Wnt/β-catenin–activated Ewing sarcoma cells promote the angiogenic switch
Allegra G. Hawkins, Elisabeth A. Pedersen, Sydney Treichel, Kelsey Temprine, Colin Sperring, Jay A. Read, Brian Magnuson, Rashmi Chugh, Elizabeth R. Lawlor
Allegra G. Hawkins, Elisabeth A. Pedersen, Sydney Treichel, Kelsey Temprine, Colin Sperring, Jay A. Read, Brian Magnuson, Rashmi Chugh, Elizabeth R. Lawlor
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Research Article Cell biology Oncology

Wnt/β-catenin–activated Ewing sarcoma cells promote the angiogenic switch

Abstract

Wnt/β-catenin signaling is active in small subpopulations of Ewing sarcoma cells, and these cells display a more metastatic phenotype, in part due to antagonism of EWS-FLI1–dependent transcriptional activity. Importantly, these β-catenin–activated Ewing sarcoma cells also alter secretion of extracellular matrix (ECM) proteins. We thus hypothesized that, in addition to cell-autonomous mechanisms, Wnt/β-catenin–active tumor cells might contribute to disease progression by altering the tumor microenvironment (TME). Analysis of transcriptomic data from primary patient biopsies and from β-catenin–active versus –nonactive tumor cells identified angiogenic switch genes as being highly and reproducibly upregulated in the context of β-catenin activation. In addition, in silico and in vitro analyses, along with chorioallantoic membrane assays, demonstrated that β-catenin–activated Ewing cells secreted factors that promote angiogenesis. In particular, activation of canonical Wnt signaling leads Ewing sarcoma cells to upregulate expression and secretion of proangiogenic ECM proteins, collectively termed the angiomatrix. Significantly, our data show that induction of the angiomatrix by Wnt-responsive tumor cells is indirect and is mediated by TGF-β. Mechanistically, Wnt/β-catenin signaling antagonizes EWS-FLI1–dependent repression of TGF-β receptor type 2, thereby sensitizing tumor cells to TGF-β ligands. Together, these findings suggest that Wnt/β-catenin–active tumor cells can contribute to Ewing sarcoma progression by promoting angiogenesis in the local TME.

Authors

Allegra G. Hawkins, Elisabeth A. Pedersen, Sydney Treichel, Kelsey Temprine, Colin Sperring, Jay A. Read, Brian Magnuson, Rashmi Chugh, Elizabeth R. Lawlor

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Figure 8

The TGF-β–mediated angiogenic response is augmented in β-catenin/TCF–active tumor cell population.

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The TGF-β–mediated angiogenic response is augmented in β-catenin/TCF–act...
(A) Ewing sarcoma cell subpopulations were isolated by FACS on the basis of TCF-GFP reporter activity following exposure to Wnt3a. Ewing sarcoma cell lines are heterogeneous in their level of Wnt responsiveness. Mean GFP+ cells ± SEM from at least triplicate experiments is shown for each cell line. (B) TGFBR2 expression was measured by qRT-PCR in Wnt/β-catenin–responsive (GFP pos) and nonresponsive (GFP neg) subpopulations sorted as in A. (C) TCF-GFP reporters expressing Ewing sarcoma cells were stably transduced with an SBE-luciferase reporter. Cells were treated with vehicle or Wnt3a and sorted into Wnt-responsive (GFP pos) and Wnt-unresponsive (GFP neg) cells. Sorted cells were exposed to TGFB1 for 24 hours and luciferase activity was measured. Fold changes in luciferase activity (arbitrary units of luminescence) in the subpopulations are shown for 3 independent experiments. (D and E) Expression of LEF1 and TGF-β–dependent angiomatrix genes (TNC, COL1A1, TGFBI, and IGFBP5) was measured by qRT-PCR in Wnt-responsive (GFP+) and Wnt-unresponsive (GFP) CHLA10 (D) and TC32 (E) cells following exposure to TGFB1. Expression of LEF1 is shown relative to HPRT. TGFB target gene expression is shown as fold change in GFP+ cells relative to the mean expression in GFP cells. P values were determined using 2-tailed paired t test in 3 independent sorting experiments, *P < 0.05 (BE).