medium, and nutrient deprivation induce Tie2-dependent EGFP expression in tumor cells. Separate cultures of H460 and OVCAR3 tumor cells were stably co-transfected with Tie2-EGFP plasmid and pFR400 encoding a mutant form of dihydrofolate reductase [36,37] and selected in G-418 and increasing concentrations of methotrexate to allow amplification of the two tandemly integrated vectors and a corresponding increase EGFP signal intensity. Cells were exposed to conditions shown previously to induce the maximal TDEC phenotype (i.e., condition 3 for H460’s and condition 4 for OVCAR3) and compared to control cells grown under standard conditions. (A) Fluorescence micrographs of each cell line after five days of growth under each set of conditions. (B) Flow cytometric analysis of the same cells. Representative results of at least three independent experiments are depicted. Scale bar = 25 um.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/e2125261-11be-3785-aac9-09032d5dd1f3/thumbnail-af912a3f-2f3e-4293-95e8-4e3523388e7d-2.png)
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CITATION STYLE
Elster, J. D., McGuire, T. F., Lu, J., & Prochownik, E. V. (2013). Rapid In Vitro Derivation of Endothelium Directly From Human Cancer Cells. PLoS ONE, 8(10). https://doi.org/10.1371/journal.pone.0077675
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