microRNA-143/145 loss induces Ras signaling to promote aggressive Pten-deficient basal-like breast cancer
Sharon Wang, Jeff C. Liu, YoungJun Ju, Giovanna Pellecchia, Veronique Voisin, Dong-Yu Wang, Rajwinder Leha l, Yaacov Ben-David, Gary D. Bader, Eldad Zacksenhaus
Sharon Wang, Jeff C. Liu, YoungJun Ju, Giovanna Pellecchia, Veronique Voisin, Dong-Yu Wang, Rajwinder Leha l, Yaacov Ben-David, Gary D. Bader, Eldad Zacksenhaus
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Research Article Oncology

microRNA-143/145 loss induces Ras signaling to promote aggressive Pten-deficient basal-like breast cancer

Abstract

The tumor suppressor PTEN is frequently inactivated in breast and other cancers; yet, germ-line mutations in this gene induce nonmalignant hamartomas, indicating dependency on additional cooperating events. Here we show that most tumors derived from conditional deletion of mouse pten in mammary epithelium are highly differentiated and lack transplantable tumor-initiating cells (TICs) capable of seeding new tumors following orthotopic injection of FACS-sorted or tumorsphere cells. A rare group of poorly differentiated tumors did harbor transplantable TICs. These transplantable tumors exhibited distinct molecular classification, signaling pathways, chromosomal aberrations, and mutational landscape, as well as reduced expression of microRNA-143/145 (miR-143/145). Stable knockdown of miR-143/145 conferred tumorigenic potential upon poorly transplantable pten-deficient tumor cells through a mechanism involving induction of RAS signaling, leading to increased sensitivity to MEK inhibition. In humans, miR-145 deficiency significantly correlated with elevated RAS-pathway activity in basal-like breast cancer, and patients with combined PTEN/miR-145 loss or PTEN-loss/high RAS-pathway activity exhibited poor clinical outcome. These results underscore a selective pressure for combined PTEN loss together with RAS-pathway activation, either through miR-145 loss or other mechanisms, in basal-like breast cancer, and a need to identify and prioritize these tumors for aggressive therapy.

Authors

Sharon Wang, Jeff C. Liu, YoungJun Ju, Giovanna Pellecchia, Veronique Voisin, Dong-Yu Wang, Rajwinder Leha l, Yaacov Ben-David, Gary D. Bader, Eldad Zacksenhaus

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Figure 7

miR-143/145 overexpression targets the Ras pathway.

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miR-143/145 overexpression targets the Ras pathway. (A) Quantitative RT-...
(A) Quantitative RT-PCR analysis of miR-143 and miR-145 levels following lentiviral transduction of miR-143 and miR-145. n = 9. Student’s t test, P < 0.05. Bars represent mean ± SD. Circles represent individual data points. (B) Representative Western blot analysis for Ras (K-Ras plus N-Ras) following miR-143/145 overexpression. n = 5 (see Figure 7D). (C) Representative Western blot analysis for phospho-Erk following miR-143/145 overexpression. n = 5 (see Figure 7D). (D) miR-143/145 overexpression leads to reduced Ras expression (n = 5, Student’s t test, P = 0.0470), and phospho-Erk levels (n = 5, Student’s t test, P = 0.0387). Bars represent mean ± SD. Circles represent individual data points. (E) Workflow used to identify potential targets and pathways regulated by miR-143/145. The conserved 61 miR-143 and 98 miR-145 genes are listed in Supplemental Table 1. (F) Venn diagram of predicted targets of miR-143 (13 genes) and miR-145 (14 genes), which are conserved, on the Ras pathway and differentially regulated between pten-deficient adenomyoepithelioma (AME) and poorly differentiated adenocarcinoma (PDA) tumors. Genes enriched in AMEs are highlighted in green; those enriched in PDAs in red. (G) Quantitative RT-PCR analysis of predicted miR-143/145 targets Mapk3, Efna1a, Epha2, Nras, Kras, and Rreb1 following miR-143/145 overexpression. ANOVA (P < 0.0001) and Bonferroni post-hoc test (#P < 0.09, *P < 0.05, **P < 0.001). n = 3. Bars represent mean ± SD. Circles represent individual data points.