Abstract
The plant phytoalexin resveratrol was previously demonstrated to inhibit the differentiation and bone resorbing activity of osteoclasts, to promote the formation of osteoblasts from mesenchymal precursors in cultures, and inhibit myeloma cell proliferation, when used at high concentrations. In the current study, we screened five structurally modified resveratrol analogues for their ability to modify the differentiation of osteoclasts and osteoblasts and proliferation of myeloma cells. Compared to resveratrol, analogues showed an up to 5,000-fold increased potency to inhibit osteoclast differentiation. To a lesser extent, resveratrol analogues also promoted osteoblast maturation. However, they did not antagonize the proliferation of myeloma cells. The potency of the best-performing candidate in vitro was tested in vivo in an ovariectomy-induced model of osteoporosis, but an effect on bone loss could not be detected. Based on their powerful antiresorptive activity in vitro, resveratrol analogues might be attractive modulators of bone remodeling. However, further studies are required to establish their efficacy in vivo.
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Resveratrol (RSV, trans-3,5,4′-hydroxystilbene) is a naturally occurring phytoalexin generated in a number of plants including grapes, mulberries, cranberries, and peanuts. RSV has recently attracted considerable interest because of its inhibitory activity on multiple cellular events associated with carcinogenesis [1], and its actions on a broad cell spectrum are well documented both in vitro and in vivo [2, 3]. These anti-cancer effects of RSV are supported by observations in different cancer cell lines in vitro and in animal cancer models such as breast cancer [4], skin cancer [1], liver cancer [5], colorectal and intestinal cancers [6, 7], lung cancers [8], and neuroblastoma [9]. The results of preclinical studies have stimulated an interest from the pharmaceutical industry, and several clinical studies are ongoing in the field of cancer (colon cancer, non-Hodgkin lymphoma, and multiple myeloma) and other areas of clinical research.
It was also reported that RSV may have beneficial effects on osteoclasts (OCs) and osteoblasts (OBs) [10–13]. Noteworthy, current therapies act mainly on only one of the remodeling processes either by inhibition of OC-mediated bone resorption (e.g., bisphosphonates) or by stimulation of bone formation by OBs (e.g., PTH or teraparatide) [14]. It is thus of interest that RSV has the potential both to antagonize OCs and to promote OBs. To our knowledge, only strontium ranelate, statins, and bortezomib share the same potential. Furthermore, RSV and the latter two drugs also prevent the proliferation of cancer cells in multiple myeloma [10, 15, 16]. Multiple myeloma is an incurable neoplasia of terminally differentiated B cells (plasma cells) that frequently causes extensive osteolytic bone lesions resulting in pathological fractures of bone, vertebral collapse, pain and disability. The bone lesions result from a combination of increased bone resorption and inhibition of bone formation in the vicinity of myeloma cells [17]. It thus appears that RSV possesses an ideal triad of properties: it suppresses OC differentiation while at the same time stimulating the differentiation of OBs and inhibits myeloma cell proliferation and survival [10].
However, these effects on OCs, OBs, and myeloma cells were seen only when RSV was used at concentrations between 50 and 100 μM, while lower concentrations seem to be ineffective. In both humans and rodents the peak plasma levels of unmetabolized RSV are well below this level even after a high oral dose, and its elimination is rather rapid [18, 19]. Another problem is that the high doses of RSV that are sufficient to obtain the desired plasma concentrations can cause side effects such as renal toxicity seen in rodents [20]. Furthermore, taking into account the broad spectrum of cellular actions [reviewed in 2, 3], RSV is a questionable option for tailored therapies where a precise effect is needed. A particular concern is its estrogen receptor (ER) agonistic activity [21] associated with genotoxicity [22] and increased risk of carcinogenesis.
Given the limited bioavailability of RSV after oral administration, the high concentrations required to obtain the desired effects seen in vitro, its potential toxicity, and its complex mechanisms of actions, RSV analogues may offer advantages over the parent compound. Structural modifications of RSV led to analogues with improved potency and specificity compared with the parental agent, thereby being more tolerable and safer [23, 24]. One of the RSV derivatives (STR501) is currently being tested in a phase II clinical trial for the treatment of multiple myeloma as a potent activator of Silent Information Regulator T-1, controlling bone mass in vivo via direct regulation of OBs and OCs [25].
In the current study, we compared the activity of a set of RSV derivatives with the parental product. They were designed for no affinity for the ER and higher affinity toward the aryl hydrocarbon receptor (AhR). The modifications in structure consisted of chloride substitution, contributing to suppress ER affinity and to increase AhR affinity [26]. ERα and ERβ (jointly referred to as “ER” in this article) are activated upon the ligation of estrogen. ER functions mainly as a DNA-binding transcription factor that regulates gene expression [27]. The engagement of ER was shown to antagonize OCs and inhibit bone resorption [28]. AhR is a transcription factor that mediates the toxicity of ubiquitous environmental contaminants. AhR ligands are prevalent in tobacco smoke [29], pesticides, and some manufactured chemicals [30]; and they may elicit toxic responses such as tumour promotion [31] and immunosuppression [32]. Emerging data indicate that AhR may also play a role in bone metabolism, mainly acting on OB maturation and the modulation of OB functions [33]. Therefore, novel RSV derivatives with restricted activity toward ER or AhR may serve as unique tools to determine whether the effects of the parental compound RSV are due to one or the other pathway.
In the present study we tested the activity of five of these RSV analogues on OCs, OBs, and myeloma cells in cultures. The best candidate was selected for in vivo testing, using ovariectomized (OVX) rats as a model of estrogen-induced bone loss.
Materials and Methods
RSV Analogues
RSV derivatives displaying different affinity toward ER and AhR are shown in Table 1 and further described in de Medina et al. [26]. Additional PDM02, PDM10, and PDM11 stocks were supplied from Cayman Chemical (Tallinn, Estonia) and solubilized in sterile 99% ethanol. For the animal study PDM02 was dissolved in DMSO.
Cell Cultures
Myeloma cell lines U266 and OPM-2 were obtained from DSMZ (Braunschweig, Germany) and cultured at 37°C in RPMI 1640 medium (GIBCO, Taastrup, Denmark) supplemented with 10% FCS. Media were replaced every other day. Primary myeloma cells were isolated from bone marrow aspirates from myeloma patients as a part of the diagnostic procedure after informed consent (ethical committee approval S-20070019). Myeloma cells were sorted immunomagnetically using MACS anti-CD138 magnetic beads (Miltenyi Biotech, Bergisch Gladbach, Germany) as recommended by the manufacturer. The purity of isolated myeloma cells varied from 70 to 90% as determined by flow cytometric analysis with anti-CD138 antibody (Becton Dickinson, Heidelberg, Germany).
To monitor cell viability upon treatment with RSV analogues, myeloma cells were seeded in flat-bottomed 96-well plates at 5 × 104 cells/well in 200 μL of RPMI 1640 medium in the presence or absence of 10% FCS and increasing concentrations of RSV analogues. The metabolic activity of the cells as a surrogate marker of cell viability was measured with the XTT Cell Proliferation Kit (Roche, Hvidovre, Denmark) according to the manufacturer’s recommendations. Apoptotic cells were labeled with Annexin V and propidium iodide (Annexin-V Apoptosis Detection Kit, BD Pharmingen, Brondby, Denmark) and analyzed on a flow cytometer (Becton Dickinson).
Human OC precursors were prepared from whole blood obtained from healthy donors at Vejle Hospital after written informed consent (ethical committee approval S-20070019). Isolation of CD14+ monocytes, OC differentiation, and monitoring of both tartrate-resistant acid phosphatase (TRAP) activity and number of TRAP-positive multinucleated cells were performed as described previously [10]. Cell viability upon treatment with RSV analogues was determined using Cell Titer Blue Viability Assay (Promega, Nacka, Sweden) according to the manufacturer’s recommendations.
For OB differentiation, we used the well-characterized human bone marrow mesenchymal stem cell line hMSC-TERT (hMSC), which stably expresses human telomerase reverse transcriptase gene (TERT) [34, 35]. hMSC cells were grown in phenol red-free MEM (GIBCO) supplemented with 10% FCS. At 60–70% cell confluence, media were replaced with OB differentiating medium (ODM) containing 10−9 mol/L 1,25(OH)2D3, 50 μg/mL l-ascorbic acid, 10−9 mol/L dexamethasone, and 10−3 mol/L β-glycerophosphate (all from Sigma, Brondby, Denmark) and increasing concentrations of RSV analogues. hMSC-TERT cells were then cultured at 37°C up to 5 days, with media replacement every other day. Cell viability upon treatment with RSV analogues was assessed using the Cell Titer Blue Viability Assay (Promega) as recommended by the manufacturer.
Bone Resorption Assays
For bone resorption assays [10], OC precursors were cultured for 2 days with rhM-CSF (25 ng/mL) and thereafter differentiated for 7 days with rhM-CSF and rhRANKL (25 ng/mL each; R&D Systems, Abingdon, UK). Cells were harvested by trypsin treatment and seeded on bone slices (6 mm in diameter; IDS, Herlev, Denmark) at a density of 105 cells in 200 μL of α-MEM supplemented with 10% FCS, rhM-CSF, rhRANKL (25 ng/mL each), and increasing concentrations of RSV analogues. OCs were cultured at 37°C for up to 3 days. At the end of the experiment, cells were scraped off in water using a cotton stick, and resorption pits were visualized with 0.1% toluidine blue staining. The resorbed areas on bone slices were quantified using an upright light microscope (Carl Zeiss, Birkeroed, Denmark) equipped with a 36-point grid, and results were presented as the total resorbed area in percentage of the whole bone surface.
Real-Time Quantitative PCR on OC Cultures
Relative gene expression was analyzed by TaqMan quantitative real-time PCR as described previously [10] using primers and probes for cathepsin K (Hs00355885_m1), RANK (Hs00187189_m1), c-fms (Hs00234617_m1), and CD14 (Hs00169122_q1). NFATc1 primers and probe were designed according to the NFATc1 Genbank accession U08015: NFATc1-fp TGGAGAGTCCTCGCATCGA, NFATc1-rp CATCGTGGAAAAACTGGTTATTGT, and NFATc1-p ATAACCTCGTGCTTGGGCCTGTACCAC. All primers and probes were purchased from Applied Biosystems (Naerum, Denmark). Cultures of differentiating OCs treated with RSV analogues were harvested at the time points indicated in figure legends, lysed, and subjected to RNA isolation. Residual cell debris was removed by centrifugation through QIA Shredder columns (Qiagen, Hilden, Germany). Total RNA was purified from the cleared homogenate using the RNeasy Mini kit (Qiagen). The yield and purity of isolated RNA were verified by spectrophotometry before reverse-transcribing into single-stranded cDNA using the Iscript cDNA Synthesis kit (Bio-Rad Laboratories, Copenhagen, Denmark) as recommended by the manufacturer. The relative standard curve method was used to calculate the amplification difference for each primer set. A standard curve was made from six points corresponding to twofold cDNA serial dilutions for each gene. For each sample, the relative amount was calculated from its respective standard curve. The quantity of the target gene mRNA was then obtained by division of each value by the mean relative gene expression of human GUS (36-3026) and ABL (06-1250) used as endogenous controls [10].
In Situ Detection of NF-κB Activation
For in situ detection of nuclear factor-κB (NF-κB) translocation, isolated CD14+ cells were seeded in chambered slides and treated for 2 days with 25 ng/mL rhM-CSF. Thereafter, cells were incubated in the presence or absence of increasing concentrations of RSV analogue PDM02 or RSV at 100 μM for 1 h or 7 days in αMEM containing 10% FCS and 25 ng/mL rhM-CSF and then exposed to 100 ng/mL of rhRANKL for 30 min at 37°C. Cells were then fixed and stained with mouse monoclonal anti-p65 antibody as described [10]. Cells showing bright staining for p65 in the nucleus were scored, and the results were presented as the number of cells with NF-κB nuclear translocation as a percentage of the total number of cells counted.
Real-Rime Quantitative PCR on OB Cultures
For real-time PCR analysis of the expression of OB markers, total RNA was isolated from cultured hMSC-TERT cells using a single-step method with TRIzol (Invitrogen, Taastrup, Denmark) according to the manufacturer’s instructions. The integrity and purity of isolated RNA were verified by spectrophotometry and gel electrophoresis, and total RNA was then transcribed into cDNA using RevertAid H Minus first-strand cDNA synthesis kit (Fermentas, Copenhagen, Denmark) as recommended by the manufacturer. Quantitative PCR and gene expression analysis of the target gene and endogenous control β-actin was done as described previously [36]. Expression levels for each target gene and endogenous control were calculated using the comparative Ct method [(1/(2∆Ct)] formula.
Animal Study
Sixty female virgin 8-month-old Sprague-Dawley rats (Taconic, Lille Skensved, Denmark) were maintained under standard conditions of 12-h day and night cycles. Rats were housed two per cage and received common chow and water ad libitum. Handling of the rats was in full accordance with the European Community guidelines for the care and management of laboratory animals.
Rats were randomized into six groups (n = 10/group), (1) sham-operated (Sham), (2) OVX treated with estrogen (OVX + estrogen), (3) OVX treated with vehicle (OVX + DMSO), (4) untreated OVX, and OVX rats treated with (5) high (40 mg/kg) or (6) low (4 mg/kg) dose of PDM02. At surgery, 60-day slow-release pellets containing 0.05 mg 17α-ethylenestradiol (Innovative Research of America, Sarasota, FL) were implanted subcutaneously in the OVX + estrogen group. For vehicle or PDM02 administration, rats were deprived of food for 8 h, anesthetized with 4% isoflurane, and injected intraperitoneally every other day.
The body weight and health status of the animals were monitored weekly. Blood samples (eye puncture) were taken before surgery, twice during treatment (weeks 2 and 4), and at the end of the experiment (week 6, cardiac puncture). Rats were killed by an overdose of pentobarbital, and the right and left tibiae were collected for further analysis.
Volumetric BMD of tibiae was measured by peripheral quantitative computed tomography (pQCT) using the XCT Research M+ pQCT machine (Stratec Medizintechnik, Pforzheim, Germany). The voxel size was 0.100 mm. One slice in the mid-diaphysis of the tibiae located 2 mm proximal to the tibia-fibular junction and one slice in the proximal tibial metaphysis located 2 mm distal from the growth plate were measured. A threshold of 710 mg/cm³ was used for calculation of cortical BMD. For the measurement of trabecular BMD in the proximal tibial metaphysis, we used contour mode 1 and peel mode 20. The percentage of trabecular bone was set to 50% of the cross-sectional area.
Serum levels of CTX, a bone resorption marker, were measured using Rat CrossLaps (IDS) as recommended by the manufacturer.
Statistical Analysis
Statistical comparisons were done with Student’s t-test or one-way ANOVA followed by Dunnett’s post-test, and P ≤ 0.05 was considered significant (Prism v.5 program; GraphPad, San Diego, CA). EC50 values were obtained using nonlinear regression of the original data.
Results
Effect of RSV Analogues on Differentiating and Mature OCs
Since RSV was previously shown to suppress RANKL-mediated OC differentiation [10], we examined whether RSV analogues have the same effect. We therefore cultured CD14+ monocytes in the presence of rhRANKL and increasing concentrations of PDM02 for 7 days. When compared with cultures treated with rhM-CSF alone, rhRANKL induced the formation of numerous TRAP+ multinucleated cells (Fig. 1a, b), increased the levels of TRAP activity in media (Fig. 1c), and strongly induced the expression of cathepsin K (Fig. 1d), all known to be hallmarks of OC differentiation. In contrast, simultaneous treatment of differentiating cultures with PDM02 significantly reduced the number of multinucleated cells staining for TRAP, in a dose-dependent manner (Fig. 1b). Moreover, PDM02-treated cells showed changes in their morphology, becoming spindle-shaped and resembling the monocytic phenotype observed in wells treated only with rhM-CSF (Fig. 1a) as did RSV-treated cells (Fig. 1a and [10]). Also, the rhRANKL-induced TRAP activity in media was diminished and the observed reduction was dose-dependent (Fig. 1c). Similarly, the expression of cathepsin K was strongly suppressed in cultures treated with PDM02 in a dose-dependent manner (Fig. 1d).
Similar experiments were performed for RSV and the other four analogues listed in Table 1. Results of these experiments are summarized in the table (Fig. 1e), and the corresponding dose–response curves are shown in Supplementary Figs. 1 and 2. In all experiments combined treatment of OC precursors with rhM-CSF and rhRANKL induced a mature OC phenotype. Supplementation of the culture media with either PDM10 or PDM11 reduced the levels of TRAP activity released into the culture media (Supplementary Fig. 1) and suppressed the expression of cathepsin K in a dose-dependent fashion. For PDM10, the dose-dependent decrease of the number of TRAP+ multinucleated cells was also verified (Supplementary Fig. 2). Neither PDM01 nor PDM06 showed any significant inhibition of differentiating OCs (Online Resource 1 in Supplementary material). Note that TRAP slightly increased at the lower concentrations of PDM01, -02, and -10 (not of PDM06 and -11); but this increase was not significant. None of the analogues affected cell viability in this OC differentiation model, as opposed to RSV, which reduced the number of viable cells by 35% at 100 μM (Fig. 1e). Thus, we conclude that PDM02, PDM10, and PDM11 are strong inhibitors of OC differentiation, the former two showing a 1,000-fold higher potency compared to RSV.
Since the primary function of mature OCs is to resorb bone, it was of interest to determine whether RSV analogues could inhibit bone resorption in vitro. CD14+ cells were differentiated with rhM-CSF and rhRANKL as described, and once they became mature OCs, they were seeded on bone slices and exposed to increasing concentrations of PDM02. Figure 2 shows that rhRANKL induced numerous pits yielding 8% of resorbed bone area. This induction of pits was not affected by PDM02, and neither was cell viability. Similar results were obtained for PDM10 (data not shown).
RSV Analogues Favor the Expression of Monocytic Markers at the Expense of RANK during OC Differentiation
As M-CSF/RANKL-induced osteoclastogenesis was strongly inhibited in the presence of RSV analogues, we tested their effect on the expression of RANK, which is obligatory for inducing OC differentiation, and compared it to the expression of broader myeloid markers. The expression of RANK was significantly reduced in the presence of RSV analogues at the concentration range that inhibited OC differentiation (100 nM to 1 μM) compared to cultures with M-CSF/RANKL alone (Fig. 3). In contrast, c-fms gene expression was significantly upregulated in the presence of 100 nM PDM02 or PDM10, a concentration that fully inhibited OC differentiation, whereas at high dose (1 μM), this effect was reversed (Fig. 3). On the other hand, PDM11, exhibiting less potent inhibition of OC differentiation (TRAP activity IC50 = 1.2 μM), induced higher expression of the c-fms gene in the range 100 nM to 1 μM (Fig. 3).
Similarly to c-fms, expression of the lipopolysacharide receptor CD14 was significantly upregulated by low doses (10 and 100 nM) of RSV analogues PDM02 and PDM10, whereas high doses (1 μM) suppressed CD14 expression. Treatment with PDM11, with less potency toward differentiating OCs, at concentrations ranging from 10 nM to 1 μM induced CD14 expression (Fig. 3). We conclude that treatment with RSV analogues induces a similar expression pattern of the monocytic markers c-fms and CD14, which is clearly distinct from the effects on RANK expression. The effects of RSV analogues on these markers parallel those they have on OC generation from monocytes. When calculating these gene expressions relative to TRAP, the same conclusions are reached (not shown).
RSV Analogues Act on NF-κB Activation and on the NFATc1 Level
Stimulation of RANK during OC differentiation results in NF-κB activation followed by induction of NFATc1 expression. We assessed the effect of RSV analogues on NF-κB activation during OC differentiation by assaying the nuclear translocation of its p65 component (Fig. 4). As expected, transient stimulation with rhRANKL increased the number of cells with p65 in the nucleus compared to the cultures treated with rhM-CSF alone (Fig. 4a). Pretreatment for 1 h or 7 days with PDM02 abrogated the rhRANKL-triggered translocation of p65 to the nucleus and activation of NF-κB even at low doses (Fig. 4a). Note for comparison that 1-h pretreatment with RSV prior to adding rhRANKL was not sufficient to prevent the nuclear translocation of NF-κB, whereas 7-day treatment resulted in an inhibitory effect as previously reported [10].
As expected, rhRANKL increased the expression of NFATc1 compared to control cells cultured with rhM-CSF alone (Fig. 4b). Seven days of treatment with RSV, PDM02, PDM10, or PDM11 at doses that were inhibitory for OC differentiation significantly reduced NFATc1 expression. However, stimulatory activities were obtained at lower doses of these RSV analogues (10 nM) at this 7-day time point, although not after 1-h treatment. At this early time point, PDM10 and PDM11 already induced a reduction in NFATc1, whereas RSV and PDM02 did not do so when used at the inhibitory doses for OC differentiation.
PDM02 Promotes Osteoblast Differentiation from hMSC-TERT Precursors
RSV was previously shown to induce the differentiation of OBs from mesenchymal precursors [10]. Therefore, we evaluated whether RSV analogues also possess osteogenic potential. When culturing hMSC-TERT cells under osteogenic conditions in the presence of increasing concentrations of PDM02 or 100 μM RSV, the expression of osteogenic markers such as vitamin D3 receptor (VD3R), osteocalcin, osteopontin (OPN), and alkaline phosphatase (ALP) was upregulated relative to cells not treated with PDM02 or RSV (Fig. 5). Levels of upregulation by PDM02 were comparable to those induced by 100 μM RSV at PDM02 doses of 10 nM for ALP, 5 μM for VD3R, and 50 μM for osteocalcin. Although a twofold upregulation of OPN was already detected at 0.5 μM PDM02, higher doses did not cause further upregulation. In contrast, eightfold upregulation was achieved by 100 μM RSV. Treatment with PDM02 in the absence of osteogenic factors was inefficient to induce OB maturation (not shown), in contrast with RSV [10]. Cell numbers as evaluated through metabolic activity were not affected by PDM02 in these cultures. Similar experiments were performed for PDM10 and PDM11 without reproducible results (not shown).
RSV Analogues Do Not Show an Effect on Proliferation and Survival of Myeloma Cells
RSV was previously shown to have a cytotoxic effect on myeloma cells. Therefore, it was of interest to test RSV analogues on myeloma cells. To this end, we treated myeloma cell lines U266 and OPM-2 as well as primary myeloma cells with all RSV analogues listed in Table 1 at doses in the range of 1 nM to 100 μM in the presence or absence of serum. Treatment with the RSV analogues did not affect metabolic activity of these cells (data not shown). No signs of apoptosis were observed in Annexin-V-stained cells (data not shown). We concluded that these RSV analogues have no effect on myeloma cell survival.
PDM02 Does Not Show a Significant Effect on OVX-Induced Bone Loss
In vitro screening identified PDM02 as the most potent RSV analogue of those listed in Table 1, strongly inhibiting OC differentiation at a nanomolar concentration without nonspecific toxicity and promoting OB maturation. In order to evaluate the in vivo relevance of these effects, we tested PDM02 in OVX-induced osteoporosis in rats. To this end, OVX animals were treated with either high (40 mg/kg) or low (4 mg/kg) doses of PDM02 for 6 weeks. As expected, OVX significantly reduced total BMD compared with sham-operated animals, and this effect was partially prevented by administration of estrogen (Fig. 6). Administration of vehicle alone induced a further decline in BMD compared with untreated OVX controls. PDM02 had no statistically significant effect on BMD or bone area (whether total or trabecular) or CTX levels (whether at the 2- or 6-week time point) in OVX rats (Fig. 6 and data not shown).
Discussion
RSV’s ability to simultaneously target the three critical cell players in multiple myeloma–induced bone disease (OCs, OBs, and myeloma cells) made it a very attractive potential therapeutic agent with possible relevance to other bone pathologies. However, its limited bioavailability by oral administration [18, 19] and too broad spectrum of activities and undesired side effects [2, 3, 20] stimulated a search for analogues that had preserved the therapeutic effect but were without the side effects of the natural product. Our study identified two compounds, PDM02 and PDM10, which are at least 1,000 times more potent in terms of inhibition of OC differentiation compared to RSV. Since OCs have a short half-life, it may be anticipated that exposure to these RSV analogues will also result in strong inhibition of bone resorption, even if in vitro these compounds proved to be without direct effect on the bone resorption process itself. Furthermore, PDM02 stimulated OB maturation at 100 times lower concentrations than RSV. In contrast to RSV, these analogues were inactive against myeloma cells, and PDM02 could not protect against OVX-induced bone loss.
The strong effects of PDM02, PDM10, and, to a lesser extent, PDM11 on OC differentiation were demonstrated in three different ways: (1) by inhibition of the formation of TRAP-positive multinucleated cells, (2) by inhibition of the release of TRAP in the medium, and (3) by downregulation of the expression of cathepsin K, all widely recognized hallmarks of OC differentiation.
The mechanism mediating their effect is not merely broad cytotoxicity since the most effective compound PDM02 acted at a dose 5,000 lower than RSV without affecting cell viability, as was the case for the active dose of RSV. Another indication of lack of cytotoxicity is the absence of a direct effect on OC resorptive activity, as mentioned above.
An interesting feature of RSV analogues compared to RSV is the lack of affinity to the ER. Several studies have previously shown that estrogen could directly inhibit OC differentiation [37]. Therefore, it was plausible that the effects of RSV on OCs seen in the present and previous study [10] were ER-mediated. The present study rules out this hypothesis since it shows that RSV derivatives which do not bind the ER still inhibit OC differentiation.
Interestingly, however, even if RSV analogues differ from RSV by lower cytotoxicity and lack of ER binding affinity, they share with RSV the ability to target the key molecules controlling OC differentiation. Indeed, both RSV and its analogues interfere with M-CSF/RANKL signaling and inhibit activation of NF-κB and NFATc1. Treatment with RSV [10] and RSV analogues induced the expression of c-fms while downregulating the expression of RANK, thus retaining the monocytic phenotype of OC progenitors. In agreement with this, CD14 is upregulated and the monocytic spindle-like morphology was observed for PDM02-treated cells, two features which were also observed in the presence of RSV [10]. NF-κB and NFATc1 function downstream of RANKL signaling and play an essential role in the developmental stage from monocyte precursors to mature OCs. We showed that short treatment with RSV analogues (30 minutes after exposure to RANKL), even at 10 nM, significantly diminished nuclear translocation of NF-κB required for RANKL signaling. At the culture time where control cells differentiate into OCs and show high NFATc1 levels, the RSV analogues at concentrations between 100 nM to 1 μM reduce both OC differentiation and NFATc1 expression. Noteworthy, at the same time point, a lower concentration (10 nM) of PDM02, PDM10, and PDM11 stimulated NFATc1; and in the case of the former 2 analogues, this stimulation correlated with a trend toward increased OC differentiation. This correlation did not hold true for PDM11, however, thereby showing that there is no general mechanism by which RSV analogues at low concentration tend to stimulate OC differentiation. Interestingly also, NFATc1 and NF-κB do not show an identical inhibition pattern. This difference reflects the fact that NFATc1 is regulated not only by NF-κB but also by the c-Fos and the Ca/calcineurin pathway, as well as by NFATc1-mediated activation of its own promoter resulting in autoamplification [38]. NFATc1 is thus downstream of several “signaling modules” and integrates them, whereas NF-κB activity is known to rise and fall rapidly, acting as an early immediate signal [39].
In relation to RSV analogues as AhR ligands, it is of interest to mention that NFATc1 was reported to be activated upon the engagement of AhR in the breast cancer cell line MCF-7 [40]. Furthermore, NF-κB is also triggered when AhR is activated so that NF-κB acts as a common transcriptional factor for both RANKL and AhR-mediated signaling. Recent results suggested a competitive model of RANKL/AhR activation [41]. The AhR ligand was shown to directly inhibit NF-κB activation and thus osteoclastogenesis. This effect was reversed by high concentrations of RANK and by RSV with antagonistic properties toward AhR [41]. Although these observations stress a close relation between the AhR, which is known to be a target for RSV analogues, and NF-κB/NFATc1, which is shown here to respond to the RSV analogues, they do not allow a full understanding of our data. Indeed, PDM02 and PDM11 are AhR antagonists, while PDM10 is an agonist (Table 1); but they all displayed the same inhibitory effect toward OC differentiation, and furthermore, RSV always showed inhibitory activity ([10] and present results), in contrast with the situation of Voronov et al. [42], where it was tested in the presence of AhR agonists and stimulated resorption.
A characteristic of the extensive bone loss observed in osteoporotic and some cancer patients is that increased bone resorption is not compensated by enhanced bone formation [43]. Formation of new bone is mediated by OBs that differentiate from mesenchymal stem cells in response to different hormones or local factors. Previous studies showed that RSV induced the mature phenotype in OB precursors [11] while decreasing adipocyte formation from mesenchymal precursors in favor of osteogenesis [44]. In our study we demonstrated that only PDM02 was able to promote the mature phenotype in hMSC-TERT. PDM02 induced the expression of VDR, OPN, osteocalcin, and ALP as important characteristics of OB differentiation. RSV analogues used in the study displayed different binding affinities to AhR and acted either as antagonists or as agonists.
The occupancy of AhR by dioxins has been correlated with suppression of OB maturation [33]. This dioxin-induced suppression could be reduced by simultaneous treatment with RSV, acting strongly antagonistically on AhR [12]. PDM02 is a 140 times more potent antagonist of AhR than RSV and correspondingly affected OB differentiation at lower concentrations compared to RSV. However, treatment of MSC-TERT cells with PDM10 and PDM11—respectively, an AhR agonist and antagonist—did not give reproducible results. Therefore, the stimulatory properties of PDM02 on OBs cannot be clearly interpreted as being mediated through AhR.
In multiple myeloma, cancer cells promote OC activation and induce bone resorption [45–47] while suppressing bone formation. We previously demonstrated cytotoxic and proapoptotic properties of RSV on myeloma cells [10] on a molecular basis explained by inhibition of the constitutional activation of NF-κB in myeloma cells [15]. In the present study we tested several RSV analogues and none of them showed antagonistic activity against either primary myeloma cells or myeloma cell lines. This discrepancy could be related to the fact that the tested analogues are structurally modified and dihydroxyl groups in RSV were replaced. Indeed, several recent studies with RSV and its natural or synthetic analogues underscore the importance of 3,4-dihydroxyl groups in exhibiting cytotoxic and proapoptotic activities [48]. Furthermore, Murias and colleagues [24] clearly demonstrated that hydroxyl groups are critical and that the natural RSV analogue piceatannol containing four hydroxyl groups exhibited more cytotoxicity toward leukemia cells than the trihydroxystilbene RSV. Accordingly, compounds lacking hydroxyl groups such as rhaponticin and stilbene performed poorer than RSV and piceatannol, confirming the importance of hydroxyl groups [23].
Among five analogues, only PDM02 both inhibited the differentiation of OCs and induced OB maturation in a nanomolar range, although it could not antagonize myeloma cells. Based on these observations, we tested the efficacy of PDM02 in vivo, using OVX rats as a model of human postmenopausal osteoporosis. It was reported that low-dose RSV given by force-feeding for 12 weeks had a beneficial effect on BMD and bone calcium content in OVX rats [49], despite its low bioavailability. In our study, the RSV analogue PDM02 administered intraperitoneally for 6 weeks had no significant effect on the loss of BMD or on serum CTX, which is a marker of bone resorption. The differences between our results and those of Liu et al. [49] may be due to the duration of the experiment (6 vs. 12 weeks), to the nature of the drug itself, or to different drug-administration modes (intraperitroneal injection vs. gavage). In our system, PDM02 was dissolved in DMSO, and administration of DMSO alone induced further bone loss compared with untreated OVX animals. It cannot be ruled out that DMSO dosing provoked inflammation and that the release of inflammatory cytokines caused further bone loss [reviewed in 50]. Thus, the lack of bone-sparing effects of PDM02 in vivo could be a result of DMSO administration. Regarding the drug itself, one may also speculate that the lack of in vivo effect of PDM02 may be due to low bioavailability. The bioavailability of PDM02 is unknown. Injected PDM02 could be rapidly excreted from the body, as is the case for RSV. A recent study suggested that RSV is mainly absorbed in the small intestine as RSV glucuronide [19]. Glucuronides of phenolic compounds are thought to be rapidly excreted in vivo and to be pharmacologically inactive [51]. PDM02 could be processed in the same or a similar way, thereby rapidly losing the activity demonstrated in vitro or maybe falling in the low concentration range where a trend to higher TRAP and NFATc1 was detected in culture conditions. Lack of efficacy might also be explained by the fact that PDM02’s inhibitory activity is restricted to OC differentiation, whereas strong antiresorptives such as bisphosphonates and denosumab not only inhibit OC differentiation but also directly inhibit OC bone resorption.
To our knowledge, the present study is the first to show that RSV analogues strongly inhibit OC differentiation and may promote OB differentiation. Therefore, RSV analogues may be of potential therapeutic interest. However, further studies are required in order to define their pharmacological characteristics and pharmacodynamics with the aim to achieve in vivo efficacy.
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Acknowledgments
The authors thank Birgit MacDonald and Christiane Schüler for excellent technical assistance. This work was supported by grants from the Region of Southern Denmark.
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Effect of RSV analogues on TRAP activity in differentiating OCs. PBMC-isolated monocytes were cultured in the presence of M-CSF initially for 2 days, followed by treatment with M-CSF and RANKL, and then cultured in the presence or absence of RSV analogues for 7 days (●). Cultures treated with M-CSF alone served as controls (○). TRAP activity was measured in conditioned media as described in Materials and Methods. Effects of RSV analogues on TRAP activity are presented relative to cultures treated with M-CSF and RANKL. Each point represents the mean ± SD of six cultures. Results are representative of three independent experiments. (TIFF 11519 kb)
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PDM10 treatment inhibits the formation of multinucleated TRAP+ osteoclasts. Monocytes were cultured in the presence of M-CSF initially for 2 days, followed by treatment with M-CSF and RANKL, and then increasing concentrations of PDM10. At the end of 7-day cultures, cells were stained for TRAP and the number of TRAP-positive multinucleated cells was scored and expressed relative to PDM10-untreated cultures. Each point represents the mean ± SD of six cultures. (TIFF 11026 kb)
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Kupisiewicz, K., Boissy, P., Abdallah, B.M. et al. Potential of Resveratrol Analogues as Antagonists of Osteoclasts and Promoters of Osteoblasts. Calcif Tissue Int 87, 437–449 (2010). https://doi.org/10.1007/s00223-010-9399-3
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DOI: https://doi.org/10.1007/s00223-010-9399-3