Culture and differentiation of chondrocytes entrapped in alginate gels

Summary We studied the response to culture conditions and the differentiative ability in suspension culture in alginate gels of resting chondrocytes from the preosseous cartilage of adult pig scapula. It was found that the maximum rate of chondrocyte duplication is reached at the fourth day in culture whereas the rate of proteoglycan synthesis and alkaline phosphatase expression do not gain a maximum value before the seventh day. During the culture time, the chondrocytes undergo differentiation as it is demonstrated by the alkaline phosphatase specific activity increase and by morphological criteria (hypertrophy, increase of the number of mitochondria per cell, increased endoplasmic reticulum, matrix vesicle production). The alginate gels can be easily dissolved to obtain cell populations in which the variation of cytosolic calcium concentration following a proliferative stimulus can be conveniently observed using the conventional procedure of Fura 2.     

Osteosarcoma cells in tissue culture: II. Characterization and localization of alkaline phosphatase activity

Although elevated alkaline phosphatase levels in osteosarcoma have been shown to be related to prognosis, the functional significance is unclear. Human osteosarcoma cells in tissue culture retain detectable amounts of alkaline phosphatase activity. In this study the specific activity of that enzyme was compared in 13 osteosarcoma tissue culture lines and 13 normal skin fibroblast lines derived from the same patients. Osteosarcoma cells had significantly higher baseline alkaline phosphatase levels and could be stimulated with hydrocortisone to produce more enzymatic activity than the fibroblast lines. Activity was localized ultracytochemically to the cell membrane and to many small intracellular vesicles in stimulated osteosarcoma cells. These observations aid in the differentiation of osteosarcoma and fibroblast lines in tissue culture and suggest an association between elevated alkaline phosphatase levels and metabolic abnormalities in patients with osteosarcoma.     

Cell culture of the intervertebral disc of rats: factors influencing culture, proteoglycan, collagen, and deoxyribonucleic acid synthesis.

To establish cell culture of the nucleus pulposus and anulus fibrosus of rat intervertebral disc, the effects of culture conditions on the growth of cells and the synthesis of DNA, proteoglycan, and collagen were studied. For cell culture of the nucleus pulposus, the use of 3-week-old rats and a medium adjusted to pH 7.0 was optimal. There was almost no difference in growth between cells in Ham's F12 medium and those in Dulbecco's Modified Eagle Medium. In cells isolated from the anulus fibrosus, a medium adjusted to pH 7.0-7.6 was preferable, but irrespective of rat age. Culture cells of the nucleus pulposus were composed of large cells with vacuoles and small polygonal cells. These cells had a slight growth activity and a fair capability of proteoglycan and collagen synthesis. Culture cells of the anulus fibrosus were composed of polygonal and spindle-shape cells, and the growth was more vigorous with the potentials for proteoglycan and collagen synthesis than the nucleus cells.     

Distinct proliferative and differentiated stages of murine MC3T3-E1 cells in culture: an in vitro model of osteoblast development.

We examine clonal murine calvarial MC3T3-E1 cells to determine if they exhibit a developmental sequence similar to osteoblasts in bone tissue, namely, proliferation of undifferentiated osteoblast precursors followed by postmitotic expression of differentiated osteoblast phenotype. During the initial phase of developmental (days 1-9 of culture), MC3T3-E1 cells actively replicate, as evidenced by the high rates of DNA synthesis and progressive increase in cell number, but maintain a fusiform appearance, fail to express alkaline phosphatase, and do not accumulate mineralized extracellular collagenous matrix, consistent with immature osteoblasts. By day 9 the cultures display cuboidal morphology, attain confluence, and undergo growth arrest. Downregulation of replication is associated with expression of osteoblast functions, including production of alkaline phosphatase, processing of procollagens to collagens, and incremental deposition of a collagenous extracellular matrix. Mineralization of extracellular matrix, which begins approximately 16 days after culture, marks the final phase of osteoblast phenotypic development. Expression of alkaline phosphatase and mineralization is time but not density dependent. Type I collagen synthesis and collagen accumulation are uncoupled in the developing osteoblast. Although collagen synthesis and message expression peaks at day 3 in immature cells, extracellular matrix accumulation is minimal. Instead, matrix accumulates maximally after 7 days of culture as collagen biosynthesis is diminishing. Thus, extracellular matrix formation is a function of mature osteoblasts. Ascorbate and beta-glycerol phosphate are both essential for the expression of osteoblast phenotype as assessed by alkaline phosphatase and mineralization of extracellular matrix. Ascorbate does not stimulate type I collagen gene expression in MC3T3-E1 cells, but it is absolutely required for deposition of collagen in the extracellular matrix. Ascorbate also induces alkaline phosphatase activity in mature cells but not in immature cells. beta-glycerol phosphate displays synergistic actions with ascorbate to further stimulate collagen accumulation and alkaline phosphatase activity in postmitotic, differentiated osteoblast-like cells. Mineralization of mature cultures requires the presence of beta-glycerol phosphate. Thus, MC3T3-E1 cells display a time-dependent and sequential expression of osteoblast characteristics analogous to in vivo bone formation. The developmental sequence associated with MC3T3-E1 differentiation should provide a useful model to study the signals that mediate the switch between proliferation and differentiation in bone cells, as well as provide a renewable culture system to examine the molecular mechanism of osteoblast maturation and the formation of bone-like extracellular matrix.     

Long-term effects of physiologic concentrations of dexamethasone on human bone-derived cells

Bone cells derived from human trabecular explants display osteoblastic features. We examined the modulation of alkaline phosphatase activity and cAMP production as the result of exposing trabecular explants to physiologic concentrations of dexamethasone for 4 weeks during cellular outgrowth and subculture. Cells treated with dexamethasone were observed to grow generally more slowly than control cells. Cells appeared larger and more polygonal, and staining for alkaline phosphatase was more intense in the dexamethasone-exposed cultures. There was a progressive increase in cellular PTH responsiveness with increasing duration of exposure of cells to dexamethasone. Cells grown for 6 weeks in 3 x 10(-8) M dexamethasone had a 10-fold increase in PTH-stimulated cyclic AMP accumulation. Dexamethasone-treated cells also had a significantly increased alkaline phosphatase activity. 1,25-(OH)2D3-stimulated alkaline phosphatase activity was increased approximately 20-fold. cAMP responses were significantly increased to PTH (21.7-fold), PGE1 (2.67-fold), and forskolin (4.81-fold), but not to cholera toxin. Dexamethasone-treated cells also had a mean decrease in 1,25-(OH)2D3-stimulated osteocalcin production to 26.2% of control values (p less than 0.001). Hydrocortisone treatment gave rise to similar effects but of smaller magnitude than those of dexamethasone. Testosterone did not have a significant effect on alkaline phosphatase activity or cAMP production. Skin fibroblasts showed a significant enhancement of alkaline phosphatase activity in response to dexamethasone, but of a much smaller magnitude than in bone cells. The phenotypic changes induced by long-term culture in dexamethasone are consistent with the promotion of a more differentiated osteoblastic phenotype.     

Establishment from mouse growth cartilage of clonal cell lines with responsiveness to parathyroid hormone,alkaline phosphatase activity,and ability to produce an endothelial cell growth inhibitor

Summary Three clonal cell lines with differences in responsiveness to parathyroid hormone (PTH), alkaline phosphatase activity, and ability to produce an endothelial cell growth inhibitor(s) during more than 3 years, more than 58 passages, in culture were established from growth cartilage (GC) of mouse ribs. In sparse, cultures the three clonal cell lines, MGC/T1.4, MGC/T1.17, and MGC/T1.18, all showed fibroblast-like morphology. However, as they became confluent, MGC/T1.4 cells became polygonal and then multilayered. MGC/T1.18 cells also became polygonal, but showed contact inhibition. MGC/T1.17 cells remained fibroblastic in confluent cultures and formed nodules when cultured for more than 7 days after they became confluent. These nodules calcified in the presence of β-glycerophosphate. Glycosaminoglycan (GAG) synthesis in the parent uncloned line, MGC/T1 cells, at early passages was about 50–75% of that of primary cultures of mouse GC cells. The GAG syntheses in the three clonal lines were much lower than that of primary cultures of GC cells Moreover, the sizes of proteoglycan monomers synthesized by these cells were not the same as that of cartilage-specific proteoglycan. The three clonal lines mainly synthesized type I collagen. PTH increased the intracellular cyclic AMP level in MGC/T1, MGC/T1.4, T1.17, and T1.18 cells: their maximal levels, observed after 2 minutes, were, respectively, about 160, 150, 70, and 200 times that of controls. The activity of alkaline phosphatase in MGC/T1.17 cells was higher than that in primary cultures of mouse GC cells, whereas those in MGC/T1 and T1.4 cells were comparable with that of GC cells, and that in MGC/T1.18 was lower. The three clonal lines, and especially MGC/T1.4, secreted a heat-stable, nondializable, growth inhibitor(s) of endothelial cells into the culture medium. Because of their different properties, these cell lines should be useful for studies on endochondral ossification, the actions of PTH on skeletal cells, and anti-angiogenesis factors.     

The mandibular condylar growth center: Separation and characterization of the cellular elements

The developing mandibular condylar growth center consists of a number of histologically distinct cell types. There is an increase in cell volume that takes place from the condylar surface layer through the center of ossification, resulting in a disorganized, irregular cellular pattern. Consequently, the isolation and separation of the different cells from this tissue is difficult using standard methodologies. Countercurrent centrifugal elutriation, whereby cells are separated on the basis of size, was applied to bovine mandibular condylar growth center cells. The cell volume, alkaline phosphatase content, proteoglycan synthesis, and type X collagen synthesis all showed a positive correlation with increasing cell size. The largest cells had characteristics that are consistent with hypertrophic chondrocytes; the smallest cells, on the other hand, had many fibroblastic characteristics.     

The role of hepatocyte growth factor in growth plate cartilage

To investigate the physiological role of hepatocyte growth factor (HGF) in endochondral bone formation, we examined the expression of HGF and its receptor c-met and the effects of HGF on growth plate chondrocytes. HGF was highly expressed in the prehypertrophic zone and hypertrophic zone in rat costal growth plate cartilage. The expression of HGF increased in rabbit chondrocytes as they matured in culture. Conversely, c-met expression was down regulated along maturation of growth plate chondrocytes. HGF had weak stimulatory effects on DNA and proteoglycan synthesis of growth plate chondrocytes. However, HGF strongly inhibited expression of terminal differentiation-related phenotypes, such as type X collagen and alkaline phosphatase (APase) synthesis and cartilage matrix mineralization. When HGF was removed from the cultures, cells quickly expressed type X collagen and APase. Once chondrocytes differentiated to mature chondrocytes, HGF did not inhibit further differentiation of these cells. These results suggested that HGF is a negative regulator of terminal differentiation of growth plate chondrocytes.. Received: Feb. 12, 1998 / Accepted: March 12, 1998     

Gene and Protein Expression During Differentiation and Matrix Mineralization in a Chondrocyte Cell Culture System

Endochondral bone formation occurs through a series of developmentally regulated cellular stages, from initial formation of cartilage tissue to calcified cartilage, resorption, and replacement by bone tissue. Nasal cartilage cells isolated by enzymatic digestion from rat fetuses were seeded at a final density of 10⁵ cell/cm² and cultured in Dulbecco's modified Eagle medium (DMEM) supplemented with 10% fetal calf serum in the presence of ascorbic acid and β-glycerophosphate. First, cells lost their phenotype but in this condition they rapidly reexpressed the chondrocyte phenotype and were able to form calcified cartilaginous nodules with the morphological appearance of cartilage mineralization that occurs in vivo during endochondral ossification. In this mineralizing chondrocyte culture system, we investigated, between day 3 and day 15, the pattern expression of types II and X collagen, proteoglycan core protein, characteristic markers of chondrocyte differentiation, as well as alkaline phosphatase and osteocalcin associated with the mineralization process. Analysis of labeled collagen and immunoblotting revealed type I collagen synthesis associated with the loss of chondrocyte phenotype at the beginning of the culture. However, our culture conditions promoted extracellular matrix mineralization and cell differentiation towards the hypertrophic phenotype. This differentiation process was characterized by the induction of type X collagen mRNA, alkaline phosphatase, and diminished expression of type II collagen and core protein of large proteoglycan after an increase in their mRNA levels before the mineralizing process. These results revealed distinct switches of the specific molecular markers and indicated a similar temporal expression to that observed in vivo recapitulating all stages of the differentiation program in vitro. Received: 12 December 1996 / Accepted: 26 June 1997     

Initial effects of partially purified bone morphogenetic protein on the expression of glycosaminoglycan, collagen, and alkaline phosphatase in nonunion cell cultures.

Bone morphogenetic protein (BMP) stimulates mesenchymal cells to differentiate, resulting in de novo endochondral ossification in vivo. The response of fibrocartilage and periosteal cells from human and canine nonunion tissues to partially purified BMP was examined in culture. Cells derived from neonatal rat muscle explants were used for comparison. Alkaline phosphatase activity and expression of alkaline phosphatase and Types I and II collagen mRNAs were compared to that of rat chondrocytes. Synthesis of Type II collagen by the muscle cells was verified by enzyme-linked immunosorbent assay (ELISA). Addition of BMP to the muscle cell and nonunion cell cultures resulted in a dose-dependent decrease in cell number. There was a decrease in matrix vesicle and plasma membrane alkaline phosphatase activity concomitant with an increase in mRNA levels for alkaline phosphatase and collagen genes. Synthesis of immunoreactive Type II collagen increased. These data indicate that neonatal rat muscle cells and nonunion cells may respond in a similar fashion to BMP. Bone morphogenetic protein stimulated hyaluronic acid synthesis at three days, but chondroitin sulfate synthesis did not increase until ten days exposure to BMP. These data, together with those summarized above, suggest that more than three days may be required for complete expression of the chondrocyte phenotype typical of endochondral ossification.     

High-density culture of mouse Meckel's cartilage cells stimulates phenotypic conversion to osteocyte-like cells

We examined the influence of cell density on the phenotypic conversion of Meckel's cartilage cells. The cells were isolated by enzymatic digestion and plated at a density of 0.5 × 10⁴ or 2 × 10⁴ cells/penicylinder and cultured under 5% CO₂ in air for up to 4 weeks. The cultures were analyzed histologically by electron microscopy, histochemistry, and immunostaining. At the early stage of high-density culture, metachromatic chondrocytes appeared concomitantly with cartilage-specific type II collagen synthesis. The cells gradually transformed from large polygonal cells to multilayered small round cells, and formed nodules. During the later stage of culture, the cells exhibiting alkaline phosphatase (ALPase) activity, type I collagen, and osteocalcin as bone-type marker proteins consisted of spindle-shaped cells showing phenotypic conversion into osteocyte-like cells in the calcified nodules. In contrast, during low-density culture, most of the cells changed from fibroblastic cells to large flattened cells without cellular nodule formation, but these cells lacked chondrocytic features. Only solitary cells exhibited chondrocyte-specific features such as metachromasia, proteoglycan synthesis, and matrix calcification, but they did not undergo osteocytic transdifferentiation. These results indicate that well-organized nodule-forming cellular and extracellular components in high-density culture stimulate transdifferentiation into osteocyte-like cells.     

Inhibition of bone collagen synthesis by the tumor promoter phorbol 12-myristate 13-acetate

We characterized the effect of the tumor promoter phorbol 12-myristate 13-acetate (PMA) on osteoblast function and DNA synthesis in 21-day-old fetal rat calvaria maintained in organ culture. Protein synthesis was determined by measuring the incorporation of [3H]proline into collagenase-digestible (CDP) and noncollagen protein (NCP), respectively. Alkaline phosphatase activity was assessed as the release of p-nitrophenol from p-nitrophenol phosphate. DNA synthesis was determined by the incorporation of [3H]thymidine into acid-insoluble bone and total DNA content. PMA at 3-100 ng/ml (4-133 nM) caused a dose-related inhibition of collagen synthesis that was observed 6 hours after adding PMA to calvaria. PMA inhibited collagen synthesis in the osteoblast-rich central bone of calvaria but did not alter collagen synthesis in the periosteum. There was little effect of PMA on noncollagen protein synthesis in the central bone or periosteum. Phorbol esters that do not promote tumor formation in vivo did not alter collagen synthesis in calvaria. PMA stimulated prostaglandin E2 (PGE2) production in calvaria, but indomethacin did not alter the inhibitory effect of PMA on bone collagen synthesis. PMA decreased alkaline phosphatase activity measured after 48 hr of culture and increased the incorporation of [3H]thymidine into bone and DNA content after 96 hr of culture. These data indicate that PMA inhibits collagen synthesis and alkaline phosphatase activity, while stimulating DNA synthesis, suggesting that activation of protein kinase C might regulate osteoblast function and bone cell replication.     

Establishment of an osteoinductive murine osteosarcoma clonal cell line showing osteoblastic phenotypic traits

A clonal cell line, BFO-6, was established in culture from a Dunn osteosarcoma cell line (BFO) and characterized on the basis of bone-inducing activity, alkaline phosphatase activity, PTH sensitive cAMP production and tumorigenicity. Lyophilized pellets of devitalized cells, when implanted into the back muscles of allogenic host mice, consistently elicited heterotopic bone formation at 3 weeks postimplantation. BFO-6 cells were found to be rich in alkaline phosphatase activity and showed a significant response to h-PTH stimulation. The doubling time in the logarithmic phase was 17.2 h and the cells revealed an acrocentric karyotype. Subcutaneous transplantation of cells (1 x 10(7) cells) into a C3H mouse resulted in the production of a tumor with histological features of osteosarcoma. This tumor also retained bone-inducing activity and high alkaline phosphatase activity.     

Relationship between collagen synthesis and expression of the osteoblast phenotype in MC3T3-E1 cells.

The MC3T3-E1 mouse calvaria-derived cell line has been used to study the role of collagen synthesis in osteoblast differentiation. MC3T3-E1 cells, like several previously characterized osteoblast culture systems, expressed osteoblast markers and formed a mineralized extracellular matrix only after exposure to ascorbic acid. Mineralization was stimulated further by beta-glycerol phosphate. Ultrastructural observations indicated that the extracellular matrix produced by ascorbic acid-treated cells was highly organized and contained well-banded collagen fibrils. Expression of osteoblast markers followed a clear temporal sequence. The earliest effects of ascorbic acid were to stimulate type I procollagen mRNA and collagen synthesis (24 h after ascorbate addition), followed by induction of alkaline phosphatase (48-72 h) and osteocalcin (96-144 h) mRNAs. Procollagen mRNA, which was expressed constitutively in the absence of ascorbate, increased only twofold after vitamin C addition. In contrast, alkaline phosphatase and osteocalcin mRNAs were undetectable in untreated cultures. Actions of ascorbic acid on osteoblast marker gene expression are mediated by increases in collagen synthesis and/or accumulation because (1) parallel dose-response relationships were obtained for ascorbic acid stimulation of collagen accumulation and alkaline phosphatase activity, and (2) the specific collagen synthesis inhibitors, 3,4-dehydroproline and cis-4-hydroxyproline, reversibly blocked ascorbic acid-dependent collagen synthesis and osteoblast marker gene expression.     

Countercurrent centrifugal elutriation. High-resolution method for the separation of growth-plate chondrocytes

Countercurrent centrifugal elutriation was used to separate, on the basis of size, isolated growth-plate chondrocytes in chicks. The mean cellular volume, activity of alkaline phosphatase, and synthesis of type-X collagen increased progressively in each of seven successive fractions. Slices of tissues that contained either proliferating or hypertrophic chondrocytes were also removed by manual dissection from the superficial and deep regions of the growth plate. These cells demonstrated differences in size and biochemistry that were similar to those observed in chondrocytes that were separated by elutriation. These differences included increased synthesis of proteoglycan and collagen in the larger chondrocytes. Radiolabeled hypertrophic chondrocytes were mixed with unlabeled resting and proliferating chondrocytes, and then were separated by elutriation. The radioactivity was recovered in fractions that contained the largest cells, confirming that differences in the sizes of the cells can be used to effect a zonal separation by centrifugal elutriation.     

A dominant negative cadherin inhibits osteoblast differentiation.

We have previously indicated that human osteoblasts express a repertoire of cadherins and that perturbation of cadherin-mediated cell-cell interaction reduces bone morphogenetic protein 2 (BMP-2) stimulation of alkaline phosphatase activity. To test whether inhibition of cadherin function interferes with osteoblast function, we expressed a truncated N-cadherin mutant (NCaddeltaC) with dominant negative action in MC3T3-E1 osteoblastic cells. In stably transfected clones, calcium-dependent cell-cell adhesion was decreased by 50%. Analysis of matrix protein expression during a 4-week culture period revealed that bone sialoprotein, osteocalcin, and type I collagen were substantially inhibited with time in culture, whereas osteopontin transiently increased. Basal alkaline phosphatase activity declined in cells expressing NCaddeltaC, relative to control cells, after 3 weeks in culture, and their cell proliferation rate was reduced moderately (17%). Finally, 45Ca uptake, an index of matrix mineralization, was decreased by 35% in NCaddeltaC-expressing cells compared with control cultures after 4 weeks in medium containing ascorbic acid and beta-glycerophosphate. Similarly, BMP-2 stimulation of alkaline phosphatase activity and bone sialoprotein and osteopontin expression also were curtailed in NCaddeltaC cells. Therefore, expression of dominant negative cadherin results in decreased cell-cell adhesion associated with altered bone matrix protein expression and decreased matrix mineralization. Cadherin-mediated cell-cell adhesion is involved in regulating the function of bone-forming cells.     

Insulin like growth factor I hormonal regulation by growth hormone and by 1,25(OH)2D3 and activity on human osteoblast-like cells in short-term cultures

IGF-1 has been shown to be locally produced in several tissues and to play a role in the regulation of cellular activity. We have investigated its production in short-term cultures of human bone derived cells, and the regulation of this production by growth hormone (GH) and by 1,25 dihydroxyvitamin D3 (1,25(OH)2D3). Bone cells obtained from surgical bone biopsies produced and secreted IGF-1 in their culture media. In four days cultures of bone-derived cells recombinant human r-IGF-1 at 20 ng/mL increased the alkaline phosphatase activity and the osteocalcin (bone gla protein) secretion, two specific markers of bone formation. This stimulation occurred only in the presence of 1,25(OH)2D3. Human bone cells exposed to GH increased their alkaline phosphatase activity, but no osteocalcin was detectable. However, in the presence of 1,25(OH)2D3 (1 nM), GH in concentrations of 8 to 40 nM increased by 30-50% the alkaline phosphatase activity and by 50 to 100% the osteocalcin secretion of human bone cells. At the same concentrations, GH also increased by 140% endogenous IGF-1 levels in cell culture supernatants, 1,25(OH)2D3 (10 nM) also increased time- and dose-dependently, IGF-1 levels in human bone cell supernatants, and stimulated dose-dependently alkaline phosphatase activity and osteocalcin secretion. It is therefore suggested that by regulating local production of growth factors such as IGF-1, GH and 1,25(OH)2D3 may modulate the metabolism of human bone cells.     

Microcarriers facilitate mineralization in MC3T3-E1 cells

Summary MC3T3-E1 cells showed mineral deposits after about 1 week of culture when incubated in the presence of microcarrier beads. These deposits appeared as white spots on the dish surface, and under light microscopy the cells showed multiple cell layers and mineralization around the microcarriers. The deposits stained positive with calcium-specific Von Kossa's method. Using conventional assay, alkaline phosphatase activity (ALP) and parathyroid hormone-stimulated intracellular cAMP production were lower in the microcarrier cultures than in the control, but using cytochemical methods, high alkaline phosphatase activity was found around the microcarriers. These results indicate that microcarriers facilitated the formation of multiple cell layers and provided a culture environment for mineralization.     

Effects of transforming growth factors beta 1 and beta 2 on a mouse clonal, osteoblastlike cell line MC3T3-E1

Transforming growth factors (TGF-beta 1 and TGF-beta 2) are polypeptide growth factors with a wide range of effects on the growth and differentiated function of a variety of cell types. Transforming growth factors of the beta class (TGF-beta) are found in large quantities in bone matrix and are synthesized by osteoblasts. For these reasons, it has been suggested that TGF-beta may play a major role in the regulation of bone cell metabolism. We have studied the effects of porcine TGF-beta 1 and the recently described porcine TGF-beta 2 in a mouse clonal, osteoblastlike cell line MC3T3-E1 that has previously been shown to have many characteristics of osteoblasts. In serum-containing medium, TGF-beta 1 inhibited alkaline phosphatase activity. The inhibition of alkaline phosphatase activity persisted for at least 72 h following a brief (24 h) exposure to TGF-beta 1. TGF-beta 1 also caused a marked change in cell morphology. High doses inhibited collagen synthesis; lower concentrations caused a small increase. Under serum-free conditions, TGF-beta 1 had biphasic effects on alkaline phosphatase activity inhibiting at high but stimulating at low concentrations and had only a slight stimulatory effect on collagen synthesis. Under the experimental conditions used, the effects of TGF-beta 1 on alkaline phosphatase activity and collagen synthesis were independent of effects on cell proliferation. In serum-containing medium, TGF-beta 2 inhibited alkaline phosphatase activity, an effect that was independent of changes in cell proliferation and caused shape changes in an identical fashion to that observed with TGF-beta 1.