Prostate cancer (PC) is the most common cancer and the third most common cause of cancer-related deaths in men in developed countries (1). In general, PC starts out as an androgen-dependent tumor. Thus, androgen-deprivation therapy represents the backbone of treatment for metastatic PC (2). However, disease progression usually occurs within a few years despite castrate levels of serum testosterone, defining a state called castration-resistant PC (CRPC). Most of these patients develop resistance to castration due to a reactivation of the androgen receptor signaling axis. In the last decade, several drugs have been shown to provide a survival benefit for men with metastatic CRPC. However, prediction of response is challenging and the optimal choice of several treatment options has to be made on an individual basis. Currently, the most frequently used first-line treatments for asymptomatic or minimally symptomatic metastatic CRPC are abiraterone acetate (AA) plus prednisone, enzalutamide, or sipuleucel-T (in North America). AA is an inhibitor of CYP17, which is a key enzyme required in testosterone synthesis. Enzalutamide is a second-generation antiandrogen that inhibits androgen binding to androgen receptors, inhibits androgen receptors from entering the cell nucleus, and inhibits androgen receptors from binding to DNA and from serving as a transcription factor. Sipuleucel-T is a personalized, autologous, cellular vaccine against prostatic acid phosphatase combined with granulocyte–macrophage colony-stimulating factor. Second-line therapy and therapy for symptomatic CRPC consist of taxane chemotherapy (docetaxel or cabazitaxel), 223Ra, or AA/enzalutamide (whichever has not been used as the first-line therapy). Taxanes disrupt the orderly microtubule function, whereas 223Ra is a calcimimetic that decays while emitting α-radiation and internally irradiates bone metastases. In contrast to androgen receptor–targeting strategies, “unspecific” cytostatic chemotherapies can be effective in metastatic CRPC, even when first- and second-line hormonal therapies fail. However, these are associated with considerably more side effects. In patients not willing to be treated with chemotherapy or not eligible for chemotherapy because of the respective toxicity profile, AA or enzalutamide is often used as the second-line therapy of choice. However, the second-line treatment success of AA or enzalutamide is often limited and short-lived because of cross resistance caused by, for example, alternative splicing of the androgen receptor (3,4). Novel targeted therapies with favorable toxicity profiles are therefore needed to broaden the therapeutic armamentarium.
Among others, the prostate-specific membrane antigen (PSMA), a transmembrane protein that is physiologically expressed in prostate cell membranes but highly overexpressed in primary PC and increasingly more in CRPC metastases, seems to be a promising molecular target both for imaging of tumor spread and for radioligand therapy (5,6). Over the past few years, PSMA-targeting PET tracers such as 68Ga-PSMA-11 have significantly improved diagnostic pathways in PC (7). PSMA PET/CT or PET/MRI should be considered the new gold standard for imaging of men with biochemical recurrence. A general challenge for PSMA imaging is the presence of few tumors without PSMA expression. Ligand-specific challenges for 68Ga-PSMA-11 PET/CT are evaluation of bladder infiltration (because of the excretion of PSMA-11 via the urinary tract), the limited availability of the radionuclide (because of generator capacity), and the short half-life of 68Ga (68 min), which prohibits delivery to distant PET centers. Therefore, investigations are under way of 18F-labeled PSMA tracers that can be produced in large amounts in a cyclotron and whose longer half-life (110 min) would enable transfer to satellite institutions (8,9).
Besides imaging, PSMA-targeted endoradiotherapy of metastatic CRPC is emerging. Several recent retrospective studies have shown a high potential for the PSMA-targeted radioligand 177Lu-PSMA-617 applied under a compassionate-use provision in end-stage metastatic CRPC patients (10–16). On ligand binding, PSMA and its bound molecule are internalized via clathrin-coated pits and subsequent endocytosis. Because internalization enhances uptake of activity and retention, targeting of PSMA results in a high local intracellular deposit for therapeutic applications. While the β-ray–emitting component of 177Lu-PSMA-617 efficiently irradiates these cells, the γ-component can be used for imaging. As demonstrated by promising PSA declines, this innovative therapy is effective and exhibits a favorable toxicity profile in patients with end-stage metastasized PC (10–16). A recent study on 177Lu-PSMA-617 radioligand therapy in the largest cohort of patients so far (248 therapy cycles in 145 men) has shown a considerable response rate, with a PSA decline of 50% or more in 45% of patients (12). An alkaline phosphatase level of less than 220 U/L, the absence of visceral metastases, and the number of therapy cycles were relevant independent predictors of biochemical response. Interestingly, prior chemotherapy did not significantly influence response rates.
Currently, radioligand therapy using PSMA ligands is limited to the treatment of metastatic CRPC patients with progressive disease despite prior treatment with at least 2 lines of approved and endorsed strategies, according to multidisciplinary guidelines and/or objective exclusion criteria against the use of (as of yet not given) remaining options. However, because of the excellent toxicity profile of this new and promising therapeutic option, it is the clear desire of PC patients and patient organizations that it be made available now to patients with earlier stages of the disease; in these stages, patients might receive a superior benefit, a longer progression-free survival, and an improved quality of life, as they exhibit a better performance status and lower tumor burden. On the basis of existing observations and experiences, prospective multicenter studies with more homogeneous groups of metastatic CRPC patients are currently being planned in Germany.
From the urologist’s point of view, these future studies must not focus on PSA declines alone but on radiographic progression-free survival as the intermediate primary endpoint. Since the introduction of PSA in the context of screening, PC diagnosis and management have been guided by this easily measurable serum biomarker. PSA levels have been shown to be associated with disease burden and are included in many prognostic tools for survival. However, in some patients the PSA test may identify and overtreat clinically insignificant cancers that would not have become evident in a man’s lifetime. Therefore, the role of PSA as a screening test is a controversial topic (17).
In patients with metastatic disease, assessment of PSA levels over time is routinely used to evaluate treatment response. Although PSA is helpful in men with castration-sensitive disease, the correlation between PSA levels and survival becomes more complex in advanced disease characterized by increasing heterogeneity, because of the complex mechanisms surrounding development of castration resistance (18,19). Assessment of therapy response by PSA alone can be impaired by flare phenomena (20) and by the presence of visceral metastases not producing PSA (21). Consequently, the Prostate Cancer Clinical Trials Working Group 3 has proposed the use of conventional imaging methods, including CT, MRI, and bone scintigraphy, as tools to evaluate the response to therapy (22). The association between radiographic progression-free survival and overall survival is still being investigated but has recently been shown to be consistent and high (23). Standardized imaging is key for patient management, biomarker development, and therapeutic clinical trials.
Approximately one third of patients treated in experienced 177Lu-PSMA-617 centers did not respond despite PSMA overexpression in prior PET scans. To break this primary radioresistance to the β-emitter lutetium and to further reduce hematologic toxicity, targeted α-radiation might be a possible solution. Consequently, the first-in-human results for 225Ac-PSMA-617, presented by Kratochwil et al. from Heidelberg, are an important step forward (24). The two patients presented were heavily pretreated men with end-stage metastatic CRPC. Strikingly, both subjects achieved a complete response on PSMA PET imaging and PSA declines to below measurable levels. As expected from a cell-specific radiotherapy with a short range, hematologic toxicity was low, but both men subsequently experienced enduring xerostomia. More recently, 14 patients were reported to demonstrate an impressive antitumor activity by means of objective radiologic response or tumor marker decline in 9 of 11 evaluable patients (25). A 100 kBq/kg treatment activity of 225Ac-PSMA-617 per cycle repeated every 8 wk was suggested as a reasonable trade-off between toxicity and antitumor activity. Certainly, these excellent results will have to be validated in larger cohorts and at different centers.
In conclusion, PSMA-targeted radioligand therapy is a promising and exciting addition to the therapeutic spectrum in men with metastatic CRPC. However, prospective clinical trials with appropriate clinically relevant endpoints are not available yet. Moreover, the optimal timing of their use, predictive and prognostic biomarkers, their possible combination with other systemic drugs, and the best treatment sequences are yet unknown. These challenges will best be met using a multidisciplinary approach and treatment in the context of clinical trials.
DISCLOSURE
No potential conflict of interest relevant to this article was reported.
Footnotes
Published online May 18, 2017.
- © 2017 by the Society of Nuclear Medicine and Molecular Imaging.
REFERENCES
- Received for publication May 10, 2017.
- Accepted for publication May 11, 2017.