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The use of luteinizing hormonereleasing hormone analogues is still an indispensable element of therapy in castrate-resistant prostate cancer

Tomasz Milecki
,
Andrzej Antczak
,
Zbigniew Kwias
,
Piotr Milecki

Contemp Oncol (Pozn) 2014; 18 (2): 85–89
Online publish date: 2014/06/03
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For decades, hormone-refractory prostate cancer was defined as a neoplasm, the development of which no longer depended on hormonal therapy, and thus on the testosterone concentration. In the light of recent fundamental and clinical research results, the definition of hormone-refractory prostatic cancer, i.e. cancer which progresses after the primary hormone treatment, has been revised, and has been changed to castrate-resistant prostate cancer.
One of the standards in the treatment of metastatic castrate-resistant prostate cancer (mCRPC) is hormone therapy, which aims to eliminate androgens from the blood via suppression of the hypothalamic-pituitary-gonadal axis and/or inhibition of androgen receptors by testosterone-competitive and dihydrotestosterone-competitive agents [1]. Unfortunately, hormone therapy is usually effective for a relatively short period of time, after which progression occurs as a result of resistance to the treatment.
Testosterone “fuels” cancer prostate cells, stimulating their proliferation. The androgen-dependent nature of prostate cancer was discovered in 1941 by Huggins and Hodges [2]. 95% of testosterone is produced in Leydig cells in man’s testicles [3]. Within neoplastic cells, testosterone is transformed into a more active form, dihydrotestosterone. Both compounds demonstrate affinity to the androgen receptor in the cytoplasm, and together create a complex which penetrates into the cell nucleus and binds with certain DNA sequences responsible for growth, proliferation and metabolism of neoplastic cells. To date, it has been assumed that being refractory to hormone therapy is caused by a certain vaguely defined “resistance” to hormonal treatment. However, numerous studies in which concentrations of testosterone and its derivatives were measured in the hormone-refractory cancer tissue provided evidence that castration therapy does not entirely eliminate androgens from the tumour cell environment, despite castration levels of testosterone in peripheral blood [4]. This is due to the fact that the metabolism of adrenal androgens and intracellular steroidogenesis pathways in the cancer cells responsible for de novo synthesis of androgens is still active [5, 6]. Another important factor in the pathogenesis of castrate-resistant cancer is the increased sensitivity of neoplastic cells to very low testosterone concentrations. This is caused by over-expression of the androgen receptor, and by its mutations [7]. It has been demonstrated that even trace amounts of androgens enable activation of the mutated and multiplied androgen receptor [8]. The discovery of these relationships in the cells of cancer resistant to hormone therapy led to the hypothesis that, although previously treated as hormone-refractory, prostate cancer is still dependent on androgen concentrations. As a result, the commonly accepted term “castrate-resistant prostate cancer” has been introduced. The main goal of castrate-resistant cancer treatment is inhibition of the androgen-receptor axis. This effect may be achieved by a maximum reduction of androgen activity. Therefore, the basic treatment strategy is the maximum inhibition of testosterone production in the testicles as a result of using luteinizing hormone-releasing hormone (LHRH) analogues. Simultaneously, new medications are introduced, which may demonstrate a direct cytotoxic effect (docetaxel, cabazitaxel), or which may lead to a further reduction of the testosterone concentration in the external environment of the prostate cancer cell by blocking testosterone production (abiraterone). Another method of reducing the effect of androgens on a cancer cell is to use chemotherapeutic agents more effective than bicalutamide for androgen receptor inhibition, then to block the androgen receptor complex inside the cell, and finally inhibit DNA activation (enzalutamide). Despite using the mentioned medications, it should be taken into consideration that the hypothalamic-pituitary-gonadal axis is active, and it is the main source of testosterone; therefore, regardless of the failure of the first-line hormone therapy, using LHRH is still crucial for effective treatment. The validity of this assumption has not been demonstrated in randomised studies. However, retrospective studies evaluating the effects of continued hormone therapy in patients with hormone-refractory prostate cancer demonstrate longer overall survival in patients using LHRH analogues, regardless of resistance to hormones [9, 10]. Moreover, there are no clinical studies on the use of new medications without concurrent castration therapy with LHRH analogues. Therefore, the continuation of castration therapy is a standard treatment in mCRPC. The present consensus on effective hormonal treatment assumes obtaining blood testosterone concentration of less than 50 ng/ml. However, clinical study results confirming the influence of this factor on disease progression gave rise to a discussion on the optimal cut-off value for testosterone. The present blood testosterone concentration of less than 50 ng/ml is being questioned as too high, and a lower cut-off point of 20 ng/ml has been suggested. A retrospective analysis evaluating the effectiveness of the LHRH analogue triptorelin, administered to patients with mCRPC every 3 months, has demonstrated that this form of treatment enables a lower testosterone castration level (< 20 ng/ml) to be achieved in 95% of patients after 6 months of therapy [11]. Another study, conducted by Perachino et al., assessed the effect of testosterone concentration on cancer-specific survival (CCS) in patients with mCRPC. The study involved 129 patients who had no history of previous hormone therapy [12]. The median baseline testosterone was 410 ng/dl at the beginning of the study. The patients then underwent hormone therapy (LHRH analogue). The median testosterone nadir during the treatment was 21 ng/dl, and after 6 months the median testosterone was 40 ng/dl. The study demonstrated that higher testosterone concentration correlated with a higher risk of death due to prostate cancer: HR 1.333 (95% CI: 1.053–1.687) p < 0.050. Based on these data, it was concluded that the aim of hormone therapy in patients with metastatic prostate cancer should be a maximum reduction of the testosterone level. As previously mentioned, the continuation of hormonal therapy with an LHRH analogue in patients with hormone-refractory prostate cancer is supported by phase III studies, involving both new generation chemotherapeutic medications used after an unsuccessful first-line therapy, and the newest hormonal medications. All clinical trials evaluating new therapies still followed the principle of obtaining castration testosterone levels as a result of using LHRH analogues, simultaneously with the new medications.
One of the first medications used in cases of progression of the prostate cancer to the metastatic castrate-resistant stage is docetaxel. Effectiveness of this chemotherapeutic has been demonstrated in two phase III clinical trials – TAX 327 and SWOG 9916 [13, 14]. It is worth emphasising that participation in these studies was conditional upon continuation of the hormone treatment, whose aim was to achieve a testosterone concentration of less than 50 ng/ml. The first of the studies compared the effectiveness of docetaxel with mitoxantrone. It was a three-arm study – docetaxel therapy was applied in two arms: 75 mg/m2 every 3 weeks or 30 mg/m2 once a week, and the control arm involved treatment with mitoxantrone 12 mg/m2. The study demonstrated that median survival in patients treated with docetaxel at 75 mg/m2 every 3 weeks was 19.2 months, and with mitoxantrone 16.3 months, whereas the therapy with docetaxel at 30 mg/m2 did not significantly affect the length of survival. The SWOG 9916 study also confirmed the effectiveness of docetaxel therapy in a slightly different configuration.
Cabazitaxel is another new generation chemotherapeutic agent, whose cytostatic effect consists in the inhibition of cell division by blocking the microtubules of the karyokinetic spindle. The TROPIC trial, assessing the effectiveness of the medication, involved patients after the first-line hormone therapy who experienced prostate cancer progression in the course of the docetaxel treatment [15]. The patients were randomised to two groups: one treated with cabazitaxel and prednisone, and the other treated with mitoxantrone and prednisone. The median overall survival for patients treated with cabazitaxel was 15.1 months vs. 12.7 months for patients receiving mitoxantrone (HR 0.70; p < 0.0001). Also in this case, all the patients were hormonally treated in order to achieve castration testosterone levels.
The ability to effectively block enzymes crucial for androgen synthesis has created new possibilities regarding hormone therapy. In a phase III randomised trial conducted in 2011, de Bono et al. compared the effectiveness of abiraterone combined with prednisone vs. placebo + prednisone in a second-line therapy, after unsuccessful chemotherapy with docetaxel in patients with castrate-resistant prostate cancer [16]. To achieve the lowest possible androgen concentration, the study involved patients who continued castration therapy with LHRH analogues, which was qualified as a combined therapy. The overall survival in the abiraterone group was 4 months longer than in the group without this therapy (14.8 months vs. 10.9 months).
In 2013, the results of another study with the use of abiraterone were published. The study involved over 1000 patients with castrate-resistant prostate cancer, who had no history of previous docetaxel therapy [17]. Also in this study, the therapy with LHRH analogue was continued concurrently with the new medication (in the absence of surgical castration). The trial demonstrated that using abiraterone significantly prolonged the radiological progression-free survival compared to the placebo group (16.5 vs. 8.3 months), and considerably extended the prostate-specific antigen (PSA) progression-free survival. Median overall survival was not achieved for the abiraterone group; however, a 25% reduction in the risk of death was demonstrated compared to the placebo group, which clearly indicates that using abiraterone prolongs the overall survival.
As abiraterone inhibits the conversion of androgens from all three sources, i.e. testicles, adrenal glands and de novo in the neoplastic cells, the question arises whether the concurrent use of an LHRH analogue (which inhibits testosterone synthesis only in the testicles) is necessary. Presently, there are no clinical studies assessing the effectiveness of abiraterone in monotherapy if the testosterone concentration is higher than 50 ng/ml, and therefore, the combined treatment with abiraterone + surgical/pharmacological castration is the most effective form of androgen suppression. Another argument supporting the necessity of LH suppression is the presence of LH receptors in prostatic neoplastic cells. Pinski et al. demonstrated that stimulation of these receptors leads to increased activity of the steroidogenesis pathways enzymes, which results in an increased intracellular androgen concentration [18]. Referring to two other phase III randomised trials, it has been proven that adding androgen synthesis inhibitors to a standard LHRH analogue based hormone therapy enables a more effective reduction of androgen concentration. The combination of dutasteride and ketoconazole with total androgen blockade (TAB) in neoadjuvant therapy, 3 months prior to a radical prostatectomy in patients with locally advanced cancer, enabled the blood testosterone concentration to be reduced to 0.03 ng/ml compared with the control group (0.92 ng/ml), where the neoadjuvant therapy was limited exclusively to TAB [19]. An analogous study assessed the effect of combining abiraterone with LHRH agonists in 3 to 6 months of neoadjuvant therapy preceding a surgical treatment, and a reduction in DHT (dihydrotestosterone) from 1.3 ng/ml to 0.18 ng/ml was also achieved, as well as a reduction in DEHA and DHT concentrations in the prostate gland [20].
Enzalutamide is another new generation medication used in the treatment of mCRPC after unsuccessful chemotherapy with docetaxel, and it was approved by the FDA in 2012. Enzalutamide blocks the intracellular androgen receptor signalling pathway in three ways: through an irreversible androgen receptor antagonism (five times stronger than the effect of bicalutamide), by inhibiting translocation of androgen receptor to the nucleus, and by preventing this receptor from binding with DNA and/or protein co-activators. In the published results of the AFFIRM trial, the effectiveness of enzalutamide at 160 mg/day was compared with placebo in patients after unsuccessful docetaxel treatment [21]. The study involved 1199 patients who continued hormone therapy with an LHRH analogue. The patients were randomised at a 2 : 1 ratio – enzalutamide (800 patients)/placebo (399 patients). The main endpoint of the study was overall survival. The trial demonstrated that enzalutamide therapy prolongs the patients’ overall survival (18.4 months vs. 13.6 months in the placebo group). Other endpoints were also assessed, which also confirmed the benefits of enzalutamide treatment. It was demonstrated that enzalutamide therapy is associated with a reduction in PSA concentration by ≥ 50% (54% vs. 2%; p < 0.001), soft tissue response (29% vs. 4%; p < 0.001), enhancement of the quality of life (43% vs. 18%; p < 0.001), PSA progression-free survival (8.3 vs. 3.0 months; HR 0.25; p < 0.001), radiographic progression-free survival (8.3 vs. 2.9 months; HR 0.40; p < 0.001), and bone-metastasis-free survival (16.7 vs. 13.3 months; HR 0.69; p < 0.001). Enzalutamide was also studied within a group of patients with no history of docetaxel treatment – during the phase III PREVAIL trial [22]. Initial results of this study indicate that enzalutamide improves the overall survival and reduces by 81% the risk of radiological events compared to the placebo.
A novel retrospective study of enzalutamide for the treatment of mCRPC patient who progressed after docetaxel and abiraterone therapy has been performed, enrolling a total of 61 patients [23]. Enzalutamide resulted in a PSA decline of more than 50% in 13 (21%) men, median progression-free survival was 12.0 weeks, the median time to PSA progression was 17.4 weeks and the median overall survival was 31.6 weeks. These data showed that some patients can still be sensitive to hormonal therapy and testosterone level even after docetaxel and abiraterone failed treatment, which is another argument why LHRH analogue therapy is still crucial for mCRPC patients.
Use of abiraterone is associated with the reduction of androgen concentrations. As a result, the neoplastic cells activate, using a feedback process, mechanisms increasing the number of androgenic receptors, thus compensating for androgenic deficiencies in the cancer cell environment, which leads to resistance. By analogy, also through a feedback mechanism, the neoplastic cells compensate the enzalutamide therapy by increasing the synthesis of androgens.
Most patients (90%) with mCRPC develop bone metastases in the natural course of the disease, which significantly affect the quality of life and doubtlessly increase the risk of death [23–25]. The symptoms and complications associated with bone metastases are referred to in the literature as skeletal-related events (SRE), and they include pathological fractures, spinal cord compression, bone pain and palliative radiotherapy of painful bone lesions. The medications recommended in patients with bone system metastases include denosumab, zoledronic acid and alpharadin 223. However, it should be emphasised that these medications are only complementary to the LHRH analogue therapy, and they cannot be used in monotherapy. Bisphosphonates were the first group of drugs used to prevent SRE. They reveal high affinity to calcium, and, absorbed by hydroxyapatite, they are built into the bone structure, thus inhibiting its resorption. The only bisphosphonate authorised by the FDA to be used in mCRPC is zoledronic acid. Denosumab is a human monoclonal antibody, which binds with the RANKL ligand, thus inhibiting maturation of osteoclasts, and contributing to reduction of bone resorption. In 2011, the results of a phase III randomised trial comparing denosumab with zoledronic acid were published [26]. The study provided evidence that denosumab prolongs the time before the first SRE to 20.7 months, compared to 17.1 months in the patients who received zoledronic acid (HR 0.82, 95% CI: 0.710.95; p = 0.008). It was also demonstrated that denosumab reduced the risk of another bone complication by 18%.
Alpharadin is a new generation drug approved by the FDA in 2013, and its mode of action consists in emitting short-range alpha radiation (ca. a range of 2–10 cells) within the areas of high growth in the bones surrounding the metastases. The condition for the participation in the trial was the confirmation of at least two metastatic sites in the bones. The study demonstrated an increase in the overall survival of the patients with mCRPC who received alpharadin therapy, in comparison to the placebo (14.9 months vs. 11.3 months) [27]. Moreover, the study revealed a significant reduction in bone complications and prolonged time to their occurrence (15.6 vs. 9.8 months). Alpharadin is the first medication from the group of radiation emitters to demonstrate a beneficial effect on overall survival, simultaneously causing fewer complications than the former generation drugs. The effectiveness of denosumab, zoledronic acid and alpharadin has been confirmed in clinical trials, and they are recommended as supportive treatment in targeted therapy of bone metastases in patients with mCRPC who continue hormone therapy.
Angiogenesis is known to play a crucial role in the progression of prostate cancer. VEGF is an important factor responsible for formation of new tumour vessels [28]. One method which can prevent neovascularization is inhibition of the VEGF signalling pathway. Two new agents – bevacizumab (a humanized monoclonal antibody which inhibits major isoforms of VEGF) and aflibercept (a VEGF fusion protein which inhibits the VEGF binding receptor) – were evaluated in the phase III randomised trials VENICE (aflibercept) and CALGB 90401 (bevacizumab) [29, 30]. The main aim of these studies was to show the prolongation of overall survival. In CALGB 90401 Kelly and colleagues compared docetaxel/prednisone and placebo with docetaxel/prednisone and bevacizumab in 1,050 men with mCRPC. The median overall survival was not prolonged significantly (22.6 months vs. 21.5 months; HR 0.91, p = 0.18). Also aflibercept in combination with docetaxel/prednisone given as first line chemotherapy for mCRPC did not lead to a statistically significant improvement in overall survival (22.1 months vs 21.2 months HR 0.94, p = 0.38). In both trials the eligibility criteria included concurrent castration therapy with LHRH analogues. These two studies further underline the importance of continuation of hormonal therapy for mCRPC patients.
Tasquinimod is a novel oral drug for mCRPC patients, which has both immunomodulatory and VEGF-independent antiangiogenic properties. In a double blinded, randomized phase II trial 201 patients were enrolled [31]. Tasquinimod therapy resulted in a prolonged overall survival of 33.4 months versus placebo 30.4 months (HR 0.87, p = 0.49). The best advantage was in a subgroup of 134 patients with bone metastases where patients treated with tasquinimod experienced 34.2 months overall survival compared to 27.1 months in placebo patients (HR 0.73, p = 0.19). Also in this trial, patients were hormonally treated in order to achieve castration testosterone levels (Table 1).
Recently, many new medications have become available which contribute to prolonged survival and enhanced quality of life in mCRPC. They have also changed the approach to the aetiopathogenesis of the disease in advanced stages, which has led to a change in the definition: from hormone-refractory cancer to castrate-resistant cancer – a stage of the disease whose development is still dependent on the presence of androgens. It should also be noted that despite the authorisation of the new medications by the FDA, mCRPC therapy is still combined with LHRH analogues. The basic argument supporting their use is a lack of studies which could confirm the effectiveness of the newest medications in monotherapy. It may be assumed that the recent drugs are not yet sufficiently effective to independently slow down the course of a metastatic disease, yet they present significant added value to LHRH analogue therapy. Important aspects which require further confirmation in clinical studies should also include the order of the mentioned therapies (sequential vs. simultaneous “cocktail”), and the possibilities of combining new medications.

The authors declare no conflict of interest. This article was supported by IPSEN (Warsaw, Poland).

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Address for correspondence
Tomasz Milecki

Department and Clinic of Urology and Urologic Oncology
Poznan University of Medical Sciences
Szwajcarska 3
61-285 Poznan, Poland
e-mail: tmilecki@wp.pl

Submitted: 3.01.2014
Accepted: 26.03.2014
Copyright: © 2014 Termedia Sp. z o. o. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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