Marja M. Hurley

Disruption of the fibroblast growth factor-2 gene results in decreased bone mass and bone formation.

Basic fibroblast growth factor (FGF-2), an important modulator of cartilage and bone growth and differentiation, is expressed and regulated in osteoblastic cells. To investigate the role of FGF-2 in bone, we examined mice with a disruption of the Fgf2 gene. Measurement of trabecular bone architecture of the femoral metaphysis of Fgf2(+/+) and Fgf2(-/-) adult mice by micro-CT revealed that the platelike trabecular structures were markedly reduced and many of the connecting rods of trabecular bone were lost in the Fgf2(-/-) mice. Dynamic histomorphometry confirmed a significant decrease in trabecular bone volume, mineral apposition, and bone formation rates. In addition, there was a profound decreased mineralization of bone marrow stromal cultures from Fgf2(-/-) mice. This study provides strong evidence that FGF-2 helps determine bone mass as well as bone formation.

Dkk2 has a role in terminal osteoblast differentiation and mineralized matrix formation.

Human and mouse genetic and in vitro evidence has shown that canonical Wnt signaling promotes bone formation, but we found that mice lacking the canonical Wnt antagonist Dickkopf2 (Dkk2) were osteopenic. We reaffirmed the finding that canonical Wnt signaling stimulates osteogenesis, including the differentiation from preosteoblasts to osteoblasts, in cultured osteoblast differentiation models, but we also found that canonical Wnts upregulated the expression of Dkk2 in osteoblasts. Although exogenous overexpression of Dkk before the expression of endogenous canonical Wnt (Wnt7b) suppressed osteogenesis in cultures, its expression after peak Wnt7b expression induced a phenotype resembling terminal osteoblast differentiation leading to mineralization. In addition, osteoblasts from Dkk2-null mice were poorly mineralized upon osteogenic induction in cultures, and Dkk2 deficiency led to attenuation of the expression of osteogenic markers, which could be partially reversed by exogenous expression of Dkk2. Taken together with the finding that Dkk2-null mice have increased numbers of osteoids, these data indicate that Dkk2 has a role in late stages of osteoblast differentiation into mineralized matrices. Because expression of another Wnt antagonist, FRP3, differs from Dkk2 expression in rescuing Dkk2 deficiency and regulating osteoblast differentiation, the effects of Dkk2 on terminal osteoblast differentiation may not be entirely mediated by its Wnt signaling antagonistic activity.

Transcriptional induction of prostaglandin G/H synthase-2 by basic fibroblast growth factor.

In serum-free mouse osteoblastic MC3T3-E1 cells, basic fibroblastic growth factor (bFGF) induced mRNA and protein for prostaglandin G/H synthase-2 (PGHS-2), the major enzyme in arachidonic acid (AA) conversion to prostaglandins. mRNA accumulation peaked at 1 h with bFGF 1 nM. In cells stably transfected with a 371-bp PGHS-2 promoter-luciferase reporter, bFGF stimulated luciferase activity, which peaked at 2-3 h with bFGF 1-10 nM. In the presence of exogenous AA, bFGF stimulated PGE2 production, which paralleled luciferase activity. In serum-free neonatal mouse calvarial cultures, bFGF stimulated PGE2 production in the absence of exogenous AA. bFGF stimulated PGHS-2 mRNA accumulation, which peaked at 2-4 h and then decreased; there were later mRNA elevations at 48 and 96 h that were inhibited by indomethacin. In both MC3T3-E1 cells and neonatal calvariae, bFGF produced smaller and slower increases in PGHS-1 mRNA levels than for PGHS-2. bFGF stimulated bone resorption in mouse calvariae with a maximal increase of 80% at 1 nM. Stimulation was partially inhibited by nonsteroidal anti-inflammatory drugs. We conclude that bFGF rapidly stimulates PGE2 production in osteoblasts, largely through transcriptional regulation of PGHS-2, and that prostaglandins mediate some of bFGFs effects on bone resorption.

Basic Fibroblast Growth Factor Induces Osteoclast Formation in Murine Bone Marrow Cultures

We determined the effect of basic fibroblast growth factor (bFGF) on osteoclast-like cell (OCL) formation in bone marrow cultures using C57BL/6 mice. Cells were cultured for 7 days with or without bFGF at various concentrations or 10(-8) mol/L 1,25(OH)2 vitamin D3 [1,25(OH)2D3]. bFGF dose-dependently increased OCL formation per well (10(-10) mol/ L = 40 +/- 2; 10(-9) mol/L = 146 +/- 13; 10(-8) mol/L = 156 +/- 12) compared with control (< 7 per well). The effects of bFGF at 10(-9) and 10(-8) mol/L were similar to that of 10(-8) mol/L 1,25(OH)2D3 (154 +/- 11 per well). OCLs formed by bFGF were multinuclear, tartrate-resistant acid phosphatase (TRAP)-positive, expressed calcitonin receptors, and formed characteristic resorption pits. We also determined whether bFGF enhanced OCL formation during the early proliferative or late differentiating phases of the cultures. When bFGF (10(-8) mol/L) was added only on days 1-2 or days 3-4 of 6 day cultures, there was a significant increase in OCL formation. In contrast, when bFGF was added only on days 5-6 few OCLs formed. Addition of bFGF at days 1-6 or days 1-2 and days 5-6 caused similar increases in OCL formation, which were greater than OCL formation induced by treatment for days 1-2 or days 1-4. We examined the production of prostaglandin E2 (PGE2) in the cultures because bFGF is a potent stimulator of PGE2 synthesis in bone, and PGE2 stimulates OCL formation. bFGF treatment significantly increased PGE2 levels in 7 day cultures (controls = 1.4 +/- 0.1 nmol/L, 10(-8) mol/L bFGF = 132.5 +/- 0.7 nmol/L). In addition, treatment of marrow cultures with the prostaglandin synthesis inhibitors, indomethacin or NS-398 (both at 10(-6) mol/L), completely blocked bFGF-induced OCL formation. We conclude that bFGF stimulates OCL formation in C57BL/6 bone marrow cultures by mechanisms that require prostaglandin synthesis. This pathway is likely to be one mechanism by which bFGF stimulates resorption.

Parathyroid Hormone Regulates the Expression of Fibroblast Growth Factor-2 mRNA and Fibroblast Growth Factor Receptor mRNA in Osteoblastic Cells

We examined the effect of parathyroid hormone (PTH) on basic fibroblast growth factor‐2 (FGF‐2) and FGF receptor (FGFR) expression in osteoblastic MC3T3‐E1 cells and in neonatal mouse calvariae. Treatment of MC3T3‐E1 cells with PTH(1–34) (10–8M) or forskolin (FSK; 10–5M) transiently increased a 7 kb FGF‐2 transcript with a peak at 2 h. The PTH increase in FGF‐2 mRNA was maintained in the presence of cycloheximide. PTH also increased FGFR‐1 mRNA at 2 h and transiently increased FGFR‐2 mRNA at 1 h. FGFR‐3 and FGFR‐4 mRNA transcripts were not detected in MC3T3‐E1 cells. In cells transiently transfected with an 1800‐bp FGF‐2 promoter‐luciferase reporter, PTH and FSK increased luciferase activity at 2 h and 4 h. Immunohistochemistry showed that PTH and FSK increased FGF‐2 protein labeling in the nuclei of MC3T3‐E1 cells. PTH also increased FGF‐2 mRNA, and FGFR‐1 and FGFR‐2 mRNA levels within 30 minutes in neonatal mouse calvarial organ cultures. We conclude that PTH and cAMP stimulate FGF‐2 mRNA abundance in part through a transcriptional mechanism. PTH also regulated FGFR gene expression. We hypothesize that some effects of PTH on bone remodeling may be mediated by regulation of FGF‐2 and FGFR expression in osteoblastic cells.

FGF and FGFR signaling in chondrodysplasias and craniosynostosis

The first experimental mouse model for FGF2 in bone dysplasia was made serendipitously by overexpression of FGF from a constitutive promoter. The results were not widely accepted, rightfully drew skepticism, and were difficult to publish; because of over 2,000 studies published on FGF‐2 at the time (1993), only a few reported a role of FGF‐2 in bone growth and differentiation. However, mapping of human dwarfisms to mutations of the FGFRs shortly, thereafter, made the case that bone growth and remodeling was a major physiological function for FGF. Subsequent production of numerous transgenic and targeted null mice for several genes in the bone growth and remodeling pathways have marvelously elucidated the role of FGFs and their interactions with other genes. Indeed, studies of the FGF pathway present one of the best success stories for use of experimental genetics in functionally parsing morphogenetic regulatory pathways. What remains largely unresolved is the pleiotropic nature of FGF‐2. How does it accelerate growth in one cell then stimulate apoptosis or retard growth for another cell in the same type of tissue? Some of the answers may come through distinguishing the FGF‐2 protein isoforms, made from alternative translation start sites, these appear to have substantially different functions. Although we have made substantial progress, there is still much to be learned regarding FGF‐2 as a most complex, enigmatic protein. Studies of genetic models in mice and human FGFR mutations have provided strong evidence that FGFRs are important modulators of osteoblast function during membranous bone formation. However, there is some controversy regarding the effects of FGFR signaling in human and murine genetic models. Although significant progress has been made in our understanding of FGFR signaling, several questions remain concerning the signaling pathways involved in osteoblast regulation by activated FGFR. Additionally, little is known about the specific role of FGFR target genes involved in cranial bone formation. These issues need to be addressed in future in in vitro and in vivo approaches to better understand the molecular mechanisms of action of FGFR signaling in osteoblasts that result in anabolic effects in bone formation. J. Cell. Biochem.

Disruption of the Fgf2 gene activates the adipogenic and suppresses the osteogenic program in mesenchymal marrow stromal stem cells

Here we determine the Fibroblast Growth Factor-2 (FGF2) dependency of the time course of changes in bone mass in female mice. This study extends our earlier reports that knockout of the FGF2 gene (Fgf2) caused low turnover bone loss in Fgf2(-/-) male mice by examining bone loss with age in Fgf2(-/-) female mice, and by assessing whether reduced bone formation is associated with differentiation of bone marrow stromal cells (BMSCs) towards the adipocyte lineage. Bone mineral density (BMD) was similar in 3-month-old female Fgf2(+/+) and Fgf2(-/-) mice but was significantly reduced as early as 5 months of age in Fgf2(-/-) mice. In vivo studies showed that there was a greater accumulation of marrow fat in long bones of 14 and 20 month old Fgf2(-/-) mice compared with Fgf2(+/+) littermates. To study the effect of disruption of FGF2 on osteoblastogenesis and adipogenesis, BMSCs from both genotypes were cultured in osteogenic or adipogenic media. Reduced alkaline phosphatase positive (ALP), mineralized colonies and a marked increase in adipocytes were observed in Fgf2(-/-) BMSC cultures. These cultures also showed an increase in the mRNA of the adipogenic transcription factor PPARgamma2 as well as the downstream target genes aP2 and adiponectin. Treatment with exogenous FGF2 blocked adipocyte formation and increased ALP colony formation and ALP activity in BMSC cultures of both genotypes. These results support an important role for endogenous FGF2 in osteoblast (OB) lineage determination. Alteration in FGF2 signaling may contribute to impaired OB bone formation capacity and to increased bone marrow fat accumulation both of which are characteristics of aged bone.

Stage specific inhibition of osteoblast lineage differentiation by FGF2 and noggin

Fibroblast growth factor 2 (FGF2) and noggin are two unrelated ligands of two distinctly different signaling pathways that have a similar inhibitory effect on osteoblast differentiation. Because of their differences, we postulated that they probably acted at a different stage within the osteoprogenitor differentiation pathway. This study was performed on primary murine bone cell cultures under conditions where alkaline phosphatase (AP) and type I collagen expression (Col1a1) were observed by day 7 (preosteoblast stage), followed by bone syaloprotein (BSP) at day 11 (early osteoblast) and osteocalcin (OC) by day 15–18 (mature osteoblast stage). FGF2 completely inhibited expression of AP and the mRNA transcript for Col1a1, while noggin showed only a partial inhibition of these markers of preosteoblast differentiation. However, the markers of differentiated osteoblasts (BSP and OC) were completely inhibited in both the FGF2 and noggin treated cultures, suggesting that noggin acts at later point in the osteoprogenitor differentiation pathway than FGF2. To further verify that the inhibition was occurring at a different stage of osteoblasts development, primary cultures derived from transgenic mice harboring segments of the collagen promoter driving green fluorescent protein (GFP) that activate at different levels of osteoblast differentiation were analyzed. Consistent with the endogenous markers, pOBCol3.6GFP and pOBCOL2.3GFP transgene activity was completely inhibited by continuous addition of FGF2, while noggin showed partial inhibition of pOBCol3.6GFP and complete inhibition of the pOBCol2.3GFP transgene. Upon removal of either agent, endogenous and GFP markers of osteoblast differentiation reappeared although at a different temporal pattern. This work demonstrates that FGF2 and noggin can reversibly modulate osteoblast lineage differentiation at different maturational stages. These agents may be useful to enrich for and maintain a population of osteoprogenitor cells at a defined stage of differentiation. J. Cell. Biochem. 88: 1168–1176, 2003.

Over-expression of fibroblast growth factor-2 causes defective bone mineralization and osteopenia in transgenic mice.

Over‐expression of human FGF‐2 cDNA linked to the phosphoglycerate kinase promoter in transgenic (TgFGF2) mice resulted in a dwarf mouse with premature closure of the growth plate and shortening of bone length. This study was designed to further characterize bone structure and remodeling in these mice. Bones of 1–6 month‐old wild (NTg) and TgFGF2 mice were studied. FGF‐2 protein levels were higher in bones of TgFGF2 mice. Bone mineral density was significantly decreased as early as 1 month in femurs from TgFGF2 mice compared with NTg mice. Micro‐CT of trabecular bone of the distal femurs from 6‐month‐old TgFGF2 mice revealed significant reduction in trabecular bone volume, trabecular number (Tb.N), and increased trabecular separation (Tb.Sp). Osteoblast surface/bone surface, double‐labeled surface, mineral apposition rate, and bone formation rates were all significantly reduced in TgFGF2 mice. There were fewer TRAP positive osteoclasts in calvaria from TgFGF2 mice. Quantitative histomorphometry showed that total bone area was similar in both genotypes, however percent osteoclast surface, and osteoclast number/bone surface were significantly reduced in TgFGF2 mice. Increased replication of TgFGF2 calvarial osteoblasts was observed and primary cultures of bone marrow stromal cells from TgFGF2 expressed markers of mature osteoblasts but formed fewer mineralized nodules. The data presented indicate that non‐targeted over‐expression of FGF‐2 protein resulted in decreased endochondral and intramembranous bone formation. These results are consistent with FGF‐2 functioning as a negative regulator of postnatal bone growth and remodeling in this animal model.

Reduced expression and function of bone morphogenetic protein-2 in bones of Fgf2 null mice.

Disruption of the fibroblast growth factor 2 (FGF‐2) gene results in reduced bone mass in mice and impairs expression of bone morphogenic protein‐2 (BMP‐2) an important mediator of osteoblast and osteoclast differentiation. Since the relationship between FGF‐2 and BMP‐2 in bone remodeling has not been fully determined, in this study we examined whether endogenous FGF‐2 was necessary for maximal effect of BMP‐2 on periosteal bone formation in vivo and bone nodule formation and osteoclast formation in vitro in Fgf2−/− mice. We showed that BMP‐2 significantly increased periosteal bone formation by 57% in Fgf2+/+ mice but the changes were not significant in Fgf2−/− littermates. In line with these results we found no significant increase in alkaline phosphatase positive (ALP) activity in calvarial osteoblasts or ALP mineralized colonies in stromal cultures from Fgf2−/− mice after BMP‐2 treatment. Moreover, BMP‐2 induced osteoclast formation was also impaired in marrow stromal cultures from Fgf2−/− mice. Interestingly, BMP‐2 induced nuclear accumulation of the runt related transcription factor (Runx2) was markedly impaired in osteoblasts from Fgf2−/− mice. Examination of the effect of loss of FGF‐2 on BMP‐2 signaling pathway showed that BMP‐2 caused a similar induction of phospho‐Smad1/5/8 within 30 min in calvarial osteoblasts from both genotypes. In contrast BMP‐2‐induced p42/44 MAPK was reduced in Fgf2−/− mice. These findings strongly demonstrated that endogenous FGF‐2 is important in the maximal responses of BMP‐2 in bone and that this may be dependent on the p42/44 MAPK signaling pathway and downstream modulation of Runx2. J. Cell. Biochem. 103: 1975–1988, 2008.