Clonal analysis in vitro of osteogenic differentiation of marrow CFU-F

Development and characterization of conditionally immortalized osteoblast precursor cell lines from human bone marrow stroma

Although the differentiation of mature osteoblasts has been well studied, there is still a need for a convenient way to study preosteoblast differentiation. Our laboratory has recently described a method for isolating small numbers of authentic osteoblast precursor cells from human bone marrow (Rickard et al., J Bone Miner Res 11:312-324, 1996). Here we describe the conditional immortalization of these cells by retroviral transfection with the amphotrophic vector, pZipSV40tsa58, which encodes for a temperature-sensitive mutant form of the simian virus large T-antigen. At the permissive temperature of 34 degrees C, the cell lines proliferated, but differentiation was arrested, whereas at the restrictive temperature of 39.5 degrees C, proliferation was decreased and differentiation was induced. As assessed by semiquantitative reverse transcriptase PCR after 4 days of culture at 39.5 degrees C, the six cell lines expressed similar mRNA levels both constitutively and in response to dexamethasone (Dex) and 1alpha,25-dihydroxyvitamin D3 (1,25(OH2)D3) for osteoblast (alkaline phosphatase [ALP], type I collagen [Col I], osteocalcin [OC], and parathyroid hormone receptor [PTH-R] and adipocyte (lipoprotein lipase [LPL]) genes. In the presence of 10(-8) M Dex, gene expression for ALP, PTH-R, and LPL increased, but that for OC decreased. Stimulation with 10(-8) M 1,25(OH2)D3 increased gene expression for ALP, OC, and Col I. Changes in protein production for ALP, OC, and type I procollagen in response to Dex and 1,25(OH2)D3 were similar to changes in mRNA levels. When cultured at 39.5 degrees C with ascorbate and beta1-glycerolphosphate for 21 days, mineralization of matrix occurred, whereas culture with Dex plus 1,25(OH2)D3, or rabbit serum led to enhanced formation of cytoplasmic lipid droplets within 6 days. Thus, these cell lines are capable of bipotential differentiation and should serve as an excellent tool to study the molecular mechanisms that regulate and select for osteoblast and adipocyte differentiation in humans.

Single-colony derived strains of human marrow stromal fibroblasts form bone after transplantation in vivo

Populations of marrow stromal fibroblasts (MSFs) can differentiate into functional osteoblasts and form bone in vivo. It is not known, however, what proportion of MSF precursor cells, colony forming units-fibroblast (CFU-Fs), have osteogenic potential. In the present study, analysis of bone formation in vivo by single-colony derived strains of human marrow stromal fibroblasts (HMSFs) has been performed for the first time. Each strain originated from an individual CFU-F and underwent four passages in vitro prior to subcutaneous implantation into immunodeficient mice within vehicles containing hydroxyapatite-tricalcium phosphate ceramic. Multicolony derived HMSF strains were also transplanted to serve as positive controls. After 8 weeks, abundant bone formation was found in the transplants of all multicolony derived HMSF strains, whereas 20 out of 34 (58.8%) single-colony derived strains from four donors formed bone. Immunostaining with antibody directed against human osteonectin and in situ hybridization for human-specific alu sequences demonstrated that cells forming new bone were of human origin and were vital for at least 45 weeks post-transplantation. Both the incidence of bone-forming colonies and the extent of bone formation by single-colony derived HMSF strains were increased by cultivation with dexamethasone and ascorbic acid phosphate. Other factors, including type of transplantation vehicle, morphology, size, and structure of the original HMSF colonies showed no obvious correlation with the incidence or extent of bone formation. Hematopoietic tissue within the newly formed bone was developed in the transplants exhibiting exuberant bone formation. These results provide evidence that individual human CFU-Fs have osteogenic potential and yet differ from each other with respect to their osteogenic capacity.

LacZ and interleukin-3 expression in vivo after retroviral transduction of marrow-derived human osteogenic mesenchymal progenitors

Human marrow-derived mesenchymal progenitor cells (hMPCs), which have the capacity for osteogenic and marrow stromal differentiation, were transduced with the myeloproliferative sarcoma virus (MPSV)-based retrovirus, vM5LacZ, that contains the LacZ and neo genes. Stable transduction and gene expression occurred in 18% of cells. After culture expansion and selection in G418, approximately 70% of neo(r) hMPCs co-expressed LacZ. G418-selected hMPC retain their osteogenic potential and form bone in vivo when seeded into porous calcium phosphate ceramic cubes implanted subcutaneously into SCID mice. LacZ expression was evident within osteoblasts and osteocytes in bone developing within the ceramics 6 and 9 weeks after implantation. Likewise, hMPCs transduced with human interleukin-3 (hIL-3) cDNA, adhered to ceramic cubes and implanted into SCID mice, formed bone and secreted detectable levels of hIL-3 into the systemic circulation for at least 12 weeks. These data indicate that genetically transduced, culture-expanded bone marrow-derived hMPCs retain a precursor phenotype and maintain similar levels of transgene expression during osteogenic lineage commitment and differentiation in vivo. Because MPCs have been shown to differentiate into bone, cartilage, and tendon, these cells may be a useful target for gene therapy.

Systemic administration of an anabolic dose of PGE2 in young rats increases the osteogenic capacity of bone marrow

Prostaglandin E2 (PGE2) possesses significant anabolic properties when administered systemically (i.e., it increases bone formation and, consequently, bone mass). We recently characterized the effects of a 3 week administration of 6 mg/kg PGE2 into young rats and showed it increases cortical and cancellous bone mass and mechanical strength in long bones and bone density in the calvaria. We also found that a single dose of PGE2 induces the expression of early-response genes (c-fos, c-jun, and egr-1) in bone marrow cells within these two types of bone. These observations, together with findings by others of new cancellous bone formation in PGE2-treated animals, suggested that recruitment of osteoblasts from their precursors is a major mechanism of the anabolic effect of PGE2. To test this hypothesis directly, we injected PGE2 (6 mg/kg) or vehicle into 4-week-old rats for 2 weeks and then assessed the osteogenic potential of bone marrow in an ex vivo culture system. Primary and first-passage bone marrow cultures were established in the presence of beta-glycerophosphate, ascorbate, and dexamethasone, and osteogenic differentiation was measured by bone nodule formation and alkaline phosphatase activity. This regimen increased bone mass expressed as femoral ash weight by 4.7% and tibial cancellous bone area by 38.3%. Nodule formation at 21 days was increased in both primary and first-passage cultures from PGE2-treated rats despite seeding of the same number of marrow cells. Alkaline phosphatase activity was elevated in both primary and first-passage cultures from PGE2-treated rats beginning 6-10 days after culture initiation. Cell proliferation was only slightly elevated in cultures from PGE2-treated rats. These data strongly suggest that in vivo administration of PGE2 induces the proliferation or differentiation of osteoprogenitor cells in bone marrow, and this effect takes a major part in its anabolic effect in vivo.

Mitogenic activity but not phenotype expression of rat osteoprogenitor cells in response to IGF-I is impaired in aged rats

The age-related deficit in the dose response of osteoprogenitor cells to IGF-I was further investigated. As expected, the effective dose, but not the maximal effect, was shifted two orders of magnitude higher in old cells. In this paper, we examined whether this age-deficit can be attributed to an alteration in the expression and binding kinetics of IGF-I receptor. We showed that the levels of IGF-I receptor mRNA in cells, estimated by RT-PCR, were not significantly altered with age. Scatchard analysis showed that there were no significant differences in Kd and Bmax in cells from the two age groups. In a parallel study, we also showed that the expression of osteoblast phenotype markers was stimulated by IGF-I. However, no apparent differences in dose response curve were observed between two age groups. These results suggest that defect(s) in cell proliferation in aging may occur specifically in the signal transduction pathway between the receptor and the mitogenic response but not in the pathway associated with phenotype expression.

Demineralized bone matrix mediates differentiation of bone marrow stromal cells in vitro: effect of age of cell donor

Bone maintenance requires a continuous source of osteoblasts throughout life. Its remodeling and regeneration during fracture repair is ensured by osteoprogenitor stem cells which are part of the stroma of the bone marrow (BM). Many investigators have reported that in cultured BM stromal cells there is a cell population that will differentiate along an osteogenic lineage if stimulated by the addition of osteogenic inducers, such as dexamethasone (dex), beta-glycerophosphate (beta-GP), transforming growth factor beta-1 (TGF-beta 1) and bone morphogenetic protein-2 (BMP-2). Here we report the effects of demineralized bone matrix (DBM) on the osteogenic differentiation of BM stromal cells in vitro, using morphological criteria, alkaline phosphatase (AP) activity, and calcium accumulation. DBM and DBM-conditioned medium (DBMcm) enhanced bone formation in the presence of dex and beta-GP, whereas DBM particles caused changes in the cell phenotype. Temporal expression of total and skeletal AP by BM stromal cells from 4-week-old rats showed a biphasic pattern enhanced by DBM and suggesting the presence of two cell populations. In one population, AP synthesis reaches a maximum during the first week in culture, following which cells either die or loose their ability to synthesize AP. A second, less abundant population begins to proliferate and synthesize AP during the second and third weeks. The synthesis of AP, which often decreases by the third week, can be maintained at high levels only if DBM is added to the cultures. BM stromal cells isolated from 24- and 48-week-old rats showed a decrease or loss of this biphasic AP expression pattern compared with cells isolated from 4-week-old rats. The addition of DBM to cultures derived from 24- and 48-week-old rats stimulated mostly the second cell population to synthesize AP, suggesting that DBM contains a factor(s) that acts on a specific bone marrow cell population by increasing the proliferation of active cells or inducing the differentiation of dormant cells.

Parathyroid hormone regulates osteoblast differentiation positively or negatively depending on the differentiation stages

The effects of parathyroid hormone (1-34) (PTH (1-34) on osteoblast differentiation were investigated using primary osteoblast-like cells isolated from newborn mouse calvaria. The osteoblast-like cells cultured at low cell densities, in which the cells remained in a subconfluent state at the end of culture, were exposed for 7 days to PTH. This stimulated alkaline phosphatase (ALP) activity in a dose-dependent manner. In contrast, PTH dose-dependently inhibited both ALP activity and osteocalcin production in cells inoculated at high cell densities, in which they had reached a confluent state before the end of culture. The changes of ALP activity by PTH were accompanied with the expression of ALP messenger RNA. PTH induced no changes of the hydroxyproline content in the cell layer when the cells were exposed to the hormone at a subconfluent state, but reduced the content at a postconfluent state. The stimulation of ALP activity by PTH at a preconfluent state was retained even after the removal of PTH from the culture media. The opposite effect of PTH, observed between the preconfluent and the postconfluent state, was reproduced by adding dibutyryl cyclic adenosine monophosphate (cAMP) or forskolin, but not by adding phorbol myristate acetate. In a colony-forming unit fibroblastic (CFU-F) assay, using bone marrow cells isolated from tibiae of 10-week-old mice, PTH induced no changes in the total number of CFU-Fs, but increased the proportion of ALP-positive colonies. These results indicate that PTH exerts opposite effects on the phenotypic expression of osteoblasts, depending on their differentiation stages of osteoblasts. PTH may preferentially stimulate osteoblast differentiation in immature osteoblasts but inhibit it in more mature cells.

Bone marrow capacity for bone cells and trabecular bone turnover in immobilized tibia after sciatic neurectomy in mice

Trabecular bone turnover and bone marrow capacity for the development of bone cells in the tibia were assessed after sciatic neurectomy (NX) in mice. The right hindlimbs of 6-week-old DDY mice were neurectomized and left hindlimbs were sham-operated and served as NX controls. Histomorphometrical analyses of the trabecular bone of the proximal tibia demonstrated the initial decrease in bone formation rate for the first 14 days and the subsequent increase in osteoclast surface for the next 14 days. The number of adherent stromal cells per tibia obtained for the NX limbs was reduced on days 7 and 10 postsurgically, and then recovered on day 12. However, the alkaline phosphatase activity of the cells was persistently depressed. The formation of osteoclast-like multinucleated cells in the marrow cultures obtained from NX limbs at days 10, 12, and 14 showed a significant increase in the medium containing parathyroid hormone (PTH). The number of colonies cultured for colony forming units-fibroblastic (CFU-f) that developed from the marrow cells did not differ in the NX and the contralateral limbs at any time during the period. On the other hand, the number of colonies cultured of colony forming units for granulocytes and macrophages (CFU-GM) was markedly increased for both the NX and the contralateral tibiae at days 12 and 14. This study clearly demonstrates that there are two stages in the development of osteopenia after NX. During the first 14 days, trabecular bone formation and number of marrow stromal cells are reduced. In the second 14 day period, the trabecular osteoclast number is increased and osteoclast formation from the bone marrow cells is enhanced in the presence of PTH. However, neither the CFU-f nor the CFU-GM assay could identify the changes in osteogenic or osteoclastogenic potential of the bone marrow. These in vitro assays provide limited information on the shifts in bone marrow cell lineages and the local environment producing osteopenia in the immobilized limb in vivo.

Bone marrow stromal cells are load responsive in vitro

Mechanical load-related effects on bone marrow stromal cells in vitro have been investigated. A dose response of a cyclical load of 1 Hz between 350 ustrain and 2500 ustrain applied to 10-day-old cultures resulted in elevated alkaline phosphatase levels and the number of cells expressing this protein after 2 days. No significant changes in the number of cells expressing or the production of collagen type 1 was observed. A critical stage of development of the cultures must be reached before load-related elevation in alkaline phosphatase expression could be measured independent of the stage at which loading was applied. Using a prostaglandin inhibitor at concentrations previously used in vivo, the load response was abolished. We have demonstrated that bone marrow stromal cells are load responsive in culture and have made preliminary studies into determining the involvement of prostaglandins in this process.

Rat tail suspension reduces messenger RNA level for growth factors and osteopontin and decreases the osteoblastic differentiation of bone marrow stromal cells

We previously reported that bone marrow stromal cells produce insulin-like growth factors (IGF-I and -II), and that medium conditioned by marrow stromal cells stimulates osteoblast proliferation in vitro. The present study employed the rat tail-suspension model to unload the hindlimbs. It was designed to test the hypothesis that the development of osteopenia or osteoporosis could be due to a deficit in the osteogenic function of marrow stromal cells. Although tail suspension suppressed body weight during the first 3 days of an 11-day pair-fed study, the overall weight gain recorded by these animals was normal. Nevertheless, bone growth was inhibited by suspension. Similarly, the total adherent marrow stromal cell population harvested from the femurs and tibias was decreased by tail suspension, and only half the normal number of fibroblastic stromal cell colonies grew when they were cultured. The proliferation of alkaline-phosphatase-positive cells in the stroma was also inhibited. Northern hybridization revealed that the messenger RNA level for transforming growth factor-beta 2 and IGF-II in stromal cell was reduced by tail suspension. The production of IGF-II by marrow stromal cells was also decreased. The steady-state level of five different transcript sizes of IGF-I mRNA was altered differentially by tail suspension. Osteopontin mRNA was also reduced in marrow stromal cells from tail-suspended rats compared with the normal rats. These data suggest that skeletal unloading not only alters the mRNA level for growth factors and peptide production, but also affects the proliferation and osteogenic differentiation of marrow stromal cells. These changes may be responsible for the reduced bone formation in osteopenia and osteoporosis.

Bone progenitor cell deficits and the age-associated decline in bone repair capacity

Aging bone shows a progressive decline in mass and strength. Previous studies have suggested that bone marrow stem cells are reduced with aging and that this could be responsible, in part, for age-associated bone deficits. We measured the number of osteoprogenitor cells present in the bone marrow from adult and aged rats as well as their ability to differentiate in vitro and to form bone in vivo. We found that the number of adherent colony-forming cells was significantly lower (65%) in marrow cells isolated from aged compared with adult rats. Furthermore, 88% of the colonies obtained from aged rats were alkaline phosphatase (AP) positive, whereas virtually all the colonies from adult rats were positive. The addition of dexamethasone to the culture medium decreased the proliferation of the adherent cells and reduced the number of colonies obtained from both adult and aged bone marrow, all of which were AP positive. No significant differences were found in the expression of certain major bone cell marker genes as a function of donor age. However, dexamethasone treatment increased expression of osteopontin (OP) by fivefold. Adult stromal cells not treated with dexamethasone and implanted subcutaneously in recipient rats exhibited about 10-fold greater formation of bone compared with cells from aged rats. In contrast, dexamethasone-treated cells exhibited high levels of bone formation, irregardless of donor age or the age of the recipient into which the cells were grafted. These studies are consistent with a deficit of osteoprogenitor cells in the bone marrow site as a contributing, perhaps correctable factor in the decline in bone repair and bone mass with age.

The effects of dexamethasone and 1,25-dihydroxyvitamin D3 on osteogenic differentiation of human marrow stromal cells in vitro

Effects of dexamethasone and 1,25-dihydroxyvitamin D3 [1,25(OH)2D3] were studied in cultures of adult human marrow stromal cells. In primary culture, dexamethasone (10(-8) M) increased the number of fibroblast colonies formed but decreased their average size. The number of colonies expressing alkaline phosphatase activity was increased, consistent with the enhancement of osteogenic differentiation by this glucocorticoid. In secondary culture, osteogenic differentiation was assessed by measurement of the steady-state levels of particular mRNAs that are characteristic of cells of the osteoblast lineage. The mRNAs for alpha 1(I)-procollagen, alkaline phosphatase, osteopontin and bone sialoprotein were expressed under all culture conditions used. In contrast, osteocalcin mRNA expression was detectable only in cultures treated with 1,25(OH)2D3 (10(-8) M). Addition of 1,25(OH)2D3 to control increased the expression of the mRNAs for alkaline phosphatase and osteopontin but had no significant effect on bone sialoprotein expression. The highest levels of expression of the mRNAs for alkaline phosphatase, bone sialoprotein and osteocalcin were observed in dexamethasone-treated cultures to which 1,25(OH)2D3 had been added. These results demonstrate that, as earlier found in other species, dexamethasone and 1,25(OH)2D3 promote the osteogenic differentiation of human marrow stromal cells as measured by expression of these osteogenic markers.

Size-selective comparison of fetal calvarial versus adult marrow osteogenic colony-forming entities

BACKGROUND

This experiment was designed to test whether a single cell suspension of adult marrow-derived cells will form mineralized bone nodules in vitro.

METHODS

At the time of plating, cellular dispersions of either young adult rabbit bone marrow cells or, as controls, of fetal mouse calvarial cells were size-selected by sieving through various pore-size plastic meshes.

RESULTS

When marrow-derived cells were passed through a 105 microns pore-size mesh, fibroblastic cell cultures grew in vitro in six of six attempts; however, marrow cell clusters backwashed off 105 microns pore-size meshes produced osteogenic colonies in vitro in six of six trials. Fetal calvarial cells filtered through a 30 microns pore-size mesh yielded osteogenic nodules in culture in six of six tests.

CONCLUSIONS

For adult bone marrow, cell clumps or clusters larger than 105 microns produced bone colonies under standard cell culture conditions, whereas for fetal calvarial cells, the initiating agent was smaller than 30 microns.

Bone marrow from mechanically unloaded rat bones expresses reduced osteogenic capacity in vitro

Bone formation during mechanical unloading is reduced, mainly as a result of osteoblastic hypofunction. At the same time, the total number of osteoblasts per long bone is also markedly reduced. We tested the hypothesis that the number of osteogenic precursors present in the bone marrow stroma was concomitantly diminished by using an in vitro cell culture system in which femoral adherent bone marrow cells differentiate into active osteoblasts and produce bone-like nodules. Hindlimbs of 32-day-old male rats were either immobilized (unloaded) by sciatic neurectomy (immo) or sham operated (sham) and animals were killed after 11 days. Femora were either ashed to determine bone mass or used to generate bone marrow cultures. Adherent marrow cells were cultured in the presence of ascorbic acid, beta-glycerophosphate, and dexamethasone. Bone mass was significantly reduced in unloaded femora (by 16%) and tibiae (by 18%). The number of adherent cells (determined on day 6) was reduced by 50% in the immo group. Reduced cell number did not result from slower proliferation in culture since [3H]thymidine incorporation on days 4 and 6 was similar in the two groups. The osteogenic potential in vitro of marrow from unloaded bones was diminished compared with that from loaded ones as evidenced by (1) lower alkaline phosphatase (ALP) activity per mg protein (by 25-40%, examined on days 6 and 12), and (2) reduced nodule formation (by 70%, expressed as percentage of the dish area stained with Alizarin Red S on day 21). None of these changes occurred in the contralateral limb of operated (immobilized) animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Differentiation and mineralization in osteogenic precursor cells derived from fetal rat mandibular bone

The process of mineralization in cells prepared either by neutral protease digestion (Pro I) or by collagenase digestion (fifth cycle, Col V) from fetal rat mandible was studied in vitro. Alkaline phosphatase (ALPase) activity of cells in Pro I was low on day 3, increased rapidly from day 8, and reached a maximum on day 16, whereas that in Col V was high on day 2, then declined and thereafter elevated to reach a maximum on day 13. Both cell populations synthesized type I collagen in cell matrix and medium. Type III collagen was observed in cell matrix of Pro I on day 14 and 21. There was alpha 2 band of type V collagen in cell matrix of Pro I on day 21. Calcium deposition could be detected from day 14 in Pro I and from day 19 in Col V. The von Kossa-positive nodules were found on day 17 in Pro I and day 21 in Col V, respectively. The extracellular matrix in Pro I electron-microscopically consisted of well-banded collagen fibrils with a large number of calcified spherules. An elevation of ALPase activity, collagen synthesis, and mineral deposition occurred sequentially with a time lapse in Col V, and almost simultaneously in Pro I. The number of mineralized nodules was correlated with the density of plated cells in Pro I, but not in Col V. Dexamethasone caused an increase in the number of mineralized nodules in Pro I, but not in Col V, suggesting that Pro I contained osteoprogenitor cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Selection of malonate-resistant stromal cell-derived osteoprogenitor cells in vitro

Bone marrow stromal cells give rise to osteoprogenitor cell (OPC) colonies, with characteristic mineralized bone nodules in vitro. During differentiation, OPCs in the culture are surrounded by heterogeneous populations of various cell lineages and by different OPC differentiation stages. In the present study, attempts were made to increase the homogeneity of OPCs in culture. The reliance on energy metabolism restricted to glycolysis, which is specific to the premineralizing skeletal cells, was tested as a selectable marker for cells in this stage. Day 12 alkaline phosphatase (ALP) and day 20-21 calcium precipitates were used as early and late OPC differentiation markers. Malonate, a competitive inhibitor of succinate dehydrogenase, was added to the OPC stimulation medium, to interfere with the Krebs cycle-dependent energy metabolism operating in most of the stromal cells. OPCs that entered the stage of energy metabolism restricted to glycolysis were expected to become malonate resistant. Malonate showed dose and time dependence, 10 mM malonate added on day 3, decreased day 12 ALP activity/well to the lowest level. Variations in time and length of exposure to malonate used during the first 12 days of differentiation showed an inverse correlation between specific ALP activity and cell yield. Malonate-treated variations of specific ALP and of cell yield indices were up to 30- to 40-fold larger than variations within day 21 calcium precipitates. Thus, calcifying cells were almost unchanged relatively to noncalcifying cells. These results indicate that malonate-resistant cells are mostly selected, rather than induced, to differentiate by malonate. The results also show that stromal derived OPCs undergo a similar biochemical stage as in chondrocytes.

Formation of mineralized nodules by bone derived cells in vitro: a model of bone formation?

The identification of the factors which regulate the proliferation and differentiation of cells of the osteoblast lineage remains one of the major challenges in the field of bone cell biology. Although considerable progress has been made in the isolation and culture of cells of the osteoblast lineage from both animal and, more recently, human bone, uncertainties have persisted as to the extent to which these cell populations retain the ability to differentiate into functional osteoblasts in vitro. The formation in vitro of mineralized nodules that exhibit the morphological, ultrastructural and biochemical characteristics of embryonic/woven bone formed in vivo, represents the first evidence that the differentiation of functional osteoblasts can occur in cultures of isolated animal bone-derived cell populations. It is clear, however, that the culture conditions employed at present only permit a small number of cells to differentiate to the extent of being capable of organising their extracellular matrix into a structure that resembles that of bone. Moreover, it has generally been found that the reproducible mineralization of this extracellular matrix requires supplementation of the culture medium with mM concentrations of beta-GP, which raises doubts as to the physiological relevance of this process. The formation of nodules has also been observed in cultures of human bone-derived cells. As found in cultures of animal bone-derived cells, reproducible mineralization of these nodules will occur in the presence of beta-GP. We have shown, however, that in the presence of the long acting ascorbate analogue Asc-2-P, the formation and mineralization of nodules can occur in the absence of beta-GP. The nodules formed in human bone-derived cell cultures have yet to be characterized as rigorously as those formed in cultures of animal bone-derived cells and thus it remains to be shown that they resemble bone formed in vivo.

Bone healing after bone marrow stromal cell transplantation to the bone defect

In experimental studies on rabbits, osteogenic properties of stromal cells were confirmed after in vitro growth for 7 and 14 d. The cell suspension was percutaneously transplanted into a surgically produced bone defect in the rabbit's radius. The bone scar produced was X-rayed, and histologically and mineralogically examined after 10, 20 and 40 d follow-ups. Differences in the bone defect healing process (the healing rate and the type of bone tissue produced) were shown between the experimental and the control foreleg. Within the experimental foreleg, healing was considerably accelerated with compact bone formation on a membranous matrix, whilst in the control foreleg, a coarse, fibrous woven bone on a cartilaginous matrix was dominant.

Bone-inducing agent (BIA) from cultured human Saos-2 osteosarcoma cells

The Saos-2 line of human osteosarcoma cells was established in culture in 1975. These cells produce a large amount of alkaline phosphatase but little or no matrix in vitro, and are unable to grow when transplanted into athymic mice. We decided to test our local strain of Saos-2 cells for bone-inducing ability in the skeletal muscle of athymic mice by implanting freeze-dried, acetone-defatted cells, with and without a collagen carrier. A bone-inducing activity (BIA) thus was demonstrated in 88% of 90 implants of devitalized Saos-2 cells. In further studies, we have used guanidinium hydrochloride (Gu-HCl) to extract, solubilize, and remove the Saos bone-inducing agent(s) in an active state which when reprecipitated by aqueous dialysis was able to induce ultrastructurally typical endochondrial bone formation in nude mouse muscle in 92% of 48 implants. This preliminary report is offered to alert investigators to the presence of an extractable BIA in Saos-2 cells.

Mineralized nodule formation in rat bone marrow stromal cell culture without beta-glycerophosphate

Rat bone marrow stromal cells were cultured in the presence of 10 nM dexamethasone and various concentrations of beta-glycerophosphate. At day 12-15, some nodules consisting of polygonal cells were formed in all culture conditions, and these nodules were mineralized 2-3 days later. beta-Glycerophosphate significantly enhanced nodule formation at concentrations of not less than 5 mM. The mineralized nodules formed in the absence of beta-glycerophosphate were examined using phase-contrast microscopy, undemineralized and demineralized tissue histology, histochemistry for alkaline phosphatase, immunohistochemistry for type I, II, and III collagen, energy dispersive X-ray microanalysis, electron diffraction, and Fourier transform infrared spectroscopy (FT-IR). Mineralized nodules had histological characteristic similar to bone. Cells associated with nodules exhibited high alkaline phosphatase activity, and extracellular matrix of the nodules predominantly consisted of type I collagen. X-Ray microanalysis showed the presence of Ca and P in the mineralized area, and electron diffraction pattern showed the mineral to have apatite crystal structure. Moreover FT-IR indicated that the mineral was a mixture of hydroxyapatite and carbonateapatite. From these observations, it is concluded that the mineralized nodules formed in our culture system are truly bone-like.

Dexamethasone induction of osteoblast mRNAs in rat marrow stromal cell cultures

We have examined the ability of dexamethasone, retinoic acid, and vitamin D3 to induce osteogenic differentiation in rat marrow stromal cell cultures by measuring the expression of mRNAs associated with the differentiated osteoblast phenotype as well as analyzing collagen secretion and alkaline phosphatase activity. Marrow cells were cultured for 8 days in primary culture and 8 days in secondary culture, with and without 10 nM dexamethasone or 1 microM retinoic acid. Under all conditions, cultures produced high levels of osteonectin mRNA. Cells grown with dexamethasone in both primary and secondary culture contained elevated alkaline phosphatase mRNA and significant amounts of type I collagen and osteopontin mRNA. Addition of 1,25-dihydroxyvitamin D3 to these dexamethasone-treated cultures induced expression of osteocalcin mRNA and increased osteopontin mRNA. The levels of alkaline phosphatase, osteopontin, and osteocalcin mRNAs in Dex/Dex/VitD3 cultures were comparable to those of 1,25-dihydroxyvitamin D3-treated ROS 17/2.8 osteosarcoma cells. Omitting dexamethasone from either primary or secondary culture resulted in significantly less alkaline phosphatase mRNA, little osteopontin mRNA, and no osteocalcin mRNA. Retinoic acid increased alkaline phosphatase activity to a greater extent than did dexamethasone but did not have a parallel effect on the expression of alkaline phosphatase mRNA and induced neither osteopontin or osteocalcin mRNAs. In all conditions, marrow stromal cells synthesized and secreted a mixture of type I and III collagens. However, dexamethasone-treated cells also synthesized an additional collagen type, provisionally identified as type V. The synthesis and secretion of collagens type I and III was decreased by both dexamethasone and retinoic acid. Neither dexamethasone nor retinoic acid induced mRNAs associated with the chondrogenic phenotype. We conclude that dexamethasone, but not retinoic acid, promotes the expression of markers of the osteoblast phenotype in cultures of rat marrow stromal fibroblasts.

Effect of cortisone on cells at the bone-marrow interface

A study of the association between the rate of proliferation of marrow fibroblast-like stromal cells (in vitro) and the rate of endosteal bone mineralization (EsMR) (in vivo) was undertaken in an osteopenic rat model. We report that 200 g male rats treated with cortisone acetate (5 mg/day for 7 days) exhibit decreases in marrow fibroblast colony-forming units (FCFU) and tetracycline-based measurements of EsMR at the level of the femoral midshaft. In cortisone-treated rats recovering for 1-3 weeks, the FCFU census and EsMR normalized during the first posttreatment week, remained at control levels after 2-3 weeks, and exhibited a relapse in the third week which signified only partial recovery. These changes were unrelated to patterns of body weight gain. The data indicate that the FCFU census can serve to index endosteal osteoblast vigor.

The adenylate cyclase response to parathyroid hormone in cultured rabbit marrow fibroblastic cells

The ability of fibroblastic cells to respond to parathyroid hormone (PTH) by an increase in adenylate cyclase activity is accepted as a characteristic of the osteogenic phenotype. Whether marrow fibroblastic cells, which have osteogenic potential when assayed in vivo, demonstrate this hormonal response when cultured in vitro has been investigated. Our study has shown a level of stimulation of adenylate cyclase activity by PTH in cultured rabbit marrow fibroblasts comparable with other osteogenic cells in vitro. The effect is seen in fibroblasts grown either from multiple colonies or from single colonies. Only a proportion of colonies had osteogenic potential in vivo assay and our results show a similar finding for the PTH response in vitro. To what degree the two parameters are expressed by the same colony has not yet been established.

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.