RB1-deficient prostate tumor growth and metastasis are vulnerable to ferroptosis induction via the E2F/ACSL4 axis
Mu-En Wang, … , Jiaoti Huang, Ming Chen
Mu-En Wang, … , Jiaoti Huang, Ming Chen
Published March 16, 2023
Citation Information: J Clin Invest. 2023;133(10):e166647. https://doi.org/10.1172/JCI166647.
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Research Article Oncology

RB1-deficient prostate tumor growth and metastasis are vulnerable to ferroptosis induction via the E2F/ACSL4 axis

Abstract

Inactivation of the RB1 tumor suppressor gene is common in several types of therapy-resistant cancers, including metastatic castration-resistant prostate cancer, and predicts poor clinical outcomes. Effective therapeutic strategies against RB1-deficient cancers remain elusive. Here, we showed that RB1 loss/E2F activation sensitized cancer cells to ferroptosis, a form of regulated cell death driven by iron-dependent lipid peroxidation, by upregulating expression of ACSL4 and enriching ACSL4-dependent arachidonic acid–containing phospholipids, which are key components of ferroptosis execution. ACSL4 appeared to be a direct E2F target gene and was critical to RB1 loss–induced sensitization to ferroptosis. Importantly, using cell line–derived xenografts and genetically engineered tumor models, we demonstrated that induction of ferroptosis in vivo by JKE-1674, a highly selective and stable GPX4 inhibitor, blocked RB1-deficient prostate tumor growth and metastasis and led to improved survival of the mice. Thus, our findings uncover an RB/E2F/ACSL4 molecular axis that governs ferroptosis and also suggest a promising approach for the treatment of RB1-deficient malignancies.

Authors

Mu-En Wang, Jiaqi Chen, Yi Lu, Alyssa R. Bawcom, Jinjin Wu, Jianhong Ou, John M. Asara, Andrew J. Armstrong, Qianben Wang, Lei Li, Yuzhuo Wang, Jiaoti Huang, Ming Chen

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Figure 3

ACSL4 is critical to RB-regulated ferroptosis.

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ACSL4 is critical to RB-regulated ferroptosis. (A) Bar graph showing the...
(A) Bar graph showing the relative MS1 peak area intensity of all the identifiable AA-containing phospholipids in control or RB stable–knockdown LNCaP or PC3 cells. (B) Immunoblot analysis of cell lysates from of control or RB stable–knockdown PC3 cells in the absence or presence of ASCL4 stable knockdown. (C and D) Levels of lipid peroxidation after 6 hours of 1 μM RSL3 treatment (C) or cell viability assay after 24 hours of 50 nM RSL3 treatment (D) in control or RB stable–knockdown PC3 cells in the absence or presence of ACSL4 stable knockdown. (E and F) 24-hour dose-response curves of RSL3 treatment in control or RB1 stable–knockout LNCaP (E) or PC3 (F) cells pretreated with vehicle or 20 μM PRGL493 for 24 hours. In A, unpaired 2-tailed t test was used to determine significance. In C and D, 1-way ANOVA with Tukey’s multiple-comparison test was used to determine significance. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001. All data are shown as the mean ± SD from n = 3~4 biological replicates.