Human chondrocytes in tridimensional culture

Summary Cartilage was taken from the macroscopically normal part of human femoral heads immediately after orthopedic surgical operations for total prothesis consecuitive to hip arthrosis. After clostridial collagenase digestion and repeated washings, chondrocytes (10⁶ cells) were cultivated in a gyrotory shaker (100 rpm). Under these conditions, cells were kept in suspension and after 3 to 5 d formed a flaky aggregate which, on Day 10, became dense. These chondrocytes were morphologically differentiated: they had a round shape, were situated inside cavities, and were surrounded by a new matrix. Histochemical methods showed the presence of collagen and polysaccharides in cell cytoplasm and in intercellular matrix, and the immunofluorescence method using specific antisera (anticartilage proteoglycans and anti-type II collagen) showed that these two constituts were in tentercellular matrix. The measurement of the amounts of proteoglycans (PG) released into culture media and those present in chondrocyte aggregate (by a specific PG radioimmunoassay) showed a maximum production on Days 3 to 5 of culture, then the production decreased and stabilized (from Day 10 to the end of culture). The observed difference between the amounts of PG in aggregates after 20 d and those after 2 h of culture demonstrated that PG neosynthesis did occur during cultivation. This conclusion was supported by other results obtained by [¹⁴C]glucosamine incorporation in chondrocyte aggregates. Moreover, the aggregate fresh weight related to cell number (appreciated by DNA assay) increased significantly with culture duration. Three-dimensional chondrocyte culture represents an interesting model: chondrocytes were differentiated morphologically as well as biosynthetically and synthesized a new cartilage matrix. This work was suported by grant 3.4529.81 from FRSM, Belgium.     

Modulation of chondrocyte migration and aggregation by insulin-like growth factor-1 in cultured cartilage

The effect of insulin-like growth factor-1 (IGF-1) on the behavior of rabbit chondrocytes in cultured collagen (CL) gels initially seeded with 2 × 10⁵ cells/ml was examined. On day 5, the frequency of migrating cells cultured in presence of 100 ng IGF-1/ml was 0.04, which was 54 % of the frequency in IGF-1-free culture. The presence of IGF-1 caused an increase in the frequency of dividing cells from 0.09 to 0.13. These results suggest that IGF-1 suppressed the migration of chondrocytes in the CL gels while stimulating cell division in the initial culture phase. The proteolytic migration of cells was thought to be suppressed by the down-regulation of membrane type 1 matrix metalloproteinase by IGF-1. This contributed to the formation of aggregates with spherical-shaped cells that produced collagen type II.     

Fine structure and molecular content of human chondrocytes encapsulated in alginate beads

Preservation of the chondrocytic phenotype in vitro requires a 3D (three‐dimensional) culture model. Diverse biomaterials have been tested as scaffolds for culture of animal chondrocytes; however, to date, none is considered a gold standard in regenerative medicine. Here, we studied the fine structure and the GAGs (glycosaminoglycans) content of human chondrocytes encapsulated in alginate beads by using electron microscopy and radioactive sulfate [³⁵S] incorporation, respectively. Cells were obtained from human cartilage, encapsulated in alginate beads and cultured for 28 days. [³⁵S]Na₂SO₄ was added to the culture media and later isolated for quantification of the sulfated GAGs found in three compartments: IC (intracellular), IB (intra‐bead) and EB (extra‐bead). Round cells were seen isolated or forming small groups throughout the alginate. Human chondrocytes presented the features of active cells such as euchromatic nuclei, abundant RER (rough endoplasmic reticulum) and many transport vesicles. We observed an extracellular matrix rich in collagen fibres and electrondense material adjacent to the cells. Most of the GAGs produced (74%) were found in the culture medium (EB), indicating that alginate has a limited capacity to retain the GAGs. CS (chondroitin sulfate), the major component of aggrecan, was the most prominent GAG produced by the encapsulated cells. Human chondrocytes cultured in alginate can sustain their phenotype, confirming the potential application of this biomaterial for cartilage engineering.     

In vitro formation of mineralized cartilagenous tissue by articular chondrocytes

Summary Study of the deep articular cartilage and adjacent calcified cartilage has been limited by the lack of an in vitro culture system which mimics this region of the cartilage. In this paper we describe a method to generate mineralized cartilagenous tissue in culture using chondrocytes obtained from the deep zone of bovine articular cartilage. The cells were plated on Millipore CM^R filters. The chondrocytes in culture accumulated extracellular matrix and formed cartilagenous tissue which calcified when β-glycerophosphate was added to the culture medium. The cartilagenous tissue generated in vitro contains both type II and type X collagens, large sulfated proteoglycans, and alkaline phosphatase activity. Ultrastructurally, matrix vesicles were seen in the extracellular matrix. Selected area electron diffraction confirmed that the calcification was composed of hydroxyapatite crystals. The chondrocytes, as characterized thus far, appear to maintain their phenotype under these culture conditions which suggests that these cultures could be used as a model to examine the metabolism of cells from the deep zone of cartilage and mineralization of cartilagenous tissue in culture.     

Chondrocytes derived from mouse embryonic stem cells

Our knowledge of cellular differentiation processes during chondro- and osteogenesis, in particular the complex interaction of differentiation factors, is still limited. We used the model system of embryonic stem (ES) cell differentiation in vitro via cellular aggregates, so called embryoid bodies (EBs), to analyze chondrogenic and osteogenic differentiation. ES cells differentiated into chondrocytes and osteocytes throughout a series of developmental stages resembling cellular differentiation events during skeletal development in vivo. A lineage from pluripotent ES cells via mesenchymal, prechondrogenic cells, chondrocytes and hypertrophicchondrocytes up to osteogenic cells was characterized. Furthermore, we found evidence for another osteogenic lineage, bypassing the chondrogenic stage. Together our results suggest that this in vitro system will be helpful to answer so far unacknowledged questions regarding chondrogenic and osteogenic differentiation. For example, we isolated an as yet unknown cDNA fragment from ES cell-derived chondrocytes, which showed a developmentally regulated expression pattern during EB differentiation. Considering ES cell differentiation as an alternative approach for cellular therapy, we used two different methods to obtain pure chondrocyte cultures from the heterogenous EBs. First, members of the transforming growth factor (TGF)-β family were applied and found to modulate chondrogenic differentiation but were not effective enough to produce sufficient amounts of chondrocytes. Second, chondrocytes were isolated from EBs by micro-manipulation. These cells initially showed dedifferentiation into fiboblastoid cells in culture, but later redifferentiated into mature chondrocytes. However, a small amount of chondrocytes isolated from EBs transdifferentiated into other mesenchymal cell types, indicating that chondrocytes derived from ES cells posses a distinct differentiation plasticity. This revised version was published online in July 2006 with corrections to the Cover Date.     

Establishment of callus and cell suspension cultures from Gypsophila paniculata leaf segments and study of the attachment of host cells by Erwinia herbicola pv. gypsophilae

Callus and cell suspension cultures were initiated from leaf segments of G. paniculata. Fresh and dry weights measurements of callus showed that callus growth was optimal on MS medium supplemented with 1.0 mg l^–1 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.2 mg l^–1 benzyladenin (BA). Calli cultured on this medium, showed a two-fold increase in fresh weight by the fourth week of incubation. The initiated hard green callus was repeatedly subcultured on MS medium containing increasing concentrations of 2,4-D in order to increase its friability. The friable callus was then used for establishment of a cell suspension culture. Maximum growth of the suspension culture was on medium supplemented with 1.0 mg l^–1 2,4-D and 0.2 mg l^–1 BA.The suspension culture was used for studying plant host attachment in both electron and light microscopy. Upon infection with E. herbicola, plant cells showed aggregate formation within 24 h of infection. In the presence of the pathogenic Ehg,the number of aggregates formed was 342 aggregates ml^–1, in the presence of the non-pathogenic Ehg154 aggregates ml^–1 and in the control 115 aggregates ml^–1. These results show that the pathogenic strain causes formation of cell aggregates 5.8 times greater than the non-pathogenic one. Based on these results, it can be hypothesized that bacterial cells of the pathogenic strains bind to the plant cells and may form a bridge for attachment of plant cells to one another. Observations by electron microscope show that bacterial cells do attach to plant cells and that this attachment might be via formation of a bridge between the bacteria and the plant cell.     

Perfusion culture system: Synovial fibroblasts modulate articular chondrocyte matrix synthesis in vitro

Objective

To investigate the interactions of chondrocyte metabolism by synovial cells and synovial supernatants in a new perfusion co-culture system.

Methods

Chondrocytes and synovial fibroblasts were obtained from knee joints of slaughtered adult cattle. For experimental studies chondrocytes and synovial fibroblasts were placed together into a perfusion chamber (co-culture) or were placed into two different perfusion culture containers, which were connected by a silicone tube (culturing of chondrocytes with synovial supernatants). A control setup was used without synovial cells. Chondrocyte proliferation was shown by measurement of DNA content. The proteoglycan synthesis was quantified using ³⁵SO₄²⁻-labelling and the dimethylmethylene blue assay. ³H-proline incorporation was used to estimate the protein biosynthesis. Type II collagen synthesis was measured by ELISA, furthermore extracellular matrix deposition was monitored immunohistochemically (collagen types I/II). Regarding to the role of reactive oxygen species LDH release before and after stimulation with hydrogen peroxide was measured.

Results

The proliferation of chondrocytes shows an increase in monoculture as well as in co-culture or in culture with synovial supernatants more than fivefold within 12 days. ³H-proline incorporation as a marker for chondrocytes biosynthetic activity decreases in co-culture system and in culture with synovial supernatants. A similar effect is seen measuring total proteoglycan content as well as the ³⁵SO₄²⁻ incorporation in chondrocytes. Co-culturing and culturing with synovial supernatants lead to a significant decrease of proteoglycan release and content. Quantification of collagen type II by ELISA shows significant lower amounts of native collagen type II in the extracellular matrix of co-cultured chondrocytes as well as in culture with synovial supernatants. The membrane damage of chondrocytes by hydrogen peroxide is reduced when chondrocytes are co-cultured with synovial fibroblasts.

Conclusion

The co-culture perfusion system is a new tool to investigate interactions of different cell types with less artificial interferences. Our results suggest that synovial supernatants and synovial fibroblasts modulate the biosynthetic activity and the matrix deposition of chondrocytes as well as the susceptibility to radical attack of reactive oxygen species.     

Reversible inhibition of cytoplasmic streaming by intracellular Ca2+ in tonoplast-free cells ofChara australis

Summary The effect of the intracellular concentration of Ca²⁺ on the cytoplasmic streaming of tonoplast-free cells ofChara australis was studied by intracellular perfusion. The perfusion media contained 1 mM Mg · ATP. Both cell ends were cut and left open. Media of different Ca²⁺ concentrations were perfused through the cell and the rate of the cytoplasmic streaming just after perfusion was measured. The critical concentration of Ca²⁺ for inhibiting the streaming was 5 × 10^–4M, which was substantially higher than that found earlier byWilliamson (1975) andHayama et al. (1979). Recovery from the inhibition occurred, though not completely, by removing Ca²⁺.In tonoplast-free cells the Ca²⁺ sensitivity differed according to the culture conditions. Cells cultured indoors exhibited a higher sensitivity than those cultured outdoors. Theformer cells contained granule-rich endoplasm aggregates after loss of the tonoplast, while the latter cells did no such aggregates. The aggregates were fixed to the cortical gel with a high dosage of Ca²⁺ and freed by removing it.     

Influence of colchicine and vinblastine on the Golgi complex and matrix deposition in chondrocyte aggregates : An ultrastructural study

Fetal guinea-pig epiphyseal chondrocytes were isolated enzymatically, aggregated, and the aggregates maintained in organ culture. As revealed by light and electron microscopy, the cultures produced a typical cartilaginous matrix, but no calcification occurred. Exposure of aggregating cells, or preformed aggregates, to colchicine or vinblastihe at 10⁻⁵ M concentration led to disappearance of the microtubules, dissociation of the Golgi complex into single dictyosomes, and clustering of lysosomes. Thus, in treated cells the dictyosomes with accompanying vesicular structures were dispersed throughout the cytoplasm, whereas they were localized in a well-defined juxtanuclear region in control cells. The number and size of the cisternae forming a dictyosome were often reduced. Cells treated with vinblastine displayed macrotubules and an increased number of phagosomes. Both drugs reduced the deposition of intercellular matrix. In cells first exposed to either of the drugs for 2 or 5 days and then transferred to fresh medium for 3 or 6 days, the microtubules reappeared, the Golgi complex regained its normal appearance, and the amount of matrix increased. These findings are discussed in view of present concepts of the role of microtubules in cell secretion.     

Liquid perfluorochemical-supported hybrid cell culture system for proliferation of chondrocytes on fibrous polylactide scaffolds

CP5 bovine chondrocytes were cultured on biodegradable electrospun fibrous polylactide (PLA) scaffolds placed on a flexible interface formed between two immiscible liquid phases: (1) hydrophobic perfluorochemical (PFC) and (2) aqueous culture medium, as a new way of cartilage implant development. Robust and intensive growth of CP5 cells was achieved in our hybrid liquid–solid–liquid culture system consisting of the fibrous PLA scaffolds in contrast to limited growth of the CP5 cells in traditional culture system with PLA scaffold placed on solid surface. The multicellular aggregates of CP5 cells covered the surface of PLA scaffolds and the chondrocytes migrated through and overgrew internal fibers of the scaffolds. Our hybrid culture system simultaneously allows the adhesion of adherent CP5 cells to fibers of PLA scaffolds as well as, due to use of phase of PFC, enhances the mass transfer in the case of supplying/removing of respiratory gases, i.e., O₂ and CO₂. Our flexible (independent of vessel shape) system is simple, ready-to-use and may utilize a variety of polymer-based scaffolds traditionally proposed for implant development.     

Restructuring dynamics of du 145 and LNCaP prostate cancer spheroids

Summary Neoplastic cells acquire multidrug resistance as they assemble into multicellular spheroids. Image analysis and Monte Carlo simulation provided an insight into the adhesion and motility events during spheroid restructuring in liquid-overlay culture of DU 145 and LNCaP human prostate cancer cells. Irregularly shaped, two-dimensional aggregates restructured through incremental cell movements into three-dimensional spheroids. Of the two cultures examined, restructuring was more pronounced for DU 145 aggregates. Motile DU 145 cells formed spheroids with a minimum cell overlay of 30% for 25-mers as estimated by simulation versus 5% for adhesive LNCaP cells in aggregates of the same size. Over 72 h, the texture ratio increased from 0.55±0.05 for DU 145 aggregates with projected areas exceeding 2000 μm² to a value approaching 0.75±0.02 (P<0.05). For LNCaP aggregates of comparable size, the increase in texture ratio was more modest, less than 15% during the same time period (P<0.05). Combined, these data suggest that motility events govern the overall rate of spheroid restructuring. This information has application to the chemosensitization of solid tumors and kinetic modeling of spheroid production.     

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.     

Apomorphine inhibits the growth-stimulating effect of retinal pigment epithelium on scleral cells in vitro

Visual deprivation of the chicken eye causes axial elongation with high myopia. The cartilaginous layer of the myopic sclera shows an increase of mitotic activity. Previous studies reported that the in vivo administration of apomorphine, a dopamine nonselective agonist, effectively prevents visual-deprivation myopia. Because the retinal pigment epithelium (RPE) regulates growth of the sclera as we and others have shown previously, it is speculated that the RPE cells may play an important role in this preventive effect of apomorphine. In this study, to clarify the mechanism by which the administration of apomorphine inhibits the proliferation of scleral chondrocytes in vivo, we have investigated the effect of apomorphine on the proliferation of scleral chondrocytes with or without co-cultured RPE cells in vitro. We previously demonstrated that cell proliferation of scleral chondrocytes remarkably increases with co-cultured RPE cells. In this study, we found that apomorphine at concentrations of higher than 2×10⁻⁵ M dramatically reduced the growth-stimulatory effect of RPE cells on the scleral chondrocytes, whereas the inhibitory effect of apomorphine on the proliferation of scleral chondrocytes without RPE cells was very little. Our results strongly suggest that apomorphine may reduce the production and/or release of some humoral factors from RPE cells, which stimulate the growth of scleral cells. There is also a possibility that apomorphine reduces the reactivity of scleral cells to the humoral factors released from RPE cells. © 1997 John Wiley & Sons, Ltd.     

The development and characterization of anin vitro system to study strain-induced cell deformation in isolated chondrocytes

Summary A model system has been developed to investigate cell deformation of chondrocytesin vitro. Chondrocytes were isolated from bovine articular cartilage by enzymatic digestion and seeded in agarose (type VII) at a final concentration of 2 × 10⁶ cells·ml⁻¹ in 3% agarose. Mechanical evaluation of the system showed no change in the tangent modulus of agarose/chondrocyte cultures over a 6-d culture period. The resulting agarose/chondrocyte cultures were subjected to compressive strains ranging from 5–20%. Cell shape was assessed by measuring the dimensions of the cell both perpendicular (x) and parallel (y) to the axis of compression and deformation indices (I = y/x) calculated. Cell deformation increased with the level of strain applied for freshly isolated chondrocytes. The cultures were maintained in medium that inhibits or stimulates matrix production (DMEM and DMEM + 20% FCS, respectively) in order to assess the effect of cartilaginous matrix on chondrocyte deformation. Matrix elaborated by the cells markedly influenced levels of cell deformation, an increase in matrix leading to a decrease in cell deformation. Freshly isolated deep zone chondrocytes were found to deform significantly more than surface zone chondrocytes, although this effect was lost after 6 d in culture. The elaborated matrix also altered the recovery characteristics of the chondrocytes following constant compressive strain of 15% for 24 h. Cells that had elaborated matrix took several hours to return to unloaded shape, while cells without matrix returned to the unloaded shape instantly.     

Production of a membrane-bound proteins,the human gamma-glutamyl transferase,by CHO cells cultivated on microcarriers,in aggregates and in suspension

Recombinant Chinese Hamster Ovary (CHO) cells, engineered for the production of human gamma-glutamyl transferase (GGT), have been grown on Cytodex 1 microcarriers, as aggregates, or as single cells in suspension after adaptation. GGT is a membrane bound enzyme which was not secreted during the culture period. The maximal enzyme activity was found to be directly related to the achieved maximal cell density. Culture of CHO on microcarriers yielded the fastest growth, with a specific growth rate of 0.04 h^–1, the highest cell density (near 1.3×10⁶ cells ml^–1), and the highest enzyme activity around 300 mU ml^–1, which corresponded to a specific cellular level of 20 mU 10^–5 cells. GGT could also be produced by growing CHO cells in suspension as single cells or as aggregates. Under these conditions, however, the specific CHO growth rate was significantly slower and the GGT level per cell was divided by a factor 6. Growing CHO cells without microcarriers also resulted in differences in cell metabolism, with a higher conversion yield of glutamine into ammonia, and a higher cell lysis. The catalytic kinetic constants of the enzyme were found identical for the three culture systems.     

Effects of cations on Methanosarcina thermophila TM-1 growing on moderate concentrations of acetate: production of single cells

Summary The effects of different concentrations of Mg²⁺, Ca²⁺, or Na⁺ on the morphology and growth of Methanosarcina thermophila TM-1 growing on acetate at concentrations comparable with those found in anaerobic digestors was studied. At 30 mm Mg²⁺ or less, M. thermophila grew as large aggregates that settled rapidly. At 100 mm Mg²⁺ or more, the bacteria grew as single cells or a mixture of single cells and small aggregates is suspended culture. Mg²⁺ was necessary for growth and could not be substituted by addition of either Ca²⁺ or Na⁺. The optimal Mg²⁺ concentration was 30 mm and no growth was observed at 400 mm Mg²⁺. Cultures could be adapted to 300 mm Mg²⁺ without a change in growth rate. Added Ca²⁺ was not required for growth and had no effect on cell morphology. Inhibition by Na⁺ was directly related to the Mg²⁺ concentration. When the Mg²⁺ was 0.05 mm or less, 0.35 m Na⁺ completely inhibited growth. However, more Na⁺ was required for inhibition at higher Mg²⁺ concentrations. The same inhibitory effect of Na⁺ was observed when the temperature was 52°C or 45°C. The potential for disaggregation of Methanosarcina aggregates in anaerobic digestor environments was discussed. Offprint requests to: B. K. Ahring     

Response of articular chondrocytes to pituitary fibroblst growth factor (FGF)

Rabbit chondrocytes from pooled articular joints have been delineated by their time of attachment of culture flasks after initiation of primary monolayer culture, either attached (48-AT) or floating (48-F) after 48 hours. A general population of chrondrocytes (attached after 72 hours, 72-AT) was also studied. The growth-promoting activity of pituitary fibroblast growth factor (FGF) and its effect on sulfated-proteoglycan synthesis was studied on each chondrocyte population in secondary monolayer culture. ³H-thymidine incorporation during a 1-hour pulse was stimulated by FGF (100 ng/ml) in each chondrocyte population. The response of AT-72 chondrocytes to FGF required an additional fetal bovine serum supplement, while 48-F cells resonded independent of serum. The response of 48-AT chondrocytes to FGF (100 ng/ml) during a 1-hour pulse with ³H-thymidine was increased in low serum (0.5–2.0%) rather than when high serum (8–10%) was present in the culture medium. FGF reduced ³⁵SO₄ incorporation into sulfated-proteoglycans in the 48-AT and 48-F chondrocyte populations, but not in the 72-AT population. The reduction in ³⁵SO₄ incorporation in the 48-AT and 48-F chondrocytes was not characterized by alterations in the hydrodynamic size of the sulfated-proteoglycans as measured by Sepharose CL-2B chromatography nor by changes in the types of sulfated-glycosaminoglycans produced. These results indicated that FGF produced quantitative rather than qualitative alterations in chondrocyte sulfated-proteoglycan synthesis. The latter appears uncoupled from the growth-promoting activity of FGF on chondrocytes.