©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Regulation of Avian Osteoclastic H-ATPase and Bone Resorption by Tamoxifen and Calmodulin Antagonists
EFFECTS INDEPENDENT OF STEROID RECEPTORS (*)

(Received for publication, August 21, 1995; and in revised form, February 15, 1996)

John P. Williams (1) Harry C. Blair (1) (2) Margaret A. McKenna (1) S. Elizabeth Jordan (2) Jay M. McDonald (1) (2)(§)

From the  (1)Department of Pathology, The University of Alabama at Birmingham and (2)Laboratory Service, Veterans Affairs Medical Center, Birmingham, Alabama 35294

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

We used highly purified avian osteoclasts and isolated membranes from osteoclasts to study effects of tamoxifen, 4-hydroxytamoxifen, calmodulin antagonists, estrogen, diethylstilbestrol, and the anti-estrogen ICI 182780 on cellular degradation of ^3H-labeled bone in vitro and on membrane HCl transport. Bone resorption was reversibly inhibited by tamoxifen, 4-hydroxytamoxifen, and trifluoperazine with IC values of 1 µM. Diethylstilbestrol and 17-beta-estradiol had no effects on bone resorption at receptor-saturating concentrations, while ICI 182780 inhibited bone resorption at concentrations greater than 1 µM. At these concentrations ICI 182780, like tamoxifen, inhibits calmodulin-stimulated cyclic nucleotide phosphodiesterase activity. Membrane HCl transport, assessed by ATP-dependent acridine orange uptake, was unaffected by 17-beta-estradiol and diethylstilbestrol at concentrations up to 10 µM, while ICI 182780 inhibited HCl transport at concentrations greater than 1 µM. In contrast HCl transport was inhibited by tamoxifen, 4-hydroxytamoxifen, and the calmodulin antagonists, trifluoperazine and calmidazolium, with IC values of 0.25-1.5 µM. These results suggested the presence of a membrane-associated non-steroid receptor for tamoxifen in osteoclasts. Tamoxifen binding studies demonstrated saturable binding in the osteoclast particulate fraction, but not in the nuclear or cytosolic fractions. Membranes enriched in ruffled border by differential centrifugation following nitrogen cavitation showed binding consistent with one site, K 1 µM. Our findings indicate that tamoxifen inhibits osteoclastic HCl transport by binding membrane-associated target(s), probably similar or related to calmodulin antagonist targets. Further, effects of estrogens or highly specific anti-estrogens on bone turnover do not support the hypothesis of a direct effect on osteoclasts by these compounds in this species.


INTRODUCTION

Transport of Ca into and out of bone is critical for maintenance of serum calcium activity. This requires continuous bone turnover at variable rates, which is mediated by the osteoclast. However, skeletal mineral is also structurally vital, so osteoclastic activity is regulated by multiple factors, often acting in opposing directions. Several hormonal signals are involved in this regulation, including peptides and low molecular weight factors(1) . Steroids including estrogens have major effects on bone turnover(2) , but the receptors and intermediary signaling involved are not established. This study was performed to determine the mechanism of steroid-related effects on central biochemical elements of osteoclastic activity.

A limiting biochemical step and the central regulated element of bone turnover is secretion of HCl to dissolve the bone mineral. This is driven by a vacuolar-like H-ATPase that is highly expressed in a unique osteoclastic organelle, the ruffled membrane(3) . Multiple intermediary cell signals influence the activity of acid secretion, but one of critical interest is intracellular calcium activity and the ubiquitous calcium-binding protein, calmodulin. The unique acid-dependent dissolution of calcium salts produces high local extracellular calcium activity(4) , which is reflected in an elaborate osteoclastic calcium regulatory mechanism including a calmodulin-dependent calcium ATPase(5) , and factors influencing osteoclastic intracellular calcium activity such as matrix attachment(6) . The vacuolar-like H-ATPase driving acid secretion in osteoclasts is also calmodulin-dependent, and osteoclasts concentrate calmodulin at the ruffled membrane(7) .

The anti-estrogenic compound, tamoxifen, reduces bone turnover(8) , suggesting that tamoxifen may be a particularly useful tool to dissect osteoclast control pathways. Tamoxifen, a known calmodulin antagonist (9) , is a triphenylethylene derivative with low toxicity and strong antitumor activity, particularly in breast cancer, properties ascribed to its anti-estrogenic activity(10) . Tamoxifen may thus regulate osteoclastic activity by either calmodulin or steroid receptor interactions. In contrast to expectations that tamoxifen would cause bone loss because of anti-estrogenic properties(11) , it preserves bone mass (8, 12) and has estrogen-like effects on human bone metabolism (13) . Tamoxifen has mixed estrogenic and anti-estrogenic effects, which can be tissue-specific. The ethoxyaminoalkyl side chain of tamoxifen is known to be essential for both the anti-estrogenic and calmodulin antagonistic effects(14) . The estrogen receptor is a calmodulin-binding protein(15) , and derivatives of estrogen substituted with the ethoxyaminoalkyl side chain of tamoxifen prevent the binding of calmodulin to the estrogen receptor(16) .

Consequently, we studied the effects of tamoxifen and its active metabolite, 4-hydroxytamoxifen, on osteoclastic HCl transport and cellular activity, and compared these effects to those of calmodulin antagonists, estrogens, and a specific anti-estrogen. We report that tamoxifen and 4-hydroxytamoxifen inhibit membrane acid transport and osteoclastic bone resorption with dose responses similar to the calmodulin antagonists, while neither estrogens nor a highly specific steroidal anti-estrogen showed measurable effects at relevant concentrations. In keeping with these findings, tamoxifen binds to osteoclast cell membrane fractions with a dissociation constant consistent with concentrations observed to have functional effects on whole cell activity and cell membrane ATP-dependent HCl transport. These data support a model for control of osteoclastic acid secretion by tamoxifen and related compounds that is not directly related to estrogen receptors, and further suggest that compounds such as tamoxifen act on the acid-secreting membrane by a mechanism similar to other calmodulin antagonists.


EXPERIMENTAL PROCEDURES

Cell Cultures

Osteoclast-rich cell fractions were obtained from medullary bone of laying hens, Gallus domesticus. Animals on a Ca-restricted diet produced large numbers of osteoclasts, 50% of the medullary bone cell mass, which were harvested and enriched by sieving through 110-µm nylon. Erythrocytes were lysed in hypotonic media and cells sedimented through 70% serum to recover the dense osteoclasts as described(17) . Typically 85-90% of cell nuclei at this stage are in osteoclasts as assessed by tartrate-resistant acid phosphatase activity. Unless noted, assays reported here used osteoclasts further purified by bone affinity binding. Osteoclast-enriched fractions were plated at 2 times 10^4/cm^2 with 60 µg/cm^2 of 20-40-µm (unlabeled) bone fragments for 36 h to allow viable osteoclasts to attach to the bone. Plates were washed gently to eliminate unattached cells, and bone fragments with attached cells are then dislodged by vigorous washing with ice-cold phosphate-buffered saline. Bone was then recovered, with attached osteoclasts, by sedimentation twice for 5 min in 10-cm columns of phosphate-buffered saline. Bone-attached cells were characterized by tartrate-resistant acid phosphatase staining and using a monoclonal antibody, 121F, reacting specifically with avian osteoclasts (Fig. 1), kindly supplied by Philip Osdoby, Washington University, Saint Louis, MO(18) . Cells were fixed 2 h in 1% phosphate-buffered formalin at 4 °C and incubated 30 min at 20 °C with 121F antibody diluted 1:100 or an equivalent dilution of nonimmune ascites in phosphate-buffered saline with 0.05% polyoxyethylene sorbitan monooleate and 1% bovine serum albumin, washed, and incubated with fluoresceinated goat anti-mouse antibody (Sigma) at 1:500 dilution to identify bound primary antibody, washed, and examined by epifluorescence using 450-490 nm excitation and a 520-nm barrier filter. Tartrate-resistant acid phosphatase was demonstrated using naphthol 6-bromo-2-phospho-3-naphthoyl-2-methoxyanilide phosphate as substrate and fast garnet 2-methyl-4-[(2-methylphenyl)-azo]benzene diazonium hydrochloride to show the product as red color, in the presence of 4 mM tartrate at pH 5.6. Cells were incubated in Dulbecco's modified Eagle's medium without phenol red (to preclude artifactual steroid-like dye effects) at 37 °C in humidified air with 5% CO(2). Media contained 100 µg/ml streptomycin, 100 units/ml penicillin, and 10% serum (5% chicken, 5% newborn calf); endogenous serum steroids were eliminated by stripping with activated charcoal.


Figure 1: Characterization of osteoclast preparations. Osteoclasts were isolated by bone affinity binding (see ``Experimental Procedures'') and characterized by 121F monoclonal antibody and tartrate-resistant acid phosphatase activity (20, 21) . Scale markers indicate 15 µm. A, a field of cells is shown by transmitted light; bone fragments used in the isolation are seen as refractile angular acellular material (arrows). B, fluorescein-labeled 121F antibody tags all of the cells in the same field as in panel A. Some cells show a rim of bright stain suggesting membrane-associated reactivity (arrow). C, tartrate-resistant acid phosphatase was demonstrated using naphthol 6-bromo-2-phospho-3-naphthoyl-2-methoxyanilide phosphate as substrate, in 4 mM tartrate at pH 5.6, and fast garnet 2-methyl-4-[(2-methylphenyl)-azo]benzene diazonium hydrochloride to show the product as red color. The affinity isolated cells are all positive, while bone fragments used in the procedure do not react (arrows). D, control cells similar to those in panel B, but reacted with non-immune serum at the same concentration.



Bone Resorption

Bone degradation by avian osteoclasts was quantified by radiometric assay using rat bone labeled in vivo with L-[2,3,4,5-^3H]proline and milled to 20-40 µM to provide a very high surface area for cellular degradative activity(17) . This assay directly measures dissolution of the cross-linked, insoluble component of bone, reflecting complete hydrolysis of mineral and non-mineral components, and is essentially unaffected by physicochemical exchange(17) . Characterization of degradation products and comparison with assay results, using Ca-labeled bone or cell pitting as reported(17, 19) , indicate that this assay of bone degradation correlates well with others and has lower background and interassay variability. In this application, 100-200 µg of 20-40-µm bone fragments at 25 dpm/µg [^3H]proline were added to 2-3 times 10^3 osteoclasts/2-cm^2 tissue culture well. [^3H]Proline released from the labeled bone into the medium was measured relative to no-cell controls, using periods less than 5 days, where activity is essentially linear(17) . Substrate was hydrolyzed with 6 N HCl at 60 °C, 18 h, for determination of specific activity by scintillation counting.

Membrane Vesicle Preparation and HCl Transport Assay

Cells were fragmented by nitrogen cavitation (20) using 10^7 cells in 20 ml of 250 mM sucrose, 20 mM KCl, 0.5 mM EDTA, 1 mM dithiothreitol, 10 mM Tris, pH 7.0, with explosive decompression following 30 min at 35 atm N(2) (3.6 megapascals), 4 °C. Sequential centrifugation at 4 °C (1,000 times g, 5 min; 5,500 times g, 10 min) removed cell fragments, nuclei, and mitochondria, and the vesicular fraction was obtained by centrifugation of the 5,500 times g supernatant at 37,000 times g for 1 h. Cell and vesicle labeling showing that 50% of membranes in these preparations are ruffled border, and cytoplasmic enzymes are <1% of whole cell levels is described(20) . To assay Mg-ATP-dependent HCl transport in response to the test compounds, membrane vesicles were suspended in 120 mM KCl, 20 mM NaCl, 10 mM HEPES, pH 7.4, at 1.5 mg/ml protein and incubated (30 min, 4 °C) to allow vesicles to stabilize. Acid transport by vesicles was determined by monitoring acridine orange uptake by fluorescence spectrophotometry with excitation at 468 nm and digital recording of averaged emission at 540 nm (E) at 5-s intervals, using 25 µg of vesicle protein (15 µl of reconstituted vesicles) in 2.5 ml of 1 mM ATP, 3.3 µM acridine orange, 120 mM KCl, 20 mM NaCl, 10 mM HEPES, pH 7.4, at 37 °C in stirred quartz cuvettes; transport was initiated with 2 mM Mg. Transport was determined as change in fluorescence on addition of a 300-fold molar excess of NH(4)Cl over acridine orange to replace acridine accumulated in acid compartments with the non-fluorescent weak base. Differences were determined 15 s after NH(4)Cl addition to eliminate mixing artifacts. Vesicle activity was stable ±10% at 4 °C from 30 min to 5 h after reconstitution, allowing several comparisons with each vesicle preparation. Antibody labeling showing that osteoclasts are the predominant source of H-ATPase in medullary bone has been reported(3) ; control assays using membrane vesicles from other bone cells, including marrow monocytes isolated as described(21) , showed negligible activity.

Tamoxifen Binding

Osteoclasts were cultured in six-well plates as described above. Cells were washed with phosphate-buffered saline at 4 °C, scraped into 4 ml of 5 mM Tris, 250 mM sucrose, 1 mM EGTA, 1 mM KH(2)CO(3), 1 mM dithiothreitol, pH 7.0, and homogenized by a Teflon pestle at 2,600 rpm. Cytosolic, crude nuclear and particulate fractions and were prepared as follows; the homogenate was centrifuged at 1,000 times g for 5 min (the pellet represents the crude nuclear fraction), and the supernatant centrifuged at 40,000 times g for 30 min. The high speed pellet (particulate fraction) was resuspended in 3 ml of homogenization buffer, while the corresponding supernatant represents the cytosolic fraction. Separate experiments utilized membrane vesicles enriched for ruffled membrane, which were isolated by the nitrogen cavitation procedure described in the previous section. Tamoxifen binding was determined by incubation with 0.63 nM [ring-^3H]tamoxifen, 83 Ci/mmol (Amersham Corp.) with increasing concentrations of unlabeled tamoxifen (10 nM to 30 µM). Reactions were incubated 30 min at 30 °C and stopped by adding one volume of 0.2% bovine -globulin with incubation 10 min on ice. One volume of 25% polyethylene glycol (M(r) 8,000), 0.1 M Na(2)HPO(4), pH 7.5, was added, samples were vortexed and placed on ice 15 min. Bound label was pelleted (30,000 times g, 15 min) supernatants aspirated. Pellets were washed twice with 1 ml of 12.5% polyethylene glycol. Pellet radioactivities were determined by liquid scintillation counting. Protein concentrations were assayed (Bradford DC, Bio-Rad), and binding was calculated as tamoxifen bound/mg of cell protein.

Phosphodiesterase Assay

Activity of calmodulin stimulated cyclic nucleotide phosphodiesterase was measured as the decrease in fluorescence of 2 µM of a cyclic GMP derivative, 2`-(N-methyl)-anthraniloylguanosine 3`:5`-cyclic monophosphate (Molecular Probes, Eugene, OR)(22) , during a 10-min assay at 37 °C, as described(23) . Fluorescence at 450 nm was measured with 280 nm excitation using an Aminco-Bowman (Urbana, IL) Series 2 luminescence spectrophotometer. Assays contained 10 mM MOPS, (^1)pH 6.8, 90 mM KCl, 5 mM MgCl(2), 1 mM EGTA, 1 mM CaCl(2) (25 µM free Ca), 8 µM unlabeled cyclic GMP, 4 nM cyclic nucleotide phosphodiesterase (gift of R. Kincaid, National Institutes of Health, Bethesda, MD), and 15 nM calmodulin (Ocean Biologics, Edmonds, WA). Background activity in the absence of calmodulin was subtracted to calculate the calmodulin-stimulated activity. Tamoxifen or ICI 182780 were preincubated 5 min with the enzyme prior to calmodulin addition.

Statistical Methods

Results are means of quadruplicate determinations unless noted. Error bars indicate standard error of the mean. Groups were compared by analysis of variance or paired Student's t test; differences are concluded if the null hypothesis is rejected at 5% confidence.


RESULTS

Steroid and Calmodulin Effects on Avian Osteoclast Activity

Because variable findings of steroid effects on bone are reported(3, 24) , the cell preparations used were affinity-purified and the composition of the resultant cell preparations was characterized using the monoclonal antibody 121F specific for avian osteoclasts (18) and by tartrate-resistant acid phospha- tase activity. Essentially all of the material in these preparations stains with the osteoclast-specific antibody (Fig. 1), except for non-cellular bone fragments used in the isolation, to which some cells remain attached (Fig. 1A, arrows, transmitted light). The antibody to some extent outlines the cells, suggesting membrane-associated antigen (Fig. 1B, epifluorescence) as reported(18) . Similarly, essentially all purified cells are tartrate-resistant acid phosphatase-positive (Fig. 1C), with only acellular bone non-reactive. Non-immune serum controls for 121F antibody staining were negative (Fig. 1D). Since essentially all cells in these preparations are osteoclasts, the effects on other steroid-receptor containing bone cells that may mediate secondary effects on osteoclasts, such as osteoblasts, are practically eliminated, allowing direct comparisons of the test compounds on osteoclastic bone degradation.

17-beta-Estradiol and diethylstilbestrol did not inhibit resorption of metabolically labeled bone by affinity-purified avian osteoclasts at concentrations meaningful with respect to receptor-mediated effects (Fig. 2). Estradiol had no measurable effect on osteoclastic bone resorption (Fig. 2A). A trend toward increased activity, on the order of 10%, was seen with diethylstilbestrol at concentrations greater than 10M (Fig. 2B), but was not statistically different. Affinity constants of estrogen receptors for these ligands are on the order of 10M, so that concentrations of 10M, and certainly 10M, would be saturating even if the 10% serum proteins in the assay medium reduced the effective free steroid activity by an order of magnitude. Similarly, the specific anti-estrogen ICI 182780 had no effect on activity of affinity-purified avian osteoclasts at physiologically meaningful concentrations (Fig. 2C). ICI 182780 inhibited bone resorption only at concentrations greater than 10M, with 50% inhibition at approximately 10M. The inhibition was reversible on removal of the compound, and so is not related to cell death. Estrogen, diethylstilbestrol and anti-estrogen effects on degradation of [^3H]proline-labeled bone were also tested in partially purified osteoclast preparations, made by serum sedimentation of cells extracted from medullary bone of calcium-deprived laying hens but without bone affinity purification. These results were qualitatively similar to the assays performed with affinity-purified osteoclasts.


Figure 2: Effect of estrogenic compounds and the anti-estrogen ICI 182780 on osteoclastic bone resorption. Avian osteoclasts purified by bone binding (Fig. 1) were incubated for 4 days with 200 µg of 25-50-µm [^3H]-labeled bone fragments in charcoal-stripped, phenol red-free medium (see ``Experimental Procedures'') without addition (controls) and with increasing concentrations of 17-beta-estradiol (A), diethylstilbestrol (B), and ICI 182780 (C) (horizontal axis). ^3H released to the media, representing degraded bone (vertical axis), was determined by scintillation counting. All results are standardized as percent of control activity to eliminate interassay differences in cellular activity. At 10, 10, and 5 times 10M, n = 4; other points are means of multiple quadruplicate tests: n = 12 (10, 10, 10M); n = 16 (control, 10, 10M). Mean ± S.E. Average control resorption was 30% of total substrate.



Tamoxifen, 4-hydroxytamoxifen, and the calmodulin antagonist trifluoperazine inhibited bone resorption by purified osteoclasts at physiologically relevant concentrations (Fig. 3), in contrast to the estrogen-related compounds which were ineffective at receptor-saturating concentrations (Fig. 2). Tamoxifen, 4-hydroxytamoxifen and trifluoperazine inhibited bone resorption in a concentration-dependent manner with maximal inhibitions near 7 µM. Effects were saturating and reversible: Half maximal inhibition was 1 µM for all compounds. Removal of the substances resulted in return of osteoclastic bone resorption to control levels during an additional 3-day incubation (data not shown), indicating that these concentrations did not kill the osteoclasts. While the effective concentrations of these compounds are 10^2- to 10^3-fold greater than those relevant to steroid receptors, these IC values are typical for calmodulin-antagonist effects and are similar to peak serum levels obtained for tamoxifen in the treatment of breast cancer, 0.5-1 µM. As with estrogen and anti-estrogen experiments, similar results were obtained when partially purified osteoclasts were used.


Figure 3: Inhibition of avian osteoclast bone resorption by tamoxifen and trifluoperazine. Purified avian osteoclasts were incubated 4 days with 200 µg of 20-40-µm [^3H]-labeled bone fragments in micromolar concentrations of tamoxifen (A), 4-hydroxytamoxifen (B), or trifluoperazine (C). Note that the effects of the calmodulin antagonist trifluoperazine are similar to those of tamoxifen and its metabolite in this concentration range. Inhibition of bone resorption was calculated relative to bone degradation by osteoclasts without drug addition (vertical axis) from ^3H released into the media, less no-cell controls. Data for tamoxifen and trifluoperazine are from three quadruplicate experiments (n = 12); data for 4-hydroxytamoxifen are from one quadruplicate experiment (n = 4). Mean ± S.E.



Because ICI 182780 inhibited osteoclasts at concentrations above 1 µM where the calmodulin antagonists were also effective, we tested whether this anti-estrogen is also a calmodulin antagonist. This would not be inconsistent with the specificity of ICI 182780 anti-estrogenic effects (27) because in that capacity its K(d) is 10^3- to 10^4-fold lower. Further, a variety of compounds with hydrophobic planar groups and flexible polar side chains, a description that fits ICI 182780, are calmodulin antagonists. To test calmodulin inhibition without introducing systematic bias, we used an unrelated in vitro calmodulin-stimulated phosphodiesterase assay. Both tamoxifen and ICI 182780 inhibited this calmodulin-dependent system similarly, with half-maximal effects at 2-4 µM (Fig. 4).


Figure 4: Effects of tamoxifen and ICI 182780 on calmodulin-stimulated cyclic nucleotide phosphodiesterase activity. The indicated concentrations of tamoxifen (closed symbols) and ICI 182780 (open symbols) were added to the cyclic nucleotide phosphodiesterase assay (see ``Experimental Procedures''). In this assay all values are compared to a control assay run in the presence of carrier alone (100%). Note that both compounds are inhibitors in this assay, with IC 2-4 µM. Data are means of two to five determinations; error bars average 10% and are omitted for clarity.



Combined Effects of Tamoxifen and Trifluoperazine

The similarity of tamoxifen and trifluoperazine action was tested by determining whether combination of the compounds at submaximal inhibitory concentrations would be complementary (Fig. 5A). Bone resorption was inhibited by 0.7 µM tamoxifen or trifluoperazine alone (columns 2 and 3), and in the presence of 0.7 µM of both tamoxifen and trifluoperazine was inhibited further, to a level approaching maximal inhibition (column 4). Thus, submaximal inhibitory concentrations of these two compounds were additive. Addition of estrogen (1 µM) had no effect over 0.7 µM of either trifluoperazine or tamoxifen (not illustrated). However, maximal inhibitory concentrations of tamoxifen or trifluoperazine were not additive, as demonstrated by the combination of 7 µM tamoxifen and 3 µM trifluoperazine (Fig. 5B, column 6), which is not different from the maximal concentrations of either agent alone.


Figure 5: Effects of various concentrations of tamoxifen and trifluoperazine in combination. A, avian osteoclast-enriched fractions from serum sedimentation (not further purified by bone affinity binding; see ``Experimental Procedures'') were incubated with labeled bone for 3 days in carrier (column 1), 0.7 µM tamoxifen (column 2), 0.7 µM trifluoperazine (column 3), or 0.7 µM tamoxifen plus 0.7 µM trifluoperazine (column 4). Bone degraded was calculated from ^3H released into the media as percent control (vertical axis). Data are compiled from three separate experiments each performed in quadruplicate, mean ± S.E. Statistical difference compared to carrier: *, p = 0.03;**, p = 0.06. Bone resorption in the presence of both substances (column 4) is less than that with tamoxifen alone (p < 0.05) or trifluoperazine alone (p < 0.02). B, affinity-purified avian osteoclasts were incubated with labeled bone for 3 days in carrier alone (column 1), 3 or 7 µM tamoxifen (columns 2 and 3), 3 or 7 µM trifluoperazine (columns 4 and 5), or 7 µM tamoxifen plus 3 µM trifluoperazine (column 6), and bone degraded was determined as in A. The data are representative of two experiments performed in quadruplicate, means ± S.E. There is no significant difference between column 6 and columns 3 and 5.



Inhibition of ATP-dependent Membrane HCl Transport

Osteoclastic HCl transport is central to bone degradation (3) and calmodulin-dependent(7) . The activity of tamoxifen or trifluoperazine on bone degradation suggested that these compounds may directly inhibit osteoclastic HCl transport. In contrast, since estrogen did not effect bone degradation, it would not be expected to affect osteoclastic acid secretion. We compared the effects of each compound on membrane ATP-dependent acid transport.

Vesicle acidification was not affected by 1 µM 17-beta-estradiol (Fig. 6A), and neither diethylstilbestrol nor ICI 182780 had measurable effects at meaningful concentrations relative to steroid receptors (10M). Tamoxifen and the calmodulin antagonist trifluoperazine completely inhibited vesicle acidification at concentrations consistent with their effects on cellular activity (Fig. 6, B and C, respectively). Concentration dependence of inhibition of ATP-dependent membrane acid transport by tamoxifen, trifluoperazine, and another calmodulin antagonist, calmidazolium, are summarized in Fig. 7. Half-maximal inhibitory concentrations were 0.25, 1.5, and 1.0 µM for tamoxifen, trifluoperazine, and calmidazolium, respectively. The half-maximal inhibitory concentrations of tamoxifen and trifluoperazine on vesicle acidification were similar to their IC values on bone resorption (Fig. 3). Membrane vesicle acidification was inhibited by 4-hydroxytamoxifen, the major metabolite of tamoxifen, similarly to tamoxifen. ICI 182780 inhibited vesicle acidification at 10M, in keeping with effects observed in the bone resorption experiments and with its inhibition of calmodulin-dependent phosphodiesterase activity at this concentration.


Figure 6: Effect of 17-beta-estradiol, tamoxifen, and trifluoperazine on osteoclast membrane vesicle acidification. ATP-dependent acid uptake was measured in avian osteoclast membranes isolated by nitrogen cavitation and differential centrifugation. Acid transport was monitored by measuring the decrease in fluorescence at 540 nm with excitation at 468 nm of acridine orange due to uptake into vesicles (vertical axis) as a function of time (horizontal axis). Assays were performed with vehicle alone (closed symbols) or with test compounds (open symbols) 1 µM 17-beta-estradiol (A), 2 µM tamoxifen (B), and 10 µM trifluoperazine (C). Test compounds were added to the assay mixture 5 min prior to addition of 2 mM MgCl(2) (open arrow, left) to initiate the reaction. Specificity for acid transport was confirmed by fluorescence recovery on washout of the fluorescent weak base with 1 mM NH(4)Cl (closed arrow, right).




Figure 7: Dose-dependent inhibition of ruffled membrane vesicle acidification by tamoxifen, calmidazolium, and trifluoperazine. Avian osteoclast vesicle acidification was measured as a function of inhibitor concentration by quenching Mg-ATP-dependent acridine orange fluorescence as in Fig. 6. Recovery on addition of 1 mM NH(4)Cl at steady state was used to calculate inhibition of acid transport as a percentage of matched vehicle-only controls (vertical axis). Tamoxifen (closed circles), calmidazolium (open circles), and trifluoperazine (open squares) were added at indicated concentrations (horizontal axis) to membrane vesicles 5 min prior to initiation of acid transport by addition of 2 mM MgCl(2). Control acidification was 2 fluorescence units; the data are typical of three experiments using different membrane vesicle preparations, which gave similar results. 100% inhibition indicates no fluorescence change on NH(4)Cl addition.



Tamoxifen Binding to Osteoclast Membrane Fractions

Tamoxifen had effects on membrane transport, but is also known to bind proteins including estrogen receptors that are found in the cytosol and nucleus. We measured tamoxifen binding as a function of concentration in particulate (membrane), cytosolic, and nuclear fractions of affinity-purified osteoclasts to determine whether tamoxifen binding sites were present in each fraction. Tamoxifen binding saturated at 3 µM in the membrane fraction. Binding in cytosol and nuclear fractions was 2-7-fold/mg of protein lower than the membrane fraction, and non-saturable, indicating nonspecific binding (Fig. 8). Binding experiments were repeated using a preparation enriched in the acid-transporting membrane obtained by nitrogen cavitation. In these preparations, tamoxifen binding saturated at 2 µM (Fig. 9A), and Scatchard analysis demonstrated a single binding affinity with an apparent K(d) of 1 µM (Fig. 9B) and 5 times 10^6 sites/cell.


Figure 8: Tamoxifen binding to membrane, cytosolic, and nuclear osteoclast fractions. Aliquots of fractions, produced as described under ``Experimental Procedures,'' were incubated with 0.63 nM [^3H]tamoxifen and 100 nM to 10 µM unlabeled tamoxifen. Samples were precipitated, washed in polyethylene glycol, and counted to determine bound tamoxifen. A, tamoxifen binding in membrane (closed circles), cytosolic (closed squares), and nuclear fractions (open circles). Data are representative of three separate experiments; triplicate determinations are shown as mean ± S.E.




Figure 9: Tamoxifen binding to osteoclast membranes containing a high proportion of HCl transporting membrane. Aliquots of membrane fractions produced by nitrogen cavitation (see ``Experimental Procedures'') were incubated with 0.63 nM [^3H]tamoxifen and 0-30 µM unlabeled tamoxifen. Samples were precipitated, washed in polyethylene glycol, and counted to determine bound and free tamoxifen. Binding at 30 µM unlabeled tamoxifen was subtracted as nonspecific binding. A, tamoxifen binding in ruffled membrane-enriched preparations. Means of duplicate determinations are shown; these data are typical of results from three separate experiments. B, Scatchard analysis of binding data for ruffled membrane-enriched preparations. The apparent K is 1 µM, with 5 times 10^6 sites/cell. This result suggests that tamoxifen at micromolar concentrations binds an abundant membrane-associated protein in osteoclasts.




DISCUSSION

Estrogens are bone sparing agents, but their mechanism of action is not clear. Which bone cells have estrogen receptors is controversial. Further, whether estrogenic effects are mechanistically related to the effects of bone-sparing compounds such as tamoxifen is enigmatic. It has been proposed that tamoxifen inhibits osteoclast activity by antagonizing estradiol binding(8, 26) . However, other mechanisms might lead to similar findings. For example, the calmodulin antagonist trifluoperazine inhibits breast cancer cell growth similarly to tamoxifen, but independently of the estrogen receptor(27) , and tamoxifen is both an anti-estrogen and a calmodulin antagonist. We studied effects of estrogen, tamoxifen, and related compounds on osteoclastic bone resorption and a key regulated process in bone resorption, membrane HCl transport, to resolve these points.

Bone affinity-purified avian osteoclasts were used to limit observations to direct osteoclast interactions (Fig. 1). This technique uses a small quantity of fragmented bone with a large surface area to concentrate osteoclasts, which attach to bone; other cells attach nonspecifically according to the substrate where they settle, which is 99% cell culture plastic (using 10-cm tissue culture plates and 2 mg of 20-40-µm bone). Thus, the ratio of osteoclasts to contaminants in the bone-attached fraction is, under ideal conditions, improved by 2 orders of magnitude, and non-osteoclastic effects, such as signals that may be generated from steroid receptors in other bone cells, are eliminated. This simplifies interpretation of results, and permits more detailed biochemical dissection of the bone resorption process.

We find that the estrogens 17-beta-estradiol and diethylstilbestrol, as well as the highly specific steroidal anti-estrogen ICI 182780, have no effect on osteoclastic activity at receptor-saturating concentrations (Fig. 2). At extremely high concentrations, over 10M, effects were variable; cell activity in the presence of diethylstilbestrol was slightly increased, although the difference was not statistically different. On the other hand, ICI 182780 inhibited bone resorption at concentrations over 10M. ICI 182780 binds the estrogen receptor with an apparent K(d) of 10M(25) , and physiological estrogen concentrations are 10 to 10M. In postmenopausal women, plasma 17-beta-estradiol is 1.5 times 10M, while premenopausal levels are 7.4 times 10M(28) , and receptor affinities are in this range. Thus, these effects of ICI 182780 are observed at 1000-fold or greater than their receptor K(d) values, and do not represent estrogen receptor-mediated effects. Estrogen and diethylstilbestrol did not effect bone resorption at all concentrations tested (10 to 10M).

There are numerous reports of effects of estrogen on bone mass not directly attributable to osteoclastic estrogen-receptor binding(2, 8, 29, 30, 31, 32) . Our findings are not inconsistent with these results, which point to effects on osteoblasts(29) , membrane-associated estrogen binding different from the classical estrogen receptor and of uncertain significance(30) , or to effects on cell number or activity related to cell differentiation(8, 31, 32) . None of these processes are modeled in our system, which specifically examined purified osteoclasts and osteoclast membrane HCl transport.

On the other hand, it has been reported that 17-beta-estradiol directly inhibits avian osteoclastic bone resorption, almost completely, with half-maximal effects at 10M(24) . Our results are not consistent with this study. Because of this controversial report, our cell preparations were carefully characterized (Fig. 1) and results were repeated with multiple cell preparations. In addition to estradiol, the general estrogen agonist diethylstilbestrol and the highly specific anti-estrogen ICI 182780 were tested. None of these compounds affected bone resorption at or below 10M. Assays measuring pit formation by avian and rat osteoclasts were run in an attempt to demonstrate an estradiol effect at submicromolar levels; differences from controls were not seen. (^2)We conclude that the results reported by Oursler et al.(24) are not reproduced under the conditions used here, which included essentially homogeneous preparations of osteoclasts, phenol-red free medium and charcoal-stripped sera to avoid possible steroid-like effects of the phenol red and effects of serum steroids. The report of estradiol effects in avian osteoclast cultures (24) may thus reflect effects of non-osteoclastic cells, in vitro differentiation, or medium components not present at measurable levels in our system.

In contrast, we found that the triphenylethylene compound tamoxifen had clear inhibitory effects on osteoclastic bone resorbing activity (Fig. 3A). 4-Hydroxytamoxifen (the principal tamoxifen metabolite) and the calmodulin antagonist trifluoperazine had similar effects (Fig. 3, B and C, respectively). In addition, the effects of tamoxifen and trifluoperazine were additive at submaximal inhibitory concentrations (Fig. 5A). Additivity was not observed when one compound was present at maximal inhibitory concentration (Fig. 5B). These results suggest that the inhibitory effect of tamoxifen are related to a calmodulin-dependent signaling mechanism. Tamoxifen and trifluoperazine^2 inhibit calmodulin-dependent cyclic nucleotide phosphodiesterase activity with IC values of 1-3 µM, supporting this hypothesis. On the other hand, tamoxifen binds both estrogen (10) and anti-estrogen (33) receptors, and these properties are believed to be the basis of its beneficial effects in malignancies such as breast cancer. However, the lack of observed estrogenic or anti-estrogenic effects on osteoclastic activity at receptor-saturating concentrations indicate that neither of these mechanisms are responsible for the observed osteoclastic effects. The calmodulin antagonist activity of tamoxifen (9, 34) depends on its ethoxyaminoalkyl side chain, which is also essential for its anti-estrogenic effects(16) . Earlier work on osteoclastic activity points to an important role for calmodulin interactions in acid secreting activity, including a high concentration of calmodulin at the acid secreting ruffled membrane and calmodulin antagonist inhibition of osteoclast membrane acid transport(7) .

We investigated this hypothesis further by comparing the effects of tamoxifen and the calmodulin antagonists trifluoperazine and calmidazolium on ATP-dependent membrane acid transport (Fig. 6Fig. 7). Tamoxifen, trifluoperazine, and the highly specific calmodulin antagonist calmidazolium were all potent inhibitors of HCl transport. Estrogen and diethylstilbestrol had no effect. The anti-estrogen ICI 182780 inhibited vesicle acidification at concentrations over 1 µM, as did the calmodulin antagonists. However, it is also a calmodulin antagonist at these concentrations (Fig. 4). ICI 182780, tamoxifen, and other calmodulin antagonists all act consistently at low micromolar concentrations by inhibiting bone resorption, osteoclast membrane vesicle acidification, and phosphodiesterase activity. This argues for a related inhibitory mechanism for these compounds, a disruption of calmodulin-dependent signaling. However, calmodulin-dependent control mechanisms are very complex and involve a large number of specific calmodulin-protein interactions with different properties. For example, the half-maximal inhibitory concentration of tamoxifen differed by severalfold in the membrane transport assay (Fig. 6) and in the phosphodiesterase assay (Fig. 4); this is likely due to differences in the particular calmodulin-protein interactions present in the different assay procedures.

A potential problem with membrane transport experiments such as those shown in Fig. 6is that the antagonists tested are themselves weak bases, which could affect acridine orange distribution. Accumulation of weak bases in acid compartments depends mainly on concentration, membrane permeability of the free base, and pK(a); high molecular weight alkylamines such as tamoxifen typically have pK(a) 11 and their membrane-permeable uncharged forms are present at concentrations too low, at pH 7.4 (the assay buffer pH), to compete effectively with acridine orange (pK(a) 9.4). Further, effective concentrations of the antagonists were 0.25-1 µM (Fig. 7), 8-30% of the acridine concentrations, suggesting that such artifacts would be much smaller than the observed effects even if pK(a) were near that of acridine orange. However, to rule out such effects, control assays were run with 1 µM NH(4)Cl included (pK(a) 9.3, competes with 3.3 µM acridine at 300 µM; see ``Experimental Procedures''). This reduced acridine orange quenching less than 5%, indicating that the effects of the compounds tested cannot be due to nonspecific effects of their amine groups on the assay.

The results of the membrane transport assays suggested that a tamoxifen binding site is present in osteoclast membranes. Tamoxifen binding was saturable in crude membrane fractions (Fig. 8). In contrast, tamoxifen binding in the nuclear and cytosolic fractions was non-saturable (Fig. 8), indicating nonspecific binding. Because ATP-dependent vesicle acid uptake was directly inhibited, a simple binding to the acid-secreting membrane was hypothesized. Ruffled border-rich cell membranes produced by nitrogen cavitation and differential centrifugation demonstrated saturable high affinity membrane binding with a single apparent K(d) of 1 µM (Fig. 9). This result is obtained under conditions that may vary substantially from those in living cells in terms of calcium activity, buffer composition, and other variables. Despite these limitations, binding of tamoxifen at low micromolar concentration to this osteoclast fraction enriched in acid-transporting membrane likely reflects a key molecular interaction of the inhibitor with an osteoclastic protein. There were 5 times 10^6 binding sites/cell, consistent with an abundant membrane-associated protein, but not a steroid receptor. It is likely that this represents interaction with membrane-bound calmodulin or calmodulin-binding proteins.

Our observations indicate that tamoxifen directly inhibits osteoclast membrane acid transport by a mechanism independent of cytosolic steroid receptors. Further, our results show that critical elements in osteoclastic acid secretion are similarly affected by tamoxifen, calmodulin antagonists, and, at high concentrations, ICI 182780. Whether the effects of calmodulin on osteoclast acid secretion derive from a direct effect of calmodulin on the H-ATPase, its charge-coupled Cl conductance, or are mediated secondarily by calmodulin-binding proteins is unknown. Further, identification of specific protein interactions of tamoxifen will be required to determine whether the similarity of pharmacological effects of tamoxifen and calmodulin antagonists reflect interactions with the same or related proteins.


FOOTNOTES

*
This work was supported in part by the Office of Research and Development, Medical Research Service, Department of Veterans Affairs, and National Institutes of Health Grants AG12951 (to H. C. B.) and AR43225 (to J. M. M.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: Dept. of Pathology, 509 LHRB, The University of Alabama at Birmingham, Birmingham, AL 35294-0007. Tel.: 205-934-6666; Fax: 205-975-9927; mcdonald{at}wp.path.uab.edu.

(^1)
The abbreviation used is: MOPS, 4-morpholinopropanesulfonic acid.

(^2)
J. P. Williams, H. C. Blair, and J. M. McDonald, unpublished observations.


ACKNOWLEDGEMENTS

We thank Randall Kincaid (National Institutes of Health, Bethesda, MD) for providing cyclic nucleotide phosphodiesterase, Philip Osdoby (Washington University, St. Louis, MO) for providing procedures and materials for 121F monoclonal antibody staining, Alan Wakeling (Zeneca Pharmaceuticals, Macclesfield, England) for supplying ICI 182780, and Dominique Salin-Drouin (Besins Iscovesco Laboratories, Paris, France) for supplying 4-hydroxytamoxifen.


REFERENCES

  1. Blair, H. C., Schlesinger, P. H., Ross, F. P., and Teitelbaum, S. L. (1993) Clin. Orthop. Relat. Res. 294, 7-22 [Medline] [Order article via Infotrieve]
  2. Liskova, M. (1976) Calcif. Tiss. Res. 22, 207-218
  3. Blair, H. C., Teitelbaum, S. L., Ghiselli, R., and Gluck, S. (1989) Science 245, 855-857 [Medline] [Order article via Infotrieve]
  4. Silver, I. A., Murrills, R. J., and Etherington, D. J. (1988) Exp. Cell. Res. 175, 266-276 [Medline] [Order article via Infotrieve]
  5. Bekker, P. J., and Gay, C. V. (1990) J. Bone Miner. Res. 5, 557-567 [Medline] [Order article via Infotrieve]
  6. Miyauchi, A., Alvarez, J., Greenfield, E. M., Teti, A., Grano, M., Colucci, S., Zambonin-Zallone, A., Ross, F. P., Teitelbaum, S. L., Cheresh, D., and Hruska, K. A. (1991) J. Biol. Chem. 266, 20369-20374 [Abstract/Free Full Text]
  7. Radding, W., Williams, J. P., Hardy, R. W., McDonald, J. M., Whitaker, C. H., Turbat-Herrera, E. A., and Blair, H. C. (1994) J. Cell. Physiol. 160, 17-28 [Medline] [Order article via Infotrieve]
  8. Turner, R. T., Wakley, G. K., Hannon, K. S., and Bell, N. H. (1988) Endocrinology 122, 1146-1150 [Abstract]
  9. Veigl, M. L., Klevit, R. E., and Sedwick, W. D. (1989) Pharmacol. Ther. 44, 181-239 [CrossRef][Medline] [Order article via Infotrieve]
  10. Lippman, S. M., Benner, S. E., and Hong, W. K. (1993) Cancer Suppl. 72, 984-990
  11. Wright, C. D. P., Mansell, R. E., Gazet, J. C., and Compston, J. E. (1993) Br. Med. J. 306, 429-430 [Medline] [Order article via Infotrieve]
  12. Wright, C. D. P., Garrahan, N. J., Gazet, J. C., Mansell, R. E., and Compston, J. E. (1994) J. Bone Miner. Res. 9, 153-159 [Medline] [Order article via Infotrieve]
  13. Love, R. R., Mazess, R. B., Barden, H. S., Epstein, S., Newcomb, P. A., Jordan, V. C., Carbone, P. P., and DeMets, D. L. (1992) N. Engl. J. Med. 326, 852-856 [Abstract]
  14. Bouhoute, A., and Leclercq, G. (1994) Biochem. Pharmacol. 47, 748-751 [Medline] [Order article via Infotrieve]
  15. Bouhoute, A., and Leclercq, G. (1992) Biochem. Biophys. Res. Commun. 184, 1432-1440 [Medline] [Order article via Infotrieve]
  16. Bouhoute, A., and Leclercq, G. (1995) Biochem. Biophys. Res. Commun. 208, 748-755 [CrossRef][Medline] [Order article via Infotrieve]
  17. Blair, H. C., Kahn, A. J., Crouch, E. C., Jeffrey, J. J., and Teitelbaum, S. L. (1986) J. Cell Biol. 102, 1164-1172 [Abstract]
  18. Oursler, M. J., Bell, L. V., Clevinger, B., and Osdoby, P. (1985) J. Cell Biol. 100, 1592-1600 [Abstract]
  19. Carano, A., Schlesinger, P. H., Athanasou, N. A., Teitelbaum, S. L., and Blair, H. C. (1993) Am. J. Physiol. 264, C694-C701
  20. Blair, H. C., Teitelbaum, S. L., Koziol, C. M., and Schlesinger, P. H. (1991) Am. J. Physiol. 260, C1315-C1324
  21. Alvarez, J. I., Teitelbaum, S. L., Blair, H. C., Greenfield, E. M., Athanasou, N. A., and Ross, F. P. (1991) Endocrinology 128, 2324-2335 [Abstract]
  22. Johnson, J. D., Walters, J. D., and Mills, J. S. (1987) Anal. Biochem. 162, 291-295 [Medline] [Order article via Infotrieve]
  23. Williams, J. P., Jo, H., Sacks, D. B., Crimmins, D. L., Thoma, R. S., Hunnicutt, R. E., Radding, W., Sharma, R. K., and McDonald, J. M. (1994) Arch. Biochem. Biophys. 315, 119-126 [CrossRef][Medline] [Order article via Infotrieve]
  24. Oursler, M. J., Osdoby, P., Pyfferoen, J., Riggs, B. L., and Spelsberg, T. C. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 6613-6617 [Abstract]
  25. Dauvois, S., White, R., and Parker, M. G. (1993) J. Cell Sci. 106, 1377-1388 [Abstract/Free Full Text]
  26. Lerner, L. J., and Jordan, V. C. (1990) Cancer Res. 50, 4177-4189 [Abstract]
  27. Lyman, S. D., and Jordan, V. C. (1985) Biochem. Pharmacol. 34, 2221-2224 [Medline] [Order article via Infotrieve]
  28. Carr, B. R. (1992) in Williams Textbook of Endocrinology (Wilson, J. D., and Foster, D. F., eds) pp. 733-798, W. B. Saunders, Philadelphia
  29. Tobias, J. H., and Chambers, T. J. (1991) Acta Endocrinol. 124, 121-127 [Medline] [Order article via Infotrieve]
  30. Brubaker, K. D., and Gay, C. (1994) Biochem. Biophys. Res. Commun. 200, 899-907 [CrossRef][Medline] [Order article via Infotrieve]
  31. Passeri, G., Girasole, G., Jilka, R. L., and Manolagas, S. C. (1993) Endocrinology 133, 822-828 [Abstract]
  32. Manolagas, S. C., and Jilka, R. L. (1995) N. Engl. J. Med. 332, 305-311 [Free Full Text]
  33. Fanidi, A., Courion-Guichardaz, C., Fayard, J-M., Pageaux, J-F., and Laugier, C. (1989) Endocrinology 125, 1187-1193 [Abstract]
  34. Lam, H. Y. P. (1984) Biochem. Biophys. Res. Commun. 118, 27-32 [Medline] [Order article via Infotrieve]

©1996 by The American Society for Biochemistry and Molecular Biology, Inc.