Active DHEA uptake in the prostate gland correlates with aggressive prostate cancer
Xuebin Zhang, … , Denglong Wu, Zhenfei Li
Xuebin Zhang, … , Denglong Wu, Zhenfei Li
Published December 15, 2023
Citation Information: J Clin Invest. 2023;133(24):e171199. https://doi.org/10.1172/JCI171199.
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Research Article Oncology

Active DHEA uptake in the prostate gland correlates with aggressive prostate cancer

Abstract

Strategies for patient stratification and early intervention are required to improve clinical benefits for patients with prostate cancer. Here, we found that active DHEA utilization in the prostate gland correlated with tumor aggressiveness at early disease stages, and 3βHSD1 inhibitors were promising for early intervention. [3H]-labeled DHEA consumption was traced in fresh prostatic biopsies ex vivo. Active DHEA utilization was more frequently found in patients with metastatic disease or therapy-resistant disease. Genetic and transcriptomic features associated with the potency of prostatic DHEA utilization were analyzed to generate clinically accessible approaches for patient stratification. UBE3D, by regulating 3βHSD1 homeostasis, was discovered to be a regulator of patient metabolic heterogeneity. Equilin suppressed DHEA utilization and inhibited tumor growth as a potent 3βHSD1 antagonist, providing a promising strategy for the early treatment of aggressive prostate cancer. Overall, our findings indicate that patients with active prostatic DHEA utilization might benefit from 3βHSD1 inhibitors as early intervention.

Authors

Xuebin Zhang, Zengming Wang, Shengsong Huang, Dongyin He, Weiwei Yan, Qian Zhuang, Zixian Wang, Chenyang Wang, Qilong Tan, Ziqun Liu, Tao Yang, Ying Liu, Ruobing Ren, Jing Li, William Butler, Huiru Tang, Gong-Hong Wei, Xin Li, Denglong Wu, Zhenfei Li

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Figure 6

UBE3D binds to 3βHSD1.

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UBE3D binds to 3βHSD1. (A) Schema of potential ubiquitin ligase screenin...
(A) Schema of potential ubiquitin ligase screening. Immunoprecipitation–mass spectrometry (IP-MS) was performed in LNCaP cells expressing FLAG-tagged 3βHSD1 (LNCaP-FLAG-3βHSD1). (B) UBE3D mRNA abundance in biopsies with high or low metabolic activities. (C) Correlation of UBE3D levels with treatment duration in TCGA. Log-rank test. (D) Deletion frequency of UBE3D in prostate cancer. (E) Correlation of UBE3D levels with DHEA transcriptomic signature and DHEA signature in our cohort. Pearson’s correlation. (F and G) UKBB-PRS and PRACTICAL-PRS in patients with different UBE3D levels. One-tailed Student’s t test. (H) Interaction between UBE3D and 3βHSD1. UBE3D and 3βHSD1 were overexpressed in HEK293T cells. (I) Interaction of 3βHSD1 with different UBE3D truncations. (J) Direct binding of UBE3D to 3βHSD1 in vitro. UBE3D was purified in E. coli system, and 3βHSD1 was purified in Sf9 cells. (K) Endogenous UBE3D binds to 3βHSD1. Stable cell line with FLAG-3βHSD1 expressed at comparable levels of endogenous 3βHSD1 was used. Two-tailed Student’s t test. *P < 0.05; **P < 0.01.