Tony D. Fang

Angiogenesis Is Required for Successful Bone Induction During Distraction Osteogenesis

The role of angiogenesis during mechanically induced bone formation is incompletely understood. The relationship between the mechanical environment, angiogenesis, and bone formation was determined in a rat distraction osteogenesis model. Disruption of either the mechanical environment or endothelial cell proliferation blocked angiogenesis and bone formation. This study further defines the role of the mechanical environment and angiogenesis during distraction osteogenesis.

Applications of a mouse model of calvarial healing: Differences in regenerative abilities of juveniles and adults

Young children are capable of healing large calvarial defects, whereas adults lack this endogenous osseous tissue-engineering capacity. Despite the important clinical implications, little is known about the molecular and cell biology underlying this differential ability. Traditionally, guinea pig, rabbit, and rat models have been used to study the orchestration of calvarial healing. To harness the research potential of knockout and transgenic mice, the authors developed a mouse model for calvarial healing. Nonsuture-associated parietal defects 3, 4, and 5 mm in diameter were made in both juvenile (6-day-old, n = 15) and adult (60-day-old, n = 15) mice. Calvariae were harvested after 8 weeks and analyzed radiographically and histologically. Percentage of healing was quantified using Scion Image software analysis of calvarial radiographs. A significant difference in the ability to heal calvarial defects was seen between 6-day-old and 60-day-old mice when 3-, 4-, or 5-mm defects were created. The authors’ analysis revealed that juvenile mice healed a significantly greater percentage of their calvarial defects than adult mice (juvenile mean percentage of healing: 3-mm defects, 59 percent; 4-mm defects, 65 percent; 5-mm defects, 44 percent; adult mean percentage of healing: <5 percent in all groups; p < 0.05). All three defect sizes were found to be critical in the adult, whereas significant healing was seen regardless of the size of the defect in juvenile mice. The establishment of this model will facilitate further, detailed evaluation of the molecular biology underlying the different regenerative abilities of juvenile versus adult mice and enhance research into membranous bone induction by making available powerful tools such as knockout and transgenic animals.

High-dose retinoic acid modulates rat calvarial osteoblast biology†

Retinoic acid has been shown to adversely affect craniofacial development. Cleft palate and craniosynostosis are two examples of craniofacial defects associated with prenatal exposure to this agent. Although the effects of retinoic acid on cephalic neural crest‐derived tissues have previously been studied, the specific effects of retinoic acid on the cellular biology of osteoblasts remain unclear. The purpose of this study was to analyze in detail the effects of pharmacologic doses of retinoic acid on the differentiation and proliferation of osteoblasts derived from an intramembranous source. Primary rat calvarial osteoblasts were established in culture and treated with 1 or 10 μM all‐trans‐retinoic acid. Retinoic acid treatment markedly increased expression of osteopontin up to 48 h after stimulation. Consistent with this early stage of differentiation, both mRNA and protein analysis of FGF receptor isoforms demonstrated a switch in predominance from fibroblast growth factor receptor 2 (fgfr2) to fgfr1. Analysis of PCNA protein confirmed inhibition of proliferation by retinoic acid. To determine whether these alterations in osteoblast biology would lead to increased differentiation, we examined short term [alkaline phosphatase (AP) activity] and long term (von Kossa staining) surrogates of bone formation in vitro. These assays confirmed that retinoic acid increased osteogenesis, with a 4‐fold increase in bone nodule formation in cells treated with 10 μM retinoic acid after 28 days. Overall, our results demonstrated that pharmacologic doses of all‐trans‐retinoic acid decreased osteoblast proliferation and increased differentiation, suggesting that retinoic acid may effect craniofacial development by pathologically enhancing osteogenesis.

Equibiaxial tensile strain affects calvarial osteoblast biology.

Mechanical tensile strain is believed to play an important role in regulating calvarial morphogenesis. To better understand the effects of mechanical strain on pathologic calvarial growth, we applied 10% constant equibiaxial tensile strain to neonatal rat calvarial osteoblast cultures and examined cellular proliferation, cytokine production, and extracellular matrix molecule expression. Mechanical strain markedly increased osteoblast proliferation as demonstrated by increased proliferating cell nuclear antigen (PCNA) protein. In addition, both transforming growth factor-&bgr;1 (TGF-&bgr;1) mRNA expression and fibroblast growth factor-2 (FGF-2) protein production were increased with exposure to strain. Moreover, mechanical strain induced expression of the extracellular matrix molecule collagen I&agr;I. To further explore the relationship between mechanotransduction, osteogenesis, and angiogenesis, we examined the effect of mechanical strain on calvarial osteoblast expression of vascular endothelial growth factor (VEGF). Interestingly, we found that mechanical strain induced a rapid (within 3 hrs) increase in osteoblast VEGF expression. These data suggest that constant equibiaxial tensile strain-induced mechanotransduction can influence osteoblasts to assume an “osteogenic” and “angiogenic” phenotype, and these findings may have important implications for understanding the mechanisms of pathologic strain-induced calvarial growth.

Mechanical strain affects dura mater biological processes: implications for immature calvarial healing.

The human brain grows rapidly during the first 2 years of life. This growth generates tensile strain in the overlying dura mater and neurocranium. Interestingly, it is largely during this 2-year growth period that infants are able to reossify calvarial defects. This clinical observation is important because it suggests that calvarial healing is most robust during the period of active intracranial volume expansion. With a rat model, it was previously demonstrated that immature dura mater proliferates more rapidly and produces more osteogenic cytokines and markers of osteoblast differentiation than does mature dura mater. It was therefore hypothesized that mechanical strain generated by the growing brain induces immature dura mater proliferation and increases osteogenic cytokine expression necessary for growth and healing of the overlying calvaria. Human and rat (n = 40) intracranial volume expansion was calculated as a function of age. These calculations demonstrated that 83 percent of human intracranial volume expansion is complete by 2 years of age and 90 percent of Sprague-Dawley rat intracranial volume expansion is achieved by 2 months of age. Next, the maximal daily circumferential tensile strains that could be generated in immature rat dura mater were calculated, and the corresponding daily biaxial tensile strains in the dura mater during this 2-month period were determined. With the use of a three-parameter monomolecular growth curve, it was calculated that rat dura mater experiences daily equibiaxial strains of at most 9.7 percent and 0.1 percent at birth (day 0) and 60 days of age, respectively. Because it was noted that immature dural cells may experience tensile strains as high as approximately 10 percent, neonatal rat dural cells were subjected to 10 percent equibiaxial strain in vitro, and dural cell proliferation and gene expression profiles were analyzed. When exposed to mechanical strain, immature dural cells rapidly proliferated (5.8-fold increase in proliferating cell nuclear antigen expression at 24 hours). Moreover, mechanical strain induced marked up-regulation of dural cell osteogenic cytokine production; transforming growth factor-&bgr;1 messenger RNA levels increased 3.4-fold at 3 hours and fibroblast growth factor-2 protein levels increased 4.5-fold at 24 hours and 5.6-fold at 48 hours. Finally, mechanical strain increased dural cell expression of markers of osteoblast differentiation (2.8-fold increase in osteopontin levels at 3 hours). These findings suggest that mechanical strain can induce changes in dura mater biological processes and gene expression that may play important roles in coordinating the growth and healing of the neonatal calvaria.

Regional dura mater differentially regulates osteoblast gene expression.

Recent studies have suggested that regionally differentiated dura mater regulates murine cranial suture fate by providing growth factors to the osteoblasts in the overlying suture complex. To determine if regionally differentiated dura mater is capable of effecting changes in osteoblast gene expression, an in vitro coculture system was established in which osteoblast-enriched cell cultures derived from neonatal rat calvaria were grown in serum-free media in the presence of dural cells derived from posterior frontal (PF) or sagittal (SAG) dural tissues, recapitulating the in situ relation between the underlying dura mater and the osteoblasts in the overlying cranial suture. In this study, the changes in osteoblast gene expression induced by signaling from regional dura mater were examined by analyzing total cellular RNA isolated from osteoblasts cocultured with PF or SAG dural cells. The expression of extracellular matrix molecules (alkaline phosphatase, bone sialoprotein, osteopontin, and osteocalcin) and the transcription factor Msx2 was assessed. Consistent with previous data, the findings demonstrate that osteoblasts cocultured with dural cells undergo changes in gene expression indicative of a more differentiated osteoblast. Additionally, the data suggest that regionally differentiated dura mater isolated from the PF suture enhances the expression of osteogenic genes to a greater extent than SAG suture-derived dural cells. These data support an osteoinductive role for suture-derived dural cells in vitro that may have implications for suture biology in vivo.

Expression and possible mechanisms of regulation of bmp3 in rat cranial sutures

Background: Clinical genetics data and investigative studies have contributed greatly to our understanding of the role of numerous genes in craniosynostosis. Recent studies have introduced antagonists of osteogenesis as potential key regulators of suture fusion and patency. The authors investigated the expression pattern of the bone morphogenetic protein antagonist BMP3 in rat cranial sutures and the factors regulating its expression in vitro. Methods: Microarray analysis was performed on rat posterior frontal and sagittal cranial sutures at 5, 10, 15, 20, and 30 days of life (n = 30 per group). Gene expression was confirmed using quantitative real-time reverse transcriptase polymerase chain reaction. Regulation of BMP3 expression was determined using primary rat calvarial osteoblasts stimulated with recombinant human fibroblast growth factor 2 or recombinant human transforming growth factor &bgr;1, or cultured with primary rat nonsuture dura mater. Gene expression was quantified with quantitative real-time reverse transcriptase polymerase chain reaction. Results: BMP3 expression in the posterior frontal suture decreased over the time course analyzed, whereas it increased in the sagittal suture. Notably, BMP3 expression was higher in the patent sagittal suture during the window of posterior frontal suture fusion. Stimulation of osteoblasts with recombinant human fibroblast growth factor 2 led to a rapid and sustained suppression of BMP3 expression (85 percent, p < 0.01) when compared with controls. Co-culture with dural cells decreased BMP3 mRNA by 50 percent compared with controls (p < 0.01). Conclusions: BMP3 is expressed in rat cranial sutures in a temporal pattern suggesting involvement in cranial suture patency and fusion. Furthermore, BMP3 is regulated in calvarial osteoblasts by recombinant human fibroblast growth factor 2 and by paracrine signaling from dura mater. These data add to our knowledge of the role of osteogenic antagonists in cranial suture biology.

Markers of osteoblast differentiation in fusing and nonfusing cranial sutures.

Accumulating clinical genetic data support the hypothesis that alterations in osteoblast differentiation are closely associated with craniosynostoses. Gain-of-function mutations in FGFR1, FGFR2, FGFR3, and Msx2 and loss-of-function mutations in Twist are examples of such alterations. Several studies have examined how these mutations alter the expression patterns for transcription factors such as Runx2 and noncollagenous extracellular matrix molecules such as osteopontin and osteocalcin. One limitation of such studies is that they examine samples derived from craniosynostotic patients with sutures that have already fused, thus missing the dynamic osteogenic process of suture fusion. In this study, in situ hybridization was used to localize Runx2, osteopontin, and osteocalcin expression in the sagittal and posterior frontal sutures in mice (n = 20), before (day 13), during (days 23, 33, and 43), and after (day 53) the period of physiological posterior frontal suture fusion. The data demonstrated similar patterns of expression in fusing (posterior frontal) and nonfusing (sagittal) sutures. The expression of all three genes was primarily concentrated in the osteogenic fronts of both sutures and decreased with time. Notably, none of the three genes was expressed in the mesenchyme of either fusing or nonfusing sutures. The data suggest that the molecular signals leading to bone formation along the osteogenic fronts in fusing and nonfusing sutures are similar, raising the possibility that other factors, such as antagonists of osteogenesis, might have a role in maintaining suture patency.

In vitro murine posterior frontal suture fate is age-dependent: Implications for cranial suture biology

In CD-1 mice, the posterior frontal suture (analogous to the human metopic suture) fuses while all other cranial sutures remain patent. In an in vitro organ culture model, the authors previously demonstrated that posterior frontal sutures explanted immediately before the onset of suture fusion (at 25 days old) mimic in vivo physiologic fusion. In the first portion of this study, the authors defined how early in development the posterior frontal suture fuses in their tension-free, serum-free organ culture system by serially analyzing posterior frontal suture fusion from calvariae explanted at different stages of postnatal development. Their results revealed a divergence of suture fate leading to abnormal patency or physiologic fusion between the first and second weeks of life, respectively, despite viability and continued growth of the calvarial explants in vitro. From these data, the authors postulated that the gene expression patterns present in the suture complex at the time of explant may determine whether the posterior frontal suture fuses or remains patent in organ culture. Therefore, to elucidate potentially important differences in gene expression within this “window of opportunity,” they performed a cDNA microarray analysis on 5-day-old and 15-day-old posterior frontal and sagittal whole suture complexes corresponding to the age ranges for unsuccessful (1 to 7 days old) and successful (14 to 21 days old) in vitro posterior frontal suture fusion. Overall, their microarray results reveal interesting differential expression patterns of candidate genes in different categories, including angiogenic cytokines and mechanosensitive genes potentially important in cranial suture biology.

Apoptosis in a rodent model of cranial suture fusion: in situ imaging and gene expression analysis.

Craniosynostosis, the premature fusion of cranial sutures, is one of the most common craniofacial anomalies, with a reported incidence of up to one in 2500 live births. Despite its prevalence, the cause of craniosynostosis remains unknown. Previously, apoptosis has been postulated to be a contributing factor in the pathogenesis of craniosynostosis, although the role of programmed cell death in cranial sutures is poorly understood. To address this problem, the authors used an established rodent model of posterior-frontal suture fusion and sagittal suture patency to globally examine apoptosis in cranial sutures. Apoptosis was evaluated by systemically coinjecting Sprague-Dawley rats with both fluorescent and technetium-99m–labeled annexin V at time points before, during, and after the period of predicted posterior-frontal suture fusion to determine the magnitude and time course of overall apoptotic activity in both fusing and patent sutures. Using these novel in situ imaging techniques, the authors observed a significant increase in the overall levels of apoptosis in both the posterior-frontal and sagittal suture complexes during the period of predicted posterior-frontal suture fusion. To further explore this increase in apoptotic activity, they used microarray technology to study apoptosis-related genes within the suture complex. Interestingly, there was activation of distinct apoptotic pathways in the posterior-frontal and sagittal sutures during the period of predicted posterior-frontal suture fusion. Whereas increased transcription of genes associated with the mitochondria-mediated apoptotic pathway occurred in the posterior-frontal suture during fusion, activation of genes associated with the death receptor–mediated apoptotic pathway predominated in the patent sagittal suture during the same time period. These data suggest that although overall apoptotic activity in rat patent and fusing sutures is similar, the pathways mediating apoptosis within each suture are distinct.