The role of estrogen receptor α in growth plate cartilage for longitudinal bone growth

Estrogens enhance skeletal growth during early sexual maturation, whereas high estradiol levels during late puberty result in growth plate fusion in humans. Although the growth plates do not fuse directly after sexual maturation in rodents, a reduction in growth plate height is seen by treatment with a high dose of estradiol. It is unknown whether the effects of estrogens on skeletal growth are mediated directly via estrogen receptors (ERs) in growth plate cartilage and/or indirectly via other mechanisms such as the growth hormone/insulin‐like growth factor 1 (GH/IGF‐1) axis. To determine the role of ERα in growth plate cartilage for skeletal growth, we developed a mouse model with cartilage‐specific inactivation of ERα. Although mice with total ERα inactivation displayed affected longitudinal bone growth associated with alterations in the GH/IGF‐1 axis, the skeletal growth was normal during sexual maturation in mice with cartilage‐specific ERα inactivation. High‐dose estradiol treatment of adult mice reduced the growth plate height as a consequence of attenuated proliferation of growth plate chondrocytes in control mice but not in cartilage‐specific ERα^?/? mice. Adult cartilage‐specific ERα^?/? mice continued to grow after 4 months of age, whereas growth was limited in control mice, resulting in increased femur length in 1‐year‐old cartilage‐specific ERα^?/? mice compared with control mice. We conclude that during early sexual maturation, ERα in growth plate cartilage is not important for skeletal growth. In contrast, it is essential for high‐dose estradiol to reduce the growth plate height in adult mice and for reduction of longitudinal bone growth in elderly mice. © 2010 American Society for Bone and Mineral Research.     

Effects of liver-derived insulin-like growth factor I on bone metabolism in mice.

Insulin-like growth factor (IGF) I is an important regulator of both skeletal growth and adult bone metabolism. To better understand the relative importance of systemic IGF-I versus locally expressed IGF-I we have developed a transgenic mouse model with inducible specific IGF-I gene inactivation in the liver (LI-IGF-I-/-). These mice are growing normally up to 12 weeks of age but have a disturbed carbohydrate and lipid metabolism. In this study, the long-term effects of liver-specific IGF-I inactivation on skeletal growth and adult bone metabolism were investigated. The adult (week 8-55) axial skeletal growth was decreased by 24% in the LI-IGF-I-/- mice whereas no major reduction of the adult appendicular skeletal growth was seen. The cortical cross-sectional bone area, as measured in the middiaphyseal region of the long bones, was decreased in old LI-IGF-I-/- mice. This reduction in the amount of cortical bone was caused mainly by decreased periosteal circumference and was associated with a weaker bone determined by a decrease in ultimate load. In contrast, the amount of trabecular bone was not decreased in the LI-IGF-I-/- mice. DNA microarray analysis of 30-week-old LI-IGF-I-/- and control mice indicated that only four genes were regulated in bone whereas approximately 40 genes were regulated in the liver, supporting the hypothesis that liver-derived IGF-I is of minor importance for adult bone metabolism. In summary, liver-derived IGF-I exerts a small but significant effect on cortical periosteal bone growth and on adult axial skeletal growth while it is not required for the maintenance of the trabecular bone in adult mice.     

Increased mandibular condylar growth in mice with estrogen receptor beta deficiency

Temporomandibular joint (TMJ) disorders predominantly afflict women of childbearing age, suggesting a role for female hormones in the disease process. In long bones, estrogen acting via estrogen receptor beta (ERβ) inhibits axial skeletal growth in female mice. However, the role of ERβ in the mandibular condyle is largely unknown. We hypothesize that female ERβ‐deficient mice will have increased mandibular condylar growth compared to wild‐type (WT) female mice. This study examined female 7‐day‐old, 49‐day‐old, and 120‐day‐old WT and ERβ knockout (KO) mice. There was a significant increase in mandibular condylar cartilage thickness as a result of an increased number of cells, in the 49‐day‐old and 120‐day‐old female ERβ KO compared with WT controls. Analysis in 49‐day‐old female ERβ KO mice revealed a significant increase in collagen type X, parathyroid hormone–related protein (Pthrp), and osteoprotegerin gene expression and a significant decrease in receptor activator for nuclear factor κ B ligand (Rankl) and Indian hedgehog (Ihh) gene expression, compared with WT controls. Subchondral bone analysis revealed a significant increase in total condylar volume and a decrease in the number of osteoclasts in the 49‐day‐old ERβ KO compared with WT female mice. There was no difference in cell proliferation in condylar cartilage between the genotypes. However, there were differences in the expression of proteins that regulate the cell cycle; we found a decrease in the expression of Tieg1 and p57 in the mandibular condylar cartilage from ERβ KO mice compared with WT mice. Taken together, our results suggest that ERβ deficiency increases condylar growth in female mice by inhibiting the turnover of fibrocartilage. © 2013 American Society for Bone and Mineral Research.     

Altered hypertrophic chondrocyte kinetics in GDF-5 deficient murine tibial growth plates.

The growth/differentiation factors (GDFs) are a subgroup of the bone morphogenetic proteins best known for their role in joint formation and chondrogenesis. Mice deficient in one of these signaling proteins, GDF-5, exhibit numerous skeletal abnormalities, including shortened limb bones. The primary aim of this study was determine whether GDF-5 deficiency would alter the growth rate in growth plates from the long bones in mice and, if so, how this is achieved. Stereologic and cell kinetic parameters in proximal tibial growth plates from 5-week-old female GDF-5 -/- mice and control littermates were examined. GDF-5 deficiency resulted in a statistically significant reduction in growth rate (-14%, p=0.03). The effect of genotype on growth rate was associated with an altered hypertrophic phase duration, with hypertrophic cells from GDF-5 deficient mice exhibiting a significantly longer phase duration compared to control littermates (+25%, p=0.006). These data suggest that one way in which GDF-5 might modulate the rate of endochondral bone growth could be by affecting the duration of the hypertrophic phase in growth plate chondrocytes.     

Skeletal effects of estrogen are mediated by opposing actions of classical and nonclassical estrogen receptor pathways.

ER alpha acts either through classical (ERE-mediated) or nonclassical (non-ERE) pathways. The generation of mice carrying a mutation that eliminates classical ER alpha signaling presents a unique opportunity to study the relative roles of these pathways in bone. This study defines the skeletal phenotype and responses to ovariectomy and estrogen replacement in these mice. INTRODUCTION: Estrogen receptor alpha (ER alpha) can act either through classical estrogen response elements (EREs) or through non-ERE (nonclassical) pathways. To unravel these in bone, we crossed mice heterozygous for a knock-in mutation abolishing ERE binding (nonclassical ER alpha knock-in [NERKI]) with heterozygote ER alpha knockout mice and studied the resulting female ER alpha(+/+), ER alpha(+/NERKI), and ER alpha(-/NERKI) mice. The only ER alpha present in ER alpha(-/NERKI) mice is incapable of activating EREs but can signal through nonclassical pathways, whereas ER alpha(+/NERKI) mice may have a less drastic alteration in the balance between classical and nonclassical estrogen signaling pathways. MATERIALS AND METHODS: BMD was measured using DXA and pQCT at 3 months of age (n = 46-48/genotype). The mice were randomly assigned to sham surgery, ovariectomy, ovariectomy + estradiol (0.25 microg/day), or ovariectomy + estradiol (1.0 microg/day; n = 10-12/group) and restudied 60 days later. RESULTS AND CONCLUSIONS: At 3 months of age, both the ER alpha(+/NERKI) and ER alpha(-/NERKI) mice had deficits in cortical, but not in trabecular, bone. Remarkably, changes in cortical bone after ovariectomy and estrogen replacement in ER alpha(-/NERKI) mice were the opposite of those in ER alpha(+/+) mice. Relative to sham mice, ovariectomized ER alpha(-/NERKI) mice gained more bone (not less, as in ER alpha(+/+) mice), and estrogen suppressed this increase (whereas augmenting it in ER alpha(+/+) mice). Estrogen also had opposite effects on bone formation and resorption parameters on endocortical surfaces in ER alpha(-/NERKI) versus ER alpha(+/+) mice. Collectively, these data show that alteration of the balance between classical and nonclassical ER alpha signaling pathways leads to deficits in cortical bone and also represent the first demonstration, in any tissue, that complete loss of classical ERE signaling can lead to paradoxical responses to estrogen. Our findings strongly support the hypothesis that there exists a balance between classical and nonclassical ER alpha signaling pathways, which, when altered, can result in a markedly aberrant response to estrogen.     

Smad6 is essential to limit BMP signaling during cartilage development

Bone morphogenetic protein (BMP) signaling pathways regulate multiple aspects of endochondral bone formation. The importance of extracellular antagonists as regulators of BMP signaling has been defined. In vitro studies reveal that the intracellular regulators, inhibitory Smads 6 and 7, can regulate BMP‐mediated effects on chondrocytes. Although in vivo studies in which inhibitory Smads were overexpressed in cartilage have shown that inhibitory Smads have the potential to limit BMP signaling in vivo, the physiological relevance of inhibitory Smad activity in skeletal tissues is unknown. In this study, we have determined the role of Smad6 in endochondral bone formation. Loss of Smad6 in mice leads to defects in both axial and appendicular skeletal development. Specifically, Smad6?/? mice exhibit a posterior transformation of the seventh cervical vertebra, bilateral ossification centers in lumbar vertebrae, and bifid sternebrae due to incomplete sternal band fusion. Histological analysis of appendicular bones revealed delayed onset of hypertrophic differentiation and mineralization at midgestation in Smad6?/? mice. By late gestation, however, an expanded hypertrophic zone, associated with an increased pool of proliferating cells undergoing hypertrophy, was evident in Smad6 mutant growth plates. The mutant phenotype is attributed, at least in part, to increased BMP responsiveness in Smad6‐deficient chondrocytes. Overall, our results show that Smad6 is required to limit BMP signaling during endochondral bone formation. © 2011 American Society for Bone and Mineral Research     

Human breast carcinoma (ZR-75-1) serially transplanted into nude mice--with reference to estradiol dependency and sensitivity to tamoxifen

Tumor cells of the ZR-75-1 line (1 X 10(7) in 0.5 ml) were inoculated into the right thigh muscles of BALB/c female nude mice which were, at the same time given 1.0 mg of estradiol subcutaneously. After the transferable strain had been established, the tumors were then transplanted into female and male nude mice either with or without estradiol treatment. Although no exponential tumor growth was observed in the untreated male and female nude mice, no complete rejection was found during the experiments. The estrogen receptor of this strain was positive and the growth of ZR-75-1 was dependent on exogenous estradiol. ZR-75-1 in the nude mouse was insensitive to tamoxifen treatment, given as 5 mg/kg intramuscularly twice a week, suggesting that dependency on estradiol is not necessarily correlated with endocrine sensitivity to tamoxifen.     

Distinct effects of loss of classical estrogen receptor signaling versus complete deletion of estrogen receptor alpha on bone

Estrogen receptor (ER) α is a major regulator of bone metabolism which can modulate gene expression via a "classical" pathway involving direct DNA binding to estrogen-response elements (EREs) or via "non-classical" pathways involving protein-protein interactions. While the skeletal consequences of loss of ERE binding by ERα have been described, a significant unresolved question is how loss of ERE binding differs from complete loss of ERα. Thus, we compared the skeletal phenotype of wild-type (ERα(+/+)) and ERα knock out (ERα(-/-)) mice with that of mice in which the only ERα present had a knock-in mutation abolishing ERE binding (non-classical ERα knock-in [NERKI], ERα(-/NERKI)). All three groups were in the same genetic background (C57BL/6). As compared to both ERα(+/+) and ERα(-/-) mice, ERα(-/NERKI) mice had significantly reduced cortical volumetric bone mineral density and thickness at the tibial diaphysis; this was accompanied by significant decreases in periosteal and endocortical mineral apposition rates. Colony forming unit (CFU)-fibroblast, CFU-alkaline phosphatase, and CFU-osteoblast numbers were all increased in ERα(-/-) compared to ERα(+/+) mice, but reduced in ERα(-/NERKI) mice compared to the two other groups. Thus, using mice in identical genetic backgrounds, our data indicate that the presence of an ERα that cannot bind DNA but can function through protein-protein interactions may have more deleterious skeletal effects than complete loss of ERα. These findings suggest that shifting the balance of classical versus non-classical ERα signaling triggers pathways that impair bone formation. Further studies defining these pathways may lead to novel approaches to selectively modulate ER signaling for beneficial skeletal effects.     

Expression of estrogen receptor alpha and beta in the epiphyseal plate of the rat

In this study we examine the spatial and temporal expression of estrogen receptor (ER) alpha and beta mRNA and protein in the tibial growth plate of the rat after birth, as well as the hormonal regulation of their expression. Using in situ hybridization and immunohistochemistry, we demonstrated ER alpha and ER beta mRNA and protein in tibial growth plates from 1 to 40 weeks after birth. ER alpha and beta mRNA and protein were localized in late proliferating and early hypertrophic chondrocytes during early life (1 and 4 weeks of age), whereas the immunohistochemistry also showed staining for ER alpha and beta in the resting cells. A similar expression pattern was observed during sexual maturation (7 weeks of age) except that ER beta mRNA was also detected in early proliferating chondrocytes. After sexual maturation (from 12 up to 40 weeks of age) ER alpha and beta mRNA and protein expression was confined to late proliferating and early hypertrophic chondrocytes. Apart from a relatively higher ER alpha mRNA expression in males after sexual maturation, we did not detect differences in expression of ERs between genders. Expression of ER beta mRNA in epiphyseal plates was increased in growth-retarded hypophysectomized rats compared with controls. Administration of growth hormone (GH) did not reverse the increased ER expression to normal. These data suggest that ER alpha and beta are coexpressed in growth plates of the rat after birth and that the level of expression of ERs in these tissues is hormonally regulated. Furthermore, our data indicate that the absence of growth-plate closure in the rat cannot be explained by disappearance of ER alpha expression during sexual maturation per se.     

High Cortical Bone Mass Phenotype in Betacellulin Transgenic Mice Is EGFR Dependent

Signaling through the epidermal growth factor receptor (EGFR) by ligands such as epidermal growth factor (EGF), transforming growth factor α (TGFA), and amphiregulin (AREG) has been reported to have effects on skeletal growth. The role of betacellulin (BTC), another EGFR ligand, in skeletal development and bone metabolism is unknown. In previous experiments, transgenic mice overexpressing BTC ubiquitously under the control of the chicken β‐actin promoter (BTC‐tg) exhibited stunted growth and disproportionately sized long bones. In this study, we performed a detailed phenotypic analysis of BTC‐tg mice at 3, 6, and 9 wk of age. Osteoblastic cells from transgenic mice showed strong expression of BTC as determined by Western blots and by immunohistochemistry on bone sections. In femurs of male and female BTC‐tg mice, we found reduced longitudinal bone growth and a pronounced increase in total volumetric BMD. The increased femoral BMD was mainly caused by augmented endocortical bone apposition and subsequent cortical bone thickening. In contrast, vertebral BMD was reduced in BTC‐tg mice of both sexes. An overall similar phenotype was found in 6‐mo‐old BTC‐tg mice. The increase in cortical bone mass in the appendicular skeleton of BTC‐tg mice was largely blocked when they were crossed into the Egfr^Wa5 background characterized by a dominant negative EGFR. Our study showed that overexpression of BTC results in an EGFR‐dependent upregulation of cortical bone mass in the appendicular skeleton of mice, uncovering a potential novel anabolic pathway for cortical bone.     

Human breast carcinoma (ZR-75-1) serially transplanted into nude mice-with reference to estradiol dependency and sensitivity to tamoxifen

Tumor cells of the ZR-75-1 line (1×10⁷ in 0.5 ml) were inoculated into the right thigh muscles of BALB/c female nude mice which were, at the same time, given 1.0 mg of estradiol subcutaneously. After the transferable strain had been established, the tumors were then transplanted into female and male nude mice either with or without estradiol treatment. Although no exponential tumor growth was observed in the untreated male and female nude mice, no complete rejection was found during the experiments. The estrogen receptor of this strain was positive and the growth of ZR-75-1 was dependent on exogenous estradiol. ZR-75-1 in the nude mouse was insensitive to tamoxifen treatment, given as 5 mg/kg intramuscularly twice a week, suggesting that dependency on estradiol is not necessarily correlated with endocrine sensitivity to tamoxifen.     

Inactivation of Pten in osteo-chondroprogenitor cells leads to epiphyseal growth plate abnormalities and skeletal overgrowth.

To study the role of the Pten tumor suppressor in skeletogenesis, we generated mice lacking this key phosphatidylinositol 3'-kinase pathway regulator in their osteo-chondroprogenitors. A phenotype of growth plate dysfunction and skeletal overgrowth was observed. INTRODUCTION: Skeletogenesis is a complex process relying on a variety of ligands that activate a range of intracellular signal transduction pathways. Although many of these stimuli are known to activate phosphatidylinositol 3'-kinase (PI3K), the function of this pathway during cartilage development remains nebulous. To study the role of PI3K during skeletogenesis, we used mice deficient in a negative regulator of PI3K signaling, the tumor suppressor, Pten. MATERIALS AND METHODS: Pten gene deletion in osteo-chondrodroprogenitors was obtained by interbreeding mice with loxP-flanked Pten exons with mice expressing the Cre recombinase under the control of the type II collagen gene promoter (Pten(flox/flox):Col2a1Cre mice). Phenotypic analyses included microcomputed tomography and immunohistochemistry techniques. RESULTS: MicroCT revealed that Pten(flox/flox):Col2a1Cre mice exhibited both increased skeletal size, particularly of vertebrae, and massive trabeculation accompanied by increased cortical thickness. Primary spongiosa development and perichondrial bone collar formation were prominent in Pten(flox/flox):Col2a1Cre mice, and long bone growth plates were disorganized and showed both matrix overproduction and evidence of accelerated hypertrophic differentiation (indicated by an altered pattern of type X collagen and alkaline phosphatase expression). Consistent with increased PI3K signaling, Pten-deficient chondrocytes showed increased phospho-PKB/Akt and phospho-S6 immunostaining, reflective of increased mTOR and PDK1 activity. Interestingly, no significant change in growth plate proliferation was seen in Pten-deficient mice, and growth plate fusion was found at 6 months. CONCLUSIONS: By virtue of its ability to modulate a key signal transduction pathway responsible for integrating multiple stimuli, Pten represents an important regulator of both skeletal size and bone architecture.     

Contributions of IL-1beta and IL-1alpha to crescentic glomerulonephritis in mice

ABSTRACT. Interleukin-1 (IL-1) is a pleiotropic proinflammatory cytokine with two distinct isoforms (IL-1alpha and IL-1beta) that signal through the same IL-1 type I receptor (IL-1RI). Contributions of IL-1beta have been demonstrated in human and experimental proliferative glomerulonephritis (GN), but the involvement of IL-1alpha has received little attention. To determine the combined contribution of IL-1alpha and IL-1beta and to dissect the specific contribution of IL-1beta, the development of anti-glomerular basement membrane globulin-induced crescentic GN was studied in mice genetically deficient in either the IL-1 receptor type I (IL-1RI-/-), which are unresponsive to both IL-1alpha and IL-1beta, or IL-1beta alone (IL-1beta-/-). IL-1beta-/- mice showed significant reductions in crescent formation and glomerular T cell and macrophage recruitment compared with strain matched controls (WT). No additional reductions of these indices of injury were observed in IL-1RI-/- mice. However, IL-1RI-/- mice showed greater functional renal protection with significantly less proteinuria and reduced serum creatinine compared with IL-1beta-/- mice, suggesting a significant contribution of IL-1alpha to these parameters of injury. IL-1RI-/- mice had lower serum titers of antibody to the nephritogenic antigen (sheep globulin) and reduced glomerular deposition of complement compared with either IL-1beta-/- or WT mice. This suggests that in the absence of responses to both IL-1alpha and IL-1beta, attenuation of humoral mediators provides additional functional protection from renal injury that is not seen in the absence of IL-1beta alone. These studies indicate that IL-1beta but not IL-1alpha contributes to crescent formation and inflammatory cell recruitment, whereas IL-1alpha but not IL-1beta contributes to humoral mechanisms of glomerular injury.     

Mice lacking the integrin beta5 subunit have accelerated osteoclast maturation and increased activity in the estrogen-deficient state.

Integrin alphavbeta5 is expressed on osteoclast precursors and is capable of recognizing the same amino acid motif as alphavbeta3. Three-month-old beta5(-/-) female OVX mice had increased osteoclastogenesis ex vivo, and microCT assessment of trabecular bone volume was 53% lower than WT-OVX animals. These preliminary data suggest alphavbeta5 integrin's presence on osteoclast precursors may inhibit of osteoclast formation. INTRODUCTION: Osteoclasts are unique resorptive skeletal cells, capable of degrading bone on contact to the juxtaposed matrix. Integrin alphavbeta5 is expressed on osteoclast precursors, structurally similar to alphavbeta3, and capable of recognizing the same amino acid motif. Given the structural relationship and reciprocal regulation of alphavbeta3 and alphavbeta5, the purpose of this study was to evaluate how alphavbeta5 might contribute to osteoclast maturation and activity. MATERIALS AND METHODS: Three-month-old wildtype (WT) and beta5(-/-) female mice had ovariectomy (OVX) or sham operations. The osteoclastogenic capacity of marrow-derived precursors, the kinetic, the circulating, and structural parameters of bone remodeling, was determined after 6 weeks of paired feeding. RESULTS AND CONCLUSIONS: OVX increased osteoclastogenesis ex vivo and in vivo. Osteoclast formation and prolonged pre-osteoclast survival were substantially enhanced in cultures containing beta5(-/-) cells whether obtained from sham-operated or OVX mice. Expression of cathepsin K, beta3 integrin subunit, and calcitonin receptor were accelerated in cultured beta5(-/-)osteoclasts. beta5(-/-) osteoclasts from OVX animals showed a 3-fold enhancement of net resorptive activity, with quantitative muCT showing trabecular bone volume loss after OVX 53% greater in beta5(-/-) OVX compared with similarly treated WT OVX mice (p < 0.05). alpha5beta3 seems to be an inhibitor of osteoclast formation, in contrast to alphavbeta3. In addition, loss of alphavbeta5 seems to accelerate osteoclast formation in the OVX model. Further examination of alphavbeta5 signaling pathways may enhance our understanding of the activation of bone resorption.     

Stimulation of bone formation in vivo by transforming growth factor-beta: remodeling of woven bone and lack of inhibition by indomethacin

Local effects of transforming growth factor-beta (TGF beta) on bone have been investigated in growing mice. The influence of indomethacin on TGF beta effects was also examined. Five daily injections of TGF beta-1 or -2 were administered subcutaneously over the frontal and parietal bones of seven-week-old mice. In animals treated with TGF beta alone or TGF beta and indomethacin, then killed on day 19 (day 1 = day of first TGF beta injection), the combined frontal and parietal bones were heavier and the frontal bones were thicker than in controls. On day 4, multiple layers of differentiating osteoblasts were visible in the periosteum of calvariae from TGF beta-treated animals. On day 8, highly vascularised periosteal woven bone was seen in the calvariae of TGF beta-treated animals. On day 19 (14 days after the last injection) the woven bone had been partially remodeled into lamellar bone containing bone marrow, and was still actively being remodeled. The histological appearance of bones from animals treated concurrently with TGF beta and indomethacin was identical to that of animals treated with TGF beta alone, and there appeared to be no difference between TGF beta-1 and TGF beta-2. Thus TGF beta-stimulated bone formation in vivo is a long term effect that appears to be independent of prostaglandins. Osteoclast counts in sections of TGF beta-treated animals were not elevated on day 4, although at this stage effects on osteoblastic cells were already morphologically apparent. Osteoclast counts in TGF beta-treated bones were significantly increased over control values on days 8 and 19.(ABSTRACT TRUNCATED AT 250 WORDS)     

Androgen deficiency induces high turnover osteopenia in aged male rats: a sequential histomorphometric study.

Hypogonadism is considered to be one of the major risk factors for osteoporosis in men. However, the mechanisms of bone loss caused by androgen deficiency are still unclear. In the present study, we sequentially investigated the skeletal and hormonal effects of androgen deficiency in aged orchiectomized (ORX) rats over a time period of 9 months. One hundred seventy 13-month-old male Fischer-344 rats were either ORX or sham-operated (SHAM). Eight rats served as baseline controls. After in vivo fluorochrome labeling, groups of 8-15 SHAM and ORX rats each were killed at 2 weeks and at 1, 2, 3, 4, 6, and 9 months postsurgery. As expected, ORX induced a fall in serum total and free testosterone levels, but also reduced serum estradiol concentrations. Cancellous bone area (BAr) in the proximal tibia but not in the first lumbar vertebral body showed an age-dependent decline in SHAM rats. Relative to SHAM controls, ORX rats had significantly reduced cancellous BAr after 2 weeks post-ORX in the tibia and after 2 months post-ORX in the vertebral body. Thereafter, vertebral and tibial cancellous BAr continued to decline in ORX animals throughout the study. Osteoclast number (NOc), osteoblast surface, bone formation rate (BFR), and activation frequency were increased in ORX animals from 1 month postsurgery until the end of the trial. Moreover, in close temporal association with the histomorphometric findings, serum osteocalcin and urinary excretion of collagen cross-links and calcium were elevated in ORX rats. In a stepwise model of multiple regression analysis using estradiol and free and total testosterone as independent variables, estradiol was the only significant predictor of histomorphometric indices of bone formation and bone resorption in SHAM and ORX rats. These data show that androgen deficiency induces substantial loss of cancellous bone in the axial and appendicular skeleton of aged male rats and that this osteopenia is associated with a sustained increase in bone turnover. Thus, the skeletal effects of androgen withdrawal in aged male rats appear to resemble those induced by estrogen withdrawal in female rats. Furthermore, our study suggests that estradiol may act as a physiological suppressor of bone remodeling in aged male rats.     

Transforming growth factor alpha controls the transition from hypertrophic cartilage to bone during endochondral bone growth

We have recently identified transforming growth factor alpha (TGFα) as a novel growth factor involved in the joint disease osteoarthritis. The role of TGFα in normal cartilage and bone physiology however, has not been well defined.PurposeThe objective of this study was to determine the role of TGFα in bone development through investigation of the Tgfa knockout mouse.MethodsThe gross skeletons as well as the cartilage growth plates of Tgfa knockout mice and their control littermates were examined during several developmental stages ranging from newborn to ten weeks old.ResultsKnockout mice experienced skeletal growth retardation and expansion of the hypertrophic zone of the growth plate. These phenotypes were transient and spontaneously resolved by ten weeks of age. Tgfa knockout growth plates also had fewer osteoclasts along the cartilage/bone interface. Furthermore, knockout mice expressed less RUNX2, RANKL, and MMP13 mRNA in their cartilage growth plates than controls did.ConclusionsTgfa knockout mice experience a delay in bone development, specifically the conversion of hypertrophic cartilage to true bone. The persistence of the hypertrophic zone of the growth plate appears to be mediated by a decrease in MMP13 and RANKL expression in hypertrophic chondrocytes and a resulting reduction in osteoclast recruitment. Overall, TGFα appears to be an important growth factor regulating the conversion of cartilage to bone during the process of endochondral ossification.     

Skeletal growth factor and other growth factors known to be present in bone matrix stimulate proliferation and protein synthesis in human bone cells

The purpose of the study was to investigate the effect of skeletal growth factor/insulinlike growth factor II and other growth factors known to be present in bone matrix on the proliferation and differentiation of human bone cells. Cells were isolated by collagenase digestion from femoral heads obtained during hip replacement operations. Cells were cultured in DMEM medium with 10% calf serum. Third to fifth passage cells were plated in multiwell plates and the medium changed to low serum (0.1%) for 2 days. The medium was changed to serum-free medium prior to addition of growth factors. Cell proliferation was measured by the incorporation of [3H]thymidine into DNA and by the percentage of cells that incorporate bromodeoxyuridine. Protein synthesis was measured by the incorporation of [3H]proline into trichloroacetic acid-precipitable material. Skeletal growth factor/insulinlike growth factor II and insulinlike growth factor I stimulated cell proliferation and protein synthesis in a dose-dependent manner. Alkaline phosphatase-specific activity was not increased by these factors. Transforming growth factor beta 1 did not affect cell proliferation but stimulated protein synthesis and increased the specific activity of alkaline phosphatase. Fibroblast growth factor did not affect any of the cell parameters. These studies suggest that skeletal growth factor/insulinlike growth factor II, insulinlike growth factor I, and transforming growth factor beta 1 may play a role in the local control of the proliferation and differentiation of human osteoblasts.