The Persistence in the Synthesis of Type H Proteoglycan and Type II Collagen by Chondrocytes Cultured in the Presence of Chick Embryo Extract1

The effect of chick embryo extract on the phenotypic expression of differentiated chondrocytes has been studied in consideration of the fact that these cells are well characterized by certain specific cell products, such as type H proteochondroitin sulfate and type II collagen. In this study, we utilized floating chondrocytes derived from chick embryonic sterna, which can be cultured in suspension with no apparent change in the type of cell products for at least a period of eight weeks, as described in a previous paper (1). In the presence of chick embryo extract in the medium, the floating chondrocytes became attached to the bottom of the culture dish, and the attached cells took on a fibroblast-like appearance. Biochemical analyses of the proteochondroitin sulfate and collagen synthesized by the attached cells revealed that if the culture medium was renewed everyday, the cells having a fibroblast-like appearance continued to synthesize type H proteochondroitin sulfate and type II collagen. When however, the medium was replaced every other day, the synthesis of both proteochondroitin sulfate and collagen by the attached cells switched from the chondrocyte type to the fibroblast type, i.e. the synthesis of type M proteochondroitin sulfate and type I collagen, with little change in the fibroblast-like appearance. The results show that the morphological features of chondrocytes are not necessarily associated with the biochemical properties of these cells, and further suggest that, in chick embryo extract, there is no modulator capable of acting directly on the chondrocytes to bring about phenotypic changes with respect to the synthesis of collagen and proteoglycans.     

Coordinate regulation of collagen and alkaline phosphatase levels in chick embryo chondrocytes

Chick embryo tibial chondrocytes release into their extracellular matrix several species of proteochondroitin sulfate and collagen as well as matrix vesicles that are rich in Ca2+ and alkaline phosphatase and that appear to play a role in the calcification of cartilage. To determine whether there was any parallel regulation of the production of these products, the rates of collagen synthesis by cultured chick embryo tibial chondrocytes were altered, and the resulting changes in proteochondroitin sulfate synthesis and alkaline phosphatase levels in the cells were measured. As the rate of collagen synthesis was increased by adding increasing amounts of ascorbic acid to the culture medium, there was a parallel increase in the level of alkaline phosphatase. Similarly, when the rate of collagen synthesis was inhibited by adding 3,4-dehydroproline to the culture medium, the levels of alkaline phosphatase fell. The alkaline phosphatase in the culture medium was associated with vesicles which appeared to be matrix vesicles. It was recovered quantitatively by filtration through membranes with a pore size of 0.1 mu and measured by solubilizing the alkaline phosphatase from the membrane with detergent and assaying with 4-methylumbelliferyl phosphate as the substrate. When the matrix vesicles from the culture medium were analyzed for collagen types, it was found that only Type X collagen was recovered in this fraction. The implications of the association of Type X collagen and the matrix vesicles, both of which are found primarily in growth plate cartilage in the zone of hypertrophied chondrocytes which is in the process of mineralization, are discussed.     

Biochemical and ultrastructural studies of collagen and proteochondroitin sulfate in normal and nanomelic cartilage.

Biochemical and ultrastructural analysis of the sternal cartilage of chick embryos homozygous for the autosomal recessive gene nanomelia suggest that the mutant cells are functional chondrocytes in all respects except in proteochondroitin sulfate synthesis. Proteochondroitin sulfate synthesized by normal and mutant sterna in vitro was chromatographed on 1% agarose. Two distinct fractions of proteochondroitin sulfate were resolved from both normal and mutant cartilage. In normal cartilage, the major fraction represents approximately 90% of the total material, and in the mutant, this fraction is reduced to 10%, while the second fraction remains unchanged. It is suggested that at the onset of chondrogenesis in the mutant, an augmentation in the syntheis of the major fraction does not occur.Collagen synthesis in the mutant cartilage was analyzed by hydroxyproline determination, carboxymethylcellulose chromatography, and amino acid analysis to determine the percentage hydroxylation of lysine residues. By these procedures, collagen synthesis in the mutant was found to be both quantitatively and qualitatively similar to normal.Ultrastructural studies on the mutant sterna revealed that while the mutant chondrocytes were normal in appearance, the amount of extracellular matrix was decreased. In conjunction with this decrease, there is a severe reduction in the number of proteochondroitin sulfate matrix granules. No differences were observed in the collagen fibrils.     

Induction and prevention of chondrocyte hypertrophy in culture

Primary chondrocytes from whole chick embryo sterna can be maintained in suspension culture stabilized with agarose for extended periods of time. In the absence of FBS, the cells remain viable only when seeded at high densities. They do not proliferate at a high rate but they deposit extracellular matrix with fibrils resembling those of authentic embryonic cartilage in their appearance and collagen composition. The cells exhibit many morphological and biochemical characteristics of resting chondrocytes and they do not produce collagen X, a marker for hypertrophic cartilage undergoing endochondral ossification. At low density, cells survive in culture without FBS when the media are conditioned by chondrocytes grown at high density. Thus, resting cartilage cells in agarose cultures can produce factors required for their own viability. Addition of FBS to the culture media leads to profound changes in the phenotype of chondrocytes seeded at low density. Cells form colonies at a high rate and assume properties of hypertrophic cells, including the synthesis of collagen X. They extensively deposit extracellular matrix resembling more closely that of adult rather than embryonic cartilage.     

Independence of cell shape and loss of cartilage matrix production during retinoic acid treatment of cultured chondrocytes

Retinoic acid has been shown to cause chondrocytes in culture to flatten and to inhibit the synthesis of cartilage specific components. Since the biochemical expression of chondrocytes is considered to be dependent on cell shape, it has been proposed that retinoic acid acts on these cells primarily by causing a change in cell morphology. This hypothesis was tested by culturing chick sternal chondrocytes suspended in methyl cellulose, which prevents cell flattening. Cultures were labeled with [35S]methionine and differentiation was assessed by polyacrylamide gel electrophoresis. The results showed that retinoic acid-treated chondrocytes in suspension remained rounded but synthesized proteins characteristic of flattened or dedifferentiated chondrocytes. Chondrocytes exposed to retinoic acid in suspension became fibroblastic when placed in monolayer culture in the absence of retinoic acid. This effect was irreversible after 2 weeks of culture. These results suggest that retinoic acid has a direct molecular or biochemical effect on the chondrocyte and that the cell shape change is secondary.     

Properties of chick embryo chondrocytes grown in serum-free medium

Chick embryo tibial chondrocyte growth and activities were compared in serum-free and serum-supplemented media. A basal salts medium containing equal volumes of Ham's F-12 and Dulbecco's modified Eagle's medium was supplemented with 10% fetal calf serum or with a mixture of bovine insulin, transferrin, fibroblast growth factor, dexamethasone, a prostaglandin E1 supplement, and a liposome supplement. Chondrocytes grew at identical rates in both media. Insulin, liposomes, and fibroblast growth factor were required for optimum growth in the serum-free medium, but removal of transferrin, dexamethasone, or prostaglandin E1 had little effect on the growth rate. In the serum-supplemented medium, the chondrocytes synthesized Type II collagen, Mr = 59,000 collagen, and both the large, cartilage-specific and the small ubiquitous proteochondroitin SO4 species typically produced by cultured chondrocytes. In the serum-free medium there was a shift toward synthesis of Type I collagen and a loss of the capacity to synthesize Mr = 59,000 collagen and the cartilage-specific proteochondroitin SO4. The loss of capacity for cartilage-specific proteochondroitin SO4 synthesis began immediately after replacement of the serum with the mixture of defined growth factors and the rate of loss was retarded but not reversed when serum was added back in place of the growth factors. When the serum and the mixture of growth factors were added together to the basal medium at the time of cell plating, the chondrocytes grew rapidly and retained their normal phenotype observed in serum-supplemented cultures. Thus, the serum appears to contain factors which are required for retention of the chondrocyte phenotype in culture over and above those factors necessary for cell growth.     

Cell hypertrophy and type X collagen synthesis in cultured articular chondrocytes

Articular cartilage is a permanent tissue whose cells do not normally take part in the endochondral ossification process. To determine whether articular chondrocytes possess the potential to express traits associated with this process such as cell hypertrophy and type X collagen, chondrocytes were isolated from adult chicken tibial articular cartilage and maintained in long-term suspension cultures. As a positive control in these experiments, we used parallel cultures of chondrocytes from the caudal portion of chick embryo sternum. Both articular and sternal chondrocytes readily proliferated and progressively increased in size with time in culture. Many had undergone hypertrophy by 4-5 weeks. Analysis of medium-released collagenous proteins revealed that both articular and sternal chondrocytes initiated type X collagen synthesis between 3 and 4 weeks of culture; synthesis of this macromolecule increased with further growth. Immunofluorescence analysis of 5-week-old cultures showed that about 15% of articular chondrocytes and 30% of sternal chondrocytes produced type X collagen; strikingly, there appeared to be no obvious relationship between type X collagen production and cell size. The results of this study show that articular chondrocytes from adult chicken tibia possess the ability to express traits associated with endochondral ossification when exposed to a permissive environment. They suggest also that the process of cell hypertrophy and initiation of type X collagen synthesis are independently regulated both in articular and sternal chondrocytes.     

Integrins alpha(6A)beta 1 and alpha(6B)beta 1 promote different stages of chondrogenic cell differentiation

The differentiation of chondrocytes and of several other cell types is associated with a switch from the alpha(6B) to the alpha(6A) isoform of the laminin alpha(6)beta(1) integrin receptor. To define whether this event plays a functional role in cell differentiation, we used an in vitro model system that allows chick chondrogenic cells to remain undifferentiated when cultured in monolayer and to differentiate into chondrocytes when grown in suspension culture. We report that: (i) upon over-expression of the human alpha(6B), adherent chondrogenic cells differentiate to stage I chondrocytes (i.e. increased type II collagen, reduced type I collagen, fibronectin, alpha(5)beta(1) and growth rate, loss of fibroblast morphology); (ii) the expression of type II collagen requires the activation of p38 MAP kinase; (iii) the over-expression of alpha(6A) induces an incomplete differentiation to stage I chondrocytes, whereas no differentiation was observed in alpha(5) and mock-transfected control cells; (iv) a prevalence of the alpha(6A) subunit is necessary to stabilize the differentiated phenotype when cells are transferred to suspension culture. Altogether, these results indicate a functional role for the alpha(6B) to alpha(6A) switch in chondrocyte differentiation; the former promotes chondrocyte differentiation, and the latter is necessary in stabilizing the differentiated phenotype.     

Formation of cartilage tissue in vitro

Articular cartilage is notoriously defective in its capacity for self-repair, making joints particularly sensitive to degenerative processes. However, methods are now available for the preparation of large numbers of differentiated chondrocytes from a small biopsy sample from any patient. The cells are amplified by proliferation as fibroblast-like cells that will re-express the cartilage phenotype when placed in suspension or gel culture. The chondrocytes can be collected from gel cultures after agarase treatment and reconstituted into cartilage tissue in pellet cultures. In addition, these chondrocytes can be suspended in an appropriate delivery vehicle and implanted into defect sites with a high reparative success rate in an animal model. Appropriate procedures can now be tested in appropriate patient populations.     

Constitutive myc expression impairs hypertrophy and calcification in cartilage.

The myc oncogene is expressed by proliferating quail embryo chondrocytes (QEC) grown as adherent cells and is repressed in QEC maintained in suspension culture. To investigate the interference of myc expression during chondrocyte differentiation, QEC were infected with a retrovirus carrying the v-myc oncogene (QEC-v-myc). Uninfected or helper virus-infected QEC were used as control. In adherent culture, QEC-v-myc displayed a chondrocytic phenotype and synthesized type II collagen and Ch21 protein, while control chondrocytes synthesized type I and type II collagen with no Ch21 protein detected as long as the attachment to the plastic was kept. In suspension culture, QEC-v-myc readily aggregated and within 1 week the cell aggregates released small single cells; still they secreted only type II collagen and Ch21 protein. In the same conditions control cell aggregates released hypertrophic chondrocytes producing type II and type X collagens and Ch21 protein. In the appropriate culture conditions, QEC-v-myc reconstituted a tissue defined as nonhypertrophic, noncalcifying cartilage by the high cellularity, the low levels of alkaline phosphatase enzymatic activity, and the absence of type X collagen synthesis and of calcium deposition. We conclude that the constitutive expression of the v-myc oncogene keeps chondrocytes in stage I (active proliferation and synthesis of type II collagen) and prevents these cells from reconstituting hypertrophic calcifying cartilage.     

Synthesis of a fluorogenic mucopolysaccharide by chondrocytes in cell culture with 4-methylumbelliferyl β-d-xyloside

Culture of chondrocytes in the presence of 4-methylumbelliferyl β-d-xyloside resulted in a synthesis of protein-free, fluorogenic chondroitin sulfate which was heterogeneous on DEAE-cellulose chromatography. Degradation of the major chromatographic fraction with chondroitinase-ABC yielded, in addition to a large quantity of Δ⁴-glucuronic acid-containing disaccharides, two flurogenic oligosaccharides of different size. Quantitative analysis showed that Δ⁴-glucuronic acid, galactose, xylose, and 4-methylumbelliferone were present in the small oligosaccharide fragment in a molar ratio of 1:2:1:1. Since these analytical data are analogous to those reported for glycopeptides derived from proteochondroitin sulfates, it may be suggested that 4-methylumbelliferyl β-d-xyloside replaces the need for xylosyl protein core in the normal synthesis of proteochondroitin sulfate with a resultant production of the unusual polysaccharide bearing the added xyloside at the reducing end.     

The culture of chick embryo chondrocytes and the control of their differentiated functions in vitro. I. Characterization of the chondrocyte-specific phenotypes

We have maintained chick embryo chondrocytes in culture for more than 2 months, passaging the floating cells in the absence of ascorbic acid. Throughout the culture period some of the cells attached to the dish, assuming an epithelial-like morphology and subsequently giving rise to new floating cells. The interconversion of the two cell populations was highest in primaries and decreased with the aging of the culture. Cartilage cells synthesized pro-alpha 1 (II) collagen and sulphated proteoglycans in vitro; compared with floaters, the epithelial-like cells secreted relatively large amounts of fibronectin. When ascorbic acid was added to the medium, all cells attached, maintaining their rounded shape; in this condition the pro-alpha, (II) collagen was matured and collagen fibres were detectable outside the cells. Other specific proteins synthesized by the chondrocytes in culture were also identified. One of these, a 64 K collagenase-sensitive protein, was not related to the type II collagen and may represent a new collagen type.     

In vitro differentiation of mouse embryo chondrocytes: requirement for ascorbic acid.

Chondrocytes enzymatically dissociated from 13-day-old mouse embryo tibia grow in monolayer culture with a fibroblast-like phenotype and express high levels of type I collagen. Chondrogenesis can be induced by transferring the adherent cells in suspension culture and maintaining them in the constant presence of mouse embryo extract. Round shaping of the cells and formation of multicellular aggregates rapidly follow the passage in anchorage-independent conditions. Cell differentiation is evidenced by a marked decrease in the level of type I collagen and by the induction of type II collagen which accumulates when ascorbic acid is included in the culture medium. The addition of the vitamin also triggers the aggregated chondrocytes to organize their extracellular matrix giving rise to a structure closely resembling the in vivo developing cartilage.     

Cell proliferation, extracellular matrix mineralization, and ovotransferrin transient expression during in vitro differentiation of chick hypertrophic chondrocytes into osteoblast-like cells

Differentiation of hypertrophic chondrocytes toward an osteoblast-like phenotype occurs in vitro when cells are transferred to anchorage- dependent culture conditions in the presence of ascorbic acid (Descalzi Cancedda, F., C. Gentili, P. Manduca, and R. Cancedda. 1992. J. Cell Biol. 117:427-435). This process is enhanced by retinoic acid addition to the culture medium. Here we compare the growth of hypertrophic chondrocytes undergoing this differentiation process to the growth of hypertrophic chondrocytes maintained in suspension culture as such. The proliferation rate is significantly higher in the adherent hypertrophic chondrocytes differentiating to osteoblast-like cells. In cultures supplemented with retinoic acid the proliferation rate is further increased. In both cases cells stop proliferating when mineralization of the extracellular matrix begins. We also report on the ultrastructural organization of the osteoblast-like cell cultures and we show virtual identity with cultures of osteoblasts grown from bone chips. Cells are embedded in a dense meshwork of type I collagen fibers and mineral is observed in the extracellular matrix associated with collagen fibrils. Differentiating hypertrophic chondrocytes secrete large amounts of an 82-kD glycoprotein. The protein has been purified from conditioned medium and identified as ovotransferrin. It is transiently expressed during the in vitro differentiation of hypertrophic chondrocytes into osteoblast-like cells. In cultured hypertrophic chondrocytes treated with 500 nM retinoic acid, ovotransferrin is maximally expressed 3 d after retinoic acid addition, when the cartilage-bone-specific collagen shift occurs, and decays between the 5th and the 10th day, when cells have fully acquired the osteoblast-like phenotype. Similar results were obtained when retinoic acid was added to the culture at the 50 nM "physiological" concentration. Cells expressing ovotransferrin also coexpress ovotransferrin receptors. This suggests an autocrine mechanism in the control of chondrocyte differentiation to osteoblast-like cells.     

Alteration of viscoelastic properties is associated with a change in cytoskeleton components of ageing chondrocytes from rabbit knee articular cartilage

The cytoskeleton network is believed to play an important role in the biomechanical properties of the chondrocyte. Ours and other laboratories have demonstrated that chondrocytes exhibit a viscoelastic solid creep behavior in vitro and that viscoelastic properties decrease in osteoarthritic chondrocytes. In this study, we aimed to understand whether the alteration of viscoelastic properties is associated with changes in cytoskeleton components of ageing chondrocytes from rabbit knee articular cartilage. Three age groups were used for this study: young (2-months-old, N=23), adult (8-months-old, N=23), and old (31-months-old, N=23) rabbit groups. Cartilage structure and proteoglycan and type II collagen content were determined by H&E and Toluidine Blue staining, and type II collagen antibody. The detailed structure of the chondrocytes in all groups was visualized using transmission electron microscopy (TEM). Chondrocytes were isolated from full-thickness knee cartilage of rabbits from all groups and their viscoelastic properties were quantified within 2 hours of isolation using a micropipette aspiration technique combined with a standard linear viscoelastic solid model. The components and network of the cytoskeleton within the cells were analyzed by laser scanning confocal microscopy (LSCM) with immunofluorescence staining as well as real time PCR and western blotting. With ageing, articular cartilage contained less chondrocytes and less proteoglycans and type II collagen. TEM observations showed that the cell membranes were not clearly defined, organelles were fewer and the nuclei were deformed or shrunk in the old cells compared with the young and adult cells. In suspension, chondrocytes from all three age groups showed significant viscoelastic creep behavior, but the deformation rate and amplitude of old chondrocytes were increased under the same negative pressure when compared to young and adult chondrocytes. Viscoelastic properties of the old cells, including equilibrium modulus (E infinity), instantaneous modulus (E0) and apparent viscosity (mu) were significantly lower than that those of the young and adult ones (P < 0.001). No significant differences were detected between young and adult chondrocytes (P > 0.05). Moreover, we found that the cytoskeletal networks of old cells were sparser, and that the contents of the various components of the intracellular networks were reduced in old cells, compared with adult and young cells. Aged chondrocytes had a different response to mechanical stimulation when compared to young and adult chondrocytes due to alteration of their viscoelastic properties, which was in turn associated with changes in cell structure and cytoskeleton composition.     

Cartilage-specific 5' end of chick alpha 2(I) collagen mRNAs

Chondrocytes grown in suspension contain both type I and type II collagen mRNAs, yet synthesize only type II collagen. The inability of chondrocytes to synthesize the alpha 2 subunit of type I collagen, alpha 2(I), results from a severely reduced translation elongation rate (Bennett, V.D., and Adams, S.L. (1987) J. Biol. Chem. 262, 14806-14814). Furthermore, the alpha 2(I) collagen mRNAs from chondrocytes are translated inefficiently in vitro and appear slightly smaller than those from other cells (Focht, R.J., and Adams, S.L. (1984) Mol. Cell. Biol. 4, 1843-1852). These observations suggest that the reduced translation elongation rate may be due to an intrinsic property of the mRNAs. In this report we demonstrate that the alpha 2(I) collagen mRNAs from suspended chondrocytes are 120 bases shorter than those from other cells, and that the first 94 bases of the chondrocyte mRNAs differ from the corresponding region of the calvaria mRNAs. The unique 5' end of the chondrocyte alpha 2(I) collagen mRNAs accounts for their smaller size and may be responsible for the translation elongation defect. Interestingly, the alpha 2(I) collagen mRNAs from chondrocytes grown in monolayer, rather than in suspension, no longer display the cartilage-specific 5' end, suggesting that cell shape and/or adhesion may modulate the structure of the 5' end of the chondrocyte alpha 2(I) collagen mRNAs.