Abstract
Prostate cancer progression can be associated with androgen receptor (AR) mutations acquired following treatment with castration and/or an anti-androgen. Abiraterone, a rationally-designed inhibitor of CYP17A1 recently approved for the treatment of docetaxel-treated castration-resistant prostate cancer (CRPC), is often effective, but requires co-administration with glucocorticoids to curtail side effects. Here we hypothesized that progressive disease on abiraterone may occur secondary to glucocorticoid-induced activation of mutated AR. We found that prednisolone plasma levels in CRPC patients were sufficiently high to activate mutant AR. Mineralocorticoid receptor antagonists, such as spironoloactone and eplerenone that are used to treat side-effects related to mineralocorticoid excess, also bound to and activated signaling through both wild-type and mutant AR. Abiraterone inhibited in vitro proliferation and AR-regulated gene expression of AR-positive prostate cancer cells, which could be explained by AR antagonism in addition to inhibition of steroidogenesis. Interestingly, activation of mutant AR by eplerenone was inhibited by MDV3100, bicalutamide or greater concentrations of abiraterone. Therefore, an increase in abiraterone exposure above this threshold could reverse resistance secondary to activation of AR by residual ligands or co-administered drugs. Together, our findings provide a strong rationale for clinical evaluation of combined CYP17A1 inhibition and AR antagonism.
INTRODUCTION
The small-molecule CYP17A1 inhibitor, abiraterone acetate (Zytiga, Jannsen), was recently approved for the treatment of men with castration-resistant prostate cancer (CRPC) progressing after docetaxel chemotherapy. Despite a significant survival advantage with 1000mg abiraterone daily and objective tumor responses in up to 60% of CRPC patients, progressive disease on treatment invariably develops (1, 2). MDV3100 is a novel anti-androgen (3, 4) that has also recently been reported to confer a survival advantage in CRPC patients progressing after docetaxel (5). As PSA often rises at progression on both these agents, we have hypothesized that resistance occurs secondary to reactivation of androgen receptor (AR) signaling. Inhibition of CYP17A1 results in significant suppression of androgens and estrogens but also of cortisol that is associated with a compensatory rise in adrenocorticotrophic hormone (2). Abiraterone acetate has therefore been developed in combination with exogenous glucocorticoids. However, up to 40% of patients on prednisone/prednisolone alone and 55% of patients on abiraterone acetate and prednisone/prednisolone develop a syndrome of secondary mineralocorticoid excess characterized by hypokalemia, hypertension and fluid overload that can be controlled by increasing the dose of prednisone or adding a mineralocorticoid receptor antagonist (MRA) such as eplerenone (1). Eplerenone is currently recommended in preference to spironolactone as previous studies demonstrated that eplerenone did not bind and activate wild-type (WT)-AR (2, 6). However, as eplerenone is not invariably available, spironolactone is also being used.
Point mutations of the AR, which appear to cluster in the ligand-binding domain, are rare in therapy-naïve patients but occur in 15-45% of castration-resistant disease and can increase AR affinity for a wide range of steroids (7, 8). Over 100 mutations have been described and many have been shown to give a functional advantage to maintain AR signaling. We hypothesized that progressive disease on abiraterone acetate could occur secondary to activation of mutated “promiscuous” AR by steroidal agents administered to patients to prevent or treat side-effects of mineralocorticoid excess.
MATERIALS AND METHODS
Materials
Fetal bovine serum (FBS) and charcoal-stripped, dextran-treated fetal bovine serum (CSS) were purchased from Gibco. Bicalutamide, dexamethasone, prednisone and dihydrotestosterone (DHT) (Sigma-Aldrich, UK), tritiated [3H]-R1881 (Perkin-Elmer), R1881 (Steraloids, RI), eplerenone and spironolactone (Tocris-Bioscience, Bristol, UK) were obtained from commercial sources. Abiraterone and MDV3100 were synthesized using the publicly-available chemical structures and checked by mass-spectrometry. Drugs were dissolved in DMSO and then diluted to a maximum DMSO concentration of 0.2%. LNCaP, VCaP, PC-3, DU145 and COS-7 cells were obtained from ATCC-LGC Standards, grown according to ATCC recommendations, used less than 6 months from receipt and freeze-down and confirmed mycoplasma-free.
Luciferase reporter assays
We constructed a PSA-ARE3-luc luciferase reporter plasmid that was co-transfected with a human AR expression plasmid, F527-AR (wild-type (WT) or mutant as stated; mutations confirmed by sequencing (Beckman Coulter Genomics, UK)) into PC-3 cells. These were seeded in white opaque 384-well plates and grown in 10% CSS-supplemented phenol red-free RPMI 1640 for 30 hours. Cells were then treated with the indicated concentration of compound and R1881 for 16 hours. Luciferase activity was determined by adding ONE Glo (Promega, Southampton, UK) and measuring luminescence on a TopCount plate reader (Perkin-Elmer). Transfection efficiency and protein expression are shown in Supplemental Figure 1.
Cell viability
LNCaP and VCaP cells were seeded in 96-well plates and grown in CSS-supplemented phenol red-free or FBS-supplemented media for 7 days. Cells were treated with compound at 24 and 96 hours after plating and cell viability was determined on day 7 by adding CellTiter Glo (Promega) and measuring luminescence.
Ligand-binding assay
PC-3 cells transfected with WT or T877A mutant AR or LNCaP cells were seeded in 24-well plates and grown in CSS-supplemented phenol-red free media for 24 hours. To determine the kinetics of [3H]-R1881 binding to the WT and T877A AR, cells were treated with 0.25-25nM [3H]-R1881 for 2 hours, then washed, lysed and radioactivity was measured (1900CA analyzer, Perkin-Elmer). Kd and Bmax were determined by nonlinear regression using Graphpad Prism™ software. When the concentration of [3H]-R1881 required to almost saturate AR in both WT and T877A AR mutant transfections was established (5nM), displacement of [3H]-R1881 by test compound was determined. The concentration at which 50% of [3H]-R1881 was displaced (EC50) was established using nonlinear regression (GraphPad Prism).
Quantitative RT-PCR
LNCaP and VCaP cells were seeded in 6-well plates and grown in CSS-supplemented phenolred free media for 24 hours and then treated for 5 hours as indicated. Following RNA extraction and cDNA synthesis, quantitative-PCR was carried out on the Mx3000P QPCR System (Agilent) using the RT2 SYBR Green ROX™ qPCR Mastermix (SABiosciences). Every sample was run in duplicate and each reaction contained 50ng of cDNA in a total volume of 20μL. ΔCt for each gene was determined after normalization to actin and GAPDH and ΔΔCt was calculated relative to the designated reference sample. Gene expression values were set equal to 2−ΔΔCt (Applied Biosystems). Primers were purchased from SABiosciences.
Measurement of plasma prednisolone
Plasma was collected from CRPC patients after 48 days of continuous daily abiraterone acetate and prednisolone. All patients provided written, informed consent to blood withdrawal for research purposes and this study was approved by the Royal Marsden Hospital ethics review committees. Prednisolone was quantified by comparison to a calibration series ranging from 5 to 500ng/mL prepared in 50/50 methanol/water. A Waters Xevo mass spectrometer with Acquity uPLC system was used, fitted with a HSS T3, 1.8μm, 1.2×50mm column (Waters, UK). The column temperature was maintained at 60°C and the settings used were an electrospray source in positive ionisation mode; capillary voltage 4.0kV; source temperature, 150°C and desolvation temperature, 500°C.
RESULTS
The selective mineralocorticoid-receptor antagonist, eplerenone, activates mutant AR
We first co-transfected PC-3 AR-negative prostate cancer cells with PSA-ARE2-luciferase and either WT-AR or three mutations previously described in CRPC (T877A-AR, D879G-AR, W741C-AR). The T877A mutation has been identified in several studies in patients treated with flutamide (8, 9) and has been extensively studied as it is found in the LNCaP prostate cancer cell line (Supplemental Table 1). D879G and W741C mutations have been identified in patients previously treated with bicalutamide (8, 9). We then compared activation of wild-type or mutant AR by synthetic androgen (R1881) to activation by the MRAs, eplerenone and spironolactone. In keeping with previous reports, spironolactone activates WT AR (7) and also T877A-AR, D879G-AR and W741C-AR only two-log less potently than R1881 does (Figure 1A, B and Supplemental Figure 2). Eplerenone does not activate WT-AR, D879G-AR or W741C-AR but importantly can activate T877A-AR with a dose proportional response and an EC50 of 5.2μM (95% CI: 2.89 to 9.37μM) (Figure 1A, B, Supplemental Figure 2). Pharmacokinetic studies with eplerenone report a Cmax of 1.72 ±0.28μg/ml (equivalent to 4.2μM ±0.7μM) and a half-life of 3 hours with 100mg eplerenone (6); doses of eplerenone between 50mg and 200mg are used to treat toxicities secondary to mineralocorticoid excess from abiraterone in CRPC patients (Supplemental Table 2) . We proceeded to confirm that both spironolactone and eplerenone (1 and 10μM) increased proliferation of hormone-stripped LNCaP (T877A-AR) but only spironolactone increased the proliferation of VCaP (WT-AR) (Figure 1C). The increase in proliferation was inhibited by AR antagonism, suggesting this effect was secondary to binding to and activation of the AR (Figure 1C). Similarly, eplerenone significantly increased expression of the androgen-regulated and clinically important genes PSA and TMPRSS2 in LNCaP but not in VCaP (Figure 1D).
Exogenous glucocorticoids can activate mutant AR at clinically relevant doses observed in CRPC patients treated with abiraterone acetate
Prednisolone (UK) or its precursor prednisone (US) are commonly administered in combination with abiraterone acetate although two Phase II studies combined abiraterone acetate with dexamethasone (2, 10). Prednisone and dexamethasone do not activate WT-AR but activate T877A-AR with EC50s of 25.1μM (95% CI: 12.64 to 36.83μM) and 21.6μM (95% CI: 12.53 to 50.26μM) respectively (Figure 1A, B). Previous reports have demonstrated that other AR mutations such as T877A in combination with L701H are highly sensitive to glucocorticoids with activation by concentrations as low as 10nM (11). We therefore proceeded to measure plasma levels of prednisolone in 15 CRPC patients on continuous daily treatment with 1000mg abiraterone acetate and 10mg prednisolone. Prednisolone levels were <4nM in two patients but >30nM in the other 13 patients. The median concentration was 153nM (range: <4 to 305nM) (Figure 2, Supplemental Table 2).
Abiraterone binds and inhibits wild-type and mutant AR
Following the observation of activation of T877A-AR by eplerenone, we proceeded to evaluate the effect of abiraterone on wild-type and mutant AR (T877A, D879G, R629Q, W741C, M749L). We did not observe an increase in reporter-luciferase activity with doses of abiraterone up to 25μM with WT-AR or any mutation tested (Supplemental Figure 3) but observed dose-proportional inhibition of stimulated WT and mutant AR activity (Figure 3A) with significant inhibition observed at doses ≤10μM. Inhibition was however not as potent as for same concentrations of MDV3100. We then proceeded to confirm our findings by comparing inhibition of AR activation using abiraterone or MDV3100 in a different model system (COS-7 cells co-transfected with AR and a GRE2-TATA-Luc reporter gene and activated by 10nM DHT for 24 hours). Similarly we observed dose-proportional inhibition of WT-AR, T877A-AR, G142VAR, P533S-AR, T575A-AR and H874Y-AR by abiraterone (Figure 3B). Higher concentrations of abiraterone were required for inhibition of R629Q-AR in this system than was observed in PC-3 cells transfected with an ARE3-luciferase assay (Figure 3A). We also confirmed significant inhibition of proliferation of the AR-positive prostate cancer cell lines LNCaP and VCaP with doses of abiraterone ≥5 μM (Figure 3C). No inhibitory effect was observed with the AR-negative prostate cancer cell lines, PC-3 and DU145 (Supplemental Figure 4). We proceeded to confirm down-regulation by quantitative-PCR of PSA and TMPRSS2 in LNCaP cells treated with abiraterone (Figure 3D).
Binding of abiraterone or eplerenone to the AR is confirmed by competitive displacement of [3H]-R1881
To confirm that AR antagonism by abiraterone and agonism by eplerenone (both previously undescribed) occurred secondary to binding to the AR ligand-binding domain, we used a competitive radiolabelled assay to demonstrate displacement of R1881 from PC-3 cells transfected with either WT-AR or T877A-AR. The EC50 of eplerenone for WT-AR was six-fold higher than T877A-AR (EC50: 2.4⌠M (95% CI 2.0-2.9⌠M) (Figure 4A,B). In keeping with the inhibitory activity of abiraterone observed in our reporter-luciferase studies, abiraterone displaced ligand from both WT-AR (EC50: 13.4μM, 95% CI: 10.3-17.4μM) and T877A (EC50: 7.9μM, 95% CI: 6.7-9.3μM) (Figure 4A,B). We also confirmed displacement of radiolabelled R1881 from LNCaP with abiraterone (EC50: 2.6μM, 95% CI: 1.0–6.8μM) and eplerenone (EC50: 4.3μM, 2.4-7.8μM) (Supplemental Figure 5).
Mutant AR activation by eplerenone can be inhibited by abiraterone or bicalutamide but most effectively by MDV3100
We observed dose-proportional growth inhibition with abiraterone of LNCaP cells stimulated by eplerenone and of LNCaP and VCaP cells stimulated by spironolactone (Figure 1C). Similar levels of inhibition were observed with bicalutamide, with more profound inhibition by MDV3100 (Figure 1C). Abiraterone, MDV3100 and bicalutamide achieved similar levels of inhibition of up-regulation of PSA by eplerenone but MDV3100 inhibited induction of TMPRSS2 expression more significantly than bicalutamide or abiraterone (Figure 3D). Similarly, MDV3100 showed more significant inhibition of spironolactone-stimulated PSA and TMPRSS2 expressions than abiraterone or bicalutamide (Supplemental Figure 6). Also, abiraterone (5μM) significantly inhibited activation of T877A-AR (in transfected PC-3) by 1μM eplerenone but not by 10μM eplerenone; stimulation by 10μM eplerenone was significantly inhibited by both bicalutamide and MDV3100 (Figure 4C).
Increased hormone levels reduce AR inhibition by MDV3100
Recent studies have demonstrated that intra-tumoral testosterone levels rise in patients treated with MDV3100 (12). We found that ≥1μM and ≥10μM MDV3100 significantly inhibited WT AR luciferase activity stimulated by 0.1nM R1881 or 1nM DHT respectively but ≥50 μM MDV3100 was required to significantly inhibit AR stimulated by 1nM R1881 (Figure 4D) or 10nM DHT (Supplemental Figure 7).
DISCUSSION
Abiraterone was developed as a specific CYP17A1 inhibitor (13). Previous studies have failed to identify binding of abiraterone to the AR (14). However, in this study we utilized both reporter-luciferase and competitive radiolabelled assays to demonstrate that abiraterone binds and inhibits WT-AR. Another study published whilst our manuscript was under review reported supporting evidence that abiraterone binds the AR and produces a dose-dependent decrease in AR levels (15). This study failed to identify the EC50 with wild-type or mutant AR but predicted it as over ≥3μM. We also tested eight AR mutations selected from a screen of 42 mutations for causing a differential response to various hormones. We included mutations in the amino terminal (G142V, P533S), DNA-binding (T575A) and ligand-binding (W741C, M749L, T877A, D879G and H874Y) domains and the hinge region (R629Q) (Supplemental Table 1). As previously described, bicalutamide activated W741C (4, 16) but no agonistic activity was observed with any mutation and abiraterone. Similarly MDV3100 potently inhibited WT-AR and mutant AR. However, these mutations were mostly identified in patients progressing on bicalutamide or flutamide and different, new mutations may develop in patients progressing on abiraterone or MDV3100.
Abiraterone is an active treatment for CRPC due to CYP17A1 inhibition and significant suppression of hormones (2). However, we observed up to 32% AR inhibition with 1μM abiraterone, with significantly greater inhibition at 5 and 10μM. Pharmacokinetic studies have reported maximum plasma levels after a single 1000mg dose of abiraterone acetate in fasting patients of 1.2 to 5μM, confirming AR antagonism could occur at clinically achievable doses (Supplemental Table 2) (2, 17). Higher doses of abiraterone up to at least 2000mg daily are safely tolerated (2) and greater activity could be observed with increased drug exposure despite complete CYP17A1 inhibition at lower doses. This could be achieved by administration with food (2, 17). Moreover, several studies of abiraterone have now reported preclinical in vitro and in vivo anti-tumor activity and inhibition of AR nuclear localization and AR-regulated transcription that was attributed entirely to inhibition of steroidogenesis (18, 19) but could in fact be partly explained by AR antagonism. Similarly, in vitro inhibition of LNCaP and VCaP cells in our study could also be explained by abiraterone’s effect on steroidogenesis.
Significant activation of both WT and mutant AR is observed with spironolactone that should be avoided in all CRPC patients. We also demonstrate activation of T877A-AR by eplerenone that was developed as a novel, non-AR binding MRA (6). This could underlie clinical resistance in a proportion of patients. Similarly, exogenous glucocorticoids that are currently administered in combination with abiraterone reach levels in patients that have been previously shown to activate mutant AR (11). Activation of “promiscuous” AR by co-administered drugs or residual hormones (as we reported recently (20)) could be inhibited by increasing the dose of abiraterone or possibly more effectively, combining with a potent antiandrogen such as MDV3100. Due to toxicity the dose of MDV3100 selected for Phase III development was 160mg daily that achieves median plasma concentrations up to approximately 35μM (3, 4). AR inhibition at these concentrations could be overcome by a rise in hormones that would be prevented by combination with abiraterone acetate. Overall these observations provide a strong rationale for clinical evaluation of combined CYP17A1 inhibition and AR antagonism.
Supplementary Material
Acknowledgements
Elaine Barrie in the Centre for Cancer Therapeutics, The Institute of Cancer Research, Sutton, Surrey for helpful discussions on experimental design. Elizabeth Folkerd and Mitch Dowsett in the Royal Marsden Hospital Academic Biochemistry Department, Fulham Road, London for assistance with radiolabelled ligand-binding studies. Penny Flohr, Cancer Biomarkers, The Institute of Cancer Research, Sutton, Surrey for assistance with processing clinical samples.
Funding: The authors are employees of the Section of Medicine that is supported by a Cancer Research UK programme grant and an Experimental Cancer Medical Centre (ECMC) grant from Cancer Research UK and the Department of Health (Ref: C51/A7401). G.A. is also supported by an NIHR clinical lectureship, a Welcome Trust Starter Grant for Clinical Lecturers and a young investigator award from the Prostate Cancer Foundation, Santa Monica, CA. J.R. and A.W. were supported by Prostate Action, London, UK. W.A. is in receipt of a Medical Research Council (MRC) UK Strategic Biomarker Grant (G0801473). CWH was supported by the Chief Scientist’s Office, Scottish Government. The authors also acknowledge NHS funding to the RMH NIHR Biomedical Research Centre.
Footnotes
Disclosure: Abiraterone acetate was developed at The Institute of Cancer Research, which therefore has a commercial interest in the development of this agent. J.S.d.B. has received consulting fees from Ortho Biotech Oncology Research and Development (a unit of Cougar Biotechnology), consulting fees and travel support from Amgen, Astellas, AstraZeneca, Boehringer Ingelheim, Bristol-Myers Squibb, Dendreon, Enzon, Exelixis, Genentech, GlaxoSmithKline, Medivation, Merck, Novartis, Pfizer, Roche, Sanofi-Aventis, Supergen, and Takeda, and grant support from AstraZeneca. G.A has received consulting fees from Janssen-Cilag, Veridex and Millennium Pharmaceuticals, lecture fees from Janssen-Cilag, Ipsen and Sanofi-Aventis, and grant support from AstraZeneca. G.A. is on The ICR rewards to inventors list of abiraterone acetate.
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