Development and phenotypic characterization of a high density in vitro model of auricular chondrocytes with applications in reconstructive plastic surgery

Cultivation of phenotypically stable auricular chondrocytes will have applications in autologous chondrocyte transplantation and reconstructive surgery of cartilage. Chondrocytes grown in monolayer culture rapidly dedifferentiate assuming a fibroblast-like morphology and lose their cartilage-specific pattern of gene expression. Three-dimensional high-density culture models mimic more closely the in vivo conditions of cartilage. Therefore, this study was undertaken to test whether the high-density cultures might serve as a suitable model system to acquire phenotypically and functionally differentiated auricular chondrocytes from porcine cartilage. Freshly isolated porcine auricular chondrocytes were cultured for 7 passages in monolayer culture. From each passage (passage 0 and 1-7) cells were introduced to high-density cultures and examined by transmission electron microscopy. Western blotting was used to analyse the expression of cartilage-specific markers, such as collagen type II and cartilage specific proteoglycan, fibronectin, cell adhesion and signal transduction receptor beta1-integrin, matrix metalloproteinases (MMP-9, MMP-13), cyclo-oxygenase (COX)-2 and the apoptosis commitment marker, activated caspase-3. When dedifferentiated auricular chondrocytes from monolayer passages 0-4 were cultured in high-density culture, they recovered their chondrocytic phenotype and formed cartilage nodules surrounded by fibroblast-like cells and synthesised collagen type II, proteoglycans, fibronectin and beta1-integrins. However, chondrocytes from monolayer passages 5-7 did not redifferentiate to chondrocytes even when transferred to high-density culture, and did not synthesize a chondrocyte-specific extracellular matrix. Instead, they produced increasing amounts of MMP-9, MMP-13, COX-2, activated caspase-3 and underwent apoptosis. Three-dimensional high-density cultures may therefore be used to obtain sufficient quantities of fully differentiated auricular chondrocytes for autologous chondrocyte transplantation and reconstructive plastic surgery.     

Molecular and immunologic differences in canine fibronectins from articular cartilage and plasma

Two new monoclonal antibodies (Mabs) which reacted with canine fibronectin were produced and characterized. Data supported the conclusion that the epitope recognized by Mab 1H9A4 is within the first three Type III homology repeats of the Hep 2 domain and that the epitope for Mab 13G3B7 is within the last Type III homology repeat of fibronectin. These antibodies, along with three others, Mabs IST-2, IST-7, and IST-9, produced and characterized in the laboratories of L. Zardi of Genoa, Italy, were used to characterize canine cartilage and plasma fibronectin. In addition, cartilage explants were labeled with [35S]methionine in order to characterize newly synthesized cartilage fibronectin. The following observations were made. (i) Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (NaDodSO4-PAGE) of reduced canine plasma fibronectin revealed a characteristic doublet; reduced cartilage fibronectin revealed two major bands and one minor band. The lower molecular weight band was 10 kDa less than the beta subunit of plasma fibronectin. In Western blots, this band stained with Mab 1H9A4 but failed to react with Mab 13G3B7. (ii) Western blots of thermolysin and trypsin digests of cartilage fibronectin revealed cleavage patterns which differed from those obtained from digestions of plasma fibronectin. (iii) The ED-A sequence, detected by Mab IST-9, was present in less than 2% of the cartilage fibronectins. (iv) NaDodSO4-PAGE of purified and reduced 35S-labeled fibronectin revealed two major radioactive bands and one minor radioactive band which comigrated with the fibronectin from the cartilage but not with plasma fibronectin. We concluded that like "cellular" fibronectin, the ratio of alpha-type subunits to beta subunits was greater than 4 to 1 in cartilage fibronectin compared to 1.25 to 1 for plasma fibronectin; however, cartilage fibronectin was not a cellular fibronectin by the criterion of the presence of the ED-A sequence. Another difference between plasma and cartilage fibronectin was the presence in cartilage fibronectin of a subpopulation of subunits on which the last Type III homology repeat could not be detected. Biosynthetic data were consistent with the concept that cartilage fibronectin originates from local synthesis by the chondrocyte.     

Butyric acid causes morphological changes in cultured chondrocytes through alterations in the extracellular matrix

Butyric acid induces characteristic changes in the morphology of chick embryo chondrocytes. Chick embryo chondrocytes when cultured in the absence of butyrate exhibit a spherical morphology and synthesize cartilage-specific chondroitin sulfate proteoglycan (CSPG). When these cultures are initiated and maintained in the presence of butyric acid, chondrocytes exhibit a mesenchymal morphology, a 90% reduction in the synthesis of CSPG, and a 75% reduction in DNA synthesis. The reduced synthesis of CSPG and DNA was shown not to be dependent on the morphological change. Chondrocytes require CSPG in order to express a spherical morphology, since including chondroitinase ABC in the culture media caused the cells to spread. In addition, the treatment of chondrocytes with purified CSPG prior to culture in media containing butyric acid resulted in spherical cells. The butyrate-induced spreading was shown to require either serum or fibronectin and could be prevented with antiserum against chick cell-surface fibronectin (cFn). Cell-surface fibronectin, which was present on both spherical and flattened chondrocytes, organized into fibrils beneath cells which spread. Increased fibronectin synthesis was not responsible for the butyrate-induced morphological change. From this evidence, it is concluded that the mechanism by which butyrate alters the morphology of these cells in culture involves inhibiting CSPG synthesis, thus preventing CSPG accumulation in the extracellular matrix (ECM). The absence of CSPG in the ECM allows fibronectin to mediate spreading of chondrocytes in culture.     

Synthesis and extracellular deposition of fibronectin in chondrocyte cultures. Response to the removal of extracellular cartilage matrix

Fibronectin, the major cell surface glycoprotein of fibroblasts, is absent from differentiated cartilage matrix and chondrocytes in situ. However, dissociation of embryonic chick sternal cartilage with collagenase and trypsin, followed by inoculation in vitro reinitiates fibronectin synthesis by chondrocytes. Immunofluorescence microscopy with antibodies prepared against plasma fibronectin (cold insoluble globulin [CIG]) reveals fibronectin associated with the chondrocyte surface. Synthesis and secretion of fibronectin into the medium are shown by anabolic labeling with [35S]methionine or [3H]glycine, and identification of the secreted proteins by immunoprecipitation and sodium dodecyl sulfate (SDS)-disc gel electrophoresis. When chondrocytes are plated onto tissue culture dishes, the pattern of surface-associated fibronectin changes from a patchy into a strandlike appearance. Where epithelioid clones of polygonal chondrocytes develop, only short strands of fibronectin appear preferentially at cellular interfaces. This pattern is observed as long as cells continue to produce type II collagen that fails to precipitate as extracellular collagen fibers for some time in culture. Using the immunofluorescence double-labeling technique, we demonstrate that fibroblasts as well as chondrocytes which synthesize type I collagen and deposit this collagen as extracellular fibers show a different pattern of extracellular fibronectin that codistributes in large parts with collagen fibers. Where chondrocytes begin to accumulate extracellular cartilage matrix, fibronectin strands disappear. From these observations, we conclude (a) that chondrocytes synthesize fibronectin only in the absence of extracellular cartilage matrix, and (b) that fibronectin forms only short intercellular "stitches" in the absence of extracellular collagen fibers in vitro.     

The splicing pattern of fibronectin mRNA changes during chondrogenesis resulting in an unusual form of the mRNA in cartilage

Chondrogenesis, the differentiation of mesenchyme into cartilage, results in a change in composition of the extracellular matrix. The cartilage matrix contains several unique components, including type II collagen and chondroitin sulfate proteoglycan; it also contains fibronectin, a glycoprotein that mediates the interaction of cells with their matrix. We show that chick cartilage fibronectin mRNA contains an unusual pattern of alternatively spliced exons. Specifically, it contains exon IIIB but does not contain exon IIIA whereas fibronectin mRNA from mesenchyme contains both exons IIIB and IIIA. Thus the splicing pattern of the fibronectin mRNA must change from B+A+ to B+A- during chondrogenesis. Most fibronectin mRNA in other mesenchymal tissues contains exon IIIA but little exon IIIB (B-A+). Culturing of chondrocytes (cartilage-producing cells) results in loss of exon IIIB from fibronectin mRNA (B-A-). Manipulation of culture conditions to produce more adhesive chondrocytes (treatment with hyaluronidase, transformation with Rous sarcoma virus, and treatment with retinoic acid) increases the amount of fibronectin mRNA containing exon IIIA. These results suggest that exon IIIB may mediate the interactions of chondrocytes with the unique components of the cartilage matrix and exon IIIA may play a role in chondrocyte adhesion.     

Chondrocyte transplantation for osteochondral defects with the use of suspension culture

Cartilage graft is considered to be useful in repairing chondral or osteochondral defects. One method of the cartilage graft is achieved by autologous chondrocyte transplantation following cell culture. However, chondrocytes change their phenotype during culture. We used costal chondrocytes cultured over agarose (suspension culture) as a source of graft materials. The suspension-cultured chondrocytes formed aggregate in culture. We first examined the expressions of cartilage-specific matrices of cultured chondrocytes after two weeks in culture. The chondrocytes cultured over agarose expressed more type II collagen mRNA than those cultured on plastic dishes did after two weeks in culture. Safranin O staining showed the presence of glycosaminoglycans in the chondrocyte culture over agarose, while glycosaminoglycans were not observed in the culture on plastic dishes. We then examined the changes of rat articular osteochondral defects after transplantation of suspension-cultured chondrocytes. The aggregate of suspension-cultured chondrocytes was easily picked up with forceps and transplanted in the osteochondral defects. The defects were filled with safranin O-stained hyaline cartilage tissue two weeks after chondrocyte transplantation. On the contrary, the fibrous materials, which were not stained with safranin O, were observed in the control defects. These results suggest that the suspension-cultured chondrocytes are useful for autologous cartilage grafts by preserving chondrocyte phenotype.     

Differing in vitro biology of equine,ovine, porcine and human articular chondrocytes derived from the knee joint: an immunomorphological study

For lack of sufficient human cartilage donors, chondrocytes isolated from various animal species are used for cartilage tissue engineering. The present study was undertaken to compare key features of cultured large animal and human articular chondrocytes of the knee joint. Primary chondrocytes were isolated from human, porcine, ovine and equine full thickness knee joint cartilage and investigated flow cytometrically for their proliferation rate. Synthesis of extracellular matrix proteins collagen type II, cartilage proteoglycans, collagen type I, fibronectin and cytoskeletal organization were studied in freshly isolated or passaged chondrocytes using immunohistochemistry and western blotting. Chondrocytes morphology, proliferation, extracellular matrix synthesis and cytoskeleton assembly differed substantially between these species. Proliferation was higher in animal derived compared with human chondrocytes. All chondrocytes expressed a cartilage-specific extracellular matrix. However, after monolayer expansion, cartilage proteoglycan expression was barely detectable in equine chondrocytes whereby fibronectin and collagen type I deposition increased compared with porcine and human chondrocytes. Animal-derived chondrocytes developed more F-actin fibers during culturing than human chondrocytes. With respect to proliferation and extracellular matrix synthesis, human chondrocytes shared more similarity with porcine than with ovine or equine chondrocytes. These interspecies differences in chondrocytes in vitro biology should be considered when using animal models.     

Thrombospondin is present in articular cartilage and is synthesized by articular chondrocytes

Thrombospondin, a multifunctional adhesive glycoprotein originally identified in platelets, was isolated and identified from an extract of ovine articular cartilage. Immunoreactive material from a cartilage extract comigrated on gel electrophoresis with purified human platelet thrombospondin. When articular chondrocytes were cultured in the presence of 35S-methionine, metabolically labeled thrombospondin was immunoprecipitated from the culture medium and cell layer extract. These results demonstrate that thrombospondin is present in articular cartilage and is synthesized by articular chondrocytes.     

Expression of ICAM-1 on intact cartilage and isolated chondrocytes

Summary A major factor in cellular cytotoxicity is the interaction between LFA-1 on leukocytes and ICAM-1 on targets. Because several inflammatory cartilage diseases are characterized by the presence of leukocyte infiltrates, the expression of ICAM-1 on human cartilage, cultured chondrocytes, and transplanted cartilage was investigated using monoclonal antibodies. Frozen tissue sections, chondrocytes in suspension, as well as total cellular mRNA were prepared from human cartilage samples. ICAM-1 expression was studied with two different monoclonal antibodies directed against ICAM-1 by immunohistochemical APAAP-staining and additional flow cytometric analyses. The expression of ICAM-1-mRNA in cartilage tissue was analyzed using the northern blot hybridization technique. Furthermore, chondrocytes were treated in culture with interleukin-1 (IL-1) and gamma-interferon (gamma-IFN). ICAM-1 expression after culture was quantified using flow cytometric analysis. We could detect ICAM-1 mRNA in cartilage tissue, however, the immunostaining of tissue sections using monoclonal antibodies did not give clear positive reactions. Isolated chondrocytes showed strongly positive staining patterns in comparison with adequate negative controls as assessed by flow cytometry. A dose-dependent increase of the expression of ICAM-1 on chondrocytes was observed when stimulated with IL-1 and gamma-IFN. Finally, two of the three studied transplanted autologous cartilage samples with advanced resorption showed the presence of ICAM-1 molecules as assessed by immunohistochemistry. This expression of ICAM-1 suggests that the molecule plays a role in severe cartilage inflammatory processes, where tissue damage leads to the exposure of chondrocyte surfaces.     

Expression of the human chondrocyte phenotype in vitro

Summary We report a culture scheme in which human epiphyseal chondrocytes lose their differentiated phenotype in monolayer and subsequently reexpress the phenotype in an agarose gel. The scheme is based on a method using rabbit chondrocytes. Culture in monolayer allowed small quantities of cells to be amplified and provided a starting point to study expression of the differentiated human chondrocyte phenotype. The cells cultured in monolayer produced type I procollagen, fibronectin, and small noncartilaginous proteoglycans. Subsequent culture in agarose was associated with the acquisition of typical chondrocyte ultrastructural features and the synthesis of type II collagen and cartilage-specific proteoglycans. The switch from the nonchondrocyte to the differented chondrocyte phenotype occurred under these conditions between 1 and 2 wk of agarose culture and was not necessarily homogeneous throughout a culture. This culture technique will facilitate direct investigation of human disorders of cartilage that have been addressed in the past by alternative approaches. This research is supported in part by research grants from the National Institutes of Health, (HD 20691) Bethesda, MD, and Shriners of North America (15953).     

ATP in the mechanotransduction pathway of normal human chondrocytes

Extracellular nucleotides have been shown to have diverse effects on chondrocyte function, generally acting via P2 purinoceptors. We have previously shown that mechanical stimulation at 0.33 Hz of normal human chondrocyte cultures causes cellular hyperpolarisation, while chondrocytes derived from osteoarthritic (OA) cartilage depolarise. Experiments have been undertaken to establish whether ATP is involved in the response of the chondrocyte to mechanical stimulation. Chondrocytes, isolated from normal and OA cartilage obtained, with consent, from human knee joints following surgery, were cultured in non-confluent monolayer. Cells were mechanically stimulated at 0.33 Hz for 20 minutes at 37 degrees C in the presence or absence of inhibitors of ATP signalling, or were stimulated by the addition of exogenous ATP or derivatives, and electrophysiological measurements recorded. Samples of medium bathing the cells were collected before and after mechanical stimulation, and the concentration of ATP in the cell medium was measured. Total RNA was extracted from cultured chondrocytes, reverse-transcribed and used for RT-PCR with primers specific for P2Y2 purinoceptors. ATP, UTP 2-methylthioadenosine and alphabeta-methylene adenosine 5'-triphosphate all induced a hyperpolarisation response in normal human articular chondrocytes. No significant change was observed in the membrane potentials of chondrocytes isolated from OA cartilage following the addition of these nucleotides to the medium. In normal chondrocytes, the hyperpolarisation induced by ATP was blocked by the presence of apamin, indicating the involvement of small-conductance calcium-activated potassium channels. Following mechanical stimulation of normal chondrocytes, an increase was observed in ATP concentration in the cell culture medium bathing the cells. The presence within the culture medium of suramin or pyridoxal-phosphate-6-azophenyl-2',4'-disulphonic acid (PPADS) prior to and during the period of mechanical stimulation abolished the hyperpolarisation response in normal chondrocytes. The presence of mRNA for P2Y2 purinoceptors was demonstrated in both normal and OA chondrocytes by RT-PCR. These results suggest that ATP has a role in the response of normal chondrocytes to mechanical stimulation, via P2Y2 purinoceptors. This response appears to be different in chondrocytes derived from OA cartilage, and may be important in the progression of this disease.     

Adenoviral transduction is more efficient in alginate-derived chondrocytes than in monolayer chondrocytes

Gene transfer into cultured chondrocytes by using adenoviral vectors has potential applications in treating cartilage disorders. The present study was undertaken to compare and optimize two chondrocyte culture conditions for adenoviral transduction efficacy by using primary human articular chondrocytes cultivated either directly in a monolayer condition or as outgrowths from alginate-stored chondrocyte cultures. Isolated primary chondrocytes from human articular cartilage were either immediately transduced with an EGFP (enhanced green fluorescent protein)-gene-bearing adenoviral vector (1,000 and 3,000 virus particles/cell) or cultured in alginate before transduction. Immunohistochemistry and flow cytometric analysis were employed to determine the expression of extracellular matrix proteins and of the αvβ5 integrin receptor involved in adenoviral cell entry. Monolayer chondrocytes exhibited moderate transduction rates (mean 22.2% and 46.9% EGFP-positive cells at 1,000 and 3,000 virus particles/cell by 72 h post-transduction), whereas alginate-derived chondrocytes revealed significantly higher transduction efficacies (95.7% and 99%). Both monolayer and alginate-derived chondrocytes expressed αvβ5 integrin, type II collagen and cartilage proteoglycans. The mean fluorescence intensity of type II collagen was significantly higher in the alginate-derived chondrocytes, whereas that of αvβ5 integrin was higher in the monolayer chondrocytes. Our results indicate that transduction efficacy is independent of αvβ5 integrin expression levels in chondrocytes. Moreover, adenoviral transduction of alginate-derived chondrocytes is more efficient than that for monolayer chondrocytes and may be a suitable tool to achieve sufficient numbers of transduced and differentiated chondrocytes for experimental applications and cartilage repair. Dr. Gundula Schulze-Tanzil is supported by a grant awarded by the Rahel Hirsh Foundation from the Charité Medical Schools Berlin. The study was supported by a grant from the Deutsche Arthrosehilfe e.V.     

Retinoids and synovial factor(s) stimulate the production of plasminogen activator by cultured human chondrocytes. A possible role for plasminogen activator in the resorption of cartilage in vitro

Agents such as retinol, interleukin 1 and catabolin stimulate resorption of cultured cartilage. This process seems to be mediated by chondrocytes, but the mechanism by which breakdown occurs remains unknown. We have found that (10(-6)-10(-8) M) retinoic acid and (1 X 10(-6) M) retinol, in the presence or absence of a factor derived from cultured synovium (synovial factor), stimulate the degradation of fibrin by human chondrocytes in culture. Plasminogen was required for the enhancement of fibrinolysis, suggesting that the breakdown depended upon the production of plasminogen activators and subsequent liberation of plasmin. However, the chondrocytes did not release significant amounts of plasminogen activator, and the effects of the synovial factor and retinoids resulted from augmentation of the production or activity of enzymes which remained bound to the cell layer. The role of plasminogen in the resorption of cultured cartilage was also investigated. In the presence of plasminogen, (1 X 10(-8) M) retinoic acid or synovial factor stimulated the breakdown of cultured bovine nasal cartilage, but in the absence of plasminogen, the effect of synovial factor was abolished and that of retinoic acid reduced. However, in cultures containing both retinoic acid and synovial factor the resorption process was not affected by removal of plasminogen. Thus, the resorption of cartilage matrix in vitro may be partially mediated by plasminogen activators and plasmin.     

Gene expression by human articular chondrocytes cultured in alginate beads.

Culture of articular chondrocytes in alginate beads offers several advantages over culture in monolayer; cells retain their phenotype for 8 months or longer. Earlier studies of chondrocytes cultured in alginate concentrated on collagen and proteoglycan synthesis. However, gene expression by in situ hybridization (ISH) has not been investigated. The purposes of the present study on human chondrocytes were (a) to modify the ISH procedure for the alginate beads to examine the mRNA expression of alpha1 (II) procollagen, aggrecan, and two matrix metalloproteinases (MMP-3 and MMP-8) thought to be involved in cartilage matrix degradation, and (b) to compare expression in cultured chondrocytes with that in chondrocytes of intact human cartilage. The modifications made for ISH include the presence of CaCl2 and BaCl2 in the fixation and washing steps and exclusion of cetyl pyridinium chloride. By ISH we show that aggrecan, MMP-3, and MMP-8 are continuously expressed during 8 months of culture. The alpha1 (II) procollagen gene is expressed only during the first 2 months of culture and after 3 months its expression is undetectable, which is consistent with its absence in adult articular cartilage. By Western blotting, Type II collagen protein had been synthesized and deposited in both the cell-associated and further-removed matrix compartments at 7 and 14 days of culture. These data indicate that chondrocytes cultured in alginate beads could be preserved for immunohistochemistry and ISH and that culture of human chondrocytes in alginate beads may serve as a good model for studying cartilage-specific phenotype as well as factors that influence cartilage matrix turnover.     

ED-A sequence containing fibronectin in human amniotic fluid and amnion epithelial cells

1. Human amniotic fluid fibronectin (aFn) was studied by using a monoclonal antibody 52DHl (DH) that recognizes the extra domain (ED-A) sequence of cellular Fn (cFn). 2. In immunoblotting the DH antibody reacted with a sharp polypeptide band at the top of the bulk of the diffuse aFn. Another monoclonal antibody 52BF12 (BF) against the cell binding site of Fn, recognized the whole aFn. 3. The ED-A sequence containing cFn (EcFn) formed a constant proportion in aFns from all amniotic fluid preparations studied. 4. In amniotic membranes the DH antibody revealed bright subepithelial immunofluorescence. 5. Also isolated and cultured human amnion epithelial cells were strongly positive in immunofluorescence and secreted EcFn into the culture medium as revealed by immunoblotting. 6. The results indicate that aFn is a composition of at least two different Fn subtypes of which the EcFn most probably originates from amnion epithelial cells.     

Tissue engineering of cartilage with chondrocytes cultured in a chemically-defined, serum-free medium

Cell culture with serum-containing medium has potential problems associated with contamination of infectious agents. This study demonstrates for the first time the feasibility of regenerating cartilage tissues in vivo by implantation of chondrocytes cultured in vitro in a chemically-defined, serum-free medium. Chondrocytes cultured in the serum-free medium grew similarly to those in a serum-containing medium. Implantation of chondrocytes cultured in the serum-free medium and seeded on to polymer scaffolds resulted in the regeneration of cartilage tissues with histological aspects similar to those of cartilage tissues regenerated from chondrocytes cultured in serum-containing medium.     

The influence of an adhesive cell surface protein on chondrogenic expression in vitro

Fibronectin is a major glycoprotein associated with fibroblasts and other cells of mesenchymal origin. However, when mesenchyme differentiates into cartilage, fibronectin is no longer synthesized. The significance of the change in fibronectin was further evaluated by culturing chondrocytes in the presence of exogenous fibronectin. Treatment with fibronectin caused the chondrocytes to assume a fibroblastic morphology and also enhanced other fibroblastic properties. These results suggest that decreased fibronectin levels may be required for chondrogenesis to occur normally.