Androgens and bone

Testosterone is the major gonadal sex steroid produced by the testes in men. Testosterone is also produced in smaller amounts by the ovaries in women. The adrenal glands produce the weaker androgens dehydroepiandrosterone, dehydroepiandrosterone sulfate, and androstenedione. These androgens collectively affect skeletal homeostasis throughout life in both men and women, particularly at puberty and during adult life. Because testosterone can be metabolized to estradiol by the aromatase enzyme, there has been controversy as to which gonadal sex steroid has the greater skeletal effect. The current evidence suggests that estradiol plays a greater role in maintenance of skeletal health than testosterone, but that androgens also have direct beneficial effects on bone. Supraphysiological levels of testosterone likely have similar effects on bone as lower levels via direct interaction with androgen receptors, as well as effects mediated by estrogen receptors after aromatization to estradiol. Whether high doses of synthetic, non-aromatizable androgens may, in fact, be detrimental to bone due to suppression of endogenous testosterone (and estrogen) levels is a potential concern that warrants further study.     

Pros and cons of existing treatment modalities in osteoporosis: a comparison between tibolone,SERMs and estrogen (+/-progestogen) treatments

Tibolone, selective estrogen receptor modulators (SERMs) like tamoxifen and raloxifene, and estrogen (±progestogen) treatments prevent bone loss in postmenopausal women. They exert their effects on bone via the estrogen receptor (ER) and the increase in bone mass is due to resorption inhibition. The effect of SERMs on bone mineral density is less than that with the other treatments, but the SERM raloxifene still has a positive effect on vertebral fractures. In contrast to tibolone and estrogens (±progestogen), SERMs do not treat climacteric complaints, whilst estrogen plus progestogen treatments cause a high incidence of bleeding. Estrogen plus progestogen combinations have compromising effects on the breast. Tibolone and SERMs do not stimulate the breast or endometrium. Unlike SERMs, tibolone does not posses antagonistic biological effects via the ER in these tissues. Estrogenic stimulation in these tissues is prevented by local metabolism and inhibition of steroid metabolizing enzymes by tibolone and its metabolites. SERMs and estrogen (±progestogen) treatments increase the risk of venous thromboembolism (VTE), whilst estrogen (±progestogen) combinations have unwanted effects on cardiovascular events. So far, no detrimental effects of tibolone have been observed with respect to VTE or cardiovascular events. The clinical profile of tibolone therefore has advantages over those of other treatment modalities. It is also clear that tibolone is a unique compound with a specific mode of action and that it belongs to a separate class of compounds that can best be described as selective, tissue estrogenic activity regulators (STEARs).     

Mechanisms of sex steroid effects on bone

Sex steroids play a major role in the regulation of bone turnover. Thus, gonadectomy in either sex is associated with an increase in bone remodeling, increased bone resorption, and a relative deficit in bone formation, resulting in accelerated bone loss. Recent physiological studies have established an important role for estrogen in regulating bone turnover not only in females, but also in males. Studies in mice with knock out of the estrogen receptor, aromatase, or androgen receptor have provided important insights into the in vivo mechanisms of sex steroid action on bone. The cellular and molecular mediators of sex steroid effects on the bone-forming osteoblasts and bone-resorbing osteoclasts are also being increasingly better defined. Estrogen inhibits bone remodeling by concurrently suppressing osteoblastogenesis and osteoclastogenesis from marrow precursors. Both estrogen and androgens inhibit bone resorption via effects on the receptor activator of NF-kappaB ligand (RANKL)/RANK/osteoprotegerin system, as well as by reducing the production of a number of pro-resorptive cytokines, along with direct effects on osteoclast activity and lifespan. Sex steroid effects on bone formation are also likely mediated by multiple mechanisms, including a prolongation of osteoblast lifespan via non-genotropic mechanisms, as well as effects on osteoblast differentiation and function. These pleiotropic actions of sex steroids on virtually all aspects of bone metabolism belie the importance of the skeleton not only in providing structural support for the body and in locomotion, but also as a dynamic tissue responsive, among other things, to the reproductive needs of the organism for calcium.     

Expression of the estrogen receptor during differentiation of human osteoclasts

Estrogens play a key role in bone structural integrity, which is maintained by the opposing activity of bone forming osteoblasts and bone resorbing osteoclasts. The cellular effects of estrogens are mediated by estrogen receptors, however, the detailed molecular mechanism of ER regulation in osteoclasts has not yet been elucidated. We provide here a detailed analysis of the expression profile and functionality of ER during osteoclast differentiation. We employed a human primary osteoclast cell culture model to evaluate the regulation of estrogen receptor (ER) variant expression. We characterized the expression profile of estrogen receptors and studied the regulation of the predominant estrogen receptor-alpha (ER-alpha) during differentiation into osteoclasts. In addition to the full-length ER-alpha, a shorter ER-alpha mRNA variant is expressed and both ER-alpha variants are regulated during osteoclastogenesis. Furthermore, we show that the pS2 gene is an estrogen-regulated gene in osteoclasts. Analysis of the activity of the pS2 gene throughout differentiation, using chromatin immunoprecipitation (ChIP), revealed the functionality of ER-alpha during differentiation and shows that the occupancy of ER-alpha and activated polymerase II on the pS2 promoter decrease with time and can be blocked by the ER antagonist ICI 182780. These results help to dissect the molecular events relevant to estrogen signaling and provide a better understanding of the role of ER-alpha regulation during bone resorption mediated by osteoclasts.     

Isoflavones and bone: animal and human evidence of efficacy

Previous reports of soy extracts and isoflavone-enriched preparations studied in animals and humans have found that these molecules, when given at appropriate doses, have positive effects on the skeleton, including improvements in bone mineral content (BMC) and bone mineral density (BMD). A reduction in fracture risk of human subjects has not yet been shown in a prospective trial. Isoflavones, which exist in significant amounts only in soybeans, exert estrogen-like effects in human bone cells because of their unique organic structures that are similar to that of estradiol. The discovery of the b isoform of the estrogen receptor (ER) suggests that the molecular regulation of bone remodeling by estrogens, or estrogen-like molecules, including isoflavones, is more complex than previously thought. Depending on the type of ER present in a particular tissue, isoflavones may act as weak estrogen agonists or as weak estrogen antagonists. For example, isoflavones act as weak estrogen agonists in osteoblasts, but in reproductive cells, such as in the breast and uterus, they behave as weak estrogen antagonists. Weak agonistic effects of the isoflavones include stimulation of osteoblast proliferation and differentiation and increasing the production of cytokines that may inhibit osteclastic activity. The selective beneficial effects of estrogen-like molecules in bone tissues, compared to the anti-estrogenic effects in cells of reproductive tissues, make isoflavones attractive for the promotion of bone health. Relatively greater values of BMC and BMD of Asian populations with high consumption of soy isoflavones throughout life, compared to those with lower intakes, indirectly support the skeletal benefits of this pattern of intake of these estrogen-like molecules.     

Resveratrol prevents RANKL-induced osteoclast differentiation of murine osteoclast progenitor RAW 264.7 cells through inhibition of ROS production

The bone protective effects of resveratrol have been demonstrated in several osteoporosis models while the underlying mechanism is largely unclear. In the present study, we evaluated the effects of resveratrol on differentiation and apoptosis of murine osteoclast progenitor RAW 264.7 cells. We found that resveratrol at non-toxic concentrations dose-dependently inhibited RANKL-induced osteoclast differentiation and induced apoptosis. Resveratrol has been shown to be an activator of Sirt1, a NAD⁺ dependent protein deacetylase, and has been demonstrated to mimic estrogen. However, we found that although Sirt1 protein was abundantly expressed in RAW264.7 cells, the specific Sirt1 inhibitor EX-527 could not attenuate the inhibition of osteoclastogenesis mediated by resveratrol. Also, the effects of resveratrol could not be attenuated by ICI-182780, a high affinity estrogen receptor antagonist. The central role of reactive oxygen species (ROS) in RANKL-induced osteoclast differentiation has recently been clarified. We found that resveratrol suppressed RANKL-induced ROS generation in a concentration dependent manner. We postulate that the direct inhibitory effects of resveratrol on osteoclastogenesis are mediated via inhibition of ROS generation.     

Pharmacological Estrogen Administration Causes a FSH-Independent Osteo-Anabolic Effect Requiring ER Alpha in Osteoblasts

Postmenopausal osteoporosis is characterized by declining estrogen levels, and estrogen replacement therapy has been proven beneficial for preventing bone loss in affected women. While the physiological functions of estrogen in bone, primarily the inhibition of bone resorption, have been studied extensively, the effects of pharmacological estrogen administration are still poorly characterized. Since elevated levels of follicle-stimulating hormone (FSH) have been suggested to be involved in postmenopausal bone loss, we investigated whether the skeletal response to pharmacological estrogen administration is mediated in a FSH-dependent manner. Therefore, we treated wildtype and FSHβ-deficicent (Fshb^−/−) mice with estrogen for 4 weeks and subsequently analyzed their skeletal phenotype. Here we observed that estrogen treatment resulted in a significant increase of trabecular and cortical bone mass in both, wildtype and Fshb^−/− mice. Unexpectedly, this FSH-independent pharmacological effect of estrogen was not caused by influencing bone resorption, but primarily by increasing bone formation. To understand the cellular and molecular nature of this osteo-anabolic effect we next administered estrogen to mouse models carrying cell specific mutant alleles of the estrogen receptor alpha (ERα). Here we found that the response to pharmacological estrogen administration was not affected by ERα inactivation in osteoclasts, while it was blunted in mice lacking the ERα in osteoblasts or in mice carrying a mutant ERα incapable of DNA binding. Taken together, our findings reveal a previously unknown osteo-anabolic effect of pharmacological estrogen administration, which is independent of FSH and requires DNA-binding of ERα in osteoblasts.     

Interleukin-6 deficient mice are protected from bone loss caused by estrogen depletion.

Interleukin-6 (IL-6) is a multifunctional cytokine whose circulating levels are under physiological conditions below detection, but whose production is rapidly and strongly induced by several pathological and inflammatory stimuli. IL-6 has been implicated in a number of cell functions connected to immunity and hematopoiesis. Recently, it has been proposed to act as a stimulator of osteoclast formation and activity, in particular following estrogen depletion. The purpose of this study was to gain additional insights into the role of IL-6 during development, as well as in physiological and pathological conditions. We report here that IL-6 deficient mice generated by gene targeting are viable and do not present any evident phenotypic abnormality. However, analysis of bone metabolism revealed a specific bone phenotype. IL-6 deficient female mice have a normal amount of trabecular bone, but higher rates of bone turnover than control littermates. Estrogen deficiency induced by ovariectomy causes in wild type animals a significant loss of bone mass together with an increase in bone turnover rates. Strikingly, ovariectomy does not induce any change in either bone mass or bone remodeling rates in the IL-6 deficient mice. These findings indicate that IL-6 plays an important role in the local regulation of bone turnover and, at least in mice, appears to be essential for the bone loss caused by estrogen deficiency.     

Osteocyte biology: its implications for osteoporosis

Osteocyte viability may play a significant role in the maintenance and integrity of bone. Bone loss due to osteoporosis may be due in part to osteocyte cell death. We have identified a factor that will protect both osteoblasts and osteocytes from cell death due to agents known to be responsible for various forms of osteoporosis. Not only does estrogen preserve osteoblast and osteocyte viability, but so does a molecule called CD40Ligand. This molecule is expressed on activated T lymphocytes, human dendritic cells, and human vascular endothelial cells, whereas its receptor CD40 is expressed on normal epithelium, B cells, and dendritic cells. CD40Ligand protects osteoblasts and the MLO-Y4 osteocyte-like cells against apoptosis induced by glucocorticoids, tumor necrosis factor alpha or etoposide. As tumor necrosis factor a has been shown to be responsible for post-menopausal bone loss and glucocorticoids induce dramatic bone loss, this finding has important implications with regards to potential therapy for both post-menopausal and steroid-induced osteoporosis.     

Common mechanism for the estrogen agonist and antagonist activities of droloxifene

The incidence of postmenopausal osteoporosis is increasing as the population ages. Even though estrogen replacement therapy has proven beneficial in reducing the number of skeletal fractures, the known risks and associated side-effects of estrogen replacement therapy make compliance poor. Recent research has focused on the development of tissue specific estrogen agonist/anatagonists such as droloxifene which can prevent estrogen deficiency-induced bone loss without causing uterine hypertrophy. Furthermore, droloxifene acts as a full estrogen antagonist on breast tissue and is being evaluated for treatment of advanced breast cancer. In this report we propose a common mechanism of action for droloxifene that underlies its estrogen agonist and antagonist effects in different tissues. Droloxifene and estrogen, which have identical effects on bone in vivo, both induced p53 expression and apoptosis in cells of in vitro rat bone marrow cultures resulting in a decrease in the number of bone-resorbing osteoclasts. Droloxifene is growth inhibitory in MCF-7 human breast cancer cells and therefore acts as an antagonist, whereas estrogen is mitogenic to these cells and acts as an agonist. Droloxifene, but not estrogen, induced p53 expression and apoptosis in MCF-7 cells. These results indicate that the induction of apoptosis by droloxifene may be the common mechanism for both its estrogen agonist effects in bone and its antagonist effects in breast tissue. J. Cell. Biochem. 65:159–171. © 1997 Wiley-Liss, Inc.     

Recent advances in the genetics of osteoporosis

It has been known for over 20 years that osteoporosis is highly influenced by genetic factors. Bone mineral density (BMD) has also been shown to be highly heritable. Other known risk factors for osteoporotic fractures such as reduced bone quality, femoral neck geometry and bone turnover are now also known to be heritable. Susceptibility to osteoporosis is mediated, in all likelihood, by multiple genes each having small effect. Different approaches are being used currently to identify the many genes responsible. These include linkage studies in man and experimental animals as well as candidate gene studies and alterations in gene expression. Linkage studies have identified multiple quantitative trait loci (QTL) for regulation of BMD and, with twin studies, have indicated that the effects of these loci are partly site-dependent and sex-specific. On the whole, the genes responsible for BMD regulation at these QTL have not yet been isolated. Most studies have used the candidate gene approach. The vitamin D receptor gene (VDR), the collagen type I alpha 1 gene (COLIA1) and estrogen receptor gene (ER) alpha have been most widely investigated and found to play a role in regulating BMD, but the effects are modest and together probably account for less than 5% of the heritable contribution to BMD. Genes may vary in their influence of particular intermediate phenotypes, and we now know that not all genes influencing BMD will be important in fracture. In addition, the study of other diseases such as osteoarthritis and metabolic bone syndromes may prove fruitful in highlighting genes which overlap to osteoporosis as well. As large scale genetic testing becomes more cost-effective, recent findings have illustrated the potential of novel approaches. These include combining large multi-national populations for candidate gene analysis, meta-analyses, DNA pooling studies and gene expression studies.     

Estrogen stimulates differentiation of megakaryocytes and modulates their expression of estrogen receptors alpha and beta

Estrogen has multifunctional effects influencing growth, differentiation, and function in many tissues. High-dose estrogen has been shown to produce anabolic skeletal effects in the skeleton of postmenopausal women with increased megakaryocyte (MK) population in the bone marrow, suggesting a possible role for these cells in bone remodelling. To investigate if estrogen stimulates megakaryocytopoiesis and affects on estrogen receptor (ER) expression, CD34(+) cells were cultured for 6, 9, and 14 days plus or minus low-dose or high-dose 17 beta estradiol (E). Cells were immunolocalised for CD61, CD41, ER alpha and beta. ER mRNA expression was assessed by RT-PCR. Cells formed more CD61 positive MK colonies with low- and high-dose E treatment (P < 0.001) at 6 and 9 days. CD41 expression was increased dose-dependently in MK (3- and 5-fold P < 0.001) at 9 days. E-stimulated ER alpha expression at 6 days (P < 0.001) whilst ER beta was dose-dependently increased only at 9 days (P < 0.01). ER alpha mRNA was increased at 6 days but not at 14 days whilst ER beta mRNA expression was only increased at 14 days with E treatment. These results demonstrate that E stimulates the colony forming potential of CD34(+) cells to a more megakaryocytic phenotype in vitro. This finding together with the stimulation of ER protein and mRNA expression adds to the increasing evidence for a role for MKs in estrogen-induced bone formation.     

Regulation of estrogen synthesis in postmenopausal women

The decrease in ovarian estrogen production that occurs at the menopause may lead to an increase in peripheral aromatase activity. While estrogens can have beneficial effects on some body tissues, such as bone and the cardiovascular system, they also have a crucial role in supporting the growth and development of breast tumors. A number of factors, including interleukin-6 (IL-6), tumor necrosis factor alpha (TNFalpha), and prostaglandin E(2) (PGE(2)), which can stimulate aromatase activity, have now been identified. As plasma concentrations of some cytokines increase at the menopause, this may account for the increased peripheral aromatase activity that is detected in older women. Macrophages and lymphocytes which infiltrate breast tissue are now thought to be an important source of cytokines that can stimulate aromatase activity in this tissue. Studies, we have recently carried out, have suggested that the endogenous estrogen metabolite, 2-methoxy-estradiol, may be able to modulate the ability of cytokines and PGE(2) to stimulate aromatase activity. Understanding the role of endogenous estrogen metabolites in regulating estrogen synthesis may give rise to new strategies for the prevention or treatment of breast cancer.     

Selective estrogen receptor modulators to prevent treatment-related osteoporosis

The intended therapeutic effect of gonadotropin-releasing hormone (GnRH) agonists is hypogonadism, which is a leading cause of osteoporosis in men. Consistent with this observation, GnRH agonists decrease bone mineral density and increase fracture risk in men with prostate cancer. GnRH agonists markedly decrease serum levels of both testosterone and estrogen. Estrogens play a central role in homeostasis of the normal male skeleton, and the available evidence suggests that estrogen deficiency rather than testosterone deficiency accounts for the adverse skeletal effects of GnRH agonists. The central role of estrogens in male bone metabolism provides a strong rationale to evaluate selective estrogen receptor modulators for prevention of treatment-related osteoporosis in men with prostate cancer. Preliminary evidence suggests that both raloxifene and toremifene increase bone mineral density in GnRH agonist-treated men. An ongoing pivotal study will evaluate the effects of toremifene on fractures and other complications of GnRH agonists in men with prostate cancer.     

An estrogen receptor basis for raloxifene action in boneProceedings of Xth International Congress on Hormonal Steroids, Quebec, Canada, 17–21 June 1998.

Although controversy remains regarding direct effects of estrogen on bone, in vivo data clearly show that estrogens suppress bone turnover, resulting in decreased bone resorption and formation activity. Selective estrogen receptor modulators (SERMs), such as raloxifene, produce effects on bone which are very similar to those of estrogen. In vitro, both raloxifene and estrogen inhibit mammalian osteoclast differentiation and bone resorption activity, but only in the presence of IL-6. Data from a number of ovariectomized rat model manipulations (i.e. hypophysectomy, low calcium diet and drug combinations) demonstrate a strong parallel between the antiosteopenic effects of raloxifene and estrogen. A characteristic action of estrogens on the skeleton is inhibition of longitudinal bone growth, an effect which is not observed with other resorption inhibitors, including calcitonin and bisphosphonates. Consistent with an estrogen-like mechanism on bone, raloxifene inhibits longitudinal bone growth in growing rats. In addition to the overall similarity of the bone activity profile in animals, estrogen and raloxifene also produce similar effects on various signaling pathways relative to the antiosteopenic effect of these two agents. For example, IL-6, a cytokine involved in high turnover bone resorption following estrogen deficiency in rats, is suppressed by both raloxifene and estrogen. Raloxifene and estrogen also produce a similar activation of TGF-β3 (a cytokine associated with inhibition of osteoclast differentiation and activity) in ovariectomized rats. Like 17β-estradiol, raloxifene binds with high affinity to both estrogen receptor- (ER) and estrogen receptor-β (ERβ). Crystal structure analyses have shown that 17β-estradiol and raloxifene bind to ER with small, but important, differences in three dimensional structure. These subtle differences in the conformation of the ligand:receptor complex are likely the basis for the key pharmacological differences between estrogens and the various SERMs (i.e. raloxifene vs tamoxifen). Raloxifene also produces estrogen-like effects on serum cholesterol metabolism and the vasculature. Thus, while raloxifene exhibits a complete estrogen antagonist in mammary tissue and the uterus, it produces beneficial effects on the cardiovascular system and prevents bone loss via an estrogen receptor mediated mechanism.     

Estrogen protects bone by inducing Fas ligand in osteoblasts to regulate osteoclast survival

Estrogen deficiency in menopause is a major cause of osteoporosis in women. Estrogen acts to maintain the appropriate ratio between bone-forming osteoblasts and bone-resorbing osteoclasts in part through the induction of osteoclast apoptosis. Recent studies have suggested a role for Fas ligand (FasL) in estrogen-induced osteoclast apoptosis by an autocrine mechanism involving osteoclasts alone. In contrast, we describe a paracrine mechanism in which estrogen affects osteoclast survival through the upregulation of FasL in osteoblasts (and not osteoclasts) leading to the apoptosis of pre-osteoclasts. We have characterized a cell-type-specific hormone-inducible enhancer located 86 kb downstream of the FasL gene as the target of estrogen receptor-alpha induction of FasL expression in osteoblasts. In addition, tamoxifen and raloxifene, two selective estrogen receptor modulators that have protective effects in bone, induce apoptosis in pre-osteoclasts by the same osteoblast-dependent mechanism. These results demonstrate that estrogen protects bone by inducing a paracrine signal originating in osteoblasts leading to the death of pre-osteoclasts and offer an important new target for the prevention and treatment of osteoporosis.