Mineralized bone nodules formed in vitro from enzymatically released rat calvaria cell populations

Cloning of an osteoblastic cell line involved in the formation of osteoclast-like cells

Experiments have been carried out to determine the mechanisms involved in the formation of osteoclast-like cells from spleen cells in mice. Osteoclasts were defined as tartrate-resistant acid phosphatase-positive multinucleated cells (TRACP-positive MNCs) in which specific calcitonin receptors were identified by autoradiography with labeled salmon calcitonin. Furthermore, cultures rich in these cells produced resorption pits when grown on dentine slices. Several clonal cell lines were obtained from fetal mouse calvariae and screened for their ability to induce TRACP-positive MNCs in response to 1 alpha, 25-dihydroxyvitamin D3 [1 alpha, 25(OH)2D3] in co-cultures with spleen cells. A cell line, KS-4, was identified with the greatest potency in inducing osteoclast-like cell formation in co-culture with spleen cells. The capacity of KS-4 cells to produce this effect was much greater than that of two bone marrow-derived stromal cell lines (MC3T3-G2/PA6 and ST2 cells), which we have previously shown to be effective in this system but to require treatment with dexamethasone in addition to 1 alpha, 25(OH)2D3 (Udagawa et al.: Endocrinology 125:1805-1813, 1989). Parathyroid hormone (PTH) increased cAMP production in KS-4 cells, and PTH and interleukin-1 alpha also induced TRACP-positive MNCs in co-cultures with spleen cells. Contact between living KS-4 and spleen cells was necessary for osteoclast formation to take place, since this did not occur when the two populations were separated by a membrane filter, or when the KS-4 cells were killed by fixation. Separate cultures of either spleen cells or KS-4 cells formed no TRACP-positive MNCs. KS-4 cells synthesized predominantly type I collagen, formed bone nodules without added of beta-glycerophosphate in a long-term culture, and expressed increasing alkaline phosphatase activity after confluence in culture. These results indicate that the KS-4 cells have properties consistent with progression toward the osteoblast phenotype and represent a single cell line with the ability to promote osteoclast formation by a contact-requiring process.

Ultrastructural and immunocytochemical study of bone-derived cells cultured in three-dimensional matrices: influence of chondroitin-4 sulfate on mineralization

Bone-derived cells were cultured in three-dimensional reconstituted matrices made of type I collagen or type I collagen chondroitin-4-sulfate. As observed by microscope, their characteristics were as follows: The cells deposited a faint extracellular matrix mainly composed of type I collagen. In the collagen-chondroitin-sulfate sponge fibers, a calcification process, which involved the deposition of hydroxyapatite crystals, was demonstrated. Mineralization occurred only in collagen chondroitin sulfate sponge fibers when seeded with bone-derived cells and was not seen with nonosteogenic cells, such as gingival fibroblasts. Gla protein was intracellularly visualized in both types of sponges seeded with bone-derived cells while an extracellular secretion was seen only in the collagen chondroitin sulfate sponge fibers where calcification occurred. These results suggest that collagen chondroitin sulfate promotes in vitro mineralization of three-dimensional collagen matrices when seeded with bone-derived cells.

Regulation of alkaline phosphatase by 1,25-dihydroxyvitamin D3 and ascorbic acid in bone-derived cells

The bone, liver, and kidney isozyme of alkaline phosphatase (ALP) has been measured in MG-63 human osteosarcoma cells after treatment with ascorbic acid (AA) and/or 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3]. Both compounds were required to achieve maximum ALP activity. When grown in the absence of 1,25-(OH)2D3 cells had low basal ALP activity regardless of whether media contained AA. In AA-free medium, 1,25-(OH)2D3 (10 nM) increased ALP activity fourfold. Addition of AA further increased levels of ALP activity induced by 1,25-(OH)2D3 to 10-15 times those found in -AA controls. The earliest effects of 1,25-(OH)2D3 were seen after 24-48 h, and ALP activity continued to increase for 6-8 days. AA and 1,25-(OH)2D3 had similar effects on ALP activity in ROS 17/2.8 rat osteosarcoma cells. In MG-63 cells the effects of AA and 1,25-(OH)2D3 could not be simply explained by the ability of these compounds to inhibit cell growth because another mitotic inhibitor, hydroxyurea, had a minimal effect on ALP activity. 1,25-(OH)2D3-specific induction of ALP +/- AA was totally blocked by inhibitors of protein and RNA synthesis. Maximal ALP induction was obtained when cells were plated at low density. Consistent with our previous report (Franceschi et al. 1988 J Biol Chem 263:18938-18945), 1,25-(OH)2D3 rapidly stimulated type I collagen synthesis and acid-precipitable hydroxyproline production in MG-63 cells and this stimulation was further increased by AA. These results suggest that induction of the osteoblast marker, ALP, is directly or indirectly coupled to collagen matrix synthesis and/or accumulation.

Establishment of an osseous cell line from fetal rat calvaria using an immunocytolytic method of cell selection: characterization of the cell line and of derived clones

Using selective media and complement-mediated lysis of primary cultures of a fetal rat calvarial cell population, we have developed a cell line (OBCK6) that exhibits osteoblastic characteristics. OBCK6 cells demonstrated enhanced parathyroid hormone (PTH)-stimulated adenylate cyclase activity relative to the primary calvarial population, production of alkaline phosphatase activity and type 1 collagen, and the capacity to form mineralized nodules in unsupplemented medium after prolonged (22-26 day) culture. Two sublines, CFK1 and CFK2, which were isolated by dilution cloning, differed morphologically and with respect to growth rate. CFK1 cells demonstrated high PTH and prostaglandin E2-stimulated adenylate cyclase activity, whereas only low PTH-stimulated activity was observed in CFK2 cells. Retinoic acid and 1,25-dihydroxyvitamin D3 [1,25(OH)2D3] each reduced PTH-stimulated adenylate cyclase activity in both the cell types. Retinoic acid and dexamethasone reduced and 1,25(OH)2D3 enhanced alkaline phosphatase activity in these cells. PTH significantly augmented alkaline phosphatase activity to a much greater extent in CFK1 than in CFK2 cells. Both CFK1 and CFK2 cells expressed type I but type III collagen, and neither expressed osteocalcin. Strong Alcian blue staining of CFK2 cells was suggestive of a cartilaginous phenotype. These three cell lines, therefore, demonstrated discrete characteristics of skeletal cell function and should provide important models for evaluation of mechanisms of mineralization and for control of skeletal cell growth and mesenchymal differentiation in vitro.

Temporal sequence of interleukin 1 alpha-mediated stimulation and inhibition of bone formation by isolated fetal rat calvaria cells in vitro

Cytokines released at sites of inflammation and infection may alter normal bone remodeling processes resulting in pathologic bone destruction or bone formation. Interleukin 1, an inflammatory mediator, has been shown to stimulate as well as inhibit parameters associated with bone formation. In this study we have examined temporal aspects of the biphasic effects of recombinant interleukin 1 alpha (IL 1 alpha) on the differentiation of osteoprogenitor cells into bone-forming osteoblasts (bone nodules) in vitro. A dose-dependent stimulation of bone formation over a concentration range of 0.5 to 50 U/mL (1.4 x 10(-12) to 1.4 x 10(-10) M) was observed when preconfluent, primary cultures of fetal rat calvaria (RC) cells were pulsed with IL 1 alpha for 72 to 96 hr from the beginning of the culture period. This was correlated with a stimulation of cell proliferation and alkaline phosphatase activity measured during the late log phase of growth. In contrast, continuous exposure to IL 1 alpha or exposure to IL 1 alpha after confluency resulted in inhibition of bone nodule formation and alkaline phosphatase activity. IL 1 alpha-stimulated prostaglandin E2 (PGE2) production until the RC cells became multilayered, but the addition of the cyclooxygenase inhibitor indomethacin had no effect in reducing the IL 1 alpha-mediated stimulation of cell proliferation or bone nodule formation. However, in cultures continuously exposed to IL 1 alpha, added indomethacin partially reduced the inhibition of bone formation, suggesting that prostaglandin production may play a role in the inhibitory effects of IL 1 alpha on bone formation.

In vitro bone formation on coral granules

We investigated the ability of fetal rat bone cells isolated after collagenase digestion to differentiate in vitro and to produce a mineralized matrix on coral granules. Scanning electron microscopy examination of the surface of the seeded coral granules revealed that cells attached, spread, and proliferated on the material surface. Bone nodule formation was studied in this in vitro system by direct examination under an inverted phase contrast microscope. The initial event observed was the appearance of cells with phosphatase alkaline activity arranged in several layers and forming a three-dimensional organization around the coral particles. By Day 7, nodule formation began and a refringent material appeared and extended to the background cells during the following days. By Day 15, some coral granules were embedded in a mineralized matrix. Histologic results demonstrated the formation of a mineralized tissue with the appearance of woven bone.

Differentiation of canalicular cell processes in bone cells by basement membrane matrix components: regulation by discrete domains of laminin

We have investigated the interaction of rat primary calvarial bone cells and a mouse osteoblast-like cell line MC3T3-E1 with basement membrane components. On a reconstituted gel of basement membrane, both cell types attached and formed isolated clusters that developed long interconnecting cell processes similar to the canalicular network observed in bone. The differentiation of the osteoblastic phenotype was stimulated as determined by increased alkaline phosphatase production and the deposition of mineral. Antibodies to laminin and to a 32/67 kd laminin receptor blocked this differentiation. Cell morphology was altered by the addition of active laminin-derived synthetic peptides, YIGSR-NH2 and CSRARKQAASIKVAVSADR-NH2, but not by an active RGD-containing peptide. When coated directly on plastic, all three peptides promoted cell adhesion, demonstrating that bone cells interact with specific molecular domains of laminin. These data demonstrate that basement membrane plays a key role in formation of a network of cytoplasmic processes resembling the osteocyte canalicular network in bone.

Osteogenic cell lineage analysis is facilitated by organ cultures of embryonic chick periosteum

Monoclonal antibodies against the surface of embryonic osteogenic cells (SB-1, SB-2, SB-3, and SB-5) have been used to characterize the sequence of transitions involved in the osteogenic cell lineage. In the present study, immunohistochemical analyses of the expression of osteogenic cell surface antigens in organ cultures of folded chick periosteum were performed. Unlike traditional culture methods using isolated osteoblastic cells, periosteal explants form a mineralized bone tissue in 4 to 6 days which is virtually identical to the in vivo counterpart. Examination of fresh explants confirm that no mature osteoblastic cells were present, although a discontinuous layer of preosteoblasts was evident. As the wave of osteodifferentiation swept through the cultured tissue, antibody SB-1 reacted with the surface of a large family of cells associated with the developing bone. Antibodies SB-3 and SB-2 reacted with progressively smaller subsets of cells, namely those in successively closer physical association with the newly formed and mineralizing bone. Cells recently encased in bone matrix were stained by both SB-2 and SB-5 antibodies, while those cells deep within the matrix reacted only with antibody SB-5. Analysis of this culture model allows dissection of the discrete cellular transition steps of osteogenesis, and reveals that osteogenic precursor cells proceed through the unique lineage stages which have been documented for in vivo osteogenesis. This culture system has furthermore provided evidence which is used to refine our understanding of the osteogenic cell lineage.

Comparison of in vitro and in vivo 44Ca labeling of bone by scanning ion microprobe

To determine whether Ca incorporation from medium into cultured bone represents normal mineralization, we labeled some neonatal mouse calvariae in vitro and others in vivo with the stable isotope 44Ca and compared surface label localization with a scanning ion microprobe utilizing secondary ion mass spectrometry. To label in vitro, we incubated live calvariae in medium containing 40Ca or 44Ca for 3 h. Compared with a 44Ca/40Ca ratio of 0.020 with 1 mM 40Ca, the ratio with 1 mM 44Ca was 0.135 and with 2 mM 44Ca was 0.556. Erosion revealed a marked decrease in 44Ca/40Ca with depth. To label in vivo, we subcutaneously injected 40Ca or 44Ca into mice equal to a percentage of their total body weight and dissected the calvariae 24 h later. Compared with a 44Ca/40Ca ratio of 0.021 with 2% 40Ca, the ratio with 2% 44Ca was 0.120 and with 6% 44Ca was 0.205. Erosion revealed only a slight decrease in 44Ca/40Ca with depth. Elemental distribution maps of in vivo labeled samples show broad deposition of 44Ca, whereas maps of in vitro labeled bones show 44Ca preferentially localized at the surface in contact with the medium. Thus calvariae can be labeled with 44Ca both in vitro and in vivo. However, the differing patterns of isotope localization under the conditions of this study indicate that in vitro Ca deposition differs from normal in vivo bone mineralization.

Morphologic characterization of osteoblast-like cell cultures isolated from newborn rat calvaria

Two methods for harvesting osteoblast-like cell populations from newborn (10 days) rat calvaria were compared. The first one consisted in culturing the periosteum-free bones and then trypsinizing the cells on the bone surface. The second one involved the migration of the osteoblasts on glass fragments before trypsinization. Since the plating efficiency, the proportion of alkaline phosphatase-positive cells, the population doubling time, and the calcium deposition were more adequate, the second method was used to further characterize the behavior of the cultures. During the first week of culture, the cells featured shapes similar to those observed in vivo on the surface of periosteum-free calvaria. They formed multilayers and, in the presence of ascorbic acid, synthetized an organic matrix containing exclusively type I collagen. Later, small amounts of type III collagen appeared. The cells were embedded in the matrix and progressively acquired the morphologic phenotype of osteocyte-like cells. The matrix mineralized in the presence of beta-glycerophosphate. The technique of drop-inoculation (high concentration of cells in a small volume of medium) promoted the multilayer formation and the achievement of large mineralized plates (about 1 cm2) in 3 weeks of culture.

Clonal distribution of osteoprogenitor cells in cultured chick periostea: functional relationship to bone formation

Folded explants of periosteum from embryonic chick calvaria form bone-like tissue when grown in the presence of ascorbic acid, organic phosphate, and dexamethasone. All osteoblast-like cells in these cultures arise de novo by differentiation of osteoprogenitor cells present in the periosteum. To study the spatial and functional relationships between bone formation and osteoprogenitor cells, cultures were continuously labeled with [3H]thymidine for periods of 1-5 days. Radioautographs of serial 2-microns plastic sections stained for alkaline phosphatase (AP) showed maximal labeling of 30% of fibroblastic (AP-negative) cells by 3 days while osteogenic cells (AP-positive) exhibited over 95% labeling by 5 days. No differential shifts in labeling indices, grain count histograms of fibroblastic and osteogenic cells or numbers of AP-positive cells were observed, indicating no significant recruitment of cells from the fibroblastic to the osteogenic compartment. Despite the continuous presence of [3H]thymidine, less than 35% of both osteoblasts and osteocytes were labeled at 5 days, indicating that only one-third of the osteoprogenitor cells had cycled prior to differentiation. Spatial clustering of [3H]thymidine-labeled cells was measured by computer-assisted morphometry and application of the Poisson distribution to assess contagion. Cluster size and number of labeled cells per cluster did not vary between 1-3 days, but the number of clusters increased 20-fold between Day 1 and Day 3. Clusters were predominantly AP-positive and located close to bone. Three-dimensional reconstruction from serial sections showed that clusters formed long, tubular arrays of osteogenic cells up to eight cells in length and located within 2-3 cell layers from the bone surface. Selective killing of S-phase cells with two pulse labels of high specific activity [3H]thymidine at 1 and 2 days of culture completely blocked bone formation. These data indicate that a very small population of cycling osteoprogenitor cells is essential for bone formation in vitro and give rise to relatively small numbers of clonally distributed progenitors with limited proliferative capacity. The progeny of these clusters undergo restricted migration and differentiate into osteoblasts.

Endochondral mineralization in cartilage organoid culture

In the development of secondary bone, mineralization of the cartilage matrix is the first step in endochondral mineralization. The circumstances of cartilage mineralization are not known. Influences of the periosteal tissue have been mentioned. In order to investigate the role of osteoblastic cells in endochondral mineralization, cartilage organoid cultures were induced to mineralize by the addition of beta-glycerophosphate (beta-GP). In cartilage organoid culture, embryonic mouse limb bud mesenchymal cells were grown at high-density. The cells differentiated into mature chondrocytes and produced hyaline cartilage matrix. When cartilage had formed after 6 days in vitro, 10 mM beta-GP was added. The developed mineralized cartilage was investigated by morphological means. Seven days after the addition of beta-GP, the first mineralized spots were visible mainly in the internodular, noncartilage tissue. After 12 to 14 days, large areas of cartilage were mineralized, and after 21 days, nearly the whole culture had been mineralized. Electron microscopic investigations showed a dramatic alteration of the cartilage matrix followed by a homogeneous mineralization of the cartilage matrix. The chondrocytes in the mineralized area died and faded. Typical rod-like apatite crystals were visible at the border between the mineralized and the unmineralized matrix. This result closely resembles the in vivo situation of cartilage mineralization. Addition of osteoblastic calvarial cells enhanced the mineralization process, as did the addition of conditioned medium of calvarial cell monolayers. Under these treatments, mineralization started after 3 days and reached a maximum after 14 days. On the other hand, addition of mouse skin fibroblast-like cells without a direct contact to the cartilage inhibited cartilage mineralization. These results indicate that osteoblastic cells induce endochondral mineralization, whereas fibroblast-like cells inhibit this mineralization via soluble factors.

Modifications of protein-DNA interactions in the proximal promoter of a cell-growth-regulated histone gene during onset and progression of osteoblast differentiation

A temporal sequence of interrelated cellular, biochemical, and molecular events which occurs during the progressive expression of the differentiated osteoblast phenotype in primary cultures of fetal rat calvarial cells results in the development of a bone-tissue-like organization. This ordered developmental sequence encompasses three periods: proliferation, matrix maturation, and mineralization. Initially, the cells actively proliferate and synthesize type I collagen. This is followed by a period of matrix organization and maturation and then by a period of extracellular matrix mineralization. At the completion of proliferation, when expression of osteoblast phenotype markers such as alkaline phosphatase is observed, the cell-cycle-related histone genes are down-regulated transcriptionally, suggesting that a key signaling mechanism at this transition point involves modifications of protein-DNA interactions in the regulatory elements of these growth-regulated genes. Our results demonstrate that there is a selective loss of interaction of the promoter binding factor HiNF-D with the site II region of an H4 histone gene proximal promoter that regulates the specificity and level of transcription only when the down-regulation of proliferation is accompanied by modifications in the extracellular matrix that contribute to progression of osteoblast differentiation. Thus, this specific loss of protein-DNA interaction serves as a marker for a key transition point in the osteoblast developmental sequence, where the down-regulation of proliferation is functionally coupled to the appearance of osteoblast phenotypic properties associated with the organization and maturation of an extracellular matrix that becomes competent to mineralize.

Determination of the capacity for proliferation and differentiation of osteoprogenitor cells in the presence and absence of dexamethasone

Osteoprogenitor cells present in single-cell suspensions prepared from fetal rat calvaria (RC) form discrete mineralized three-dimensional bone nodules when cultured long-term in the presence of ascorbic acid and beta-glycerophosphate. These cells (CFU-O) constitute less than 1% of the total cell population under standard culture conditions and their number is increased in the presence of dexamethasone. Using the formation of the bone nodule as a marker for CFU-O, we have now analyzed the proliferation and differentiation capacity of these CFU-O by redistribution and continuous subculture experiments in the presence and absence of dexamethasone. Cell redistribution experiments showed no increase in nodule number after one population doubling with either treatment. After 5.4 population doublings of the entire RC population, nodule number increased up to 2.0-fold in control cultures and 4.5-fold in cultures containing 10 nM dexamethasone. Continuous subculture experiments in which cultures were split 1:3 every 3 day for up to seven subcultures showed that nodule number decreased in parallel with the split ratio in the absence of dexamethasone, while with dexamethasone nodule number was elevated above the number present in primary cultures for 1 or 2 subcultures after which nodule number decreased with the split ratio. Bone nodules were present for up to 18 population doublings. Measurements of nodule area by automated image analysis showed that dexamethasone increased nodule size and that nodule size decreased from primary to 1st to 2nd subculture with or without dexamethasone. The data suggest that dexamethasone selectively stimulates the proliferation of osteoprogenitor cells and that these progenitor cells have a limited capacity for generating daughter cells capable of expressing the bone phenotype.

Progressive changes in the protein composition of the nuclear matrix during rat osteoblast differentiation

Primary cultures of fetal rat calvarial osteoblasts undergo a developmental sequence with respect to the temporal expression of genes encoding osteoblast phenotypic markers. Based on previous suggestions that gene-nuclear matrix associations are involved in regulating cell- and tissue-specific gene expression, we investigated the protein composition of the nuclear matrix during this developmental sequence by using high-resolution two-dimensional gel electrophoresis. The nuclear matrix was isolated at times during a 4-week culture period that represent the three principal osteoblast phenotypic stages: proliferation, extracellular matrix (ECM) maturation, and mineralization. The most dramatic changes in the nuclear matrix protein patterns occurred during transitions from the proliferation to the ECM maturation stage and from ECM maturation to the mineralization period, with only minor variations in the profiles within each period. These stage-specific changes, corresponding to the major transition points in gene expression, indicate that the nuclear matrix proteins reflect the progressive differentiation of the bone cell phenotype. Subcultivation of primary cells delays mineralization, and a corresponding delay was observed for the nuclear matrix protein patterns. Thus, the sequential changes in protein composition of the nuclear matrix that occur during osteoblast differentiation represent distinct stage-specific markers for maturation of the osteoblast to an osteocytic cell in a bone-like mineralized ECM. These changes are consistent with a functional involvement of the nuclear matrix in mediating modifications of developmental gene expression.

Progressive development of the rat osteoblast phenotype in vitro: reciprocal relationships in expression of genes associated with osteoblast proliferation and differentiation during formation of the bone extracellular matrix

The relationship of cell proliferation to the temporal expression of genes characterizing a developmental sequence associated with bone cell differentiation was examined in primary diploid cultures of fetal calvarial derived osteoblasts by the combined use of autoradiography, histochemistry, biochemistry, and mRNA assays of osteoblast cell growth and phenotypic genes. Modifications in gene expression define a developmental sequence that has 1) three principle periods--proliferation, extracellular matrix maturation, and mineralization--and 2) two restriction points to which the cells can progress but cannot pass without further signals--the first when proliferation is down-regulated and gene expression associated with extracellular matrix maturation is induced, and the second when mineralization occurs. Initially, actively proliferating cells, expressing cell cycle- and cell growth-regulated genes, produce a fibronectin/type I collagen extracellular matrix. A reciprocal and functionally coupled relationship between the decline in proliferative activity and the subsequent induction of genes associated with matrix maturation and mineralization is supported by 1) a temporal sequence of events in which there is an enhanced expression of alkaline phosphatase immediately following the proliferative period, and later, an increased expression of osteocalcin and osteopontin at the onset of mineralization; 2) increased expression of a specific subset of osteoblast phenotype markers, alkaline phosphatase and osteopontin, when proliferation is inhibited by hydroxyurea; and 3) enhanced levels of expression of the osteoblast markers as a function of ascorbic acid-induced collagen deposition, suggesting that the extracellular matrix contributes to both the shutdown of proliferation and the development of the osteoblast phenotype.

A suitable culture medium for ossification of embryonic chick femur in organ culture

To establish a culture medium which allows ossification in organ culture, 9-day-old embryonic chick femurs were cultured in variously supplemented BGJb-HW2 media. Changes of Ca and Pi concentrations in the BGJb-HW2 medium or the 10% addition of chick embryo extract (CEE) did not induce ossification. Furthermore, combinations of the 10% CEE with a high Ca x Pi product or with 5 mM beta-glycerophosphate (beta-GP) or with 10% horse serum plus a high Ca x Pi product often caused pathological abnormalities in the periosteum. On the other hand, BGJb-HW2 medium supplemented with 5 mM beta-GP induced development of ossification. The Ca content of femurs and the diaphysial hydroxyproline content were markedly increased. Histological observation showed a formation of a thick and active periosteum, numerous osteoblastic cells, a sufficient amount of osteoid tissue and well developed calcified trabeculae without any pathological changes. Thus, the organ culture system using this medium was considered to be an appropriate one for studies on osteogenesis in vitro.

Factors that promote progressive development of the osteoblast phenotype in cultured fetal rat calvaria cells

Rat calvaria osteoblasts derived from 21-day-old fetal rat pups undergo a temporal expression of markers of the osteoblast phenotype during a 5 week culture period. Alkaline phosphatase and osteocalcin are sequentially expressed in relation to collagen accumulation and mineralization. This pattern of expression of these osteoblast parameters in cultured rat osteoblasts (ROB) is analogous to that seen in vivo in developing fetal rat calvaria tissue (Yoon et. al: Biochem. Biophis. Res. Commun. 148:1129, 1987) and is similar to that observed in cultures of subcultivated 16-day-old embryonic chick calvaria-derived osteoblasts (COB) (Gerstenfeld, et.al: Dev. Biol. 122:46, 1987). While the cellular organization of subcultivated COB and primary ROB cultures are somewhat different, the temporal expression of the parameters remains. Both the rat and chick culture systems support formation of matrix mineralization even in the absence of beta-glycerol-phosphate. A systematic examination of factors which constitute conditions supporting complete expression of the osteoblast phenotype in ROB cultures indicate requirements for specific serum lots, ascorbic acid and the ordered deposition of mineral in the extracellular matrix. The present studies suggest that formation of a collagenous matrix, dependent on ascorbic acid, is requisite for expression of the osteoblast phenotype. In ROB cultures, expression of osteocalcin synthesis occurs subsequent to initiation of alkaline phosphatase activity and accompanies the formation of mineralized nodules. Thus, extracellular matrix mineralization (deposition of hydroxyapatite) is required for complete development of the osteoblast phenotype, as reflected by a 200-fold increase in osteocalcin synthesis. These data show the temporal expression of the various osteoblast parameters during the formation and mineralization of an extracellular matrix can provide markers reflective of various stages of osteoblast differentiation/maturation in vitro.

In vitro mineralization of osteoblastic cells derived from human bone

Osteoblastic cells were isolated from human maxilla by embedding the bone pieces in collagen gel. The isolated cells could be maintained in monolayer culture up to 50 population doubling levels (PDLs). Both parathyroid hormone (PTH) and prostaglandin E2 (PGE2) increased intracellular cyclic AMP level of the cells. The cells also showed high level of alkaline phosphatase (ALPase) activity and formed mineralized areas in monolayer culture. Electron microscopy demonstrated that these cells were surrounded by numerous well-banded collagen fibrils, among which matrix vesicles were scattered. It was also observed that needle-shaped crystals protruded from some matrix vesicles. These protruded crystals appeared to deposit along the collagen fibrils and a mineralized matrix was formed. The minerals of mineralized matrix mainly consisted of calcium and phosphorus and had the same Ca/P ratio as hydroxyapatite. These results indicate that the cells derived from human bone have characteristics of osteoblastic cells.

The effects of fluoride on osteoblast progenitors in vitro

The number of discrete, three-dimensional bone nodules formed in vitro from a class of osteoprogenitor cells present in fetal rat calvaria cell populations (RC cells) is linearly related to the number of cells plated, implying that this system functions as a colony assay for the expression of osteoprogenitor cells. To determine the effect of fluoride on the expression of these cells, primary RC cells were grown for periods of up to 21 days in alpha-MEM (minimal essential medium) containing 5-15% heat-inactivated fetal bovine serum (FBS), 50 micrograms/ml ascorbic acid, 10 mM Na beta-glycerophosphate, and NaF at concentrations from 10 microM to 5 mM. The continuous presence of NaF resulted in an increase in the number of bone nodules with maximal response occurring at 500 microM (p less than 0.001). A similar response at 500 microM NaF was observed also with regard to alkaline phosphatase activity. NaF levels up to 500 microM did not affect the growth of the mixed RC cell population, however, higher concentrations (1 mM) significantly reduced cell numbers (p less than 0.001) suggestive of cytotoxicity. Plating efficiency tests for colony formation in the presence of 0.5 to 2 mM NaF showed that the decreases in nodule formation observed at concentrations above 500 microM correlated with cytotoxicity. NaC1 at 1 mM had no effect on nodule formation, alkaline phosphatase activity, or cell growth. The results show that NaF stimulates osteoprogenitor cell number in vitro and that the maximal effect occurs at concentrations close to toxic levels.

Effects of donor age on osteogenic cells of rat bone marrow in vitro

The effect of donor age on the production of bone-like tissue and expression of cellular alkaline phosphatase was examined in cultures of cells obtained from rat bone marrow. Stromal cells were obtained from the bone marrow of young (5-6 weeks) and old (18 months) rats and cultured in vitro. After 28 days in first subculture, the following were quantified: (1) the total number of mineralised nodules and the size distribution of nodules and (2) the density of osteoblasts and osteocytes associated with nodules in histological sections. The doubling times of the cultures and the numbers of cells in cultures which expressed alkaline phosphatase activity were determined in separate experiments. Cells from young cultures produced three times more bone-like nodules than old cultures, although no differences were seen in the size distribution of nodules, or on osteoblast and osteocyte density. Doubling times for both groups were similar. The numbers of alkaline phosphatase (AP) positive cells was reduced by half in old cultures. These data show that this model may be useful for the study of the mechanisms of ageing on osteogenesis, and demonstrate a reduced osteogenic capacity in old cultures. The results suggest that this effect may be due to a reduction in the generation of cells of osteoblast lineage during ageing.

Direct modulatory effect of hexasodium N,N,N',N'-ethylenediamine-tetramethylene-phosphonate on bone cell function in vitro

The phosphonate hexasodium N,N,N',N'-ethylenediamine-tetramethylenephosphonate (EDITEMP.Na6) reduced alkaline phosphatase (Alp) activity and cAMP response to parathyroid hormone (PTH) in primary cultures of foetal rat calvaria cells in a dose-dependent manner, while not affecting culture DNA content. EDITEMP.Na6 also inhibited the mineralization of three-dimensional bone nodules formed in vitro, but not the number of nodules formed. Bone cell culture DNA content was also reduced by EDITEMP.Na6 but at concentrations in excess of those needed to modulate osteoblastic cell function. Withdrawal of EDITEMP.Na6 led to slow but complete recovery of Alp activity. At EDITEMP.Na6 concentrations of 25 microM and higher, recovery of Alp activity appeared to be independent of protein and/or DNA synthesis. Cell culture acid phosphatase (Acp) activity was not affected by EDITEMP.Na6. The results indicate that EDITEMP.Na6 has a direct inhibitory effect on (mature) osteoblastic cell function. In the presence of bone tissue this inhibition also occurred, although not at a relatively low dose level.

Bone conditioned medium enhances cell aggregation, cell proliferation and alkaline phosphatase activity in serum-deprived medium

The effect of medium conditioned by whole bone was examined on the activity of a heterogeneous population of rat calvarial cells grown under serum-deprived conditions. Conditioned medium (CM) had pronounced effects on the appearance of cultures within 24-48 hours of addition. This was characterized by the breakdown of the cell monolayer, rounding of cells and formation of alkaline phosphatase-positive aggregates. Cellular alkaline phosphatase activity was increased compared to controls while acid phosphatase levels were reduced. These aggregates grown in the presence of 10 mM beta-glycerophosphate did not show evidence of mineralization. These results show that soluble factors derived from calvarial bone are responsible for cell aggregation, cell proliferation and increase in alkaline phosphatase activity.

Bone formation by osteoblast-like cells in a three-dimensional cell culture

Cells of the clonal osteogenic cell line MC3T3-E1 were seeded onto a three-dimensional matrix of denatured collagen type 1 and cultured for a period of up to 8 weeks. Specimens were analyzed by histological, enzyme histochemical, immunocytochemical, and ultrastructural methods and by in situ hybridization between day 7 and day 56 after seeding. In 56-day cultures, the MC3T3-E1 cells were arranged in a three-dimensional network and formation of bone-like tissue was indicated by calcification of a newly synthesized collagen type I matrix resembling osteoid and surrounding osteocyte-like cells. The differentiating culture showed high expression of osteocalcin and alkaline phosphatase activity. NIH3T3 fibroblasts used as control cells passed through the network of the substrate forming a confluent monolayer underneath. This culture system offers a potentially powerful model for bone formation in vitro and for investigating the osteogenic potential of bone-derived cells.

An immortalized osteogenic cell line derived from mouse teratocarcinoma is able to mineralize in vivo and in vitro

The hybrid plasmid pK4 containing the early genes of the simian virus SV-40, under the control of the adenovirus type 5 E1a promoter, was introduced into the multipotent embryonal carcinoma (EC) 1003. Expression of the SV-40 oncogenes was observed at the EC cell stage, and this allowed the derivation of immortalized cells corresponding to early stages of differentiation. Among the immortalized mesodermal derivatives obtained, one clone, C1, is committed to the osteogenic pathway. C1 cells have a stable phenotype, synthesize type I collagen, and express alkaline phosphatase activity. Although immortalized and expressing the SV-40 T antigen, the cells continue to be able to differentiate in vivo and in vitro. In vivo, after injection into syngeneic mice, they produce osteosarcomas. In vitro, the cells form nodules and deposit a collagenous matrix that mineralizes, going to hydroxyapatite crystal formation, in the presence of beta-glycerophosphate. This clonal cell line, which originates from an embryonal carcinoma, therefore differentiates into osteogenic cells in vivo and in vitro. This immortalized cell line will be useful in identifying specific molecular markers of the osteogenic pathway, to investigate gene regulation during osteogenesis and to study the ontogeny of osteoblasts.

Forskolin has biphasic effects on osteoprogenitor cell differentiation in vitro

Cells isolated from fetal rat calvaria (RC) and maintained in vitro in medium containing ascorbic acid and B-glycerophosphate form three-dimensional, mineralized nodules having the histological, immunohistological, and ultrastructural characteristics of woven bone. We have studied the effects of forskolin (FSK), a diterpene that activates adenylate cyclase, in this system. While 10(-7)-10(-5) M FSK significantly stimulated cAMP levels in RC cells, lower concentrations did not. cAMP levels with 10(-5) M FSK reached a maximum by 30 min at 37 degrees C and returned to basal level in 2-3 hr. Changes in cAMP levels correlated with changes in cellular shape: cells treated with 10(-5) M FSK assumed a stellate morphology, lost microfilament bundles, and reduced their substrate adhesiveness, while cells treated with 10(-9) M were not affected. Exponential growth and saturation densities of FSK-treated cultures were similar to untreated cultures, indicating that FSK was neither toxic nor stimulatory to the population. The effect on bone nodule formation of FSK present continuously depended on concentration: 10(-5) M FSK significantly inhibited the number of nodules formed, while 10(-9) M FSK significantly stimulated bone nodule formation. Single short treatments with either 10(-5) M or 10(-9) M FSK had no effect on nodule formation, but repeated short duration treatments (1 hr every 2 days for 21 days) gave results similar to continuous exposure. These results indicate that intermittent elevations in intracellular cAMP have an inhibitory effect on bone formation. In addition, our work indicates that low concentrations of FSK stimulate differentiation of osteoprogenitor cells possibly through a non-cAMP-dependent process.

Regulation of bone sialoprotein mRNA by steroid hormones

In this report we demonstrate an increase in the steady-state level of bone sialoprotein (BSP) mRNA in rat calvaria and a rat osteosarcoma cell line (ROS 17/2.8) after treatment with the synthetic glucocorticoid, dexamethasone. In contrast, 1.25-dihydroxyvitamin D3 reduced the amount of BSP mRNA in calvaria and inhibited the dexamethasone induction in ROS 17/2.8 cells. The increase in BSP mRNA is most likely due to an increase in the transcriptional rate. The stability of mRNA was unchanged after dexamethasone treatment with a half-life of approximately 5 h. Nuclear transcription experiments with nuclei isolated from ROS 17/2.8 cells showed an increased BSP mRNA synthesis in cells treated with dexamethasone.

Stimulation of the expression of osteogenic and chondrogenic phenotypes in vitro by osteogenin

Osteogenin was recently purified and the amino acid sequences of tryptic peptides were determined. Osteogenin in conjunction with insoluble collagenous bone matrix induces cartilage and bone formation in vivo. To understand the mechanism of action of osteogenin, we examined its influence on periosteal cells, osteoblasts, fibroblasts, chondrocytes, and bone marrow stromal cells in vitro. Osteogenin stimulated alkaline phosphatase activity and collagen synthesis in periosteal cells. The cAMP response to parathyroid hormone in periosteal cells was increased by osteogenin. In primary cultures of calvarial osteoblasts, osteogenin stimulated alkaline phosphatase activity, the cAMP response to parathyroid hormone, and the synthesis of collagenous and noncollagenous proteins; however, cell proliferation was not affected. Osteogenin increased the production of sulfated proteoglycans in fetal rat chondroblasts and in rabbit articular chondrocytes. The present experiments demonstrate the significant influence of osteogenin in the stimulation of osteogenic and chondrogenic phenotypes in vitro.

High-affinity sodium-dependent uptake of ascorbic acid by rat osteoblasts

Ascorbic acid is essential for the formation of bone by osteoblasts, but the mechanism by which osteoblasts transport ascorbate has not been investigated previously. We examined the uptake of L-[14C]ascorbate by a rat osteoblast-like cell line (ROS 17/2.8) and by primary cultures of rat calvaria cells. In both systems, cells accumulated L-[14C]ascorbate during incubations of 1-30 min at 37 degrees C. Unlike propionic acid, which diffuses across membranes in protonated form, ascorbic acid did not markedly alter cytosolic pH. Initial ascorbate uptake rate saturated with increasing substrate concentration, reflecting a high-affinity interaction that could be described by Michaelis-Menten kinetics (apparent Km = 30 +/- 2 microM and Vmax = 1460 +/- 140 nmol ascorbate/g protein/min in ROS 17/2.8 cells incubated with 138 mM extracellular Na+). Consistent with a stereoselective carrier-mediated mechanism, unlabeled L-ascorbate was a more potent inhibitor (IC50 = 30 +/- 5 microM) of L-[14C]ascorbate transport than was D-isoascorbate (IC50 = 380 +/- 55 microM). Uptake was dependent on both temperature and Na+, since it was inhibited by cooling to 4 degrees C and by substitution of K+, Li+ or N-methyl-D-glucamine for extracellular Na+. Decreasing the external Na+ concentration lowered both the affinity of the transporter for ascorbate and the apparent maximum velocity of transport. We conclude that osteoblasts possess a stereoselective, high-affinity, Na+-dependent transport system for ascorbate. This system may play a role in the regulation of bone formation.

The regulatory effect of phosphates on bone metabolism in vitro

One of the most important indicators in vitro of the bone-cell phenotype is the synthesis of mineralized bone-like tissue. This has been achieved by supplementing isolated bone-cell and tissue cultures with organic phosphates, in particular, beta-glycerophosphate. To analyze the effects of beta-glycerophosphate on bone-cell metabolism and osteogenesis in vitro, both biochemical analyses and computer-assisted morphometry were used. Simultaneous autoradiographic and histochemical analyses of proliferating and alkaline phosphatase-positive cells were used to measure osteogenic events at the cellular level. Morphometric data showed that beta-glycerophosphate-treated cultures mineralized, but exhibited significantly less bone matrix (P less than 0.05) than non-mineralizing controls. Cultures treated with inorganic phosphate failed to mineralize. Cellular proliferation was unaffected by beta-glycerophosphate; however, there was a decrease in the amount of 3H-thymidine incorporation into the DNA of beta-glycerophosphate-treated cells as detected by autoradiography. The percentage of alkaline phosphatase-positive cells was identical in beta-glycerophosphate-treated or control cultures. In agreement with previous biochemical results, there was a decrease in the amount of alkaline phosphatase enzyme activity per cell. The kinetics of alkaline phosphatase enzymes were measured on individual cells by microdensitometry. beta-Glycerophosphate-treated cultures exhibited more rapid reaction rates than control cultures (p less than 0.05). Taken together, the results suggest that beta-glycerophosphate has global effects on bone-cell metabolism in vitro including its importance in mineralization.

Expression of the chondrogenic phenotype by mineralizing cultures of embryonic chick calvarial bone cells

Cells released by sequential enzymatic digestion of 18-day chick calvariae were cultured over a 4-5 week period in Alpha modified Eagles medium. In some cultures the medium was supplemented with ascorbate and/or Na-beta-glycerophosphate. Microscopic examination of these cultures showed both polygonal and spindle-shaped cells. The biochemical nature of these cells was investigated by incubating the cultures with radiolabelled proline and subsequently analysing the medium and cell layer proteins by SDS/PAGE and fluorography. Osteoblast and chondrocyte-containing cultures were clearly distinguished in this way as the former cells secreted type I collagen while the latter secreted types II and X collagens as the major medium macromolecules. Type X collagen synthesis occurred after 14 days, but only in cultures supplemented with both ascorbate and Na-beta-glycerophosphate, and was maintained for the duration of the culture period. Unsupplemented cultures and those containing either ascorbate alone or Na-beta-glycerophosphate alone failed to synthesize type X collagen after 28 days. Isolated cells pulsed with radiolabelled proline at confluence and organ cultures of embryonic chick calvaria synthesized types I and V collagens only. These data demonstrate that the expression of phenotype by heterogeneous populations of bone cells could be modulated by a combination of culture conditions including the length of time in culture and conditions favourable for the formation of a mineralized matrix.

Effects of transforming growth factor beta and epidermal growth factor on cell proliferation and the formation of bone nodules in isolated fetal rat calvaria cells

When cells enzymatically isolated from fetal rat calvaria (RC cells) are cultured in vitro in the presence of ascorbic acid and Na beta-glycerophosphate, discrete three-dimensional nodules form with the histologic, immunohistochemical, and ultrastructural characteristics of bone (Bellows et al; Calcified Tissue International 38:143-154, 1986; Bhargava et al., Bone, 9:155-163, 1988). Quantitation of the number of bone nodules that forms provides a colony assay for osteoprogenitor cells present in the RC population (Bellows and Aubin, Develop. Biol., 133:8-13, 1989). Continuous culture with either epidermal growth factor (EGF) or transforming growth factor beta (TGF-beta) results in dose-dependent inhibition of bone nodule formation; however, the former causes increased proliferation and saturation density, while the latter reduces both parameters. Addition of EGF (48 h pulse, 2-200 ng/ml) to RC cells at day 1 after plating results in increased proliferation and population saturation density and an increased number of bone nodules formed. Similar pulses at confluence and in postconfluent multilayered cultures when nodules first begin forming (approx. day 11) inhibited bone nodule formation and resulted in a smaller stimulation of cell proliferation. Forty-eight hour pulses of TGF-beta (0.01-1 ng/ml) reduced bone nodule formation and proliferation at all times examined, with pulses on day 1 causing maximum inhibition. The effects of pulses with TGF-beta and EGF on inhibition of nodule formation are independent of the presence of serum in the culture medium during the pulse. The data suggest that whereas EGF can either stimulate or inhibit the formation of bone nodules depending upon the time and duration of exposure, TGF-B inhibits bone nodule formation under all conditions tested. Moreover, these effects on osteoprogenitor cell differentiation do not always correlate with the effects of the growth factors on RC cell proliferation.

Bone marrow-derived stromal cell line expressing osteoblastic phenotype in vitro and osteogenic capacity in vivo

Marrow stroma has been shown to have osteogenic potential. Here we report the characterization of a unique stromal cell line derived from mouse bone marrow (MBA-15), which expresses osteoblastic phenotype in vitro and forms bone in vivo. More than 70% of cells in culture were histochemically positive for alkaline phosphatase. The enzyme levels were enhanced threefold when cultures were treated with dexamethasone. Gel electrophoresis of [3H]-proline-labeled cultures showed that MBA-15 cells produced only type I collagen. These cells were responsive to PTH, as indicated by a 50-fold increase in intracellular cAMP. Prostaglandin E2, but not calcitonin, stimulated cAMP up to 70-fold. When cultures were grown to confluence and fed daily with ascorbic acid and beta-glycerophosphate, the cells formed a Von Kossa positive, thick extracellular matrix, shown to contain hydroxyapatite crystals. MBA-15 cells produced mineralized bone when implanted in diffusion chambers. These results indicate that the MBA-15 cell line possesses osteoblastic features in vitro and osteogenic capacity in vivo.

In vitro mineralization of fetal rat parietal bones in defined serum-free medium: effect of beta-glycerol phosphate

We have developed a bone organ culture system that mineralizes in vitro. Fetal rat parietal bones (20 days old) were cultured in a chemically defined serum-free medium containing physiological 3 mM phosphate. During 5 days in culture, calcium content increased from 26 to 55 micrograms and dry weight increased from 137 to 194 micrograms. After 2 days in vivo, the calcium content of the parietal bone showed a comparable increase to 49 micrograms and dry weight increased to 183 micrograms. During culture, the mineralized bone area in thick sections increased from 11 to 23%, which paralleled the doubling in calcium content. Fluorescent calcein labeling during the 5 day culture period demonstrated that calcification occurs in an ordered pattern. Protein synthesis was assessed by measuring incorporation of [3H]proline into collagenase-digestible protein (CDP) and noncollagen protein (NCP). The percentage collagen synthesis decreased from 17.5% at 0 time to 5.0% at 2 days and then increased to 9.4% at 5 days of culture. Varying the inorganic phosphate concentration in the medium or adding beta-glycerol phosphate was found to affect mineralization. After 5 days in culture, bones treated with 1 mM phosphate exhibited a large region of unmineralized osteoid with only a 23% increase in calcium content compared with 112% in control (3 mM phosphate) bones and a 28% increase in dry weight compared with a 40% increase in control. Treatment for 5 days with 6 mM phosphate or 1, 3, or 10 mM beta-glycerol phosphate had no significant effect on dry weight compared to control bones. However, bone calcium content increased significantly from 55 +/- 5 micrograms in control cultures to 105 +/- 7 with 6 mM phosphate, 74 +/- 6 with 3 mM beta-glycerol phosphate, and 75 +/- 5 micrograms with 10 mM beta-glycerol phosphate. Calcified area measured by histomorphometry was also significantly greater than in control bones, but this was mainly due to ectopic calcification in the periosteum, representing from 23 to 74% of the total increase in calcified matrix in bones cultured with 6 mM phosphate or 1-10 mM beta-glycerol phosphate. Ultrastructural analysis demonstrated that ectopic calcification was associated with cell death and debris. Therefore, calcification with beta-glycerol phosphate and high concentrations of inorganic phosphate differed from mineralization in vivo or in bones cultured with a physiologically concentration of phosphate.

Determination of numbers of osteoprogenitors present in isolated fetal rat calvaria cells in vitro

When maintained in long-term cell culture in the presence of ascorbic acid and organic phosphate, single cell suspensions isolated from fetal rat calvaria form discrete, three-dimensional bone nodules. We have used limiting dilution analysis in microtiter wells to determine the number of osteoprogenitor cells expressing the capacity to form bone in the isolated mixed population, to examine the possibility of cooperativity among cell types in bone nodule formation, and to determine the effects of dexamethasone on osteoprogenitor cells. Cells plated at very low densities and screened for the presence or absence of bone nodules revealed a linear relationship (r = -00.997) between the number of cells plated and the number of bone nodules formed. The complete limiting dilution analyses showed that 1 of every 335 plated cells (0.30% of the cell population) has the capacity to form a bone nodule under standard culture conditions and when the actual numbers of nodules were quantitated from the same plated cell populations the ratio of nodules formed to plated cells was similar. Comparison of data from 13 different isolates of cells in which cells were plated into 35-mm dishes and number of nodules were determined indicated a mean +/- 95% confidence interval of one nodule for every 301 +/- 61 plated cells, consistent with the data obtained from the limiting dilution experiments. Dexamethasone increased the number of bone-forming cells to 1 in 225 cells, in contrast to 1 in 340 cells in the same population grown without added dexamethasone. The results suggest that approximately 0.30% of the cells in isolated rat calvaria populations are osteoprogenitor cells, that one osteoprogenitor cell gives rise to one bone nodule, that cooperativity between different cells in vitro is not necessary for bone formation, and that dexamethasone stimulates the expression of osteoprogenitor cells.

Site-specific regulation of osteogenesis: maintenance of discrete levels of phenotypic expression in vitro

Intrinsic differences in bone formation rate, cell numbers, and the percentages of cells expressing alkaline phosphatase activity were studied in explants of chick calvaria periosteum cultured for 4 days and 6 days. Proliferation, differentiation, and bone production were examined in radioautographs of plastic sections and by using whole-culture biochemical assays of protein and alkaline phosphatase. Ectocranial explants at both 4 days and 6 days exhibited more alkaline phosphatase-positive cells and significantly more bone formation than endocranial cultures. There were no detectable differences in cell numbers or 3H-thymidine labeling indices. The volume of bone synthesized per osteoblast was significantly higher in the ectocranial group. Examination of bone stripped of periostea and then cultured for 4 days revealed that large areas of bone were covered by osteoblasts, indicating that the periosteal explant cultures were composed almost exclusively of osteoprogenitor cells and fibroblasts. The data suggest that the level of expression of predetermined osteogenic phenotypes can be maintained in vitro for 6 days following explantation and that variations in the rate of osteogenesis are programmed into progenitor cells prior to their differentiation into osteoblasts.

Osteocalcin: characterization and regulated expression of the rat gene

An osteocalcin gene was isolated from a rat genomic DNA library, and sequence analysis indicated that the mRNA is represented in 953 nucleotide segment of DNA consisting of 4 exons and 3 introns. Although the introns in the rat gene are larger, its overall organization is similar to the human gene. Analysis of the 5' flanking sequences of the rat gene shows a modular organization of the promotor as reflected by the the presence of at least 3 classes of regulatory elements. These include (1) typical sequences associated with most genes transcribed by RNA polymerase II (e.g. TATA, CAAT, AP1, AP2), (2) a series of consensus sequences for cyclic nucleotide responsive elements and several hormone receptor binding-sites (estrogen, thyroid and clusters of AG-rich putative Vitamin D responsive elements); and (3) a 24 nucleotide highly conserved sequence between the rat and human gene having a CAAT motif as a central element, designated as an "osteocalcin box." Two regulatory factors of osteocalcin gene expression have been identified. First, contained within the 600 nucleotides immediately upstream from the transcription initiation site are sequences which support Vitamin D dependent transcription of the rat osteocalcin gene. 1,25(OH)2D3 increases osteocalcin mRNA by 6-20 fold increases. In contrast, up to a 200 fold increase in osteocalcin gene expression occurs with mineralization of the extracellular matrix produced by osteoblasts. We propose osteocalcin is a bone-specific marker protein of the mature osteoblast in a mineralizing matrix.

The onset and progression of osteoblast differentiation is functionally related to cellular proliferation

The relationship of proliferation to the developmental sequence associated with bone cell differentiation was examined in primary osteoblast cultures derived from fetal rat and embryonic chick calvaria. A reciprocal and functional relationship exists between the decline in proliferative activity which occurs during the initial stages of the developmental sequence and the induction of genes encoding osteoblast phenotype proteins associated with matrix maturation and mineralization. This relationship is supported by 1) a temporal sequence of events in which there is an enhanced expression of alkaline phosphatase (AP) and osteopontin (OP) genes immediately following the proliferative period and expression of osteocalcin with the onset of mineralization, and 2) increases in AP and OP when DNA synthesis is inhibited. By determining cellular mRNA levels and rates of mRNA synthesis in isolated nuclei, we found that the down-regulation of cell growth-related genes is modified at both the levels of transcription and mRNA stability. For a histone gene where down-regulation is transcriptionally mediated, we have observed that the shutdown of osteoblast proliferation is associated with the selective loss of the interaction of a promoter binding factor (HiNF-D) with a proximal regulatory element (Site II). A relationship between Site II occupancy by HiNF-D and the onset of osteoblast differentiation is supported by the persistence of Site II-HiNF-D interactions when proliferating rat osteoblasts are growth arrested under conditions that do not induce differentiation; and additionally, by the loss of Site II-HiNF-D interactions during the shut-down of proliferation when HL60 promyelocytic leukemia cells are induced to differentiate into monocytes. Our results are consistent with a requirement of proliferation for expression of genes involved with production, deposition and possibly organization of the osteoblast extracellular matrix. It is also reasonable to postulate that properties of the mineralizing matrix are related to the shut-down of proliferation.

Immunohistochemical studies using BRL 12, a monoclonal antibody reacting specifically with osteogenic tissues

A monoclonal antibody of immunoglobulin class G1 has been produced which reacts with a high molecular weight antigen apparently present exclusively in osteogenic tissues. Immunohistochemical studies have shown that the antigen is present throughout the mineralized matrix and in osteoid. None of the other tissues examined namely liver, intestine, kidney, spleen, thymus, heart, lung, skin, cartilage and skeletal muscle showed evidence of specific antibody binding. Immunohistochemical staining was also demonstrated in tissues developing from rabbit marrow cultured in vitro and in diffusion chambers in vivo. Temporal studies of antigen expression in the chambers indicated that the antigen occurs at sites of bone formation after the appearance of alkaline phosphatase but before the formation of a mineralized matrix. The results of these studies suggest that the monoclonal antibody recognises a product of differentiated osteoblasts. This antibody may therefore prove useful in studies of osteogenic differentiation.

Growth of osteoblasts on porous calcium phosphate ceramic: an in vitro model for biocompatibility study

Biomaterial implantation in animals is commonly used for biocompatibility studies as well as examination of long-term interaction between tissue and the test material. An in vitro cell culture model is proposed as an alternative which will save animal lives and reduce the pain and discomfort of animals used for such studies. In this study the biomaterial was matched to the cell types typical of the implant site of the particular material: porous calcium phosphate ceramic, used as dental and orthopaedic implants, with periosteal fibroblasts, osteoblasts and chondrocytes. All three cell types attached on to the ceramic and formed multicellular layers. Numbers of periosteal fibroblasts, osteoblasts and chondrocytes increased 29-, 23- and 17-fold, respectively, during the 10 wk period. Osteoblasts retained their phenotypic expression by producing only Type I collagen. Parathyroid hormone (PTH, 50 nM) suppressed the alkaline phosphatase activity of osteoblasts by over 50% and increased cAMP by more than 10-fold over control cultures.

Microcinematographic and autoradiographic kinetic studies of bone cell differentiation in vitro: matrix formation and mineralization

Matrix formation and mineralization have been reported in vitro with cells isolated from rat calvaria bones by collagenase digestion (Nefussi et al., 1985). In the current study, kinetics of bone nodule formation and osteoblastic cell differentiation were studied in this in vitro system using an improved microcinematographic device and flash and follow-up labeling autoradiographic techniques. Microcinematographic analysis showed the formation of bone nodules within 24 h. The initial event observed was the change in the top cells layer which became alkaline phosphatase positive. Matrix synthesis occurred a few hours after this. The autoradiographic results demonstrated the formation of an integrated system where osteoblasts and osteocytes were active and synthesized a collagen matrix and mineralized it in a similar time sequence than in vivo.

Effect of immune cytokines on bone

The effect of the bone resorptive cytokines IL-1 alpha, IL-1 beta, and TNF on bone formation was studied in an in vitro system. All three cytokines were profoundly inhibitory, with the rank order of potency IL-1 beta greater than IL-1 alpha greater than TNF. Inhibition was mediated by a depression of differentiated osteoblast functions, including alkaline phosphatase expression and matrix synthesis. Osteoblast proliferation was not affected. Bone formation inhibition was independent of PGE2 production, indicating a direct effect of cytokines on osteoblasts. High concentrations of IL-1 beta (10 U/ml) abrogated IGF-1-stimulated bone formation, providing evidence for the hypothesis that cytokines act as 'uncoupling factors'. Conversely, high concentrations of IGF-1 circumvented inhibition by IL-1 beta (0.1-1.0 U/ml). The interaction of cytokines and bone growth factors with osteoblasts are likely to be of critical importance in the regulation of bone mass at local inflammatory sites.

A comparative ultrahistochemical study of glycosaminoglycans with cuprolinic blue in bone formed in vivo and in vitro

Histochemical and morphological studies have shown that proteoglygans (PG) are involved in mineralization process in vivo but such studies have not yet been conducted in vitro. A comparative histochemical study in electronic microscopy of the localization, organization, and morphology of the PG was performed with bones of calvaria rat formed in vivo and bone nodules formed in vitro from osteoblastic cells in culture. For this investigation, we used a cationic phthalocyanin dye, cuprolinic blue, in a critical electrolyte concentration which simultaneously stained the glycosaminoglycans and demineralized the bone. This histochemical technique demonstrated (1) osteoblast cells in vitro synthesized PG which were included in the matrix formed. (2) These PG were found in the calcified and uncalcified matrix both in vivo and in vitro. In the uncalcified matrix, PG were either free with a granular or rodlike structure or tightly connected to the periphery of the collagen fiber. Contrarily, in the calcified matrix, PG formed dense filamentous reticular patches between the collagen fibers. (3) Similarities in localization, organization, and morphology were noted in PG of bone formed de novo in vitro and in vivo with the exception of the mineralization front, where the staining in vivo compared with in vitro was faint or absent.

Bone formation by rat calvarial cells grown at high density in organoid culture

Calvarial cells from day 21 rat fetuses were isolated by enzymatic digestion and grown at high density in an organoid culture system at the medium/air interface. In this type of culture, mineralization occurred as early as 7 days in vitro, as revealed by light and electron microscopic means. After about 18 days in vitro, most of the culture consisted of mineralized tissue. Mineralization was also achieved without beta-glycerophosphate, but it was delayed by 2 to 3 days. Maximal alkaline phosphatase activity occurred at days 8 to 12 in vitro and then declined continuously during further cultivation. Two types of mineralization could be observed: (1) mineralization of a collagen-rich osteoid by typical apatite crystals; (2) mineralization of a nearly collagen-free matrix by amorphous material which was possibly secreted by the cells. The importance of higher cell densities for cell differentiation and formation of histotypic tissue in vitro is apparent, and it is indicated that cell-cell contacts and cell-matrix interactions may be prerequisites for the development of histotypic conditions similar to the in vivo situation.

Bone formation in vitro by stromal cells obtained from bone marrow of young adult rats

Cells from fetal or neonatal skeleton can synthesize bone-like tissue in vitro. In contrast, formation of bone-like tissue in vitro by cells derived from adult animals has rarely been reported and has not been achieved using cells from bone marrow. We have explored development of bone-like tissue in vitro by bone marrow stromal cells. Marrow stromal cells obtained from 40-43-day-old Wistar rats were grown in primary culture for 7 days and then subcultured for 20-30 days. Cells were cultured in either alpha-minimal essential medium containing 15% fetal bovine serum, antibiotics, and 50 micrograms/ml ascorbic acid, or the above medium supplemented with either 10 mM Na-beta-glycerophosphate, 10(-8) M dexamethasone, or a combination of both. Cultures were examined using phase-contrast microscopy, undemineralized and demineralized tissue histology, histochemistry (for alkaline phosphatase activity), immunohistochemistry (for collagen type, osteonectin, and bone Gla-protein), scanning and transmission electron microscopy, energy dispersive X-ray microanalysis, and X-ray diffraction. Collagenous, mineralized nodules exhibiting morphological and ultrastructural characteristics similar to bone were formed in the cultures, but only in the presence of both beta-glycerophosphate and dexamethasone. Cells associated with the nodules exhibited alkaline phosphatase activity. The matrix of the nodules was composed predominantly of type-I collagen and both osteonectin and Gla-protein were present. X-ray microanalysis showed the presence of Ca and P, and X-ray diffraction indicated the mineral to be hydroxyapatite. The nodules were also examined for bone morphogenetic protein-like activity. Paired diffusion chambers containing partly demineralized nodules and fetal muscle were implanted intraperitonealy in rats. Induction of cartilage in relation to muscle was observed histologically after 40 days in the chambers. This finding provided further support for the bone-like nature of the nodules. The observations show that bone-like tissue can be synthesized in vitro by cells cultured from young-adult bone marrow, provided that the medium contains both beta-glycerophosphate and, particularly, dexamethasone.

Differentiation of muscle, fat, cartilage, and bone from progenitor cells present in a bone-derived clonal cell population: effect of dexamethasone

RCJ 3.1, a clonally derived cell population isolated from 21-d fetal rat calvaria, expresses the osteoblast-associated characteristics of polygonal morphology, a cAMP response to parathyroid hormone, synthesis of predominantly type I collagen, and the presence of 1,25-dihydroxyvitamin D3-regulated alkaline phosphatase activity. When cultured in the presence of ascorbic acid, sodium beta-glycerophosphate, and the synthetic glucocorticoid dexamethasone, this clone differentiated in a time-dependent manner into four morphologically distinct phenotypes of known mesenchymal origin. Multinucleated muscle cells were observed as early as 9-10 d in culture, lipid-containing adipocytes formed after 12 d, chondrocyte nodules were observed after 16 d, and mineralized bone nodules formed after 21 d in culture. The differentiated cell types were characterized morphologically, histochemically, and immunohistochemically. The formation of adipocytes and chondrocytes was dependent upon the addition of dexamethasone; the muscle and bone phenotypes were also expressed at low frequency in the absence of dexamethasone. The sex steroid hormones progesterone and 17 beta-estradiol had no effect on differentiation in this system, suggesting that the effects of dexamethasone represent effects specific for glucocorticosteroids. Increasing concentrations of dexamethasone (10(-9)-10(-6) M) increased the numbers of myotubes, adipocytes, and chondrocytes; however, when present continuously for 35 d, the lower concentrations appeared to better maintain the muscle and adipocyte phenotypes. Bone nodules were not quantitated because the frequency of bone nodule formation was too low. Single cells obtained by plating RCJ 3.1 cells at limiting dilutions in the presence of dexamethasone, were shown to give rise to subclones that could differentiate into either single or multiple phenotypes. Thus, the data suggest that this clonal cell line contains subpopulations of mesenchymal progenitor cells which can, under the influence of glucocorticoid hormones, differentiate in vitro into four distinct cell types. It is, therefore, a unique cell line which will be of great use in the study of the regulation of mesenchymal stem cell differentiation.

Collagen expression, ultrastructural assembly, and mineralization in cultures of chicken embryo osteoblasts

A newly defined chick calvariae osteoblast culture system that undergoes a temporal sequence of differentiation of the osteoblast phenotype with subsequent mineralization (Gerstenfeld, L. C., S. Chipman, J. Glowacki, and J. B. Lian. 1987. Dev. Biol. 122:49-60) has been examined for the regulation of collagen synthesis, ultrastructural organization of collagen fibrils, and extracellular matrix mineralization. Collagen gene expression, protein synthesis, processing, and accumulation were studied in this system over a 30-d period. Steady state mRNA levels for pro alpha 1(I) and pro alpha 2 collagen and total collagen synthesis increased 1.2- and 1.8-fold, respectively, between days 3 and 12. Thereafter, total collagen synthesis decreased 10-fold while mRNA levels decreased 2.5-fold. In contrast to the decreasing protein synthesis after day 12, total accumulated collagen in the cell layers increased sixfold from day 12 to 30. Examination of the kinetics of procollagen processing demonstrated that there was a sixfold increase in the rate of procollagen conversion to alpha chains from days 3 to 30 and the newly synthesized collagen was more efficiently incorporated into the extracellular matrix at later culture times. The macrostructural assembly of collagen and its relationship to culture mineralization were also examined. High voltage electron microscopy demonstrated that culture cell layers were three to four cells thick. Each cell layer was associated with a layer of well developed collagen fibrils orthogonally arranged with respect to adjacent layers. Fibrils had distinct 64-70-nm periodicity typical of type I collagen. Electron opaque areas found principally associated with the deepest layers of the fibrils consisted of calcium and phosphorus determined by electron probe microanalysis and were identified by electron diffraction as a very poorly crystalline hydroxyapatite mineral phase. These data demonstrate for the first time that cultured osteoblasts are capable of assembling their collagen fibrils into a bone-specific macrostructure which mineralizes in a manner similar to that characterized in vivo. Further, this matrix maturation may influence the processing kinetics of the collagen molecule.

Calcium incorporation in cultured chondroblasts perturbed by an electromagnetic field

We tested the hypothesis that electric perturbation influences 45Ca incorporation in extracellular matrix (ECM) of cartilage in vitro. Hypertrophic chondroblasts of tibial epiphyses (HC), sternum (SC), and skin fibroblasts (F) were cultured from chick embryos. HC, SC, and F cells were micromass seeded three times per week and maintained at 37.5 degrees C with 5% CO2 for two weeks. Cultures were randomly designated control (C) or exposed (E) to a pulsed electromagnetic field (PEMF). A time course experiment of calcium incorporation for all cultured groups showed that 24 h of exposure produced the largest biological response in chondroblasts. Calcium incorporation required supplemental phosphate. Autoradiography data indicated that the calcium incorporation into macromolecules largely occurred in the ECM. 45Ca steady-state perturbation was enhanced by Streptomyces hyaluronidase (SH) but not by testicular hyaluronidase (TH). 45Ca incorporation experiments tested the effects of phosphate, SH, TH, and PEMF alone and in various combinations on these cultures. Only PEMF or SH plus PEMF with phosphate enhanced 45Ca incorporation. Other experiments examined the effect of rotenone or freeze-thawing on cells exposed to PEMF. PEMF plus freeze-thaw enhanced calcium incorporation in HC only. PEMF appeared to cause disruption of the ECM, enhancing the probability of matrix calcification.

Mineralization in osteoblast cultures: a light and electron microscopic study

Osteoblasts isolated mechanically from newborn mouse calvaria produced a calcified matrix when cultured in the presence of 10 mM beta-glycerophosphate or 3 mM inorganic phosphate. The uncalcified matrix revealed numerous matrix vesicles scattered among collagen fibrils. The calcified matrix showed mineralized collagen fibrils and calcified nodules whose underlying organic matrix was detected after decalcification. These structures resembled those described in fetal and woven bone. In partially decalcified areas, calcification was shown to spread out from these structures along collagen fibrils. Alkaline phosphatase activity was found associated with the plasma membrane and matrix vesicles. X-ray diffraction analysis demonstrated that the mineral phase deposited in culture was hydroxyapatite. These observations which demonstrate that the isolated cells elaborate in culture a mineralized matrix with chemical and ultrastructural properties of woven bone further support the osteoblastic nature of the cells.