Loss of dihydrotestosterone-inactivation activity promotes prostate cancer castration resistance detectable by functional imaging

Zhu, Ziqi; Chung, Yoon‐Mi; Сергеева, О. Н.; Kepe, Vladimir; Berk, Michael; Li, Jianneng; Ko, Hyun-Kyung; Li, Zhenfei; Petro, Marianne; DiFilippo, Frank P.; Lee, Zhenghong; Sharifi, Nima

doi:10.1074/jbc.ra118.004846

Cited by 32 publications

(19 citation statements)

References 33 publications

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“…76 The somatic loss of UGT2B17 in tumour cells is associated with the development of a castration-resistant phenotype in vitro and in xenograft mouse models, consistent with the importance of this pathway in ligand-dependent pre-androgen receptor control of androgen metabolism. 79 Indeed, inherited or acquired loss or inhibition of the UGT androgen inactivation pathway increases exposure to local androgens, enhances androgen receptor activation and promotes cancer-cell proliferation. 80 However, there is accumulating evidence that UGT overexpression could function as an independent prognostic factor associated with the progression of prostate cancer.…”

Section: Ugt2b17mentioning

confidence: 99%

Emerging roles for UDP-glucuronosyltransferases in drug resistance and cancer progression

et al. 2020

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The best-known role of UDP-glucuronosyltransferase enzymes (UGTs) in cancer is the metabolic inactivation of drug therapies. By conjugating glucuronic acid to lipophilic drugs, UGTs impair the biological activity and enhance the water solubility of these agents, driving their elimination. Multiple clinical observations support an expanding role for UGTs as modulators of the drug response and in mediating drug resistance in numerous cancer types. However, accumulating evidence also suggests an influence of the UGT pathway on cancer progression. Dysregulation of the expression and activity of UGTs has been associated with the progression of several cancers, arguing for UGTs as possible mediators of oncogenic pathways and/or disease accelerators in a drug-naive context. The consequences of altered UGT activity on tumour biology are incompletely understood. They might be associated with perturbed levels of bioactive endogenous metabolites such as steroids and bioactive lipids that are inactivated by UGTs or through non-enzymatic mechanisms, thereby eliciting oncogenic signalling cascades. This review highlights the evidence supporting dual roles for the UGT pathway, affecting cancer progression and drug resistance. Pharmacogenomic testing of UGT profiles in patients and the development of therapeutic options that impair UGT actions could provide useful prognostic and predictive biomarkers and enhance the efficacy of anti-cancer drugs.

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Section: Ugt2b17mentioning

confidence: 99%

Emerging roles for UDP-glucuronosyltransferases in drug resistance and cancer progression

et al. 2020

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“…AR target genes notably associated with energy production were repressed, including the putative tumor suppressor hydroxyprostaglandin dehydrogenase ( HPGD ) 75 , as well as Acyl-CoA synthetase long chain family member 3 (ACSL3) 76 and Alpha-2-glycoprotein 1, zinc-binding ( AZGP1 ) 77 . Up-regulated peroxisome genes included retinoic acid anabolizing enzyme, Dehydrogenase/Reductase 3 ( DHRS3 ) 78 , and the steroid catabolizing enzyme UDP Glucuronosyltransferase Family 2 Member B17 ( UGT2B17 ) 79 . These changes in hallmark gene sets suggests that altered PGC1α disrupts the energetic utilization of the cell and distorts AR signaling.…”

Section: Resultsmentioning

confidence: 99%

Identification of transcription factor co-regulators that drive prostate cancer progression

Siddappa

Wani

Long

et al. 2020

Sci Rep

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In prostate cancer (PCa), and many other hormone-dependent cancers, there is clear evidence for distorted transcriptional control as disease driver mechanisms. Defining which transcription factor (TF) and coregulators are altered and combine to become oncogenic drivers remains a challenge, in part because of the multitude of TFs and coregulators and the diverse genomic space on which they function. The current study was undertaken to identify which TFs and coregulators are commonly altered in PCa. We generated unique lists of TFs (n = 2662), coactivators (COA; n = 766); corepressors (COR; n = 599); mixed function coregulators (MIXED; n = 511), and to address the challenge of defining how these genes are altered we tested how expression, copy number alterations and mutation status varied across seven prostate cancer (PCa) cohorts (three of localized and four advanced disease). Testing of significant changes was undertaken by bootstrapping approaches and the most significant changes were identified. For one commonly and significantly altered gene were stably knocked-down expression and undertook cell biology experiments and RNA-Seq to identify differentially altered gene networks and their association with PCa progression risks. COAS, CORS, MIXED and TFs all displayed significant down-regulated expression (q.value < 0.1) and correlated with protein expression (r 0.4–0.55). In localized PCa, stringent expression filtering identified commonly altered TFs and coregulator genes, including well-established (e.g. ERG) and underexplored (e.g. PPARGC1A, encodes PGC1α). Reduced PPARGC1A expression significantly associated with worse disease-free survival in two cohorts of localized PCa. Stable PGC1α knockdown in LNCaP cells increased growth rates and invasiveness and RNA-Seq revealed a profound basal impact on gene expression (~ 2300 genes; FDR < 0.05, logFC > 1.5), but only modestly impacted PPARγ responses. GSEA analyses of the PGC1α transcriptome revealed that it significantly altered the AR-dependent transcriptome, and was enriched for epigenetic modifiers. PGC1α-dependent genes were overlapped with PGC1α-ChIP-Seq genes and significantly associated in TCGA with higher grade tumors and worse disease-free survival. These methods and data demonstrate an approach to identify cancer-driver coregulators in cancer, and that PGC1α expression is clinically significant yet underexplored coregulator in aggressive early stage PCa.

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“…However, in a castrate environment these cells may become glucuronidation deficient and resistant to androgen deprivation. Using CRISPR/Cas9mediated gene ablation, loss of UDP glucuronosyltransferase family 2 member B15α(UGT2B15) and UGT2B17 was sufficient to restore free 5α-DHT, sustain androgen signaling, and lead to the development of castration resistance (41). However paradoxically, several studies show that these enzymes are elevated in CRPC and may represent adaptive changes to make the tumor independent of AR ligands (42)(43)(44).…”

Section: 6 Deficiencies In Glucuronidationmentioning

confidence: 99%

Intracrinology-revisited and prostate cancer

Penning

Detlefsen

2020

The Journal of Steroid Biochemistry and Molecular Biology

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The formation of steroid hormones in peripheral target tissues is referred to as their intracrine formation. This process occurs in hormone dependent malignancies such as prostate and breast cancer in which the disease can be either castrate resistant or occur post-menopausally, respectively. In these instances, the major precursor steroid of androgens and estrogens is dehydroepiandrosterone (DHEA) and DHES-SO 4 . This article reviews the major pathways by which adrenal steroids are converted to the potent male sex hormones, testosterone (T) and 5αdihydrotestosterone (5α-DHT) and the discrete enzyme isoforms involved in castration resistant prostate cancer. Previous studies have mainly utilized radiotracers to investigate these pathways but have not used prevailing concentrations of precursors found in castrate male human serum. In addition, the full power of stable-isotope dilution liquid chromatography tandem mass spectrometry has not been applied routinely. Furthermore, it is clear that adaptive responses occur in the transporters and enzyme isoforms involved in response to androgen deprivation therapy that need to be considered.

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Loss of dihydrotestosterone-inactivation activity promotes prostate cancer castration resistance detectable by functional imaging

Cited by 32 publications

References 33 publications

Emerging roles for UDP-glucuronosyltransferases in drug resistance and cancer progression

Emerging roles for UDP-glucuronosyltransferases in drug resistance and cancer progression

Identification of transcription factor co-regulators that drive prostate cancer progression

Intracrinology-revisited and prostate cancer

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