RSK1-driven TRIM28/E2F1 feedback loop promotes castration-resistant prostate cancer progression
Miyeong Kim, Jinpeng Liu, Yanquan Zhang, Ruixin Wang, Ryan Goettl, Jennifer Grasso, Derek B. Allison, Chi Wang, Tianyan Gao, Xiaoqi Liu, Ka-Wing Fong
Miyeong Kim, Jinpeng Liu, Yanquan Zhang, Ruixin Wang, Ryan Goettl, Jennifer Grasso, Derek B. Allison, Chi Wang, Tianyan Gao, Xiaoqi Liu, Ka-Wing Fong
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Research Article Cell biology Endocrinology

RSK1-driven TRIM28/E2F1 feedback loop promotes castration-resistant prostate cancer progression

Abstract

Castration-resistant prostate cancer (CRPC) marks the advanced and lethal stage of prostate cancer (PCa). TRIM28, also known as KAP1, is a transcriptional regulator recently shown to promote CRPC cell proliferation and xenograft tumor growth. Nonetheless, knowledge gaps persist regarding the mechanisms underlying TRIM28 upregulation in CRPC as well as the genomic targets regulated by TRIM28. Here, we report that TRIM28 is a E2F1 target in CRPC. Using an integrated genomic approach, we have demonstrated that TRIM28 forms a positive feedback loop to promote the transcriptional activation and genomic function of E2F1 independent of retinoblastoma (Rb) status. Furthermore, we identified RSK1 as a kinase that directly phosphorylates TRIM28 at S473, and, as such, RSK1 drives the TRIM28/E2F1 feedback loop. Accordingly, pS473-TRIM28 promotes CRPC progression, which is mitigated by RSK inhibition. In summary, our study reveals a critical role of the RSK1–TRIM28–E2F1 axis in CRPC progression, which may be exploited as a vulnerability in treating Rb-deficient CRPC.

Authors

Miyeong Kim, Jinpeng Liu, Yanquan Zhang, Ruixin Wang, Ryan Goettl, Jennifer Grasso, Derek B. Allison, Chi Wang, Tianyan Gao, Xiaoqi Liu, Ka-Wing Fong

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Figure 5

RSK1 directly phosphorylates TRIM28 at S473 in CRPC.

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RSK1 directly phosphorylates TRIM28 at S473 in CRPC. (A and B) RSK1 inte...
(A and B) RSK1 interacts with TRIM28 in cells. Co-IP was performed in 293T cell lysates expressing MYC-RSK1 along with HA-Flag GFP fusion (as negative control) or HA-Flag TRIM28 (A), MYC-TRIM28 along with HA-Flag GFP fusion or HA-Flag RSK1 (B) using Flag antibody. The eluted protein was analyzed by immunoblot. (CE) RSK1 phosphorylates TRIM28 at S473 in vitro. Using E.coli-expressed GST-TRIM28 fragments (F1-F2) (C), in vitro kinase assay was performed in presence of γ-32P–labelled ATP and with the use of an autoradiograph to detect protein phosphorylation (D) or in the presence of unlabeled ATP and with the use of immunoblotting to detect pS473-TRIM28 (E). (F and G) RSK1 phosphorylates TRIM28 at S473 in PCa cells. C4-2B cells transiently expressing MYC-RSK1 along with TRIM28-WT or TRIM28-S473A (F); MYC-TRIM28 along with Flag-RSK1-WT, -CA (constitutively active) and -KI (kinase-inactive) were harvested for immunoblot (G). (H and I) Protein lysates of C42B and DU145 cells with LKO and 2-independent shRSK1 were collected for immunoblot.