Project description:The biosynthesis of androgen from cholesterol in testis is well understood, however, how cancer cells gauge dwindling androgen to dexterously initiate its de novo synthesis remained elusive. We uncovered that sterol regulatory element-binding protein 1 (SREBP1) and its switch to hitherto unknown dual-phosphorylated form (pY673/951-SREBP1), acts as an androgen sensor. Androgen deficiency promoted SREBP1 dual-phosphorylation, causing its dissociation from androgen receptor (AR) in its androgen-unbound state, followed by nuclear translocation. SREBP1 recruited KAT2A/GCN5 and deposited novel epigenetic marks, histone H2A Lys130-acetylation (H2A-K130ac) in SREBF1, reigniting de novo lipogenesis & steroidogenesis. Tumor-derived androgen retained SREBP1 in cytosol, promoting T cell exhaustion, reflected in elevated PD-1 and Tim3. Reversal of H2A-K130ac or pY-SREBP1 sensitized castration-resistant prostate cancer (CRPC) resistant to androgen synthesis inhibitor, Abiraterone. Further, nuclear SREBP1 and H2A-K130ac levels were significantly increased and directly correlated with late stage prostate cancer patients. Global lipidomics analysis revealed a distinct lipid signature in androgen-deprived CRPCs, resembling the lipid profile of prostate cancers of African-American (AA) men. Overall, self-perpetuating pY-SREBP1/H2A-K130ac signaling explains sex bias in cancers and reveal a novel therapeutic vulnerability wherein synchronous inhibition of GCN5 and Tyr-kinases could overcome drug-resistant disease, benefiting AA men with aggressive prostate cancer.

Project description:Cell lysates were immunoprecipitated using pTyr-beads, followed by mass spectrometry-based identification of the bound protein. Tyr-phosphorylated form of SREBP1 was identified with two Tyr-phosphorylation sites, Y673 and Y951 (Y649 & Y927 in SREBP-1C, and Y703 & Y981 in longer form)

Project description:Epigenetic Control of Androgen Production by Histone H2A Lys130 acetylation

Project description:Deciphering the epigenetic "code" remains a central issue in transcriptional regulation. Here, we report the identification of a JAMM/MPN(+) domain-containing histone H2A deubiquitinase (2A-DUB, or KIAA1915/MYSM1) specific for monoubiquitinated H2A (uH2A) that has permitted delineation of a strategy for specific regulatory pathways of gene activation. 2A-DUB regulates transcription by coordinating histone acetylation and deubiquitination, and destabilizing the association of linker histone H1 with nucleosomes. 2A-DUB interacts with p/CAF in a coregulatory protein complex, with its deubiquitinase activity modulated by the status of acetylation of nucleosomal histones. Consistent with this mechanistic role, 2A-DUB participates in transcriptional regulation events in androgen receptor-dependent gene activation, and the levels of uH2A are dramatically decreased in prostate tumors, serving as a cancer-related mark. We suggest that H2A ubiquitination represents a widely used mechanism for many regulatory transcriptional programs and predict that various H2A ubiquitin ligases/deubiquitinases will be identified for specific cohorts of regulated transcription units.

Project description:Prostate cancers (PCs), initially responsive to anti-androgen therapies, often advance to a hormone-refractory 'castrate-resistant' PC (CRPC) stage. However, the androgen receptor (AR) pathway remains active and key for cell growth and gene expression within tumours, even in the apparent absence of hormone. Proposed mechanisms to explain progression, including AR amplification/mutation, are insufficient to completely explain CRPC and possible roles of AR cofactors such as prohibitin (PHB) are poorly understood. We investigated whether PHB loss could sensitise PC cells and tumours to adrenal gland-derived androgens, which persist even after androgen ablation, hence contribute to development of CRPC. Using a pair of PC cell lines, inducibly expressing ectopic cDNA or RNAi for PHB, responses to different androgens and hormone concentrations were studied both in vitro and in vivo. PHB was found at the promoters of several genes, both AR and non-AR-regulated, and knockdown increased histone acetylation at these promoters. Further, PHB knockdown increased the rate of AR ligand-induced chromatin binding, and binding rate and occupancy of AR upon the PSA promoter. This resulted in increased cell growth and AR activity in response to all androgens, including promoting a response to the weaker adrenal androgens previously absent at physiological concentrations. In vivo this had functional consequences such that PHB knockdown resulted in androstenedione being sufficient to promote tumour growth, under conditions mimicking those in patients undergoing androgen ablation therapy. We conclude that reduction in PHB levels is sufficient to lower the threshold of AR activity in vitro and in vivo; this may be via a general increase in histone acetylation that could potentially affect signalling by other transcription factors. PHB loss may provide a mechanism for progression to CRPC by sensitising PC cells to 'castrate' conditions-that is, low levels of testicular androgens in the continued presence of weak adrenal and dietary androgens.

Project description:The lysine demethylase 3A (KDM3A, JMJD1A or JHDM2A) controls transcriptional networks in a variety of biological processes such as spermatogenesis, metabolism, stem cell activity, and tumor progression. We matched transcriptomic and ChIP-Seq profiles to decipher a genome-wide regulatory network of epigenetic control by KDM3A in prostate cancer cells. ChIP-Seq experiments monitoring histone 3 lysine 9 (H3K9) methylation marks show global histone demethylation effects of KDM3A. Combined assessment of histone demethylation events and gene expression changes presented major transcriptional activation suggesting that distinct oncogenic regulators may synergize with the epigenetic patterns by KDM3A. Pathway enrichment analysis of cells with KDM3A knockdown prioritized androgen signaling indicating that KDM3A plays a key role in regulating androgen receptor activity. Matched ChIP-Seq and knockdown experiments of KDM3A in combination with ChIP-Seq of the androgen receptor resulted in a gain of H3K9 methylation marks around androgen receptor binding sites of selected transcriptional targets in androgen signaling including positive regulation of KRT19, NKX3-1, KLK3, NDRG1, MAF, CREB3L4, MYC, INPP4B, PTK2B, MAPK1, MAP2K1, IGF1, E2F1, HSP90AA1, HIF1A, and ACSL3. The cancer systems biology analysis of KDM3A-dependent genes identifies an epigenetic and transcriptional network in androgen response, hypoxia, glycolysis, and lipid metabolism. Genome-wide ChIP-Seq data highlights specific gene targets and the ability of epigenetic master regulators to control oncogenic pathways and cancer progression.

Project description:Neuroendocrine prostate cancer (NEPC) is a more aggressive subtype of castration-resistant prostate cancer (CRPC). Although it is well established that PHF8 can enhance prostate cancer cell proliferation, whether PHF8 is involved in prostate cancer initiation and progression is relatively unclear. By comparing the transgenic adenocarcinoma of the mouse prostate (TRAMP) mice with or without Phf8 knockout, we systemically examined the role of PHF8 in prostate cancer development. We found that PHF8 plays a minimum role in initiation and progression of adenocarcinoma. However, PHF8 is essential for NEPC because not only is PHF8 highly expressed in NEPC but also animals without Phf8 failed to develop NEPC. Mechanistically, PHF8 transcriptionally upregulates FOXA2 by demethylating and removing the repressive histone markers on the promoter region of the FOXA2 gene, and the upregulated FOXA2 subsequently regulates the expression of genes involved in NEPC development. Since both PHF8 and FOXA2 are highly expressed in NEPC tissues from patients or patient-derived xenografts, the levels of PHF8 and FOXA2 can either individually or in combination serve as NEPC biomarkers and targeting either PHF8 or FOXA2 could be potential therapeutic strategies for NEPC treatment. © 2020 The Authors. The Journal of Pathology published by John Wiley & Sons, Ltd. on behalf of The Pathological Society of Great Britain and Ireland.

Project description:Differences in global levels of histone acetylation occur in normal and cancer cells, although the reason why cells regulate these levels has been unclear. Here we demonstrate a role for histone acetylation in regulating intracellular pH (pH(i)). As pH(i) decreases, histones are globally deacetylated by histone deacetylases (HDACs), and the released acetate anions are coexported with protons out of the cell by monocarboxylate transporters (MCTs), preventing further reductions in pH(i). Conversely, global histone acetylation increases as pH(i) rises, such as when resting cells are induced to proliferate. Inhibition of HDACs or MCTs decreases acetate export and lowers pH(i), particularly compromising pH(i) maintenance in acidic environments. Global deacetylation at low pH is reflected at a genomic level by decreased abundance and extensive redistribution of acetylation throughout the genome. Thus, acetylation of chromatin functions as a rheostat to regulate pH(i) with important implications for mechanism of action and therapeutic use of HDAC inhibitors.

Project description:BackgroundEpigenetic factors influence stem cell function and other developmental events but their role in prostate morphogenesis is not completely known. We tested the hypothesis that histone deacetylase (HDAC) activity is required for prostate morphogenesis.ResultsWe identified the presence of class I nuclear HDACs in the mouse urogenital sinus (UGS) during prostate development and found that Hdac 2 mRNA abundance diminishes as development proceeds which is especially evident in prostatic epithelium. Blockade of HDACs with the inhibitor trichostatin A (TSA) decreased the number of prostatic buds formed in UGS explant cultures but not the number of buds undergoing branching morphogenesis. In the latter, TSA promoted an extensive branching phenotype that was reversed by exogenous NOGGIN protein, which functions as a bone morphogenetic protein (BMP) inhibitor. TSA also increased Bmp2 promoter H3K27ac abundance, Bmp2 and Bmp4 mRNA abundance, and the percentage of epithelial cells marked by BMP-responsive phosphorylated SMAD1/5/8 protein. TSA exposed UGS explants grafted under the kidney capsule of untreated host mice for continued development achieved a smaller size without an obvious difference in glandular histology compared with control treated grafts.ConclusionsThese results are consistent with an active role for HDACs in shaping prostate morphogenesis by regulating Bmp abundance.

Project description:BACKGROUND:MRE11 is an important nuclease which functions in the end-resection step of homologous recombination (HR) repair of DNA double-strand breaks (DSBs). As MRE11-deficient ATLD cells exhibit hyper radio-sensitivity and impaired DSB repair, MRE11 inhibitors could possibly function as potent radio-sensitizers. Therefore, we investigated whether a bisbenzamidine derivative, pentamidine, which can inhibit endoexonuclease activity, might influence DSB-induced damage responses via inhibition of MRE11. RESULTS:We first clarified that pentamidine inhibited MRE11 nuclease activity and also reduced ATM kinase activity in vitro. Pentamidine increased the radio-sensitivity of HeLa cells, suggesting that this compound could possibly influence DNA damage response factors in vivo. Indeed, we found that pentamidine reduced the accumulation of gamma-H2AX, NBS1 and phospho-ATM at the sites of DSBs. Furthermore, pentamidine decreased HR activity in vivo. Pentamidine was found to inhibit the acetylation of histone H2A which could contribute both to inhibition of IR-induced focus formation and HR repair. These results suggest that pentamidine might exert its effects by inhibiting histone acetyltransferases. We found that pentamidine repressed the activity of Tip60 acetyltransferase which is known to acetylate histone H2A and that knockdown of Tip60 by siRNA reduced HR activity. CONCLUSION:These results indicate that inhibition of Tip60 as well as hMRE11 nuclease by pentamidine underlies the radiosensitizing effects of this compound making it an excellent sensitizer for radiotherapy or chemotherapy.