Regulation of Prostaglandin Metabolism by Calcitriol Attenuates Growth Stimulation in Prostate Cancer Cells

Introduction

In the United States, prostate cancer remains the most common solid tumor malignancy in men, causing ∼30,000 deaths in 2005 ( 1). Effective treatment options include surgery and radiation therapy. The main treatment strategy for advanced prostate cancer involves androgen deprivation therapy to which patients initially respond very well. However, most patients eventually fail this therapy and frequently develop metastatic disease. Current research on prostate cancer aims to identify new agents that would prevent and/or inhibit its progression.

1,25-Dihydroxyvitamin D₃ (calcitriol), the active form of vitamin D, is the major regulator of calcium and phosphate homeostasis in bone, kidney, and intestine ( 2). However, calcitriol has also been shown to exhibit antiproliferative and prodifferentiation effects in many normal and malignant cells including prostate cancer cells ( 3– 10). There are multiple mechanisms underlying the antiproliferative effects of calcitriol, which vary between target cells ( 10). These include cell cycle arrest ( 9, 11) and the induction of apoptosis ( 12). Several genes that mediate these growth regulatory effects have been identified to be the molecular targets of calcitriol action, such as p21, p27, bcl-2, and insulin-like growth factor binding protein-3 (IGFBP-3; refs. 5– 14). We recently did cDNA microarray analyses to more fully characterize the spectrum of genes regulated by calcitriol in prostate cells ( 15, 16). Among the newly identified genes regulated by calcitriol, we found two genes which play a key role in prostaglandin (PG) metabolism: the prostaglandin endoperoxide synthase-2 or cyclooxygenase (COX)-2 and the NAD⁺-dependent 15-hydroxyprostaglandin dehydrogenase (15-PGDH). PGs are synthesized from free arachidonic acid ( 17) by COXs. There are two well-characterized COX isoforms: COX-1, a constitutive form of the enzyme, and COX-2, an inducible form of the enzyme. PGs are implicated in the initiation and progression of many malignancies including prostate cancer ( 18– 20). Tumor cells with elevated COX-2 levels are highly resistant to apoptosis, show increased angiogenic potential, and exert suppressive effects on host immunity ( 19, 20). Nonsteroidal anti-inflammatory drugs (NSAIDs), known inhibitors of both COX-1 and COX-2 enzymatic activity, are under intense investigation to prevent and/or treat malignancies ( 19, 21). 15-PGDH, which mediates the catalytic inactivation of PGs by converting them to the corresponding keto derivatives, has been found to be down-regulated in some cancers ( 22, 23) and has recently been regarded as a tumor suppressor gene ( 24).

In the current study, we investigated the regulation of COX-2 and 15-PGDH by calcitriol in the androgen-dependent LNCaP and androgen-independent PC-3 human prostate cancer cell lines as well as in primary prostatic epithelial cells derived from normal and cancerous human prostate tissue. Calcitriol reduced the expression of COX-2 and increased that of 15-PGDH. Calcitriol treatment of prostate cancer cells decreased the concentration of prostaglandin E₂ (PGE₂) secreted into the conditioned medium. In addition, calcitriol also decreased the expression of the mRNA of PG receptors EP2 and FP. Our data indicate that these mechanisms led to the attenuation of PG-mediated functional responses by calcitriol, including the suppression of PG stimulation of cell growth. Further, our study showed that the combination of calcitriol and NSAIDs exhibited synergistic growth inhibition, suggesting that the combination might be a useful therapeutic and/or chemopreventive strategy in prostate cancer.

Materials and Methods

Results

We previously showed by cDNA microarray analysis that calcitriol regulated the expression of two of the key genes involved in PG metabolism (i.e., COX-2 and 15-PGDH) in LNCaP human prostate cancer cells ( 15) and 15-PGDH in primary normal prostatic epithelial cells ( 16). In the present study, we extended these observations to include an evaluation of calcitriol effects on the expression of these two genes at both the mRNA and protein levels in LNCaP and PC-3 cells. In addition, we also examined the effects of calcitriol in primary prostatic epithelial cell strains derived from normal prostate as well as prostate adenocarcinoma specimens.

Down-regulation of cyclooxygenase-2 expression by calcitriol. Real-time reverse transcription-PCR (RT-PCR) analysis showed significant decreases in COX-2 mRNA levels in both androgen-dependent LNCaP (∼70% inhibition) and androgen-independent PC-3 cells (∼45% inhibition) due to calcitriol treatment ( Fig. 1A ). Although both LNCaP and PC-3 prostate cancer cells have been shown to express COX-2 protein ( 31), we found that PC-3 cells exhibited higher basal levels of COX-2 protein expression when compared with LNCaP cells (not shown). We therefore used PC-3 cells to assess the effect of calcitriol on COX-2 protein expression. Figure 1B shows that the addition of 10 nmol/L calcitriol to PC-3 cultures for 48 hours reduced COX-2 protein level to ∼60% of control, with 100 nmol/L calcitriol having no further effect.

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Figure 1.

Calcitriol regulates COX-2 and 15-PGDH expression in prostate cancer cell lines. A, calcitriol decreases COX-2 mRNA levels. Subconfluent cultures of LNCaP and PC-3 cells were treated with 0.1% ethanol (Con) or 10 nmol/L calcitriol (Cal) for 24 hours and total RNA was extracted. COX-2 mRNA levels were determined by real-time RT-PCR as described in Materials and Methods and were normalized to TBP mRNA levels in the same samples. COX-2/TBP ratio shown as a percent of control set at 100%; columns, mean from five experiments; bars, SE. B, calcitriol decreases COX-2 protein levels. Subconfluent cultures of PC-3 cells were treated with 0.1% ethanol (Con) or 10 or 100 nmol/L calcitriol (Cal) for 48 hours. Fifty micrograms of total protein were subjected to Western blot analysis as described in Materials and Methods. Representative Western blot. The densitometric units of COX-2 immunoreactive bands were normalized to the densitometric units of the corresponding β-actin bands. Results expressed as the ratio of the control set at 1. C, calcitriol increases 15-PGDH mRNA levels. Cells were treated and processed as described in A. 15-PGDH/TBP ratio in calcitriol-treated cells given as a percent of control set at 100%; columns, mean from five experiments; bars, SE. D, calcitriol increases 15-PGDH protein levels. LNCaP cells were treated as in B. The densitometric units of 15-PGDH immunoreactive bands were normalized to the densitometric units of the corresponding β-actin bands. Results expressed as the ratio of the control set at 1; columns, mean of three experiments; bars, SE. *, P < 0.05; **, P < 0.01, when compared with control.

Up-regulation of 15-hydroxyprostaglandin dehydrogenase expression by calcitriol. We examined the effect of calcitriol on 15-PGDH mRNA levels in LNCaP and PC-3 cells. Our data show that 10 nmol/L calcitriol increased 15-PGDH mRNA expression by ∼3.6-fold in LNCaP cells and by ∼3-fold in PC-3 cells ( Fig. 1C). We found that the basal protein expression of 15-PGDH varied between different cell lines with the LNCaP exhibiting appreciable levels of the 15-PGDH protein whereas barely detectable levels were seen in PC-3 cells. Therefore, we examined the effect of calcitriol on 15-PGDH protein expression in LNCaP cells and found a dose-dependent increase in 15-PGDH protein levels in response to calcitriol treatment ( Fig. 1D).

Calcitriol effects on cyclooxygenase-2 and 15-hydroxyprostaglandin dehydrogenase mRNA levels in primary prostatic epithelial cells. We extended our analysis to include calcitriol effects on primary cultures of prostatic epithelial cells derived from normal prostate as well as adenocarcinoma specimens removed at surgery. Real-time RT-PCR analysis showed considerable decreases (55-90%) in COX-2 mRNA levels in two of the three normal primary cell strains tested (E-PZ-1 and E-PZ-3) after 24 hours of calcitriol treatment ( Fig. 2A ). In all three cancer-derived primary cultures (E-CA-1 to -3) significant reductions (∼48-60%) in COX-2 mRNA levels were seen at an earlier time point, after 6 hours of calcitriol treatment, and the down-regulatory effect was lost by 24 hours except in the case of E-CA-2 ( Fig. 2B). Figure 2C and D shows the calcitriol-induced changes in 15-PGDH mRNA in primary prostatic cells. In the normal primary cells, calcitriol treatment caused appreciable increases in 15-PGDH mRNA in two of the three strains tested. The time course of this effect showed minor differences. In E-PZ-1 and E-PZ-2 cells significant increases (∼2- to 18-fold) were achieved at the end of 6 and 24 hours, respectively ( Fig. 2C). In two of three of the cancer-derived primary cultures (E-CA-2 and -3), significant increases (∼2- to 5-fold) were seen at the end of 24 hours ( Fig. 2D). In general, the magnitude of COX-2 mRNA down-regulation as well as 15-PGDH mRNA increase was more pronounced in the primary cells derived from normal prostatic tissue when compared with both the cancer-derived primary cells and the established prostate cancer cell lines.

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Figure 2.

Calcitriol regulates the expression of COX-2 and 15-PGDH mRNA in primary prostatic epithelial cells. Primary cultures of prostatic epithelial cells derived from the peripheral zone of normal prostate tissue (E-PZ-1 to -3) or adenocarcinoma (E-CA-1 to -3) were treated with 0.1% ethanol (Con) or with 10 nmol/L calcitriol (Cal) for 6 or 24 hours. Total RNA was extracted and COX-2 and 15-PGDH mRNA levels were quantitated by real-time RT-PCR using gene-specific primers as described in Materials and Methods. COX-2 and 15-PGDH mRNA levels were normalized to GAPDH mRNA levels and are given as a percent of control set at 100%. Columns, mean from three experiments; bars, SE. Effect of calcitriol on COX-2 mRNA in three different normal primary epithelial cell strains (A) and in cancer-derived cell strains (B). Changes in 15-PGDH mRNA in normal cell strains (C) and in cancer-derived cell strains (D). *, P < 0.05; **, P < 0.01; ***, P < 0.001, when compared with control.

Effect of calcitriol on prostaglandin levels. As a result of the dual action of calcitriol to down-regulate the expression of PG synthesizing COX-2 and increase the PG catabolizing 15-PGDH, we expected a reduction in PG production and secretion in prostate cancer cells treated with calcitriol. We measured the levels of PGE₂ in the conditioned media from LNCaP cells treated with various concentrations of calcitriol for 48 hours. Figure 3A shows that the addition of calcitriol caused a significant reduction in PGE₂ secretion with the maximal decrease (∼34%) seen with 100 nmol/L calcitriol.

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Figure 3.

A, calcitriol decreases PGE₂ levels. Subconfluent cultures of LNCaP cells were treated with 0.1% ethanol (Con) or with the indicated concentrations of calcitriol (Cal) for 48 hours. Conditioned media from control and calcitriol-treated cultures were collected and PGE₂ levels were determined using an enzyme immunoassay kit (Materials and Methods). Columns, mean from three experiments; bars, SE. *, P < 0.05. B, changes due to calcitriol treatment in EP2 mRNA. LNCaP cells were grown to subconfluence and treated with vehicle (0.1% ethanol; Con) or 10 nmol/L calcitriol (Cal) for 24 hours. Total RNA was extracted and analyzed for the mRNA expression of EP2 by real-time RT-PCR using gene-specific primers as described in Materials and Methods. EP2 mRNA levels were normalized to the TBP mRNA levels. Values given as a percent of control set at 100%; columns, mean from three experiments; bars, SE. *, P < 0.05, when compared with control. C, changes due to calcitriol treatment in FP mRNA. LNCaP cells were treated and processed as in B for the mRNA expression of FP by real-time RT-PCR. FP mRNA levels were normalized to the TBP mRNA levels. Values are given as a percent of control set at 100%; columns, mean from three experiments; bars, SE. *, P < 0.05, when compared with control. D, calcitriol inhibits PG-mediated induction of c-fos mRNA. Subconfluent cultures of PC-3 cells were transferred to serum-free RPMI 1640 containing 0.1% ethanol vehicle or 10 nmol/L calcitriol during 48 hours (pretreatment). Following the pretreatment, the cultures were exposed for 30 minutes to arachidonic acid (AA; 3 μmol/L) added to the culture medium. The cell cultures were then scraped, RNA was isolated, and c-fos mRNA levels were determined by real-time RT-PCR as described in Materials and Methods. c-fos mRNA levels were normalized to TBP mRNA levels and are given as a percent of control set at 100%. Columns, mean from three experiments; bars, SE. *, P < 0.05, when compared with control; +, P < 0.05, when compared with arachidonic acid.

Effects of calcitriol on prostaglandin receptor expression. Prostate cancer cells have been shown to express the PGE receptor subtypes EP2 and EP4 ( 29). We examined the effects of calcitriol on the expression of the PGE₂ receptor isoforms EP1, EP2, EP3, and EP4, and the PGF_2α receptor FP. LNCaP cells treated with 10 nmol/L calcitriol for 24 hours showed a significant (∼45%) down-regulation of EP2 mRNA ( Fig. 3B). We did not detect any changes in the levels of EP1, EP3, or EP4 mRNA following calcitriol treatment (not shown). FP mRNA levels were also down-regulated (∼33% decrease) by calcitriol ( Fig. 3C).

Inhibition of prostaglandin-mediated induction of c-fos mRNA by calcitriol. Because calcitriol modulated the levels of biologically active PGs as well as PG receptor expression, we examined its effect on a PG-mediated functional response, (i.e., the induction of the immediate-early gene c-fos; ref. 29). As serum is a potent inducer of c-fos expression ( 32), we conducted the experiment under serum-free conditions using PC-3 cells. Unlike LNCaP, PC-3 cells could be briefly maintained in serum-free media for calcitriol pretreatment and subsequent treatment with the PG precursor arachidonic acid. PC-3 cells were pretreated with vehicle or 10 nmol/L calcitriol for 48 hours followed by a brief (30 minutes) exposure to exogenous arachidonic acid (3 μmol/L) directly added to the culture medium. RNA was then isolated and the induction of c-fos mRNA was determined as an indicator of the biological activity of PGs endogenously synthesized from arachidonic acid. As shown in Fig. 3D, in vehicle pretreated cells arachidonic acid exposure resulted in a significant induction (∼2.5-fold) of c-fos mRNA levels after 30 minutes. Calcitriol pretreatment completely abrogated the induction of c-fos mRNA due to arachidonic acid addition. Calcitriol pretreatment by itself caused a minor increase in c-fos mRNA levels when compared with vehicle pretreated cells, which was not statistically significant.

Effects of calcitriol on prostaglandin-mediated growth stimulation. We examined the effect of calcitriol on the stimulation of prostate cancer cell growth by exogenous PG addition as well as by endogenous PGs derived from the substrate arachidonic acid added to the culture medium. We treated LNCaP and PC-3 cells with arachidonic acid (3 μmol/L), PGE₂, or PGF_2α (10 μmol/L each) in the absence or presence of 10 nmol/L calcitriol. Our results revealed a moderate but significant growth stimulation by arachidonic acid and exogenous PGs in both LNCaP ( Fig. 4A ) and PC-3 cells ( Fig. 4B). Calcitriol had a marked growth inhibitory action when given alone. In addition, calcitriol blocked the growth stimulation due to endogenous PGs derived from the added arachidonic acid as well as exogenous PG addition ( Fig. 4A and B).

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Figure 4.

Calcitriol abrogates the growth stimulatory effects of arachidonic acid (AA) and exogenous PGs. LNCaP (A) and PC-3 (B) were treated with arachidonic acid (3 μmol/L), PGE₂ (10 μmol/L), or PGF_2α (10 μmol/L) individually or in combination with 10 nmol/L calcitriol (Cal) for 6 days. Cell growth was determined by measurement of DNA content as described in Materials and Methods. DNA contents are given as percentage of control value set at 100%, which was equivalent to 12.3 ± 1.2 μg/well for LNCaP cells and 19.3 ± 1.7 μg/well for PC-3 cells. Columns, mean from six experiments; bars, SE. *, P < 0.05, when compared with control; ++, P < 0.01, when compared with arachidonic acid, PGE₂, or PGF_2α alone.

Synergistic inhibition of prostate cancer cell growth by calcitriol and nonsteroidal anti-inflammatory drugs. We next examined the combined effect of calcitriol and NSAIDs, which are potent inhibitors of COX enzyme activity. We tested a number of both COX-2–selective and nonselective NSAIDs including NS-398, SC-58125, flufenamic acid, sulindac sulfide, indomethacin, naproxen, and ibuprofen. Figure 5A to D illustrates the effect on prostate cancer cell growth of calcitriol alone or in combination with the NSAIDs that exhibited the best growth inhibitory effect when used at a reduced dose. We show the effects of calcitriol alone and in combination with the COX-2–selective NSAIDs SC-58125 on the growth of LNCaP cells ( Fig. 5A) and NS-398 on the growth of PC-3 cells ( Fig. 5B). In LNCaP cells, calcitriol by itself had a modest effect (∼20%) at 1 nmol/L but caused significant growth inhibition (∼40%) at 10 nmol/L ( Fig. 5A). The addition of the COX-2–specific inhibitor SC-58125 by itself had a modest effect on cell growth (∼20% inhibition), which was not statistically significant, at the concentration tested (5 μmol/L). The combination of 1 nmol/L calcitriol with SC-58125, however, had a more pronounced inhibitory effect (∼73% growth inhibition with the combination versus ∼20% inhibition with the individual agents), indicating a synergistic interaction between these two drugs to inhibit cell growth. SC-58125 also enhanced the growth inhibition seen with the higher concentration of calcitriol (∼80% inhibition with the combination versus ∼40% inhibition with 10 nmol/L calcitriol alone). Similar synergistic growth inhibitory effects were evident in PC-3 cells treated with a combination of calcitriol and the COX-2–selective inhibitor NS-398 ( Fig. 5B). NS-398, when used alone at 7.5 μmol/L, did not affect the growth of PC-3 cells. However, it enhanced the growth inhibition seen with both 1 and 10 nmol/L calcitriol (∼60% inhibition with the combination versus ∼20% inhibition with 1 nmol/L calcitriol alone, and ∼75% inhibition with the combination versus ∼40% inhibition with 10 nmol/L calcitriol alone).

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Figure 5.

Synergistic inhibition of prostate cancer cell growth by calcitriol and NSAIDs. LNCaP or PC-3 cells were treated with 0.1% ethanol vehicle (Con) or 10 nmol/L calcitriol (Cal) in the presence and absence of the indicated NSAID. Cell growth was determined by measuring the DNA content as indicated in Materials and Methods. DNA contents are given as percentage of control value set at 100%. A, LNCaP cells treated with a combination of calcitriol (Cal) and COX-2–specific NSAID SC-58125 (5 μmol/L). 100% DNA content = 10.15 ± 1.22 μg/well. B, PC-3 treated with calcitriol (Cal) in the presence and absence of the COX-2–selective NSAID NS-398 (7.5 μmol/L). 100% DNA content = 17.42 ± 1.93 μg/well. C, LNCaP cells treated with calcitriol (Cal) in the presence and absence of the nonselective NSAID naproxen (Nap; 200 μmol/L). 100% DNA content = 9.22 ± 0.5 μg/well. D, PC-3 cells treated with calcitriol (Cal) in the presence and absence of the nonselective NSAID ibuprofen (Ibu; 150 μmol/L). 100% DNA content = 21.7 ± 0.9 μg/well. Columns, mean from six experiments; bars, SE. *, P < 0.05; **, P < 0.01, when compared with control. ++, P < 0.01, when compared with 1 or 10 nmol/L Cal alone.

The growth inhibitory effect of calcitriol was similarly enhanced when combined with nonselective NSAIDs that inhibit the enzymatic activity of both COX-1 and COX-2. The nonselective NSAID naproxen at 200 μmol/L did not inhibit the growth of LNCaP cells ( Fig. 5C). However, it enhanced the growth inhibition seen with 1 and 10 nmol/L calcitriol (∼65% inhibition with the combination versus ∼48% inhibition with 10 nmol/L calcitriol alone). Similarly, in PC-3 cells ( Fig. 5D), the nonselective NSAID ibuprofen at 150 μmol/L enhanced the growth inhibitory effect of calcitriol (∼74% inhibition with the combination versus ∼40% inhibition with 10 nmol/L calcitriol alone) whereas it did not affect cell growth when used alone at this concentration.

Based on extensive dose-response analysis (not shown), we calculated the interaction index (γ) using an isobolar method ( 33) for each drug combination. This analysis indicated a synergistic (superadditive) effect. The data suggested that ∼2 to 10 times lower concentration of each drug is needed when used in combination to achieve the same degree of growth inhibition as achieved by the individual drugs.

Discussion

Calcitriol acts by multiple pathways to inhibit the proliferation of prostate cancer cells ( 5– 14). Our study shows that the regulation of PG metabolism is a novel and additional pathway by which calcitriol may exert its antiproliferative actions in prostate cancer cells. We have shown that calcitriol regulates biologically active PG levels and PG actions by three mechanisms: (a) the suppression of COX-2 expression, (b) the up-regulation of 15-PGDH expression, and (c) the reduction of EP2 and FP PG receptor mRNA expression. We propose that these three effects act together to effectively inhibit the stimulation of prostate cancer cell proliferation by endogenously derived PGs as well as PGs added exogenously. Because PGs have been shown to promote prostate cell growth, inhibit apoptosis, and stimulate prostate cancer progression ( 18– 20), we postulate that these effects of calcitriol to reduce PG actions significantly contribute to the anticancer effects of the hormone in prostate cancer.

The transformation of arachidonic acid into PGs and thromboxanes in mammalian cells is catalyzed by the enzyme COX, which has two well-characterized isoforms. COX-1 is constitutively expressed and is involved in housekeeping functions ( 17, 34). COX-2 is an immediate-early gene that is induced by a variety of growth promoting stimuli such as serum and growth factors, tumor promoters, cytokines, and proinflammatory agents ( 17, 34), and is regarded as an oncogene ( 24). COX-2 is overexpressed in various cancers including some, but not all, prostate cancers ( 18, 21). Inhibitors of COX-2 activity have been shown to suppress prostate cancer cell growth both in vivo and in vitro ( 31, 35, 36). Our results show the significant repression of COX-2 mRNA expression by calcitriol in prostate cancer cell lines as well as in primary prostatic epithelial cells and also a reduction in COX-2 protein levels in prostate cancer cell lines, suggesting that COX-2 is a calcitriol target gene.

PGE₂ and PGF_2α are rapidly catabolized in vivo into their biologically inactive 13,14-dihydro-15-keto metabolites by a two-step process carried out sequentially. The first step is initiated by the reversible oxidation of their 15(S)-hydroxyl group by the enzyme 15-PGDH ( 37). 15-PGDH is widely expressed in many mammalian tissues ( 38) and has been shown to be modulated by several hormones and factors ( 37– 39), indicating the potential importance of the regulation of this enzyme. In LNCaP cells, 15-PGDH expression is up-regulated by androgens, interleukin-6, and the cyclic AMP inducer forskolin in a protein kinase A–dependent manner ( 40, 41). We now show that calcitriol is an important regulator of 15-PGDH expression in prostate cancer cells. The partial repression of COX-2 mRNA expression and the increase in 15-PGDH mRNA expression are also seen in primary prostatic epithelial cells derived from normal prostate, suggesting that these calcitriol effects are not restricted to malignant prostate cells. 15-PGDH expression has been shown to be decreased in many cancers ( 22, 23, 42). Calcitriol has also been shown to increase the expression of 15-PGDH in neonatal monocytes ( 43), where it exhibits prodifferentiation effects. 15-PGDH, which physiologically antagonizes COX-2, has recently been described as a putative oncogene antagonist that functions as a tumor suppressor in colon cancer by Yan et al. ( 24) who found that 15-PGDH was universally expressed in normal colon specimens but was routinely absent or severely reduced in cancer specimens. More importantly, stable transfection of a 15-PGDH expression vector into cancer cells greatly reduced the ability of the cells to form tumors and/or slowed tumor growth in nude mice. The authors concluded that 15-PGDH suppressed the effects of the oncogene COX-2 and exhibited an additional effect to inhibit angiogenesis in vivo ( 24). Our present study shows calcitriol-mediated suppression of the oncogene COX-2 and an increase in the expression of the putative tumor suppressor 15-PGDH in prostate cells, suggesting that calcitriol may play an important role in the chemoprevention of prostate cancer.

As a result of its dual action to modulate COX-2 and 15-PGDH expression, we expected calcitriol to reduce the levels of PGs in prostate cancer cells. This indeed was the case as shown by the decrease in PGE₂ levels in the conditioned media from LNCaP cells following calcitriol treatment. Calcitriol regulation of PGE₂ synthesis and secretion has been also reported in growth plate chondrocytes ( 44), in monocytes ( 43, 45), and in interleukin-1β–stimulated rheumatoid synovial fibroblasts ( 46). The effects of calcitriol on PG synthesis and signaling in these target cells seem to be related to the rapid nongenomic actions of calcitriol ( 47).

PGs exert their myriad effects through G-protein coupled membrane receptors which activate different signal transduction pathways ( 48). Prostate cancer cells have been shown to express the PGE receptor subtypes EP2 and EP4 ( 29). Interestingly, our study shows that calcitriol decreases the mRNA expression of the PGE₂ and PGF_2α receptor subtypes EP2 and FP, providing yet another mechanism for the suppression of the biological activity of PGs by calcitriol. In a recent study examining the changes in gene expression profile in the kidney of vitamin D receptor (VDR) knockout mice, Li et al. ( 49) report increases in the expression of EP3 and FP genes in VDR^−/− kidneys, suggesting that calcitriol may also regulate the expression of PG receptors in kidney. Our study indicates that calcitriol not only decreases the concentration of PGs but may also inhibit the biological activity of these reduced PG levels by repressing of EP2 and FP receptor mRNA expression in prostate cancer cells.

Chen and Hughes-Fulford ( 29) have shown that arachidonic acid increases the expression of the immediate-early gene c-fos by undergoing a COX-2–mediated conversion to PGE₂, binding of PGE₂ to EP2/EP4 receptors, and subsequent activation of the protein kinase A pathway, which leads to the expression of growth-related genes. PGE₂ has also been to shown to up-regulate the gene expression of its own synthesizing enzyme COX-2 in prostate cancer cells, thereby completing a positive feedback loop ( 31, 50). We therefore examined the effect of calcitriol treatment on the induction of c-fos and cell growth by arachidonic acid in prostate cancer cells and found that calcitriol abolished c-fos induction and growth stimulation by arachidonic acid. Our interpretation of these observations is that they reflect both the effect of calcitriol to decrease endogenous synthesis of PGs due to COX-2 suppression and the ability of calcitriol to attenuate the biological activity of the PGs due to 15-PGDH up-regulation and EP and FP receptor down-regulation. The suppression by calcitriol of the growth stimulation by exogenous PG addition is probably due to its ability to enhance PG catabolism through the up-regulation of 15-PGDH expression as well as PG receptor down-regulation.

NSAIDs are known inhibitors of COX activity and have been shown to exhibit growth-suppressive effects in in vivo and in vitro models of prostate cancer ( 19, 35, 36, 50– 52). The growth inhibitory and proapoptotic actions of NSAIDs are due to their ability to inhibit cyclooxygenase activity to a large degree, although in recent years mechanisms independent of COX-2 inhibition are also believed to play a role ( 52). Our data show that the combination of calcitriol with COX-2–selective, as well as nonselective NSAIDs, acts synergistically to reduce the growth of prostate cancer cells. Our hypothesis is that the action of calcitriol at the genomic level to reduce COX-2 expression decreases the levels of COX-2 protein and allows the use of lower concentrations of NSAIDs to inhibit COX-2 enzyme activity, resulting in the enhanced growth inhibition seen with the combination. The potential use of NSAIDs as chemopreventive or therapeutic agents for a variety of malignancies, including prostate cancer, is being intensely investigated ( 20, 21, 51, 53). We propose that a combination of calcitriol and NSAID might be a useful therapeutic strategy in prostate cancer. The clinical use of NSAIDs has recently become controversial because of the cardiovascular complications associated with the use of high doses of COX-2–selective NSAIDs for prolonged periods of time ( 54, 55). In comparison with the COX-2–selective inhibitors, the use of a nonselective NSAID such as naproxen has been shown to be associated with decreased cardiovascular adverse effects ( 56). As shown by our study, an enhancement of growth inhibition is seen when calcitriol is combined with nonselective NSAIDs such as naproxen and ibuprofen. The clinical utility of the calcitriol combination with a nonselective NSAID is therefore worthy of evaluation, especially because the combination allows the use of lower concentrations of calcitriol and the NSAIDs, thereby improving the safety profile of the NSAIDs.

In conclusion, calcitriol acts by three separate mechanisms: decreasing COX-2 expression, increasing 15-PGDH expression, and reducing PG receptor mRNA levels. We believe that these actions contribute to suppress the proliferative stimulus provided by PGs in prostate cancer cells. The regulation of PG metabolism and biological actions constitutes an additional novel pathway of calcitriol action mediating its antiproliferative effects in prostate cells. We propose that a combination of calcitriol and a nonselective NSAID, such as naproxen, might be a useful therapeutic and/or chemopreventive strategy in prostate cancer, as it would achieve greater efficacy and allow the use of lower concentrations of both drugs, thereby reducing their toxic side effects.