A novel method for analysis of the periodicity of chondrogenic patterns in limb bud cell culture: correlation of in vitro pattern formation with theoretical models

To experimentally examine whether the pattern changes predicted by theoretical models of pattern formation actually occur in a limb bud cell culture system, we developed a practical method to automatically measure the periodicity of chondrogenic patterns in vitro. The method utilizes binary image processing to quantify the total number of peak and valley pixels in a pattern to obtain the average interval between stripes in the chondrogenic pattern, and we named it the peak length method. The reliability of the peak length method was examined by using computer simulation results. The peak length method enabled us quantitatively obtain the average interval between chondrogenic islands, and the values obtained by this method were closely correlated with the average intervals obtained by manual measurement and two-dimensional Fourier transformation. The average intervals obtained by the peak length method were shown to be stable over a wide range of pattern variations that are frequently observed in actual experiments. By applying the peak length method to actual experimental data, we compared the validity of two theoretical models of pattern formation (cell sorting model and reaction-diffusion model) and it was concluded that the peak-length method is a useful tool to quantitatively analyze chondrogenic patterns in limb micromass culture and to relate theoretical predictions and experimental results of pattern formation.     

TGFbeta2 acts as an "activator" molecule in reaction-diffusion model and is involved in cell sorting phenomenon in mouse limb micromass culture.

It was previously speculated that TGFbeta acts as an "activator"-molecule in chondrogenic pattern formation in the limb micromass culture system, but its precise role and relationship with the cell sorting phenomenon have not been properly studied. In the present study, we examined whether the TGFbeta2 molecule satisfies the necessary conditions for an "activator"-molecule in the reaction-diffusion model. Firstly, we showed that TGFbeta2 became localized at chondrogenic sites during the establishment of a chondrogenic pattern, and exogenous TGFbeta2 promoted chondrogenesis when added in the culture medium. Secondly, TGFbeta2 protein was shown to promote the production of its own mRNA after 3 hr, indicating that a positive feedback mechanism exists which may be responsible for the emergence of the chondrogenic pattern. We then found that when locally applied with beads, TGFbeta2 suppressed chondrogenesis around the beads, indicating it induces the lateral inhibitory mechanism, which is a key element for the formation of the periodic pattern. We also examined the possible effects of TGFbeta2 on the cell sorting phenomenon and found that TGFbeta2 exerts differential chemotactic activity on proximal and distal mesenchyme cells of the limb bud, and at very early phases of differentiation TGFbeta2 promotes the expression of N-cadherin protein which is known to be involved in pattern formation in this culture system. These findings suggest that TGFbeta2 acts as an "activator"-like molecule in chondrogenic pattern formation in vitro, and is possibly responsible for the cell sorting phenomenon.     

A co-culture system for studies of paracrine effects of stromal cells on the growth of epithelial cells

Summary We have developed a co-culture system to study paracrine effects of fetal mesenchyme cells on the growth of primary mammary epithelial cells of the mouse. The method should be adaptable for study of interaction of a variety of cell populations. The procedure is simple and inexpensive. The culture consists of four layers: a monolayer of mesenchyme cells on a plastic culture dish, a soft agarose layer overlaying the cell monolayer, epithelial cells suspended in collagen gel placed atop the agarose, and culture medium above the collagen gel. The agarose layer prevents direct contact of two different cell populations but allows soluble molecules produced by either cell population to diffuse through the system, so as to contact and interact with the other cell population.     

The extracellular ATP receptor, cP2Y(1), inhibits cartilage formation in micromass cultures of chick limb mesenchyme.

We have investigated the function of the G protein-coupled receptor for extracellular ATP, chick P2Y(1) (cP2Y(1)) during development of the chick limb. cP2Y(1) is strongly expressed in undifferentiated limb mesenchyme cells but appears to be lost from cells as they differentiate, raising the possibility that the function of this receptor may be to inhibit cell differentiation. This pattern of expression was particularly striking surrounding areas of cartilage formation. We tested whether cP2Y(1) was able to regulate cartilage formation by using an in-vitro micromass model of chondrogenesis. Because limb cells in micromass culture lose expression of cP2Y(1), we have used a gain-of-function approach to demonstrate that cP2Y(1) expression can inhibit cartilage differentiation. We also demonstrate that early limb mesenchyme cells release ATP into the extracellular medium and have mechanisms to breakdown extracellular ATP. These results suggest that extracellular ATP, signaling through cP2Y(1), can modulate the differentiation of limb mesenchyme cells in vitro, and the expression pattern of cP2Y(1) suggests that this type of signaling could play a similar role in ovo.     

In vitro production of monoclonal antibodies to cultured embryonic chick limb mesenchyme

A simple, rapid protocol for the in vitro production of monoclonal antibodies (MAbs) that recognize native antigens in cultured chick limb mesenchyme during chondrogenic differentiation is described. Murine lymphocytes were stimulated by direct exposure to methanol-fixed micromass cultures of limb mesenchyme derived from the distal tip of stage 25 chick limb buds. Initial immunohistochemical characterization of two antibodies (DIDI and DIIA5) produced by this method showed preferential localization of reactivity with antigens in developing cartilage nodules during chondrogenesis in cultured chick limb mesenchyme. This study demonstrates the utility of in vitroimmunization of lymphocytes for the production of MAbs to native antigens expressed by differentiating embryonic limb cells in culture. Immunohistochemical data provided by DIDI and DIIA5 suggest that antigens bearing these epitopes may be important in early morphogenetic events during limb skeletal development.     

Morphogenesis of precursor subpopulations of chicken limb mesenchyme in three dimensional collagen gel culture

Although homogeneous in appearance, several lines of evidence suggest early (stage 17-19) limb mesenchymal cells are committed to particular cell lineages, e.g., myogenic or chondrogenic. However, subsequent expression of cell or tissue phenotype in the developing limb does not occur in a randomized process but rather in a spatially specific pattern. The potential regulatory mechanisms controlling the "patterned" expression of tissue phenotype in the limb have not been resolved. The purpose of this study was to determine if, prior to the formation of an apical ectodermal ridge, nondissociated limb mesenchyme has inherent morphogenetic potential to form nonrandomized patterns of tissue organization. The hypotheses to be tested were that, if provided a spatially permissive culture environment, 1) mesenchymal cells committed to a particular lineage would segregate into precursor (sub)populations prior to overt expression of phenotype and 2) the ultimate expression of a tissue phenotype may be regulated, in part, by histogenic interactions between the precursor cell groups. For these studies, mesoblasts (intact mesenchyme minus ectoderm) from stage 17-19 hindlimb buds were explanted intact to the surface of a 1-3 mm thick hydrated lattice of repolymerized type I collagen and incubated for 2-11 days. Examination of cultures at variable intervals revealed three distinct temporal sequences (periods) which were arbitrarily termed early morphogenesis (0-3 days), cytodifferentiation (3-5.5 days), and primitive tissue formation (5.5-11 days) based on similarities to in situ limb development. By the end of the first period, the mesenchymal cells had sorted into three distinct precursor populations: 1) an epithelial-like outgrowth of premyogenic and prefibrogenic cells at the surface of the gel lattice (termed the "surface subset") which circumscribed, 2) a centrally positioned prechondrogenic condensate ("central subset"), and overlaid 3) a dispersed, population of free cells that invaded the collagen lattice ("seeded subset"). Subsequent cytodifferentiation led to the appearance of multinucleated myotubes within the surface subset and chondrification of the central subset. Cells of the seeded subset remained dispersed within the collagen lattice. Primitive histogenic events were initiated during the final period of development including 1) at sites where surface cells established boundaries with the central subset, collectives or "bundles" of variable sized myotubes were formed which became partially ensheathed by the attenuated processes of fibroblastlike cells; and 2) a secondary site of chondrogenic activity was initiated within the gel lattice at the boundary between the central and seeded cell populations. Transformation of seeded fibroblasts into chondroblasts accompanied expansion of the secondary chondrogenic element within the gel lattice.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of different embedding gels on periostealchondrogenesis in vitro

To develop a more useful organ culture model for periosteal chondrogenesis in vitro, we compared the effects of the embedding of explants in agarose versus collagen gels. Chondrogenic differentiation was examined by means of histological observation and in terms of the expression of mRNA encoding two cartilage markers, Type II collagen and Aggrecan. Periosteal explants were derived from the tibiae of rabbits. These explants were embedded in either agarose gel or collagen gel and cultured for 6 weeks. Histological examinations revealed that in the agarose gel, cells were neither present in the explants nor in the gel. In the collagen gel, cells migrated from the explanted tissues into the gel, and some cells were round. However, no explants showed safranin-O staining. Only 10% of 10 surviving explants in the agarose gel expressed the Type II collagen gene and the Aggrecan gene. On the other hand, of 25 surviving explants in the collagen gel, the expression of the Type II collagen gene was detected in 18 explants (72%) and that of the Aggrecan gene was detected in 21 explants (84%). In conclusion, we demonstrated that the periosteum exerts chondrogenesis in certain circumstances and its chondrogenesis is closely related to the culture material.     

Hydrogel effects on bone marrow stromal cell response to chondrogenic growth factors

The aim of this study was to investigate the effects of alginate and agarose on the response of bone marrow stromal cells (BMSCs) to chondrogenic stimuli. Rat BMSCs were expanded in monolayer culture with or without FGF-2 supplementation. Cells were then seeded in 2% alginate and agarose gels and cultured in media with or without TGF-beta1 or dexamethasone (Dex). Sulfated glycosaminoglycans (sGAGs), collagen type II, and aggrecan were expressed in all groups that received TGF-beta1 treatment during hydrogel culture. Expansion of rat BMSCs in the presence of FGF-2 increased production of sGAG in TGF-beta1-treated groups over those cultures that were treated with TGF-beta1 alone in alginate cultures. However, in agarose, cells exposed to FGF-2 during expansion produced less sGAG within TGF-beta1-supplemented groups over those cultures treated with TGF-beta1 alone. Dex was required for optimal matrix synthesis in both hydrogels, but was found to decrease cell viability in agarose constructs. These results indicate that the response of BMSCs to a chondrogenic growth factor regimen is scaffold dependent.     

Characterization of cortical neuron outgrowth in two- and three-dimensional culture systems

To improve the ability of regeneration by grafting living cells or by adding growth factor to a lesion site, it is important to find good biomaterials for neuron survival and regeneration. This study focused on two- and three-dimensional cultures in a matrix using biomaterials such as agarose, collagen, fibrin, and their mixtures, because these are considered to be suitable biomaterials for neuron outgrowth. Cortical neurons were dissected from E17 rat embryos and cultured in agarose gel, collagen gel, fibrin glue, and mixtures of collagen and fibrin. Results showed that neurons cultured in collagen gel and fibrin glue had longer periods of survival (more than 3 weeks) and better neurite extension than those observed in agarose gels. As to the survival rate according to the MTT and lactate dehydrogenase assays, fibrin glue was the most suitable biomaterial for neuron survival among the biomaterials examined. With two-dimensional fibrin plating, neuron cells exhibited cell aggregation and stress fibers, but the same results were not observed with collagen gel. There were no differences in neurite extension and survival in the mixtures of collagen and fibrin. The results suggest that collagen and fibrin can provide a suitable substrate for a three-dimensional culture matrix for neuronal survival and differentiation.     

Influence of retinol on human chondrocytes in agarose culture

Vitamin A and its congeners, collectively called retinoids, are known to have teratogenic potential and have induced craniofacial and limb malformations in numerous animal species. More importantly, retinoids are recognized as teratogenic to fetuses of pregnant women who have taken such preparations for dermatologic disorders. Information gathered from the study of animal models suggests that retinoids interfere with cartilage differentiation. If chondrogenesis in limb development is disturbed it may contribute to limb reductions and malformations. In vitro studies using various animal systems have shown that cartilage matrix macromolecules are altered to resemble those secreted by mesenchymal cells. The response of human chondrocytes to retinoids in vitro is not known. Culture of human chondrocytes in agarose maintains the cartilage phenotype and therefore serves as a model system to evaluate the influence of retinoids directly on human chondrogenesis. The studies presented in this paper were done to determine if the expression of specific matrix macromolecules of human chondrocytes in agarose culture is altered by retinol treatment. Immunocytochemistry demonstrated enhanced labeling of type I collagen while type II collagen labeling was reduced in cultures treated with retinol. In addition, morphometric analyses indicated a decrease in the size and number of chondrogenic clusters and that individual cells synthesized less alcian blue matrix when compared to parallel control cultures. The size of the proteoglycan monomers, glycosaminoglycan side chains as well as the disaccharide composition were not affected. However, there was a reduction in the quantity of proteoglycan monomers produced.     

Influence of retinol on human chondrocytes in agarose culture.

Vitamin A and its congeners, collectively called retinoids, are known to have teratogenic potential and have induced craniofacial and limb malformations in numerous animal species. More importantly, retinoids are recognized as teratogenic to fetuses of pregnant women who have taken such preparations for dermatologic disorders. Information gathered from the study of animal models suggests that retinoids interfere with cartilage differentiation. If chondrogenesis in limb development is disturbed it may contribute to limb reductions and malformations. In vitro studies using various animal systems have shown that cartilage matrix macromolecules are altered to resemble those secreted by mesenchymal cells. The response of human chondrocytes to retinoids in vitro is not known. Culture of human chondrocytes in agarose maintains the cartilage phenotype and therefore serves as a model system to evaluate the influence of retinoids directly on human chondrogenesis. The studies presented in this paper were done to determine if the expression of specific matrix macromolecules of human chondrocytes in agarose culture is altered by retinol treatment. Immunocytochemistry demonstrated enhanced labeling of type I collagen while type II collagen labeling was reduced in cultures treated with retinol. In addition, morphometric analyses indicated a decrease in the size and number of chondrogenic clusters and that individual cells synthesized less alcian blue matrix when compared to parallel control cultures. The size of the proteoglycan monomers, glycosaminoglycan side chains as well as the disaccharide composition were not affected. However, there was a reduction in the quantity of proteoglycan monomers produced.     

A comparison of the functionality and in vivo phenotypic stability of cartilaginous tissues engineered from different stem cell sources

Joint-derived stem cells are a promising alternative cell source for cartilage repair therapies that may overcome many of the problems associated with the use of primary chondrocytes (CCs). The objective of this study was to compare the in vitro functionality and in vivo phenotypic stability of cartilaginous tissues engineered using bone marrow-derived stem cells (BMSCs) and joint tissue-derived stem cells following encapsulation in agarose hydrogels. Culture-expanded BMSCs, fat pad-derived stem cells (FPSCs), and synovial membrane-derived stem cells (SDSCs) were encapsulated in agarose and maintained in a chondrogenic medium supplemented with transforming growth factor-β3. After 21 days of culture, constructs were either implanted subcutaneously into the back of nude mice for an additional 28 days or maintained for a similar period in vitro in either chondrogenic or hypertrophic media formulations. After 49 days of in vitro culture in chondrogenic media, SDSC constructs accumulated the highest levels of sulfated glycosaminoglycan (sGAG) (～2.8% w/w) and collagen (～1.8% w/w) and were mechanically stiffer than constructs engineered using other cell types. After subcutaneous implantation in nude mice, sGAG content significantly decreased for all stem cell-seeded constructs, while no significant change was observed in the control constructs engineered using primary CCs, indicating that the in vitro chondrocyte-like phenotype generated in all stem cell-seeded agarose constructs was transient. FPSCs and SDSCs appeared to undergo fibrous dedifferentiation or resorption, as evident from increased collagen type I staining and a dramatic loss in sGAG content. BMSCs followed a more endochondral pathway with increased type X collagen expression and mineralization of the engineered tissue. In conclusion, while joint tissue-derived stem cells possess a strong intrinsic chondrogenic capacity, further studies are needed to identify the factors that will lead to the generation of a more stable chondrogenic phenotype.     

Myogenic potential of chick limb bud mesenchyme in micromass culture

Summary The myogenic potential of chick limb mesenchyme from stages 18–25 was assessed by micromass culture under conditions conductive to myogenesis, and was measured as the proportion of differentiated (muscle myosin-positive) mononucleated cells detected. It was found that similar myogenic potentials existed in mesenchyme from whole limbs between stages 18 and 19, but this potential was halved by stage 20. At stage 21, proximal mesenchyme showed significantly more myogenesis than distal mesenchyme, but this difference was abolished by stage 22. Thereafter, myogenesis was increasingly restricted from the distal mesenchyme, whilst the potential in more proximal regions did not significantly increase after stage 23. When the ratio between total limb myoblasts which differentiated on days 1 and 4 of culture was analysed, it was found that two distinct peaks existed at stages 20 and 23. The significance of these ratio peaks is unclear, but may be related to different proliferative potentials of the pre-myoblasts at these stages.     

Combined effects of TGFβ1 and BMP2 in serum-free chondrogenic differentiation of mesenchymal stem cells induced hyaline-like cartilage formation

This study investigated the effects of TGFβ1, BMP2 or a combination of both on the chondrogenic differentiation of mesenchymal stem cells (MSCs) in a serum-free micromass culture system in vitro. Putative MSCs harvested from the iliac crest of 4–5 month old New Zealand White Rabbits were expanded and cultured in three-dimensional high density micromass aggregate cultures containing TGFβ1, BMP2 or a combination of both, in the absence of serum. After 14–20 days of culture, chondrogenic differentiation of the MSCs was assayed by toluidine blue staining, immunohistochemistry and semi-quantitative RT-RCR of type I collagen (CI) and type II collagen (CII). Quantitative measurements of cell proliferation and sulfated glycosaminoglycan (s-GAG) were also carried out to assess the growth rate and matrix deposition of the cultured aggregates. Both immunohistochemical staining and semi-quantitative RT-PCR showed that the combination of BMP2 and TGFβ1 resulted in a marked enhancement of collagen II synthesis, with minimal collagen I expression, which would suggest hyaline-like cartilage formation. Additionally, BMP2 and TGFβ1 had a synergistic effect on matrix proteoglycan deposition, as assessed by metachromatic toluidine blue staining. This is consistent with the quantitative measurement of glycosaminoglycans, whereby a significant increase in GAG/DNA was noted in the co-treatment group. Hence, it can be concluded that the combination of BMP2 and TGFβ1 has a synergistic effect on the differentiation of MSC into hyaline-like cartilage tissue.     

Combined effects of TGFbeta1 and BMP2 in serum-free chondrogenic differentiation of mesenchymal stem cells induced hyaline-like cartilage formation

This study investigated the effects of TGFbeta1, BMP2 or a combination of both on the chondrogenic differentiation of mesenchymal stem cells (MSCs) in a serum-free micromass culture system in vitro. Putative MSCs harvested from the iliac crest of 4-5 month old New Zealand White Rabbits were expanded and cultured in three-dimensional high density micromass aggregate cultures containing TGFbeta1, BMP2 or a combination of both, in the absence of serum. After 14-20 days of culture, chondrogenic differentiation of the MSCs was assayed by toluidine blue staining, immunohistochemistry and semi-quantitative RT-RCR of type I collagen (CI) and type II collagen (CII). Quantitative measurements of cell proliferation and sulfated glycosaminoglycan (s-GAG) were also carried out to assess the growth rate and matrix deposition of the cultured aggregates. Both immunohistochemical staining and semi-quantitative RT-PCR showed that the combination of BMP2 and TGFbeta1 resulted in a marked enhancement of collagen II synthesis, with minimal collagen I expression, which would suggest hyaline-like cartilage formation. Additionally, BMP2 and TGFbeta1 had a synergistic effect on matrix proteoglycan deposition, as assessed by metachromatic toluidine blue staining. This is consistent with the quantitative measurement of glycosaminoglycans, whereby a significant increase in GAG/DNA was noted in the co-treatment group. Hence, it can be concluded that the combination of BMP2 and TGFbeta1 has a synergistic effect on the differentiation of MSC into hyaline-like cartilage tissue.     

Musculoskeletal differentiation of cells derived from human embryonic germ cells

Stem cells have the potential to significantly improve cell and tissue regeneration therapies, but little is understood about how to control their behavior. We investigated the potential differentiation capability of cells derived from human embryonic germ (EG) cells into musculoskeletal lineages by providing a three-dimensional environment with increased cell-cell contact and growth factors. Cells were clustered into pellets to mimic the mesenchyme condensation process during limb development. LVEC cells, an embryoid body-derived (EBD) cell culture generated from EG cells, were cultured in micromass pellets for 21 days in the presence of bone morphogenetic protein 2 (BMP2) and/or transforming growth factor beta-3 (TGFbeta3). Gene expression for cartilage-, bone-, and muscle-specific matrix proteins--including collagen types I, II, III, IX, X; aggrecan; cartilage proteoglycan link protein; cartilage oligomeric protein; chondroitin sulfate-4-S; and myf5--was upregulated in the pellets treated with TGFbeta3, while mRNAs for neurofilament heavy (NFH), a neuron marker, and flk-1, a hematopoietic marker, decreased. Total collagen and proteoglycan production exhibited a time-dependent increase in the pellets treated with TGFbeta3, further confirming the expression of characteristic musculoskeletal markers. Furthermore, our results indicate the ability to select or differentiate stem cells toward a musculoskeletal lineage from a heterogenous EBD cell line.     

生长分化因子5诱导脂肪干细胞复合Ⅰ型胶原支架成软骨细胞的分化

背景：前期实验中发现生长分化因子5可以诱导脂肪干细胞向软骨细胞分化,但在复合Ⅰ型胶原支架的体外培养条件下其向软骨细胞分化的能力尚未见研究报道。 目的：探讨生长分化因子5诱导脂肪干细胞复合Ⅰ型胶原支架向软骨细胞分化的能力。 方法：从兔脂肪组织中分离培养脂肪干细胞,使用倒置相差显微镜观察细胞形态,使用免疫荧光对其表型进行鉴定。在复合Ⅰ型胶原支架条件下,加入外源性生长分化因子5对脂肪干细胞向软骨细胞进行诱导,在诱导14 d时,采用苏木精-伊红染色和扫描电镜对诱导的细胞进行形态学观察。在诱导7,14和21 d时,采用反转录PCR方法检测诱导的细胞的Ⅱ型胶原和蛋白多糖mRNA表达情况。 结果与结论：原代脂肪干细胞贴壁生长,呈梭形、多角形分布,细胞表面抗原CD44、CD49d 阳性,CD106 阴性。生长分化因子5诱导的脂肪干细胞与Ⅰ型胶原支架黏附良好,增殖能力旺盛,细胞表面存在着大量的细胞外基质分泌,Ⅱ型胶原和蛋白聚糖mRNA表达水平明显增加。说明生长分化因子5能够成功诱导复合Ⅰ型胶原支架的脂肪干细胞成软骨细胞分化。     

Clonal populations of chondrocytes with progenitor properties identified within human articular cartilage

The aim of the present study was to identify and characterize progenitor properties of human articular chondrocytes selected by using agarose suspension culture. In this chondrogenic selective culture condition, about 3.6% of seeded surplus chondrocytes from patients undergoing articular chondrocyte transplantation proliferated and formed cell clusters after 6 weeks. Phase-contrast microscopy and transmission electron microscopy revealed four different types of cell clusters differing in cellular content and matrix production. Based on their morphological features, they were named the homogenous (H), the homogenous matrix (HM), the differentiated matrix (DM) and the differentiated (D) cell clusters. All cell clusters showed positive safranin O staining, and matrix was positive for antibodies detecting type II collagen and aggrecan. The clusters were further demonstrated to express the genes for fibroblast growth factor receptor 3, type IIA collagen and type IIB collagen, while type X collagen was not expressed. After subcloning, the H and HM clusters demonstrated the best proliferative capacity. Chondrocytes from these two cell clusters also showed phenotypic plasticity in chondrogenic, adipogenic as well as osteogenic assays. This study demonstrates that existing subpopulations of cells with chondroprogenitor properties can be isolated from human adult articular cartilage using agarose suspension cultures.