Characterization of bone-derived chondrogenesis-stimulating activity on embryonic limb mesenchymal cells in vitro

Abstract. Demineralized bone matrix contains factors which stimulate chondrogenesis and osteogenesis in vivo. A water-soluble extract of bone has been shown to stimulate chondrogenesis in vitro in embryonic limb mesenchymal cells (Syftestad, Lucas & Caplan, 1985). The aim of this study was to analyse the cellular mechanism of the bone-derived chondrogenesis-stimulating activity, with particular attention on how normal requirements for chondrogenesis may be altered. The effects of bovine bone extract (BBE) on chondrogenesis in vitro were studied using micromass cultures of chick limb bud mesenchyme isolated from embryos at Hamburger-Hamilton (HH) stage 23/24, an experimental system which is capable of undergoing chondrogenic differentiation. Bovine diaphyseal long bones were demineralized and extracted with guanidine-HCl to prepare BBE (Syftestad & Caplan, 1984). High-density mesenchyme cultures (30 times 10⁶ cells/ml) were exposed to different doses of BBE (0–01-1-0 mg ml^-1) and chondrogenesis was quantified based on cartilage nodule number and [³⁵S]sulphate incorporation. BBE was tested on micromass cultures of varying plating densities (2–30 times 10⁶ cells/ml), on cultures of ‘young’ limb bud cells (HH stage 17/18), and on cultures enriched with chondroprogenitor cells obtained from subridge mesoderm. Since poly-L-lysine (PL) has recently been shown (San Antonio & Tuan, 1986) to promote chondrogensis, PL and BBE were introduced together in different doses, in the culture medium, to determine if their actions were synergistic. Our results show that BBE stimulates chondrogenesis in a dose-dependent manner and by a specific, direct action on the chondroprogenitor cells but not in normally non-chondrogenic, low density or ‘young’ limb bud cell cultures. The effects of PL and BBE are additive and these agents appear to act by separate mechanisms to stimulate chondrogenesis; PL primarily enhances nodule formation, and BBE appears to promote nodule growth.     

In VitroDifferentiation Potential of the Periosteal Cells from a Membrane Bone, the Quadratojugal of the Embryonic Chick

The quadratojugal (QJ) is a neural crest-derived membrane bone in the maxillary region of the avian head.In vivoits periosteum undergoes both osteogenesis to form membrane bone and chondrogenesis to form secondary cartilage. This bipotential property, which also exists in some other membrane bones, is poorly understood. The present study used cell culture to investigate the differentiation potential of QJ periosteal cells. Three cell populations were enzymatically released from QJ periostea and plated at different densities. Cell density greatly affected phenotypic expression and differentiation pathways. We found two culture conditions that favored osteogenesis and chondrogenesis, respectively. In micromass culture, the periosteal cells produced a layer of osteogenic cells that expressed alkaline phosphatase (APase) and secreted bony extracellular matrix (ECM). In contrast, low-density monolayer culture elicited chondrogenesis. Cells with pericellular refractile ECM and round shape appeared at 7 to 8 days and formed colonies later. The chondrogenic phenotype of these cells was confirmed by immunolocalization of type II collagen and Alcian blue staining of ECM. This result demonstrated that a fully expressed chondrogenic phenotype can be achieved from membrane bone periosteal cells in primary monolayer culture. Chondrogenesis requires a cell density lower than confluence and cannot be initiated in confluent cultures. Among the three cell populations, those cells from the outer layer have the highest growth rate and require the lowest initial plating density (below 5 × 10³cells/ml) to achieve chondrogenesis. Cells from the inner layer have the slowest growth rate and chondrify at the highest initial density (below 5 × 10⁴cells/ml). Chondrocytes from all populations express distinct phenotypic markers—APase and type I collagen—from initial chondrogenesis, but are not hypertrophic morphologically. Furthermore, the fact that chondrocytes arise within the same colony as APase-positive polygonal cells suggests that chondrocytes may differentiate from precursors related to the osteogenic cell lineage. This cell culture approach mimics secondary cartilage and membrane bone formationin vivo.     

Characterization of bone-derived chondrogenesis-stimulating activity on embryonic limb mesenchymal cells in vitro

Demineralized bone matrix contains factors which stimulate chondrogenesis and osteogenesis in vivo. A water-soluble extract of bone has been shown to stimulate chondrogenesis in vitro in embryonic limb mesenchymal cells (Syftestad, Lucas & Caplan, 1985). The aim of this study was to analyse the cellular mechanism of the bone-derived chondrogenesis-stimulating activity, with particular attention on how normal requirements for chondrogenesis may be altered. The effects of bovine bone extract (BBE) on chondrogenesis in vitro were studied using micromass cultures of chick limb bud mesenchyme isolated from embryos at Hamburger-Hamilton (HH) stage 23/24, an experimental system which is capable of undergoing chondrogenic differentiation. Bovine diaphyseal long bones were demineralized and extracted with guanidine-HCl to prepare BBE (Syftestad & Caplan, 1984). High-density mesenchyme cultures (30 x 10(6) cells/ml) were exposed to different doses of BBE (0.01-1.0 mg ml-1) and chondrogenesis was quantified based on cartilage nodule number and [35S]sulphate incorporation. BBE was tested on micromass cultures of varying plating densities (2-30 x 10(6) cells/ml), on cultures of 'young' limb bud cells (HH stage 17/18), and on cultures enriched with chondroprogenitor cells obtained from subridge mesoderm. Since poly-L-lysine (PL) has recently been shown (San Antonio & Tuan, 1986) to promote chondrogensis, PL and BBE were introduced together in different doses, in the culture medium, to determine if their actions were synergistic. Our results show that BBE stimulates chondrogenesis in a dose-dependent manner and by a specific, direct action on the chondroprogenitor cells but not in normally non-chondrogenic, low density or 'young' limb bud cell cultures. The effects of PL and BBE are additive and these agents appear to act by separate mechanisms to stimulate chondrogenesis; PL primarily enhances nodule formation, and BBE appears to promote nodule growth.     

Evidence for histogenic interactions during in vitro limb chondrogenesis

The requirement for homotypic cell interaction was studied by making chimeric micromass cultures containing various proportions of chick and quail limb mesenchyme. Cultures made from limb mesenchyme from embryos of Hamburger and Hamilton stages 23–24 produce large clumps of cartilage cells, identified by the accumulation of an extracellular matrix which stains with alcian blue at pH 1 and by the ability of cells to take up ³⁵SO₄ rapidly, as demonstrated autoradiographically. Dissociated mesenchyme from stage 19 embryos did not produce cartilage in micromass cultures, but only precartilage cell aggregates. Micromass cultures prepared from mixtures of mesenchyme cells obtained from stage 19 and stages 23–24 embryos contained decreasing numbers of cartilage nodules as the proportion of stage 19-derived mesenchyme increased. At the same time the number of aggregates was not affected. When the ratio of stage 19- to stage 24-derived cells was 3:1 or greater, no nodules were detected. The actual number of cells from each stage was verified by using mixtures of quail and chick cells, which are microscopically distinguishable. Additional evidence suggests that the stage 19-derived mesenchyme inhibits chondrogenesis by passively preventing stage 24-derived cells from interacting. The results presented are consistent with the suggestions that (1) homotypic cell interaction plays a role in limb chondrogenesis and (2) the capacity to interact in the required manner is acquired after the embryos have reached stage 19. These phenomena might be involved in the normal histogenesis of cartilage tissue.     

The patterns on chondrogenesis of cells from facial primordia of chick embryos in micromass culture

Chondrogenesis of mesenchymal cells from the frontonasal mass, mandibles and maxillae of stage-24 chick embryos has been investigated in micromass (high-density) cultures. Distinct differences in the amount and pattern of cartilage differentiation are found. In cultures of frontonasal mass cells, a central sheet of cartilage develops; in cultures of mandible cells, less cartilage differentiates and nodules form; while in cultures of maxillae cells, virtually no chondrogenesis takes place. The same patterns of cartilage are found in cultures established from stage-20 embryos. At stage 28, frontonasal mass cultures form cartilage nodules and the number of nodules in mandible cultures is markedly decreased. There are striking parallels between the chondrogenic patterns of cells from the face and limb buds in micromass culture. The frontonasal mass cell cultures of stage-20 and -24 chick embryos resemble those established from the progress zone of limb buds. The progress zone is an undifferentiated region of the limb in which positional cues operate. Cultures established from the frontonasal mass of stage-28 chick embryos and from the mandibles of all stages resemble cultures of whole limb buds. These contain a mixture of committed and uncommitted cells. Ectoderm from facial primordia locally inhibits chondrogenesis in micromass cultures and this could provide a positional cue. The differences in chondrogenic potential of cells from facial primordia may underlie the specific retinoid effects on the frontonasal mass.     

Chondrogenic differentiation of murine C3H10T1/2 multipotential mesenchymal cells: I. Stimulation by bone morphogenetic protein-2 in high-density micromass cultures

Chondrogenic differentiation of mesenchymal cells is generally thought to be initiated by the inductive action of specific growth factors and depends on intimate cell-cell interactions. In this study, we have used multipotential murine C3H10T1/2 cells to analyze the effect and mechanism of action of bone morphogenetic protein 2 (BMP-2) on chondrogenesis. C3H10T1/2 cells have been previously shown to undergo multiple differentiation pathways. While chondrogenesis, osteogenesis, myogenesis and adipogenesis have been observed, chondrocytes appear significantly less frequently than the other cell types, and the appearance of chondrocytes exclusive of the other cell types has not been observed. We report here that the appearance of chondrocytes in C3H10T1/2 cells is markedly enhanced as a result of culture under conditions favorable for chondrogenesis, i.e. plating as high-density micromass and treatment with BMP-2. Such cultures contain chondrocyte-like cells, elaborate an Alcian blue stained cartilage-like matrix, express link protein and type II collagen, both cartilage matrix markers, and show increased [35S]sulfate incorporation. The appearance of Alcian blue positive material and increased sulfate incorporation are dependent on the dose of BMP-2, culture time, and cell plating density of the micromass cultures. Differentiation of cells within the micromass was specific to the chondrogenic lineage, as alkaline phosphatase staining revealed only faint staining in the micromass at the highest BMP-2 concentration. The importance of enhanced cell-cell interaction in the chondroinductive effects of BMP-2 on high-density C3H10T1/2 cultures was further implicated by the additional promotion of chondrogenesis in the presence of the polycationic compound, poly-L-lysine, which has been previously reported to enhance cellular interactions and chondrogenesis in embryonic limb mesenchymal cells. Taken together, these findings suggest that chondrogenesis in C3H10T1/2 cells is inducible by BMP-2 and requires cell-cell interaction.     

A fraction from extracts of demineralized adult bone stimulates the conversion of mesenchymal cells into chondrocytes

Demineralized adult bone contains factors which stimulate nonskeletal mesenchymal cells to undergo a developmental progression resulting in de novo endochondral ossification. In this study, isolated embryonic stage 24 chick limb bud mesenchymal cells maintained in culture were utilized as an in vitro assay system for detection of specific bioactive components solubilized from adult chicken bone matrix. Guanidinium chloride extracts (4 M) of demineralized-defatted bone were fractionated and tested in limb mesenchymal cell cultures for possible effects upon growth and chondrogenesis. Two low-molecular-weight fractions were found to be active in these cultures. A cold water-insoluble, but warm Trisbuffered saline-soluble fraction provoked a dose-dependent increase in the amount of cartilage formed after 7 days of continuous exposure as evidenced by an increased number of chondrocytes observed in living cultures, elevated cell-layer-associated ³⁵S incorporation per microgram DNA, and greater numbers of toluidine blue-staining foci (i.e., cartilage nodules). Growth inhibitory substances were detected in a low-molecular-weight, water-soluble fraction; 7 days of continuous exposure to this material resulted in less cartilage formation and reduced cell numbers (accumulated DNA) on each plate. These observations demonstrate the usefulness of stage 24 chick limb bud cell cultures for identifying bioactive factors extracted from adult bone matrix. In addition, the action of these factors on mesenchymal cells may now be studied in a cell culture system.     

Evaluation of the sensitive step of inhibition of chondrogenesis by retinoids in limb mesenchymal cells in vitro

The sensitive step of inhibition of chondrogenesis in vitro by retinoids was investigated in modified micromass cultures of limb bud mesenchymal cells from mouse embryos of day 11 and 12. Evaluation of chondrogenesis was performed after alcian blue staining, using a simple random hit counting of cartilage nodules. All-trans-retinoic acid, 13-cis-retinoic acid, and a newly developed arotinoid, RO 13-6298, were tested for their ability to inhibit chondrogenesis. We found that inhibition of chondrogenesis depended on the dosage and the duration of treatment with the different retinoids. Further analysis showed that chondrogenesis in limb bud mesenchymal cells from the proximal part was irreversibly inhibited after one hour of treatment, whereas distal cells showed a reduction of cartilage development only after a treatment period of 12 and more hours. In respect to the doses of the retinoids, proximal cells were about one magnitude more vulnerable than distal cells. These proximo-distal differences were obtained with 13-cis-retinoic acid at 10 micrograms/ml, with all-trans-retinoic acid at 1 microgram/ml and with arotinoid RO 13-6298 with 10 ng/ml. It is supposed that the late blastemal stage of chondrogenic differentiation before the onset of matrix synthesis is the step which is most vulnerable to retinoid treatment.     

Sulfoxide stimulation of chondrogenesis in limb mesenchyme is accompanied by an increase in type II collagen enhancer activity

We have utilized a modification of the limb bud mesenchyme micromass culture system to screen compounds that might stimulate chondrogenesis. Two compounds in the sulfoxide family (methylphenylsulfoxide and p-chlorophenyl methyl sulfoxide) were stimulatory at 10(-2) M and 10(-3) M, respectively; whereas other sulfoxides and organic solvents were not active at these concentrations. In addition, specific growth factors (basic FGF, IGF-I, IGF-II) were not chondroinductive at concentrations that are active in other cell systems. Both sulfoxide compounds stimulated cartilage nodule formation, [35S]sulfate incorporation, and activity of the regulatory sequences of the collagen II gene. In contrast, transforming growth factor beta-1 (10 ng/ml) stimulated sulfate incorporation but produced only a diffuse deposition of cartilage matrix and reduced the ability of the cells to utilize the regulatory sequences of the collagen II gene. The sulfoxides appear to promote the differentiation of limb bud cells to chondrocytes and thus exhibit chondroinductive activity.     

Toxic effects of cyclophosphamide in differentiating chicken limb bud cell culture using rat liver 9,000 g supernatant or rat liver cells as an activation system: an in vitro short-term test for proteratogens

Cells from 4-day chicken embryo limb buds plated as micromass cultures differentiate and form cartilage nodules after a 5- to 6-day growth period. The innate ability of these cells to biotransform compounds, such as cyclophosphamide (CP), into reactive metabolites is apparently inadequate. Protocols used rat liver S9 from Aroclor 1254-pretreated (PCB) rats or hepatocytes from control rats or polychlorinated biphenyls (PCB)-pretreated rats and were added to micromass cultures with CP causing concentration-related toxicity in the cell cultures. Coculturing chicken limb bud cells with PCB-hepatocytes was the most efficient method, yielding an IC50 of 2 micrograms CP per ml. Toxic CP metabolites accumulated in the medium of PCB-hepatocyte cultures and were quite stable. The toxicity of bioactivated CP was nearly identical for both proliferation and cartilage proteoglycan accumulation.     

Inactivation of Patched1 in the Mouse Limb Has Novel Inhibitory Effects on the Chondrogenic Program

The bones of the vertebrate limb form by the process of endochondral ossification, whereby limb mesenchyme condenses to form an intermediate cartilage scaffold that is then replaced by bone. Although Indian hedgehog (IHH) is known to control hypertophic differentiation of chondrocytes during this process, the role of hedgehog signaling in the earlier stages of chondrogenesis is less clear. We have conditionally inactivated the hedgehog receptor Ptc1 in undifferentiated limb mesenchyme of the mouse limb using Prx1-Cre, thus inducing constitutively active ligand-independent hedgehog signaling. In addition to major patterning defects, we observed a marked disruption to the cartilage elements in the limbs of Prx1-Cre:Ptc1^c/c embryos. Using an in vitro micromass culture system we show that this defect lies downstream of mesenchymal cell condensation and likely upstream of chondrocyte differentiation. Despite early increases in levels of chondrogenic genes, soon after mesenchymal condensation the stromal layer of Prx1-Cre:Ptc1^c/c-derived micromass cultures is characterized by a loss of cell integrity, which is associated with increased cell death and a striking decrease in Alcian blue staining cartilage nodules. Furthermore, inhibition of the hedgehog pathway activation using cyclopamine was sufficient to essentially overcome this chondrogenic defect in both micromass and ex vivo explant assays of Prx1-Cre:Ptc1^c/c limbs. These data demonstrate for the first time the inhibitory effect of cell autonomously activated hedgehog signaling on chondrogenesis, and stress the importance of PTC1 in maintaining strict control of signaling levels during this phase of skeletal development.     

Effect of insulin at dilution endpoint concentrations on macromolecular synthesis in normal mouse mammary and human breast cancer epithelial cells

Employing defined media conditions, the insulin sensitivities of mouse mammary gland epithelial cells in primary culture and MCF-7 human mammary epithelial cells were determined. Insulin stimulated the rates of [³H]uridine incorporation into RNA and [³H]leucine incorporation into protein in both primary mouse mammary gland epithelial cell cultures and MCF-7 cell cultures at concentrations approximating the dilution endpoint of the hormone (10⁻²¹ M). Insulin stimulated the rate of [³H]thymidine incorporation into DNA in primary mouse mammary gland epithelial cells at the dilution endpoint concentrations. However, MCF-7 cells required insulin concentrations 100–1000-times that necessary in mouse mammary epithelial cultures to elicit an increased rate of [³H]thymidine incorporation into DNA. Evidence is presented which suggests that the increased rates of uptake of [³H]uridine, [³H]thymidine and [³H]leucine into their respective precursor pools is not responsible for the apparent stimulatation of RNA, DNA and protein synthesis.     

Inhibition of chondrogenesis by retinoic acid in limb mesenchymal cells in vitro: Effects on PGE2 and cyclic AMP concentrations

Effects of retinoic acid (RA) on prostaglandin E₂ (PGE₂) and cyclic AMP (cAMP) concentrations were investigated in high density, micromass cultures of mesenchymal cells derived from chick limb buds. Exposure of cells during the initial 24 h of culture to RA concentrations between 0.05–1.0 μg/ml inhibited chondrogenesis in a dose-dependent manner with 1.0 μg/ml totally inhibiting cartilage formation. Concentrations of PGE₂ and cAMP increased during the prechondrogenic period in control cells in a closely related way and remained elevated throughout the six-day period examined. Addition of RA (0.05 and 0.5 μg/ml) did not significantly alter cAMP concentrations at any time point, but significantly elevated PGE₂ levels relative to control cells in six-day cultures in a concentration-dependent manner. Addition of dibutyryl cAMP enhanced chondrogenesis in control cells between days 3 and 4, but failed to alter the inhibitory effect of RA on chondrogenesis. The results indicate that while PGE₂ and cAMP are important signals in cartilage differentiation, the inhibitory effects of RA on this process are mediated through some other mechanism.     

Osteogenesis in cultures of limb mesenchymal cells

The results of previous reports demonstrated that osteoblasts develop in cultures derived from phenotypically unexpressive stage 24 chick limb mesenchymal cells. The observations reported here suggest that initial cell plating densities may provide environmental conditions deterministic to a particular limb phenotype. Quantitative microscopic studies, histochemical localization of calcium phosphate, and electron microscopy indicate that osteoblasts develop in cultures derived from stage 24 limb mesenchymal cells. Additionally, 1–3% of the cells from stage 24 limbs are associated with mineral deposits when plated at initial high densities (5 × 10⁶ cells per 35-mm culture dish), while more than 50% of the cells are associated with cartilage by Day 9. Cultures plated at intermediate seeding densities (between 2.0 and 2.5 × 10⁶ cells per 35-mm culture dish) have minimal cartilage development, and approximately 20% of the cells are associated with mineral by Day 9. Furthermore, cultures prepared from stage 31 limb mesenchymal cells form well-developed bone nodules with both osteoblasts and osteocytes present, but no cartilage. It is clear from these observations and from a consideration of the initiation of osteogenesisin vivo that the initiation of bone development in the limb is not associated with cartilage development. Based on these studies and observations on the effect of nutrient factors on phenotypic expression in culture, an hypothesis is presented relating differential vascularization and nutrient flow to the determination of limb phenotypesin vivo.     

Chick endogenous lectin enhances chondrogenesis of cultured chick limb bud cells

We have studied the effect of β-d-galactoside-specific lectin purified from 14-day-old chick embryos on the differentiation of the mesenchymal cells dissociated from the limb buds of stage 24 chick embryos, using the micro-mass culture method described previously. When the cells were incubated with the lectin during the initial 12 hr of culture, cell proliferation became slightly activated. The lectin-treated cells formed a greater number of cartilage nodules and incorporated about twice as much as [³⁵S]sulfate per cell than the control cultures. The results of this study show that the chick endogenous lectin promotes cartilage differentiation in vitro and that endogenous lectin may possibly be involved in chondrogenesis in vivo.     

The effects of retinoids on cartilage differentiation in micromass cultures of chick facial primordia and the relationship to a specific facial defect

Retinoids produce facial defects in chicken embryos. Outgrowth of the frontonasal mass with accompanying cartilage differentiation and pattern formation is inhibited. In contrast, the development of the mandibular primordia that give rise to the lower beak proceeds normally. To investigate whether the upper beak defect is based on the inhibition of cartilage differentiation specifically in the frontonasal mass, the effects of retinoids on chondrogenesis in micromass (high density) cultures of cells from facial primordia have been studied. When either 10(-6) M retinoic acid or 10(-8) M (E)-4-[2-(5,6,7,8-tetrahydro-5,5,8,8-tetramethyl-2-napthalenyl-1- propenyl]benzoic acid (TTNPB; a stable retinoid) is added to the culture medium, cartilage differentiation is inhibited. Both frontonasal mass and mandible cultures are equally affected. The concentration of TTNPB found in both facial primordia in vivo, after a treatment that produces the defect, is also about 10(-8) M. This rules out preferential accumulation of the retinoid by the frontonasal mass as an explanation for the defect. In fact, the concentration of retinoid found in vivo, should, from the culture studies, be sufficient to markedly inhibit chondrogenesis in both the frontonasal mass and mandibles. The effects of exposure to retinoids in the intact face appear to be different to those in culture. Furthermore, when cells from retinoid-treated facial primordia are cultured in micromass, the extent and pattern of chondrogenesis in frontonasal mass cultures is identical to that of cells from untreated primordia. Cartilage differentiation in mandible cultures is slightly affected. These findings suggest that retinoids do not produce the specific facial defect by directly interfering with cartilage differentiation.     

Distinct functions of BMP4 and GDF5 in the regulation of chondrogenesis

Bone morphogenetic protein 4 (BMP4) and growth/differentiation factor 5 (GDF5) are closely related protein family members and regulate early cartilage patterning and differentiation. In this study, we compared the functional outcome of their actions systematically at various stages of chondrogenesis in mouse embryonic limb bud mesenchyme grown in micromass cultures. Overall, both growth factors enhanced cartilage growth and differentiation in these cultures. Uniquely, BMP4 not only accelerated the formation and maturation of cartilaginous nodules, but also induced internodular mesenchymal cells to express cartilage differentiation markers. On the other hand, GDF5 increased the number of prechondrogenic mesenchymal cell condensation and cartilaginous nodules, without altering the overall pattern of differentiation. In addition, GDF5 caused a more sustained elevated expression level of Sox9 relative to that associated with BMP4. BMP4 accelerated chondrocyte maturation throughout the cultures and sustained an elevated level of Col10 expression, whereas GDF5 caused a transient increase in Col10 expression. Taken together, we conclude that BMP4 is instructive to chondrogenesis and induces mesenchymal cells toward the chondrogenic lineage. Furthermore, BMP4 accelerates the progression of cartilage differentiation to maturation. GDF5 enhances cartilage formation by promoting chondroprogenitor cell aggregation, and amplifying the responses of cartilage differentiation markers. These differences may serve to fine-tune the normal cartilage differentiation program, and can be exploited for the molecular manipulation in biomimetics.     

Hyaluronic acid bonded to cell-culture surfaces stimulates chondrogenesis in stage 24 limb mesenchyme cell cultures

The influence on the differentiation of stage 24 chick limb mesenchymal cells of hyaluronic acid (HA) covalently bonded onto plastic substrates has been examined. Under control conditions, stage 24 cells express phenotypes related to the initial plating density: When plated at high density (5 X 10(6) cells/35-mm culture dish), these cells express a chondrogenic phenotype collectively visualized as a mound or nodule of cartilage. Cartilage nodules are not found in cultures plated at intermediate or low densities, 2 X 10(6) and 1 X 10(6) cells/35-mm dish, respectively. However, when cells are plated onto HA surfaces, expression of the cartilage phenotype occurs at all three plating densities in roughly comparable frequencies. This increase in cartilage nodule formation does not appear to be due to an increased plating efficiency or increased replication rate. The observed effect is dependent on HA concentration; with an increase in bound HA, an increase in the number of cartilage nodules is observed. Digestion of HA substrates with hyaluronidase abolishes the stimulation in chondrogenesis, while no effect is observed if the HA substrates are treated with either trypsin or alkaline borohydride. No other glycosaminoglycan, except for the HA analog, unsulfated chondroitin, exhibits this unique stimulation of chondrogenic expression. While the rate of radiolabeled sulfate incorporation is dramatically increased with cells plated onto HA substrates, the protein biosynthetic rate, as evidenced by radiolabeled proline incorporation, remains unaffected. This dramatic increase in chondrogenic expression is considered in contrast to the previously reported inhibitory effect of HA substrates on myogenesis. These observations suggest that HA may have a regulatory role in the chondrogenic differentiation of chick limb mesenchymal cells.     

High density micromass cultures of embryonic limb bud mesenchymal cells: An in vitro model of endochondral skeletal development

Summary To study the mechanisms regulating endochondral skeletal development, we examined the characteristics of long-term, high density micromass cultures of embryonic chicken limb bud mesenchymal cells. By culture Day 3, these cells underwent distinct chondrogenesis, evidenced by cellular condensation to form large nodules exhibiting cartilage-like morphology and extracellular matrix. By Day 14, extensive cellular hypertrophy was seen in the core of the nodules, accompanied by increased alkaline phosphatase activity, and the limitation of cellular proliferation to the periphery of the nodules and to internodular areas. By Day 14, matrix calcification was detected by alizarin red staining, and calcium incorporation increased as a function of culture time up to 2 to 3 wk and then decreased. X-ray probe elemental analysis detected the presence of hydroxyapatite. Analogous to growth cartilage developing in vivo, these cultures also exhibited time-dependent apoptosis, on the basis of DNA fragmentation detected in situ by terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate (dUTP) nick end labeling (TUNEL), ultrastructural nuclear morphology, and the appearance of internucleosomal DNA degradation. These findings showed that cellular differentiation, maturation, hypertrophy, calcification, and apoptosis occurred sequentially in the embryonic limb mesenchyme micromass cultures and indicate their utility as a convenient in vitro model to investigate the regulatory mechanisms of endochondral ossification.