Isolation and Culturing of Primary Murine Chondroprogenitor Cells: A Mammalian Model of Chondrogenesis.

Embryonic limb bud-derived micromass cultures are valuable tools for investigating cartilage development, tissue engineering, and therapeutic strategies for cartilage-related disorders. This collection of fine-tuned protocols used in our laboratories outlines step-by-step procedures for the isolation, expansion, and differentiation of primary mouse limb bud cells into chondrogenic micromass cultures. Key aspects covered in these protocols include synchronized fertilization of mice (Basic Protocol 1), tissue dissection, cell isolation, micromass formation, and culture optimization parameters, such as cell density and medium composition (Basic Protocol 2). We describe techniques for characterizing the chondrogenic differentiation process by histological analysis (Basic Protocol 3). The protocols also address common challenges encountered during the process and provide troubleshooting strategies. This fine-tuned comprehensive protocol serves as a valuable resource for scientists working in the fields of developmental biology, cartilage tissue engineering, and regenerative medicine, offering an updated methodology for the study of efficient chondrogenic differentiation and cartilage tissue regeneration. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Synchronized fertilization of mice Basic Protocol 2: Micromass culture of murine embryonic limb bud-derived cells Basic Protocol 3: Qualitative assessment of cartilage matrix production using Alcian blue staining.

Isolation and Micromass Culturing of Primary Chicken Chondroprogenitor Cells for Cartilage Regeneration.

Much of the skeletal system develops by endochondral ossification, a process that takes place in early fetal life. This makes the early stages of chondrogenesis, i.e., when chondroprogenitor mesenchymal cells differentiate to chondroblasts, challenging to study in vivo. In vitro methods for the study of chondrogenic differentiation have been available for some time. There is currently high interest in developing fine-tuned methodology that would allow chondrogenic cells to rebuild articular cartilage and restore joint functionality. The micromass culture system that relies on embryonic limb bud-derived chondroprogenitor cells is a popular method for the study of the signaling pathways that control the formation and maturation of cartilage. In this protocol, we describe a technique fine-tuned in our laboratory for culturing limb bud-derived mesenchymal cells from early-stage chick embryos in high density (Basic Protocol 1). We also provide a fine-tuned method for high-efficiency transient transfection of cells before plating using electroporation (Basic Protocol 2). In addition, protocols for histochemical detection of cartilage extracellular matrix using dimethyl methylene blue, Alcian blue, and safranin O are also provided (Basic Protocol 3 and Alternate Protocols 1 and 2, respectively). Finally, a step-by-step guide on a cell viability/proliferation assay using MTT reagent is also described (Basic Protocol 4). © 2023 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Micromass culture of chick embryonic limb bud-derived cells Basic Protocol 2: Transfection of cells with siRNA constructs using electroporation prior to micromass culturing Basic Protocol 3: Qualitative and quantitative assessment of cartilage matrix production using dimethyl methylene blue staining and image analysis Alternate Protocol 1: Qualitative assessment of cartilage matrix production using Alcian blue staining Alternate Protocol 2: Qualitative assessment of cartilage matrix production using safranin O staining Basic Protocol 4: Measurement of mitochondrial activity with the MTT assay.

Pentosan polysulfate sodium promotes redifferentiation to the original phenotype in micromass-cultured canine articular chondrocytes and exerts molecular weight-dependent effects.

Pentosan polysulfate sodium (PPS) is a heparin-like polysaccharide that is applied as a therapeutic treatment for osteoarthritis (OA) in animals. This study investigated the efficacy of different molecular weights PPS (1,500-7,000 Da) on the phenotype regulatory and chondrogenic properties of canine articular chondrocytes. The cytotoxicity of PPS on chondrocytes was assessed using flow cytometry and 3-(4,5-dimehylthiazolyl-2)-2,5-diphenyltetrazolium bromide assay. After 72 hr of exposure, PPS did not induce chondrocyte apoptosis, regardless of molecular weight. In addition, chondrogenic properties were determined according to the mRNA and protein levels in micromass-cultured chondrocytes. Quantitative polymerase chain reaction analysis confirmed that PPS promotes a chondrogenic phenotype in chondrocytes in a molecular weight-dependent manner, with significant upregulation of collagen type II alpha 1 chain, aggrecan, and SRY-box transcription factor 9 (SOX9) mRNA levels relative to those in the control. However, the collagen type I alpha 2 chain mRNA level simultaneously increased after 7,000 Da PPS treatment. PPS exposure also increased collagen type II and SOX9 protein production in a molecular weight-dependent manner and inhibited Akt phosphorylation in chondrocytes. Alcian blue staining indicated that PPS treatment enhanced proteoglycan deposition in micromass cultures, with stronger effects observed in 5,000 and 7,000 Da groups. Overall, these results indicate that PPS exerts protective effects on the chondrocyte phenotype and may represent a potential therapeutic target for OA treatment. Increasing the molecular weight of PPS could enhance these anabolic effects.

Geometric analysis of chondrogenic self-organisation of embryonic limb bud cells in micromass culture.

Spatial and temporal control of chondrogenesis generates precise, species-specific patterns of skeletal structures in the developing vertebrate limb. The pattern-template is laid down when mesenchymal cells at the core of the early limb bud condense and undergo chondrogenic differentiation. Although the mechanisms involved in organising such complex patterns are not fully understood, the interplay between BMP and Wnt signalling pathways is fundamental. Primary embryonic limb bud cells grown under high-density micromass culture conditions spontaneously create a simple cartilage nodule pattern, presenting a model to investigate pattern generation. We describe a novel analytical approach to quantify geometric properties and spatial relationships between chondrogenic condensations, utilizing the micromass model. We follow the emergence of pattern in live cultures with nodules forming at regular distances, growing and changing shape over time. Gene expression profiling supports rapid chondrogenesis and transition to hypertrophy, mimicking the process of endochondral ossification within the limb bud. Manipulating the signalling environment through addition of BMP or Wnt ligands, as well as the BMP pathway antagonist Noggin, altered the differentiation profile and nodule pattern. BMP2 addition increased chondrogenesis while WNT3A or Noggin had the opposite effect, but with distinct pattern outcomes. Titrating these pro- and anti-chondrogenic factors and examining the resulting patterns support the hypothesis that regularly spaced cartilage nodules formed by primary limb bud cells in micromass culture are influenced by the balance of Wnt and BMP signalling under a Turing-like mechanism. This study demonstrates an approach for investigating the mechanisms governing chondrogenic spatial organization using simple micromass culture.

[Evaluation of developmental toxicity of ammonium dinitramide by micromass culture and embryonic stem cells models].

Objective: To evaluated the potential developmental toxicity and teratogenicity of ammonium dinitroamide (ADN) by micromass test (MM Test) and embryonic stem cell test models. Methods: In September 2018, rat embryos were isolated and limb bud cells were collected. The limb bud cells were treated with different concentrations of ADN (0, 312.50, 625.00, 1250.00, 2500.00, 5000.00, 10000.00 µg/ml) . Half proliferation inhibitory concentration and half differentiation inhibitory concentration were calculated and the teratogenic effects were evaluated according to the criteria. For the embryonic stem cell test, the effects of different concentrations of ADN (0, 39.06, 78.13, 156.25, 312.50, 625.00, 1250.00, 2500.00 µg/ml) on the differentiation of mouse embryonic stem cells (mESCs) into myocardial cells and the cytotoxicity of mESCs and 3T3 cells were detected. The embryonic toxicity was evaluated according to the criteria. In this study, both 5-fluorouracil (5-FU) , a known strong embryonic toxic drug, and penicillin-G (P-G) , a non-embryonic toxic drug, were used to verify the effectiveness of the model, and the validated test model was applied to evaluate the embryonic toxicity of ADN. Results: In the MM Test, the inhibition rates of proliferation and differentiation of limb bud cells in ADN groups were higher than that in control group (P<0.05) . And the half proliferation inhibitory concentration and half differentiation inhibitory concentration of ADN on limb bud cells were 7480.32 and 4526.09 µg/ml, respectively. ADN was determined to be non-teratogenic by standard. In the embryonic stem cell test, the inhibition rates of mESCs proliferation in ADN groups were higher than that in control group, and the inhibition rates of 3T3 cells in 156.25, 312.50, 625.00, 1250.00, 2500.00 µg/ml ADN groups were higher than that in control group (P<0.05) . The half proliferation inhibitory concentration and half differentiation inhibitory concentration of ADN on mESCs were 1851.73 and 1796.39 µg/ml, respectively, and the half proliferation inhibitory concentration on 3T3 cells was 3334.35 µg/ml. ADN was determined to be non-embryotoxic by standard. Conclusion: After evaluation by MM Test and embryonic stem cell models, ADN has no embryo toxicity and is a non-teratogenic substance.

Analysis of Gene Expression Patterns of Epigenetic Enzymes Dnmt3a, Tet1 and Ogt in Murine Chondrogenic Models.

We investigated the gene expression pattern of selected enzymes involved in DNA methylation and the effects of the DNA methylation inhibitor 5-azacytidine during in vitro and in vivo cartilage formation. Based on the data of a PCR array performed on chondrifying BMP2-overexpressing C3H10T1/2 cells, the relative expressions of Tet1 (tet methylcytosine dioxygenase 1), Dnmt3a (DNA methyltransferase 3), and Ogt (O-linked N-acetylglucosamine transferase) were further examined with RT-qPCR in murine cell line-based and primary chondrifying micromass cultures. We found very strong but gradually decreasing expression of Tet1 throughout the entire course of in vitro cartilage differentiation along with strong signals in the cartilaginous embryonic skeleton using specific RNA probes for in situ hybridization on frozen sections of 15-day-old mouse embryos. Dnmt3a and Ogt expressions did not show significant changes with RT-qPCR and gave weak in situ hybridization signals. The DNA methylation inhibitor 5-azacytidine reduced cartilage-specific gene expression and cartilage formation when applied during the early stages of chondrogenesis. In contrast, it had a stimulatory effect when added to differentiated chondrocytes, and quantitative methylation-specific PCR proved that the DNA methylation pattern of key chondrogenic marker genes was altered by the treatment. Our results indicate that the DNA demethylation inducing Tet1 plays a significant role during chondrogenesis, and inhibition of DNA methylation exerts distinct effects in different phases of in vitro cartilage formation.

A Synchronized Circadian Clock Enhances Early Chondrogenesis.

OBJECTIVE: Circadian rhythms in cartilage homeostasis are hypothesized to temporally segregate and synchronize the activities of chondrocytes to different times of the day, and thus may provide an efficient mechanism by which articular cartilage can recover following physical activity. While the circadian clock is clearly involved in chondrocyte homeostasis in health and disease, it is unclear as to what roles it may play during early chondrogenesis. DESIGN: The purpose of this study was to determine whether the rhythmic expression of the core circadian clock was detectable at the earliest stages of chondrocyte differentiation, and if so, whether a synchronized expression pattern of chondrogenic transcription factors and developing cartilage matrix constituents was present during cartilage formation. RESULTS: Following serum shock, embryonic limb bud-derived chondrifying micromass cultures exhibited synchronized temporal expression patterns of core clock genes involved in the molecular circadian clock. We also observed that chondrogenic marker genes followed a circadian oscillatory pattern. Clock synchronization significantly enhanced cartilage matrix production and elevated SOX9, ACAN, and COL2A1 gene expression. The observed chondrogenesis-promoting effect of the serum shock was likely attributable to its synchronizing effect on the molecular clockwork, as co-application of small molecule modulators (longdaysin and KL001) abolished the stimulating effects on extracellular matrix production and chondrogenic marker gene expression. CONCLUSIONS: Results from this study suggest that a functional molecular clockwork plays a positive role in tissue homeostasis and histogenesis during early chondrogenesis.

Modeling appendicular skeletal cartilage development with modified high-density micromass cultures of adult human bone marrow-derived mesenchymal progenitor cells.

BACKGROUND: Animal cell-based systems have been critical tools in understanding tissue development and physiology, but they are less successful in more practical tasks, such as predicting human toxicity to pharmacological or environmental factors, in which the congruence between in vitro and clinical outcomes lies on average between 50 and 60%. Emblematic of this problem is the high-density micromass culture of embryonic limb bud mesenchymal cells, derived from chick, mouse, or rat. While estimated predictive value of this model system in toxicological studies is relatively high, important failures prevent its use by international regulatory agencies for toxicity testing and policy development. A likely underlying reason for the poor predictive capacity of animal-based culture models is the small but significant physiological differences between species. This deficiency has inspired investigators to develop more organotypic, 3-dimensional culture system using human cells to model normal tissue development and physiology and assess pharmacological and environmental toxicity. METHODS: We have developed a modified, miniaturized micromass culture model using adult human bone marrow-derived mesenchymal progenitor cells (hBM-MPCs) that is amenable to moderate throughput and high content analysis to study chondrogenesis. The number of cells per culture was reduced, and a methacrylated gelatin (gelMA) overlay was incorporated to normalize the morphology of the cultures. RESULTS: These modified human cell-based micromass cultures demonstrated robust chondrogenesis, indicated by increased Alcian blue staining and immunodetectable production of collagen type II and aggrecan, and stage-specific chondrogenic gene expression. In addition, in cultures of hBM-MPCs transduced with a lentiviral collagen type II promoter-driven GFP reporter construct, levels of GFP reporter activity correlated well with changes in endogenous collagen type II transcript levels, indicating the feasibility of non-invasive monitoring of chondrogenesis. CONCLUSIONS: The modified hBM-MPC micromass culture system described here represents a reproducible and controlled model for analyzing mechanisms of human skeletal development that may later be applied to pharmacological and environmental toxicity studies.

A novel and efficient method for culturing mouse nucleus pulposus cells.

BACKGROUND CONTEXT: As degeneration of the nucleus pulposus (NP) is a major cause of intervertebral disc degeneration, research directed toward nucleus pulposus cells (NPCs) is drawing increased attention. However, caused by the difficulties associated with their harvest and culture, there are few reports describing cultivation methods for mouse NP cells (mNPCs). PURPOSE: To establish efficient culture methods for mNPCs. STUDY DESIGN: In vitro animal study. METHODS: After primary 3-dimensional (3D) gel culture of mNPCs and analysis of gene expression, cells digested from the gel were cultured in various bio-coated dishes with and without basic fibroblast growth factor (bFGF), and their growth kinetics and changes in gene expression profiles were evaluated. Next, the mNPCs obtained after sequential 3D gel and 2D culture were subjected to micromass culture and the effects of adding transforming growth factor-ß3 (TGF-ß3) on their gene expression profile and extracellular matrix (ECM) synthesis were evaluated. RESULTS: The cell morphology and gene expression pattern of mNPCs proliferated in primary 3D collagen gel culture resembled those of mNP. In contrast, mNPCs could not proliferate in conventional monolayer culture. Cell adhesion (colony number) and proliferation (colony size) were greater in fibronectin-coated dishes than in dishes with other bio-coatings. The addition of bFGF enhanced mNPCs proliferation, but the gene expression characteristics of mNPCs were lost as passage number increased. 2D culture with bFGF followed by micromass culture allowed for the recovery of the mNPC gene expression profile in primary 3D-gel culture, and TGF-ß3 supplementation during micromass culture enhanced ECM synthesis. CONCLUSIONS: We established novel culture methods for mNPCs. These methods will benefit basic cell-based and molecular research involving these cells.

Cartilage Induction from Mouse Mesenchymal Stem Cells in High-density Micromass Culture.

Mesenchymal stem cells have the ability to differentiate into multiple lineages, including adipocytes, osteoblasts and chondrocytes. Mesenchymal stem cells can be induced to differentiate into chondrocytes in extracellular matrices, such as alginate or collagen gel. Mesenchymal stem cells in a cell pellet or micromass culture can be also induced to form cartilages in a defined medium containing chondrogenic cytokines, such as transforming growth factor-ß (TGF-ß). Here, we describe a simple method to form cartilage by seeding mesenchymal cells derived from limb-bud cells at high cell density. First, we dissected the limb buds from embryonic mice (embryonic day 12.5) and digested them with enzymes (dispase and collagenase). After filtration using a cell strainer, we seeded the cells at high density. Unlike other methods, the method described here is simple and does not require the use of specialized equipment, expensive materials or complex reagents.

Micromass cultures are effective for differentiation of human amniotic fluid stem cells into chondrocytes

OBJECTIVES: Articular cartilage is vulnerable to injuries and undergoes an irreversible degenerative process. The use of amniotic fluid mesenchymal stromal stem cells for the reconstruction of articular cartilage is a promising therapeutic alternative. The aim of this study was to investigate the chondrogenic potential of amniotic fluid mesenchymal stromal stem cells from human amniotic fluid from second trimester pregnant women in a micromass system (high-density cell culture) with TGF-β3 for 21 days. METHODS: Micromass was performed using amniotic fluid mesenchymal stromal stem cells previously cultured in a monolayer. Chondrocytes from adult human normal cartilage were used as controls. After 21 days, chondrogenic potential was determined by measuring the expression of genes, such as SOX-9, type II collagen and aggrecan, in newly differentiated cells by real-time PCR (qRT-PCR). The production of type II collagen protein was observed by western blotting. Immunohistochemistry analysis was also performed to detect collagen type II and aggrecan. This study was approved by the local ethics committee. RESULTS: SOX-9, aggrecan and type II collagen were expressed in newly differentiated chondrocytes. The expression of SOX-9 was significantly higher in newly differentiated chondrocytes than in adult cartilage. Collagen type II protein was also detected. CONCLUSION: We demonstrate that stem cells from human amniotic fluid are a suitable source for chondrogenesis when cultured in a micromass system. amniotic fluid mesenchymal stromal stem cells are an extremely viable source for clinical applications, and our results suggest the possibility of using human amniotic fluid as a source of mesenchymal stem cells.

Chondrogenesis of embryonic limb bud cells in micromass culture progresses rapidly to hypertrophy and is modulated by hydrostatic pressure.

Chondrogenesis in vivo is precisely controlled in time and space. The entire limb skeleton forms from cells at the core of the early limb bud that condense and undergo chondrogenic differentiation. Whether they form stable cartilage at the articular surface of the joint or transient cartilage that progresses to hypertrophy as endochondral bone, replacing the cartilage template of the skeletal rudiment, is spatially controlled over several days in the embryo. Here, we follow the differentiation of cells taken from the early limb bud (embryonic day 11.5), grown in high-density micromass culture and show that a self-organising pattern of evenly spaced cartilage nodules occurs spontaneously in growth medium. Although chondrogenesis is enhanced by addition of BMP6 to the medium, the spatial pattern of nodule formation is disrupted. We show rapid progression of the entire nodule to hypertrophy in culture and therefore loss of the local signals required to direct formation of stable cartilage. Dynamic hydrostatic pressure, which we have previously predicted to be a feature of the forming embryonic joint region, had a stabilising effect on chondrogenesis, reducing expression of hypertrophic marker genes. This demonstrates the use of micromass culture as a relatively simple assay to compare the effect of both biophysical and molecular signals on spatial and temporal control of chondrogenesis that could be used to examine the response of different types of progenitor cell, both adult- and embryo-derived.

Rac1 promotes chondrogenesis by regulating STAT3 signaling pathway.

The small GTPase protein Rac1 is involved in a wide range of biological processes including cell differentiation. Previously, Rac1 was shown to promote chondrogenesis in micromass cultures of limb mesenchyme. However, the pathways mediating Rac1's role in chondrogenesis are not fully understood. This study aimed to explore the molecular mechanisms by which Rac1 regulates chondrogenic differentiation. Phosphorylation of signal transducer and activator of transcription 3 (STAT3) was increased as chondrogenesis proceeded in micromass cultures of chick wing bud mesenchyme. Inhibition of Rac1 with NSC23766, janus kinase 2 (JAK2) with AG490, or STAT3 with stattic inhibited chondrogenesis and reduced phosphorylation of STAT3. Conversely, overexpression of constitutively active Rac1 (Rac L61) increased phosphorylation of STAT3. Rac L61 expression resulted in increased expression of interleukin 6 (IL-6), and treatment with IL-6 increased phosphorylation of STAT3. NSC23766, AG490, and stattic prohibited cell aggregation, whereas expression of Rac L61 increased cell aggregation, which was reduced by stattic treatment. Our studies indicate that Rac1 induces STAT3 activation through expression and action of IL-6. Overexpression of Rac L61 increased expression of bone morphogenic protein 4 (BMP4). BMP4 promoted chondrogenesis, which was inhibited by K02288, an activin receptor-like kinase-2 inhibitor, and increased phosphorylation of p38 MAP kinase. Overexpression of Rac L61 also increased phosphorylation of p38 MAPK, which was reduced by K02288. These results suggest that Rac1 activates STAT3 by expression of IL-6, which in turn increases expression and activity of BMP4, leading to the promotion of chondrogenesis.

Chlormequat chloride retards rat embryo growth in vitro.

Chlormequat chloride is the most widely used plant growth regulator in agriculture to promote sturdier growth of grain crops by avoidance of lodging. Therefore, human exposure to chlormequat chloride is very common, but its developmental toxicity has not been studied. Thus, we investigated the developmental toxicity of chlormequat chloride by applying rat whole embryo culture (WEC) model, limb bud micromass culture and 3T3 fibroblast cytotoxicity test. Chlormequat chloride at 150µg/ml (0.93mM) retarded the rat embryo growth without causing significant morphological malformations and at 500µg/ml (3.1mM) caused both retardation and morphological malformation of the embryos. However, the proliferation and differentiation of limb bud cells were not affected by chlormequat chloride at as high as up to 1000µg/ml (6.2mM) applied. This concentration of chlormequat chloride did not affect the cell viability as examined by 3T3 fibroblast cytotoxicity test either, suggesting that cellular toxicity may not play a role in chlormequat induced inhibition of rat embryo growth. Collectively, our results demonstrated that chlormequat chloride may affect embryo growth and development without inhibiting cell viability.

Ethanol exposure represses osteogenesis in the developing chick embryo.

It is known that excess alcohol consumption during pregnancy can increase the risk of fetal alcohol spectrum disorder (FASD). However, the effect of ethanol exposure on bone morphogenesis in fetus is largely unknown. In this study, we demonstrated that ethanol treatment of gastrulating chick embryos could inhibit long bone (humerus, radius and ulna) development. Histological examination revealed that ethanol exposure reduced the width of the proliferation and hypertrophic zones. In addition, cell proliferation and alkaline phosphatase activities were repressed. We also investigated the effect on chondrogenesis and chondrogenesis was inhibited. Ethanol exposure also induced excess reactive oxygen species (ROS) production and altered the expression of osteogenesis-related genes. The inhibiting effect on flat bone (sclerotic ossicle) and the generation of cranial neural crest cells (progenitors of craniofacial bones) was also presented. In conclusion, ethanol exposure during the embryonic period retards bone development through excess ROS production and altered bone-associated gene expression.

Inflammatory effects of TNFα are counteracted by X-ray irradiation and AChE inhibition in mouse micromass cultures.

As a means to analyze anti-inflammatory effects by radiation and/or by cholinergic mechanisms, we found that cultured primary human osteoblasts express most cholinergic components. After X-ray irradiation, their level of acetylcholinesterase (AChE) was strongly elevated. As a 3D model, we cultured mesenchymal stem cells isolated from E11 mouse embryos as micromass nodules, and differentiated them into chondro- and osteoblasts. They were stimulated by 5 or 10 ng/ml of the inflammatory cytokine TNF-α to mimic an inflammatory condition in vitro, before exposure to 2 Gy X-rays. Effects on chondro- and osteoblasts of TNF-α, of X-rays, or both were analysed by Alcian Blue, or Alizarin Red staining, respectively. Acetylcholinesterase (AChE) activity was visualized histochemically. The results showed that treatment with TNF-α affected cartilage and bone formation in vitro, while X-rays reversed the effects of TNF-α. After irradiation, both AChE and alkaline phosphatase (ALP) activities, a marker for bone mineralization, were raised, suggesting that X-rays stimulated cholinergic mechanisms during calcification. Notably, the TNFα-effects on cultures were also counterbalanced after AChE activity was blocked by BW284c51. These findings suggest a complex crosstalk between radiation, cholinergic and inflammatory mechanisms, which could have wide significances, e.g. for understanding rheumatoid arthritis.

Differentiation of Human Induced Pluripotent Stem Cells to Chondrocytes.

Human induced pluripotent stem (iPS) cells are relevant tools for modeling human skeletal development and disease, and represent a promising source of patient-specific cells for the regeneration of skeletal tissue, such as articular cartilage. Devising efficient and reproducible strategies, which closely mimic the physiological chondrogenic differentiation process, will be necessary to generate functional chondrocytes from human iPS cells. Our previous study demonstrated the generation of chondrogenically committed human iPS cells via the enrichment of a mesenchymal-like progenitor population, application of appropriate high-density culture conditions, and stimulation with bone morphogenetic protein-2 (Bmp-2). The differentiated iPS cells showed temporal expression of cartilage genes and the accumulation of a cartilaginous extracellular matrix in vitro. In this chapter, we provide detailed methodologies for the differentiation of human iPS cells to the chondrogenic lineage and describe protocols for the analysis of chondrogenic differentiation.

Gradient Fractionated Separation of Chondrogenically Committed Cells Derived from Human Embryonic Stem Cells.

Cartilage regeneration is a fast growing field that combines biotechnology and molecular techniques in creating new tissue mimicking the native microenvironment. Human embryonic stem cells (hESCs) are a highly potent cell source for cartilage regeneration owing to their infinite proliferation capacity and pluripotency. Thus, lineage-specific differentiation of hESCs often results in populations with cellular heterogeneity. Chondrogenesis was induced through high-density micromass culture of hESCs and by addition of chondrogenic medium; 1:100 ITS(+), 100 nM dexamethasone, 40 µg/ml l-proline, 50 µg/mL ascorbic acid-2-phosphate, 1:100 Knockout serum, and 10 ng/mL TGFß3. At day 14 micromasses were dissociated and chondrogenically committed cell separated in a fraction-based discontinuous density gradient. After fractionation the chondrogenically committed cells were analyzed with regard to embryonic- and chondrogenic gene expression and fraction F3 and F4 with histology. In general, we found that the chondrogenic condition compared with the control condition had a significant effect on the following gene expression levels: NANOG, OCT4, SOX5, SOX9, ACAN, and COL2A1 in all fractions. Furthermore, we found in the chondrogenic condition that NANOG, OCT4, and SOX9 were significantly higher in F4 compared with F3, whereas COL2A1 and the ratio COL2A1:COL1A1 were significantly lower. Additionally, toluidine blue pH 4 stains of pellet cultures of F3 and F4 revealed that cells from F3 were more homogenous in morphology than F4. In conclusion, we propose a simple strategy to obtain more homogenous population of chondrogenically committed cells from hESCs using micromass culture and discontinuous density gradient separation.

Carbamazepine toxic effects in chick cardiomyocyte micromass culture and embryonic stem cell derived cardiomyocyte systems--possible protective role of antioxidants.

The use of carbamazepine (CBZ) during pregnancy increases cardiovascular anomalies. In this study CBZ developmental cardiotoxic effects were evaluated using chick cardiomyocyte micromass (MM) culture and mouse embryonic stem cells derived cardiomyocyte (ESDC) systems. In MM culture, CBZ only inhibited the cardiomyocyte contractile activity, while in ESDC it completely ceased the contractile activity at 200 µM with decreased cell viability and protein content. The antioxidant superoxide dismutase (SOD) supplement in MM and ascorbic acid (AA) in ESDC showed protective effects on CBZ toxicity, but elevated levels of reactive oxygen species (ROS) production were recorded with CBZ treatment only in ESDC. CBZ has also affected cardiac connexin 43 expression in both in vitro systems. Our results indicated CBZ induced ROS stress as mechanism of developmental cardiotoxicity at early stage of cardiogenesis in ESDC system compared to MM system's differentiated cells. These toxic effects can be negated by using antioxidant agent.

Biphasic influence of dexamethasone exposure on embryonic vertebrate skeleton development.

Dexamethasone (Dex) has anti-inflammatory and immunomodulatory properties against many conditions. There is a potential teratogenic risk, however, for pregnant women receiving Dex treatment. It has been claimed that Dex exposure during pregnancy could affect osteogenesis in the developing embryo, which still remains highly controversial. In this study, we employed chick embryos to investigate the effects of Dex exposure on skeletal development using combined in vivo and in vitro approach. First, we demonstrated that Dex (10(-8)-10(-6)µmol/egg) exposure resulted in a shortening of the developing long bones of chick embryos, and it accelerated the deposition of calcium salts. Secondly, histological analysis of chick embryo phalanxes exhibited Dex exposure inhibited the proliferation of chondrocytes, increased apoptosis of chondrocytes and osteocytes, and led to atypical arranged hypertrophic chondrocytes. The expression of genes related to skeletogenesis was also analyzed by semi-quantitative RT-PCR. The expression of ALP, Col1a2 and Col2a1 was decreased in the Dex treated phalanxes. A detectable increase was observed in Runx-2 and Mmp-13 expression. We next examined how Dex affected the different stages of skeletogenesis in vitro. Utilizing limb bud mesenchyme micromass cultures, we determined that Dex exposure exerted no effect on apoptosis but impaired chondrogenic cell proliferation. Interestingly, low dose of Dex moderately prompted nodule formation as revealed by alcian blue staining, but higher doses of Dex significantly inhibited similar chondrogenic differentiation. Dex exposure did not induce apoptosis when the chondrogenic precursors were still at the mesenchymal stage, however, cell viability was suppressed when the mesenchyme differentiated into chondrocytes. Alizarin red staining revealed that the capacity to form mineralized bone nodules was correspondingly enhanced as Dex concentrations increased. The mRNA level of Sox-9 was slightly increased in mesenchymal cell mass treated by low concentration of Dex. Mmp-13 expression was obviously up-regulated by Dex in both mesenchymal cells and primary chondrocyte cultures. And Col10a1 expression was also increased by Dex exposure in chondrocyte. In summary, we have revealed that different concentrations of Dex exposure during early gestation could exert a biphasic effect on vertebrate skeletal development.