PRC2 loss drives MPNST metastasis and matrix remodeling
Qierra R. Brockman, Amanda Scherer, Gavin R. McGivney, Wade R. Gutierrez, Andrew P. Voigt, Alexandra L. Isaacson, Emily A. Laverty, Grace Roughton, Vickie Knepper-Adrian, Benjamin Darbro, Munir R. Tanas, Christopher S. Stipp, Rebecca D. Dodd
Qierra R. Brockman, Amanda Scherer, Gavin R. McGivney, Wade R. Gutierrez, Andrew P. Voigt, Alexandra L. Isaacson, Emily A. Laverty, Grace Roughton, Vickie Knepper-Adrian, Benjamin Darbro, Munir R. Tanas, Christopher S. Stipp, Rebecca D. Dodd
View: Text | PDF
Research Article Oncology

PRC2 loss drives MPNST metastasis and matrix remodeling

Abstract

The histone methyltransferase PRC2 plays a complex role in cancer. Malignant peripheral nerve sheath tumors (MPNSTs) are aggressive sarcomas with frequent loss-of-function mutations in PRC2 that are associated with poor outcome. Here, we identify a critical role for PRC2 loss in driving MPNST metastasis. PRC2-dependent metastatic phenotypes included increased collagen-dependent invasion, upregulation of matrix-remodeling enzymes, and elevated lung metastasis in orthotopic mouse models. Furthermore, clinical sample analysis determined that PRC2 loss correlated with metastatic disease, increased fibrosis, and decreased survival in patients with MPNSTs. These results may have broad implications for PRC2 function across multiple cancers and provide a strong rationale for investigating potential therapies targeting ECM-remodeling enzymes and tumor fibrosis to improve outcomes in patients with MPNSTs.

Authors

Qierra R. Brockman, Amanda Scherer, Gavin R. McGivney, Wade R. Gutierrez, Andrew P. Voigt, Alexandra L. Isaacson, Emily A. Laverty, Grace Roughton, Vickie Knepper-Adrian, Benjamin Darbro, Munir R. Tanas, Christopher S. Stipp, Rebecca D. Dodd

×

Figure 1

PRC2 deletion drives MPNST metastatic phenotypes in vitro.

Options: View larger image (or click on image) Download as PowerPoint
PRC2 deletion drives MPNST metastatic phenotypes in vitro. (A) The 4 par...
(A) The 4 parental cell lines were derived from primary mouse MPNST models generated from either NC tumors (Nf1fl/fl Cdkn2afl/fl) mice injected with adenovirus expressing Cre recombinaseinto the sciatic nerve) or NP tumors (wild-type mice injected with adenovirus containing Cas9 and guide RNAs for Nf1 and p53 into the sciatic nerve). Isogenic panels were made by CRISPR editing of cells in vitro with Cas9 and guide RNAs targeting Eed, Suz12, or a nontargeting control (NT). (B) Representative Western blots of isogenic cell series show loss of EED, SUZ12, and the downstream functional target H3K27me3 compared with NT (n = 3). (C) Transwell migration assays show increased migration of ΔEed and ΔSuz12 cells compared with NT by 1-way ANOVA with Tukey’s multiple comparisons (n = 4). (D) Transwell invasion assays show increased invasion through collagen of ΔEed and ΔSuz12 cells compared with NT by Kruskal-Wallis with multiple comparisons (n = 3–6). Data represent biological replicates with the mean ± SD; *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.