- Email: [email protected]
Skeletal Growth Factors
Chapter 19
Skeletal Growth Factors Ernesto Canalis
I. II. III. IV. V.
I.
Introduction Platelet-Derived Growth Factor Vascular Endothelial Growth Factor Fibroblast Growth Factor Transforming Growth Factor Beta
INTRODUCTION
Bone formation and resorption are regulated by systemic and local factors acting in concert to maintain bone mass. Calciotropic and steroid hormones have been studied extensively for their effects on bone remodeling. However, there is compelling evidence to support the concept that systemic and locally produced growth factors play a central role in the regulation of bone remodeling. Growth factors regulate the replication, differentiation, and function of bone cells. This chapter will be limited to the description of factors that have a major effect on bone formation and osteoblastic function, whereas other chapters of this book will describe cytokines that regulate bone resorption. This is a somewhat arbitrary division since bone remodeling is coupled and osteoclastogenesis is highly dependent on osteoblastic signals. Furthermore, cytokines with primary effects on cells of the osteoclast lineage also play a role in the process of bone formation. Although skeletal cells synthesize a variety of factors, some skeletal growth factors, such as platelet-derived growth factor (PDGF), vascular endothelial growth factor (VEGF), fibroblast growth factor (FGF), transforming growth factor β (TGF β), bone morphogenetic proteins (BMP), and insulin-like growth factors (IGF) have been studied in more detail. Some of these factors act as bone cell mitogens, and as such they are important in the maintenance of an adequate number of skeletal cells. They also may increase bone cell replication when additional cells are needed, such as during fracture healing and repair. A factor may play a role in the differentiation of cells and osteoblastogenesis, or may stimulate the differentiated function of mature cells. There are no growth factors specifically synthesized by skeletal cells, and those known as skeletal growth factors also are expressed in various nonskeletal tissues. However, growth factors are regulated specifically in bone at the level of synthesis or activity by agents that OSTEOPOROSIS, 3RD EDITION Marcus, Feldman, Nelson, and Rosen
Marcus-Ch19.indd 529
VI. VII. VIII. IX.
Bone Morphogenetic Protein Insulin-Like Growth Factor Insulin-Like Growth Factor Binding Proteins Hepatocyte Growth Factor Acknowledgments
act primarily on this tissue. Growth factors synthesized by skeletal cells may be present in the systemic circulation, and act both as local and systemic regulators of bone remodeling. The source of circulating growth factors varies, although it is frequently the liver, the circulating platelets, or peripheral tissues. The systemic form of a factor can be regulated by agents and mechanisms different from those affecting the locally produced factor, and it is conceivable that the roles of the circulating and local form of a growth factor differ. This is not only because their synthesis is regulated by different hormones, but also because they may become available under different physiological or pathophysiological circumstances. It is tempting to believe that the local form of a growth factor plays a more immediate, and possibly important role in the control of cell function since it has a more direct access to its target cell. Locally synthesized growth factors can act either as autocrine factors and affect cells of the same class, or paracrine factors and affect different or adjacent cells. In this chapter the function and regulation of selected growth factors will be discussed and their relevance to skeletal physiology will be considered.
II. PLATELET-DERIVED GROWTH FACTOR PDGF was originally isolated from human platelets, and four members of the pdgf gene family have been identified—pdgf a, pdgf b, pdgf c, and pdgf d [1]. VEGF shares a high degree of sequence homology with PDGF and these factors are often referred as members of the PDGF/VEGF family [2]. This family of genes encodes a highly conserved cystine knot motif. The recently discovered pdgf c and pdgf d genes have a Clr/ Cls, urchin endothelial growth factor, BMP l (CUB) domain linked to the cystine knot core motif by a hinge domain [3, 4, 5, 6]. Several reports have indicated that Copyright © 2008, Elsevier, Inc. All rights reserved.
8/22/2007 4:17:38 PM
530 proteolytic release of the core from the CUB domain is required for the activation of PDGF C and PDGF D, although activity for the full-length peptide and independent activity for the CUB domain have been postulated [3, 5, 6]. PDGFs must form homo- or heterodimers to exhibit activity, and they can form PDGF AA, BB, AB, CC, or DD dimers [3]. The various pdgf genes are conspicuously expressed during development and in adult tissues. Transcripts for the pdgf a, pdgf b, and pdgf c genes are detected in osteoblasts, but their basal expression is relatively low [3, 7, 8, 9]. PDGF D is synthesized by myocardial and vascular cells, where it induces cell proliferation and fibrosis, but there are no reports of PDGF D synthesis by the osteoblast [10]. Since PDGF is present in circulating platelets, it can act as a local and systemic regulator of cell function [11]. The five PDGF isoforms described can interact with either one of two PDGF receptors, which have differential binding specificity for the various PDGF dimers [12, 13, 14, 15]. PDGF receptor (PDGFR) α ligates PDGF A, B, and C chains and PDGFR β binds PDGF B and D chains [3]. The two PDGF receptors are structurally and functionally related, and PDGF binding results in receptor dimerization and the formation of PDGF αα, ββ, and αβ receptor dimers [3]. For receptor activation, PDGF AA and PDGF CC require PDGFR αα, or αβ dimers, PDGF DD requires PDGFR ββ, or αβ dimers, whereas PDGF AB and PDGF BB can activate either PDGFR αα, αβ, or ββ dimers. PDGF AA, AB, and BB are the isoforms studied more extensively in skeletal cells, and they exert similar biological actions. However, in skeletal as well as nonskeletal cells, PDGF BB is more potent than PDGF AA, and PDGF AB has intermediate activity [16]. The primary action of PDGF in bone is the stimulation of DNA synthesis and of cell replication. Histomorphometric analysis reveals an increase in cells of the osteoblastic lineage, but the effect is not specific and PDGF causes a generalized stimulation of cell replication in bone [17]. The mitogenic effect is observed primarily in the periosteal layer, a zone rich in fibroblasts and preosteoblasts. It could be presumed that preosteoblastic cells, replicating under the influence of PDGF, eventually differentiate into mature osteoblasts. However, an inhibitory effect on the differentiation of stromal cells into cells of the osteoblastic lineage has been reported [18]. This would indicate that the cells affected could remain in a proliferative undifferentiated state. Some cells, responding to other local signals, may differentiate, and as a consequence of the increased cell number, a modest increase in collagen synthesis is observed following exposure to PDGF. It is important to note that, in accordance with the impaired cell differentiation, PDGF inhibits the expression of the mature osteoblastic
Marcus-Ch19.indd 530
Ernesto Canalis
phenotype, and decreases alkaline phosphatase activity and type I collagen mRNA levels [19, 16, 17]. In calvariae, PDGF inhibits mineral apposition rates. These effects may be direct and indirect since PDGF inhibits the synthesis of IGF-I and -II in osteoblasts, and IGF-I and -II enhance osteoblastic functions [20, 21]. PDGF enhances bone resorption by increasing the number of osteoclasts, an effect that may be secondary to an increase in the expression of interleukin (IL)-6, a cytokine known to induce osteoclastogenesis [22]. In agreement with its effects on bone resorption, PDGF increases the expression of matrix metalloproteinases (MMP) by the osteoblast [23, 24]. PDGF increases the rate of transcription of the collagenase 3 (MMP-13) gene, and mRNA stability in transcriptionally arrested osteoblasts. MMP-13 is a proteinase capable of initiating the degradation of type I collagen at neutral pH, and necessary to achieve a bone resorptive response to parathyroid hormone (PTH) [25]. Cells of the osteoblastic lineage express PDGF α and β receptors. PDGF binding to its osteoblast receptor results in receptor dimerization, and activation of tyrosine kinase activity, leading to activation of protein kinase C (PKC), and intracellular calcium signaling pathways [26, 27]. In rodent, but not in human osteoblasts, IL-1 increases PDGF α receptor transcripts and the binding and mitogenic activity of PDGF AA [16, 28, 29]. TGF β decreases PDGF binding, and hormones have no effect on PDGF binding to osteoblasts [30]. Information on the activity of PDGF CC and PDGF DD in skeletal cells is limited. PDGF CC interacts with PDGF αα and αβ receptor dimers, and has potent mitogenic activity for mesenchymal cells [4]. PGDF CC induces the differentiation and regulation of endothelial cells and has potent angiogenic properties, directly or indirectly by upregulating VEGF [31]. These properties of PDGF CC could be important during the vascularization of endochondral bone formation, as it has been described for VEGF. PDGF DD interacts with PDGF β receptors, has mitogenic activity for vascular cells, and induces tissue fibrosis, but its effects on the skeleton are not known [10]. Although there is considerable knowledge about the actions of PDGF in vitro, information about its effects on the skeleton in vivo is more limited. Consistent with some of its in vitro effects, the systemic administration of PDGF BB to ovariectomized rats prevents bone loss, and increases the number of osteoblasts and bone formation [32]. It is likely that the mitogenic effects of PDGF on preosteoblasts result in an increased number of osteoblasts, which are capable of forming bone. PDGF does not change osteoclast number when administered systemically to ovariectomized rats, but this may be related to this particular model
8/22/2007 4:17:39 PM
531
Chapter 19 Skeletal Growth Factors
where the ovariectomy causes a substantial increase in bone resorption and remodeling, precluding an additional effect by PDGF. Topical application of PDGF to craniotomy defects in rodents stimulates soft tissue repair, but not osteogenesis [33]. The effects of PDGF on endothelial cell proliferation and angiogenesis are likely beneficial to the process of wound healing, and PDGF accelerates the healing response of wounds due to an increase in cellularity and in the formation of granulation tissue [34]. Genetically engineered mice with gain and loss of function mutations have provided important information on the physiological role of PDGF during development and post-natality. Null mutations of pdgf b, pdgf a and b receptors cause embryonic lethality, and pdgf a deletions cause prenatal and perinatal death [35]. Therefore, these models have not allowed for the study of the function of PDGF in the postnatal skeleton. pdgf b and pdgf b receptor null mice develop microvascular bleeding and absent vascular and mesangial cells [36, 37]. pdgf a and pdgf a receptor null mutants have defective alveolar formation in the lungs leading to emphysema, and have reduced intestinal villi, thin dermis, and spermatogenic arrest, but pdgf a null mutants do not manifest a skeletal phenotype [38,39]. pdgf c null mice exhibit neonatal lethality and numerous skeletal developmental abnormalities, including cleft palate and spina bifida [40]. Similar defects are observed in pdgf a receptor null mice, which exhibit a phenotype characterized by embryonic lethality, cleft face, spina bifida, and vascular and skeletal defects [38, 39]. Although PDGF B can interact with the PDGF α receptor, loss of function mutations of the pdgf b gene do not resemble the pdgf a receptor null phenotype, indicating that the functions of the PDGF α and β receptors are not redundant [36, 37]. The phenotype of pdgf d gene deletion has not been reported, but overexpression of PDGF DD, like that of PDGF CC, results in tissue fibrosis [41,10]. This may be secondary to the mitogenic properties of PDGF CC and PDGF DD or due to the induction of tissue inhibitors of metalloproteinases. The major source of PDGF is the systemic circulation, and skeletal cells probably become exposed to significant concentrations of PDGF following platelet aggregation. Nevertheless, skeletal cells express the pdgf a, pdgf b and pdgf c genes indicating that PDGF isoforms may act as autocrine regulators of skeletal cell function [8, 42, 9]. The expression of the pdgf a gene is enhanced by TGF β and by PDGF, and that of pdgf b enhanced by TGF β [42, 9]. Following an initial induction of PDGF A, an autoregulatory mechanism may serve to maintain local levels of the growth factor. The regulation of pdgf gene expression in skeletal
Marcus-Ch19.indd 531
cells is analogous to its regulation in nonskeletal cells indicating that there are no specific transcription factors responsible for the expression of PDGF in bone. Systemic hormones are not known to regulate pdgf gene expression in osteoblasts. Since both TGF β and PDGF are released by platelets following platelet aggregation, the subsequent induction of PDGF by these factors in the bone microenvironment may be a mechanism to ensure adequate levels of PDGF in skeletal tissues in conditions that follow platelet aggregation, such as fracture repair. Under basal conditions there may be no need for skeletal cells to be exposed to significant concentrations of PDGF, and its levels are low [42, 9].
III. VASCULAR ENDOTHELIAL GROWTH FACTOR VEGF shares sequence homology and angiogenic properties with PDGFs, and often they are referred to as members of the PDGF/VEGF family [3, 43]. VEGF A belongs to a gene family also composed of placenta growth factor, vegf b, vegf c, and vegf d [43]. In the mouse, differential splicing results in three VEGF A isoforms, VEGF A 120, VEGF A 164, and VEGF A 188. VEGF A is essential for angiogenesis and vegf a and vegf receptor 1 and 2 genes are expressed by chondrocytes and osteoblasts [44, 45]. VEGF A is required for blood vessel formation and vessel invasion into cartilage during the process of endochondral bone formation, and for chondrocyte survival during skeletal development [46, 47]. The expression of vegf a by chondrocytes requires runt related transcription factor-2 (Runx-2), a transcription factor essential for normal osteogenesis [47]. VEGF A also is required for intramembranous bone formation, it enhances osteoblastic maturation in vitro, and VEGF receptor 1 signaling is essential for osteoclast development [48, 49, 47]. vegf a gene null deletions are lethal due to defective hematopoiesis and defective blood vessel formation, but mice expressing one of three VEGF A isoforms, VEGF A 120, survive and their study has documented the function of VEGF A on endochondral bone formation and osteoblastic maturation [50]. Bone histomorphometric analysis following adenoviral vector delivery of VEGF A also demonstrates a stimulatory effect of VEGF on osteoblast number, and in vivo VEGF A promotes angiogenesis and fracture repair [51, 45]. The expression of VEGF by osteoblasts is regulated by various growth factors. Activation of mitogen activated protein (MAP) kinases by BMP, TGF β, or FGF-2 and activation of phosphatidylinositol-3 (PI3) kinase by IGF-I induces vegf expression in osteoblasts [52, 53, 54, 55]. Following growth factor-induced
8/22/2007 4:17:39 PM
532
Ernesto Canalis
synthesis, VEGF may serve to couple angiogenesis and osteoblastic differentiation and function [56, 46]. The stimulatory effect of IGF-I on vegf a gene expression is mediated by the hypoxia inducible factor (HIF) 2 α. This may result in an increased vascular supply to the local environment, and may serve as a protective mechanism in response to changes in oxygen availability to the osteoblast [52]. It is of interest that the phenotypes of the conditional deletion of hif-1 and of vegf-a in cartilage are analogous [47].
IV.
FIBROBLAST GROWTH FACTOR
FGFs form a family of at least 23 structurally related polypeptides, characterized by their affinity to glycosaminoglycan heparin binding sites [57]. FGFs were initially isolated from the central nervous system and subsequently found in a variety of tissues, where they regulate cell function [58, 59]. Skeletal cells synthesize both FGF-1 and -2, the forms of FGF most extensively studied for their actions on the skeleton [60, 61]. FGF has mitogenic activity in skeletal and nonskeletal cells and potent angiogenic properties [62, 63, 64]. FGF increases a population of cells of the osteoblastic lineage, which differentiate into osteoblasts [63]. However, FGF, like other potent mitogens, does not enhance the differentiated function of the osteoblast directly, and FGF-2 inhibits alkaline phosphatase activity, type I collagen, osteocalcin and osteopontin synthesis, independently of its stimulatory effects on osteoblastic cell growth [65, 66]. These effects are paralleled in vivo and transgenic mice overexpressing FGF-2 are osteopenic, although fgf 2 null mice exhibit impaired bone formation [67, 68]. The inhibitory effect of FGF-2 on osteoblast differentiation is secondary to the induction of the transcription factor Sox 2 and the inhibition of Wnt signaling, which is essential for osteoblastogenesis [69, 70]. Confirming an inhibitory effect on osteoblastic function, FGF-2 suppresses the synthesis of IGF-I, a factor that stimulates the differentiated function of the osteoblast [20]. FGF-2 increases bone resorption by favoring osteoclastogenesis, and stimulates the synthesis of collagenase 3 (MMP-13) by the osteoblast [71, 72]. Marrow stromal cells from fgf-2 null mice exhibit decreased osteoclastogenesis in response to PTH. FGF-2 induces TFG β1 transcription, and TGF β could mediate selected actions of FGF in bone [73]. The actions of FGF can be regulated by modifications in the affinity or number of FGF receptors in target cells. FGF receptors are a family of four distinct receptors, FGFR1 through 4 [74, 75, 76]. FGF receptors are
Marcus-Ch19.indd 532
transmembrane protein responsive kinases with two to three immunoglobulin-like domains. Differential splicing of the extracellular region of FGF receptors can generate receptor variants with different ligand binding specificity [74, 76]. The four known receptors, and variants, bind the members of the FGF family of polypeptides with different affinity, and have different signaling and mitogenic potential. Activation of FGFR1, 2, and 3 by FGFs induces a mitogenic response, whereas activation of FGFR4 does not [75]. Accordingly, mutations of the fgfr-1, -2, or -3 cause diverse skeletal syndromes including achondroplasia, a common cause of dwarfism [77]. Studies on FGF receptors in preosteoblasts and osteoblasts have been limited. Activation of the signal transducers and activators of transcription 1 regulates FGF receptor in skeletal cells, and suppresses FGFR-3 expression in osteoblasts and mediates FGF-2 actions in chondrocytes [78, 79]. In vivo administration of FGF-2 promotes bone and cartilage repair and topical administration of FGF-2 accelerates fracture healing in rodents and nonhuman primates [80, 81]. The mechanism is related to the mitogenic properties of FGF-2 in skeletal cells in conjunction with its angiogenic activity. Although studies in fgf-2 null mice demonstrate that FGF-2 is required for bone formation, transgenic mice overexpressing FGF-2 in the bone environment are osteopenic [68, 67]. This observation is in accordance with in vitro studies demonstrating an inhibitory effect of FGF-2 on Wnt signaling, IGF-I expression, and osteoblastic function [20, 70]. Embryos harboring null mutations of the fgf receptor 2 die prior to skeletogenesis, but conditional inactivation of the FGF receptor 2 results in skeletal dwarfism secondary to decreased proliferation of osteoprogenitors without affecting osteoblast differentiation [82]. These observations confirm early in vitro studies demonstrating a central role of FGF-2 on preosteoblastic cell proliferation, but not a stimulatory effect on osteoblastic function. Investigations on the regulation of FGF synthesis in skeletal cells are limited to FGF-2. In fibroblasts, heat shock induces the release of FGF, suggesting that its secretion is related to cellular stress [83]. The regulation of FGF-2 expression in osteoblasts and nonskeletal fibroblasts is similar, and TGF β1 and FGF-2 increase FGF-2 synthesis in osteoblasts [61]. Sequence analysis of the FGF-2 promoter reveals AP-1 recognition sequences; therefore, signals that induce Fos and Jun, components of the AP-1 complex, have the potential to upregulate fgf-2 gene transcription [84]. PDGF enhances the expression of FGF-2 mRNA levels in fibroblasts, and possibly in osteoblasts. Therefore, skeletal growth factors with mitogenic properties, such as FGF-2 and PDGF, are major inducers of FGF-2 synthesis. PTH
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
causes a transient induction of FGF-2 transcripts in osteoblasts [85]. FGF is stored in the extracellular matrix, where it is complexed by extracellular matrix and cell surface-associated heparan sulfate proteoglycans, which may prolong its half-life and allow future interactions with its receptors [86]. Binding of FGF to heparan sulfate proteoglycans is a necessary step for the presentation of the factor to its receptor. The heparan sulfate proteoglycan syndecan is an integral membrane proteoglycan that binds FGF and components of the extracellular matrix, suggesting that it can regulate the effects of FGF-2 on cell growth [57].
V. TRANSFORMING GROWTH FACTOR BETA TGF β belongs to a family of closely related polypeptides with various degrees of structural homology and important effects on cell function [87, 88]. There are five TFG β genes, and mammalian cells express TGF β1, 2, and 3. Bone matrix contains TGF β1, 2, and 3 homodimers as well as 1.2 and 2.3 heterodimers [88, 89]. TGF β1, 2, and 3 have similar effects on bone cell function although their potency differs [89]. TGF β stimulates DNA synthesis and cell replication and has a modest stimulatory effect on collagen synthesis in calvariae [90]. Bone histomorphometric analysis of intact rat calvariae exposed to TGF β demonstrates a stimulatory effect on mineral apposition rates, and in vivo studies have confirmed a stimulatory effect of TGF β on bone formation [91, 92, 93]. The effects of TGF β on cell replication and the differentiated function of the osteoblast are dependent on the target cell, its state of differentiation and the culture conditions used. In primary cultures of rat osteoblasts, TGF β has a biphasic stimulatory effect on DNA synthesis, whereas in rat osteosarcoma cells it inhibits cell growth [94, 95, 96]. In osteoblasts, TGF β inhibits alkaline phosphatase activity and osteocalcin synthesis, suggesting an inhibitory effect on their differentiated function. TGF β stimulates collagen synthesis by increasing type I collagen gene transcription [97]. In osteosarcoma cells, TGF β increases type I collagen, fibronectin, osteonectin, and osteopontin mRNA expression [98]. In stromal cell cultures, TGF β favors chondrocytic differentiation, and opposes the effect of BMP on osteoblastogenesis [99]. Consequently, whereas TGF β stimulates selected parameters of osteoblastic function, it does not direct the maturation of undifferentiated cells toward osteoblasts, and seems more relevant to chondrogenesis than to osteoblastogenesis. The actions of TGF β on bone resorption also have been a source of controversy. TGF β has a biphasic effect on osteoclastogenesis.
Marcus-Ch19.indd 533
533 At low concentrations it enhances osteoclast formation, whereas at high concentrations it is inhibitory. The stimulatory effect on osteoclast formation seems to be related to the production of prostaglandins, and the inhibitory effect secondary to a decrease in the differentiation of early stem cells into cells of the osteoclast lineage because of a shift toward cells of the granulocyte lineage [100, 101]. The impaired osteoclastogenesis would explain a decrease in bone resorption [102]. Osteoblasts express type I and II TGF β receptors, and PTH and glucocorticoids modify TGF β binding to its receptors on osteoblasts [103, 104]. Glucocorticoids shift the binding of TGF β from type I and II receptors to betaglycan, which is not a signal transducing molecule [105]. In accordance with its actions in vitro, the systemic administration of TGF β2 to experimental animals stimulates cancellous bone formation, and subperiosteal injections of TGF β1 and 2 induce osteogenesis and chondrogenesis in rat femurs [106, 93]. In contrast, transgenic mice overexpressing TGF β2, under the control of the osteoblast specific osteocalcin promoter, exhibit osteopenia [107]. Although TGF β induces chondrocyte differentiation, suppression of TGF β signaling in vivo also favors terminal chondrocyte differentiation, suggesting a dual role of TGF β on chondrocyte maturation [108]. Targeted gene disruption of the mouse tgf b gene does not result in changes in skeletal development [109]. This may be secondary to an early lethal phenotype of tgf b null mice, due to a severe inflammatory disease. TGF β enhances soft tissue wound healing, and like FGF-2 it may play a role in fracture repair [110]. However, its cytostatic actions and its fibrosis-inducing properties would limit its topical and systemic use in the treatment of metabolic bone disorders [111, 112, 113]. TGF β is secreted as a latent high molecular weight complex consisting of the carboxy terminal remnant of the TGF β precursor and a TGF β binding protein [114, 115, 116, 117]. The biologically active levels of TGF β depend on changes in its synthesis and in the activation of its latent form. By inducing lysosomal proteases, bone regulatory agents increase the levels of biologically active TGF β in bone [118, 119]. FGF, TGF β itself, and estrogens increase TGF β1 synthesis in osteoblasts, and ovariectomy reduces the concentration of TGF β in rodent bone [118, 120]. The latter may suggest a role of TGF β in the abnormalities observed in the estrogen deficient state. There have been limited studies on the regulation of TGF β2 and TGF β3 synthesis in osteoblasts, but the tgf b2 and tgf b3 gene promoters contain cyclic AMP responsive elements, indicating a potential regulation by cyclic AMP inducers [121, 122].
8/22/2007 4:17:39 PM
534 VI.
Ernesto Canalis
BONE MORPHOGENETIC PROTEIN
BMPs are members of the TGF β superfamily of polypeptides, and were originally identified because of their ability to induce endochondral bone formation [123, 124, 125]. BMPs account for most of the TGF β superfamily of peptides, and the proteins display extensive conservation among species [123]. BMP-1 is a protease, which cleaves procollagen fibrils, and is unrelated to other BMPs [126]. BMP-3, or osteogenin, is different from other BMPs since it lacks their osteogenetic properties, and it inhibits osteogenesis and opposes BMP-2 actions [127, 128, 129]. Although BMPs are synthesized by skeletal cells, their synthesis is not limited to bone, and they are expressed by a variety of extraskeletal tissues, where they play a critical role in developmental and cellular functions. BMP-1 through -6 are expressed by osteoblasts, but the degree of expression depends on the cell line examined, and its stage of differentiation [130, 131, 132, 133]. BMP-2, -4, and -6 are the most readily detectable BMPs in osteoblast cultures and BMP-2 and -4 are 92% identical in their amino acid sequence and have virtually identical biological activities. Experiments using kinase-deficient truncated BMP receptors or using BMP antagonists have demonstrated that the locally synthesized BMPs play an autocrine role in osteoblastic differentiation and function [134]. A fundamental function of BMPs is the induction of mesenchymal cell differentiation toward cells of the osteoblastic lineage, and to the promotion of osteoblastic activity [135, 136]. As osteoblasts undergo terminal differentiation, they undergo apoptosis, an expected result of cell maturation [137,138,139]. Consequently, BMPs favor osteoblastic cell death. The genesis and differentiation of bone-forming osteoblasts and boneresorbing osteoclasts are coordinated events. Receptor activator of nuclear factor-κ B-ligand (RANK-L) and colony stimulating factor 1 are osteoblast products and are major determinants of osteoclastogenesis [140]. Osteoprotegerin, a secreted receptor of the tumor necrosis factor receptor family, acts as a decoy receptor that binds RANK-L, precluding RANK-L binding to RANK and its effects on osteoclastogenesis and bone resorption. BMPs play a direct and indirect role in osteoclastogenesis. By inducing osteoblast maturation, there is increased RANK-L availability. In addition, BMPs sensitize osteoclasts to the effects of RANK-L on osteoclastogenesis and osteoclast survival [141, 142]. BMPs also induce osteoprotegerin transcription, and this may temper their effects on osteoclastogenesis [143]. BMPs inhibit collagenase 3 or MMP-13 expression in osteoblasts, a matrix metalloprotease required for normal bone resorption [144, 145].
Marcus-Ch19.indd 534
BMPs induce endochondral ossification and chondrogenesis [146]. BMPs stimulate chondrocyte maturation and function, increasing the expression of type II and type X collagens and the incorporation of sulfate into glycosaminoglycans [147,148]. Overexpression of BMP-2 and -4 in developing limbs results in an increase in chondrocyte number and in matrix cartilage, which may lead to joint fusions [149]. The anabolic effects of Indian and Sonic hedgehog and BMP-2 and -4 in metatarsal cultures are analogous, and BMPs mediate their actions on endochondral ossification [150]. Whereas BMPs induce osteogenesis and chondrogenesis, they prevent terminal differentiation of myogenic cells, inhibiting the transcription of the muscle-specific nuclear factors MyoD and myogenin [151, 152]. BMPs act in conjunction with other growth factors, and by inducing the differentiation of cells of the osteoblastic lineage, BMPs increase the pool of IGF-I producing and IGF-I target cells [153]. BMPs interact with type IA or activin receptor like kinase (ALK)-3 and type IB or ALK-6, and BMP type II receptors [154]. Upon ligand binding and activation of the type I receptor, dimers of the type I and type II receptor initiate a signal transduction cascade activating the signaling mothers against decapentaplegic (Smad) or the MAP kinase signaling pathways [155, 156]. Following receptor activation by BMPs, Smad 1, 5 and 8 are phosphorylated at serine residues, and translocated into the nucleus following heterodimerization with Smad 4 [157, 158]. In the nucleus, Smads can bind to DNA sequences directly, bind and cooperate with other transcription factors, or bind and displace nuclear factors from their DNA binding sites. MAP kinase signaling results in P38 MAP kinase or extracellular regulated kinase (ERK) activation by BMPs [87, 159]. The transcriptional and post-transcriptional regulation of BMP expression in osteoblasts reveals autoregulation of BMP synthesis since BMP-2 and -4 mRNA levels are BMP dependent [130, 132]. BMPs cause an early, short lived, induction of BMP-4 mRNA in osteoblasts followed by an inhibitory effect. A positive feedback loop regulating BMP-2 and -4 expression involving Runx-2 is possible since BMPs induce Runx-2 expression and the BMP-2 and -4 promoters contain Runx-2 binding sequences. BMP-6 expression in osteoblasts is steroid-dependent, and BMP-6 mRNA levels are induced by estrogens [133]. Mice deficient in BMP-2 are not viable due to placental and developmental defects, and the bmp-4 null mutation is lethal between 6.5 and 9.5 days of gestation due to a lack of mesodermal differentiation, and patterning defects [160, 161]. Mice with disruptions of the BMP signaling smad 5 gene also develop multiple embryonic defects, some reminiscent of those observed
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
in bmp-2 null mutants [162, 163]. The lethality of these mutations has prevented the assessment of the impact of BMP-2 and -4 on the adult skeleton. The bmp-6 null mutation is not lethal, and skeletogenesis is normal except for delayed ossification in the sternum [164]. bmp gene inactivation results in significant developmental defects outside the skeleton, and bmp-7 null mice display lack of eye and glomerular development, and bmp-8 null mutations result in defective spermatogenesis [165, 166]. BMP activity is regulated by a large group of secreted polypeptides that bind and limit BMP action. These extracellular BMP antagonists prevent BMP signaling by binding BMPs, and precluding their binding to cell surface receptors [167,168]. Extracellular BMP antagonists include noggin, follistatin and follistatin related gene; ventroptin; twisted gastrulation; the chordin family, which is comprised of chordin, chordin-like, neuralin, CR rich motor neuron, BMP binding endothelial cell precursor-derived regulator, kielin, and crossveinless; and the Dan/cerberus family of genes, which is comprised of the tumor suppressor Dan, Cerberus, Cer 1, gremlin, and its rat homologue drm, the protein related to Dan and Cerberus, caronte, Dante, sclerostin (the product of the sost gene), Wise, and Coco [167, 169, 170, 171]. It is of interest that selected BMP antagonists, such as sclerostin and Coco, also block Wnt signaling [172, 173]. The pattern of tissue expression of BMP antagonists is dependent on the gene studied. Sclerostin is expressed selectively in osteoblasts and osteocytes, where it is regulated by PTH, and ectodin is expressed in tooth enamel [174, 175]. Overexpression of noggin and gremlin, two classic BMP antagonists, or sclerostin, in the skeletal microenvironment prevents osteoblastic differentiation in vitro, and in vivo causes osteopenia secondary to decreased bone formation [176, 177, 178, 179]. Inactivation of the noggin gene causes intrauterine lethality, and articular developmental defects leading to joint fusions [180]. It is of interest that the synthesis of many BMP antagonists, such as that of noggin and gremlin, is induced by BMPs in osteoblasts, suggesting the existence of a protective mechanism to prevent skeletal cells from excessive exposure to BMPs [181, 182].
VII.
INSULIN-LIKE GROWTH FACTOR
IGF-I and -II have structural similarities with proinsulin and are considered essential for normal cell growth in multiple tissues including bone [183]. IGF-I and -II are present in the systemic circulation and are secreted by the osteoblast. In the circulation, IGF-I forms a large molecular weight complex with
Marcus-Ch19.indd 535
535 insulin-like growth factor binding proteins (IGFBPs) and the acid labile subunit [184]. Although several IGFBPs form the complex, IGFBP-3 is the most abundant, and systemic IGF-I and IGFBP-3 levels are growth hormone (GH) dependent. IGFBPs are present in the circulation at concentrations in excess of those of IGF-I. Consequently, there is little free IGF-I in plasma. Systemic IGF-I is mostly synthesized in the liver and it is responsible for the growth-promoting effects of GH in various tissues [185, 186, 187]. It is important to note that IGF-I is synthesized by multiple peripheral tissues, where it is regulated by alternate hormones, and only to a minor extent by GH. In addition to their function as systemic regulators of growth, IGF-I and -II play an important role in the autocrine and paracrine regulation of cell metabolism in a variety of tissues, including bone [188, 189]. IGF-I and -II are the most prevalent growth factors present in the skeletal tissue. IGF-I and -II have similar effects on bone formation, although IGF-I is more potent than IGF-II [190, 191]. IGFs are modest mitogens, increasing the replication of preosteoblastic cells, which presumably differentiate into mature osteoblasts. The most important function of IGFs is to enhance the differentiated function of the osteoblast. IGFs stimulate type I collagen transcription, an effect independent from their mitogenic actions, and increase mineral apposition rates [192, 191]. IGF-I and -II inhibit collagenase 3 (MMP-13) synthesis by the osteoblast and as a consequence decrease bone collagen degradation [193]. IGF-I and -II are important in the maintenance of the differentiated osteoblast phenotype. IGFs not only enhance osteoblastic function, but their synthesis is differentially regulated by factors that stimulate or inhibit the differentiated expression of the osteoblastic phenotype [20]. A similar role has been suggested for IGF-II in myoblasts, where its expression follows that of genes that are determinants of myogenic differentiation [194]. It is important to note that whereas IGF-I stimulates the differentiated function of the osteoblast, it does not induce the differentiation of marrow stromal cells toward the osteoblastic pathway [195]. Indirectly, IGF-I might favor osteoblastogenesis since it stabilizes β catenin; consequently it has the potential to enhance the Wnt/β catenin signaling pathway, which is essential for osteoblastogenesis [196]. Although the primary role of IGFs is the stimulation of bone formation, IGF-I can increase the synthesis of RANK-L by osteoblasts and, in this way, enhance osteoclast recruitment, although in vivo experiments have demonstrated an inconsistent impact of IGF-I on osteoclastogenesis [197, 198, 199]. Skeletal cells express the IGF-I and IGF-II receptors, and the IGF-I receptor mediates their anabolic actions. This receptor is a transmembrane glycoprotein
8/22/2007 4:17:39 PM
536 tetramer with ligand-activated tyrosine kinase activity. Insulin receptor substrate (IRS) 1 and 2 are well-characterized substrates for the IGF receptor tyrosine kinase, mediating the effects of IGF-I [200, 201]. In osteoblasts, tyrosine phosphorylation of IRS molecules by the activated receptor results in the activation of PI-3 kinase-phospho Akt signaling or in the activation of the MAP kinases, p38, Jun-N-terminal kinases and ERK1/2 [202]. The IGF-II receptor is the same as the mannose-6-phosphate receptor, does not have a function in IGF signal transduction, and clears IGF-II, regulating its levels during fetal development [203]. IGF-I receptor number in osteoblasts can be modulated by various agents, known to regulate bone cell metabolism, including PDGF, glucocorticoids, and 1,25 dihydroxyvitamin D3 [204, 205, 206, 207]. IGF-I has been tested for its effects on bone metabolism in vivo in experimental animals and humans. IGF-I increases bone formation and prevents trabecular bone loss in experimental conditions of skeletal unloading and increases bone mineral density (BMD) in ovariectomized animals [208]. The short-term administration of IGF-I to normal humans results in an increase in serum levels of type I procollagen peptide and an increase in the excretion of collagen crosslinks, demonstrating an increase in bone turnover [209]. IGF-I increases BMD in patients with osteopenia secondary to anorexia nervosa, but the potential use of IGF-I in humans may be limited by possible side effects and the lack of skeletal specificity [210]. The content of IGF-I in human cortical bone decreases with age, a decline that parallels the one observed in serum concentrations of IGF-I with aging [211,212]. Consequently, it is not known whether it is due to a decrease in skeletal IGF-I accumulation from the systemic circulation, or due to a decrease in the synthesis of IGF-I by the aging skeleton. The study of genetically engineered mice has provided additional insight into the action of IGF-I in vivo. Transgenic mice overexpressing IGF-I under the control of the osteocalcin promoter exhibit a transient increase in trabecular bone volume secondary to an increase in osteoblast function and bone formation [197]. igf-1 and igf-1 receptor gene deletions have provided valuable information on the role of IGF-I during development, and conditional gene deletions have provided information on the effects of IGF-I in the adult skeleton [213, 186]. igf-1 deletion causes a reduction in chondrocyte maturation, and femoral length, and osteopenia secondary to a decrease in bone formation [186, 214]. Mice carrying mutations of the GH releasing hormone receptor or of the GH receptor have absent GH secretion or action, and consequently low serum IGF-I [215, 216]. These models allow for the determination of the contribution of systemic IGF-I
Marcus-Ch19.indd 536
Ernesto Canalis
to the skeleton, and the phenotype of either mutant is characterized by small growth plates, osteopenia and reduced cortical bone, but normal trabecular bone volume. This suggests a more pronounced role of systemic IGF-I on cortical than on trabecular bone. Mice carrying a liver-specific igf-1 deletion display a 75% reduction in total serum IGF-I levels, normal free IGFI levels, and absent skeletal phenotype attributed to the normal serum levels of free IGF-I and the extra hepatic synthesis of IGF-I [217]. However, mice carrying dual deletions of igf-1 and the acid labile subunit display marked reduction in total serum IGF-I and a significant reduction of cortical bone volume [218]. Igf-1 receptor null mice die after birth and demonstrate severe growth retardation, and the conditional disruption of the igf-1 receptor gene selectively in osteoblastic cells causes a decrease in osteoblast number, and impaired bone formation resulting in reduced trabecular bone volume [186, 198]. This observation documents the fundamental role played by IGF-I in the maintenance of bone formation and structure. Accordingly, deletion of the irs-1 or -2 gene causes osteopenia [219, 220]. However the phenotypes are not identical and irs-1 null mice exhibit low bone turnover osteopenia and do not respond to PTH, whereas igf-2 null mice exhibit increased bone resorption and respond to the anabolic effects of PTH in bone [220]. The various models described confirm the anabolic function of IGF-I on bone. Skeletal IGF-I might play a more important role in the maintenance of trabecular bone, and systemic IGF-I might be more important in the regulation of cortical bone. The igf-1 gene is complex, contains six exons, and has alternate promoters in exons 1 and 2 [221, 222]. The exon 1 promoter has four transcription initiation sites, and is responsible for the regulation of IGF-I expression in most extrahepatic tissues including bone [223]. The IGF-I exon 2 promoter has two transcription initiation sites and is responsible for the transcriptional regulation of IGF-I by GH in the liver [223]. IGF-I exon 2 is minimally expressed by osteoblasts, and GH is not a major inducer of IGF-I in these cells [224]. Hormones and growth factors regulate the synthesis of IGF-I in osteoblasts, and PTH, PTH related peptide, and other inducers of cyclic AMP in osteoblasts increase IGF-I synthesis [224]. IGF-I mediates selected anabolic actions of PTH in bone in vitro and in vivo [225]. The stimulatory effect of PTH on collagen synthesis in vitro is decreased by IGF-I neutralizing antibodies, and the stimulatory effect of PTH on bone formation in vivo is not observed in igf-1 or irs-1 null mice [226, 220]. These observations do not exclude the possibility that other factors mediate selected actions of PTH on the skeleton. For example, the effects of PTH on cell replication in the skeleton are independent
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
of IGF-I synthesis and are dependent on Notch activation [227]. PTH also increases the levels of, and activates, skeletal TGF β, which could mediate selected effects of PTH in bone [228]. Estrogens increase and glucocorticoids inhibit IGF-I synthesis in osteoblasts [229, 230]. Selected inhibitory effects of glucocorticoids on bone metabolism can be explained by reduced IGF-I levels in the bone microenvironment. However, glucocorticoids also inhibit osteoblastic gene expression and function directly. In addition to hormones, skeletal growth factors regulate IGF-I synthesis. PDGF, FGF, and TGF β1 decrease IGF-I transcripts and polypeptide levels in osteoblasts, and this inhibition of IGF-I synthesis correlates with their inhibitory actions on osteoblastic differentiated function [20]. In contrast, BMP-2, an agent that enhances osteoblastic differentiation and function, increases IGF-I synthesis in osteoblasts [153]. The igf-2 gene is complex and contains four promoters, and in osteoblasts, like in hepatocytes, IGF-II expression is under the control of the IGF-II P3 promoter [231, 232]. Hormones do not modify IGF-II synthesis in skeletal cells. The skeletal growth factors FGF-2, PDGF, and TGF β1 inhibit IGF-II transcription by inhibiting IGF-II P3 activity, an effect analogous to their inhibition of IGF-I expression, demonstrating a coordinated suppression of IGF-I and -II synthesis by mitogenic growth factors [231].
VIII. INSULIN-LIKE GROWTH FACTOR BINDING PROTEINS IGFBPs are a family of related proteins known to bind specifically IGF-I and -II. There are six classic IGFBPs, termed IGFBP-1 to -6, and additional IGFBP related proteins [184]. There are significant structural similarities in IGFBPs among species, indicating a high degree of evolutionary conservation. Osteoblasts express IGFBP-1 to -6 transcripts [233]. IGFBPs regulate the bioavailability of IGFs and prevent their degradation. IGFBPs can potentiate or inhibit the effects of IGF-I and -II on cell function and vary in their affinity for IGF-I and IGF-II [184, 183]. The binding of IGFs to IGFBPs may sequester the growth factor and preclude its interactions with cell surface receptors, although IGFBPs associated with the extracellular matrix may increase the local effective concentration of the growth factor and potentiate its effects [234, 235]. In addition, IGFBPs may have IGF independent effects and regulate cellular events directly. IGFBP-2 is important in the storage and transport of IGFs, and IGFBP-2 serum levels correlate with BMD in humans [236]. In vitro, IGFBP-2 prevents the effects
Marcus-Ch19.indd 537
537 of IGF-I on osteoblast function, and overexpression of IGFBP-2 under the control of the cytomegalovirus (CMV) promoter leads to small mice with decreased bone mineral content and failure to respond to the anabolic effects of GH in bone [237]. IGFBP-3 is the major component of the IGF complex in serum and, like the circulating IGF-I, is GH dependent [184]. IGFBP-3 can inhibit or stimulate IGF activities, the latter by upregulating IGF-I delivery to cell surface receptors. Overexpression of IGFBP-3 under the control of the CMV or phosphoglycerate kinase promoter causes growth retardation and osteopenia [238]. IGBP4 is an IGF-I inhibitory binding protein, but under specific conditions IGFBP-4 and IGFBP-5 were reported to stimulate bone cell function independent from their interactions with IGF-I [239, 240]. However, transgenic mice overexpressing either IGFBP-4 or IGFBP-5 under the control of the osteoblast specific osteocalcin promoter exhibit osteopenia and decreased bone formation [241, 242]. The osteopenia is probably secondary to sequestration of the IGF-I present in the bone microenvironment inhibiting its biological activity. It is possible that the different reported effects of IGFBP-4 and -5 are dependent on their interactions with extracellular matrix proteins, or on the levels of IGFBP present in a specific tissue. However, both transgenic models indicate that IGFBP-4 and IGFBP-5 are inhibitory proteins in the skeletal environment. This was documented further using retroviral vectors to overexpress IGFBP-5, in osteoblastic cells, which provoked an inhibition of osteoblastic cell function [243]. IGFBP-1 is important for glucose homeostasis, and there is limited information on the function of IGFBP-6 in skeletal tissue. The synthesis of IGFBPs is regulated by transcriptional, post-transcriptional, and post-translational mechanisms. Although the six IGFBPs are expressed by skeletal and nonskeletal cells, their basal and regulated expression is cell specific [244, 245]. In vitro studies indicate that the pattern of IGFBP expression is dependent on the stages of osteoblast differentiation. IGFBP-2 and -5 expression is highest in the proliferative phase of rat osteoblastic cell cultures, and IGFBP3, -4, and -6 expression peaks during the maturation phase [246]. The regulation of IGFBP expression during osteoblastic cell differentiation may be related to the relative levels of autocrine and paracrine factors present in the cellular environment. IGFs increase osteoblast IGFBP-5 expression, whereas growth factors with mitogenic activity inhibit IGFBP-5 and stimulate IGFBP-4 expression [247, 248, 249]. In addition to local autocrine and paracrine factors, systemic hormones modulate IGFBP synthesis; however, the effects appear to be cell line and culture condition dependent [244]. GH increases IGFBP-3 in
8/22/2007 4:17:39 PM
538
Ernesto Canalis
normal rat osteoblasts, but not in osteosarcoma cells, and cyclic AMP inducers increase the synthesis of IGFBP-3, -4, and -5 [245]. Since agents that induce cyclic AMP in osteoblasts also stimulate the synthesis of IGF-I, the induction of the binding proteins may be a mechanism to control overexposure of cells to the newly synthesized IGF-I. Conversely, glucocorticoids inhibit the synthesis of IGF-I, IGFBP-3, -4 and -5, although they increase the expression of the inhibitory IGFBP-2 in osteoblasts, leading to a marked suppression of IGF-I available to skeletal cells [229, 233]. 1,25-dihydroxyvitamin D3 increases osteoblast IGFBP3 and -4 expression [250]. The abundance of IGFBPs in the extracellular space can be regulated by proteolytic degradation. IGFBP proteases have been characterized from diverse sources, including osteoblasts, which secrete MMPs and serine proteases [251]. Interestingly, the protease activity for IGFBP-4, an inhibitory IGFBP, and for IGFBP-5 is modulated by IGFs, which promote the degradation of IGFBP-4 and stabilize IGFBP-5, suggesting an alternate mechanism by which IGF activity can be modulated in bone [252]. The activity or synthesis of IGFBP proteases is modulated by agents known to regulate bone remodeling, such as IL-6 and glucocorticoids [253, 254].
IX.
HEPATOCYTE GROWTH FACTOR
Hepatocyte growth factor (HGF), also known as Scatter factor, is a large molecular weight polypeptide known for its angiogenic and mitogenic properties [255]. HGF plays a role in liver and kidney repair [256, 257]. HGF signals via the product of the protooncogene c-met, a tyrosine kinase-activated receptor, and HGF and c-met are expressed by mesenchymal cells, osteoblasts, and osteoclasts [258, 259]. HGF is mitogenic for cells of the osteoblastic and osteoclastic lineage, and its synthesis by the osteoblast is enhanced by growth factors with a role in wound and fracture repair [260]. Therefore, HGF may play a role in bone remodeling and repair. Studies in transgenic mice overexpressing HGF under the control of the metallothionein I promoter and studies in hgf or c-met null mice have revealed that HGF is required for muscle cell migration [261, 262]. hgf null mutants fail to form normal muscles, but due to embryonic lethality, the skeletal phenotype was not examined. FGF-2 and PDGF increase the synthesis of HGF by osteoblasts, whereas glucocorticoids are inhibitory [258, 262]. Since HGF plays a role in mitogenesis and tissue repair, inhibition of its synthesis by glucocorticoids may be relevant to the inhibitory effect of these steroids on wound healing
Marcus-Ch19.indd 538
and tissue repair. Recently, HGF and c-met were found to be expressed at the site of fractured bone and HGF to induce BMP receptors [263]. Through this mechanism HGF may contribute to fracture healing and repair.
ACKNOWLEDGMENTS The work described in this chapter was supported by grants from the National Institutes of Health AR 21707, DK 42424, and DK 45227. The author thanks Ms. Marcia Dupont and Ms. Mary Yurczak for valuable secretarial assistance.
REFERENCES 1. L. Fredriksson, H. Li, and U. Eriksson. The PDGF family: Four gene products form five dimeric isoforms. Cytokine Growth Factor Rev, 15, 197–204 (2004). 2. N. Ferrara and T. Davis-Smyth. The biology of vascular endothelial growth factor. Endocr Rev, 18, 4–25 (1997). 3. L. J. Reigstad, J. E. Varhaug, and J. R. Lillehaug. Structural and functional specificities of PDGF-C and PDGF-D, the novel members of the platelet-derived growth factors family. FEBS J, 272, 5723–5741 (2005). 4. D. G. Gilbertson, M. E. Duff, J. W. West, J. D. Kelly, P. O. Sheppard, P. D. Hofstrand, Z. Gao, K. Shoemaker, T. R. Bukowski, M. Moore, A. L. Feldhaus, J. M. Humes, T. E. Palmer, and C. E. Hart. Platelet-derived growth factor C (PDGF-C), a novel growth factor that binds to PDGF alpha and beta receptor. J Biol Chem, 276, 27406–27414 (2001). 5. E. Bergsten, M. Uutela, X. Li, K. Pietras, A. Ostman, C. H. Heldin, K. Alitalo, and U. Eriksson. PDGF-D is a specific, protease-activated ligand for the PDGF beta-receptor. Nat Cell Biol, 3, 512–516 (2001). 6. W. J. LaRochelle, M. Jeffers, W. F. McDonald, R. A. Chillakuru, N. A. Giese, N. A. Lokker, C. Sullivan, F. L. Boldog, M. Yang, C. Vernet, C. E. Burgess, E. Fernandes, L. L. Deegler, B. Rittman, J. Shimkets, R. A. Shimkets, J. M. Rothberg, and H. S. Lichenstein. PDGF-D, a new proteaseactivated growth factor. Nat Cell Biol, 3, 517–521 (2001). 7. C. Betsholtz, A. Johnsson, C. H. Heldin, B. Westermark, P. Lind, M. S. Urdea, R. Eddy, T. B. Shows, K. Philpott, and A. L. Mellor. cDNA sequence and chromosomal localization of human platelet-derived growth factor A-chain and its expression in tumour cell lines. Nature, 320, 695–699 (1986). 8. H. Ding, X. Wu, I. Kim, P. P. Tam, G. Y. Koh, and A. Nagy. The mouse Pdgfc gene: Dynamic expression in embryonic tissues during organogenesis. Mech Dev, 96, 209–213 (2000). 9. S. Rydziel, S. Shaikh, and E. Canalis. Platelet-derived growth factor-AA and -BB (PDGF-AA and -BB) enhance the synthesis of PDGF-AA in bone cell cultures. Endocrinology, 134, 2541–2546 (1994). 10. A. Ponten, E. B. Folestad, K. Pietras, and U. Eriksson. Platelet-derived growth factor D induces cardiac fibrosis and proliferation of vascular smooth muscle cells in heart-specific transgenic mice. Circ Res, 97, 1036–1045 (2005). 11. B. Westermark and C. H. Heldin. Platelet-derived growth factor. Structure, function and implications in normal and malignant cell growth. Acta Oncol, 32, 101–105 (1993).
8/22/2007 4:17:40 PM
539
Chapter 19 Skeletal Growth Factors
12. L. Claesson-Welsh, A. Eriksson, B. Westermark, and C. H. Heldin. cDNA cloning and expression of the human A-type platelet-derived growth factor (PDGF) receptor establishes structural similarity to the B-type PDGF receptor. Proc Natl Acad Sci USA, 86, 4917–4921 (1989). 13. R. G. Gronwald, F. J. Grant, B. A. Haldeman, C. E. Hart, P. J. O’Hara, F. S. Hagen, R. Ross, D. F. Bowen-Pope, and M. J. Murray. Cloning and expression of a cDNA coding for the human platelet-derived growth factor receptor: Evidence for more than one receptor class. Proc Natl Acad Sci USA, 85, 3435–3439 (1988). 14. R. A. Seifert, C. E. Hart, P. E. Phillips, J. W. Forstrom, R. Ross, M. J. Murray, and D. F. Bowen-Pope. Two different subunits associate to create isoform-specific platelet-derived growth factor receptors. J Biol Chem, 264, 8771–8778 (1989). 15. Y. Yarden, J. A. Escobedo, W. J. Kuang, T. L. Yang-Feng, T. O. Daniel, P. M. Tremble, E. Y. Chen, M. E. Ando, R. N. Harkins, and U. Francke. Structure of the receptor for plateletderived growth factor helps define a family of closely related growth factor receptors. Nature, 323, 226–232 (1986). 16. M. Centrella, T. L. McCarthy, W. F. Kusmik, and E. Canalis. Isoform-specific regulation of platelet-derived growth factor activity and binding in osteoblast-enriched cultures from fetal rat bone. J Clin Invest, 89, 1076–1084 (1992). 17. J. M. Hock and E. Canalis. Platelet-derived growth factor enhances bone cell replication, but not differentiated function of osteoblasts. Endocrinology, 134, 1423–1428 (1994). 18. H. Tanaka and C. T. Liang. Effect of platelet-derived growth factor on DNA synthesis and gene expression in bone marrow stromal cells derived from adult and old rats. J Cell Physiol, 164, 367–375 (1995). 19. E. Canalis, T. L. McCarthy, and M. Centrella. Effects of platelet-derived growth factor on bone formation in vitro. J Cell Physiol, 140, 530–537 (1989). 20. E. Canalis, J. Pash, B. Gabbitas, S. Rydziel, and S. Varghese. Growth factors regulate the synthesis of insulin-like growth factor-I in bone cell cultures. Endocrinology, 133, 33–38 (1993). 21. B. Gabbitas, J. Pash, and E. Canalis. Regulation of insulinlike growth factor-II synthesis in bone cell cultures by skeletal growth factors. Endocrinology, 135, 284–289 (1994). 22. G. D. Roodman. Interleukin-6: An osteotropic factor? J Bone Miner Res, 7, 475–478 (1992). 23. L. S. Holliday, H. G. Welgus, C. J. Fliszar, G. M. Veith, J. J. Jeffrey, and S. L. Gluck. Initiation of osteoclast bone resorption by interstitial collagenase. J Biol Chem, 272, 22053–22058 (1997). 24. S. Varghese, A. M. Delany, L. Liang, B. Gabbitas, J. J. Jeffrey, and E. Canalis. Transcriptional and posttranscriptional regulation of interstitial collagenase by platelet-derived growth factor BB in bone cell cultures. Endocrinology, 137, 431–437 (1996). 25. W. Zhao, M. H. Byrne, B. F. Boyce, and S. M. Krane. Bone resorption induced by parathyroid hormone is strikingly diminished in collagenase-resistant mutant mice. J Clin Invest, 103, 517–524 (1999). 26. L. Claesson-Welsh. Platelet-derived growth factor receptor signals. J Biol Chem, 269, 32023–32026 (1994). 27. C. H. Heldin, A. Ernlund, C. Rorsman, and L. Ronnstrand. Dimerization of B-type platelet-derived growth factor receptors occurs after ligand binding and is closely associated with receptor kinase activation. J Biol Chem, 264, 8905–8912 (1989). 28. R. S. Gilardetti, M. S. Chaibi, J. Stroumza, S. R. Williams, H. N. Antoniades, D. C. Carnes, and D. T. Graves. High-affinity binding of PDGF-AA and PDGF-BB to normal human osteo-
Marcus-Ch19.indd 539
29.
30.
31.
32.
33.
34.
35. 36.
37. 38.
39. 40.
41.
42.
blastic cells and modulation by interleukin-1. Am J Physiol, 261, C980–C985 (1991). T. Tsukamoto, T. Matsui, H. Nakata, M. Ito, T. Natazuka, M. Fukase, and T. Fujita. Interleukin-1 enhances the response of osteoblasts to platelet-derived growth factor through the alpha receptor-specific up-regulation. J Biol Chem, 266, 10143–10147 (1991). K. N. Kose, J. F. Xie, D. L. Carnes, and D. T. Graves. Proinflammatory cytokines downregulate platelet derived growth factor-alpha receptor gene expression in human osteoblastic cells. J Cell Physiol, 166, 188–197 (1996). X. Li, M. Tjwa, L. Moons, P. Fons, A. Noel, A. Ny, J. M. Zhou, J. Lennartsson, H. Li, A. Luttun, A. Ponten, L. Devy, A. Bouche, H. Oh, A. Manderveld, S. Blacher, D. Communi, P. Savi, F. Bono, M. Dewerchin, J. M. Foidart, M. Autiero, J. M. Herbert, D. Collen, C. H. Heldin, U. Eriksson, and P. Carmeliet. Revascularization of ischemic tissues by PDGFCC via effects on endothelial cells and their progenitors. J Clin Invest, 115, 118–127 (2005). B. H. Mitlak, R. D. Finkelman, E. L. Hill, J. Li, B. Martin, T. Smith, M. D’Andrea, H. N. Antoniades, and S. E. Lynch. The effect of systemically administered PDGF-BB on the rodent skeleton. J Bone Miner Res, 11, 238–247 (1996). L. J. Marden, R. S. Fan, G. F. Pierce, A. H. Reddi, and J. O. Hollinger. Platelet-derived growth factor inhibits bone regeneration induced by osteogenin, a bone morphogenetic protein, in rat craniotomy defects. J Clin Invest, 92, 2897–2905 (1993). T. F. Deuel, R. S. Kawahara, T. A. Mustoe, and A. F. Pierce. Growth factors and wound healing: Platelet-derived growth factor as a model cytokine. Annu Rev Med, 42, 567–584 (1991). C. Betsholtz. Insight into the physiological functions of PDGF through genetic studies in mice. Cytokine Growth Factor Rev, 15, 215–228 (2004). P. Leveen, M. Pekny, S. Gebre-Medhin, B. Swolin, E. Larsson, and C. Betsholtz. Mice deficient for PDGF B show renal, cardiovascular, and hematological abnormalities. Genes Dev, 8, 1875–1887 (1994). P. Soriano. Abnormal kidney development and hematological disorders in PDGF beta-receptor mutant mice. Genes Dev, 8, 1888–1896 (1994). M. Fruttiger, L. Karlsson, A. C. Hall, A. Abramsson, A. R. Calver, H. Bostrom, K. Willetts, C. H. Bertold, J. K. Heath, C. Betsholtz, and W. D. Richardson. Defective oligodendrocyte development and severe hypomyelination in PDGF-A knockout mice. Development, 126, 457–467 (1999). M. D. Tallquist and P. Soriano. Cell autonomous requirement for PDGFRalpha in populations of cranial and cardiac neural crest cells. Development, 130, 507–518 (2003). H. Ding, X. Wu, H. Bostrom, I. Kim, N. Wong, B. Tsoi, M. O’Rourke, G. Y. Koh, P. Soriano, C. Betsholtz, T. C. Hart, M. L. Marazita, L. L. Field, P. P. Tam, and A. Nagy. A specific requirement for PDGF-C in palate formation and PDGFRalpha signaling. Nat Genet, 36, 1111–1116 (2004). J. S. Campbell, S. D. Hughes, D. G. Gilbertson, T. E. Palmer, M. S. Holdren, A. C. Haran, M. M. Odell, R. L. Bauer, H. P. Ren, H. S. Haugen, M. M. Yeh, and N. Fausto. Platelet-derived growth factor C induces liver fibrosis, steatosis, and hepatocellular carcinoma. Proc Natl Acad Sci USA, 102, 3389–3394 (2005). S. Rydziel, C. Ladd, T. L. McCarthy, M. Centrella, and E. Canalis. Determination and expression of platelet-derived growth factor-AA in bone cell cultures. Endocrinology, 130, 1916–1922 (1992).
8/22/2007 4:17:40 PM
540 43. C. J. Robinson and S. E. Stringer. The splice variants of vascular endothelial growth factor (VEGF) and their receptors. J Cell Sci, 114, 853–865 (2001). 44. N. Ferrara, K. Carver-Moore, H. Chen, M. Dowd, L. Lu, K. S. O’Shea, L. Powell-Braxton, K. J. Hillan, and M. W. Moore. Heterozygous embryonic lethality induced by targeted inactivation of the VEGF gene. Nature, 380, 439–442 (1996). 45. E. Zelzer and B. R. Olsen. Multiple roles of vascular endothelial growth factor (VEGF) in skeletal development, growth, and repair. Curr Top Dev Biol, 65, 169–187 (2005). 46. H. P. Gerber, T. H. Vu, A. M. Ryan, J. Kowalski, Z. Werb, and N. Ferrara. VEGF couples hypertrophic cartilage remodeling, ossification and angiogenesis during endochondral bone formation. Nat Med, 5, 623–628 (1999). 47. E. Zelzer, R. Mamluk, N. Ferrara, R. S. Johnson, E. Schipani, and B. R. Olsen. VEGFA is necessary for chondrocyte survival during bone development. Development, 131, 2161–2171 (2004). 48. S. Niida, T. Kondo, S. Hiratsuka, S. Hayashi, N. Amizuka, T. Noda, K. Ikeda, and M. Shibuya. VEGF receptor 1 signaling is essential for osteoclast development and bone marrow formation in colony-stimulating factor 1–deficient mice. Proc Natl Acad Sci USA, 102, 14016–14021 (2005). 49. J. Street, M. Bao, L. deGuzman, S. Bunting, F. V. Peale, Jr., N. Ferrara, H. Steinmetz, J. Hoeffel, J. L. Cleland, A. Daugherty, N. van Bruggen, H. P. Redmond, R. A. Carano, and E. H. Filvaroff. Vascular endothelial growth factor stimulates bone repair by promoting angiogenesis and bone turnover. Proc Natl Acad Sci USA, 99, 9656–9661 (2002). 50. E. Zelzer, W. McLean, Y. S. Ng, N. Fukai, A. M. Reginato, S. Lovejoy, P. A. D’Amore, and B. R. Olsen. Skeletal defects in VEGF(120/120) mice reveal multiple roles for VEGF in skeletogenesis. Development, 129, 1893–1904 (2002). 51. M. O. Hiltunen, M. Ruuskanen, J. Huuskonen, A. J. Mahonen, M. Ahonen, J. Rutanen, V. M. Kosma, A. Mahonen, H. Kroger, and S. Yla-Herttuala. Adenovirus-mediated VEGFA gene transfer induces bone formation in vivo. FASEB J, 17, 1147–1149 (2003). 52. N. Akeno, J. Robins, M. Zhang, M. F. Czyzyk-Krzeska, and T. L. Clemens. Induction of vascular endothelial growth factor by IGF-I in osteoblast-like cells is mediated by the PI3K signaling pathway through the hypoxia-inducible factor-2alpha. Endocrinology, 143, 420–425 (2002). 53. Y. Kanno, A. Ishisaki, M. Yoshida, H. Tokuda, O. Numata, and O. Kozawa. SAPK/JNK plays a role in transforming growth factor-beta-induced VEGF synthesis in osteoblasts. Horm Metab Res, 37, 140–145 (2005). 54. H. Tokuda, K. Hirade, X. Wang, Y. Oiso, and O. Kozawa. Involvement of SAPK/JNK in basic fibroblast growth factor-induced vascular endothelial growth factor release in osteoblasts. J Endocrinol, 177, 101–107 (2003). 55. H. Tokuda, D. Hatakeyama, T. Shibata, S. Akamatsu, Y. Oiso, and O. Kozawa. p38 MAP kinase regulates BMP-4–stimulated VEGF synthesis via p70 S6 kinase in osteoblasts. Am J Physiol Endocrinol Metab, 284, E1202–E1209 (2003). 56. M. M. Deckers, R. L. van Bezooijen, H. G. van der, J. Hoogendam, B. C. van Der, S. E. Papapoulos, and C. W. Lowik. Bone morphogenetic proteins stimulate angiogenesis through osteoblast-derived vascular endothelial growth factor A. Endocrinology 143, 1545–1553 (2002). 57. N. Itoh and D. M. Ornitz. Evolution of the Fgf and Fgfr gene families. Trends Genet, 20, 563–569 (2004). 58. A. Baird and D. M. Ornitz. Fibroblast growth factors and their receptors. In Skeletal Growth Factors (E. Canalis, ed.), pp. 167–178. Lippincott Williams & Wilkins, Philadelphia (2000).
Marcus-Ch19.indd 540
Ernesto Canalis
59. F. Esch, A. Baird, N. Ling, N. Ueno, F. Hill, L. Denoroy, R. Klepper, D. Gospodarowicz, P. Bohlen, and R. Guillemin. Primary structure of bovine pituitary basic fibroblast growth factor (FGF) and comparison with the amino-terminal sequence of bovine brain acidic FGF. Proc Natl Acad Sci USA, 82, 6507–6511 (1985). 60. R. K. Globus, J. Plouet, and D. Gospodarowicz. Cultured bovine bone cells synthesize basic fibroblast growth factor and store it in their extracellular matrix. Endocrinology, 124, 1539–1547 (1989). 61. M. M. Hurley, C. Abreu, G. Gronowicz, H. Kawaguchi, and J. Lorenzo. Expression and regulation of basic fibroblast growth factor mRNA levels in mouse osteoblastic MC3T3–E1 cells. J Biol Chem, 269, 9392–9396 (1994). 62. E. Canalis, J. Lorenzo, W. H. Burgess, and T. Maciag. Effects of endothelial cell growth factor on bone remodelling in vitro. J Clin Invest, 79, 52–58 (1987). 63. E. Canalis, M. Centrella, and T. McCarthy. Effects of basic fibroblast growth factor on bone formation in vitro. J Clin Invest, 81, 1572–1577 (1988). 64. R. Montesano, J. D. Vassalli, A. Baird, R. Guillemin, and L. Orci. Basic fibroblast growth factor induces angiogenesis in vitro. Proc Natl Acad Sci USA, 83, 7297–7301 (1986). 65. S. B. Rodan, G. Wesolowski, K. Yoon, and G. A. Rodan. Opposing effects of fibroblast growth factor and pertussis toxin on alkaline phosphatase, osteopontin, osteocalcin, and type I collagen mRNA levels in ROS 17/2.8 cells. J Biol Chem, 264, 19934–19941 (1989). 66. T. L. McCarthy, M. Centrella, and E. Canalis. Effects of fibroblast growth factors on deoxyribonucleic acid and collagen synthesis in rat parietal bone cells. Endocrinology, 125, 2118–2126 (1989). 67. T. Sobue, T. Naganawa, L. Xiao, Y. Okada, Y. Tanaka, M. Ito, N. Okimoto, T. Nakamura, J. D. Coffin, and M. M. Hurley. Over-expression of fibroblast growth factor-2 causes defective bone mineralization and osteopenia in transgenic mice. J Cell Biochem, 95, 83–94 (2005). 68. A. Montero, Y. Okada, M. Tomita, M. Ito, H. Tsurukami, T. Nakamura, T. Doetschman, J. D. Coffin, and M. M. Hurley. Disruption of the fibroblast growth factor-2 gene results in decreased bone mass and bone formation. J Clin Invest, 105, 1085–1093 (2000). 69. M. L. Johnson, K. Harnish, R. Nusse, and W. Van Hul. LRP5 and Wnt signaling: A union made for bone. J Bone Miner Res, 19, 1749–1757 (2004). 70. A. Mansukhani, D. Ambrosetti, G. Holmes, L. Cornivelli, and C. Basilico. Sox2 induction by FGF and FGFR2 activating mutations inhibits Wnt signaling and osteoblast differentiation. J Cell Biol, 168, 1065–1076 (2005). 71. Y. Okada, A. Montero, X. Zhang, T. Sobue, J. Lorenzo, T. Doetschman, J. D. Coffin, and M. M. Hurley. Impaired osteoclast formation in bone marrow cultures of Fgf2 null mice in response to parathyroid hormone. J Biol Chem, 278, 21258–21266 (2003). 72. S. Varghese, S. Rydziel, and E. Canalis. Basic fibroblast growth factor stimulates collagenase-3 promoter activity in osteoblasts through an activator protein-1–binding site. Endocrinology, 141, 2185–2191 (2000). 73. M. Noda and R. Vogel. Fibroblast growth factor enhances type beta 1 transforming growth factor gene expression in osteoblast-like cells. J Cell Biol, 109, 2529–2535 (1989). 74. D. M. Ornitz and P. Leder. Ligand specificity and heparin dependence of fibroblast growth factor receptors 1 and 3. J Biol Chem, 267, 16305–16311 (1992). 75. J. K. Wang, G. Gao, and M. Goldfarb. Fibroblast growth factor receptors have different signaling and mitogenic potentials. Mol Cell Biol, 14, 181–188 (1994).
8/22/2007 4:17:40 PM
Chapter 19 Skeletal Growth Factors
76. S. Werner, D. S. Duan, C. de Vries, K. G. Peters, D. E. Johnson, and L. T. Williams. Differential splicing in the extracellular region of fibroblast growth factor receptor 1 generates receptor variants with different ligand-binding specificities. Mol Cell Biol, 12, 82–88 (1992). 77. R. Shiang, L. M. Thompson, Y. Z. Zhu, D. M. Church, T. J. Fielder, M. Bocian, S. T. Winokur, and J. J. Wasmuth. Mutations in the transmembrane domain of FGFR3 cause the most common genetic form of dwarfism, achondroplasia. Cell, 78, 335–342 (1994). 78. M. Sahni, D. C. Ambrosetti, A. Mansukhani, R. Gertner, D. Levy, and C. Basilico. FGF signaling inhibits chondrocyte proliferation and regulates bone development through the STAT-1 pathway. Genes Dev, 13, 1361–1366 (1999). 79. L. Xiao, T. Naganawa, E. Obugunde, G. Gronowicz, D. M. Ornitz, J. D. Coffin, and M. M. Hurley. Stat1 controls postnatal bone formation by regulating fibroblast growth factor signaling in osteoblasts. J Biol Chem, 279, 27743–27752 (2004). 80. H. Kawaguchi, T. Kurokawa, K. Hanada, Y. Hiyama, M. Tamura, E. Ogata, and T. Matsumoto. Stimulation of fracture repair by recombinant human basic fibroblast growth factor in normal and streptozotocin-diabetic rats. Endocrinology, 135, 774–781 (1994). 81. H. Kawaguchi, K. Nakamura, Y. Tabata, Y. Ikada, I. Aoyama, J. Anzai, T. Nakamura, Y. Hiyama, and M. Tamura. Acceleration of fracture healing in nonhuman primates by fibroblast growth factor-2. J Clin Endocrinol Metab, 86, 875–880 (2001). 82. K. Yu, J. Xu, Z. Liu, D. Sosic, J. Shao, E. N. Olson, D. A. Towler, and D. M. Ornitz. Conditional inactivation of FGF receptor 2 reveals an essential role for FGF signaling in the regulation of osteoblast function and bone growth. Development, 130, 3063–3074 (2003). 83. A. Jackson, S. Friedman, X. Zhan, K. A. Engleka, R. Forough, and T. Maciag. Heat shock induces the release of fibroblast growth factor 1 from NIH 3T3 cells. Proc Natl Acad Sci USA, 89, 10691–10695 (1992). 84. F. Shibata, A. Baird, and R. Z. Florkiewicz. Functional characterization of the human basic fibroblast growth factor gene promoter. Growth Factors, 4, 277–287 (1991). 85. M. M. Hurley, S. Tetradis, Y. F. Huang, J. Hock, B. E. Kream, L. G. Raisz, and M. G. Sabbieti. Parathyroid hormone regulates the expression of fibroblast growth factor-2 mRNA and fibroblast growth factor receptor mRNA in osteoblastic cells. J Bone Miner Res, 14, 776–783 (1999). 86. M. Mali, K. Elenius, H. M. Miettinen, and M. Jalkanen. Inhibition of basic fibroblast growth factor-induced growth promotion by overexpression of syndecan-1. J Biol Chem, 268, 24215–24222 (1993). 87. L. Attisano and J. L. Wrana. Signal transduction by the TGFbeta superfamily. Science, 296, 1646–1647 (2002). 88. J. A. Barnard, R. M. Lyons, and H. L. Moses. The cell biology of transforming growth factor beta. Biochim Biophys Acta, 1032, 79–87 (1990). 89. M. Centrella, T. L. McCarthy, and E. Canalis. Transforming growth factor-beta and remodeling of bone. J Bone Joint Surg Am, 73, 1418–1428 (1991). 90. M. Centrella, J. Massague, and E. Canalis. Human plateletderived transforming growth factor-beta stimulates parameters of bone growth in fetal rat calvariae. Endocrinology, 119, 2306–2312 (1986). 91. J. M. Hock, E. Canalis, and M. Centrella. Transforming growth factor-beta stimulates bone matrix apposition and bone cell replication in cultured fetal rat calvariae. Endocrinology, 126, 421–426 (1990).
Marcus-Ch19.indd 541
541 92. C. Marcelli, A. J. Yates, and G. R. Mundy. In vivo effects of human recombinant transforming growth factor beta on bone turnover in normal mice. J Bone Miner Res, 5, 1087–1096 (1990). 93. D. Rosen, S. C. Miller, E. DeLeon, A. Y. Thompson, H. Bentz, M. Mathews, and S. Adams. Systemic administration of recombinant transforming growth factor beta 2 (rTGF-beta 2) stimulates parameters of cancellous bone formation in juvenile and adult rats. Bone, 15, 355–359 (1994). 94. M. Centrella, T. L. McCarthy, and E. Canalis. Transforming growth factor beta is a bifunctional regulator of replication and collagen synthesis in osteoblast-enriched cell cultures from fetal rat bone. J Biol Chem, 262, 2869–2874 (1987). 95. M. Noda and G. A. Rodan. Type beta transforming growth factor (TGF beta) regulation of alkaline phosphatase expression and other phenotype-related mRNAs in osteoblastic rat osteosarcoma cells. J Cell Physiol, 133, 426–437 (1987). 96. D. M. Rosen, S. A. Stempien, A. Y. Thompson, and S. M. Seyedin. Transforming growth factor-beta modulates the expression of osteoblast and chondroblast phenotypes in vitro. J Cell Physiol, 134, 337–346 (1988). 97. R. A. Ignotz and J. Massague. Transforming growth factorbeta stimulates the expression of fibronectin and collagen and their incorporation into the extracellular matrix. J Biol Chem, 261, 4337–4345 (1986). 98. L. F. Bonewald, M. B. Kester, Z. Schwartz, L. D. Swain, A. Khare, T. L. Johnson, R. J. Leach, and B. D. Boyan. Effects of combining transforming growth factor beta and 1, 25–dihydroxyvitamin D3 on differentiation of a human osteosarcoma (MG-63). J Biol Chem, 267, 8943–8949 (1992). 99. S. Spinella-Jaegle, S. Roman-Roman, C. Faucheu, F. W. Dunn, S. Kawai, S. Gallea, V. Stiot, A. M. Blanchet, B. Courtois, R. Baron, and G. Rawadi. Opposite effects of bone morphogenetic protein-2 and transforming growth factor-beta1 on osteoblast differentiation. Bone, 29, 323–330 (2001). 100. C. Chenu, J. Pfeilschifter, G. R. Mundy, and G. D. Roodman. Transforming growth factor beta inhibits formation of osteoclast-like cells in long-term human marrow cultures. Proc Natl Acad Sci USA, 85, 5683–5687 (1988). 101. D. M. Shinar and G. A. Rodan. Biphasic effects of transforming growth factor-beta on the production of osteoclast-like cells in mouse bone marrow cultures: The role of prostaglandins in the generation of these cells. Endocrinology, 126, 3153–3158 (1990). 102. J. Pfeilschifter, S. M. Seyedin, and G. R. Mundy. Transforming growth factor beta inhibits bone resorption in fetal rat long bone cultures. J Clin Invest, 82, 680–685 (1988). 103. M. Centrella, T. L. McCarthy, and E. Canalis. Parathyroid hormone modulates transforming growth factor beta activity and binding in osteoblast-enriched cell cultures from fetal rat parietal bone. Proc Natl Acad Sci USA, 85, 5889–5893 (1988). 104. M. Centrella, T. L. McCarthy, and E. Canalis. Glucocorticoid regulation of transforming growth factor beta 1 activity and binding in osteoblast-enriched cultures from fetal rat bone. Mol Cell Biol, 11, 4490–4496 (1991). 105. F. Lopez-Casillas, S. Cheifetz, J. Doody, J. L. Andres, W. S. Lane, and J. Massague. Structure and expression of the membrane proteoglycan betaglycan, a component of the TGF-beta receptor system. Cell, 67, 785–795 (1991). 106. M. E. Joyce, A. B. Roberts, M. B. Sporn, and M. E. Bolander. Transforming growth factor-beta and the initiation of chondrogenesis and osteogenesis in the rat femur. J Cell Biol, 110, 2195–2207 (1990). 107. A. Erlebacher and R. Derynck. Increased expression of TGFbeta 2 in osteoblasts results in an osteoporosis-like phenotype. J Cell Biol, 132, 195–210 (1996).
8/22/2007 4:17:40 PM
542 108. R. Serra, M. Johnson, E. H. Filvaroff, J. LaBorde, D. M. Sheehan, R. Derynck, and H. L. Moses. Expression of a truncated, kinase-defective TGF-beta type II receptor in mouse skeletal tissue promotes terminal chondrocyte differentiation and osteoarthritis. J Cell Biol, 139, 541–552 (1997). 109. M. M. Shull, I. Ormsby, A. B. Kier, S. Pawlowski, R. J. Diebold, M. Yin, R. Allen, C. Sidman, G. Proetzel, and D. Calvin. Targeted disruption of the mouse transforming growth factor-beta 1 gene results in multifocal inflammatory disease. Nature, 359, 693–699 (1992). 110. L. S. Beck, T. L. Chen, P. Mikalauski, and A. J. Ammann. Recombinant human transforming growth factor-beta 1 (rhTGF-beta 1) enhances healing and strength of granulation skin wounds. Growth Factors, 3, 267–275 (1990). 111. W. A. Border and E. Ruoslahti. Transforming growth factorbeta in disease: The dark side of tissue repair. J Clin Invest, 90, 1–7 (1992). 112. A. Migdalska, G. Molineux, H. Demuynck, G. S. Evans, F. Ruscetti, and T. M. Dexter. Growth inhibitory effects of transforming growth factor-beta 1 in vivo. Growth Factors, 4, 239–245 (1991). 113. A. B. Roberts, M. B. Sporn, R. K. Assoian, J. M. Smith, N. S. Roche, L. M. Wakefield, U. I. Heine, L. A. Liotta, V. Falanga, and J. H. Kehrl. Transforming growth factor type beta: Rapid induction of fibrosis and angiogenesis in vivo and stimulation of collagen formation in vitro. Proc Natl Acad Sci USA, 83, 4167–4171 (1986). 114. R. Derynck, J. A. Jarrett, E. Y. Chen, and D. V. Goeddel. The murine transforming growth factor-beta precursor. J Biol Chem, 261, 4377–4379 (1986). 115. K. Miyazono, U. Hellman, C. Wernstedt, and C. H. Heldin. Latent high molecular weight complex of transforming growth factor beta 1. Purification from human platelets and structural characterization. J Biol Chem, 263, 6407–6415 (1988). 116. K. Miyazono, A. Olofsson, P. Colosetti, and C. H. Heldin. A role of the latent TGF-beta 1–binding protein in the assembly and secretion of TGF-beta 1. EMBO J, 10, 1091–1101 (1991). 117. L. M. Wakefield, D. M. Smith, K. C. Flanders, and M. B. Sporn. Latent transforming growth factor-beta from human platelets. A high molecular weight complex containing precursor sequences. J Biol Chem, 263, 7646–7654 (1988). 118. M. J. Oursler, C. Cortese, P. Keeting, M. A. Anderson, S. K. Bonde, B. L. Riggs, and T. C. Spelsberg. Modulation of transforming growth factor-beta production in normal human osteoblast-like cells by 17 beta-estradiol and parathyroid hormone. Endocrinology, 129, 3313–3320 (1991). 119. M. J. Oursler, B. L. Riggs, and T. C. Spelsberg. Glucocorticoidinduced activation of latent transforming growth factor-beta by normal human osteoblast-like cells. Endocrinology, 133, 2187–2196 (1993). 120. R. D. Finkelman, N. H. Bell, D. D. Strong, L. M. Demers, and D. J. Baylink. Ovariectomy selectively reduces the concentration of transforming growth factor beta in rat bone: Implications for estrogen deficiency-associated bone loss. Proc Natl Acad Sci USA, 89, 12190–12193 (1992). 121. R. Lafyatis, R. Lechleider, S. J. Kim, S. Jakowlew, A. B. Roberts, and M. B. Sporn. Structural and functional characterization of the transforming growth factor beta 3 promoter. A cAMP-responsive element regulates basal and induced transcription. J Biol Chem, 265, 19128–19136 (1990). 122. T. Noma, A. B. Glick, A. G. Geiser, M. A. O’Reilly, J. Miller, A. B. Roberts, and M. B. Sporn. Molecular cloning and structure of the human transforming growth factor-beta 2 gene promoter. Growth Factors, 4, 247–255 (1991).
Marcus-Ch19.indd 542
Ernesto Canalis
123. M. Kawabata and K. Miyazono. Bone morphogenetic proteins. In Skeletal Growth Factors (E. Canalis, ed.), pp. 269– 290. Lippincott Williams & Wilkins, Philadelphia (2000). 124. E. A. Wang, V. Rosen, J. S. D’Alessandro, M. Bauduy, P. Cordes, T. Harada, D. I. Israel, R. M. Hewick, K. M. Kerns, and P. LaPan. Recombinant human bone morphogenetic protein induces bone formation. Proc Natl Acad Sci USA, 87, 2220–2224 (1990). 125. J. M. Wozney, V. Rosen, A. J. Celeste, L. M. Mitsock, M. J. Whitters, R. W. Kriz, R. M. Hewick, and E. A. Wang. Novel regulators of bone formation: Molecular clones and activities. Science, 242, 1528–1534 (1988). 126. M. I. Uzel, I. C. Scott, H. Babakhanlou-Chase, A. H. Palamakumbura, W. N. Pappano, H. H. Hong, D. S. Greenspan, and P. C. Trackman. Multiple bone morphogenetic protein 1–related mammalian metalloproteinases process pro-lysyl oxidase at the correct physiological site and control lysyl oxidase activation in mouse embryo fibroblast cultures. J Biol Chem, 276, 22537–22543 (2001). 127. M. E. Bahamonde and K. M. Lyons. BMP3: To be or not to be a BMP. J Bone Joint Surg Am, 83–A (Suppl 1), S56–S62 (2001). 128. A. Daluiski, T. Engstrand, M. E. Bahamonde, L. W. Gamer, E. Agius, S. L. Stevenson, K. Cox, V. Rosen, and K. M. Lyons. Bone morphogenetic protein-3 is a negative regulator of bone density. Nat Genet, 27, 84–88 (2001). 129. F. P. Luyten, N. S. Cunningham, S. Ma, N. Muthukumaran, R. G. Hammonds, W. B. Nevins, W. I. Woods, and A. H. Reddi. Purification and partial amino acid sequence of osteogenin, a protein initiating bone differentiation. J Biol Chem, 264, 13377–13380 (1989). 130. D. Chen, M. A. Harris, G. Rossini, C. R. Dunstan, S. L. Dallas, J. Q. Feng, G. R. Mundy, and S. E. Harris. Bone morphogenetic protein 2 (BMP-2) enhances BMP-3, BMP-4, and bone cell differentiation marker gene expression during the induction of mineralized bone matrix formation in cultures of fetal rat calvarial osteoblasts. Calcif Tissue Int, 60, 283–290 (1997). 131. N. Ghosh-Choudhury, M. A. Harris, J. Q. Feng, G. R. Mundy, and S. E. Harris. Expression of the BMP 2 gene during bone cell differentiation. Crit Rev Eukaryot Gene Expr, 4, 345–355 (1994). 132. R. C. Pereira, S. Rydziel, and E. Canalis. Bone morphogenetic protein-4 regulates its own expression in cultured osteoblasts. J Cell Physiol, 182, 239–246 (2000). 133. D. J. Rickard, L. C. Hofbauer, S. K. Bonde, F. Gori, T. C. Spelsberg, and B. L. Riggs. Bone morphogenetic protein-6 production in human osteoblastic cell lines. Selective regulation by estrogen. J Clin Invest, 101, 413–422 (1998). 134. M. Suzawa, Y. Takeuchi, S. Fukumoto, S. Kato, N. Ueno, K. Miyazono, T. Matsumoto, and T. Fujita. Extracellular matrix-associated bone morphogenetic proteins are essential for differentiation of murine osteoblastic cells in vitro. Endocrinology, 140, 2125–2133 (1999). 135. A. Yamaguchi, T. Ishizuya, N. Kintou, Y. Wada, T. Katagiri, J. M. Wozney, V. Rosen, and S. Yoshiki. Effects of BMP-2, BMP-4, and BMP-6 on osteoblastic differentiation of bone marrow-derived stromal cell lines, ST2 and MC3T3–G2/ PA6. Biochem Biophys Res Commun, 220, 366–371 (1996). 136. S. E. Gitelman, M. Kirk, J. Q. Ye, E. H. Filvaroff, A. J. Kahn, and R. Derynck. Vgr-1/BMP-6 induces osteoblastic differentiation of pluripotential mesenchymal cells. Cell Growth Differ, 6, 827–836 (1995). 137. E. Hay, J. Lemonnier, O. Fromigue, and P. J. Marie. Bone morphogenetic protein-2 promotes osteoblast apoptosis
8/22/2007 4:17:40 PM
Chapter 19 Skeletal Growth Factors
138. 139.
140. 141.
142.
143. 144. 145.
146.
147.
148.
149.
150.
151.
152.
Marcus-Ch19.indd 543
through a Smad-independent, protein kinase C-dependent signaling pathway. J Biol Chem, 276, 29028–29036 (2001). R. M. Pereira, A. M. Delany, and E. Canalis. Cortisol inhibits the differentiation and apoptosis of osteoblasts in culture. Bone, 28, 484–490 (2001). Y. Yokouchi, J. Sakiyama, T. Kameda, H. Iba, A. Suzuki, N. Ueno, and A. Kuroiwa. BMP-2/-4 mediate programmed cell death in chicken limb buds. Development, 122, 3725–3734 (1996). S. L. Teitelbaum. Bone resorption by osteoclasts. Science, 289, 1504–1508 (2000). Y. H. Gao, T. Shinki, T. Yuasa, H. Kataoka-Enomoto, T. Komori, T. Suda, and A. Yamaguchi. Potential role of cbfa1, an essential transcriptional factor for osteoblast differentiation, in osteoclastogenesis: Regulation of mRNA expression of osteoclast differentiation factor (ODF). Biochem Biophys Res Commun, 252, 697–702 (1998). H. Kaneko, T. Arakawa, H. Mano, T. Kaneda, A. Ogasawara, M. Nakagawa, Y. Toyama, Y. Yabe, M. Kumegawa, and Y. Hakeda. Direct stimulation of osteoclastic bone resorption by bone morphogenetic protein (BMP)-2 and expression of BMP receptors in mature osteoclasts. Bone, 27, 479–486 (2000). M. Wan, X. Shi, X. Feng, and X. Cao. Transcriptional mechanisms of bone morphogenetic protein-induced osteoprotegrin gene expression. J Biol Chem, 276, 10119–10125 (2001). S. Varghese and E. Canalis. Regulation of collagenase3 by bone morphogenetic protein-2 in bone cell cultures. Endocrinology, 138, 1035–1040 (1997). S. Varghese, S. Rydziel, and E. Canalis. Bone morphogenetic protein-2 suppresses collagenase-3 promoter activity in osteoblasts through a runt domain factor 2 binding site. J Cell Physiol, 202, 391–399 (2005). P. Leboy, G. Grasso-Knight, M. D’Angelo, S. W. Volk, J. V. Lian, H. Drissi, G. S. Stein, and S. L. Adams. Smad-Runx interactions during chondrocyte maturation. J Bone Joint Surg Am, 83–A(Suppl 1), S15–S22 (2001). C. D. Grimsrud, P. R. Romano, M. D’Souza, J. E. Puzas, E. M. Schwarz, P. R. Reynolds, R. N. Roiser, and R. J. O’Keefe. BMP signaling stimulates chondrocyte maturation and the expression of Indian hedgehog. J Orthop Res, 19, 18–25 (2001). F. De Luca, K. M. Barnes, J. A. Uyeda, S. De Levi, V. Abad, T. Palese, V. Mericq, and J. Baron. Regulation of growth plate chondrogenesis by bone morphogenetic protein-2. Endocrinology, 142, 430–436 (2001). D. Duprez, E. J. Bell, M. K. Richardson, C. W. Archer, L. Wolpert, P. M. Brickell, and P. H. Francis-West. Overexpression of BMP-2 and BMP-4 alters the size and shape of developing skeletal elements in the chick limb. Mech Dev, 57, 145–157 (1996). V. Krishnan, Y. Ma, J. Moseley, A. Geiser, S. Friant, and C. Frolik. Bone anabolic effects of sonic/Indian hedgehog are mediated by bmp-2/4–dependent pathways in the neonatal rat metatarsal model. Endocrinology, 142, 940–947 (2001). T. Katagiri, A. Yamaguchi, M. Komaki, E. Abe, N. Takahashi, T. Ikeda, V. Rosen, J. M. Wozney, A. Fujisawa-Sehara, and T. Suda. Bone morphogenetic protein-2 converts the differentiation pathway of C2C12 myoblasts into the osteoblast lineage. J Cell Biol, 127, 1755–1766 (1994). T. Katagiri, S. Akiyama, M. Namiki, M. Komaki, A. Yamaguchi, V. Rosen, J. M. Wozney, A. Fujisawa-Sehara, and T. Suda. Bone morphogenetic protein-2 inhibits terminal differentiation of myogenic cells by suppressing the transcriptional activity of MyoD and myogenin. Exp Cell Res, 230, 342–351 (1997).
543 153. E. Canalis and B. Gabbitas. Bone morphogenetic protein 2 increases insulin-like growth factor I and II transcripts and polypeptide levels in bone cell cultures. J Bone Miner Res, 9, 1999–2005 (1994). 154. H. Yamashita, P. ten Dijke, C. H. Heldin, and K. Miyazono. Bone morphogenetic protein receptors. Bone, 19, 569–574 (1996). 155. R. Derynck, Y. Zhang, and X. H. Feng. Smads: Transcriptional activators of TGF-beta responses. Cell, 95, 737–740 (1998). 156. A. Nohe, S. Hassel, M. Ehrlich, F. Neubauer, W. Sebald, Y. I. Henis, and P. Knaus. The mode of bone morphogenetic protein (BMP) receptor oligomerization determines different BMP-2 signaling pathways. J Biol Chem, 277, 5330–5338 (2002). 157. F. Liu, A. Hata, J. C. Baker, J. Doody, J. Carcamo, R. M. Harland, and J. Massague. A human Mad protein acting as a BMP-regulated transcriptional activator. Nature, 381, 620– 623 (1996). 158. K. Miyazono. Signal transduction by bone morphogenetic protein receptors: Functional roles of Smad proteins. Bone, 25, 91–93 (1999). 159. C. F. Lai and S. L. Cheng. Signal transductions induced by bone morphogenetic protein-2 and transforming growth factor-beta in normal human osteoblastic cells. J Biol Chem, 277, 15514–15522 (2002). 160. G. Winnier, M. Blessing, P. A. Labosky, and B. L. Hogan. Bone morphogenetic protein-4 is required for mesoderm formation and patterning in the mouse. Genes Dev, 9, 2105–2116 (1995). 161. H. Zhang and A. Bradley. Mice deficient for BMP2 are nonviable and have defects in amnion/chorion and cardiac development. Development, 122, 2977–2986 (1996). 162. H. Chang, D. Huylebroeck, K. Verschueren, Q. Guo, M. M. Matzuk, and A. Zwijsen. Smad5 knockout mice die at midgestation due to multiple embryonic and extraembryonic defects. Development, 126, 1631–1642 (1999). 163. X. Yang, L. H. Castilla, X. Xu, C. Li, J. Gotay, M. Weinstein, P. P. Liu, and C. X. Deng. Angiogenesis defects and mesenchymal apoptosis in mice lacking SMAD5. Development, 126, 1571–1580 (1999). 164. M. J. Solloway, A. T. Dudley, E. K. Bikoff, K. M. Lyons, B. L. Hogan, and E. J. Robertson. Mice lacking Bmp6 function. Dev Genet, 22, 321–339 (1998). 165. G. Q. Zhao, K. Deng, P. A. Labosky, L. Liaw, and B. L. Hogan. The gene encoding bone morphogenetic protein 8B is required for the initiation and maintenance of spermatogenesis in the mouse. Genes Dev, 10, 1657–1669 (1996). 166. G. Luo, C. Hofmann, A. L. Bronckers, M. Sohocki, A. Bradley, and G. Karsenty. BMP-7 is an inducer of nephrogenesis, and is also required for eye development and skeletal patterning. Genes Dev, 9, 2808–2820 (1995). 167. E. Canalis, A. N. Economides, and E. Gazzerro. Bone morphogenetic proteins, their antagonists, and the skeleton. Endocr Rev, 24, 218–235 (2003). 168. L. B. Zimmerman, J. M. Jesus-Escobar, and R. M. Harland. The Spemann organizer signal noggin binds and inactivates bone morphogenetic protein 4. Cell, 86, 599–606 (1996). 169. D. R. Hsu, A. N. Economides, X. Wang, P. M. Eimon, and R. M. Harland. The Xenopus dorsalizing factor Gremlin identifies a novel family of secreted proteins that antagonize BMP activities. Mol Cell, 1, 673–683 (1998). 170. J. J. Pearce, G. Penny, and J. Rossant. A mouse cerberus/Danrelated gene family. Dev Biol, 209, 98–110 (1999). 171. R. P. Ray and K. A. Wharton. Twisted perspective: New insights into extracellular modulation of BMP signaling during development. Cell, 104, 801–804 (2001).
8/22/2007 4:17:40 PM
544 172. E. Bell, I. Munoz-Sanjuan, C. R. Altmann, A. Vonica, and A. H. Brivanlou. Cell fate specification and competence by Coco, a maternal BMP, TGFbeta and Wnt inhibitor. Development, 130, 1381–1389 (2003). 173. D. G. Winkler, M. S. Sutherland, E. Ojala, E. Turcott, J. C. Geoghegan, D. Shpektor, J. E. Skonier, C. Yu, and J. A. Latham. Sclerostin inhibition of Wnt-3a-induced C3H10T1/2 cell differentiation is indirect and mediated by bone morphogenetic proteins. J Biol Chem, 280, 2498–2502 (2005). 174. T. Bellido, A. A. Ali, I. Gubrij, L. I. Plotkin, Q. Fu, C. A. O’Brien, S. C. Manolagas, and R. L. Jilka. Chronic elevation of parathyroid hormone in mice reduces expression of sclerostin by osteocytes: A novel mechanism for hormonal control of osteoblastogenesis. Endocrinology, 146, 4577–4583 (2005). 175. J. Laurikkala, Y. Kassai, L. Pakkasjarvi, I. Thesleff, and N. Itoh. Identification of a secreted BMP antagonist, ectodin, integrating BMP, FGF, and SHH signals from the tooth enamel knot. Dev Biol, 264, 91–105 (2003). 176. R. D. Devlin, Z. Du, R. C. Pereira, R. B. Kimble, A. N. Economides, V. Jorgetti, and E. Canalis. Skeletal overexpression of noggin results in osteopenia and reduced bone formation. Endocrinology, 144, 1972–1978 (2003). 177. E. Gazzerro, Z. Du, R. D. Devlin, S. Rydziel, L. Priest, A. N. Economides, and E. Canalis. Noggin arrests stromal cell differentiation in vitro. Bone, 32, 111–119 (2003). 178. E. Gazzerro, R. C. Pereira, V. Jorgetti, S. Olson, A. N. Economides, and E. Canalis. Skeletal overexpression of gremlin impairs bone formation and causes osteopenia. Endocrinology, 146, 655–665 (2005). 179. G. G. Loots, M. Kneissel, H. Keller, M. Baptist, J. Chang, N. M. Collette, D. Ovcharenko, I. Plajzer-Frick, and E. M. Rubin. Genomic deletion of a long-range bone enhancer misregulates sclerostin in Van Buchem disease. Genome Res, 15, 928–935 (2005). 180. L. J. Brunet, J. A. McMahon, A. P. McMahon, and R. M. Harland. Noggin, cartilage morphogenesis, and joint formation in the mammalian skeleton. Science, 280, 1455–1457 (1998). 181. E. Gazzerro, V. Gangji, and E. Canalis. Bone morphogenetic proteins induce the expression of noggin, which limits their activity in cultured rat osteoblasts. J Clin Invest, 102, 2106– 2114 (1998). 182. R. C. Pereira, A. N. Economides, and E. Canalis. Bone morphogenetic proteins induce gremlin, a protein that limits their activity in osteoblasts. Endocrinology, 141, 4558–4563 (2000). 183. J. I. Jones and D. R. Clemmons. Insulin-like growth factors and their binding proteins: Biological actions. Endocr Rev, 16, 3–34 (1995). 184. V. Hwa, Y. Oh, and R. G. Rosenfeld. The insulin-like growth factor-binding protein (IGFBP) superfamily. Endocr Rev, 20, 761–787 (1999). 185. J. Baker, J. P. Liu, E. J. Robertson, and A. Efstratiadis. Role of insulin-like growth factors in embryonic and postnatal growth. Cell, 75, 73–82 (1993). 186. J. P. Liu, J. Baker, A. S. Perkins, E. J. Robertson, and A. Efstratiadis. Mice carrying null mutations of the genes encoding insulin-like growth factor I (Igf-1) and type 1 IGF receptor (Igf1r). Cell, 75, 59–72 (1993). 187. L. S. Mathews, R. E. Hammer, R. L. Brinster, and R. D. Palmiter. Expression of insulin-like growth factor I in transgenic mice with elevated levels of growth hormone is correlated with growth. Endocrinology, 123, 433–437 (1988). 188. E. Canalis, T. McCarthy, and M. Centrella. Isolation and characterization of insulin-like growth factor I (somatome-
Marcus-Ch19.indd 544
Ernesto Canalis
189.
190. 191.
192. 193.
194.
195.
196.
197.
198.
199.
200.
201.
202.
din-C) from cultures of fetal rat calvariae. Endocrinology, 122, 22–27 (1988). S. Mohan, J. C. Jennings, T. A. Linkhart, and D. J. Baylink. Primary structure of human skeletal growth factor: Homology with human insulin-like growth factor-II. Biochim Biophys Acta, 966, 44–55 (1988). E. Canalis. Effect of insulinlike growth factor I on DNA and protein synthesis in cultured rat calvaria. J Clin Invest, 66, 709–719 (1980). T. L. McCarthy, M. Centrella, and E. Canalis. Regulatory effects of insulin-like growth factors I and II on bone collagen synthesis in rat calvarial cultures. Endocrinology, 124, 301–309 (1989). J. M. Hock, M. Centrella, and E. Canalis. Insulin-like growth factor I has independent effects on bone matrix formation and cell replication. Endocrinology, 122, 254–260 (1988). E. Canalis, S. Rydziel, A. M. Delany, S. Varghese, and J. J. Jeffrey. Insulin-like growth factors inhibit interstitial collagenase synthesis in bone cell cultures. Endocrinology, 136, 1348–1354 (1995). K. M. Rosen, B. M. Wentworth, N. Rosenthal, and L. VillaKomaroff. Specific, temporally regulated expression of the insulin-like growth factor II gene during muscle cell differentiation. Endocrinology, 133, 474–481 (1993). T. Thomas, F. Gori, T. C. Spelsberg, S. Khosla, B. L. Riggs, and C. A. Conover. Response of bipotential human marrow stromal cells to insulin-like growth factors: Effect on binding protein production, proliferation, and commitment to osteoblasts and adipocytes. Endocrinology, 140, 5036–5044 (1999). M. P. Playford, D. Bicknell, W. F. Bodmer, and V. M. Macaulay. Insulin-like growth factor 1 regulates the location, stability, and transcriptional activity of beta-catenin. Proc Natl Acad Sci USA, 97, 12103–12108 (2000). G. Zhao, M. C. Monier-Faugere, M. C. Langub, Z. Geng, T. Nakayama, J. W. Pike, S. D. Chernausek, C. J. Rosen, L. R. Donahue, H. H. Malluche, J. A. Fagin, and T. L. Clemens. Targeted overexpression of insulin-like growth factor I to osteoblasts of transgenic mice: Increased trabecular bone volume without increased osteoblast proliferation. Endocrinology, 141, 2674–2682 (2000). M. Zhang, S. Xuan, M. L. Bouxsein, D. von Stechow, N. Akeno, M. C. Faugere, H. Malluche, G. Zhao, C. J. Rosen, A. Efstratiadis, and T. L. Clemens. Osteoblast-specific knockout of the insulin-like growth factor (IGF) receptor gene reveals an essential role of IGF signaling in bone matrix mineralization. J Biol Chem, 277, 44005–44012 (2002). H. Mochizuki, Y. Hakeda, N. Wakatsuki, N. Usui, S. Akashi, T. Sato, K. Tanaka, and M. Kumegawa. Insulin-like growth factor-I supports formation and activation of osteoclasts. Endocrinology, 131, 1075–1080 (1992). L. M. Chuang, M. G. Myers, Jr., G. A. Seidner, M. J. Birnbaum, M. F. White, and C. R. Kahn. Insulin receptor substrate 1 mediates insulin and insulin-like growth factor Istimulated maturation of Xenopus oocytes. Proc Natl Acad Sci USA, 90, 5172–5175 (1993). M. G. Myers, Jr., X. J. Sun, B. Cheatham, B. R. Jachna, E. M. Glasheen, J. M. Backer, and M. F. White. IRS-1 is a common element in insulin and insulin-like growth factor-I signaling to the phosphatidylinositol 3-kinase. Endocrinology, 132, 1421–1430 (1993). A. Grey, Q. Chen, X. Xu, K. Callon, and J. Cornish. Parallel phosphatidylinositol-3 kinase and p42/44 mitogen-activated protein kinase signaling pathways subserve the mitogenic and antiapoptotic actions of insulin-like growth factor I in osteoblastic cells. Endocrinology, 144, 4886–4893 (2003).
8/22/2007 4:17:41 PM
545
Chapter 19 Skeletal Growth Factors
203. P. F. Collett-Solberg and P. Cohen. Genetics, chemistry, and function of the IGF/IGFBP system. Endocrine, 12, 121–136 (2000). 204. A. Bennett, T. Chen, D. Feldman, R. L. Hintz, and R. G. Rosenfeld. Characterization of insulin-like growth factor I receptors on cultured rat bone cells: Regulation of receptor concentration by glucocorticoids. Endocrinology, 115, 1577– 1583 (1984). 205. Y. Hakeda, S. Harada, T. Matsumoto, K. Tezuka, K. Higashino, H. Kodama, T. Hashimoto-Goto, E. Ogata, and M. Kumegawa. Prostaglandin F2 alpha stimulates proliferation of clonal osteoblastic MC3T3–E1 cells by up-regulation of insulin-like growth factor I receptors. J Biol Chem, 266, 21044–21050 (1991). 206. H. Kurose, K. Yamaoka, S. Okada, S. Nakajima, and Y. Seino. 1,25–Dihydroxyvitamin D3 [1,25–(OH)2D3] increases insulin-like growth factor I (IGF-I) receptors in clonal osteoblastic cells. Study on interaction of IGF-I and 1,25–(OH)2D3. Endocrinology, 126, 2088–2094 (1990). 207. M. Rubini, H. Werner, E. Gandini, C. T. Roberts, Jr., D. LeRoith, and R. Baserga. Platelet-derived growth factor increases the activity of the promoter of the insulin-like growth factor-1 (IGF-1) receptor gene. Exp Cell Res, 211, 374–379 (1994). 208. M. Machwate, E. Zerath, X. Holy, P. Pastoureau, and P. J. Marie. Insulin-like growth factor-I increases trabecular bone formation and osteoblastic cell proliferation in unloaded rats. Endocrinology, 134, 1031–1038 (1994). 209. P. R. Ebeling, J. D. Jones, W. M. O’Fallon, C. H. Janes, and B. L. Riggs. Short-term effects of recombinant human insulin-like growth factor I on bone turnover in normal women. J Clin Endocrinol Metab, 77, 1384–1387 (1993). 210. S. Grinspoon, L. Thomas, K. Miller, D. Herzog, and A. Klibanski. Effects of recombinant human IGF-I and oral contraceptive administration on bone density in anorexia nervosa. J Clin Endocrinol Metab, 87, 2883–2891 (2002). 211. E. Canalis. Skeletal growth factors and aging. J Clin Endocrinol Metab, 78, 1009–1010 (1994). 212. V. Nicolas, A. Prewett, P. Bettica, S. Mohan, R. D. Finkelman, D. J. Baylink, and J. R. Farley. Age-related decreases in insulin-like growth factor-I and transforming growth factor-beta in femoral cortical bone from both men and women: Implications for bone loss with aging. J Clin Endocrinol Metab, 78, 1011–1016 (1994). 213. A. Efstratiadis. Genetics of mouse growth. Int J Dev Biol, 42, 955–976 (1998). 214. D. Bikle, S. Majumdar, A. Laib, L. Powell-Braxton, C. Rosen, W. Beamer, E. Nauman, C. Leary, and B. Halloran. The skeletal structure of insulin-like growth factor I-deficient mice. J Bone Miner Res, 16, 2320–2329 (2001). 215. W. H. Beamer and E. M. Eicher. Stimulation of growth in the little mouse. J Endocrinol, 71, 37–45 (1976). 216. N. A. Sims, P. Clement-Lacroix, F. Da Ponte, Y. Bouali, N. Binart, R. Moriggl, V. Goffin, K. Coschigano, M. GaillardKelly, J. Kopchick, R. Baron, and P. A. Kelly. Bone homeostasis in growth hormone receptor-null mice is restored by IGF-I but independent of Stat5. J Clin Invest, 106, 1095–1103 (2000). 217. S. Yakar, J. L. Liu, B. Stannard, A. Butler, D. Accili, B. Sauer, and D. LeRoith. Normal growth and development in the absence of hepatic insulin-like growth factor I. Proc Natl Acad Sci USA, 96, 7324–7329 (1999). 218. S. Yakar, C. J. Rosen, W. G. Beamer, C. L. AckertBicknell, Y. Wu, J. L. Liu, G. T. Ooi, J. Setser, J. Frystyk, Y. R. Boisclair, and D. LeRoith. Circulating levels of IGF-1
Marcus-Ch19.indd 545
219.
220.
221.
222. 223.
224. 225.
226.
227.
228. 229. 230.
231.
232.
233.
234.
directly regulate bone growth and density. J Clin Invest, 110, 771–781 (2002). N. Ogata, D. Chikazu, N. Kubota, Y. Terauchi, K. Tobe, Y. Azuma, T. Ohta, T. Kadowaki, K. Nakamura, and H. Kawaguchi. Insulin receptor substrate-1 in osteoblast is indispensable for maintaining bone turnover. J Clin Invest, 105, 935–943 (2000). M. Yamaguchi, N. Ogata, Y. Shinoda, T. Akune, S. Kamekura, Y. Terauchi, T. Kadowaki, K. Hoshi, U. I. Chung, K. Nakamura, and H. Kawaguchi. Insulin receptor substrate-1 is required for bone anabolic function of parathyroid hormone in mice. Endocrinology, 146, 2620–2628 (2005). L. J. Hall, Y. Kajimoto, D. Bichell, S. W. Kim, P. L. James, D. Counts, L. J. Nixon, G. Tobin, and P. Rotwein. Functional analysis of the rat insulin-like growth factor I gene and identification of an IGF-I gene promoter. DNA Cell Biol, 11, 301– 313 (1992). S. W. Kim, R. Lajara, and P. Rotwein. Structure and function of a human insulin-like growth factor-I gene promoter. Mol Endocrinol, 5, 1964–1972 (1991). M. L. Adamo, H. Ben Hur, C. T. Roberts, Jr., and D. LeRoith. Regulation of start site usage in the leader exons of the rat insulin-like growth factor-I gene by development, fasting, and diabetes. Mol Endocrinol, 5, 1677–1686 (1991). T. L. McCarthy, M. Centrella, and E. Canalis. Cyclic AMP induces insulin-like growth factor I synthesis in osteoblastenriched cultures. J Biol Chem, 265, 15353–15356 (1990). E. Canalis, M. Centrella, W. Burch, and T. L. McCarthy. Insulin-like growth factor I mediates selective anabolic effects of parathyroid hormone in bone cultures. J Clin Invest, 83, 60–65 (1989). D. D. Bikle, T. Sakata, C. Leary, H. Elalieh, D. Ginzinger, C. J. Rosen, W. Beamer, S. Majumdar, and B. P. Halloran. Insulin-like growth factor I is required for the anabolic actions of parathyroid hormone on mouse bone. J Bone Miner Res, 17, 1570–1578 (2002). L. M. Calvi, G. B. Adams, K. W. Weibrecht, J. M. Weber, D. P. Olson, M. C. Knight, R. P. Martin, E. Schipani, P. Divieti, F. R. Bringhurst, L. A. Milner, H. M. Kronenberg, and D. T. Scadden. Osteoblastic cells regulate the haematopoietic stem cell niche. Nature, 425, 841–846 (2003). J. Pfeilschifter and G. R. Mundy. Modulation of type beta transforming growth factor activity in bone cultures by osteotropic hormones. Proc Natl Acad Sci USA, 84, 2024–2028 (1987). A. M. Delany, D. Durant, and E. Canalis. Glucocorticoid suppression of IGF I transcription in osteoblasts. Mol Endocrinol, 15, 1781–1789 (2001). M. Ernst and G. A. Rodan. Estradiol regulation of insulinlike growth factor-I expression in osteoblastic cells: Evidence for transcriptional control. Mol Endocrinol, 5, 1081–1089 (1991). V. Gangji, S. Rydziel, B. Gabbitas, and E. Canalis. Insulinlike growth factor II promoter expression in cultured rodent osteoblasts and adult rat bone. Endocrinology, 139, 2287–2292 (1998). M. A. van Dijk, F. M. van Schaik, H. J. Bootsma, P. Holthuizen, and J. S. Sussenbach. Initial characterization of the four promoters of the human insulin-like growth factor II gene. Mol Cell, Endocrinol, 81, 81–94 (1991). R. Okazaki, B. L. Riggs, and C. A. Conover. Glucocorticoid regulation of insulin-like growth factor-binding protein expression in normal human osteoblast-like cells. Endocrinology, 134, 126–132 (1994). D. L. Andress and R. S. Birnbaum. Human osteoblast-derived insulin-like growth factor (IGF) binding protein-5 stimulates
8/22/2007 4:17:41 PM
546
235.
236.
237.
238.
239.
240.
241.
242.
243. 244.
245.
246.
247. 248.
Marcus-Ch19.indd 546
Ernesto Canalis
osteoblast mitogenesis and potentiates IGF action. J Biol Chem, 267, 22467–22472 (1992). J. I. Jones, A. Gockerman, W. H. Busby, Jr., C. CamachoHubner, and D. R. Clemmons. Extracellular matrix contains insulin-like growth factor binding protein-5: Potentiation of the effects of IGF-I. J Cell Biol, 121, 679–687 (1993). S. Amin, B. L. Riggs, E. J. Atkinson, A. L. Oberg, L. J. Melton, III, and S. Khosla. A potentially deleterious role of IGFBP-2 on bone density in aging men and women. J Bone Miner Res, 19, 1075–1083 (2004). F. Eckstein, T. Pavicic, S. Nedbal, C. Schmidt, U. Wehr, W. Rambeck, E. Wolf, and A. Hoeflich. Insulin-like growth factor-binding protein-2 (IGFBP-2) overexpression negatively regulates bone size and mass, but not density, in the absence and presence of growth hormone/IGF-I excess in transgenic mice. Anat Embryol (Berl), 206, 139–148 (2002). J. V. Silha, S. Mishra, C. J. Rosen, W. G. Beamer, R. T. Turner, D. R. Powell, and L. J. Murphy. Perturbations in bone formation and resorption in insulin-like growth factor binding protein-3 transgenic mice. J Bone Miner Res, 18, 1834–1841 (2003). N. Miyakoshi, X. Qin, Y. Kasukawa, C. Richman, A. K. Srivastava, D. J. Baylink, and S. Mohan. Systemic administration of insulin-like growth factor (IGF)-binding protein-4 (IGFBP-4) increases bone formation parameters in mice by increasing IGF bioavailability via an IGFBP-4 protease-dependent mechanism. Endocrinology, 142, 2641–2648 (2001). C. Richman, D. J. Baylink, K. Lang, C. Dony, and S. Mohan. Recombinant human insulin-like growth factor-binding protein-5 stimulates bone formation parameters in vitro and in vivo. Endocrinology, 140, 4699–4705 (1999). R. D. Devlin, Z. Du, V. Buccilli, V. Jorgetti, and E. Canalis. Transgenic mice overexpressing insulin-like growth factor binding protein-5 display transiently decreased osteoblastic function and osteopenia. Endocrinology, 143, 3955–3962 (2002). M. Zhang, M. C. Faugere, H. Malluche, C. J. Rosen, S. D. Chernausek, and T. L. Clemens. Paracrine overexpression of IGFBP-4 in osteoblasts of transgenic mice decreases bone turnover and causes global growth retardation. J Bone Miner Res, 18, 836–843 (2003). D. Durant, R. M. Pereira, and E. Canalis. Overexpression of insulin-like growth factor binding protein-5 decreases osteoblastic function in vitro. Bone, 35, 1256–1262 (2004). C. Hassager, L. A. Fitzpatrick, E. M. Spencer, B. L. Riggs, and C. A. Conover. Basal and regulated secretion of insulin-like growth factor binding proteins in osteoblast-like cells is cell line specific. J Clin Endocrinol Metab, 75, 228–233 (1992). T. L. McCarthy, S. Casinghino, M. Centrella, and E. Canalis. Complex pattern of insulin-like growth factor binding protein expression in primary rat osteoblast enriched cultures: Regulation by prostaglandin E2, growth hormone, and the insulin-like growth factors. J Cell Physiol, 160, 163–175 (1994). R. S. Birnbaum and K. M. Wiren. Changes in insulin-like growth factor-binding protein expression and secretion during the proliferation, differentiation, and mineralization of primary cultures of rat osteoblasts. Endocrinology, 135, 223– 230 (1994). E. Canalis and B. Gabbitas. Skeletal growth factors regulate the synthesis of insulin-like growth factor binding protein-5 in bone cell cultures. J Biol Chem, 270, 10771–10776 (1995). T. L. Chen, L. Y. Chang, D. A. DiGregorio, A. J. Perlman, and Y. F. Huang. Growth factor modulation of insulin-like
249.
250.
251. 252.
253.
254.
255. 256. 257.
258.
259.
260.
261.
262.
263.
growth factor-binding proteins in rat osteoblast-like cells. Endocrinology, 133, 1382–1389 (1993). Y. Dong and E. Canalis. Insulin-like growth factor (IGF) I and retinoic acid induce the synthesis of IGF-binding protein 5 in rat osteoblastic cells. Endocrinology, 136, 2000–2006 (1995). T. Moriwake, H. Tanaka, S. Kanzaki, J. Higuchi, and Y. Seino. 1,25–Dihydroxyvitamin D3 stimulates the secretion of insulin-like growth factor binding protein 3 (IGFBP-3) by cultured human osteosarcoma cells. Endocrinology, 130, 1071–1073 (1992). C. A. Conover. Insulin-like growth factor binding protein proteolysis in bone cell models. Prog Growth Factor Res, 6, 301–309 (1995). S. Kanzaki, S. Hilliker, D. J. Baylink, and S. Mohan. Evidence that human bone cells in culture produce insulin-like growth factor-binding protein-4 and -5 proteases. Endocrinology, 134, 383–392 (1994). N. Franchimont, D. Durant, and E. Canalis. Interleukin-6 and its soluble receptor regulate the expression of insulinlike growth factor binding protein-5 in osteoblast cultures. Endocrinology, 138, 3380–3386 (1997). S. Rydziel, A. M. Delany, and E. Canalis. AU-rich elements in the collagenase 3 mRNA mediate stabilization of the transcript by cortisol in osteoblasts. J Biol Chem, 279, 5397–5404 (2004). A. J. Strain. Hepatocyte growth factor: Another ubiquitous cytokine. J Endocrinol, 137, 1–5 (1993). K. Matsumoto and T. Nakamura. Emerging multipotent aspects of hepatocyte growth factor. J Biochem (Tokyo), 119, 591–600 (1996). J. Okano, G. Shiota, and H. Kawasaki. Protective action of hepatocyte growth factor for acute liver injury caused by D-galactosamine in transgenic mice. Hepatology, 26, 1241–1249 (1997). F. Blanquaert, A. M. Delany, and E. Canalis. Fibroblast growth factor-2 induces hepatocyte growth factor/scatter factor expression in osteoblasts. Endocrinology, 140, 1069–1074 (1999). M. Grano, F. Galimi, G. Zambonin, S. Colucci, E. Cottone, A. Z. Zallone, and P. M. Comoglio. Hepatocyte growth factor is a coupling factor for osteoclasts and osteoblasts in vitro. Proc Natl Acad Sci USA, 93, 7644–7648 (1996). G. Zambonin, C. Camerino, G. Greco, V. Patella, B. Moretti, and M. Grano. Hydroxyapatite coated with hepatocyte growth factor (HGF) stimulates human osteoblasts in vitro. J Bone Joint Surg Br, 82, 457–460 (2000). F. Bladt, D. Riethmacher, S. Isenmann, A. Aguzzi, and C. Birchmeier. Essential role for the c-met receptor in the migration of myogenic precursor cells into the limb bud. Nature, 376, 768–771 (1995). F. Blanquaert, R. C. Pereira, and E. Canalis. Cortisol inhibits hepatocyte growth factor/scatter factor expression and induces c-met transcripts in osteoblasts. Am J Physiol Endocrinol Metab, 278, E509–E515 (2000). Y. Imai, H. Terai, C. Nomura-Furuwatari, S. Mizuno, K. Matsumoto, T. Nakamura, and K. Takaoka. Hepatocyte growth factor contributes to fracture repair by upregulating the expression of BMP receptors. J Bone Miner Res, 20, 1723–1730 (2005).
8/22/2007 4:17:41 PM
Skeletal Growth Factors Ernesto Canalis
I. II. III. IV. V.
I.
Introduction Platelet-Derived Growth Factor Vascular Endothelial Growth Factor Fibroblast Growth Factor Transforming Growth Factor Beta
INTRODUCTION
Bone formation and resorption are regulated by systemic and local factors acting in concert to maintain bone mass. Calciotropic and steroid hormones have been studied extensively for their effects on bone remodeling. However, there is compelling evidence to support the concept that systemic and locally produced growth factors play a central role in the regulation of bone remodeling. Growth factors regulate the replication, differentiation, and function of bone cells. This chapter will be limited to the description of factors that have a major effect on bone formation and osteoblastic function, whereas other chapters of this book will describe cytokines that regulate bone resorption. This is a somewhat arbitrary division since bone remodeling is coupled and osteoclastogenesis is highly dependent on osteoblastic signals. Furthermore, cytokines with primary effects on cells of the osteoclast lineage also play a role in the process of bone formation. Although skeletal cells synthesize a variety of factors, some skeletal growth factors, such as platelet-derived growth factor (PDGF), vascular endothelial growth factor (VEGF), fibroblast growth factor (FGF), transforming growth factor β (TGF β), bone morphogenetic proteins (BMP), and insulin-like growth factors (IGF) have been studied in more detail. Some of these factors act as bone cell mitogens, and as such they are important in the maintenance of an adequate number of skeletal cells. They also may increase bone cell replication when additional cells are needed, such as during fracture healing and repair. A factor may play a role in the differentiation of cells and osteoblastogenesis, or may stimulate the differentiated function of mature cells. There are no growth factors specifically synthesized by skeletal cells, and those known as skeletal growth factors also are expressed in various nonskeletal tissues. However, growth factors are regulated specifically in bone at the level of synthesis or activity by agents that OSTEOPOROSIS, 3RD EDITION Marcus, Feldman, Nelson, and Rosen
Marcus-Ch19.indd 529
VI. VII. VIII. IX.
Bone Morphogenetic Protein Insulin-Like Growth Factor Insulin-Like Growth Factor Binding Proteins Hepatocyte Growth Factor Acknowledgments
act primarily on this tissue. Growth factors synthesized by skeletal cells may be present in the systemic circulation, and act both as local and systemic regulators of bone remodeling. The source of circulating growth factors varies, although it is frequently the liver, the circulating platelets, or peripheral tissues. The systemic form of a factor can be regulated by agents and mechanisms different from those affecting the locally produced factor, and it is conceivable that the roles of the circulating and local form of a growth factor differ. This is not only because their synthesis is regulated by different hormones, but also because they may become available under different physiological or pathophysiological circumstances. It is tempting to believe that the local form of a growth factor plays a more immediate, and possibly important role in the control of cell function since it has a more direct access to its target cell. Locally synthesized growth factors can act either as autocrine factors and affect cells of the same class, or paracrine factors and affect different or adjacent cells. In this chapter the function and regulation of selected growth factors will be discussed and their relevance to skeletal physiology will be considered.
II. PLATELET-DERIVED GROWTH FACTOR PDGF was originally isolated from human platelets, and four members of the pdgf gene family have been identified—pdgf a, pdgf b, pdgf c, and pdgf d [1]. VEGF shares a high degree of sequence homology with PDGF and these factors are often referred as members of the PDGF/VEGF family [2]. This family of genes encodes a highly conserved cystine knot motif. The recently discovered pdgf c and pdgf d genes have a Clr/ Cls, urchin endothelial growth factor, BMP l (CUB) domain linked to the cystine knot core motif by a hinge domain [3, 4, 5, 6]. Several reports have indicated that Copyright © 2008, Elsevier, Inc. All rights reserved.
8/22/2007 4:17:38 PM
530 proteolytic release of the core from the CUB domain is required for the activation of PDGF C and PDGF D, although activity for the full-length peptide and independent activity for the CUB domain have been postulated [3, 5, 6]. PDGFs must form homo- or heterodimers to exhibit activity, and they can form PDGF AA, BB, AB, CC, or DD dimers [3]. The various pdgf genes are conspicuously expressed during development and in adult tissues. Transcripts for the pdgf a, pdgf b, and pdgf c genes are detected in osteoblasts, but their basal expression is relatively low [3, 7, 8, 9]. PDGF D is synthesized by myocardial and vascular cells, where it induces cell proliferation and fibrosis, but there are no reports of PDGF D synthesis by the osteoblast [10]. Since PDGF is present in circulating platelets, it can act as a local and systemic regulator of cell function [11]. The five PDGF isoforms described can interact with either one of two PDGF receptors, which have differential binding specificity for the various PDGF dimers [12, 13, 14, 15]. PDGF receptor (PDGFR) α ligates PDGF A, B, and C chains and PDGFR β binds PDGF B and D chains [3]. The two PDGF receptors are structurally and functionally related, and PDGF binding results in receptor dimerization and the formation of PDGF αα, ββ, and αβ receptor dimers [3]. For receptor activation, PDGF AA and PDGF CC require PDGFR αα, or αβ dimers, PDGF DD requires PDGFR ββ, or αβ dimers, whereas PDGF AB and PDGF BB can activate either PDGFR αα, αβ, or ββ dimers. PDGF AA, AB, and BB are the isoforms studied more extensively in skeletal cells, and they exert similar biological actions. However, in skeletal as well as nonskeletal cells, PDGF BB is more potent than PDGF AA, and PDGF AB has intermediate activity [16]. The primary action of PDGF in bone is the stimulation of DNA synthesis and of cell replication. Histomorphometric analysis reveals an increase in cells of the osteoblastic lineage, but the effect is not specific and PDGF causes a generalized stimulation of cell replication in bone [17]. The mitogenic effect is observed primarily in the periosteal layer, a zone rich in fibroblasts and preosteoblasts. It could be presumed that preosteoblastic cells, replicating under the influence of PDGF, eventually differentiate into mature osteoblasts. However, an inhibitory effect on the differentiation of stromal cells into cells of the osteoblastic lineage has been reported [18]. This would indicate that the cells affected could remain in a proliferative undifferentiated state. Some cells, responding to other local signals, may differentiate, and as a consequence of the increased cell number, a modest increase in collagen synthesis is observed following exposure to PDGF. It is important to note that, in accordance with the impaired cell differentiation, PDGF inhibits the expression of the mature osteoblastic
Marcus-Ch19.indd 530
Ernesto Canalis
phenotype, and decreases alkaline phosphatase activity and type I collagen mRNA levels [19, 16, 17]. In calvariae, PDGF inhibits mineral apposition rates. These effects may be direct and indirect since PDGF inhibits the synthesis of IGF-I and -II in osteoblasts, and IGF-I and -II enhance osteoblastic functions [20, 21]. PDGF enhances bone resorption by increasing the number of osteoclasts, an effect that may be secondary to an increase in the expression of interleukin (IL)-6, a cytokine known to induce osteoclastogenesis [22]. In agreement with its effects on bone resorption, PDGF increases the expression of matrix metalloproteinases (MMP) by the osteoblast [23, 24]. PDGF increases the rate of transcription of the collagenase 3 (MMP-13) gene, and mRNA stability in transcriptionally arrested osteoblasts. MMP-13 is a proteinase capable of initiating the degradation of type I collagen at neutral pH, and necessary to achieve a bone resorptive response to parathyroid hormone (PTH) [25]. Cells of the osteoblastic lineage express PDGF α and β receptors. PDGF binding to its osteoblast receptor results in receptor dimerization, and activation of tyrosine kinase activity, leading to activation of protein kinase C (PKC), and intracellular calcium signaling pathways [26, 27]. In rodent, but not in human osteoblasts, IL-1 increases PDGF α receptor transcripts and the binding and mitogenic activity of PDGF AA [16, 28, 29]. TGF β decreases PDGF binding, and hormones have no effect on PDGF binding to osteoblasts [30]. Information on the activity of PDGF CC and PDGF DD in skeletal cells is limited. PDGF CC interacts with PDGF αα and αβ receptor dimers, and has potent mitogenic activity for mesenchymal cells [4]. PGDF CC induces the differentiation and regulation of endothelial cells and has potent angiogenic properties, directly or indirectly by upregulating VEGF [31]. These properties of PDGF CC could be important during the vascularization of endochondral bone formation, as it has been described for VEGF. PDGF DD interacts with PDGF β receptors, has mitogenic activity for vascular cells, and induces tissue fibrosis, but its effects on the skeleton are not known [10]. Although there is considerable knowledge about the actions of PDGF in vitro, information about its effects on the skeleton in vivo is more limited. Consistent with some of its in vitro effects, the systemic administration of PDGF BB to ovariectomized rats prevents bone loss, and increases the number of osteoblasts and bone formation [32]. It is likely that the mitogenic effects of PDGF on preosteoblasts result in an increased number of osteoblasts, which are capable of forming bone. PDGF does not change osteoclast number when administered systemically to ovariectomized rats, but this may be related to this particular model
8/22/2007 4:17:39 PM
531
Chapter 19 Skeletal Growth Factors
where the ovariectomy causes a substantial increase in bone resorption and remodeling, precluding an additional effect by PDGF. Topical application of PDGF to craniotomy defects in rodents stimulates soft tissue repair, but not osteogenesis [33]. The effects of PDGF on endothelial cell proliferation and angiogenesis are likely beneficial to the process of wound healing, and PDGF accelerates the healing response of wounds due to an increase in cellularity and in the formation of granulation tissue [34]. Genetically engineered mice with gain and loss of function mutations have provided important information on the physiological role of PDGF during development and post-natality. Null mutations of pdgf b, pdgf a and b receptors cause embryonic lethality, and pdgf a deletions cause prenatal and perinatal death [35]. Therefore, these models have not allowed for the study of the function of PDGF in the postnatal skeleton. pdgf b and pdgf b receptor null mice develop microvascular bleeding and absent vascular and mesangial cells [36, 37]. pdgf a and pdgf a receptor null mutants have defective alveolar formation in the lungs leading to emphysema, and have reduced intestinal villi, thin dermis, and spermatogenic arrest, but pdgf a null mutants do not manifest a skeletal phenotype [38,39]. pdgf c null mice exhibit neonatal lethality and numerous skeletal developmental abnormalities, including cleft palate and spina bifida [40]. Similar defects are observed in pdgf a receptor null mice, which exhibit a phenotype characterized by embryonic lethality, cleft face, spina bifida, and vascular and skeletal defects [38, 39]. Although PDGF B can interact with the PDGF α receptor, loss of function mutations of the pdgf b gene do not resemble the pdgf a receptor null phenotype, indicating that the functions of the PDGF α and β receptors are not redundant [36, 37]. The phenotype of pdgf d gene deletion has not been reported, but overexpression of PDGF DD, like that of PDGF CC, results in tissue fibrosis [41,10]. This may be secondary to the mitogenic properties of PDGF CC and PDGF DD or due to the induction of tissue inhibitors of metalloproteinases. The major source of PDGF is the systemic circulation, and skeletal cells probably become exposed to significant concentrations of PDGF following platelet aggregation. Nevertheless, skeletal cells express the pdgf a, pdgf b and pdgf c genes indicating that PDGF isoforms may act as autocrine regulators of skeletal cell function [8, 42, 9]. The expression of the pdgf a gene is enhanced by TGF β and by PDGF, and that of pdgf b enhanced by TGF β [42, 9]. Following an initial induction of PDGF A, an autoregulatory mechanism may serve to maintain local levels of the growth factor. The regulation of pdgf gene expression in skeletal
Marcus-Ch19.indd 531
cells is analogous to its regulation in nonskeletal cells indicating that there are no specific transcription factors responsible for the expression of PDGF in bone. Systemic hormones are not known to regulate pdgf gene expression in osteoblasts. Since both TGF β and PDGF are released by platelets following platelet aggregation, the subsequent induction of PDGF by these factors in the bone microenvironment may be a mechanism to ensure adequate levels of PDGF in skeletal tissues in conditions that follow platelet aggregation, such as fracture repair. Under basal conditions there may be no need for skeletal cells to be exposed to significant concentrations of PDGF, and its levels are low [42, 9].
III. VASCULAR ENDOTHELIAL GROWTH FACTOR VEGF shares sequence homology and angiogenic properties with PDGFs, and often they are referred to as members of the PDGF/VEGF family [3, 43]. VEGF A belongs to a gene family also composed of placenta growth factor, vegf b, vegf c, and vegf d [43]. In the mouse, differential splicing results in three VEGF A isoforms, VEGF A 120, VEGF A 164, and VEGF A 188. VEGF A is essential for angiogenesis and vegf a and vegf receptor 1 and 2 genes are expressed by chondrocytes and osteoblasts [44, 45]. VEGF A is required for blood vessel formation and vessel invasion into cartilage during the process of endochondral bone formation, and for chondrocyte survival during skeletal development [46, 47]. The expression of vegf a by chondrocytes requires runt related transcription factor-2 (Runx-2), a transcription factor essential for normal osteogenesis [47]. VEGF A also is required for intramembranous bone formation, it enhances osteoblastic maturation in vitro, and VEGF receptor 1 signaling is essential for osteoclast development [48, 49, 47]. vegf a gene null deletions are lethal due to defective hematopoiesis and defective blood vessel formation, but mice expressing one of three VEGF A isoforms, VEGF A 120, survive and their study has documented the function of VEGF A on endochondral bone formation and osteoblastic maturation [50]. Bone histomorphometric analysis following adenoviral vector delivery of VEGF A also demonstrates a stimulatory effect of VEGF on osteoblast number, and in vivo VEGF A promotes angiogenesis and fracture repair [51, 45]. The expression of VEGF by osteoblasts is regulated by various growth factors. Activation of mitogen activated protein (MAP) kinases by BMP, TGF β, or FGF-2 and activation of phosphatidylinositol-3 (PI3) kinase by IGF-I induces vegf expression in osteoblasts [52, 53, 54, 55]. Following growth factor-induced
8/22/2007 4:17:39 PM
532
Ernesto Canalis
synthesis, VEGF may serve to couple angiogenesis and osteoblastic differentiation and function [56, 46]. The stimulatory effect of IGF-I on vegf a gene expression is mediated by the hypoxia inducible factor (HIF) 2 α. This may result in an increased vascular supply to the local environment, and may serve as a protective mechanism in response to changes in oxygen availability to the osteoblast [52]. It is of interest that the phenotypes of the conditional deletion of hif-1 and of vegf-a in cartilage are analogous [47].
IV.
FIBROBLAST GROWTH FACTOR
FGFs form a family of at least 23 structurally related polypeptides, characterized by their affinity to glycosaminoglycan heparin binding sites [57]. FGFs were initially isolated from the central nervous system and subsequently found in a variety of tissues, where they regulate cell function [58, 59]. Skeletal cells synthesize both FGF-1 and -2, the forms of FGF most extensively studied for their actions on the skeleton [60, 61]. FGF has mitogenic activity in skeletal and nonskeletal cells and potent angiogenic properties [62, 63, 64]. FGF increases a population of cells of the osteoblastic lineage, which differentiate into osteoblasts [63]. However, FGF, like other potent mitogens, does not enhance the differentiated function of the osteoblast directly, and FGF-2 inhibits alkaline phosphatase activity, type I collagen, osteocalcin and osteopontin synthesis, independently of its stimulatory effects on osteoblastic cell growth [65, 66]. These effects are paralleled in vivo and transgenic mice overexpressing FGF-2 are osteopenic, although fgf 2 null mice exhibit impaired bone formation [67, 68]. The inhibitory effect of FGF-2 on osteoblast differentiation is secondary to the induction of the transcription factor Sox 2 and the inhibition of Wnt signaling, which is essential for osteoblastogenesis [69, 70]. Confirming an inhibitory effect on osteoblastic function, FGF-2 suppresses the synthesis of IGF-I, a factor that stimulates the differentiated function of the osteoblast [20]. FGF-2 increases bone resorption by favoring osteoclastogenesis, and stimulates the synthesis of collagenase 3 (MMP-13) by the osteoblast [71, 72]. Marrow stromal cells from fgf-2 null mice exhibit decreased osteoclastogenesis in response to PTH. FGF-2 induces TFG β1 transcription, and TGF β could mediate selected actions of FGF in bone [73]. The actions of FGF can be regulated by modifications in the affinity or number of FGF receptors in target cells. FGF receptors are a family of four distinct receptors, FGFR1 through 4 [74, 75, 76]. FGF receptors are
Marcus-Ch19.indd 532
transmembrane protein responsive kinases with two to three immunoglobulin-like domains. Differential splicing of the extracellular region of FGF receptors can generate receptor variants with different ligand binding specificity [74, 76]. The four known receptors, and variants, bind the members of the FGF family of polypeptides with different affinity, and have different signaling and mitogenic potential. Activation of FGFR1, 2, and 3 by FGFs induces a mitogenic response, whereas activation of FGFR4 does not [75]. Accordingly, mutations of the fgfr-1, -2, or -3 cause diverse skeletal syndromes including achondroplasia, a common cause of dwarfism [77]. Studies on FGF receptors in preosteoblasts and osteoblasts have been limited. Activation of the signal transducers and activators of transcription 1 regulates FGF receptor in skeletal cells, and suppresses FGFR-3 expression in osteoblasts and mediates FGF-2 actions in chondrocytes [78, 79]. In vivo administration of FGF-2 promotes bone and cartilage repair and topical administration of FGF-2 accelerates fracture healing in rodents and nonhuman primates [80, 81]. The mechanism is related to the mitogenic properties of FGF-2 in skeletal cells in conjunction with its angiogenic activity. Although studies in fgf-2 null mice demonstrate that FGF-2 is required for bone formation, transgenic mice overexpressing FGF-2 in the bone environment are osteopenic [68, 67]. This observation is in accordance with in vitro studies demonstrating an inhibitory effect of FGF-2 on Wnt signaling, IGF-I expression, and osteoblastic function [20, 70]. Embryos harboring null mutations of the fgf receptor 2 die prior to skeletogenesis, but conditional inactivation of the FGF receptor 2 results in skeletal dwarfism secondary to decreased proliferation of osteoprogenitors without affecting osteoblast differentiation [82]. These observations confirm early in vitro studies demonstrating a central role of FGF-2 on preosteoblastic cell proliferation, but not a stimulatory effect on osteoblastic function. Investigations on the regulation of FGF synthesis in skeletal cells are limited to FGF-2. In fibroblasts, heat shock induces the release of FGF, suggesting that its secretion is related to cellular stress [83]. The regulation of FGF-2 expression in osteoblasts and nonskeletal fibroblasts is similar, and TGF β1 and FGF-2 increase FGF-2 synthesis in osteoblasts [61]. Sequence analysis of the FGF-2 promoter reveals AP-1 recognition sequences; therefore, signals that induce Fos and Jun, components of the AP-1 complex, have the potential to upregulate fgf-2 gene transcription [84]. PDGF enhances the expression of FGF-2 mRNA levels in fibroblasts, and possibly in osteoblasts. Therefore, skeletal growth factors with mitogenic properties, such as FGF-2 and PDGF, are major inducers of FGF-2 synthesis. PTH
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
causes a transient induction of FGF-2 transcripts in osteoblasts [85]. FGF is stored in the extracellular matrix, where it is complexed by extracellular matrix and cell surface-associated heparan sulfate proteoglycans, which may prolong its half-life and allow future interactions with its receptors [86]. Binding of FGF to heparan sulfate proteoglycans is a necessary step for the presentation of the factor to its receptor. The heparan sulfate proteoglycan syndecan is an integral membrane proteoglycan that binds FGF and components of the extracellular matrix, suggesting that it can regulate the effects of FGF-2 on cell growth [57].
V. TRANSFORMING GROWTH FACTOR BETA TGF β belongs to a family of closely related polypeptides with various degrees of structural homology and important effects on cell function [87, 88]. There are five TFG β genes, and mammalian cells express TGF β1, 2, and 3. Bone matrix contains TGF β1, 2, and 3 homodimers as well as 1.2 and 2.3 heterodimers [88, 89]. TGF β1, 2, and 3 have similar effects on bone cell function although their potency differs [89]. TGF β stimulates DNA synthesis and cell replication and has a modest stimulatory effect on collagen synthesis in calvariae [90]. Bone histomorphometric analysis of intact rat calvariae exposed to TGF β demonstrates a stimulatory effect on mineral apposition rates, and in vivo studies have confirmed a stimulatory effect of TGF β on bone formation [91, 92, 93]. The effects of TGF β on cell replication and the differentiated function of the osteoblast are dependent on the target cell, its state of differentiation and the culture conditions used. In primary cultures of rat osteoblasts, TGF β has a biphasic stimulatory effect on DNA synthesis, whereas in rat osteosarcoma cells it inhibits cell growth [94, 95, 96]. In osteoblasts, TGF β inhibits alkaline phosphatase activity and osteocalcin synthesis, suggesting an inhibitory effect on their differentiated function. TGF β stimulates collagen synthesis by increasing type I collagen gene transcription [97]. In osteosarcoma cells, TGF β increases type I collagen, fibronectin, osteonectin, and osteopontin mRNA expression [98]. In stromal cell cultures, TGF β favors chondrocytic differentiation, and opposes the effect of BMP on osteoblastogenesis [99]. Consequently, whereas TGF β stimulates selected parameters of osteoblastic function, it does not direct the maturation of undifferentiated cells toward osteoblasts, and seems more relevant to chondrogenesis than to osteoblastogenesis. The actions of TGF β on bone resorption also have been a source of controversy. TGF β has a biphasic effect on osteoclastogenesis.
Marcus-Ch19.indd 533
533 At low concentrations it enhances osteoclast formation, whereas at high concentrations it is inhibitory. The stimulatory effect on osteoclast formation seems to be related to the production of prostaglandins, and the inhibitory effect secondary to a decrease in the differentiation of early stem cells into cells of the osteoclast lineage because of a shift toward cells of the granulocyte lineage [100, 101]. The impaired osteoclastogenesis would explain a decrease in bone resorption [102]. Osteoblasts express type I and II TGF β receptors, and PTH and glucocorticoids modify TGF β binding to its receptors on osteoblasts [103, 104]. Glucocorticoids shift the binding of TGF β from type I and II receptors to betaglycan, which is not a signal transducing molecule [105]. In accordance with its actions in vitro, the systemic administration of TGF β2 to experimental animals stimulates cancellous bone formation, and subperiosteal injections of TGF β1 and 2 induce osteogenesis and chondrogenesis in rat femurs [106, 93]. In contrast, transgenic mice overexpressing TGF β2, under the control of the osteoblast specific osteocalcin promoter, exhibit osteopenia [107]. Although TGF β induces chondrocyte differentiation, suppression of TGF β signaling in vivo also favors terminal chondrocyte differentiation, suggesting a dual role of TGF β on chondrocyte maturation [108]. Targeted gene disruption of the mouse tgf b gene does not result in changes in skeletal development [109]. This may be secondary to an early lethal phenotype of tgf b null mice, due to a severe inflammatory disease. TGF β enhances soft tissue wound healing, and like FGF-2 it may play a role in fracture repair [110]. However, its cytostatic actions and its fibrosis-inducing properties would limit its topical and systemic use in the treatment of metabolic bone disorders [111, 112, 113]. TGF β is secreted as a latent high molecular weight complex consisting of the carboxy terminal remnant of the TGF β precursor and a TGF β binding protein [114, 115, 116, 117]. The biologically active levels of TGF β depend on changes in its synthesis and in the activation of its latent form. By inducing lysosomal proteases, bone regulatory agents increase the levels of biologically active TGF β in bone [118, 119]. FGF, TGF β itself, and estrogens increase TGF β1 synthesis in osteoblasts, and ovariectomy reduces the concentration of TGF β in rodent bone [118, 120]. The latter may suggest a role of TGF β in the abnormalities observed in the estrogen deficient state. There have been limited studies on the regulation of TGF β2 and TGF β3 synthesis in osteoblasts, but the tgf b2 and tgf b3 gene promoters contain cyclic AMP responsive elements, indicating a potential regulation by cyclic AMP inducers [121, 122].
8/22/2007 4:17:39 PM
534 VI.
Ernesto Canalis
BONE MORPHOGENETIC PROTEIN
BMPs are members of the TGF β superfamily of polypeptides, and were originally identified because of their ability to induce endochondral bone formation [123, 124, 125]. BMPs account for most of the TGF β superfamily of peptides, and the proteins display extensive conservation among species [123]. BMP-1 is a protease, which cleaves procollagen fibrils, and is unrelated to other BMPs [126]. BMP-3, or osteogenin, is different from other BMPs since it lacks their osteogenetic properties, and it inhibits osteogenesis and opposes BMP-2 actions [127, 128, 129]. Although BMPs are synthesized by skeletal cells, their synthesis is not limited to bone, and they are expressed by a variety of extraskeletal tissues, where they play a critical role in developmental and cellular functions. BMP-1 through -6 are expressed by osteoblasts, but the degree of expression depends on the cell line examined, and its stage of differentiation [130, 131, 132, 133]. BMP-2, -4, and -6 are the most readily detectable BMPs in osteoblast cultures and BMP-2 and -4 are 92% identical in their amino acid sequence and have virtually identical biological activities. Experiments using kinase-deficient truncated BMP receptors or using BMP antagonists have demonstrated that the locally synthesized BMPs play an autocrine role in osteoblastic differentiation and function [134]. A fundamental function of BMPs is the induction of mesenchymal cell differentiation toward cells of the osteoblastic lineage, and to the promotion of osteoblastic activity [135, 136]. As osteoblasts undergo terminal differentiation, they undergo apoptosis, an expected result of cell maturation [137,138,139]. Consequently, BMPs favor osteoblastic cell death. The genesis and differentiation of bone-forming osteoblasts and boneresorbing osteoclasts are coordinated events. Receptor activator of nuclear factor-κ B-ligand (RANK-L) and colony stimulating factor 1 are osteoblast products and are major determinants of osteoclastogenesis [140]. Osteoprotegerin, a secreted receptor of the tumor necrosis factor receptor family, acts as a decoy receptor that binds RANK-L, precluding RANK-L binding to RANK and its effects on osteoclastogenesis and bone resorption. BMPs play a direct and indirect role in osteoclastogenesis. By inducing osteoblast maturation, there is increased RANK-L availability. In addition, BMPs sensitize osteoclasts to the effects of RANK-L on osteoclastogenesis and osteoclast survival [141, 142]. BMPs also induce osteoprotegerin transcription, and this may temper their effects on osteoclastogenesis [143]. BMPs inhibit collagenase 3 or MMP-13 expression in osteoblasts, a matrix metalloprotease required for normal bone resorption [144, 145].
Marcus-Ch19.indd 534
BMPs induce endochondral ossification and chondrogenesis [146]. BMPs stimulate chondrocyte maturation and function, increasing the expression of type II and type X collagens and the incorporation of sulfate into glycosaminoglycans [147,148]. Overexpression of BMP-2 and -4 in developing limbs results in an increase in chondrocyte number and in matrix cartilage, which may lead to joint fusions [149]. The anabolic effects of Indian and Sonic hedgehog and BMP-2 and -4 in metatarsal cultures are analogous, and BMPs mediate their actions on endochondral ossification [150]. Whereas BMPs induce osteogenesis and chondrogenesis, they prevent terminal differentiation of myogenic cells, inhibiting the transcription of the muscle-specific nuclear factors MyoD and myogenin [151, 152]. BMPs act in conjunction with other growth factors, and by inducing the differentiation of cells of the osteoblastic lineage, BMPs increase the pool of IGF-I producing and IGF-I target cells [153]. BMPs interact with type IA or activin receptor like kinase (ALK)-3 and type IB or ALK-6, and BMP type II receptors [154]. Upon ligand binding and activation of the type I receptor, dimers of the type I and type II receptor initiate a signal transduction cascade activating the signaling mothers against decapentaplegic (Smad) or the MAP kinase signaling pathways [155, 156]. Following receptor activation by BMPs, Smad 1, 5 and 8 are phosphorylated at serine residues, and translocated into the nucleus following heterodimerization with Smad 4 [157, 158]. In the nucleus, Smads can bind to DNA sequences directly, bind and cooperate with other transcription factors, or bind and displace nuclear factors from their DNA binding sites. MAP kinase signaling results in P38 MAP kinase or extracellular regulated kinase (ERK) activation by BMPs [87, 159]. The transcriptional and post-transcriptional regulation of BMP expression in osteoblasts reveals autoregulation of BMP synthesis since BMP-2 and -4 mRNA levels are BMP dependent [130, 132]. BMPs cause an early, short lived, induction of BMP-4 mRNA in osteoblasts followed by an inhibitory effect. A positive feedback loop regulating BMP-2 and -4 expression involving Runx-2 is possible since BMPs induce Runx-2 expression and the BMP-2 and -4 promoters contain Runx-2 binding sequences. BMP-6 expression in osteoblasts is steroid-dependent, and BMP-6 mRNA levels are induced by estrogens [133]. Mice deficient in BMP-2 are not viable due to placental and developmental defects, and the bmp-4 null mutation is lethal between 6.5 and 9.5 days of gestation due to a lack of mesodermal differentiation, and patterning defects [160, 161]. Mice with disruptions of the BMP signaling smad 5 gene also develop multiple embryonic defects, some reminiscent of those observed
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
in bmp-2 null mutants [162, 163]. The lethality of these mutations has prevented the assessment of the impact of BMP-2 and -4 on the adult skeleton. The bmp-6 null mutation is not lethal, and skeletogenesis is normal except for delayed ossification in the sternum [164]. bmp gene inactivation results in significant developmental defects outside the skeleton, and bmp-7 null mice display lack of eye and glomerular development, and bmp-8 null mutations result in defective spermatogenesis [165, 166]. BMP activity is regulated by a large group of secreted polypeptides that bind and limit BMP action. These extracellular BMP antagonists prevent BMP signaling by binding BMPs, and precluding their binding to cell surface receptors [167,168]. Extracellular BMP antagonists include noggin, follistatin and follistatin related gene; ventroptin; twisted gastrulation; the chordin family, which is comprised of chordin, chordin-like, neuralin, CR rich motor neuron, BMP binding endothelial cell precursor-derived regulator, kielin, and crossveinless; and the Dan/cerberus family of genes, which is comprised of the tumor suppressor Dan, Cerberus, Cer 1, gremlin, and its rat homologue drm, the protein related to Dan and Cerberus, caronte, Dante, sclerostin (the product of the sost gene), Wise, and Coco [167, 169, 170, 171]. It is of interest that selected BMP antagonists, such as sclerostin and Coco, also block Wnt signaling [172, 173]. The pattern of tissue expression of BMP antagonists is dependent on the gene studied. Sclerostin is expressed selectively in osteoblasts and osteocytes, where it is regulated by PTH, and ectodin is expressed in tooth enamel [174, 175]. Overexpression of noggin and gremlin, two classic BMP antagonists, or sclerostin, in the skeletal microenvironment prevents osteoblastic differentiation in vitro, and in vivo causes osteopenia secondary to decreased bone formation [176, 177, 178, 179]. Inactivation of the noggin gene causes intrauterine lethality, and articular developmental defects leading to joint fusions [180]. It is of interest that the synthesis of many BMP antagonists, such as that of noggin and gremlin, is induced by BMPs in osteoblasts, suggesting the existence of a protective mechanism to prevent skeletal cells from excessive exposure to BMPs [181, 182].
VII.
INSULIN-LIKE GROWTH FACTOR
IGF-I and -II have structural similarities with proinsulin and are considered essential for normal cell growth in multiple tissues including bone [183]. IGF-I and -II are present in the systemic circulation and are secreted by the osteoblast. In the circulation, IGF-I forms a large molecular weight complex with
Marcus-Ch19.indd 535
535 insulin-like growth factor binding proteins (IGFBPs) and the acid labile subunit [184]. Although several IGFBPs form the complex, IGFBP-3 is the most abundant, and systemic IGF-I and IGFBP-3 levels are growth hormone (GH) dependent. IGFBPs are present in the circulation at concentrations in excess of those of IGF-I. Consequently, there is little free IGF-I in plasma. Systemic IGF-I is mostly synthesized in the liver and it is responsible for the growth-promoting effects of GH in various tissues [185, 186, 187]. It is important to note that IGF-I is synthesized by multiple peripheral tissues, where it is regulated by alternate hormones, and only to a minor extent by GH. In addition to their function as systemic regulators of growth, IGF-I and -II play an important role in the autocrine and paracrine regulation of cell metabolism in a variety of tissues, including bone [188, 189]. IGF-I and -II are the most prevalent growth factors present in the skeletal tissue. IGF-I and -II have similar effects on bone formation, although IGF-I is more potent than IGF-II [190, 191]. IGFs are modest mitogens, increasing the replication of preosteoblastic cells, which presumably differentiate into mature osteoblasts. The most important function of IGFs is to enhance the differentiated function of the osteoblast. IGFs stimulate type I collagen transcription, an effect independent from their mitogenic actions, and increase mineral apposition rates [192, 191]. IGF-I and -II inhibit collagenase 3 (MMP-13) synthesis by the osteoblast and as a consequence decrease bone collagen degradation [193]. IGF-I and -II are important in the maintenance of the differentiated osteoblast phenotype. IGFs not only enhance osteoblastic function, but their synthesis is differentially regulated by factors that stimulate or inhibit the differentiated expression of the osteoblastic phenotype [20]. A similar role has been suggested for IGF-II in myoblasts, where its expression follows that of genes that are determinants of myogenic differentiation [194]. It is important to note that whereas IGF-I stimulates the differentiated function of the osteoblast, it does not induce the differentiation of marrow stromal cells toward the osteoblastic pathway [195]. Indirectly, IGF-I might favor osteoblastogenesis since it stabilizes β catenin; consequently it has the potential to enhance the Wnt/β catenin signaling pathway, which is essential for osteoblastogenesis [196]. Although the primary role of IGFs is the stimulation of bone formation, IGF-I can increase the synthesis of RANK-L by osteoblasts and, in this way, enhance osteoclast recruitment, although in vivo experiments have demonstrated an inconsistent impact of IGF-I on osteoclastogenesis [197, 198, 199]. Skeletal cells express the IGF-I and IGF-II receptors, and the IGF-I receptor mediates their anabolic actions. This receptor is a transmembrane glycoprotein
8/22/2007 4:17:39 PM
536 tetramer with ligand-activated tyrosine kinase activity. Insulin receptor substrate (IRS) 1 and 2 are well-characterized substrates for the IGF receptor tyrosine kinase, mediating the effects of IGF-I [200, 201]. In osteoblasts, tyrosine phosphorylation of IRS molecules by the activated receptor results in the activation of PI-3 kinase-phospho Akt signaling or in the activation of the MAP kinases, p38, Jun-N-terminal kinases and ERK1/2 [202]. The IGF-II receptor is the same as the mannose-6-phosphate receptor, does not have a function in IGF signal transduction, and clears IGF-II, regulating its levels during fetal development [203]. IGF-I receptor number in osteoblasts can be modulated by various agents, known to regulate bone cell metabolism, including PDGF, glucocorticoids, and 1,25 dihydroxyvitamin D3 [204, 205, 206, 207]. IGF-I has been tested for its effects on bone metabolism in vivo in experimental animals and humans. IGF-I increases bone formation and prevents trabecular bone loss in experimental conditions of skeletal unloading and increases bone mineral density (BMD) in ovariectomized animals [208]. The short-term administration of IGF-I to normal humans results in an increase in serum levels of type I procollagen peptide and an increase in the excretion of collagen crosslinks, demonstrating an increase in bone turnover [209]. IGF-I increases BMD in patients with osteopenia secondary to anorexia nervosa, but the potential use of IGF-I in humans may be limited by possible side effects and the lack of skeletal specificity [210]. The content of IGF-I in human cortical bone decreases with age, a decline that parallels the one observed in serum concentrations of IGF-I with aging [211,212]. Consequently, it is not known whether it is due to a decrease in skeletal IGF-I accumulation from the systemic circulation, or due to a decrease in the synthesis of IGF-I by the aging skeleton. The study of genetically engineered mice has provided additional insight into the action of IGF-I in vivo. Transgenic mice overexpressing IGF-I under the control of the osteocalcin promoter exhibit a transient increase in trabecular bone volume secondary to an increase in osteoblast function and bone formation [197]. igf-1 and igf-1 receptor gene deletions have provided valuable information on the role of IGF-I during development, and conditional gene deletions have provided information on the effects of IGF-I in the adult skeleton [213, 186]. igf-1 deletion causes a reduction in chondrocyte maturation, and femoral length, and osteopenia secondary to a decrease in bone formation [186, 214]. Mice carrying mutations of the GH releasing hormone receptor or of the GH receptor have absent GH secretion or action, and consequently low serum IGF-I [215, 216]. These models allow for the determination of the contribution of systemic IGF-I
Marcus-Ch19.indd 536
Ernesto Canalis
to the skeleton, and the phenotype of either mutant is characterized by small growth plates, osteopenia and reduced cortical bone, but normal trabecular bone volume. This suggests a more pronounced role of systemic IGF-I on cortical than on trabecular bone. Mice carrying a liver-specific igf-1 deletion display a 75% reduction in total serum IGF-I levels, normal free IGFI levels, and absent skeletal phenotype attributed to the normal serum levels of free IGF-I and the extra hepatic synthesis of IGF-I [217]. However, mice carrying dual deletions of igf-1 and the acid labile subunit display marked reduction in total serum IGF-I and a significant reduction of cortical bone volume [218]. Igf-1 receptor null mice die after birth and demonstrate severe growth retardation, and the conditional disruption of the igf-1 receptor gene selectively in osteoblastic cells causes a decrease in osteoblast number, and impaired bone formation resulting in reduced trabecular bone volume [186, 198]. This observation documents the fundamental role played by IGF-I in the maintenance of bone formation and structure. Accordingly, deletion of the irs-1 or -2 gene causes osteopenia [219, 220]. However the phenotypes are not identical and irs-1 null mice exhibit low bone turnover osteopenia and do not respond to PTH, whereas igf-2 null mice exhibit increased bone resorption and respond to the anabolic effects of PTH in bone [220]. The various models described confirm the anabolic function of IGF-I on bone. Skeletal IGF-I might play a more important role in the maintenance of trabecular bone, and systemic IGF-I might be more important in the regulation of cortical bone. The igf-1 gene is complex, contains six exons, and has alternate promoters in exons 1 and 2 [221, 222]. The exon 1 promoter has four transcription initiation sites, and is responsible for the regulation of IGF-I expression in most extrahepatic tissues including bone [223]. The IGF-I exon 2 promoter has two transcription initiation sites and is responsible for the transcriptional regulation of IGF-I by GH in the liver [223]. IGF-I exon 2 is minimally expressed by osteoblasts, and GH is not a major inducer of IGF-I in these cells [224]. Hormones and growth factors regulate the synthesis of IGF-I in osteoblasts, and PTH, PTH related peptide, and other inducers of cyclic AMP in osteoblasts increase IGF-I synthesis [224]. IGF-I mediates selected anabolic actions of PTH in bone in vitro and in vivo [225]. The stimulatory effect of PTH on collagen synthesis in vitro is decreased by IGF-I neutralizing antibodies, and the stimulatory effect of PTH on bone formation in vivo is not observed in igf-1 or irs-1 null mice [226, 220]. These observations do not exclude the possibility that other factors mediate selected actions of PTH on the skeleton. For example, the effects of PTH on cell replication in the skeleton are independent
8/22/2007 4:17:39 PM
Chapter 19 Skeletal Growth Factors
of IGF-I synthesis and are dependent on Notch activation [227]. PTH also increases the levels of, and activates, skeletal TGF β, which could mediate selected effects of PTH in bone [228]. Estrogens increase and glucocorticoids inhibit IGF-I synthesis in osteoblasts [229, 230]. Selected inhibitory effects of glucocorticoids on bone metabolism can be explained by reduced IGF-I levels in the bone microenvironment. However, glucocorticoids also inhibit osteoblastic gene expression and function directly. In addition to hormones, skeletal growth factors regulate IGF-I synthesis. PDGF, FGF, and TGF β1 decrease IGF-I transcripts and polypeptide levels in osteoblasts, and this inhibition of IGF-I synthesis correlates with their inhibitory actions on osteoblastic differentiated function [20]. In contrast, BMP-2, an agent that enhances osteoblastic differentiation and function, increases IGF-I synthesis in osteoblasts [153]. The igf-2 gene is complex and contains four promoters, and in osteoblasts, like in hepatocytes, IGF-II expression is under the control of the IGF-II P3 promoter [231, 232]. Hormones do not modify IGF-II synthesis in skeletal cells. The skeletal growth factors FGF-2, PDGF, and TGF β1 inhibit IGF-II transcription by inhibiting IGF-II P3 activity, an effect analogous to their inhibition of IGF-I expression, demonstrating a coordinated suppression of IGF-I and -II synthesis by mitogenic growth factors [231].
VIII. INSULIN-LIKE GROWTH FACTOR BINDING PROTEINS IGFBPs are a family of related proteins known to bind specifically IGF-I and -II. There are six classic IGFBPs, termed IGFBP-1 to -6, and additional IGFBP related proteins [184]. There are significant structural similarities in IGFBPs among species, indicating a high degree of evolutionary conservation. Osteoblasts express IGFBP-1 to -6 transcripts [233]. IGFBPs regulate the bioavailability of IGFs and prevent their degradation. IGFBPs can potentiate or inhibit the effects of IGF-I and -II on cell function and vary in their affinity for IGF-I and IGF-II [184, 183]. The binding of IGFs to IGFBPs may sequester the growth factor and preclude its interactions with cell surface receptors, although IGFBPs associated with the extracellular matrix may increase the local effective concentration of the growth factor and potentiate its effects [234, 235]. In addition, IGFBPs may have IGF independent effects and regulate cellular events directly. IGFBP-2 is important in the storage and transport of IGFs, and IGFBP-2 serum levels correlate with BMD in humans [236]. In vitro, IGFBP-2 prevents the effects
Marcus-Ch19.indd 537
537 of IGF-I on osteoblast function, and overexpression of IGFBP-2 under the control of the cytomegalovirus (CMV) promoter leads to small mice with decreased bone mineral content and failure to respond to the anabolic effects of GH in bone [237]. IGFBP-3 is the major component of the IGF complex in serum and, like the circulating IGF-I, is GH dependent [184]. IGFBP-3 can inhibit or stimulate IGF activities, the latter by upregulating IGF-I delivery to cell surface receptors. Overexpression of IGFBP-3 under the control of the CMV or phosphoglycerate kinase promoter causes growth retardation and osteopenia [238]. IGBP4 is an IGF-I inhibitory binding protein, but under specific conditions IGFBP-4 and IGFBP-5 were reported to stimulate bone cell function independent from their interactions with IGF-I [239, 240]. However, transgenic mice overexpressing either IGFBP-4 or IGFBP-5 under the control of the osteoblast specific osteocalcin promoter exhibit osteopenia and decreased bone formation [241, 242]. The osteopenia is probably secondary to sequestration of the IGF-I present in the bone microenvironment inhibiting its biological activity. It is possible that the different reported effects of IGFBP-4 and -5 are dependent on their interactions with extracellular matrix proteins, or on the levels of IGFBP present in a specific tissue. However, both transgenic models indicate that IGFBP-4 and IGFBP-5 are inhibitory proteins in the skeletal environment. This was documented further using retroviral vectors to overexpress IGFBP-5, in osteoblastic cells, which provoked an inhibition of osteoblastic cell function [243]. IGFBP-1 is important for glucose homeostasis, and there is limited information on the function of IGFBP-6 in skeletal tissue. The synthesis of IGFBPs is regulated by transcriptional, post-transcriptional, and post-translational mechanisms. Although the six IGFBPs are expressed by skeletal and nonskeletal cells, their basal and regulated expression is cell specific [244, 245]. In vitro studies indicate that the pattern of IGFBP expression is dependent on the stages of osteoblast differentiation. IGFBP-2 and -5 expression is highest in the proliferative phase of rat osteoblastic cell cultures, and IGFBP3, -4, and -6 expression peaks during the maturation phase [246]. The regulation of IGFBP expression during osteoblastic cell differentiation may be related to the relative levels of autocrine and paracrine factors present in the cellular environment. IGFs increase osteoblast IGFBP-5 expression, whereas growth factors with mitogenic activity inhibit IGFBP-5 and stimulate IGFBP-4 expression [247, 248, 249]. In addition to local autocrine and paracrine factors, systemic hormones modulate IGFBP synthesis; however, the effects appear to be cell line and culture condition dependent [244]. GH increases IGFBP-3 in
8/22/2007 4:17:39 PM
538
Ernesto Canalis
normal rat osteoblasts, but not in osteosarcoma cells, and cyclic AMP inducers increase the synthesis of IGFBP-3, -4, and -5 [245]. Since agents that induce cyclic AMP in osteoblasts also stimulate the synthesis of IGF-I, the induction of the binding proteins may be a mechanism to control overexposure of cells to the newly synthesized IGF-I. Conversely, glucocorticoids inhibit the synthesis of IGF-I, IGFBP-3, -4 and -5, although they increase the expression of the inhibitory IGFBP-2 in osteoblasts, leading to a marked suppression of IGF-I available to skeletal cells [229, 233]. 1,25-dihydroxyvitamin D3 increases osteoblast IGFBP3 and -4 expression [250]. The abundance of IGFBPs in the extracellular space can be regulated by proteolytic degradation. IGFBP proteases have been characterized from diverse sources, including osteoblasts, which secrete MMPs and serine proteases [251]. Interestingly, the protease activity for IGFBP-4, an inhibitory IGFBP, and for IGFBP-5 is modulated by IGFs, which promote the degradation of IGFBP-4 and stabilize IGFBP-5, suggesting an alternate mechanism by which IGF activity can be modulated in bone [252]. The activity or synthesis of IGFBP proteases is modulated by agents known to regulate bone remodeling, such as IL-6 and glucocorticoids [253, 254].
IX.
HEPATOCYTE GROWTH FACTOR
Hepatocyte growth factor (HGF), also known as Scatter factor, is a large molecular weight polypeptide known for its angiogenic and mitogenic properties [255]. HGF plays a role in liver and kidney repair [256, 257]. HGF signals via the product of the protooncogene c-met, a tyrosine kinase-activated receptor, and HGF and c-met are expressed by mesenchymal cells, osteoblasts, and osteoclasts [258, 259]. HGF is mitogenic for cells of the osteoblastic and osteoclastic lineage, and its synthesis by the osteoblast is enhanced by growth factors with a role in wound and fracture repair [260]. Therefore, HGF may play a role in bone remodeling and repair. Studies in transgenic mice overexpressing HGF under the control of the metallothionein I promoter and studies in hgf or c-met null mice have revealed that HGF is required for muscle cell migration [261, 262]. hgf null mutants fail to form normal muscles, but due to embryonic lethality, the skeletal phenotype was not examined. FGF-2 and PDGF increase the synthesis of HGF by osteoblasts, whereas glucocorticoids are inhibitory [258, 262]. Since HGF plays a role in mitogenesis and tissue repair, inhibition of its synthesis by glucocorticoids may be relevant to the inhibitory effect of these steroids on wound healing
Marcus-Ch19.indd 538
and tissue repair. Recently, HGF and c-met were found to be expressed at the site of fractured bone and HGF to induce BMP receptors [263]. Through this mechanism HGF may contribute to fracture healing and repair.
ACKNOWLEDGMENTS The work described in this chapter was supported by grants from the National Institutes of Health AR 21707, DK 42424, and DK 45227. The author thanks Ms. Marcia Dupont and Ms. Mary Yurczak for valuable secretarial assistance.
REFERENCES 1. L. Fredriksson, H. Li, and U. Eriksson. The PDGF family: Four gene products form five dimeric isoforms. Cytokine Growth Factor Rev, 15, 197–204 (2004). 2. N. Ferrara and T. Davis-Smyth. The biology of vascular endothelial growth factor. Endocr Rev, 18, 4–25 (1997). 3. L. J. Reigstad, J. E. Varhaug, and J. R. Lillehaug. Structural and functional specificities of PDGF-C and PDGF-D, the novel members of the platelet-derived growth factors family. FEBS J, 272, 5723–5741 (2005). 4. D. G. Gilbertson, M. E. Duff, J. W. West, J. D. Kelly, P. O. Sheppard, P. D. Hofstrand, Z. Gao, K. Shoemaker, T. R. Bukowski, M. Moore, A. L. Feldhaus, J. M. Humes, T. E. Palmer, and C. E. Hart. Platelet-derived growth factor C (PDGF-C), a novel growth factor that binds to PDGF alpha and beta receptor. J Biol Chem, 276, 27406–27414 (2001). 5. E. Bergsten, M. Uutela, X. Li, K. Pietras, A. Ostman, C. H. Heldin, K. Alitalo, and U. Eriksson. PDGF-D is a specific, protease-activated ligand for the PDGF beta-receptor. Nat Cell Biol, 3, 512–516 (2001). 6. W. J. LaRochelle, M. Jeffers, W. F. McDonald, R. A. Chillakuru, N. A. Giese, N. A. Lokker, C. Sullivan, F. L. Boldog, M. Yang, C. Vernet, C. E. Burgess, E. Fernandes, L. L. Deegler, B. Rittman, J. Shimkets, R. A. Shimkets, J. M. Rothberg, and H. S. Lichenstein. PDGF-D, a new proteaseactivated growth factor. Nat Cell Biol, 3, 517–521 (2001). 7. C. Betsholtz, A. Johnsson, C. H. Heldin, B. Westermark, P. Lind, M. S. Urdea, R. Eddy, T. B. Shows, K. Philpott, and A. L. Mellor. cDNA sequence and chromosomal localization of human platelet-derived growth factor A-chain and its expression in tumour cell lines. Nature, 320, 695–699 (1986). 8. H. Ding, X. Wu, I. Kim, P. P. Tam, G. Y. Koh, and A. Nagy. The mouse Pdgfc gene: Dynamic expression in embryonic tissues during organogenesis. Mech Dev, 96, 209–213 (2000). 9. S. Rydziel, S. Shaikh, and E. Canalis. Platelet-derived growth factor-AA and -BB (PDGF-AA and -BB) enhance the synthesis of PDGF-AA in bone cell cultures. Endocrinology, 134, 2541–2546 (1994). 10. A. Ponten, E. B. Folestad, K. Pietras, and U. Eriksson. Platelet-derived growth factor D induces cardiac fibrosis and proliferation of vascular smooth muscle cells in heart-specific transgenic mice. Circ Res, 97, 1036–1045 (2005). 11. B. Westermark and C. H. Heldin. Platelet-derived growth factor. Structure, function and implications in normal and malignant cell growth. Acta Oncol, 32, 101–105 (1993).
8/22/2007 4:17:40 PM
539
Chapter 19 Skeletal Growth Factors
12. L. Claesson-Welsh, A. Eriksson, B. Westermark, and C. H. Heldin. cDNA cloning and expression of the human A-type platelet-derived growth factor (PDGF) receptor establishes structural similarity to the B-type PDGF receptor. Proc Natl Acad Sci USA, 86, 4917–4921 (1989). 13. R. G. Gronwald, F. J. Grant, B. A. Haldeman, C. E. Hart, P. J. O’Hara, F. S. Hagen, R. Ross, D. F. Bowen-Pope, and M. J. Murray. Cloning and expression of a cDNA coding for the human platelet-derived growth factor receptor: Evidence for more than one receptor class. Proc Natl Acad Sci USA, 85, 3435–3439 (1988). 14. R. A. Seifert, C. E. Hart, P. E. Phillips, J. W. Forstrom, R. Ross, M. J. Murray, and D. F. Bowen-Pope. Two different subunits associate to create isoform-specific platelet-derived growth factor receptors. J Biol Chem, 264, 8771–8778 (1989). 15. Y. Yarden, J. A. Escobedo, W. J. Kuang, T. L. Yang-Feng, T. O. Daniel, P. M. Tremble, E. Y. Chen, M. E. Ando, R. N. Harkins, and U. Francke. Structure of the receptor for plateletderived growth factor helps define a family of closely related growth factor receptors. Nature, 323, 226–232 (1986). 16. M. Centrella, T. L. McCarthy, W. F. Kusmik, and E. Canalis. Isoform-specific regulation of platelet-derived growth factor activity and binding in osteoblast-enriched cultures from fetal rat bone. J Clin Invest, 89, 1076–1084 (1992). 17. J. M. Hock and E. Canalis. Platelet-derived growth factor enhances bone cell replication, but not differentiated function of osteoblasts. Endocrinology, 134, 1423–1428 (1994). 18. H. Tanaka and C. T. Liang. Effect of platelet-derived growth factor on DNA synthesis and gene expression in bone marrow stromal cells derived from adult and old rats. J Cell Physiol, 164, 367–375 (1995). 19. E. Canalis, T. L. McCarthy, and M. Centrella. Effects of platelet-derived growth factor on bone formation in vitro. J Cell Physiol, 140, 530–537 (1989). 20. E. Canalis, J. Pash, B. Gabbitas, S. Rydziel, and S. Varghese. Growth factors regulate the synthesis of insulin-like growth factor-I in bone cell cultures. Endocrinology, 133, 33–38 (1993). 21. B. Gabbitas, J. Pash, and E. Canalis. Regulation of insulinlike growth factor-II synthesis in bone cell cultures by skeletal growth factors. Endocrinology, 135, 284–289 (1994). 22. G. D. Roodman. Interleukin-6: An osteotropic factor? J Bone Miner Res, 7, 475–478 (1992). 23. L. S. Holliday, H. G. Welgus, C. J. Fliszar, G. M. Veith, J. J. Jeffrey, and S. L. Gluck. Initiation of osteoclast bone resorption by interstitial collagenase. J Biol Chem, 272, 22053–22058 (1997). 24. S. Varghese, A. M. Delany, L. Liang, B. Gabbitas, J. J. Jeffrey, and E. Canalis. Transcriptional and posttranscriptional regulation of interstitial collagenase by platelet-derived growth factor BB in bone cell cultures. Endocrinology, 137, 431–437 (1996). 25. W. Zhao, M. H. Byrne, B. F. Boyce, and S. M. Krane. Bone resorption induced by parathyroid hormone is strikingly diminished in collagenase-resistant mutant mice. J Clin Invest, 103, 517–524 (1999). 26. L. Claesson-Welsh. Platelet-derived growth factor receptor signals. J Biol Chem, 269, 32023–32026 (1994). 27. C. H. Heldin, A. Ernlund, C. Rorsman, and L. Ronnstrand. Dimerization of B-type platelet-derived growth factor receptors occurs after ligand binding and is closely associated with receptor kinase activation. J Biol Chem, 264, 8905–8912 (1989). 28. R. S. Gilardetti, M. S. Chaibi, J. Stroumza, S. R. Williams, H. N. Antoniades, D. C. Carnes, and D. T. Graves. High-affinity binding of PDGF-AA and PDGF-BB to normal human osteo-
Marcus-Ch19.indd 539
29.
30.
31.
32.
33.
34.
35. 36.
37. 38.
39. 40.
41.
42.
blastic cells and modulation by interleukin-1. Am J Physiol, 261, C980–C985 (1991). T. Tsukamoto, T. Matsui, H. Nakata, M. Ito, T. Natazuka, M. Fukase, and T. Fujita. Interleukin-1 enhances the response of osteoblasts to platelet-derived growth factor through the alpha receptor-specific up-regulation. J Biol Chem, 266, 10143–10147 (1991). K. N. Kose, J. F. Xie, D. L. Carnes, and D. T. Graves. Proinflammatory cytokines downregulate platelet derived growth factor-alpha receptor gene expression in human osteoblastic cells. J Cell Physiol, 166, 188–197 (1996). X. Li, M. Tjwa, L. Moons, P. Fons, A. Noel, A. Ny, J. M. Zhou, J. Lennartsson, H. Li, A. Luttun, A. Ponten, L. Devy, A. Bouche, H. Oh, A. Manderveld, S. Blacher, D. Communi, P. Savi, F. Bono, M. Dewerchin, J. M. Foidart, M. Autiero, J. M. Herbert, D. Collen, C. H. Heldin, U. Eriksson, and P. Carmeliet. Revascularization of ischemic tissues by PDGFCC via effects on endothelial cells and their progenitors. J Clin Invest, 115, 118–127 (2005). B. H. Mitlak, R. D. Finkelman, E. L. Hill, J. Li, B. Martin, T. Smith, M. D’Andrea, H. N. Antoniades, and S. E. Lynch. The effect of systemically administered PDGF-BB on the rodent skeleton. J Bone Miner Res, 11, 238–247 (1996). L. J. Marden, R. S. Fan, G. F. Pierce, A. H. Reddi, and J. O. Hollinger. Platelet-derived growth factor inhibits bone regeneration induced by osteogenin, a bone morphogenetic protein, in rat craniotomy defects. J Clin Invest, 92, 2897–2905 (1993). T. F. Deuel, R. S. Kawahara, T. A. Mustoe, and A. F. Pierce. Growth factors and wound healing: Platelet-derived growth factor as a model cytokine. Annu Rev Med, 42, 567–584 (1991). C. Betsholtz. Insight into the physiological functions of PDGF through genetic studies in mice. Cytokine Growth Factor Rev, 15, 215–228 (2004). P. Leveen, M. Pekny, S. Gebre-Medhin, B. Swolin, E. Larsson, and C. Betsholtz. Mice deficient for PDGF B show renal, cardiovascular, and hematological abnormalities. Genes Dev, 8, 1875–1887 (1994). P. Soriano. Abnormal kidney development and hematological disorders in PDGF beta-receptor mutant mice. Genes Dev, 8, 1888–1896 (1994). M. Fruttiger, L. Karlsson, A. C. Hall, A. Abramsson, A. R. Calver, H. Bostrom, K. Willetts, C. H. Bertold, J. K. Heath, C. Betsholtz, and W. D. Richardson. Defective oligodendrocyte development and severe hypomyelination in PDGF-A knockout mice. Development, 126, 457–467 (1999). M. D. Tallquist and P. Soriano. Cell autonomous requirement for PDGFRalpha in populations of cranial and cardiac neural crest cells. Development, 130, 507–518 (2003). H. Ding, X. Wu, H. Bostrom, I. Kim, N. Wong, B. Tsoi, M. O’Rourke, G. Y. Koh, P. Soriano, C. Betsholtz, T. C. Hart, M. L. Marazita, L. L. Field, P. P. Tam, and A. Nagy. A specific requirement for PDGF-C in palate formation and PDGFRalpha signaling. Nat Genet, 36, 1111–1116 (2004). J. S. Campbell, S. D. Hughes, D. G. Gilbertson, T. E. Palmer, M. S. Holdren, A. C. Haran, M. M. Odell, R. L. Bauer, H. P. Ren, H. S. Haugen, M. M. Yeh, and N. Fausto. Platelet-derived growth factor C induces liver fibrosis, steatosis, and hepatocellular carcinoma. Proc Natl Acad Sci USA, 102, 3389–3394 (2005). S. Rydziel, C. Ladd, T. L. McCarthy, M. Centrella, and E. Canalis. Determination and expression of platelet-derived growth factor-AA in bone cell cultures. Endocrinology, 130, 1916–1922 (1992).
8/22/2007 4:17:40 PM
540 43. C. J. Robinson and S. E. Stringer. The splice variants of vascular endothelial growth factor (VEGF) and their receptors. J Cell Sci, 114, 853–865 (2001). 44. N. Ferrara, K. Carver-Moore, H. Chen, M. Dowd, L. Lu, K. S. O’Shea, L. Powell-Braxton, K. J. Hillan, and M. W. Moore. Heterozygous embryonic lethality induced by targeted inactivation of the VEGF gene. Nature, 380, 439–442 (1996). 45. E. Zelzer and B. R. Olsen. Multiple roles of vascular endothelial growth factor (VEGF) in skeletal development, growth, and repair. Curr Top Dev Biol, 65, 169–187 (2005). 46. H. P. Gerber, T. H. Vu, A. M. Ryan, J. Kowalski, Z. Werb, and N. Ferrara. VEGF couples hypertrophic cartilage remodeling, ossification and angiogenesis during endochondral bone formation. Nat Med, 5, 623–628 (1999). 47. E. Zelzer, R. Mamluk, N. Ferrara, R. S. Johnson, E. Schipani, and B. R. Olsen. VEGFA is necessary for chondrocyte survival during bone development. Development, 131, 2161–2171 (2004). 48. S. Niida, T. Kondo, S. Hiratsuka, S. Hayashi, N. Amizuka, T. Noda, K. Ikeda, and M. Shibuya. VEGF receptor 1 signaling is essential for osteoclast development and bone marrow formation in colony-stimulating factor 1–deficient mice. Proc Natl Acad Sci USA, 102, 14016–14021 (2005). 49. J. Street, M. Bao, L. deGuzman, S. Bunting, F. V. Peale, Jr., N. Ferrara, H. Steinmetz, J. Hoeffel, J. L. Cleland, A. Daugherty, N. van Bruggen, H. P. Redmond, R. A. Carano, and E. H. Filvaroff. Vascular endothelial growth factor stimulates bone repair by promoting angiogenesis and bone turnover. Proc Natl Acad Sci USA, 99, 9656–9661 (2002). 50. E. Zelzer, W. McLean, Y. S. Ng, N. Fukai, A. M. Reginato, S. Lovejoy, P. A. D’Amore, and B. R. Olsen. Skeletal defects in VEGF(120/120) mice reveal multiple roles for VEGF in skeletogenesis. Development, 129, 1893–1904 (2002). 51. M. O. Hiltunen, M. Ruuskanen, J. Huuskonen, A. J. Mahonen, M. Ahonen, J. Rutanen, V. M. Kosma, A. Mahonen, H. Kroger, and S. Yla-Herttuala. Adenovirus-mediated VEGFA gene transfer induces bone formation in vivo. FASEB J, 17, 1147–1149 (2003). 52. N. Akeno, J. Robins, M. Zhang, M. F. Czyzyk-Krzeska, and T. L. Clemens. Induction of vascular endothelial growth factor by IGF-I in osteoblast-like cells is mediated by the PI3K signaling pathway through the hypoxia-inducible factor-2alpha. Endocrinology, 143, 420–425 (2002). 53. Y. Kanno, A. Ishisaki, M. Yoshida, H. Tokuda, O. Numata, and O. Kozawa. SAPK/JNK plays a role in transforming growth factor-beta-induced VEGF synthesis in osteoblasts. Horm Metab Res, 37, 140–145 (2005). 54. H. Tokuda, K. Hirade, X. Wang, Y. Oiso, and O. Kozawa. Involvement of SAPK/JNK in basic fibroblast growth factor-induced vascular endothelial growth factor release in osteoblasts. J Endocrinol, 177, 101–107 (2003). 55. H. Tokuda, D. Hatakeyama, T. Shibata, S. Akamatsu, Y. Oiso, and O. Kozawa. p38 MAP kinase regulates BMP-4–stimulated VEGF synthesis via p70 S6 kinase in osteoblasts. Am J Physiol Endocrinol Metab, 284, E1202–E1209 (2003). 56. M. M. Deckers, R. L. van Bezooijen, H. G. van der, J. Hoogendam, B. C. van Der, S. E. Papapoulos, and C. W. Lowik. Bone morphogenetic proteins stimulate angiogenesis through osteoblast-derived vascular endothelial growth factor A. Endocrinology 143, 1545–1553 (2002). 57. N. Itoh and D. M. Ornitz. Evolution of the Fgf and Fgfr gene families. Trends Genet, 20, 563–569 (2004). 58. A. Baird and D. M. Ornitz. Fibroblast growth factors and their receptors. In Skeletal Growth Factors (E. Canalis, ed.), pp. 167–178. Lippincott Williams & Wilkins, Philadelphia (2000).
Marcus-Ch19.indd 540
Ernesto Canalis
59. F. Esch, A. Baird, N. Ling, N. Ueno, F. Hill, L. Denoroy, R. Klepper, D. Gospodarowicz, P. Bohlen, and R. Guillemin. Primary structure of bovine pituitary basic fibroblast growth factor (FGF) and comparison with the amino-terminal sequence of bovine brain acidic FGF. Proc Natl Acad Sci USA, 82, 6507–6511 (1985). 60. R. K. Globus, J. Plouet, and D. Gospodarowicz. Cultured bovine bone cells synthesize basic fibroblast growth factor and store it in their extracellular matrix. Endocrinology, 124, 1539–1547 (1989). 61. M. M. Hurley, C. Abreu, G. Gronowicz, H. Kawaguchi, and J. Lorenzo. Expression and regulation of basic fibroblast growth factor mRNA levels in mouse osteoblastic MC3T3–E1 cells. J Biol Chem, 269, 9392–9396 (1994). 62. E. Canalis, J. Lorenzo, W. H. Burgess, and T. Maciag. Effects of endothelial cell growth factor on bone remodelling in vitro. J Clin Invest, 79, 52–58 (1987). 63. E. Canalis, M. Centrella, and T. McCarthy. Effects of basic fibroblast growth factor on bone formation in vitro. J Clin Invest, 81, 1572–1577 (1988). 64. R. Montesano, J. D. Vassalli, A. Baird, R. Guillemin, and L. Orci. Basic fibroblast growth factor induces angiogenesis in vitro. Proc Natl Acad Sci USA, 83, 7297–7301 (1986). 65. S. B. Rodan, G. Wesolowski, K. Yoon, and G. A. Rodan. Opposing effects of fibroblast growth factor and pertussis toxin on alkaline phosphatase, osteopontin, osteocalcin, and type I collagen mRNA levels in ROS 17/2.8 cells. J Biol Chem, 264, 19934–19941 (1989). 66. T. L. McCarthy, M. Centrella, and E. Canalis. Effects of fibroblast growth factors on deoxyribonucleic acid and collagen synthesis in rat parietal bone cells. Endocrinology, 125, 2118–2126 (1989). 67. T. Sobue, T. Naganawa, L. Xiao, Y. Okada, Y. Tanaka, M. Ito, N. Okimoto, T. Nakamura, J. D. Coffin, and M. M. Hurley. Over-expression of fibroblast growth factor-2 causes defective bone mineralization and osteopenia in transgenic mice. J Cell Biochem, 95, 83–94 (2005). 68. A. Montero, Y. Okada, M. Tomita, M. Ito, H. Tsurukami, T. Nakamura, T. Doetschman, J. D. Coffin, and M. M. Hurley. Disruption of the fibroblast growth factor-2 gene results in decreased bone mass and bone formation. J Clin Invest, 105, 1085–1093 (2000). 69. M. L. Johnson, K. Harnish, R. Nusse, and W. Van Hul. LRP5 and Wnt signaling: A union made for bone. J Bone Miner Res, 19, 1749–1757 (2004). 70. A. Mansukhani, D. Ambrosetti, G. Holmes, L. Cornivelli, and C. Basilico. Sox2 induction by FGF and FGFR2 activating mutations inhibits Wnt signaling and osteoblast differentiation. J Cell Biol, 168, 1065–1076 (2005). 71. Y. Okada, A. Montero, X. Zhang, T. Sobue, J. Lorenzo, T. Doetschman, J. D. Coffin, and M. M. Hurley. Impaired osteoclast formation in bone marrow cultures of Fgf2 null mice in response to parathyroid hormone. J Biol Chem, 278, 21258–21266 (2003). 72. S. Varghese, S. Rydziel, and E. Canalis. Basic fibroblast growth factor stimulates collagenase-3 promoter activity in osteoblasts through an activator protein-1–binding site. Endocrinology, 141, 2185–2191 (2000). 73. M. Noda and R. Vogel. Fibroblast growth factor enhances type beta 1 transforming growth factor gene expression in osteoblast-like cells. J Cell Biol, 109, 2529–2535 (1989). 74. D. M. Ornitz and P. Leder. Ligand specificity and heparin dependence of fibroblast growth factor receptors 1 and 3. J Biol Chem, 267, 16305–16311 (1992). 75. J. K. Wang, G. Gao, and M. Goldfarb. Fibroblast growth factor receptors have different signaling and mitogenic potentials. Mol Cell Biol, 14, 181–188 (1994).
8/22/2007 4:17:40 PM
Chapter 19 Skeletal Growth Factors
76. S. Werner, D. S. Duan, C. de Vries, K. G. Peters, D. E. Johnson, and L. T. Williams. Differential splicing in the extracellular region of fibroblast growth factor receptor 1 generates receptor variants with different ligand-binding specificities. Mol Cell Biol, 12, 82–88 (1992). 77. R. Shiang, L. M. Thompson, Y. Z. Zhu, D. M. Church, T. J. Fielder, M. Bocian, S. T. Winokur, and J. J. Wasmuth. Mutations in the transmembrane domain of FGFR3 cause the most common genetic form of dwarfism, achondroplasia. Cell, 78, 335–342 (1994). 78. M. Sahni, D. C. Ambrosetti, A. Mansukhani, R. Gertner, D. Levy, and C. Basilico. FGF signaling inhibits chondrocyte proliferation and regulates bone development through the STAT-1 pathway. Genes Dev, 13, 1361–1366 (1999). 79. L. Xiao, T. Naganawa, E. Obugunde, G. Gronowicz, D. M. Ornitz, J. D. Coffin, and M. M. Hurley. Stat1 controls postnatal bone formation by regulating fibroblast growth factor signaling in osteoblasts. J Biol Chem, 279, 27743–27752 (2004). 80. H. Kawaguchi, T. Kurokawa, K. Hanada, Y. Hiyama, M. Tamura, E. Ogata, and T. Matsumoto. Stimulation of fracture repair by recombinant human basic fibroblast growth factor in normal and streptozotocin-diabetic rats. Endocrinology, 135, 774–781 (1994). 81. H. Kawaguchi, K. Nakamura, Y. Tabata, Y. Ikada, I. Aoyama, J. Anzai, T. Nakamura, Y. Hiyama, and M. Tamura. Acceleration of fracture healing in nonhuman primates by fibroblast growth factor-2. J Clin Endocrinol Metab, 86, 875–880 (2001). 82. K. Yu, J. Xu, Z. Liu, D. Sosic, J. Shao, E. N. Olson, D. A. Towler, and D. M. Ornitz. Conditional inactivation of FGF receptor 2 reveals an essential role for FGF signaling in the regulation of osteoblast function and bone growth. Development, 130, 3063–3074 (2003). 83. A. Jackson, S. Friedman, X. Zhan, K. A. Engleka, R. Forough, and T. Maciag. Heat shock induces the release of fibroblast growth factor 1 from NIH 3T3 cells. Proc Natl Acad Sci USA, 89, 10691–10695 (1992). 84. F. Shibata, A. Baird, and R. Z. Florkiewicz. Functional characterization of the human basic fibroblast growth factor gene promoter. Growth Factors, 4, 277–287 (1991). 85. M. M. Hurley, S. Tetradis, Y. F. Huang, J. Hock, B. E. Kream, L. G. Raisz, and M. G. Sabbieti. Parathyroid hormone regulates the expression of fibroblast growth factor-2 mRNA and fibroblast growth factor receptor mRNA in osteoblastic cells. J Bone Miner Res, 14, 776–783 (1999). 86. M. Mali, K. Elenius, H. M. Miettinen, and M. Jalkanen. Inhibition of basic fibroblast growth factor-induced growth promotion by overexpression of syndecan-1. J Biol Chem, 268, 24215–24222 (1993). 87. L. Attisano and J. L. Wrana. Signal transduction by the TGFbeta superfamily. Science, 296, 1646–1647 (2002). 88. J. A. Barnard, R. M. Lyons, and H. L. Moses. The cell biology of transforming growth factor beta. Biochim Biophys Acta, 1032, 79–87 (1990). 89. M. Centrella, T. L. McCarthy, and E. Canalis. Transforming growth factor-beta and remodeling of bone. J Bone Joint Surg Am, 73, 1418–1428 (1991). 90. M. Centrella, J. Massague, and E. Canalis. Human plateletderived transforming growth factor-beta stimulates parameters of bone growth in fetal rat calvariae. Endocrinology, 119, 2306–2312 (1986). 91. J. M. Hock, E. Canalis, and M. Centrella. Transforming growth factor-beta stimulates bone matrix apposition and bone cell replication in cultured fetal rat calvariae. Endocrinology, 126, 421–426 (1990).
Marcus-Ch19.indd 541
541 92. C. Marcelli, A. J. Yates, and G. R. Mundy. In vivo effects of human recombinant transforming growth factor beta on bone turnover in normal mice. J Bone Miner Res, 5, 1087–1096 (1990). 93. D. Rosen, S. C. Miller, E. DeLeon, A. Y. Thompson, H. Bentz, M. Mathews, and S. Adams. Systemic administration of recombinant transforming growth factor beta 2 (rTGF-beta 2) stimulates parameters of cancellous bone formation in juvenile and adult rats. Bone, 15, 355–359 (1994). 94. M. Centrella, T. L. McCarthy, and E. Canalis. Transforming growth factor beta is a bifunctional regulator of replication and collagen synthesis in osteoblast-enriched cell cultures from fetal rat bone. J Biol Chem, 262, 2869–2874 (1987). 95. M. Noda and G. A. Rodan. Type beta transforming growth factor (TGF beta) regulation of alkaline phosphatase expression and other phenotype-related mRNAs in osteoblastic rat osteosarcoma cells. J Cell Physiol, 133, 426–437 (1987). 96. D. M. Rosen, S. A. Stempien, A. Y. Thompson, and S. M. Seyedin. Transforming growth factor-beta modulates the expression of osteoblast and chondroblast phenotypes in vitro. J Cell Physiol, 134, 337–346 (1988). 97. R. A. Ignotz and J. Massague. Transforming growth factorbeta stimulates the expression of fibronectin and collagen and their incorporation into the extracellular matrix. J Biol Chem, 261, 4337–4345 (1986). 98. L. F. Bonewald, M. B. Kester, Z. Schwartz, L. D. Swain, A. Khare, T. L. Johnson, R. J. Leach, and B. D. Boyan. Effects of combining transforming growth factor beta and 1, 25–dihydroxyvitamin D3 on differentiation of a human osteosarcoma (MG-63). J Biol Chem, 267, 8943–8949 (1992). 99. S. Spinella-Jaegle, S. Roman-Roman, C. Faucheu, F. W. Dunn, S. Kawai, S. Gallea, V. Stiot, A. M. Blanchet, B. Courtois, R. Baron, and G. Rawadi. Opposite effects of bone morphogenetic protein-2 and transforming growth factor-beta1 on osteoblast differentiation. Bone, 29, 323–330 (2001). 100. C. Chenu, J. Pfeilschifter, G. R. Mundy, and G. D. Roodman. Transforming growth factor beta inhibits formation of osteoclast-like cells in long-term human marrow cultures. Proc Natl Acad Sci USA, 85, 5683–5687 (1988). 101. D. M. Shinar and G. A. Rodan. Biphasic effects of transforming growth factor-beta on the production of osteoclast-like cells in mouse bone marrow cultures: The role of prostaglandins in the generation of these cells. Endocrinology, 126, 3153–3158 (1990). 102. J. Pfeilschifter, S. M. Seyedin, and G. R. Mundy. Transforming growth factor beta inhibits bone resorption in fetal rat long bone cultures. J Clin Invest, 82, 680–685 (1988). 103. M. Centrella, T. L. McCarthy, and E. Canalis. Parathyroid hormone modulates transforming growth factor beta activity and binding in osteoblast-enriched cell cultures from fetal rat parietal bone. Proc Natl Acad Sci USA, 85, 5889–5893 (1988). 104. M. Centrella, T. L. McCarthy, and E. Canalis. Glucocorticoid regulation of transforming growth factor beta 1 activity and binding in osteoblast-enriched cultures from fetal rat bone. Mol Cell Biol, 11, 4490–4496 (1991). 105. F. Lopez-Casillas, S. Cheifetz, J. Doody, J. L. Andres, W. S. Lane, and J. Massague. Structure and expression of the membrane proteoglycan betaglycan, a component of the TGF-beta receptor system. Cell, 67, 785–795 (1991). 106. M. E. Joyce, A. B. Roberts, M. B. Sporn, and M. E. Bolander. Transforming growth factor-beta and the initiation of chondrogenesis and osteogenesis in the rat femur. J Cell Biol, 110, 2195–2207 (1990). 107. A. Erlebacher and R. Derynck. Increased expression of TGFbeta 2 in osteoblasts results in an osteoporosis-like phenotype. J Cell Biol, 132, 195–210 (1996).
8/22/2007 4:17:40 PM
542 108. R. Serra, M. Johnson, E. H. Filvaroff, J. LaBorde, D. M. Sheehan, R. Derynck, and H. L. Moses. Expression of a truncated, kinase-defective TGF-beta type II receptor in mouse skeletal tissue promotes terminal chondrocyte differentiation and osteoarthritis. J Cell Biol, 139, 541–552 (1997). 109. M. M. Shull, I. Ormsby, A. B. Kier, S. Pawlowski, R. J. Diebold, M. Yin, R. Allen, C. Sidman, G. Proetzel, and D. Calvin. Targeted disruption of the mouse transforming growth factor-beta 1 gene results in multifocal inflammatory disease. Nature, 359, 693–699 (1992). 110. L. S. Beck, T. L. Chen, P. Mikalauski, and A. J. Ammann. Recombinant human transforming growth factor-beta 1 (rhTGF-beta 1) enhances healing and strength of granulation skin wounds. Growth Factors, 3, 267–275 (1990). 111. W. A. Border and E. Ruoslahti. Transforming growth factorbeta in disease: The dark side of tissue repair. J Clin Invest, 90, 1–7 (1992). 112. A. Migdalska, G. Molineux, H. Demuynck, G. S. Evans, F. Ruscetti, and T. M. Dexter. Growth inhibitory effects of transforming growth factor-beta 1 in vivo. Growth Factors, 4, 239–245 (1991). 113. A. B. Roberts, M. B. Sporn, R. K. Assoian, J. M. Smith, N. S. Roche, L. M. Wakefield, U. I. Heine, L. A. Liotta, V. Falanga, and J. H. Kehrl. Transforming growth factor type beta: Rapid induction of fibrosis and angiogenesis in vivo and stimulation of collagen formation in vitro. Proc Natl Acad Sci USA, 83, 4167–4171 (1986). 114. R. Derynck, J. A. Jarrett, E. Y. Chen, and D. V. Goeddel. The murine transforming growth factor-beta precursor. J Biol Chem, 261, 4377–4379 (1986). 115. K. Miyazono, U. Hellman, C. Wernstedt, and C. H. Heldin. Latent high molecular weight complex of transforming growth factor beta 1. Purification from human platelets and structural characterization. J Biol Chem, 263, 6407–6415 (1988). 116. K. Miyazono, A. Olofsson, P. Colosetti, and C. H. Heldin. A role of the latent TGF-beta 1–binding protein in the assembly and secretion of TGF-beta 1. EMBO J, 10, 1091–1101 (1991). 117. L. M. Wakefield, D. M. Smith, K. C. Flanders, and M. B. Sporn. Latent transforming growth factor-beta from human platelets. A high molecular weight complex containing precursor sequences. J Biol Chem, 263, 7646–7654 (1988). 118. M. J. Oursler, C. Cortese, P. Keeting, M. A. Anderson, S. K. Bonde, B. L. Riggs, and T. C. Spelsberg. Modulation of transforming growth factor-beta production in normal human osteoblast-like cells by 17 beta-estradiol and parathyroid hormone. Endocrinology, 129, 3313–3320 (1991). 119. M. J. Oursler, B. L. Riggs, and T. C. Spelsberg. Glucocorticoidinduced activation of latent transforming growth factor-beta by normal human osteoblast-like cells. Endocrinology, 133, 2187–2196 (1993). 120. R. D. Finkelman, N. H. Bell, D. D. Strong, L. M. Demers, and D. J. Baylink. Ovariectomy selectively reduces the concentration of transforming growth factor beta in rat bone: Implications for estrogen deficiency-associated bone loss. Proc Natl Acad Sci USA, 89, 12190–12193 (1992). 121. R. Lafyatis, R. Lechleider, S. J. Kim, S. Jakowlew, A. B. Roberts, and M. B. Sporn. Structural and functional characterization of the transforming growth factor beta 3 promoter. A cAMP-responsive element regulates basal and induced transcription. J Biol Chem, 265, 19128–19136 (1990). 122. T. Noma, A. B. Glick, A. G. Geiser, M. A. O’Reilly, J. Miller, A. B. Roberts, and M. B. Sporn. Molecular cloning and structure of the human transforming growth factor-beta 2 gene promoter. Growth Factors, 4, 247–255 (1991).
Marcus-Ch19.indd 542
Ernesto Canalis
123. M. Kawabata and K. Miyazono. Bone morphogenetic proteins. In Skeletal Growth Factors (E. Canalis, ed.), pp. 269– 290. Lippincott Williams & Wilkins, Philadelphia (2000). 124. E. A. Wang, V. Rosen, J. S. D’Alessandro, M. Bauduy, P. Cordes, T. Harada, D. I. Israel, R. M. Hewick, K. M. Kerns, and P. LaPan. Recombinant human bone morphogenetic protein induces bone formation. Proc Natl Acad Sci USA, 87, 2220–2224 (1990). 125. J. M. Wozney, V. Rosen, A. J. Celeste, L. M. Mitsock, M. J. Whitters, R. W. Kriz, R. M. Hewick, and E. A. Wang. Novel regulators of bone formation: Molecular clones and activities. Science, 242, 1528–1534 (1988). 126. M. I. Uzel, I. C. Scott, H. Babakhanlou-Chase, A. H. Palamakumbura, W. N. Pappano, H. H. Hong, D. S. Greenspan, and P. C. Trackman. Multiple bone morphogenetic protein 1–related mammalian metalloproteinases process pro-lysyl oxidase at the correct physiological site and control lysyl oxidase activation in mouse embryo fibroblast cultures. J Biol Chem, 276, 22537–22543 (2001). 127. M. E. Bahamonde and K. M. Lyons. BMP3: To be or not to be a BMP. J Bone Joint Surg Am, 83–A (Suppl 1), S56–S62 (2001). 128. A. Daluiski, T. Engstrand, M. E. Bahamonde, L. W. Gamer, E. Agius, S. L. Stevenson, K. Cox, V. Rosen, and K. M. Lyons. Bone morphogenetic protein-3 is a negative regulator of bone density. Nat Genet, 27, 84–88 (2001). 129. F. P. Luyten, N. S. Cunningham, S. Ma, N. Muthukumaran, R. G. Hammonds, W. B. Nevins, W. I. Woods, and A. H. Reddi. Purification and partial amino acid sequence of osteogenin, a protein initiating bone differentiation. J Biol Chem, 264, 13377–13380 (1989). 130. D. Chen, M. A. Harris, G. Rossini, C. R. Dunstan, S. L. Dallas, J. Q. Feng, G. R. Mundy, and S. E. Harris. Bone morphogenetic protein 2 (BMP-2) enhances BMP-3, BMP-4, and bone cell differentiation marker gene expression during the induction of mineralized bone matrix formation in cultures of fetal rat calvarial osteoblasts. Calcif Tissue Int, 60, 283–290 (1997). 131. N. Ghosh-Choudhury, M. A. Harris, J. Q. Feng, G. R. Mundy, and S. E. Harris. Expression of the BMP 2 gene during bone cell differentiation. Crit Rev Eukaryot Gene Expr, 4, 345–355 (1994). 132. R. C. Pereira, S. Rydziel, and E. Canalis. Bone morphogenetic protein-4 regulates its own expression in cultured osteoblasts. J Cell Physiol, 182, 239–246 (2000). 133. D. J. Rickard, L. C. Hofbauer, S. K. Bonde, F. Gori, T. C. Spelsberg, and B. L. Riggs. Bone morphogenetic protein-6 production in human osteoblastic cell lines. Selective regulation by estrogen. J Clin Invest, 101, 413–422 (1998). 134. M. Suzawa, Y. Takeuchi, S. Fukumoto, S. Kato, N. Ueno, K. Miyazono, T. Matsumoto, and T. Fujita. Extracellular matrix-associated bone morphogenetic proteins are essential for differentiation of murine osteoblastic cells in vitro. Endocrinology, 140, 2125–2133 (1999). 135. A. Yamaguchi, T. Ishizuya, N. Kintou, Y. Wada, T. Katagiri, J. M. Wozney, V. Rosen, and S. Yoshiki. Effects of BMP-2, BMP-4, and BMP-6 on osteoblastic differentiation of bone marrow-derived stromal cell lines, ST2 and MC3T3–G2/ PA6. Biochem Biophys Res Commun, 220, 366–371 (1996). 136. S. E. Gitelman, M. Kirk, J. Q. Ye, E. H. Filvaroff, A. J. Kahn, and R. Derynck. Vgr-1/BMP-6 induces osteoblastic differentiation of pluripotential mesenchymal cells. Cell Growth Differ, 6, 827–836 (1995). 137. E. Hay, J. Lemonnier, O. Fromigue, and P. J. Marie. Bone morphogenetic protein-2 promotes osteoblast apoptosis
8/22/2007 4:17:40 PM
Chapter 19 Skeletal Growth Factors
138. 139.
140. 141.
142.
143. 144. 145.
146.
147.
148.
149.
150.
151.
152.
Marcus-Ch19.indd 543
through a Smad-independent, protein kinase C-dependent signaling pathway. J Biol Chem, 276, 29028–29036 (2001). R. M. Pereira, A. M. Delany, and E. Canalis. Cortisol inhibits the differentiation and apoptosis of osteoblasts in culture. Bone, 28, 484–490 (2001). Y. Yokouchi, J. Sakiyama, T. Kameda, H. Iba, A. Suzuki, N. Ueno, and A. Kuroiwa. BMP-2/-4 mediate programmed cell death in chicken limb buds. Development, 122, 3725–3734 (1996). S. L. Teitelbaum. Bone resorption by osteoclasts. Science, 289, 1504–1508 (2000). Y. H. Gao, T. Shinki, T. Yuasa, H. Kataoka-Enomoto, T. Komori, T. Suda, and A. Yamaguchi. Potential role of cbfa1, an essential transcriptional factor for osteoblast differentiation, in osteoclastogenesis: Regulation of mRNA expression of osteoclast differentiation factor (ODF). Biochem Biophys Res Commun, 252, 697–702 (1998). H. Kaneko, T. Arakawa, H. Mano, T. Kaneda, A. Ogasawara, M. Nakagawa, Y. Toyama, Y. Yabe, M. Kumegawa, and Y. Hakeda. Direct stimulation of osteoclastic bone resorption by bone morphogenetic protein (BMP)-2 and expression of BMP receptors in mature osteoclasts. Bone, 27, 479–486 (2000). M. Wan, X. Shi, X. Feng, and X. Cao. Transcriptional mechanisms of bone morphogenetic protein-induced osteoprotegrin gene expression. J Biol Chem, 276, 10119–10125 (2001). S. Varghese and E. Canalis. Regulation of collagenase3 by bone morphogenetic protein-2 in bone cell cultures. Endocrinology, 138, 1035–1040 (1997). S. Varghese, S. Rydziel, and E. Canalis. Bone morphogenetic protein-2 suppresses collagenase-3 promoter activity in osteoblasts through a runt domain factor 2 binding site. J Cell Physiol, 202, 391–399 (2005). P. Leboy, G. Grasso-Knight, M. D’Angelo, S. W. Volk, J. V. Lian, H. Drissi, G. S. Stein, and S. L. Adams. Smad-Runx interactions during chondrocyte maturation. J Bone Joint Surg Am, 83–A(Suppl 1), S15–S22 (2001). C. D. Grimsrud, P. R. Romano, M. D’Souza, J. E. Puzas, E. M. Schwarz, P. R. Reynolds, R. N. Roiser, and R. J. O’Keefe. BMP signaling stimulates chondrocyte maturation and the expression of Indian hedgehog. J Orthop Res, 19, 18–25 (2001). F. De Luca, K. M. Barnes, J. A. Uyeda, S. De Levi, V. Abad, T. Palese, V. Mericq, and J. Baron. Regulation of growth plate chondrogenesis by bone morphogenetic protein-2. Endocrinology, 142, 430–436 (2001). D. Duprez, E. J. Bell, M. K. Richardson, C. W. Archer, L. Wolpert, P. M. Brickell, and P. H. Francis-West. Overexpression of BMP-2 and BMP-4 alters the size and shape of developing skeletal elements in the chick limb. Mech Dev, 57, 145–157 (1996). V. Krishnan, Y. Ma, J. Moseley, A. Geiser, S. Friant, and C. Frolik. Bone anabolic effects of sonic/Indian hedgehog are mediated by bmp-2/4–dependent pathways in the neonatal rat metatarsal model. Endocrinology, 142, 940–947 (2001). T. Katagiri, A. Yamaguchi, M. Komaki, E. Abe, N. Takahashi, T. Ikeda, V. Rosen, J. M. Wozney, A. Fujisawa-Sehara, and T. Suda. Bone morphogenetic protein-2 converts the differentiation pathway of C2C12 myoblasts into the osteoblast lineage. J Cell Biol, 127, 1755–1766 (1994). T. Katagiri, S. Akiyama, M. Namiki, M. Komaki, A. Yamaguchi, V. Rosen, J. M. Wozney, A. Fujisawa-Sehara, and T. Suda. Bone morphogenetic protein-2 inhibits terminal differentiation of myogenic cells by suppressing the transcriptional activity of MyoD and myogenin. Exp Cell Res, 230, 342–351 (1997).
543 153. E. Canalis and B. Gabbitas. Bone morphogenetic protein 2 increases insulin-like growth factor I and II transcripts and polypeptide levels in bone cell cultures. J Bone Miner Res, 9, 1999–2005 (1994). 154. H. Yamashita, P. ten Dijke, C. H. Heldin, and K. Miyazono. Bone morphogenetic protein receptors. Bone, 19, 569–574 (1996). 155. R. Derynck, Y. Zhang, and X. H. Feng. Smads: Transcriptional activators of TGF-beta responses. Cell, 95, 737–740 (1998). 156. A. Nohe, S. Hassel, M. Ehrlich, F. Neubauer, W. Sebald, Y. I. Henis, and P. Knaus. The mode of bone morphogenetic protein (BMP) receptor oligomerization determines different BMP-2 signaling pathways. J Biol Chem, 277, 5330–5338 (2002). 157. F. Liu, A. Hata, J. C. Baker, J. Doody, J. Carcamo, R. M. Harland, and J. Massague. A human Mad protein acting as a BMP-regulated transcriptional activator. Nature, 381, 620– 623 (1996). 158. K. Miyazono. Signal transduction by bone morphogenetic protein receptors: Functional roles of Smad proteins. Bone, 25, 91–93 (1999). 159. C. F. Lai and S. L. Cheng. Signal transductions induced by bone morphogenetic protein-2 and transforming growth factor-beta in normal human osteoblastic cells. J Biol Chem, 277, 15514–15522 (2002). 160. G. Winnier, M. Blessing, P. A. Labosky, and B. L. Hogan. Bone morphogenetic protein-4 is required for mesoderm formation and patterning in the mouse. Genes Dev, 9, 2105–2116 (1995). 161. H. Zhang and A. Bradley. Mice deficient for BMP2 are nonviable and have defects in amnion/chorion and cardiac development. Development, 122, 2977–2986 (1996). 162. H. Chang, D. Huylebroeck, K. Verschueren, Q. Guo, M. M. Matzuk, and A. Zwijsen. Smad5 knockout mice die at midgestation due to multiple embryonic and extraembryonic defects. Development, 126, 1631–1642 (1999). 163. X. Yang, L. H. Castilla, X. Xu, C. Li, J. Gotay, M. Weinstein, P. P. Liu, and C. X. Deng. Angiogenesis defects and mesenchymal apoptosis in mice lacking SMAD5. Development, 126, 1571–1580 (1999). 164. M. J. Solloway, A. T. Dudley, E. K. Bikoff, K. M. Lyons, B. L. Hogan, and E. J. Robertson. Mice lacking Bmp6 function. Dev Genet, 22, 321–339 (1998). 165. G. Q. Zhao, K. Deng, P. A. Labosky, L. Liaw, and B. L. Hogan. The gene encoding bone morphogenetic protein 8B is required for the initiation and maintenance of spermatogenesis in the mouse. Genes Dev, 10, 1657–1669 (1996). 166. G. Luo, C. Hofmann, A. L. Bronckers, M. Sohocki, A. Bradley, and G. Karsenty. BMP-7 is an inducer of nephrogenesis, and is also required for eye development and skeletal patterning. Genes Dev, 9, 2808–2820 (1995). 167. E. Canalis, A. N. Economides, and E. Gazzerro. Bone morphogenetic proteins, their antagonists, and the skeleton. Endocr Rev, 24, 218–235 (2003). 168. L. B. Zimmerman, J. M. Jesus-Escobar, and R. M. Harland. The Spemann organizer signal noggin binds and inactivates bone morphogenetic protein 4. Cell, 86, 599–606 (1996). 169. D. R. Hsu, A. N. Economides, X. Wang, P. M. Eimon, and R. M. Harland. The Xenopus dorsalizing factor Gremlin identifies a novel family of secreted proteins that antagonize BMP activities. Mol Cell, 1, 673–683 (1998). 170. J. J. Pearce, G. Penny, and J. Rossant. A mouse cerberus/Danrelated gene family. Dev Biol, 209, 98–110 (1999). 171. R. P. Ray and K. A. Wharton. Twisted perspective: New insights into extracellular modulation of BMP signaling during development. Cell, 104, 801–804 (2001).
8/22/2007 4:17:40 PM
544 172. E. Bell, I. Munoz-Sanjuan, C. R. Altmann, A. Vonica, and A. H. Brivanlou. Cell fate specification and competence by Coco, a maternal BMP, TGFbeta and Wnt inhibitor. Development, 130, 1381–1389 (2003). 173. D. G. Winkler, M. S. Sutherland, E. Ojala, E. Turcott, J. C. Geoghegan, D. Shpektor, J. E. Skonier, C. Yu, and J. A. Latham. Sclerostin inhibition of Wnt-3a-induced C3H10T1/2 cell differentiation is indirect and mediated by bone morphogenetic proteins. J Biol Chem, 280, 2498–2502 (2005). 174. T. Bellido, A. A. Ali, I. Gubrij, L. I. Plotkin, Q. Fu, C. A. O’Brien, S. C. Manolagas, and R. L. Jilka. Chronic elevation of parathyroid hormone in mice reduces expression of sclerostin by osteocytes: A novel mechanism for hormonal control of osteoblastogenesis. Endocrinology, 146, 4577–4583 (2005). 175. J. Laurikkala, Y. Kassai, L. Pakkasjarvi, I. Thesleff, and N. Itoh. Identification of a secreted BMP antagonist, ectodin, integrating BMP, FGF, and SHH signals from the tooth enamel knot. Dev Biol, 264, 91–105 (2003). 176. R. D. Devlin, Z. Du, R. C. Pereira, R. B. Kimble, A. N. Economides, V. Jorgetti, and E. Canalis. Skeletal overexpression of noggin results in osteopenia and reduced bone formation. Endocrinology, 144, 1972–1978 (2003). 177. E. Gazzerro, Z. Du, R. D. Devlin, S. Rydziel, L. Priest, A. N. Economides, and E. Canalis. Noggin arrests stromal cell differentiation in vitro. Bone, 32, 111–119 (2003). 178. E. Gazzerro, R. C. Pereira, V. Jorgetti, S. Olson, A. N. Economides, and E. Canalis. Skeletal overexpression of gremlin impairs bone formation and causes osteopenia. Endocrinology, 146, 655–665 (2005). 179. G. G. Loots, M. Kneissel, H. Keller, M. Baptist, J. Chang, N. M. Collette, D. Ovcharenko, I. Plajzer-Frick, and E. M. Rubin. Genomic deletion of a long-range bone enhancer misregulates sclerostin in Van Buchem disease. Genome Res, 15, 928–935 (2005). 180. L. J. Brunet, J. A. McMahon, A. P. McMahon, and R. M. Harland. Noggin, cartilage morphogenesis, and joint formation in the mammalian skeleton. Science, 280, 1455–1457 (1998). 181. E. Gazzerro, V. Gangji, and E. Canalis. Bone morphogenetic proteins induce the expression of noggin, which limits their activity in cultured rat osteoblasts. J Clin Invest, 102, 2106– 2114 (1998). 182. R. C. Pereira, A. N. Economides, and E. Canalis. Bone morphogenetic proteins induce gremlin, a protein that limits their activity in osteoblasts. Endocrinology, 141, 4558–4563 (2000). 183. J. I. Jones and D. R. Clemmons. Insulin-like growth factors and their binding proteins: Biological actions. Endocr Rev, 16, 3–34 (1995). 184. V. Hwa, Y. Oh, and R. G. Rosenfeld. The insulin-like growth factor-binding protein (IGFBP) superfamily. Endocr Rev, 20, 761–787 (1999). 185. J. Baker, J. P. Liu, E. J. Robertson, and A. Efstratiadis. Role of insulin-like growth factors in embryonic and postnatal growth. Cell, 75, 73–82 (1993). 186. J. P. Liu, J. Baker, A. S. Perkins, E. J. Robertson, and A. Efstratiadis. Mice carrying null mutations of the genes encoding insulin-like growth factor I (Igf-1) and type 1 IGF receptor (Igf1r). Cell, 75, 59–72 (1993). 187. L. S. Mathews, R. E. Hammer, R. L. Brinster, and R. D. Palmiter. Expression of insulin-like growth factor I in transgenic mice with elevated levels of growth hormone is correlated with growth. Endocrinology, 123, 433–437 (1988). 188. E. Canalis, T. McCarthy, and M. Centrella. Isolation and characterization of insulin-like growth factor I (somatome-
Marcus-Ch19.indd 544
Ernesto Canalis
189.
190. 191.
192. 193.
194.
195.
196.
197.
198.
199.
200.
201.
202.
din-C) from cultures of fetal rat calvariae. Endocrinology, 122, 22–27 (1988). S. Mohan, J. C. Jennings, T. A. Linkhart, and D. J. Baylink. Primary structure of human skeletal growth factor: Homology with human insulin-like growth factor-II. Biochim Biophys Acta, 966, 44–55 (1988). E. Canalis. Effect of insulinlike growth factor I on DNA and protein synthesis in cultured rat calvaria. J Clin Invest, 66, 709–719 (1980). T. L. McCarthy, M. Centrella, and E. Canalis. Regulatory effects of insulin-like growth factors I and II on bone collagen synthesis in rat calvarial cultures. Endocrinology, 124, 301–309 (1989). J. M. Hock, M. Centrella, and E. Canalis. Insulin-like growth factor I has independent effects on bone matrix formation and cell replication. Endocrinology, 122, 254–260 (1988). E. Canalis, S. Rydziel, A. M. Delany, S. Varghese, and J. J. Jeffrey. Insulin-like growth factors inhibit interstitial collagenase synthesis in bone cell cultures. Endocrinology, 136, 1348–1354 (1995). K. M. Rosen, B. M. Wentworth, N. Rosenthal, and L. VillaKomaroff. Specific, temporally regulated expression of the insulin-like growth factor II gene during muscle cell differentiation. Endocrinology, 133, 474–481 (1993). T. Thomas, F. Gori, T. C. Spelsberg, S. Khosla, B. L. Riggs, and C. A. Conover. Response of bipotential human marrow stromal cells to insulin-like growth factors: Effect on binding protein production, proliferation, and commitment to osteoblasts and adipocytes. Endocrinology, 140, 5036–5044 (1999). M. P. Playford, D. Bicknell, W. F. Bodmer, and V. M. Macaulay. Insulin-like growth factor 1 regulates the location, stability, and transcriptional activity of beta-catenin. Proc Natl Acad Sci USA, 97, 12103–12108 (2000). G. Zhao, M. C. Monier-Faugere, M. C. Langub, Z. Geng, T. Nakayama, J. W. Pike, S. D. Chernausek, C. J. Rosen, L. R. Donahue, H. H. Malluche, J. A. Fagin, and T. L. Clemens. Targeted overexpression of insulin-like growth factor I to osteoblasts of transgenic mice: Increased trabecular bone volume without increased osteoblast proliferation. Endocrinology, 141, 2674–2682 (2000). M. Zhang, S. Xuan, M. L. Bouxsein, D. von Stechow, N. Akeno, M. C. Faugere, H. Malluche, G. Zhao, C. J. Rosen, A. Efstratiadis, and T. L. Clemens. Osteoblast-specific knockout of the insulin-like growth factor (IGF) receptor gene reveals an essential role of IGF signaling in bone matrix mineralization. J Biol Chem, 277, 44005–44012 (2002). H. Mochizuki, Y. Hakeda, N. Wakatsuki, N. Usui, S. Akashi, T. Sato, K. Tanaka, and M. Kumegawa. Insulin-like growth factor-I supports formation and activation of osteoclasts. Endocrinology, 131, 1075–1080 (1992). L. M. Chuang, M. G. Myers, Jr., G. A. Seidner, M. J. Birnbaum, M. F. White, and C. R. Kahn. Insulin receptor substrate 1 mediates insulin and insulin-like growth factor Istimulated maturation of Xenopus oocytes. Proc Natl Acad Sci USA, 90, 5172–5175 (1993). M. G. Myers, Jr., X. J. Sun, B. Cheatham, B. R. Jachna, E. M. Glasheen, J. M. Backer, and M. F. White. IRS-1 is a common element in insulin and insulin-like growth factor-I signaling to the phosphatidylinositol 3-kinase. Endocrinology, 132, 1421–1430 (1993). A. Grey, Q. Chen, X. Xu, K. Callon, and J. Cornish. Parallel phosphatidylinositol-3 kinase and p42/44 mitogen-activated protein kinase signaling pathways subserve the mitogenic and antiapoptotic actions of insulin-like growth factor I in osteoblastic cells. Endocrinology, 144, 4886–4893 (2003).
8/22/2007 4:17:41 PM
545
Chapter 19 Skeletal Growth Factors
203. P. F. Collett-Solberg and P. Cohen. Genetics, chemistry, and function of the IGF/IGFBP system. Endocrine, 12, 121–136 (2000). 204. A. Bennett, T. Chen, D. Feldman, R. L. Hintz, and R. G. Rosenfeld. Characterization of insulin-like growth factor I receptors on cultured rat bone cells: Regulation of receptor concentration by glucocorticoids. Endocrinology, 115, 1577– 1583 (1984). 205. Y. Hakeda, S. Harada, T. Matsumoto, K. Tezuka, K. Higashino, H. Kodama, T. Hashimoto-Goto, E. Ogata, and M. Kumegawa. Prostaglandin F2 alpha stimulates proliferation of clonal osteoblastic MC3T3–E1 cells by up-regulation of insulin-like growth factor I receptors. J Biol Chem, 266, 21044–21050 (1991). 206. H. Kurose, K. Yamaoka, S. Okada, S. Nakajima, and Y. Seino. 1,25–Dihydroxyvitamin D3 [1,25–(OH)2D3] increases insulin-like growth factor I (IGF-I) receptors in clonal osteoblastic cells. Study on interaction of IGF-I and 1,25–(OH)2D3. Endocrinology, 126, 2088–2094 (1990). 207. M. Rubini, H. Werner, E. Gandini, C. T. Roberts, Jr., D. LeRoith, and R. Baserga. Platelet-derived growth factor increases the activity of the promoter of the insulin-like growth factor-1 (IGF-1) receptor gene. Exp Cell Res, 211, 374–379 (1994). 208. M. Machwate, E. Zerath, X. Holy, P. Pastoureau, and P. J. Marie. Insulin-like growth factor-I increases trabecular bone formation and osteoblastic cell proliferation in unloaded rats. Endocrinology, 134, 1031–1038 (1994). 209. P. R. Ebeling, J. D. Jones, W. M. O’Fallon, C. H. Janes, and B. L. Riggs. Short-term effects of recombinant human insulin-like growth factor I on bone turnover in normal women. J Clin Endocrinol Metab, 77, 1384–1387 (1993). 210. S. Grinspoon, L. Thomas, K. Miller, D. Herzog, and A. Klibanski. Effects of recombinant human IGF-I and oral contraceptive administration on bone density in anorexia nervosa. J Clin Endocrinol Metab, 87, 2883–2891 (2002). 211. E. Canalis. Skeletal growth factors and aging. J Clin Endocrinol Metab, 78, 1009–1010 (1994). 212. V. Nicolas, A. Prewett, P. Bettica, S. Mohan, R. D. Finkelman, D. J. Baylink, and J. R. Farley. Age-related decreases in insulin-like growth factor-I and transforming growth factor-beta in femoral cortical bone from both men and women: Implications for bone loss with aging. J Clin Endocrinol Metab, 78, 1011–1016 (1994). 213. A. Efstratiadis. Genetics of mouse growth. Int J Dev Biol, 42, 955–976 (1998). 214. D. Bikle, S. Majumdar, A. Laib, L. Powell-Braxton, C. Rosen, W. Beamer, E. Nauman, C. Leary, and B. Halloran. The skeletal structure of insulin-like growth factor I-deficient mice. J Bone Miner Res, 16, 2320–2329 (2001). 215. W. H. Beamer and E. M. Eicher. Stimulation of growth in the little mouse. J Endocrinol, 71, 37–45 (1976). 216. N. A. Sims, P. Clement-Lacroix, F. Da Ponte, Y. Bouali, N. Binart, R. Moriggl, V. Goffin, K. Coschigano, M. GaillardKelly, J. Kopchick, R. Baron, and P. A. Kelly. Bone homeostasis in growth hormone receptor-null mice is restored by IGF-I but independent of Stat5. J Clin Invest, 106, 1095–1103 (2000). 217. S. Yakar, J. L. Liu, B. Stannard, A. Butler, D. Accili, B. Sauer, and D. LeRoith. Normal growth and development in the absence of hepatic insulin-like growth factor I. Proc Natl Acad Sci USA, 96, 7324–7329 (1999). 218. S. Yakar, C. J. Rosen, W. G. Beamer, C. L. AckertBicknell, Y. Wu, J. L. Liu, G. T. Ooi, J. Setser, J. Frystyk, Y. R. Boisclair, and D. LeRoith. Circulating levels of IGF-1
Marcus-Ch19.indd 545
219.
220.
221.
222. 223.
224. 225.
226.
227.
228. 229. 230.
231.
232.
233.
234.
directly regulate bone growth and density. J Clin Invest, 110, 771–781 (2002). N. Ogata, D. Chikazu, N. Kubota, Y. Terauchi, K. Tobe, Y. Azuma, T. Ohta, T. Kadowaki, K. Nakamura, and H. Kawaguchi. Insulin receptor substrate-1 in osteoblast is indispensable for maintaining bone turnover. J Clin Invest, 105, 935–943 (2000). M. Yamaguchi, N. Ogata, Y. Shinoda, T. Akune, S. Kamekura, Y. Terauchi, T. Kadowaki, K. Hoshi, U. I. Chung, K. Nakamura, and H. Kawaguchi. Insulin receptor substrate-1 is required for bone anabolic function of parathyroid hormone in mice. Endocrinology, 146, 2620–2628 (2005). L. J. Hall, Y. Kajimoto, D. Bichell, S. W. Kim, P. L. James, D. Counts, L. J. Nixon, G. Tobin, and P. Rotwein. Functional analysis of the rat insulin-like growth factor I gene and identification of an IGF-I gene promoter. DNA Cell Biol, 11, 301– 313 (1992). S. W. Kim, R. Lajara, and P. Rotwein. Structure and function of a human insulin-like growth factor-I gene promoter. Mol Endocrinol, 5, 1964–1972 (1991). M. L. Adamo, H. Ben Hur, C. T. Roberts, Jr., and D. LeRoith. Regulation of start site usage in the leader exons of the rat insulin-like growth factor-I gene by development, fasting, and diabetes. Mol Endocrinol, 5, 1677–1686 (1991). T. L. McCarthy, M. Centrella, and E. Canalis. Cyclic AMP induces insulin-like growth factor I synthesis in osteoblastenriched cultures. J Biol Chem, 265, 15353–15356 (1990). E. Canalis, M. Centrella, W. Burch, and T. L. McCarthy. Insulin-like growth factor I mediates selective anabolic effects of parathyroid hormone in bone cultures. J Clin Invest, 83, 60–65 (1989). D. D. Bikle, T. Sakata, C. Leary, H. Elalieh, D. Ginzinger, C. J. Rosen, W. Beamer, S. Majumdar, and B. P. Halloran. Insulin-like growth factor I is required for the anabolic actions of parathyroid hormone on mouse bone. J Bone Miner Res, 17, 1570–1578 (2002). L. M. Calvi, G. B. Adams, K. W. Weibrecht, J. M. Weber, D. P. Olson, M. C. Knight, R. P. Martin, E. Schipani, P. Divieti, F. R. Bringhurst, L. A. Milner, H. M. Kronenberg, and D. T. Scadden. Osteoblastic cells regulate the haematopoietic stem cell niche. Nature, 425, 841–846 (2003). J. Pfeilschifter and G. R. Mundy. Modulation of type beta transforming growth factor activity in bone cultures by osteotropic hormones. Proc Natl Acad Sci USA, 84, 2024–2028 (1987). A. M. Delany, D. Durant, and E. Canalis. Glucocorticoid suppression of IGF I transcription in osteoblasts. Mol Endocrinol, 15, 1781–1789 (2001). M. Ernst and G. A. Rodan. Estradiol regulation of insulinlike growth factor-I expression in osteoblastic cells: Evidence for transcriptional control. Mol Endocrinol, 5, 1081–1089 (1991). V. Gangji, S. Rydziel, B. Gabbitas, and E. Canalis. Insulinlike growth factor II promoter expression in cultured rodent osteoblasts and adult rat bone. Endocrinology, 139, 2287–2292 (1998). M. A. van Dijk, F. M. van Schaik, H. J. Bootsma, P. Holthuizen, and J. S. Sussenbach. Initial characterization of the four promoters of the human insulin-like growth factor II gene. Mol Cell, Endocrinol, 81, 81–94 (1991). R. Okazaki, B. L. Riggs, and C. A. Conover. Glucocorticoid regulation of insulin-like growth factor-binding protein expression in normal human osteoblast-like cells. Endocrinology, 134, 126–132 (1994). D. L. Andress and R. S. Birnbaum. Human osteoblast-derived insulin-like growth factor (IGF) binding protein-5 stimulates
8/22/2007 4:17:41 PM
546
235.
236.
237.
238.
239.
240.
241.
242.
243. 244.
245.
246.
247. 248.
Marcus-Ch19.indd 546
Ernesto Canalis
osteoblast mitogenesis and potentiates IGF action. J Biol Chem, 267, 22467–22472 (1992). J. I. Jones, A. Gockerman, W. H. Busby, Jr., C. CamachoHubner, and D. R. Clemmons. Extracellular matrix contains insulin-like growth factor binding protein-5: Potentiation of the effects of IGF-I. J Cell Biol, 121, 679–687 (1993). S. Amin, B. L. Riggs, E. J. Atkinson, A. L. Oberg, L. J. Melton, III, and S. Khosla. A potentially deleterious role of IGFBP-2 on bone density in aging men and women. J Bone Miner Res, 19, 1075–1083 (2004). F. Eckstein, T. Pavicic, S. Nedbal, C. Schmidt, U. Wehr, W. Rambeck, E. Wolf, and A. Hoeflich. Insulin-like growth factor-binding protein-2 (IGFBP-2) overexpression negatively regulates bone size and mass, but not density, in the absence and presence of growth hormone/IGF-I excess in transgenic mice. Anat Embryol (Berl), 206, 139–148 (2002). J. V. Silha, S. Mishra, C. J. Rosen, W. G. Beamer, R. T. Turner, D. R. Powell, and L. J. Murphy. Perturbations in bone formation and resorption in insulin-like growth factor binding protein-3 transgenic mice. J Bone Miner Res, 18, 1834–1841 (2003). N. Miyakoshi, X. Qin, Y. Kasukawa, C. Richman, A. K. Srivastava, D. J. Baylink, and S. Mohan. Systemic administration of insulin-like growth factor (IGF)-binding protein-4 (IGFBP-4) increases bone formation parameters in mice by increasing IGF bioavailability via an IGFBP-4 protease-dependent mechanism. Endocrinology, 142, 2641–2648 (2001). C. Richman, D. J. Baylink, K. Lang, C. Dony, and S. Mohan. Recombinant human insulin-like growth factor-binding protein-5 stimulates bone formation parameters in vitro and in vivo. Endocrinology, 140, 4699–4705 (1999). R. D. Devlin, Z. Du, V. Buccilli, V. Jorgetti, and E. Canalis. Transgenic mice overexpressing insulin-like growth factor binding protein-5 display transiently decreased osteoblastic function and osteopenia. Endocrinology, 143, 3955–3962 (2002). M. Zhang, M. C. Faugere, H. Malluche, C. J. Rosen, S. D. Chernausek, and T. L. Clemens. Paracrine overexpression of IGFBP-4 in osteoblasts of transgenic mice decreases bone turnover and causes global growth retardation. J Bone Miner Res, 18, 836–843 (2003). D. Durant, R. M. Pereira, and E. Canalis. Overexpression of insulin-like growth factor binding protein-5 decreases osteoblastic function in vitro. Bone, 35, 1256–1262 (2004). C. Hassager, L. A. Fitzpatrick, E. M. Spencer, B. L. Riggs, and C. A. Conover. Basal and regulated secretion of insulin-like growth factor binding proteins in osteoblast-like cells is cell line specific. J Clin Endocrinol Metab, 75, 228–233 (1992). T. L. McCarthy, S. Casinghino, M. Centrella, and E. Canalis. Complex pattern of insulin-like growth factor binding protein expression in primary rat osteoblast enriched cultures: Regulation by prostaglandin E2, growth hormone, and the insulin-like growth factors. J Cell Physiol, 160, 163–175 (1994). R. S. Birnbaum and K. M. Wiren. Changes in insulin-like growth factor-binding protein expression and secretion during the proliferation, differentiation, and mineralization of primary cultures of rat osteoblasts. Endocrinology, 135, 223– 230 (1994). E. Canalis and B. Gabbitas. Skeletal growth factors regulate the synthesis of insulin-like growth factor binding protein-5 in bone cell cultures. J Biol Chem, 270, 10771–10776 (1995). T. L. Chen, L. Y. Chang, D. A. DiGregorio, A. J. Perlman, and Y. F. Huang. Growth factor modulation of insulin-like
249.
250.
251. 252.
253.
254.
255. 256. 257.
258.
259.
260.
261.
262.
263.
growth factor-binding proteins in rat osteoblast-like cells. Endocrinology, 133, 1382–1389 (1993). Y. Dong and E. Canalis. Insulin-like growth factor (IGF) I and retinoic acid induce the synthesis of IGF-binding protein 5 in rat osteoblastic cells. Endocrinology, 136, 2000–2006 (1995). T. Moriwake, H. Tanaka, S. Kanzaki, J. Higuchi, and Y. Seino. 1,25–Dihydroxyvitamin D3 stimulates the secretion of insulin-like growth factor binding protein 3 (IGFBP-3) by cultured human osteosarcoma cells. Endocrinology, 130, 1071–1073 (1992). C. A. Conover. Insulin-like growth factor binding protein proteolysis in bone cell models. Prog Growth Factor Res, 6, 301–309 (1995). S. Kanzaki, S. Hilliker, D. J. Baylink, and S. Mohan. Evidence that human bone cells in culture produce insulin-like growth factor-binding protein-4 and -5 proteases. Endocrinology, 134, 383–392 (1994). N. Franchimont, D. Durant, and E. Canalis. Interleukin-6 and its soluble receptor regulate the expression of insulinlike growth factor binding protein-5 in osteoblast cultures. Endocrinology, 138, 3380–3386 (1997). S. Rydziel, A. M. Delany, and E. Canalis. AU-rich elements in the collagenase 3 mRNA mediate stabilization of the transcript by cortisol in osteoblasts. J Biol Chem, 279, 5397–5404 (2004). A. J. Strain. Hepatocyte growth factor: Another ubiquitous cytokine. J Endocrinol, 137, 1–5 (1993). K. Matsumoto and T. Nakamura. Emerging multipotent aspects of hepatocyte growth factor. J Biochem (Tokyo), 119, 591–600 (1996). J. Okano, G. Shiota, and H. Kawasaki. Protective action of hepatocyte growth factor for acute liver injury caused by D-galactosamine in transgenic mice. Hepatology, 26, 1241–1249 (1997). F. Blanquaert, A. M. Delany, and E. Canalis. Fibroblast growth factor-2 induces hepatocyte growth factor/scatter factor expression in osteoblasts. Endocrinology, 140, 1069–1074 (1999). M. Grano, F. Galimi, G. Zambonin, S. Colucci, E. Cottone, A. Z. Zallone, and P. M. Comoglio. Hepatocyte growth factor is a coupling factor for osteoclasts and osteoblasts in vitro. Proc Natl Acad Sci USA, 93, 7644–7648 (1996). G. Zambonin, C. Camerino, G. Greco, V. Patella, B. Moretti, and M. Grano. Hydroxyapatite coated with hepatocyte growth factor (HGF) stimulates human osteoblasts in vitro. J Bone Joint Surg Br, 82, 457–460 (2000). F. Bladt, D. Riethmacher, S. Isenmann, A. Aguzzi, and C. Birchmeier. Essential role for the c-met receptor in the migration of myogenic precursor cells into the limb bud. Nature, 376, 768–771 (1995). F. Blanquaert, R. C. Pereira, and E. Canalis. Cortisol inhibits hepatocyte growth factor/scatter factor expression and induces c-met transcripts in osteoblasts. Am J Physiol Endocrinol Metab, 278, E509–E515 (2000). Y. Imai, H. Terai, C. Nomura-Furuwatari, S. Mizuno, K. Matsumoto, T. Nakamura, and K. Takaoka. Hepatocyte growth factor contributes to fracture repair by upregulating the expression of BMP receptors. J Bone Miner Res, 20, 1723–1730 (2005).
8/22/2007 4:17:41 PM