Effects of dried plum supplementation on bone metabolism in adult C57BL/6 male mice.

Dietary supplementation of dried plum (DP) prevents bone loss and restores bone mass in osteopenic animal models. This study was designed to determine the effects of DP supplementation on bone metabolic activity over time using adult (6-month-old) male C57BL/6 mice (n = 40) receiving control (CON = AIN93 M) or CON+DP 25 % (w/w) diets for 4 or 12 weeks. After 4 weeks of treatment, animals consuming the DP diet had a higher whole-body bone mineral density, vertebral trabecular bone volume (BV/TV), and femoral cortical thickness compared to the CON animals. In the distal metaphysis of the femur, BV/TV was increased in the DP-treated animals, but only after 12 weeks. Bone histomorphometric analyses revealed that DP decreased osteoblast surface (67 %) and osteoclast surface (62 %) at 4 weeks, but these surfaces normalized to the CON animals by 12 weeks. Coincident with these changes, the mineralizing surface (MS/BS) and cancellous bone formation rate (BFR/BS) were reduced at 4 weeks in the DP group compared to the CON, but by 12 weeks of DP supplementation, BFR/BS (~twofold) and MS/BS (~1.7-fold) tended to be increased (p < 0.10). The relative abundance of RNA for key regulators of osteoblast and osteoclast differentiation and indicators of osteoblast activity were reduced in the DP group at 4 weeks with no difference between groups at 12 weeks. These results indicate that supplementing the diet with DP initially suppressed cancellous bone turnover, but a biphasic response occurs over time, resulting in a positive effect on bone mass and structure.

Amelogenesis imperfecta and other biomineralization defects in Fam20a and Fam20c null mice.

The FAM20 family of secreted proteins consists of three members (FAM20A, FAM20B, and FAM20C) recently linked to developmental disorders suggesting roles for FAM20 proteins in modulating biomineralization processes. The authors report here findings in knockout mice having null mutations affecting each of the three FAM20 proteins. Both Fam20a and Fam20c null mice survived to adulthood and showed biomineralization defects. Fam20b (-/-) embryos showed severe stunting and increased mortality at E13.5, although early lethality precluded detailed investigations. Physiologic calcification or biomineralization of extracellular matrices is a normal process in the development and functioning of various tissues (eg, bones and teeth). The lesions that developed in teeth, bones, or blood vessels after functional deletion of either Fam20a or Fam20c support a significant role for their encoded proteins in modulating biomineralization processes. Severe amelogenesis imperfecta (AI) was present in both Fam20a and Fam20c null mice. In addition, Fam20a (-/-) mice developed disseminated calcifications of muscular arteries and intrapulmonary calcifications, similar to those of fetuin-A deficient mice, although they were normocalcemic and normophosphatemic, with normal dentin and bone. Fam20a gene expression was detected in ameloblasts, odontoblasts, and the parathyroid gland, with local and systemic effects suggesting both local and/or systemic effects for FAM20A. In contrast, Fam20c (-/-) mice lacked ectopic calcifications but were severely hypophosphatemic and developed notable lesions in both dentin and bone to accompany the AI. The bone and dentin lesions, plus the marked hypophosphatemia and elevated serum alkaline phosphatase and FGF23 levels, are indicative of autosomal recessive hypophosphatemic rickets/osteomalacia in Fam20c (-/-) mice.

Enhanced alveolar bone loss in a model of non-invasive periodontitis in rice rats.

OBJECTIVE: The rice rat (Oryzomys palustris) develops periodontitis-like lesions when fed a diet rich in sucrose and casein (H-SC). We aimed to establish whether this model can accurately mimic the development of human periodontitis. MATERIALS AND METHODS: For this purpose, 28-day-old rice rats (15/group) were assigned to standard (STD) or H-SC diets and sacrificed after 6, 12, and 18 weeks. Jaws were processed for morphometric, histometric, histologic, histomorphometric, and micro-CT analyses. RESULTS: We found a progressive increase in horizontal alveolar bone loss (ABL) with age in maxillae of rats fed the STD diet as determined by morphometry. The H-SC diet exacerbated horizontal ABL at the palatal surface at 12 and 18 weeks. Furthermore, increased vertical ABL was detected in mandibles and maxillae of rats fed the H-SC diet for 12 and/or 18 weeks by histometry and micro-CT. Remarkably, the H-SC diet significantly increased bone remodeling at the interproximal alveolar bone of mandibles from rats fed for 6 weeks, but not in those fed for longer periods. CONCLUSIONS: These findings indicate that the H-SC diet induced a transient increase in alveolar bone remodeling, which is followed by ABL characteristic of moderate periodontitis.

Issues in modern bone histomorphometry.

This review reports on proceedings of a bone histomorphometry session conducted at the Fortieth International IBMS Sun Valley Skeletal Tissue Biology Workshop held on August 1, 2010. The session was prompted by recent technical problems encountered in conducting histomorphometry on bone biopsies from humans and animals treated with anti-remodeling agents such as bisphosphonates and RANKL antibodies. These agents reduce remodeling substantially, and thus cause problems in calculating bone remodeling dynamics using in vivo fluorochrome labeling. The tissue specimens often contain few or no fluorochrome labels, and thus create statistical and other problems in analyzing variables such as mineral apposition rates, mineralizing surface and bone formation rates. The conference attendees discussed these problems and their resolutions, and the proceedings reported here summarize their discussions and recommendations.

Effects of increased hypothalamic leptin gene expression on ovariectomy-induced bone loss in rats.

Estrogen deficiency results in accelerated bone turnover with a net increase in bone resorption. Subcutaneous administration of leptin attenuates bone loss in ovariectomized (ovx) rats by reducing bone resorption. However, in addition to its direct beneficial effects, leptin has been reported to have indirect (central nervous system-mediated) antiosteogenic effects on bone, which may limit the efficacy of elevated serum leptin to prevent estrogen deficiency-associated bone loss. The present study evaluated the long-term effects of increased hypothalamic leptin transgene expression, using recombinant adeno-associated virus-leptin (rAAV-Lep) gene therapy, on bone mass, architecture, and cellular endpoints in sexually mature ovx Sprague-Dawley rats. Ovx rats were implanted with cannulae in the 3rd ventricle of the hypothalamus and injected with either rAAV-Lep or rAAV-GFP (control vector encoding green fluorescent protein) and maintained for 10 weeks. Additional controls consisted of ovary-intact rats and ovx rats pair-fed to rAAV-Lep rats. Lumbar vertebrae were analyzed by micro-computed tomography and tibiae by histomorphometry. Cancellous bone volume was lower and osteoclast perimeter, osteoblast perimeter, and bone marrow adipocyte density were greater in ovx rats compared to ovary-intact controls. In contrast, differences among ovx groups were not detected for any endpoint evaluated. In conclusion, whereas estrogen deficiency resulted in marked cancellous osteopenia, increased bone turnover and marrow adiposity, increasing hypothalamic leptin transgene expression in ovx rats had neither detrimental nor beneficial effects on bone mass, architecture, or cellular endpoints. These findings demonstrate that the antiresorptive effects of subcutaneous leptin administration in ovx rats are mediated through leptin targets in the periphery.

Effects of alendronate on bone healing after tooth extraction in rats.

OBJECTIVES: Tooth extraction has been identified as an important risk factor for bisphosphonate-induced osteonecrosis of the jaw. Therefore, the main goal of this study was to determine the effects of alendronate on healing of the extraction socket and on interdental alveolar bone after tooth extraction in rats. MATERIALS AND METHODS: Animals were injected subcutaneously with vehicle or alendronate for 3-4 weeks before the first mandibular molar was extracted and these treatments were continued during post-extraction periods of 10, 21, 35 and 70 days. Mandibles were processed to evaluate healing of the extraction socket and adjacent alveolar bone by assessing bone formation, bone resorption and vascularity by histomorphometric techniques. RESULTS: Alendronate decreased new woven bone formation, blood vessel area, perimeter and number in the extraction socket at 10 days postextraction, but not at later time points. Furthermore, alendronate-treated rats had increased interdental alveolar bone volume and height only at 10 days postextraction. In addition, a 2.5-fold increase in the percentage of empty osteocyte lacunae was found in alveolar bone of alendronate-treated rats only at 10 days postextraction. CONCLUSIONS: Alendronate transiently decreases bone formation and vascularity in the extraction socket and delays the removal of interdental alveolar bone after tooth extraction in rats.

Osteoclast polarization and orthodontic tooth movement.

INTRODUCTION: Osteoclasts polarize when they contact activation signals that are associated with bone. Polarization is required for bone resorption and involves highly specialized mechanisms that represent attractive targets for the development of osteoclast-specific therapeutic agents. One potential use of such agents is to block tooth movement in spatially discrete locations to provide orthodontic anchorage. MATERIALS AND METHODS: Our group's research was directed toward the development of agents that inhibited the polarization of osteoclasts, and efforts were underway to develop means to experimentally modulate orthodontic tooth movement. We performed 'proof-in-principle' experiments demonstrating pharmacological blockades of orthodontic tooth movement using integrin and matrix metalloproteinase inhibitors in a rat model. RESULTS: We identified novel mechanisms underlying osteoclast bone resorption. Interactions between vacuolar H(+)-ATPase and the microfilament cytoskeleton that were unique to osteoclasts were described and characterized. Our group is now seeking to make use of this new knowledge, coupled with an emerging technique, supercomputer-based molecular modeling for the rational development of novel, osteoclast-specific therapeutic agents. CONCLUSION: Fresh insight into the molecular details of osteoclastic bone resorption provides new opportunities for identifying agents to selectively modulate osteoclast activity. Such agents may contribute to evolution of the practice of orthodontics.

Skeletal effects of fibroblast growth factor mimetic (F2A) in ovariectomized rats.

The current study was designed to determine whether short-term, systemic treatment with F2A, a mimetic for FGF-2, has skeletal effects in ovariectomized (OVX) rats and adverse side effects in non-skeletal tissues. Groups of sham-operated and OVX rats were maintained untreated for 6 weeks postOVX. These groups (N=6) were then treated IP with vehicle or F2A (0.3, 1.0, or 3.0 mg/kg) daily for 14 days. Histomorphometric analyses were performed in the proximal tibial metaphyses. Hematocrit was normal in F2A-treated OVX rats. Although organ function was not evaluated, histological examination of several organs did not detect any abnormalities. F2A treatment did not increase cancellous bone mass regardless of dose, but OVX rats treated with 1 mg/kg did exhibit increased osteoclast surface. All 3 doses of F2A induced a modest increase in cancellous bone formation. Therefore, F2A appears to increase both cancellous bone resorption and formation, but these skeletal processes are in balance so that, unlike FGF-2, cancellous bone mass is not augmented. However, F2A did not induce the anemia and impaired bone mineralization associated with FGF-2. Therefore, local application of F2A for orthopedic procedures would presumably have minimal side effects, even if the peptide is released to the systemic circulation.

In vitro and in vivo evidence for stimulation of bone resorption by an EP4 receptor agonist and basic fibroblast growth factor: Implications for their efficacy as bone anabolic agents.

Prostaglandin E2 receptor subtype 4 agonists (EP4A) and basic fibroblast growth factor (FGF2) stimulate bone formation, but their effects on bone resorption are controversial. To provide additional insight into the skeletal effects of EP4A and FGF2, their regulation of expression of genes associated with bone formation and resorption in aged ovariectomized (OVX) rats and in cultured mouse bone marrow cells was determined. RNA was isolated from lumbar vertebrae of OVX rats (16 months of age) treated daily for 3 weeks with FGF2 or EP4A and processed for quantitative real time-PCR analyses. mRNA expression for the receptor activator of NF-kappaB ligand (RANKL) and cathepsin K (CTSK), but not osteoprotegerin (OPG), were upregulated by both FGF2 and EP4A. Addition of FGF2 and EP4A to the medium of cultured mouse bone marrow cells increased the formation of tartrate resistant acid phosphatase (TRAP) positive cells, upregulated the expression of RANKL and CTSK, and downregulated expression for OPG. EP4A also increased the formation of actin rings, an indicator of osteoclast activation, in a dose dependent manner in osteoclasts cultured on bone slices and triggered the formation of pits as revealed by a pitting assay. Gene expression for osterix (OSX) and IGF-2, genes associated with bone formation, was significantly greater in FGF2-treated OVX rats compared with EP4A-treated OVX rats. These findings at the molecular level are consistent with previous tissue-level histomorphometric findings, and at the doses tested, support the contention that FGF2 has a stronger bone anabolic effect than EP4A. The results of these in vivo and in vitro analyses clarify the effects of FGF2 and EP4A on bone formation and resorption, and provide insight into differences in the efficacy of two potential bone anabolic agents for restoration of lost bone mass in the osteopenic, estrogen-deplete skeleton.

Conditional expression of a Gi-coupled receptor in osteoblasts results in trabecular osteopenia.

G protein-coupled receptors (GPCRs) coupled to activation of Gs, such as the PTH1 receptor (PTH1R), have long been known to regulate skeletal function and homeostasis. However, the role of GPCRs coupled to other G proteins such as Gi is not well established. We used the tet-off system to regulate the expression of an activated Gi-coupled GPCR (Ro1) in osteoblasts in vivo. Skeletal phenotypes were assessed in mice expressing Ro1 from conception, from late stages of embryogenesis, and after weaning. Long bones were assessed histologically and by microcomputed tomography. Expression of Ro1 from conception resulted in neonatal lethality that was associated with reduced bone mineralization. Expression of Ro1 starting at late embryogenesis resulted in a severe trabecular bone deficit at 12 wk of age (>51% reduction in trabecular bone volume fraction in the proximal tibia compared with sex-matched control littermates; n = 11; P < 0.01). Ro1 expression for 8 wk beginning at 4 wk of age resulted in a more than 20% reduction in trabecular bone volume fraction compared with sex-matched control littermates (n = 16; P < 0.01). Bone histomorphometry revealed that Ro1 expression is associated with reduced rates of bone formation and mineral apposition without a significant change in osteoblast or osteoclast surface. Our results indicate that signaling by a Gi-coupled GPCR in osteoblasts leads to osteopenia resulting from a reduction in trabecular bone formation. The severity of the phenotype is related to the timing and duration of Ro1 expression during growth and development. The skeletal phenotype in Ro1 mice bears some similarity to that produced by knockout of Gs-alpha expression in osteoblasts and thus may be due at least in part to Gi-mediated inhibition of adenylyl cyclase.

A comparative study of the bone-restorative efficacy of anabolic agents in aged ovariectomized rats.

INTRODUCTION: The study was designed to compare the bone anabolic effects of basic fibroblast growth factor (bFGF), a selective agonist for prostaglandin E receptor subtype EP4, and parathyroid hormone (PTH) in aged ovariectomized (OVX) rats with severe cancellous osteopenia. METHODS: Groups of aged OVX rats were maintained untreated for 1 year postovariectomy (15 months of age) to develop severe tibial cancellous osteopenia. These animals were then treated with bFGF or the EP4 agonist (EP4) for 3 weeks. Other groups of aged OVX rats were treated with EP4 or PTH alone for 11 weeks, or sequentially with bFGF or EP4 for 3 weeks followed by PTH for 8 weeks. Cancellous and cortical bone histomorphometry were performed in the right proximal tibial metaphysis and tibial diaphysis respectively. RESULTS: Treatment with bFGF for 3 weeks markedly increased serum osteocalcin, osteoid volume, and osteoblast and osteoid surfaces to a greater extent than EP4. Basic FGF, but not EP4 or PTH, induced formation of osteoid islands within bone marrow. EP4 stimulated cancellous bone turnover, but failed to restore lost cancellous bone in the severely osteopenic proximal tibia after 11 weeks of treatment. In contrast, EP4, much like PTH, increased cortical bone mass in the tibial diaphysis by stimulating both periosteal and endocortical bone formation. Treatment of aged OVX rats with PTH alone tended to partially reverse the severe tibial cancellous osteopenia, whereas sequential treatment with bFGF and PTH increased tibial cancellous bone mass to near the level of vehicle-treated control rats. These findings indicate that bFGF had the strongest stimulatory effect on cancellous bone formation, and was the only anabolic agent to induce formation of osteoid islands within the bone marrow of the severely osteopenic proximal tibia. Therefore, bFGF may be more effective for the reversal of severe cancellous osteopenia. PTH and EP4 increased cortical bone mass to nearly the same extent, but cancellous bone mass was greater by two-fold in PTH-treated OVX rats than in EP4-treated OVX rats. CONCLUSION: These findings in aged OVX rats suggest that PTH is more efficacious than EP4 for augmentation of cancellous bone in the severely osteopenic, estrogen-deplete skeleton.

Skeletal phenotype of growing transgenic mice that express a function-perturbing form of beta1 integrin in osteoblasts.

Skeletal modeling entails the deposition of large amounts of extracellular matrix (ECM) to form structures tailored to withstand increasing mechanical loads during rapid growth. Specific ECM molecules bind to integrin receptors on the cell surface, thereby triggering a cascade of signaling events that affect critical cell functions. To evaluate the role of integrins during skeletal growth, transgenic mice were engineered to express a function-perturbing fragment of beta1 integrin consisting of the transmembrane domain and cytoplasmic tail under the control of the osteocalcin promoter (TG mice). Thus, transgene expression was targeted to mature cells of the osteoblast lineage, and herein we show that cultured cells resembling osteocytes from 90-day-old TG mice display impaired adhesion to collagen I, a ligand for beta1 integrin. To determine the influence of beta1 integrin on bones that are responsible for providing structural support during periods of rapid growth, we examined the phenotype of the appendicular skeleton in TG mice compared to wild type (WT) mice. According to radiographs, bones from mice of both genotypes between 14 and 90 days of age appeared similar in gross structure and density, although proximal tibiae from 35-90 days old TG mice were less curved than those of WT mice (72-92% TG/WT). Although there were only mild and transient differences in absolute bone mass and strength, once normalized to body mass, the tibial dry mass (79.1% TG/WT females), ash mass (78.5% TG/WT females), and femoral strength in torsion (71.6% TG/WT females) were reduced in TG mice compared to WT mice at 90 days of age. Similar effects of genotype on bone mass and curvature were observed in 1-year-old retired breeders, indicating that these phenotypic differences between TG and WT mice were stable well into adulthood. Effects of genotype on histomorphometric indices of cancellous bone turnover were minimal and evident only transiently during growth, but when present they demonstrated differences in osteoblast rather than osteoclast parameters. Together, these results suggest that integrin signals generated during growth enhance the acquisition of a skeletal mass, structure, and strength to withstand the mechanical loads generated by weight-bearing.

Effects of disrupted beta1-integrin function on the skeletal response to short-term hindlimb unloading in mice.

The study was designed to determine whether beta1-integrin plays a role in mediating the acute skeletal response to mechanical unloading. Transgenic (TG) mice were generated to express a dominant negative form of beta1-integrin under the control of the osteocalcin promoter, which targets expression of the transgene to mature osteoblasts. At 63 days of age, wild-type (WT) and TG mice were subjected to hindlimb unloading by tail suspension for 1 wk. Pair-fed, normally loaded WT and TG mice served as age-matched controls. Bone samples from each mouse were processed for quantitative bone histomorphometry and biomechanical testing. The skeletal phenotype of TG mice was characterized by lower cancellous bone mass in the distal femoral metaphysis (-52%) and lumbar vertebral body (-20%), reduced curvature of the proximal tibia (-20%), and decreased bone strength (-20%) and stiffness (-23%) of the femoral diaphysis with relatively normal indexes of cancellous bone turnover. Hindlimb unloading for only 1 wk induced a 10% decline in tibial curvature and a 30% loss of cancellous bone in the distal femur due to a combination of increased bone resorption and decreased bone formation in both WT and TG mice. However, the strength and stiffness of the femoral diaphysis were unaffected by short-term hindlimb unloading in both genotypes. The observed increase in osteoclast surface was greater in unloaded TG mice (92%) than in unloaded WT mice (52%). Cancellous bone formation rate was decreased in unloaded WT (-29%) and TG (-15%) mice, but, in contrast to osteoclast surface, the genotype by loading interaction was not statistically significant. The results indicate that altered integrin function in mature osteoblasts may enhance the osteoclastic response to mechanical unloading but that it does not have a major effect on the development of cancellous osteopenia in mice during the early stages of hindlimb unloading.

Basic fibroblast growth factor has rapid bone anabolic effects in ovariectomized rats.

Basic fibroblast growth factor (bFGF) has a strong bone anabolic effect in intact and ovariectomized (OVX) rats treated for 7-14 days. Other growth factors such as IGF-I and TGF-beta have been implicated as potential mediators for this effect. The purpose of this study was to examine the early effects of bFGF therapy, in vivo, on bone formation and gene expression in OVX rats in order to determine whether upregulation of gene expression for IGF-I and/or TGF-beta precedes or coincides with the stimulatory effects of bFGF on bone formation. At 3 months of age, Sprague Dawley rats were OVX or sham-operated (SHAM), then maintained untreated for 3 months. One group of baseline OVX rats (BSL OVX) and BSL SHAM rats were then killed. Additional OVX groups were treated IV with bFGF at a daily dose of 200 microg/kg and killed at 1-7 and 10 days. Another group of OVX rats was treated IV with vehicle daily for 10 days, then killed. Lumbar vertebrae were processed for cancellous bone histomorphometry or RNA isolation. Ovariectomy induced increased cancellous bone turnover and a significant decrease in vertebral bone mass. Treatment of OVX rats with bFGF resulted in a significant increase in bone formation. As early as 24 h after bFGF treatment of OVX rats, osteoblast surface, osteoid surface, and osteoid volume were more than double those in BSL OVX rats and continued to increase with time. These variables were also significantly higher in bFGF-treated OVX rats at 10 days compared with vehicle-treated OVX rats. Gene expression for IGF-I was not different between BSL OVX rats and bFGF-treated OVX rats at 1 day, but was significantly higher by approximately 50% in OVX rats treated with bFGF for 2 and 7 days, and was also significantly higher by nearly 75% in OVX rats treated for 10 days compared with OVX rats treated with vehicle. Gene expression for TGF-beta1 was unchanged at early times and only significantly upregulated by a relatively modest 30% in OVX rats treated with bFGF for 10 days. The results indicate that the bone anabolic effects of bFGF in OVX rats begin as early as 24 h following the initial treatment, and increase with time. These early stages of the strong stimulatory effect of bFGF on bone formation were not associated with a large upregulation of gene expression for IGF-I and TGF-beta. The rapid increase in osteoblast surface in bFGF-treated OVX rats suggests that the growth factor induces conversion of bone lining cells to osteoblasts.

Bone anabolic effects of subcutaneous treatment with basic fibroblast growth factor alone and in combination with estrogen in osteopenic ovariectomized rats.

Although basic fibroblast growth factor (bFGF) is a potent stimulator of bone formation when administered intravenously, less is known regarding the effects of this peptide on bone following subcutaneous (s.c.) administration. In addition, it is unknown whether coadministration of estrogen enhances the bone response to treatment with bFGF. Therefore, the purpose of this study was (1) to characterize the skeletal response to s.c. injection of a high dose of bFGF, and (2) to determine whether concurrent administration of estrogen affects the skeletal response to bFGF treatment. Female Sprague-Dawley rats were ovariectomized (ovx) or sham-operated (sham) at 3 months of age and left untreated for 2 months to establish cancellous osteopenia in the ovx group. The sham rats (n=10) and one group of ovx rats (n=9) were then injected s.c. with vehicle alone for 3 weeks. Two additional groups of ovx rats were injected s.c. with bFGF (n=10) or with bFGF + estrogen (n=10) for 3 weeks. bFGF was administered s.c. at a daily dose of 1 mg/kg/day and estrogen was administered s.c. 4 days per week at a dose of 10 microg/kg for the 3-week duration of treatment. Lumbar vertebrae were collected and processed undecalcified for quantitative bone histomorphometry. Cancellous bone volume was lower and cancellous bone turnover was higher in vehicle-treated ovx rats than in vehicle-treated sham rats. Subcutaneous treatment of ovx rats with bFGF for 3 weeks resulted in a 4-fold increase in osteoblast surface and an 8-fold increase in osteoid surface in comparison to vehicle treatment of ovx rats. Osteoid volume was also markedly increased in the bFGF-treated ovx rats (7 +/- 4%) in comparison to vehicle-treated ovx rats (<0.1%). Osteoblast surface, osteoid surface, and osteoid volume were nearly identical in ovx rats treated with bFGF alone and with bFGF + estrogen. Although the majority of the osteoid in bFGF- and bFGF + estrogen-treated animals was deposited along mineralized bone surfaces, osteoid spicules without any connections to preexisting bone surfaces were also detected, providing definitive proof for bone formation within bone marrow in response to bFGF administration. Osteoclast surface, an index of bone resorption, was not affected by bFGF treatment. However, cotreatment of ovx rats with bFGF + estrogen resulted in lower osteoclast surface in comparison to treatment of ovx rats with either vehicle or bFGF alone. In summary, these findings indicate that administration of a high dose of bFGF via s.c. injection markedly increases bone formation and may be a useful treatment for cancellous osteopenia in the estrogen-deplete skeleton. The anabolic effects of bFGF on bone are not enhanced by concurrent treatment with estrogen at the replacement dose used in this study.

Changes in gene expression associated with the bone anabolic effects of basic fibroblast growth factor in aged ovariectomized rats.

Basic fibroblast growth factor (bFGF) stimulates bone formation in vitro and in vivo. The purpose of this study was to determine changes in gene expression for bone matrix proteins, growth factors, and cytokines associated with the stimulatory effects of bFGF on bone formation in aged ovariectomized (ovx) rats. At 3 months of age, female Sprague-Dawley rats were sham-operated (sham) or ovariectomized (ovx), then maintained untreated for 1 year. At 15 months of age, baseline (BSL) sham and ovx rats were killed. All other rats received daily intravenous injections of bFGF (200 microg/kg) or vehicle (veh) for 14 days. Lumbar vertebrae were processed for quantitative bone histomorphometry or molecular analyses. Ovariectomy decreased vertebral cancellous bone volume by approximately 33% and increased most indices of bone turnover. Treatment of aged ovx rats with bFGF for only 14 days significantly increased cancellous bone volume compared with vehicle treatment of ovx rats, but this variable remained lower than in sham + veh rats. Osteoid volume, osteoblast surface, and osteoid surface were markedly increased, and osteoclast surface was significantly decreased in ovx + bFGF rats compared with sham + veh and ovx + veh rats. Northern analyses revealed that mRNA levels for osteocalcin and type I collagen, relative to 18S RNA, were significantly higher in ovx + bFGF rats than in ovx + veh rats by a factor of >10. RNase protection assays revealed that insulin-like growth factor (IGF-I) mRNA levels, relative to L32 housekeeping gene, were also significantly higher, by nearly a factor of 3, in ovx + bFGF rats than in ovx + veh rats. Treatment of ovx rats with bFGF did not appear to affect message levels for transforming growth factor-beta (TGF-beta), interleukin-6 (IL-6), and interferon-gamma (IFN-gamma). These in vivo results suggest that bFGF treatment upregulates gene expression for IGF-I, which may mediate, at least in part, the increased gene expression for bone matrix proteins and the bone anabolic effects of bFGF in aged ovx rats.

Sequential treatment with basic fibroblast growth factor and PTH is more efficacious than treatment with PTH alone for increasing vertebral bone mass and strength in osteopenic ovariectomized rats.

The study was designed 1) to determine whether treatment with basic fibroblast growth factor (bFGF) and PTH is more efficacious than treatment with PTH alone for increasing bone mass and strength and improving trabecular microarchitecture in osteopenic ovariectomized rats, and 2) to assess whether prior and concurrent administration of the antiresorptive agents estrogen and risedronate suppresses the bone anabolic response to treatment with bFGF alone and sequential treatment with bFGF and PTH. Three-month-old female Sprague Dawley rats were ovariectomized (OVX) or sham-operated (sham) and maintained untreated for 1 yr. Baseline sham and OVX rats were killed at this time (15 months of age). Groups of rats were injected sc with estrogen (10 microg/kg, 4 d/wk), risedronate (5 microg/kg, 2 d/wk), or vehicle. At the end of the second week of antiresorptive treatment, catheters were inserted into the jugular veins of all rats, and vehicle or bFGF at a dose of 250 microg/kg was injected daily for 14 d. Three groups of rats were killed at the end of bFGF treatment. The remaining rats were continued on their respective antiresorptive therapy and injected sc with vehicle or synthetic human PTH-(1-34) at a dose of 80 microg/kg, 5 d/wk, for 8 wk. Lumbar vertebrae were processed for cancellous bone histomorphometry and biomechanical testing. Ovariectomy resulted in a decrease in vertebral bone mass and strength. Treatment of OVX rats for 14 d with bFGF markedly increased osteoblast surface, osteoid surface, and osteoid volume compared with vehicle treatment of sham and OVX rats. Furthermore, osteoid bridges were observed extending between preexisting trabeculae in bFGF-treated OVX rats. Prior and concurrent administration of estrogen and risedronate did not suppress these bone anabolic effects of bFGF. Treatment of OVX rats with PTH alone increased vertebral cancellous bone mass and strength to the level of vehicle-treated sham rats. Sequential treatment of OVX rats with bFGF and PTH further augmented vertebral bone mass and strength to a level above that observed in OVX rats treated with PTH alone. The improvements in bone mass and strength were associated with an increase in trabecular thickness in OVX rats treated with PTH alone and with an increase in trabecular thickness and node to terminus ratio, an index of trabecular connectivity, in OVX rats treated sequentially with bFGF and PTH. Cotreatment with estrogen and risedronate did not suppress the anabolic response of bone to bFGF and PTH. In fact, a trend for an even greater increase in cancellous bone mass and node to terminus ratio was observed in OVX rats treated with risedronate, bFGF, and PTH. These findings indicate that sequential treatment with bFGF and PTH is more efficacious than treatment with PTH alone for increasing bone mass and strength and improving trabecular microarchitecture in osteopenic OVX rats.

Spaceflight alters bone mechanics and modeling drifts in growing rats.

BACKGROUND: Alterations in bone metabolism may be a particularly serious consequence of spaceflight and a major obstacle to long-term space exploration. The effects of spaceflight on bone mechanics are unclear. This study examined the effects of spaceflight on bone mechanics in a growing rat model during a 17-d mission aboard the space shuttle (STS-78). METHODS: There were 18 rats that were divided into 3 experimental groups: flight rats (n = 6), ground-based control rats housed in an animal enclosure module (AEM, n = 6), and ground-based control rats housed in standard vivarium caging (n = 6). At the conclusion of the mission, rat femurs were tested in three-point bending followed by static and dynamic bone histomorphometry. RESULTS: Maximum stress was unaffected by spaceflight, but flexural rigidity was significantly decreased in flight animals. Much of the decrease appeared to be the result of decreases in tissue properties (elastic modulus) rather than structural changes within the bone. No significant differences in cortical bone mass or geometry were observed. In contrast, endocortical resorption was significantly decreased in flight rats accompanied by a nonsignificant decrease in periosteal bone formation, suggesting alterations in bone modeling drifts during spaceflight. For nearly all measured indices, ground-based AEM rats displayed values intermediate to flight and ground-based vivarium rats. CONCLUSIONS: Spaceflight can impair tissue properties in femoral cortical bone during growth without significant decreases in bone mass or geometry.

Sequential treatment with basic fibroblast growth factor and parathyroid hormone restores lost cancellous bone mass and strength in the proximal tibia of aged ovariectomized rats.

This study was designed to determine whether sequential treatment with basic fibroblast growth factor (bFGF) and parathyroid hormone (PTH) can restore lost cancellous bone mass and strength at a severely osteopenic skeletal site in aged ovariectomized (OVX) rats. Female Sprague-Dawley rats were subjected to sham surgery or ovariectomy at 3 months of age and maintained untreated for the first year after surgery. At 15 months of age, groups of baseline control and OVX rats were killed and catheters were inserted in the jugular veins of all remaining rats. Two groups of OVX rats were injected intravenously (iv) daily with bFGF for 14 days at a dose of 200 microg/kg body weight. At the end of bFGF treatment, one group was killed whereas the other group was subjected to 8 weeks of treatment with synthetic human PTH 1-34 [hPTH(1-34)] consisting of subcutaneous (sc) injections 5 days/week at a dose of 80 microg/kg. Another group of OVX rats was treated iv with vehicle for 2 weeks followed by treatment with PTH alone for 8 weeks. Other groups of sham-operated control rats and OVX rats were treated iv and sc with vehicle alone. The right proximal tibia from each rat was processed undecalcified for quantitative bone histomorphometry and the left proximal tibia was subjected to biomechanical testing. Baseline and vehicle-treated OVX rats were severely osteopenic because their tibial cancellous bone volumes were less than 5% compared with mean values of 20.3% and 15.0% in baseline and vehicle-treated control rats, respectively. Treatment of OVX rats for 2 weeks with bFGF alone did not significantly increase tibial cancellous bone volume but induced marked increases in osteoid volume, osteoblast surface, and osteoid surface. Sequential treatment of aged OVX rats with bFGF and PTH increased tibial cancellous bone volume (15.1%) and load to failure to at least the level of vehicle-treated control rats. Tibial cancellous bone volume (10.8%) and load to failure also were significantly increased by treatment with PTH alone, and these variables were not significantly different from those of OVX rats treated with bFGF + PTH. However, tibial ash density was significantly greater in OVX rats treated sequentially with bFGF and PTH compared with OVX rats treated with PTH alone. Our findings suggest that sequential treatment with bFGF and PTH may be useful for restoration of lost cancellous bone in the severely osteopenic, estrogen-deplete skeleton, but it cannot be concluded with certainty that this sequential treatment has a greater bone restorative effect than treatment with PTH alone.

Decreased bone anabolic effect of basic fibroblast growth factor at fatty marrow sites in ovariectomized rats.

The purpose of the study was to compare the bone anabolic effects of basic fibroblast growth factor (bFGF) at hematopoietic (red) and fatty (yellow) marrow sites in ovariectomized (ovx) rats. Female Sprague Dawley rats were subjected to ovariectomy or sham surgery at 3 months of age and maintained untreated for 2 months after surgery. Three groups of ovx rats were then injected intravenously with bFGF for 14 days at a dose of 200 microg/kg body weight. One group of bFGF-treated OVX rats was killed at the end of the treatment period, whereas the other two groups were killed at 7 or 14 days after withdrawal of bFGF treatment. Another group of ovx rats and a group of sham-operated control rats were treated intravenously with vehicle alone for 14 days. The proximal tibia and first lumbar vertebra, bone sites with hematopoietic marrow, as well as the distal tibia and caudal vertebra, bone sites with primarily fatty marrow, were processed undecalcified for quantitative bone histomorphometry. At the hematopoietic marrow sites, bFGF treatment induced a marked accumulation of osteoid, which calcified during the withdrawal period to result in a significant increase in cancellous bone volume. Osteoblast and osteoid surfaces were increased by at least a factor of 10 at these sites in bFGF-treated ovx rats before declining rapidly during the withdrawal period. In contrast, osteoid volume was negligible in the fatty marrow sites of bFGF-treated ovx rats. Although these animals exhibited a nonsignificant trend for increased cancellous bone volume in the fatty distal tibia during the withdrawal period, no such trend was observed in the fatty caudal vertebra. Indices of bone formation (osteoblast and osteoid surfaces) were significantly increased by bFGF treatment in the fatty distal tibia, which retained some small pockets of hematopoietic cells, but not to the same great extent as in the skeletal sites with hematopoietic marrow. Furthermore, not even a trend for increased osteoblast and osteoid surfaces was observed in the fatty caudal vertebra of bFGF-treated ovx rats. These findings indicate that bFGF is a strong bone anabolic agent at skeletal sites with hematopoietic marrow, but the stimulatory effects of the growth factor on bone formation are greatly attenuated at fatty marrow sites.