Prostatic Acid Phosphatase Is a Progenitor Cell Marker That Persists After Androgen Ablation

Introduction: Prostatic Acid Phosphatase (PAP), a protein phosphatase and 5’ecto-nucleotidase, is expressed in prostate cancer (PCa) bone metastases and correlates with poor survival. Growing evidence suggests that PAP is not regulated by androgens, but rather by factors in the tumor microenvironment. Hypothesis: We hypothesized that PAP is a marker for a more progenitor type PCa cell and its expression is androgen-independent, persisting in castration-resistant disease. Methods: Protein expression of PAP and three androgen-regulated proteins, the Androgen Receptor (AR), Prostate-Specific Antigen (PSA), and ETS-related gene (ERG) protein, was assessed with immunohistochemistry in human fetal prostate (9.5 - 20 weeks of gestational age), archival human PCa bone metastases, and human PCa cell lines. VCaP cells were treated in vitro with dihydrotestosterone (DHT) and the effects on AR and PAP protein expression determined with Western Blotting. PAP-expressing PCa cell lines (LNCaP, C42B, and VCaP) were inoculated subcutaneously (s.c.) into SCID mice. To model tumor-bone interaction, LNCaP and MC3T3 osteoblast cells were co-inoculated s.c. into SCID mice. A VCaP castration study with surgical or sham castration was performed after tumors were palpable and effects of castration on tumor growth and protein expression determined. Results: PAP expression was observed in the fetal prostate as early as 11.5 weeks of gestational age prior to PSA and AR expression. Strong PAP expression was noted in all human PCa bone metastases examined, both treatment-naive and castrate-resistant (n=10). In vitro, VCaP cells expressed high levels of AR and PAP protein and DHT treatment increased AR and decreased PAP protein expression. In vivo, PAP expression was observed in all tumor models; LNCaP (low PAP expression), C42B (moderate PAP expression) and VCaP (high PAP expression). Castrated VCaP tumors underwent tumor stasis, were significantly smaller compared to intact mice, had decreased AR, PSA and ERG expression but persistent expression of PAP. Double staining of tumors for PAP and AR demonstrated a population of cells that were positive for PAP but negative for AR expression in hypoxic areas near necrosis. Inoculation of LNCaP cells with MC3T3 osteoblastic cells increased PAP expression in vivo. Conclusions: PAP is expressed early in human fetal prostate development prior to the secretion of significant androgens or expression of AR. In mouse xenograft tumors and human PCa bone metastases, androgens did not significantly regulate PAP expression. Both hypoxia and stroma increased PAP expression. These data demonstrate that PAP is a marker of early progenitor cells, is persistently expressed after castration and is upregulated by tumor microenvironmental factors. PAP may be a suitable target for the treatment of castration-resistant metastatic disease.