Chondrocytic differentiation of mesenchymal stem cells sequentially exposed to transforming growth factor-beta1 in monolayer and insulin-like growth factor-I in a three-dimensional matrix.

This study evaluated chondrogenesis of mesenchymal progenitor stem cells (MSCs) cultured initially under pre-confluent monolayer conditions exposed to transforming growth factor-beta1 (TGF-beta1), and subsequently in three-dimensional cultures containing insulin-like growth factor I (IGF-I). Bone marrow aspirates and chondrocytes were obtained from horses and cultured in monolayer with 0 or 5 ng of TGF-beta 1 per ml of medium for 6 days. TGF-beta 1 treated and untreated cultures were distributed to three-dimensional fibrin disks containing 0 or 100 ng of IGF-I per ml of medium to establish four treatment groups. After 13 days, cultures were assessed by toluidine blue staining, collagen types I and II in situ hybridization and immunohistochemistry, proteoglycan production by [35S]-sulfate incorporation, and disk DNA content by fluorometry. Mesenchymal cells in monolayer cultures treated with TGF-beta1 actively proliferated for the first 4 days, developed cellular rounding, and formed cell clusters. Treated MSC cultures had a two-fold increase in medium proteoglycan content. Pretreatment of MSCs with TGF-beta1 followed by exposure of cells to IGF-I in three-dimensional culture significantly increased the formation of markers of chondrocytic function including disk proteoglycan content and procollagen type II mRNA production. However, proteoglycan and procollagen type II production by MSC's remained lower than parallel chondrocyte cultures. MSC pretreatment with TGF-beta1 without sequential IGF-I was less effective in initiating expression of markers of chondrogenesis. This study indicates that although MSC differentiation was less than complete when compared to mature chondrocytes, chondrogenesis was observed in IGF-I supplemented cultures, particularly when used in concert with TGF-beta1 pretreatment.     

以ITS为主要成分的无血清培养基对软骨细胞增殖和表型的影响

目的观察以ITS为主要成分的无血清培养基对软骨细胞增殖和表型的影响。方法培养猪耳软骨细胞,分为无血清组和含血清组,无血清组应用包含胰岛素铁硒传递蛋白（ITS）、地塞米松及维生素C为主要成分的无血清培养基：含血清组应用包含10％血清的常规培养基。观察平面和三维培养状态下无血清培养基对软骨细胞增殖、基质分泌和软骨表型维持的作用。结果平面培养条件下．无血清组的细胞增殖率出现下调．细胞表型不能维持。在三维培养情况下无血清组可以保持软骨细胞存活和软骨细胞的表型,Ⅱ型胶原和蛋白多糖组织学染色结果与含血清组无明显差异,软骨特异基因ColⅡ、Aggrecan的表达与含血清组无明显差异,并能够形成较好的软骨样组织。结论以ITS、地塞米松及维生素C为主要成分的无血清培养基．在三维培养条件下能基本保持软骨细胞的存活和表型．可用于软骨细胞的体外三维培养．     

Coordinate upregulation of cartilage matrix synthesis in fibrin cultures supplemented with exogenous insulin-like growth factor-I.

The addition of insulin-like growth factor-I to cartilage cultures is known to stimulate the synthesis of proteoglycan and type-II collagen in explant and monolayer studies. The purpose of this study was to determine the effects of long-term supplementation with insulin-like growth factor-I in chondrocytes cultured in fibrin discs as a preliminary investigation to in vivo application of chondrocyte/insulin-like growth factor-I/fibrin grafts to articular-cartilage repair procedures. Chondrocyte-fibrin cultures were maintained for 14 days, with insulin-like growth factor-I added at varying concentrations of 0, 10, 50, or 100 ng/ml medium. Cultures supplemented with 50 or 100 ng of growth factor/ml had increased levels of aggrecan and type-IIB procollagen mRNA, and translation to aggrecan and type-IIB collagen was confirmed by dye-binding assay of total proteoglycan, type-II collagen immunohistochemistry, and determination of collagen content by high-performance liquid chromatography. Maintenance of the chondrocyte phenotype during the 14 days of culture was confirmed by round cell morphology on routine staining, expression of type-II procollagen mRNA on in situ hybridization, evidence of production of pericellular type-II collagen on immunocytochemistry, synthesis of large-molecular-size aggrecan monomer on CL-2B column chromatography, and lack of appreciable message expression for type I or IIA collagen on Northern blot hybridization. Dose-response effects of insulin-like growth factor-I on the expression of chondrocyte matrix constituents were most pronounced at 50 and 100 ng of growth factor per milliliter of medium. These data confirm that (a) culture of chondrocytes for extended periods in three-dimensional cultures of fibrin maintains the chondrocyte phenotype and (b) supplementation with increasing concentrations of insulin-like growth factor-I enhances chondrocyte matrix synthesis and may provide a means to enhance chondrocyte phenotypic stability and function during transplantation grafting procedures.     

Wnt激活剂SB-216763对软骨细胞的作用

目的 观察Wnt激活剂SB-216763对于软骨细胞的作用.方法 将兔关节软骨细胞与SB-216763共同培养,采用免疫细胞化学染色检测SB-216763对于软骨细胞表达β-catenin的影响和分泌Ⅱ型胶原的能力,以噻唑蓝(MTT)比色法检测软骨细胞的增殖活性、用Alcian blue染色法检测软骨细胞分泌硫酸化糖胺聚糖的能力.结果 与SB-216763共同培养的软骨细胞,核βcatenin表达阳性者较对照组明显增多(28.00±2.76比18.17±2.14,P<0.01)、增殖活性显著增强(P<0.01),但Ⅱ型胶原的分泌受到抑制,硫酸化糖胺聚糖分泌显著减少(P<0.01).结论 SB216763可以作为Wnt信号通路的激活分子,其激活Wnt信号通路后促进软骨细胞的增殖,但抑制软骨细胞分泌Ⅱ型胶原和硫酸化糖胺聚糖.     

Chondrogenic potential of human synovial mesenchymal stem cells in alginate

OBJECTIVE: In a recent study, we demonstrated that mesenchymal stem cells (MSCs) derived from the synovial membranes of bovine shoulder joints could differentiate into chondrocytes when cultured in alginate. The purpose of the present study was to establish the conditions under which synovial MSCs derived from aging human donors can be induced to undergo chondrogenic differentiation using the same alginate system. METHODS: MSCs were obtained by digesting the knee-joint synovial membranes of osteoarthritic human donors (aged 59-76 years), and expanded in monolayer cultures. The cells were then seeded at a numerical density of 4x10(6)/ml within discs of 2% alginate, which were cultured in serum-containing or serum-free medium (the latter being supplemented with 1% insulin, transferrin, selenium (ITS). The chondrogenic differentiation capacity of the cells was tested by exposing them to the morphogens transforming growth factor-beta1 (TGF-beta1), TGF-beta2, TGF-beta3, insulin-like growth factor-1 (IGF-1), bone morphogenetic protein-2 (BMP-2) and BMP-7, as well as to the synthetic glucocorticoid dexamethasone. The relative mRNA levels of collagen types I and II, of aggrecan and of Sox9 were determined quantitatively by the real-time polymerase chain reaction (PCR). The extracellular deposition of proteoglycans was evaluated histologically after staining with Toluidine Blue, and that of type-II collagen by immunohistochemistry. RESULTS: BMP-2 induced the chondrogenic differentiation of human synovial MSCs in a dose-dependent manner. The response elicited by BMP-7 was comparable. Both of these agents were more potent than TGF-beta1. A higher level of BMP-2-induced chondrogenic differentiation was achieved in the absence than in the presence of serum. In the presence of dexamethasone, the BMP-2-induced expression of mRNAs for aggrecan and type-II collagen was suppressed; the weaker TGF-beta1-induced expression of these chondrogenic markers was not obviously affected. CONCLUSIONS: We have demonstrated that synovial MSCs derived from the knee joints of aging human donors possess chondrogenic potential. Under serum-free culturing conditions and in the absence of dexamethasone, BMP-2 and BMP-7 were the most potent inducers of this transformation process.     

Effect of dynamic compressive loading and its combination with a growth factor on the chondrocytic phenotype of 3-dimensional scaffold-embedded chondrocytes

Background and purpose Three-dimensionally (3D-) embedded chondrocytes have been suggested to maintain the chondrocytic phenotype. Furthermore, mechanical stress and growth factors have been found to be capable of enhancing cell proliferation and ECM synthesis. We investigated the effect of mechanical loading and growth factors on reactivation of the 3D-embedded chondrocytes.Methods Freshly isolated chondrocytes from rat articular cartilage were grown in monolayer cultures and then in collagen gel. Real-time RT-PCR and histological analysis for aggrecan and type II and type I collagen was performed to evaluate their chondrocytic activity. Then, the 3D-embedded chondrocytes were cultured under either mechanical loading alone or in combination with growth factor. The dynamic compression (5% compression, 0.33 Hz) was loaded for 4 durations: 0, 10, 60, and 120 min/day. The growth factor administered was either basic fibroblast growth factor (bFGF) or bone morphogenetic protein-2 (BMP-2).Results Mechanical loading statistically significantly reactivated the aggrecan and type II collagen expression with loading of 60 min/day as compared to the other durations. The presence of BMP-2 and bFGF clearly enhanced the aggrecan and type II collagen expression of 3D-embedded chondrocytes. Unlike previous reports using monolayer chondrocytes, however, BMP-2 or bFGF did not augment the chondrocytic phenotype when applied together with mechanical loading.Interpretation Dynamic compression effectively reactivated the dedifferentiated chondrocytes in 3D culture. However, the growth factors did not play any synergistic role when applied with dynamic compressive loading, suggesting that growth factors should be administered at different time points during regeneration of the transplantation-ready cartilage.     

In vitro cartilage regeneration from proliferated adult elastic chondrocytes

The purpose of this study was to investigate cellular feasibility in the proliferation and differentiation status of adult chondrocytes for cartilage regeneration in comparison to fetal chondrocytes. Primary cells were isolated from adult (n = 6) and fetal (n = 6) sheep ear cartilages and expanded in 10% fetal bovine serum (FBS) containing Ham's F12 medium, in which adult and fetal cell proliferation rates were compared using a WST-1 assay kit. Approximately 4 million cells were seeded onto each 1 x 1 x 0.2-cm (200 microL) nonwoven fabric scaffold made from polyglycolic acid. Cell/polymer constructs were cultured in serum-free DMEM/F12 medium supplemented with 5 ng/mL TGF-beta2 and 5 ng/mL des(1-3)IGF-I (adult chondrocytes, group A) or in 10% FBS containing Ham's F12 medium (adult chondrocytes, group B, and fetal chondrocytes, group C) as controls in a rotating bioreactor for 6 weeks. The proliferation assay showed that fetal cells had a significantly better growth potential than did adult cells. Histology and extracellular matrix analyses revealed that groups A and C qualitatively displayed better matrix deposition than did group B. In conclusion, although adult sheep elastic chondrocytes had less growth potential than did fetal cells, the serum-free medium supplemented with growth factors significantly enhanced the production of cartilage matrix secreted from proliferated adult sheep elastic chondrocytes.     

Effect of dynamic compressive loading and its combination with a growth factor on the chondrocytic phenotype of 3-dimensional scaffold-embedded chondrocytes

Background and purpose Three-dimensionally (3D-) embedded chondrocytes have been suggested to maintain the chondrocytic phenotype. Furthermore, mechanical stress and growth factors have been found to be capable of enhancing cell proliferation and ECM synthesis. We investigated the effect of mechanical loading and growth factors on reactivation of the 3D-embedded chondrocytes.

Methods Freshly isolated chondrocytes from rat articular cartilage were grown in monolayer cultures and then in collagen gel. Real-time RT-PCR and histological analysis for aggrecan and type II and type I collagen was performed to evaluate their chondrocytic activity. Then, the 3D-embedded chondrocytes were cultured under either mechanical loading alone or in combination with growth factor. The dynamic compression (5% compression, 0.33 Hz) was loaded for 4 durations: 0, 10, 60, and 120 min/day. The growth factor administered was either basic fibroblast growth factor (bFGF) or bone morphogenetic protein-2 (BMP-2).

Results Mechanical loading statistically significantly reactivated the aggrecan and type II collagen expression with loading of 60 min/day as compared to the other durations. The presence of BMP-2 and bFGF clearly enhanced the aggrecan and type II collagen expression of 3D-embedded chondrocytes. Unlike previous reports using monolayer chondrocytes, however, BMP-2 or bFGF did not augment the chondrocytic phenotype when applied together with mechanical loading.

Interpretation Dynamic compression effectively reactivated the dedifferentiated chondrocytes in 3D culture. However, the growth factors did not play any synergistic role when applied with dynamic compressive loading, suggesting that growth factors should be administered at different time points during regeneration of the transplantation-ready cartilage.     

Expansion of chondrocytes for tissue engineering in alginate beads enhances chondrocytic phenotype compared to conventional monolayer techniques

Chondrocytes are known to dedifferentiate when cultured in monolayer culture, which may compromise the efficacy of cartilage repair systems in which cells are expanded by repeat passage in monolayer prior to implantation. We tested the hypothesis that repeat passage in alginate beads can provide sufficient expansion of cells, while producing cells with enhanced chondrocytic phenotype. Bovine articular chondrocytes were seeded in 2% alginate beads or in monolayer. 4 passages at 7-day intervals were performed. Values of 9.1 days for monolayer expansion and 12.5 days for alginate expansion were estimated for a 10-fold increase in cell number. For assessment of chondrocytic and fibroblastic phenotype, expanded cells were seeded in alginate beads or on glass coverslips and cultured for 7 days. On subsequent seeding in alginate, cells which had previously been subcultured in alginate showed higher levels of both DNA and GAG synthesis than cells passaged in monolayer. Furthermore, the alginate-passaged cells retained a chondrocytic phenotype, indicated by synthesis of type II collagen and chondroitin-6-sulphate, while cells passaged in monolayer synthesised type I collagen, indicating a fibroblastic phenotype. In conclusion, expansion of cells for autologous cartilage repair systems, using subculture within alginate beads, provides a potentially attractive alternative to monolayer expansion.     

Expansion of chondrocytes for tissue engineering in alginate beads enhances chondrocytic phenotype compared to conventional monolayer techniques

Chondrocytes are known to dedifferentiate when cultured in monolayer culture, which may compromise the efficacy of cartilage repair systems in which cells are expanded by repeat passage in monolayer prior to implantation. We tested the hypothesis that repeat passage in alginate beads can provide sufficient expansion of cells, while producing cells with enhanced chondrocytic phenotype. Bovine articular chondrocytes were seeded in 2% alginate beads or in monolayer. 4 passages at 7-day intervals were performed. Values of 9.1 days for monolayer expansion and 12.5 days for alginate expansion were estimated for a 10-fold increase in cell number. For assessment of chondrocytic and fibroblastic phenotype, expanded cells were seeded in alginate beads or on glass coverslips and cultured for 7 days. On subsequent seeding in alginate, cells which had previously been subcultured in alginate showed higher levels of both DNA and GAG synthesis than cells passaged in monolayer. Furthermore, the alginate-passaged cells retained a chondrocytic phenotype, indicated by synthesis of type II collagen and chondroitin-6-sulphate, while cells passaged inmonolayer synthesised type I collagen, indicating a fibroblastic phenotype. In conclusion, expansion of cells for autologous cartilage repair systems, using subculture within alginate beads, provides a potentially attractive alternative to monolayer expansion.     

Expansion of chondrocytes for tissue engineering in alginate beads enhances chondrocytic phenotype compared to conventional monolayer techniques

Chondrocytes are known to dedifferentiate when cultured in monolayer culture, which may compromise the efficacy of cartilage repair systems in which cells are expanded by repeat passage in monolayer prior to implantation. We tested the hypothesis that repeat passage in alginate beads can provide sufficient expansion of cells, while producing cells with enhanced chondrocytic phenotype. Bovine articular chondrocytes were seeded in 2% alginate beads or in monolayer. 4 passages at 7-day intervals were performed. Values of 9.1 days for monolayer expansion and 12.5 days for alginate expansion were estimated for a 10-fold increase in cell number. For assessment of chondrocytic and fibroblastic phenotype, expanded cells were seeded in alginate beads or on glass coverslips and cultured for 7 days. On subsequent seeding in alginate, cells which had previously been subcultured in alginate showed higher levels of both DNA and GAG synthesis than cells passaged in monolayer. Furthermore, the alginate-passaged cells retained a chondrocytic phenotype, indicated by synthesis of type II collagen and chondroitin-6-sulphate, while cells passaged in monolayer synthesised type I collagen, indicating a fibroblastic phenotype. In conclusion, expansion of cells for autologous cartilage repair systems, using subculture within alginate beads, provides a potentially attractive alternative to monolayer expansion.     

Response of human chondrocytes prepared for autologous implantation to growth factors

This study investigated metabolism of autologous chondrocytes after initial expansion immediately before implantation. Chondrocytes cultured in either monolayers or alginate beads were treated with insulin-like growth factor-1 (IGF-1), osteogenic protein-1 (OP-1), or a combination. Proteoglycan synthesis and DNA content were tested in both cultures. Alginate beads also were analyzed with live/dead cell assay, safranin O/fast green stain for histology, and immunohistochemistry with antibodies against collagen type II and VI, aggrecan, decorin, and fibronectin. In monolayers, autologous chondrocytes changed their morphologic appearance. In alginate, they maintained chondrocytic phenotype. Growth factors, especially combined, promoted cell survival and induced chondrocyte proliferation. OP-1 stimulated the largest cartilage-specific matrix and the most accumulation of collagen type II and fibronectin, although the overall matrix synthesized by autologous chondrocyte implantation cells was smaller than that produced by normal chondrocytes. The clinical implications of this study suggest a significant promise for anabolic growth factors in cartilage repair as a potential modifying therapy for the enhancement of chondrocytic phenotype of autologous chondrocytes.     

Expression of a stable articular cartilage phenotype without evidence of hypertrophy by adult human articular chondrocytes in vitro

Chondrocytes that were isolated from adult human articular cartilage changed phenotype during monolayer tissue culture, as characterized by a fibroblastic morphology and cellular proliferation. Increased proliferation was accompanied by downregulation of the cartilage-specific extracellular matrix proteoglycan, aggrecan, by cessation of type-II collagen expression, and by upregulation of type-I collagen and versican. This phenomenon observed in monolayer was reversible after the transfer of cells to a suspension culture system. The transfer of chondrocytes to suspension culture in alginate beads resulted in the rapid upregulation of aggrecan and type-II collagen and the downregulation of expression of versican and type-I collagen. Type-X collagen and osteopontin, markers of chondrocyte hypertrophy and commitment to endochondral ossification, were not expressed by adult articular chondrocytes cultured in alginate, even after 5 months. In contrast, type-X collagen was expressed within 2 weeks in a population of cells derived from a fetal growth plate. The inability of adult articular chondrocytes to express markers of chondrocyte hypertrophy has underscored the fundamental distinction between the differentiation pathways that lead to articular cartilage or to bone. Adult articular chondrocytes expressed only hyaline articular cartilage markers without evidence of hypertrophy.     

Gene expression and proliferation analysis in young, aged, and osteoarthritic sheep chondrocytes effect of growth factor treatment.

Cartilage is a support tissue with a poor capacity to self-repair. Its cells, chondrocytes, are responsible for synthesizing and renewing the matrix that surrounds them in a constant turnover mechanism. Autologous chondrocyte implantation (ACI) is one of the techniques that promises to be an alternative to common strategies for chondral lesions. To apply this technique, a large amount of cells must be obtained. In our work, we studied the state of cells from different cartilage (young, aged, and osteoarthritic sheep) cultured in monolayer by analyzing their proliferation rate using bromodeoxyuridine and their gene expression profile by RT-PCR. A decrease was found in expression of type II collagen and aggrecan in aged, osteoarthritic, and passaged chondrocytes. Treatment of cells with growth factors aFGF, IGF-I, TGF-beta, and OP-1 improved the proliferation rate in all cells studied and stimulated gene expression of type II collagen, aggrecan, and TGF-beta. Osteoarthritic cells showed a poor response according to matrix gene expression, while young cells responded properly, and aged chondrocytes showed a moderate response. These results suggest that the state of cartilage may affect the behavior of cultured chondrocytes.     

Chondrocytes in culture produce a mechanically functional tissue

A mechanically testable tissue was grown in vitro from rabbit chondrocytes that were initially plated at high density (approximately 80.000 cells/cm²). The DNA, collagen, and proteoglycan content, as well as the tissue thickness, tensile stiffness, and synthesis rates, were measured at 4, 6, and 8 weeks. The biochemical properties were similar to those for immature cartilage, with predominantly type-II collagen produced; this indicated that the cells retained their chondrocytic phenotype. The tissue formed a coherent mechanical layer with testable tensile stiffness as early as 4 weeks. The tensile elastic modulus reached 1.3 MPa at 8 weeks, which is in the range of values for native cartilage from the midzone. Collagen density was approximately 24 mg/ml at 8 weeks, which is about one-half the value for native cartilage, and the collagen fibril diameters were smaller. Chondrocytes in culture responded to culture conditions and were stimulated by cytokine interleukin-1β. When culture conditions were varied to RPMI nutrient medium with lower fetal bovine serum and higher ascorbic acid concentrations, the thickness decreased and the modulus increased significantly. Interleukin-1β. added to the 8-week culture for 2 weeks. caused a decrease of 60% in thickness, a decrease of 81% in proteoglycan content, and a decrease of 31% in collagen content; this is similar to the response of cartilage explants to interleukin-1β. This cartilage analog may be useful as a model system to study structure-function relationships in cartilage or as cartilage-replacement tissue.     

New target genes for NOV/CCN3 in chondrocytes: TGF-beta2 and type X collagen.

We studied the involvement of NOV/CCN3, whose function is poorly understood, in chondrocyte differentiation. NOV was found to upregulate TGF-beta2 and type X collagen and to act as a downstream effector of TGF-beta1 in ATDC5 and primary chondrocytes. Thus, NOV is a positive modulator of chondrogenesis. INTRODUCTION: NOV/CCN3 is a matricellular protein that belongs to the CCN family. A growing body of evidence indicates that NOV could play a role in cell differentiation, particularly in chondrogenesis. During chick embryo development, NOV expression is tightly regulated in cartilage, and a high expression of NOV has been associated with cartilage differentiation in Wilms' tumors. However, a precise role for NOV and potential target genes of NOV in chondrogenesis are unknown. MATERIALS AND METHODS: ATDC5 cells and primary chondrocytes were either treated with NOV recombinant protein or transfected with a NOV-specific siRNA to determine, using quantitative RT-PCR, the effect of NOV on the expression of several molecules involved in chondrocyte differentiation. Stable ATDC5 clones expressing NOV were also established to show that NOV was a downstream effector of TGF-beta1. RESULTS: We established that NOV/CCN3 expression increases in ATDC5 cells at early stages of chondrogenic differentiation and precedes the appearance of TGF-beta2 and of several chondrocytic markers such as SOX9 or type X collagen. When exogenously administered, NOV recombinant protein up-regulates TGF-beta2 and type X collagen mRNA levels both in ATDC5 cells and in primary mouse chondrocytes but does not influence SOX9 expression. This regulation also occurs at the endogenous level because downregulation of NOV expression is correlated with an inhibition of TGF-beta2 and type X collagen in primary chondrocytes. Furthermore, we found that NOV expression is downregulated when chondrocytes are exposed to TGF-beta1-dedifferentiating treatment in chondrocytes, further providing evidence that NOV may counteract TGF-beta1 effects on chondrocytes. CONCLUSIONS: This study provides the first characterization of two new targets of NOV involved in chondrocyte differentiation, shows that NOV acts with TGF-beta1 in a cascade of gene regulation, and indicates that NOV is a positive modulator of chondrogenesis.     

Characterization of a biomaterial with cartilage-like properties expressing type X collagen generated in vitro using neonatal porcine articular and growth plate chondrocytes

OBJECTIVE: The availability of cartilage with or without the potential to ossify and suitable for surgical restoration and resurfacing of joints is an important clinical problem in arthritis-related pathology, trauma and reconstructive surgery. Here, we designed experiments to generate a biomaterial with cartilage-like properties by culturing neonatal porcine articular and growth plate chondrocytes on a hydrogel substrate and to examine the biochemical and histological characteristics of the resulting tissue. DESIGN: Neonatal porcine epiphyseal and growth plate chondrocytes were cultured on poly(2-hydroxyethyl methacrylate) (polyHEMA)-coated dishes to prevent their adherence to plastic. We previously described that this procedure allows the maintenance of the chondrocyte-specific phenotype for > or = 8 months. Chondrocytes were isolated by successive enzymatic digestions and cultured at high density (>2.0 x 10(7) cells/ml) in DMEM with 10% FBS, 50 microg/ml ascorbic acid, glutamine, vitamins, and antibiotics for up to 10 weeks on 60 mm plastic culture dishes coated with polyHEMA. The tissues produced during culture were studied histologically and biochemically and were examined for cellular proliferation employing(3)H-thymidine incorporation and for their collagen production employing biosynthetic labeling with(14)C-proline and Western blot with specific antibodies. The expression of relevant collagen genes was examined employing RT-PCR. RESULTS: Within 24 h of culture, isolated chondrocytes organized into well-formed clusters and in 2 weeks formed structures with gross appearance and consistency similar to those of natural cartilage. The wet weight of the tissue formed in vitro increased six-fold during the 10-week period of study. Cell proliferation measured by the incorporation of(3)H-thymidine increased during the first 3 weeks and reached a plateau in subsequent weeks. Histological examination showed that the cultures contained rounded chondrocytes embedded in an abundant cartilaginous extracellular matrix. The cartilage formed contained large amounts of collagen and sulfated proteoglycans as examined by staining with Masson's Trichrome and Alcian blue, respectively. Deposition of calcium in the deeper layers of the tissue was demonstrated with the von Kossa stain. Western analyses with specific antibodies showed that type II collagen was present from the first week and progressively increased in the cultures, whereas type X collagen was first detected at 4 weeks and increased with length of culture. When chondrocytes isolated from the growth plate were included, small amounts of type I collagen were detected in the medium of cultured biomaterial as expected. Type III collagen was not detected by Western blot over the 10-week period. High levels of type II and type X collagen gene expression were demonstrated by RT-PCR. CONCLUSION: These studies demonstrate the production in vitro of cartilage-like tissue with similar morphological, histochemical and biochemical characteristics to those of natural growth plate cartilage. The cartilage generated in vitro has the potential to be used in reconstructive surgery and in joint resurfacing and restoration of skeletal defects.     

Phenotypic characteristics of rabbit intervertebral disc cells. Comparison with cartilage cells from the same animals.

STUDY DESIGN: Intervertebral disc cells were extracted from the surrounding matrix, and their metabolic activities and phenotypes were studied. OBJECTIVES: To compare the metabolic activities and phenotypes of cell populations extracted from the intervertebral discs of young rabbits with those of articular and growth plate chondrocytes from the same animals. SUMMARY OF BACKGROUND DATA: The phenotype of intervertebral disc cells has been poorly studied and still is debated. METHODS: The intervertebral discs as well as articular and vertebral growth plate cartilage of rabbits were digested enzymatically. The morphology of freshly isolated cells was examined. Their contents of collagen II and X mRNAs were determined by Northern blot analysis, and their sulfation activity by 35S-sulfate incorporation as chondrocytic markers. Cells were cultured at high density or low density and grown in primary culture. The stability of their phenotype was monitored by evaluating the collagen I and II mRNA ratio. The proteoglycans newly synthesized by the cells also were quantified, and their elution profile analyzed on Sepharose 2B columns. RESULTS: The anulus fibrosus cells were morphologically undistinguishable from articular chondrocytes. The nucleus pulposus contained mainly large vacuolated cells and a few smaller cells. All freshly extracted cells expressed different levels of collagen II mRNA. Anulus fibrosus and nucleus pulposus cells contained, respectively, 22% and 8% of collagen II mRNA compared with that found in articular or growth plate chondrocytes from the same animal. Only growth plate chondrocytes expressed collagen X. When anulus fibrosus cells were incubated for 48 hours at high density, they had collagen II mRNA contents similar to those of articular and growth plate chondrocytes, but synthesized five to six times fewer sulfated proteoglycans. When seeded at low density, anulus fibrosus cells divided more slowly than articular chondrocytes and incorporated four times fewer 35S-sulfate into proteoglycans. Their collagen II mRNA content was 2.75-fold lower than that of chondrocytes, and the procollagen alpha 1II/alpha 1I mRNA ratio was 3.1 for anulus fibrosus cells and 7 for chondrocytes. No collagen X mRNA was detected. When incubated for 48 hours at high density, the nucleus pulposus giant cells had four times less collagen II mRNA content than cartilage cells but synthesized the same amounts of sulfated proteoglycans. They did not divide during 21 days in culture and still contained collagen II mRNA but no collagen X mRNA. CONCLUSIONS: Findings showed that intervertebral disc cells all express cartilage-specific matrix proteins with quantitative differences, depending on their anatomic situation. It is suggested that anulus fibrosus cells are chondrocytic cells at a different stage of differentiation than articular and growth plate chondrocytes. The phenotype of nucleus pulposus cells still is unclear. They could be chondrocytic or notochordal. A definitive answer to this important question requires differentiating markers of notochordal cells.