Synergistic Activity with NOTCH Inhibition and Androgen Ablation in ERG-Positive Prostate Cancer Cells

Overview

Journal Mol Cancer Res

Specialty Cell Biology

Date 2017 Jun 14

PMID 28607007

Citations 27

Authors

Ahmed A Mohamed

Shyh-Han Tan

Charles P Xavier

Shilpa Katta

Wei Huang

Lakshmi Ravindranath

Muhammad Jamal

Hua Li

Meera Srivastava

Eri S Srivatsan

Taduru L Sreenath

David G McLeod

Alagarsamy Srinivasan

Gyorgy Petrovics

Albert Dobi

Shiv Srivastava

Affiliations

Soon will be listed here.

Abstract

The oncogenic activation of the ETS-related gene () due to gene fusions is present in over half of prostate cancers in Western countries. Because of its high incidence and oncogenic role, ERG and components of ERG network have emerged as potential drug targets for prostate cancer. Utilizing gene expression datasets, from matched normal and prostate tumor epithelial cells, an association of NOTCH transcription factors with expression status was identified, confirming that factors are direct transcriptional targets of ERG. Inhibition of ERG in -positive VCaP cells led to decreased levels of NOTCH1 and 2 proteins and downstream transcriptional targets and partially recapitulated the phenotypes associated with ERG inhibition. Regulation of and genes by ERG were also noted with ectopic ERG expression in LNCaP (ERG-negative prostate cancer) and RWPE-1 (benign prostate-derived immortalized) cells. Furthermore, inhibition of NOTCH by the small-molecule γ-secretase inhibitor 1, GSI-1, conferred an increased sensitivity to androgen receptor (AR) inhibitors (bicalutamide and enzalutamide) or the androgen biosynthesis inhibitor (abiraterone) in VCaP cells. Combined treatment with bicalutamide and GSI-1 showed strongest inhibition of AR, ERG, NOTCH1, NOTCH2, and PSA protein levels along with decreased cell growth, cell survival, and enhanced apoptosis. Intriguingly, this effect was not observed in ERG-negative prostate cancer cells or immortalized benign/normal prostate epithelial cells. These data underscore the synergy of AR and NOTCH inhibitors in reducing the growth of ERG-positive prostate cancer cells. Combinational targeting of NOTCH and AR signaling has therapeutic potential in advanced ERG-driven prostate cancers. .

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