Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-15T11:18:56.728Z Has data issue: false hasContentIssue false

Zinc modifies the effect of phyto-oestrogens on osteoblast and osteoclast differentiation in vitro

Published online by Cambridge University Press:  31 January 2012

Sahar Karieb
Affiliation:
School of Biomedical and Biological Sciences, Room 404 Davy Building, Drake Circus, Plymouth University, PlymouthPL4 8AA, UK
Simon W. Fox*
Affiliation:
School of Biomedical and Biological Sciences, Room 404 Davy Building, Drake Circus, Plymouth University, PlymouthPL4 8AA, UK
*
*Corresponding author: Dr S. W. Fox, fax +44 1752 232970, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Osteoblast and osteoclast activity is disrupted in post-menopausal osteoporosis. Thus, to fully address this imbalance, therapies should reduce bone resorption and promote bone formation. Dietary factors such as phyto-oestrogens and Zn have beneficial effects on osteoblast and osteoclast activity. However, the effect of combinations of these factors has not been widely studied. We therefore examined the effect of coumestrol, daidzein and genistein in the presence or absence of zinc sulphate (Zn) on osteoclast and osteoblast activity. Osteoclast differentiation and bone resorption were significantly reduced by coumestrol (10− 7 m), daidzein (10− 5 m) and genistein (10− 7 m); and this direct anti-osteoclastic action was unaffected by Zn (10− 5 m). In addition, Zn augmented the inhibitory effect of phyto-oestrogens on the osteoblast-derived stimulus for osteoclast formation, significantly reducing the ratio of receptor activator of NF-κB ligand (RANKL)-to-osteoprotegerin mRNA expression in human osteoblast. We then examined the effect of these compounds on osteoblast activity. Mineralisation was enhanced by coumestrol (10− 5 to 10− 7 m), daidzein (10− 5 to 10− 6 m) and genistein (10− 5 m); and Zn significantly augmented this response. Zn and phyto-oestrogens also significantly enhanced alkaline phosphatase activity and Runt-related transcription factor 2 (Runx2) mRNA expression. On the other hand, Zn blunted phyto-oestrogen-induced type I collagen and osteocalcin expression and suppressed coumestrol and daidzein-stimulated osterix expression. Zn may therefore modify the anabolic action of phyto-oestrogens, promoting characteristics associated with early rather than late stages of osteoblast differentiation. Our data suggest that while Zn enhances the anti-osteoclastic effect of phyto-oestrogens, it may limit aspects of their anabolic action on bone matrix formation.

Type
Full Papers
Copyright
Copyright © The Authors 2012

The skeleton constantly remodels in response to changes in mechanical load, serum Ca and micro-damage(Reference Martin and Seeman1, Reference Henriksen, Neutzsky-Wulff and Bonewald2). This dynamic process generates a bone mass and structure optimised to current physical and mineral requirements. At a cellular level, remodelling is performed by osteoblasts that secrete and mineralise new bone matrix and osteoclasts that resorb bone. Osteoblast and osteoclast activity is tightly regulated such that during each remodelling cycle osteoblast formation is temporally coupled to resorption, ensuring that there is little net bone loss. However, this balance is disrupted in many skeletal disorders such as post-menopausal osteoporosis and osteomyelitis(Reference Nair, Meghji and Wilson3, Reference Manolagas, Kousteni and Jilka4). In post-menopausal women, the reduction in circulating oestrogen increases bone turnover and skews remodelling in favour of osteoclastic resorption(Reference Manolagas, Kousteni and Jilka4). The resulting bone loss increases fracture risk at elements with a high trabecular content such as the femoral neck and distal radius and ulna.

Hormone replacement has been shown to prevent the increase in osteoclast formation and thereby reduce fracture risk(5). Hormone replacement also has an anabolic action, increasing bone formation and volume in rats and humans(Reference Chow, Tobias and Colston6, Reference Khastgir, Studd and Fox7). This contrasts with other antiresorptive drugs, such as bisphosphonates, which typically only suppress osteoclast activity. However, the widespread use of hormone replacement has been re-assessed in the light of large-scale clinical trials that showed a substantial increase in the risk of breast cancer and CHD in older women prescribed combination hormone replacement(5). Therefore, several alternative compounds with oestrogenic actions have been examined for their antiresorptive and anabolic potential. These include phyto-oestrogens, a diverse group of plant-derived factors with a structure and function similar to oestradiol. Some epidemiological studies suggest that diets with high phyto-oestrogen content, such as soya-rich diets, may generate a more robust skeleton. A positive association between soya consumption and bone mineral density has been noted in Asians(Reference Horiuchi, Onouchi and Takahashi8Reference Kim, Chung and Yu10) and supplements have also been shown to have beneficial effects on bone mineral density(Reference Alekel, Germain and Peterson11Reference Wu, Oka and Tabata14). However, not all studies note a positive effect at all skeletal sites and efficacy varies depending on the phyto-oestrogen and dose studied(Reference Ricci, Cipriani and Chiaffarino15).

The protective effect of phyto-oestrogens is thought to occur through a combination of osteoclast- and osteoblast-mediated actions. Several studies note decreases in resorption markers following phyto-oestrogen supplementation(Reference Mei, Yeung and Kung9, Reference Weaver, Martin and Jackson16) and in vitro studies show a direct suppressive effect of phyto-oestrogens on cytokine-induced osteoclast differentiation(Reference Gao and Yamouguchi17, Reference Karieb and Fox18). In addition to suppressing resorption, phyto-oestrogens have also been shown to increase bone formation markers such as serum alkaline phosphatase (ALP) and osteocalcin levels in post-menopausal women(Reference Morabito, Crisafulli and Vergara12, Reference Roudsari, Tahbaz and Hossein-Nezhad19). Genistein has also been shown to increase mineral apposition and bone formation rates in ovariectomised rats(Reference Dai, Ma and Sheng20) and phyto-oestrogens stimulate osteoblast differentiation and mineralisation in vitro (Reference Kanno, Hirano and Kayama21Reference Yadav, Gautam and Kureel23).

In addition, other nutritional factors have been shown to influence remodelling activity. Zn promotes osteoblast activity in vitro (Reference Kwun, Cho and Lomeda24), Zn deficiency is associated with osteopenia in men(Reference Hyun, Barrett-Connor and Milne25) and Zn supplements prevent exercise-induced falls in long bone mass in rats(Reference Seco, Revilla and Hernández26). Osteoclast activity is also decreased by Zn(Reference Yamaguchi and Uchiyama27, Reference Uchiyama and Yamaguchi28). The ability of dietary factors to not only prevent further bone resorption but also replace bone already lost is desirable; however, studies have not fully examined the effect of combinations of dietary factors on bone cell differentiation and activity. Similarly, the effect of these factors on osterix mRNA expression which regulates the formation of mature osteoblasts has not been investigated. We therefore examined the effect of genistein, coumestrol and daidzein in the presence of Zn on osteoblast and osteoclast function in vitro.

Methods

Media and reagents

Saos-2 human osteoblast-like cells were obtained from ECACC (catalogue no. 89050205) and cultured in phenol red-free Roswell Park Memorial Institute (RPMI)-1640 supplemented with 10 % charcoal-stripped fetal calf serum (Autogen Bioclear) 2 mmol/l glutamine, 100 IU/ml benzylpenicillin and 100 mg/ml streptomycin (all from Sigma). RAW264.7 monocytes (American Type Culture Collection, catalogue no. TIB-71) were incubated in phenol red-free Dulbecco's minimum essential medium supplemented with 10 % charcoal-stripped fetal calf serum (Autogen Bioclear), 2 mmol/l glutamine, 100 IU/ml benzylpenicillin and 100 mg/ml streptomycin (all from Sigma). All incubations were performed at 37°C in 5 % CO2, and cultures fed every 2–3 d by replacing half of the culture volume with fresh medium. Zinc sulphate heptahydrate (Zn) was obtained from Sigma. The non-selective oestrogen antagonist ICI 182780 was obtained from Tocris Biosciences. Recombinant murine TNF-α was purchased from Insight Biotechnology. All other reagents and kits were obtained from Sigma unless stated.

Measurement of mineralisation and alkaline phosphatase activity

Preliminary studies established that concentrations of Zn below 10− 5 m showed no interaction with phyto-oestrogens; and all subsequent studies therefore used Zn at a concentration of 10− 5 m. The effect of coumestrol (10− 5 to 10− 9 m), daidzein (10− 5 to 10− 9 m) and genistein (10− 5 to 10− 9 m) in the presence or absence of Zn (10− 5 m) on ALP activity was assessed as follows. Saos-2 cells (1 × 104 per well) were incubated in ninety-six-well plates for 24 h to enable cells to adhere. Cultures were then incubated in relevant phyto-oestrogen and Zn concentrations in the presence of β-glycerophosphate (β-GP; 10 mm) and l-ascorbic acid (l-AA; 50 mg/l) for 4 d. ALP activity was measured by staining cultures with p-nitrophenyl phosphate (1 mg/ml) in 0·2 m-Tris buffer at 37°C for 30 min(Reference Sabokbar, Millett and Myer29). Absorbance was measured at 405 nm and the results were then normalised to total cell number and expressed as the amount of ALP required to liberate 1 mmol of p-nitrophenol/min per 104 cells.

Mineralisation was assessed using a modification of Hale's methodology(Reference Hale, Ma and Santerre30). This enables the rapid and direct quantification of mineralisation by measuring calcein incorporation into mineralised nodules. Cells were treated with β-GP (10 mm) and l-AA (50 mg/l) to initiate mineralisation and the medium supplemented with genistein, daidzein or coumestrol (10− 5 to 10− 9 m) with or without Zn (10− 5 m). After 18 d of incubation, the culture medium was aspirated, the monolayer washed with PBS and incubated in culture medium containing 1 μg/ml calcein for 4 h at 37°C. Cultures were then washed three times in PBS and the fluorescence measured by a cytofluor II fluorescence multi-well plate reader (PerSeptive Biosystem) at 485 nm excitation and 530 nm emission.

Proliferation

Saos-2 cells were cultured in ninety-six-well plates at a density of 1 × 104 cells per well in the presence of coumestrol (10− 5 to 10− 9 m), daidzein (10− 5 to 10− 9 m) or genistein (10− 5 to 10− 9 m) with or without Zn (10− 5 m) for 4 d. Proliferation was then assessed using a commercial AQueous one solution cell proliferation assay (Promega) according to the manufacturer's instructions.

Real-time quantitative PCR analysis

Saos-2 cells (5 × 105 per well) were incubated in six-well plates for 24, 48 or 96 h with coumestrol (10− 7 m), genistein (10− 7 m) or daidzein (10− 5 m) with or without Zn (10− 5 m). Total RNA was extracted from these cultures using a Sigma genelute RNA isolation kit and reverse-transcribed with Moloney Murine Leukemia Virus RT using random nonamer primers. Real-time PCR was performed on a StepOne PCR system (Applied Biosystems) using the DNA-binding dye SYBR green for detection of PCR products. A total of 2 μl of external plasmid standard or complementary DNA were added to a final reaction volume of 25 μl containing 0·05 U/μl Taq, SYBR green and specific primers (0·2 μm). Primers for genes were as follows: human osteocalcin forward CCCAGCGGTGCAGAGTCCAG, reverse CCTCCCTCCTGGGCTCCAGG; human Runt-related transcription factor 2 (Runx2) forward AGACCCCAGGCAGGCACAGT, reverse GCGCCTAGGCACATCGGTGA; human osterix forward GCACCCTGGAGGCAACTGGC, reverse GAGCTGGGTAGGGGGCTGGA; human type I collagen forward CCTGGCAGCCCTGGTCCTGA, reverse CTTGCCGGGCTCTCCAGCAG; human receptor activator of NF-κB ligand (RANKL) forward ACAGGCCTTTCAAGGAGCTGTGC, reverse ACCAGATGGGATGTCGGTGGC; human osteoprotegerein forward AATCGCACCCACAACCGCGT reverse AGCAGGAGACCAAAGACACTGCA; human β-actin forward GCGCGGCTACAGCTTCACCA, reverse TGGCCGTCAGGCAGCTCGTA. For the generation of standard curves, the corresponding complementary DNA was cloned into pGEM-T Easy (Promega). The concentration of DNA plasmid stock was determined by the optical density at 260 nm. Copy number for each plasmid was calculated from these measurements. The linear range of the assay was determined by the amplification of log serial dilutions of external plasmid standard from 500 to 5 × 106 copies. The progress of the PCR amplification was monitored by real-time fluorescence emitted from SYBR Green during the extension time. Reaction conditions were 94°C for 2 min, followed by thirty-five cycles of 94°C for 30 s, 60°C for 30 s and 72°C for 30 s. At the end of each PCR run, a melt curve analysis was performed to show the absence of non-specific bands. For each sample, mRNA levels were expressed as an absolute copy number normalised against the β-actin gene. The mRNA copy number was calculated for each sample from the standard curves by the instrument's software. The samples were analysed in triplicate.

Osteoclast differentiation and bone resorption assays

To examine the direct effect of Zn on the anti-osteoclastic action of phyto-oestrogens, RAW264.7 cells were transferred to ninety-six-well plates at a density of 1 × 104 cells per well. The effect of Zn on the anti-resorptive action of phyto-oestrogens was assessed by seeding 104 RAW264.7 cells onto 20 mm2 slices of devitalised bovine bone in ninety-six-well plates. Cells and bone slices were then incubated with combinations of TNF-α (50 ng/ml), genistein (10− 5 to 10− 9 m), daidzein (10− 5 to 10− 9 m) or coumestrol (10− 5 to 10− 9 m) with or without Zn (10− 5 m) for 4 d for assessment of tartrate-resistant acid phosphatase (TRAP)-positive osteoclast formation or 8 d for bone resorption.

Assessment of tartrate-resistant acid phosphatase-positive osteoclast formation

Osteoclast formation was evaluated by staining for the specific osteoclastic marker TRAP using a modification of the method of Burstone(Reference Burstone31) using naphthol AS-BI phosphate as a substrate. The number of TRAP-positive cells was counted using an eyepiece graticule at a magnification of × 100 and the results expressed as the number of cells/cm2. All experiments were performed in triplicate.

Bone resorption

After incubation, cells were removed from the surface of bone slices by immersion in 10 % (v/v) receptor activator of NF-κB (RANK) sodium hypochlorite for 10 min, followed by washing in distilled water and dehydration in 70 % ethanol. After drying, slices were mounted onto glass slides and stained with 1 % toluidine blue for 2 min, washed in distilled water and then dehydrated in ethanol to enable visualisation of resorption pits. The percentage of bone surface resorbed was quantified by reflected light microscopy using an eyepiece graticule and magnification of × 100 on an Olympus BHB microscope with a Schott KL1500 light source.

Statistical analysis

Differences between groups were assessed using Fisher's one-way ANOVA (Statview; Abacus Concepts). A difference of P < 0·05 was considered statistically significant.

Results

Zinc has no effect on the direct anti-osteoclastic action of phyto-oestrogens

Excessive resorption is central to bone loss in several skeletal disorders including post-menopausal osteoporosis. We and others have previously shown that phyto-oestrogens possess antiresorptive actions, directly suppressing cytokine-induced osteoclast differentiation and bone resorption(Reference Karieb and Fox18). However, the effect of combinations of phyto-oestrogens and Zn on this direct anti-osteoclastic action has not been examined. As shown previously(Reference Karieb and Fox18), coumestrol, daidzein and genistein, all significantly suppressed TRAP-positive osteoclast formation and bone resorption (Fig. 1). The dose–response for the phyto-oestrogens matched previous results with maximal suppression noted with coumestrol (10− 7 m), daidzein (10− 5 m) and genistein (10− 7 m). In contrast, TRAP-positive osteoclast formation and bone resorption were unaffected in the presence of Zn alone. Furthermore, the anti-osteoclastic action of all phyto-oestrogens was not affected by the addition of Zn (Fig. 1).

Fig. 1 Zinc has no effect on the direct anti-osteoclastic action of phyto-oestrogens. RAW264.7 cells were incubated in the presence of TNF-α (50 ng/ml) for 4–8 d plus coumestrol (10− 5 to 10− 9 m, ), daidzein (10− 5 to 10− 9 m, ) or genistein (10− 9 to 10− 5 m, ) in the presence or absence of zinc (10− 5 m, ). Osteoclast formation was assessed by tartrate-resistant acid phosphatase (TRAP) staining and bone resorption was determined by the percentage of bone surface displaying resorption pits analysed by reflected light microscopy. Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the TNF-α-treated group (P < 0·05).

Zinc augments the suppressive action of phyto-oestrogens on osteoblastic receptor activator of NF-κB ligand:osteoprotegerin ratio

Phyto-oestrogens may also indirectly suppress osteoclast formation by modifying expression of the key osteoblast-derived regulators of osteoclastogenesis RANKL and osteoprotegerin (OPG). Osteoclast formation is dependent on a balance between two osteoblast-derived cytokines, RANKL which induces osteoclast differentiation after binding to its receptorreceptor activator of NF-κB (RANK) and OPG, a soluble decoy receptor which sequesters RANKL, preventing RANK activation(Reference Boyce and Xing32). To assess the effect of phyto-oestrogens and Zn on RANKL and OPG expression, we incubated osteoblasts with Zn and the concentrations of phyto-oestrogens shown to have the maximal suppressive effect on osteoclastogenesis. We found that the RANKL:OPG gene expression ratio was significantly reduced by Zn (4·16-fold), coumestrol (1·88-fold) and genistein (3·57-fold) in comparison to control (Fig. 2). Furthermore, combinations of Zn and genistein or coumestrol further reduced RANKL/OPG gene expression in comparison to Zn or phyto-oestrogens alone (Fig. 2). In contrast, although daidzein lowered RANKL/OPG expression, this did not reach significance and in the presence of daidzein the suppressive action of Zn was not noted (Fig. 2).

Fig. 2 Phyto-oestrogens and zinc suppress the osteoblast-derived stimulus for osteoclast formation. Human osteoblast-like Saos-2 cells were incubated with zinc plus coumestrol (10− 7 m, ), daidzein (10− 5 m, ) or genistein (10− 7 m, ) in the presence or absence of zinc (10− 5 m, ). Total RNA was extracted and the expression of receptor activator of NF-κB ligand (RANKL) and osteoprotegerin (OPG) quantified by real-time PCR. Data were normalised to β-actin and expressed as a ratio of RANKL-to-OPG expression in comparison to control. Values are means of two separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the control group (P < 0·05). † Mean values were significantly different from those of the zinc- or relevant phyto-oestrogen-treated group alone (P < 0·05).

Zinc augments the stimulatory effect of phyto-oestrogens on osteoblast mineralisation

To examine the potential interaction between phyto-oestrogens and Zn on osteoblast differentiation and activity, we utilised human Saos-2 osteoblast-like cells which readily form mineralised nodules in the presence of l-AA and β-GP. Genistein, daidzein and coumestrol all enhanced mineralisation, with coumestrol having the most pronounced effect (Fig. 3(a)). Zn alone had no significant effect on mineralisation as assessed by calcein incorporation into mineralised nodules. Coumestrol (10− 5 to 10− 7 m) significantly enhanced osteoblastic mineralisation, with maximal effects noted at 10− 6 m which induced a 1·62-fold increase in mineralisation. Daidzein (10− 5 to 10− 6 m) also significantly enhanced mineralisation with a maximal 1·43-fold increase noted at 10− 5 m. Genistein stimulated a significant 1·39-fold increase in calcein incorporation at the highest dose studied (10− 5 m). The addition of Zn augmented the anabolic effect of all phyto-oestrogens, significantly increasing mineralisation compared to cultures treated with phyto-oestrogen alone, coumestrol (10− 5 to 10− 7 m), daidzein (10− 5 to 10− 6 m) and genistein (10− 5 to 10− 7 m). To assess whether the augmentative action of genistein, coumestrol and daidzein was mediated by an oestrogen-dependent mechanism, we cultured cells with concentrations of phyto-oestrogens shown to enhance mineralisation in the presence or absence of the oestrogen antagonist ICI 182780 (10− 6 m). The antagonist had no effect on mineralisation in control cultures, but prevented the augmentative effect of genistein, daidzein or coumestrol in the presence or absence of Zn (Fig. 4), suggesting that phyto-oestrogens directly enhance osteoblastic mineralisation by an oestrogen receptor-dependent mechanism.

Fig. 3 Zinc augments the effect of phyto-oestrogens on osteoblast mineralisation and differentiation. Saos-2 cells were incubated with coumestrol (10− 5 to 10− 9 m, ), daidzein (10− 5 to 10− 9 m, ) or genistein (10− 9 to 10− 5 m, ) with or without zinc (10− 5 m, ) for 4–18 d. Mineralisation, osteoblast differentiation and proliferation were then assessed using (a) calcein incorporation, (b) alkaline phosphatase (ALP) activity and (c) 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium inner salt (MTS) assays. Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the control group (P < 0·05). † Mean values were significantly different from those of the zinc- or relevant phyto-oestrogen-treated group (P < 0·05).

Fig. 4 The oestrogen antagonist ICI 182780 abolished the augmentative effect of phyto-oestrogens on mineralisation in the presence or absence of zinc. (a) Saos-2 cells were cultured with phyto-oestrogen concentrations shown to promote mineralisation and suppress osteoclast formation coumestrol (10− 7 m, ), daidzein (10− 5 m, ), genistein (10− 7 m, ) with or without ICI 182780 (10− 6 m, ■). (b) Saos-2 cells were cultured with zinc (10− 5 m) plus phyto-oestrogen concentrations shown to promote mineralisation coumestrol (10− 7 m, ), daidzein (10− 5 m, ), genistein (10− 7 m, ) with or without ICI 182780 (10− 6 m, ■). Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from the indicated group (P < 0·05). RFU, related fluorescence ratio.

To determine the cellular mechanism by which Zn and phyto-oestrogens enhanced mineralisation, we examined their effect on osteoblast proliferation and ALP expression. As shown previously, Saos-2 cells constitutively express detectable levels of ALP in the presence of l-AA and β-GP, which was significantly elevated in the presence of Zn for 4 d (Fig. 3(b)). The augmentative action of Zn was further enhanced in the presence of coumestrol (10− 5 to 10− 7 m), daidzein (10− 5 to 10− 9 m) or genistein (10− 5 to 10− 7 m). Peak interactions were noted at 10− 5 m daidzein, 10− 6 m coumestrol and 10− 6 m genistein which induced a significant 1·34-, 1·24- and 1·21-fold increase in ALP activity compared to Zn-treated cultures.

While phyto-oestrogens and Zn clearly enhanced osteoblast differentiation, they had little effect on proliferation. Zn alone had no effect on osteoblast number (Fig. 3(c)). Similarly, coumestrol on its own or in combination with Zn had no proliferative effect although there was a trend towards lower osteoblast number in all groups. Concentrations of daidzein shown to enhance mineralisation also had no effect on proliferation although daidzein 10− 6 and 10− 9 m with or without Zn increased osteoblast number. Genistein (10− 6 to 10− 9 m) induced a modest but significant increase in cell number and Zn increased the effect of the highest genistein concentration examined (10− 5 m).

Zinc blunts the augmentative action of phyto-oestrogens on type I collagen and osteocalcin expression

Bone matrix comprises two major elements, inorganic hydoxyapatite and a range of organic constituents. The organic component consists primarily of type I collagen and several non-collagenous proteins such as osteocalcin. During formation, osteoblasts first secrete organic elements to form osteoid which is subsequently mineralised during maturation. Aberrant osteoid formation or inadequate mineralisation, as occurs in vitamin D associated rickets or osteomalacia, compromises skeletal integrity and can lead to an increased fracture risk. Thus, to assess the effects of compounds on bone quality, both the level of mineralisation and organic constituents has to be considered. We therefore examined the effect of Zn and phyto-oestrogen concentrations shown to augment mineralisation and suppress osteoclast formation on type I collagen and osteocalcin expression. Zn alone had no effect on type I collagen or osteocalcin mRNA expression (Table 1). In contrast, all phyto-oestrogens significantly enhanced type I collagen mRNA expression, a marker that is expressed from progenitor stages of osteoblast differentiation; coumestrol (10− 7 m) stimulated a 12·04-fold increase, daidzein (10− 5 m) a 14·39-fold increase and genistein (10− 7 m) a 7·35-fold increase (Table 1). Phyto-oestrogens also enhanced osteocalcin expression, a marker of mature osteoblast differentiation; coumestrol induced a 2·1-fold increase, daidzein a 16·7-fold increase and genistein a 3·1-fold increase.

Table 1 Zinc blunts the stimulatory effect of phyto-oestrogens on the expression of organic components of bone matrix (Mean values and standard deviations)

* Mean values were significantly different from those of the control group (P < 0·05).

Mean values were significantly different from those of the relevant phyto-oestrogen alone (P < 0·05).

Interestingly, the addition of Zn blunted the stimulatory effect of phyto-oestrogens on type I collagen and osteocalcin expression, although mRNA levels were still significantly above that of control. Thus, in contrast to a positive interaction with phyto-oestrogens on mineralisation, Zn appears to blunt the stimulatory action of phyto-oestrogens on organic components of bone matrix.

Zinc augments the effect of phyto-oestrogens on Runx2 expression but suppresses osterix expression

Osteoblast differentiation is regulated by a network of transcription factors that control gene expression. These include Runx2 and osterix which are expressed in a temporally defined manner. Runx2 expression is elevated during the early stages of osteoblast differentiation, when it promotes the formation of immature osteoblasts from mesenchymal stem cells. Runx2 expression is then down-regulated during the formation of mature osteoblasts(Reference Marie33), whereas osterix expression is restricted to mature osteoblasts(Reference Marie33). To determine the potential molecular mechanism mediating the effect of Zn and phyto-oestrogens on osteoblast differentiation, we examined the effect of phyto-oestrogens and Zn on Runx2 and osterix mRNA expression.

In keeping with their lack of effect on mineralisation, Zn or genistein (10− 7 m) alone had no effect on Runx2 or osterix gene expression (Table 2). Similarly, coumestrol (10− 7 m) and daidzein (10− 5 m) enhanced Runx2 and osterix expression. Interestingly, the addition of Zn had a differential effect on phyto-oestrogen-induced Runx2 and osterix mRNA expression. Phyto-oestrogen-induced Runx2 expression was significantly enhanced by Zn, whereas Zn suppressed the augmentative effect of coumestrol and daidzein on osterix expression.

Table 2 Zinc augments the effect of phyto-oestrogens on Runx2 expression (Mean values and standard deviations)

Runx2, Runt-related transcription factor 2

* Mean values were significantly different from those of the control group (P < 0·05).

Mean values were significantly different from those of the relevant phyto-oestrogen treatment alone (P < 0·05).

Discussion

Bone remodelling, the coupled process of osteoclastic bone resorption and osteoblastic bone formation, generates a skeleton optimised to current mechanical and mineral requirements. During a normal remodelling cycle, bone resorption and formation are balanced such that there is little net bone loss. However, this balance is disrupted in disorders associated with an increased fracture risk such as post-menopausal osteoporosis and osteomyelitis. Numerous studies suggest that dietary factors such as Zn and phyto-oestrogens have a positive impact on bone cell activity(Reference Karieb and Fox18, Reference Poulsen and Kruger34Reference Yamaguchi36); however, the cellular mechanism mediating this action is unclear and few studies have examined the effect of combinations of these factors on osteoclast and osteoblast activity in vitro. Our present study further clarifies the cellular mechanism through which these dietary factors may interact and suggests that appropriate combinations of Zn and phyto-oestrogens may augment mineralisation and further suppress bone resorption. These results strengthen the data for the use of combinations of Zn and phyto-oestrogens in the treatment of skeletal disorders.

Bone resorption is regulated by osteoblast/stromal-derived signals that stimulate osteoclast differentiation from monocytic precursors. Resorptive stimuli such as a fall in circulating calcium increase the expression of osteoblastic RANKL while decreasing OPG expression, a soluble decoy receptor for RANKL(Reference Boyce and Xing32). The subsequent binding of RANKL to its receptor RANK on the surface of non-committed monocytes activates a network of intracellular signals that induce the expression of osteoclastic genes such as TRAP and cathepsin K. In the absence of pro-osteoclastic stimuli, osteoblastic RANKL expression decreases and OPG concentrations rise; OPG then sequesters RANKL and thereby prevents RANK activation and osteoclast differentiation. Elevated RANKL levels and the presence of pro-osteoclastic inflammatory cytokines such as TNF-α are hallmarks of many osteolytic disorders(Reference Nanes37, Reference Somayaji, Ritchie and Sahraei38). At a cellular level, it is therefore possible to suppress osteoclast formation by either directly inhibiting the osteoclast precursor response to cytokine activation or alternatively by an indirect action on osteoblasts to lower RANKL:OPG ratios.

Previous studies suggest that phyto-oestrogens suppress osteoclast formation through both mechanisms. Coumestrol, daidzein and genistein directly inhibit osteoclast formation in response to pro-osteoclastic cytokines in vitro (Reference Karieb and Fox18, Reference Garcia Palacios, Robinson and Borysenko39) and decreased osteoblastic RANKL:OPG ratios have been noted following treatment with a range of phyto-oestrogens(Reference Wu, Wang and Wei22, Reference Chen and Wong40). Genistein and daidzein also reduce osteoblastic expression of other inducers of osteoclast differentiation including IL-6(Reference Chen, Garner and Anderson41). Zn has also been shown to reduce osteoclast formation in vitro (Reference Uchiyama and Yamaguchi28, Reference Holloway, Collier and Herbst42, Reference Yamaguchi and Weitzmann43), whereas Zn deficiency is associated with increased levels of osteoclast formation and bone resorption(Reference Fong, Tan and Tran44). However, the cellular mechanism by which Zn suppresses osteoclast differentiation is unclear, as previous studies have used heterogeneous bone marrow cultures(Reference Uchiyama and Yamaguchi28) or have shown inconsistent osteoclastic responses to changes in Zn status(Reference Fong, Tan and Tran44Reference Windisch, Wher and Rambeck46). Similarly, interactions between Zn and phyto-oestrogens have not been widely investigated.

To help clarify this, we examined the direct effect of Zn on homogeneous RAW264.7 monocytic cultures and the indirect action on osteoblastic RANKL:OPG ratios. We noted no direct effect of Zn on TNF-α-induced osteoclast formation in RAW264.7 cells and Zn also had no effect on the anti-osteoclastic action of coumestrol, daidzein or genistein in these cultures. This differs from results using mouse bone marrow cultures where Zn significantly suppressed parathyroid hormone-induced osteoclast formation and combinations of Zn and genistein decreased RANKL-induced osteoclastogenesis(Reference Uchiyama and Yamaguchi28). The suppressive action noted in these studies may be due to an indirect effect of Zn mediated through stromal cells present in bone marrow cultures which are absent from RAW264.7 cultures. In keeping with this, we noted that Zn alone suppressed osteoblastic RANKL:OPG gene expression ratio and also augmented the suppressive effect of phyto-oestrogens. This assertion is strengthened by the studies of Holloway in which Zn suppressed bone resorption in the presence of added osteoblasts(Reference Holloway, Collier and Herbst42). Thus, Zn-associated changes in osteoclast number are most probably mediated through an indirect action on osteoblasts rather than a direct effect on monocyte differentiation and appropriate concentrations of Zn and coumestrol or genistein may have a more pronounced anti-osteoclastic effect than either alone.

Serum phyto-oestrogen concentrations differ between populations and are dependent on an individual's diet. Asians who typically have a soya-rich diet have significantly higher phyto-oestrogen concentrations compared to Westerners(Reference Morton, Arisaka and Miyake47). The range of phyto-oestrogen concentrations examined in the present study reflects those measured in Asians (10− 6 to 10− 7 m) and Westerners (10− 8 m). The anti-osteoclastic concentrations of genistein and coumestrol seen in this study are similar to those shown previously(Reference Karieb and Fox18) and are in the range of levels measured in Asian populations but higher than those achieved by Western diets(Reference Morton, Arisaka and Miyake47). In contrast, typical Asian and Western diets are unable to generate serum concentrations of daidzein similar to those shown to suppress TNF-α-induced osteoclastogenesis in our studies. However, these concentrations could be achieved with daidzein supplementation which generates tissue levels several orders of magnitude higher than dietary sources(Reference Gardner, Oelrich and Liu48). Serum Zn concentration also varies between populations with diets that lack animal-sourced foods, leading to a high risk of Zn deficiency(Reference Hotz49). The Zn concentration used in our studies is similar to previous in vitro experiments, and is within normal serum reference ranges reflecting those achieved by healthy Western diets(Reference Martín-Lagos, Navarro-Alarcón and Terrés-Martos50, Reference Yamaguchi, Goto and Uchiyama51). Thus, Zn tissue levels of this concentration could augment the anti-osteoclastic effect of coumestrol and genistein, which in turn could limit the excessive resorption associated with post-menopausal osteoporosis and osteomyelitis.

However, antiresorptives such as bisphosphonates only address part of the underlying pathology as they have little effect on the reduction in osteoblast function(Reference Raisz52). Antiresorptives also fail to restore bone that has already been lost and may in the long term lead to atypical fractures, as normal remodelling rates are required to repair micro damage(Reference Shane, Burr and Ebeling53). An ideal therapeutic strategy would therefore rectify defects in both osteoclast and osteoblast activity. Osteoblastic bone formation is a tightly regulated process in which an organic extracellular matrix, consisting primarily of type I collagen and other non-collagenous proteins such as osteocalcin and osteonectin, is initially secreted(Reference Golub54). Non-collagenous proteins may then have a role in controlling the subsequent mineralisation of the matrix regulating the nucleation and appropriate growth of hydroxyapatite crystals within osteoid. We found that Zn enhanced the stimulatory effect of coumestrol, daidzein and genistein on osteoblast mineralisation in vitro. Combinations of coumestrol and Zn and genistein and Zn had the most potent effect (10− 7 m), whereas effects with diaidzein were only noted at 10− 6 m and above.

In contrast to the beneficial action on mineralisation, Zn partly blunted the stimulatory effect of coumestrol, daidzein and genistein on type I collagen and osteocalcin mRNA expression. However, expression levels were still significantly above control, indicating that matrix formation was still enhanced. Thus, appropriate combinations of Zn, coumestrol, daidzein or genistein augment osteoblast function in vitro, enhancing the expression of components of the organic matrix and stimulating mineral deposition.

The augmentative action of Zn would at least in part appear to be due to increased expression of the marker of osteoblast differentiation ALP. Osteoblast-derived matrix vesicles contain high ALP levels and mutations in ALP lead to the genetic disorder hypophosphatasia which is characterised by poorly mineralised bone(Reference Fedde, Blair and Silverstein55). ALP promotes the initial stage of mineralisation by hydrolysing inhibitory pyrophosphate to generate inorganic phosphate needed for the initiation of hydroxyapatite deposition(Reference Golub54). Thus, elevated ALP activity would be expected to enhance mineral formation. In contrast, the augmentative effect of phyto-oestrogens alone would not appear to be mediated through an effect on ALP as levels remained near control. Similarly, although daidzein and genistein stimulated a modest increase in osteoblast number, this was only seen at concentrations other than those shown to enhance mineralisation.

To further examine the mechanism by which phyto-oestrogens and Zn augment osteoblast function, we examined the expression of key intracellular regulators of osteoblast differentiation. Osteoblastogenesis is a sequential process involving multiple transcription factors that stimulate mesenchymal precursors to form immature pre-osteoblasts and ultimately mature osteoblasts(Reference Jensen, Gopalakrishnan and Westendorf56). The initial stage of osteoblastic lineage commitment is controlled by the selective expression of Runx2, which promotes the formation of immature osteoblasts characterised by the production of organic extracellular matrix components including type I collagen and osteocalcin. Homozygous loss of Runx2 is lethal due to the lack of osteoblasts and skeletal elements in mice(Reference Otto, Thornell and Crompton57), whereas heterozygous loss leads to cleidocranial dysplasia in humans and is associated with abnormal osteoblast development in mice(Reference Otto, Thornell and Crompton57, Reference Mundlos, Otto and Mundlos58). With the formation of mature osteoblasts capable of mineralising osteoid, Runx2 expression falls whereas levels of osterix increase(Reference Komori59).

Previous studies have shown that Zn enhances Runx2 expression(Reference Yamaguchi, Goto and Uchiyama51), but to date no study has examined the effect of Zn on osterix expression. We found that anti-osteoclastic concentrations of coumestrol (10− 7 m) and daidzein (10− 5 m) significantly enhanced Runx2 expression and Zn significantly augmented Runx2 in the presence of all phyto-oestrogens. On the other hand, Zn blunted the stimulatory action of coumestrol and daidzein on osterix expression. Therefore, Zn appears to promote the expression of a transcription factor profile typical of early mature osteoblast with high Runx2 and low osterix levels. This profile is likely to explain the observed changes in organic matrix protein expression. The studies of Liu et al. (Reference Liu, Toyosawa and Furuichi60) showed that Runx2 maintains osteoblasts in an immature state, with transgenic Runx2 expression suppressing type I collagen and osteocalcin production and preventing the formation of mature osteoblasts. Osteocalcin levels are comparatively low in pre-osteoblasts when Runx2 expression peaks, and osteocalcin levels subsequently rise as Runx2 expression decreases in mature osteoblasts. Thus, the blunting of type I collagen and osteocalcin expression is in keeping with Zn promoting the formation of early rather than late stages of mature osteoblast differentiation.

Our data show that Zn augments the indirect anti-osteoclastic action of coumestrol and genistein at concentrations typically generated by soya-rich diets. Interactions between Zn and anti-osteoclastic phyto-oestrogen concentrations were also noted for osteoblast differentiation and function. Appropriate combinations of Zn and phyto-oestrogens increased ALP activity, extracellular matrix expression and mineralisation. This effect may be due to Zn inducing the formation of an early mature stage of osteoblast differentiation. These results strengthen data for the use of combinations of Zn and phyto-oestrogens in the treatment of skeletal disorders.

Acknowledgements

The authors report no conflict of interest. Both authors contributed to the experimental design, laboratory work, data analysis and manuscript preparation. This work was supported by an Iraqi government PhD studentship.

References

1Martin, TJ & Seeman, E (2008) Bone remodelling: its local regulation and the emergence of bone fragility. Best Pract Res Clin Endocrinol Metab 22, 701722.CrossRefGoogle ScholarPubMed
2Henriksen, K, Neutzsky-Wulff, AV, Bonewald, LF, et al. (2009) Local communication on and within bone controls bone remodeling. Bone 44, 10261033.CrossRefGoogle ScholarPubMed
3Nair, SP, Meghji, S, Wilson, M, et al. (1996) Bacterially induced bone destruction: mechanisms and misconceptions. Infect Immun 64, 23712380.Google Scholar
4Manolagas, SC, Kousteni, S & Jilka, RL (2002) Sex steroids and bone. Recent Prog Horm Res 57, 385409.Google Scholar
5Writing Group for the Women's Health Initiative Investigators (2002) Risks and benefits of estrogen plus progestin in healthy postmenopausal women. JAMA 288, 321333.Google Scholar
6Chow, J, Tobias, JH, Colston, KW, et al. (1992) Estrogen maintains trabecular bone volume in rats not only by suppression of bone resorption but also by stimulation of bone formation. J Clin Invest 89, 7478.Google Scholar
7Khastgir, G, Studd, JW, Fox, SW, et al. (2003) A longitudinal study of the effect of subcutaneous estrogen replacement on bone in young women with Turner's syndrome. J Bone Miner Res 18, 925932.Google Scholar
8Horiuchi, T, Onouchi, T, Takahashi, M, et al. (2000) Effect of soy protein on bone metabolism in postmenopausal Japanese women. Osteoporos Int 11, 721724.Google Scholar
9Mei, J, Yeung, SSC & Kung, AWC (2001) High dietary phytoestrogen intake is associated with higher bone mineral density in postmenopausal but not premenopausal women. J Clin Endocrinol Metab 86, 52175221.Google Scholar
10Kim, MK, Chung, BC, Yu, VY, et al. (2002) Relationships of urinary phyto-oestrogen excretion to BMD in postmenopausal women. Clin Endocrinol 56, 321328.Google Scholar
11Alekel, DL, Germain, AS, Peterson, CT, et al. (2000) Isoflavone-rich soy protein isolate attenuates bone loss in the lumbar spine of perimenopausal women. Am J Clin Nutr 72, 844852.CrossRefGoogle ScholarPubMed
12Morabito, N, Crisafulli, A, Vergara, C, et al. (2002) Effects of genistein and hormone-replacement therapy on bone loss in early postmenopausal women: a randomized double-blind placebo-controlled study. J Bone Miner Res 17, 19041912.CrossRefGoogle Scholar
13Atkinson, C, Compston, JE, Day, NE, et al. (2004) The effects of phytoestrogen isoflavones on bone density in women: a double-blind, randomized, placebo-controlled trial. Am J Clin Nutr 79, 326333.Google Scholar
14Wu, J, Oka, J, Tabata, I, et al. (2006) Effects of isoflavone and exercise on BMD and fat mass in postmenopausal Japanese women: a 1-year randomized placebo-controlled trial. J Bone Miner Res 21, 780789.Google Scholar
15Ricci, E, Cipriani, S, Chiaffarino, F, et al. (2010) Soy isoflavones and bone mineral density in perimenopausal and postmenopausal western women: a systematic review and meta-analysis of randomized controlled trials. J Womens Health 19, 16091617.CrossRefGoogle ScholarPubMed
16Weaver, CM, Martin, BR, Jackson, GS, et al. (2009) Antiresorptive effects of phytoestrogen supplements compared with estradiol or risedronate in postmenopausal women using 41Ca methodology. J Clin Endocrinol Metab 94, 37983805.CrossRefGoogle ScholarPubMed
17Gao, YH & Yamouguchi, M (1999) Inhibitory effect of genistein on osteoclast-like cell formation in mouse marrow cultures. Biochem Pharmacol 58, 767772.CrossRefGoogle ScholarPubMed
18Karieb, S & Fox, SW (2011) Phytoestrogens directly inhibit TNF-alpha-induced bone resorption in RAW264.7 cells by suppressing c-fos-induced NFATc1 expression. J Cell Biochem 112, 476487.Google Scholar
19Roudsari, AZ, Tahbaz, F, Hossein-Nezhad, A, et al. (2005) Assessment of soy phytoestrogens' effects on bone turnover indicators in menopausal women with osteopenia in Iran: a before and after clinical trial. Nutr J 4, 3035.Google Scholar
20Dai, R, Ma, Y, Sheng, Z, et al. (2008) Effects of genistein on vertebral trabecular bone microstructure, bone mineral density, microcracks, osteocyte density, and bone strength in ovariectomized rats. J Bone Miner Metab 26, 342349.Google Scholar
21Kanno, S, Hirano, S & Kayama, F (2004) Effects of phytoestrogens and environmental estrogens on osteoblastic differentiation in MC3T3-E1 cells. Toxicology 196, 137145.Google Scholar
22Wu, X-T, Wang, B & Wei, J-N (2009) Coumestrol promotes proliferation and osteoblastic differentiation in rat bone marrow stromal cells. J Biomed Mater Res B Appl Biomater 90, 621628.Google Scholar
23Yadav, DK, Gautam, AK, Kureel, J, et al. (2011) Synthetic analogs of daidzein, having more potent osteoblast stimulating effect. Bioorg Med Chem Lett 21, 677681.Google Scholar
24Kwun, I-S, Cho, Y-E, Lomeda, RA, et al. (2010) Zinc deficiency suppresses matrix mineralization and retards osteogenesis transiently with catch-up possibly through Runx 2 modulation. Bone 46, 732741.Google Scholar
25Hyun, TH, Barrett-Connor, E & Milne, DB (2004) Zinc intakes and plasma concentrations in men with osteoporosis: the Rancho Bernardo Study. Am J Clin Nutr 80, 715721.Google Scholar
26Seco, C, Revilla, M, Hernández, ER, et al. (1998) Effects of zinc supplementation on vertebral and femoral bone mass in rats on strenuous treadmill training exercise. J Bone Miner Res 13, 508512.Google Scholar
27Yamaguchi, M & Uchiyama, S (2004) Receptor activator of NF-κB ligand-stimulated osteoclastogenesis in mouse marrow culture is suppressed by zinc in vitro. Int J Mol Med 14, 8185.Google Scholar
28Uchiyama, S & Yamaguchi, M (2007) Genistein and zinc synergistically stimulate apoptotic cell death and suppress RANKL signaling-related gene expression in osteoclastic cells. J Cell Biochem 101, 529542.Google Scholar
29Sabokbar, A, Millett, PJ, Myer, B, et al. (1994) A rapid, quantitative assay for measuring alkaline phosphatase activity in osteoblastic cells in vitro. Bone Miner 27, 5767.Google Scholar
30Hale, LV, Ma, YF & Santerre, RF (2000) Semi-quantitative fluorescence analysis of calcein binding as a measurement of in-vitro mineralization. Calcif Tissue Int 67, 8084.CrossRefGoogle ScholarPubMed
31Burstone, MS (1958) Histochemical demonstration of acid phosphatases with naphthol AS-phosphates. J Natl Cancer Inst 21, 523539.Google Scholar
32Boyce, BF & Xing, L (2008) Functions of RANKL/RANK/OPG in bone modeling and remodeling. Arch Biochem Biophys 473, 139146.Google Scholar
33Marie, PJ (2008) Transcription factors controlling osteoblastogenesis. Arch Biochem Biophys 473, 98105.CrossRefGoogle ScholarPubMed
34Poulsen, RC & Kruger, MC (2008) Soy phytoestrogens: impact on postmenopausal bone loss and mechanisms of action. Nutr Rev 66, 359374.Google Scholar
35Seo, HJ, Cho, YE, Kim, T, et al. (2010) Zinc may increase bone formation through stimulating cell proliferation, alkaline phosphatase activity and collagen synthesis in osteoblastic MC3T3-E1 cells. Nutr Res Pract 4, 356361.Google Scholar
36Yamaguchi, M (2010) Role of nutritional zinc in the prevention of osteoporosis. Mol Cell Biochem 338, 241254.Google Scholar
37Nanes, MS (2003) Tumour necrosis factor-alpha: molecular and cellular mechanisms in skeletal pathology. Gene 321, 115.CrossRefGoogle ScholarPubMed
38Somayaji, SN, Ritchie, S, Sahraei, M, et al. (2008) Staphylococcus aureus induces expression of receptor activator of NF-{kappa}B ligand and prostaglandin E2 in infected murine osteoblasts. Infect Immun 76, 51205126.Google Scholar
39Garcia Palacios, V, Robinson, LJ, Borysenko, CW, et al. (2005) Negative regulation of RANKL-induced osteoclastic differentiation in RAW264.7 cells by estrogen and phytoestrogens. J Biol Chem 280, 1372013727.CrossRefGoogle ScholarPubMed
40Chen, WF & Wong, MS (2006) Genistein modulates the effects of parathyroid hormone in human osteoblastic SaOS-2 cells. Br J Nutr 95, 10391047.Google Scholar
41Chen, XW, Garner, SC & Anderson, JJB (2002) Isoflavones regulate interleukin-6 and osteoprotegerin synthesis during osteoblast cell differentiation via an estrogen-receptor-dependent pathway. Biochem Biophys Res Commun 295, 417422.Google Scholar
42Holloway, WR, Collier, FM, Herbst, RE, et al. (1996) Osteoblast-mediated effects of zinc on isolated rat osteoclasts: inhibition of bone resorption and enhancement of osteoclast number. Bone 19, 137142.Google Scholar
43Yamaguchi, M & Weitzmann, MN (2011) Zinc stimulates osteoblastogenesis and suppresses osteoclastogenesis by antagonizing NF-κB activation. Mol Cell Biochem 355, 179186.Google Scholar
44Fong, L, Tan, K, Tran, C, et al. (2009) Interaction of dietary zinc and intracellular binding protein metallothionein in postnatal bone growth. Bone 44, 11511162.Google Scholar
45Eberle, J, Schmidmayer, S, Erben, RG, et al. (1999) Skeletal effects of zinc deficiency in growing rats. J Trace Elem Med Biol 13, 2126.CrossRefGoogle ScholarPubMed
46Windisch, W, Wher, U, Rambeck, W, et al. (2002) Effect of Zn deficiency and subsequent Zn repletion on bone mineral composition and markers of bone tissue metabolism in 65Zn-labelled, young-adult rats. J Anim Phys Anim Nutr 86, 214221.Google Scholar
47Morton, MS, Arisaka, O, Miyake, N, et al. (2002) Phytoestrogen concentrations in serum from Japanese men and women over forty years of age. J Nutr 132, 31683171.Google Scholar
48Gardner, CD, Oelrich, B, Liu, JP, et al. (2009) Prostatic soy isoflavone concentrations exceed serum levels after dietary supplementation. Prostate 69, 719726.CrossRefGoogle ScholarPubMed
49Hotz, C (2007) Dietary indicators for assessing the adaquacy of poulation zinc intakes. Food Nutr Bull 28, S430S453.Google Scholar
50Martín-Lagos, F, Navarro-Alarcón, M, Terrés-Martos, C, et al. (1998) Serum zinc levels in healthy subjects from southeastern Spain. Biol Trace Elem Res 61, 5160.Google Scholar
51Yamaguchi, M, Goto, M, Uchiyama, S, et al. (2008) Effect of zinc on gene expression in osteoblastic MC3T3-E1 cells: enhancement of Runx2, OPG, and regucalcin mRNA expressions. Mol Cell Biochem 312, 157166.Google Scholar
52Raisz, LG (2005) Pathogenesis of osteoporosis: concepts, conflicts, and prospects. J Clin Invest 115, 33183325.Google Scholar
53Shane, E, Burr, D, Ebeling, PR, et al. (2010) Atypical subtrochanteric and diaphyseal femoral fractures: report of a task force of the american society for bone and mineral research. J Bone Miner Res 25, 22672294.Google Scholar
54Golub, EE (2009) Role of matrix vesicles in biomineralization. Biochim Biophys Acta 1790, 15921598.Google Scholar
55Fedde, KN, Blair, L, Silverstein, J, et al. (1999) Alkaline phosphatase knock-out mice recapitulate the metabolic and skeletal defects of infantile hypophosphatasia. J Bone Miner Res 14, 20152026.Google Scholar
56Jensen, ED, Gopalakrishnan, R & Westendorf, JJ (2010) Regulation of gene expression in osteoblasts. BioFactors 36, 2532.CrossRefGoogle ScholarPubMed
57Otto, F, Thornell, AP, Crompton, T, et al. (1997) Cbfa1, a candidate gene for cleidocranial dysplasia syndrome, is essential for osteoblast differentiation and bone development. Cell 89, 765771.Google Scholar
58Mundlos, S, Otto, F, Mundlos, C, et al. (1997) Mutations involving the transcription factor CBFA1 cause cleidocranial dysplasia. Cell 89, 773779.Google Scholar
59Komori, T (2010) Regulation of bone development and extracellular matrix protein genes by RUNX2. Cell Tissue Res 339, 189195.Google Scholar
60Liu, W, Toyosawa, S, Furuichi, T, et al. (2001) Overexpression of Cbfa1 in osteoblasts inhibits osteoblast maturation and causes osteopenia with multiple fractures. J Cell Biol 155, 157166.Google Scholar
Figure 0

Fig. 1 Zinc has no effect on the direct anti-osteoclastic action of phyto-oestrogens. RAW264.7 cells were incubated in the presence of TNF-α (50 ng/ml) for 4–8 d plus coumestrol (10− 5 to 10− 9 m, ), daidzein (10− 5 to 10− 9 m, ) or genistein (10− 9 to 10− 5 m, ) in the presence or absence of zinc (10− 5 m, ). Osteoclast formation was assessed by tartrate-resistant acid phosphatase (TRAP) staining and bone resorption was determined by the percentage of bone surface displaying resorption pits analysed by reflected light microscopy. Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the TNF-α-treated group (P < 0·05).

Figure 1

Fig. 2 Phyto-oestrogens and zinc suppress the osteoblast-derived stimulus for osteoclast formation. Human osteoblast-like Saos-2 cells were incubated with zinc plus coumestrol (10− 7 m, ), daidzein (10− 5 m, ) or genistein (10− 7 m, ) in the presence or absence of zinc (10− 5 m, ). Total RNA was extracted and the expression of receptor activator of NF-κB ligand (RANKL) and osteoprotegerin (OPG) quantified by real-time PCR. Data were normalised to β-actin and expressed as a ratio of RANKL-to-OPG expression in comparison to control. Values are means of two separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the control group (P < 0·05). † Mean values were significantly different from those of the zinc- or relevant phyto-oestrogen-treated group alone (P < 0·05).

Figure 2

Fig. 3 Zinc augments the effect of phyto-oestrogens on osteoblast mineralisation and differentiation. Saos-2 cells were incubated with coumestrol (10− 5 to 10− 9 m, ), daidzein (10− 5 to 10− 9 m, ) or genistein (10− 9 to 10− 5 m, ) with or without zinc (10− 5 m, ) for 4–18 d. Mineralisation, osteoblast differentiation and proliferation were then assessed using (a) calcein incorporation, (b) alkaline phosphatase (ALP) activity and (c) 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium inner salt (MTS) assays. Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from those of the control group (P < 0·05). † Mean values were significantly different from those of the zinc- or relevant phyto-oestrogen-treated group (P < 0·05).

Figure 3

Fig. 4 The oestrogen antagonist ICI 182780 abolished the augmentative effect of phyto-oestrogens on mineralisation in the presence or absence of zinc. (a) Saos-2 cells were cultured with phyto-oestrogen concentrations shown to promote mineralisation and suppress osteoclast formation coumestrol (10− 7 m, ), daidzein (10− 5 m, ), genistein (10− 7 m, ) with or without ICI 182780 (10− 6 m, ■). (b) Saos-2 cells were cultured with zinc (10− 5 m) plus phyto-oestrogen concentrations shown to promote mineralisation coumestrol (10− 7 m, ), daidzein (10− 5 m, ), genistein (10− 7 m, ) with or without ICI 182780 (10− 6 m, ■). Values are means of three separate experiments, with their standard errors represented by vertical bars. Differences between groups were assessed by one-way ANOVA. * Mean values were significantly different from the indicated group (P < 0·05). RFU, related fluorescence ratio.

Figure 4

Table 1 Zinc blunts the stimulatory effect of phyto-oestrogens on the expression of organic components of bone matrix (Mean values and standard deviations)

Figure 5

Table 2 Zinc augments the effect of phyto-oestrogens on Runx2 expression (Mean values and standard deviations)