Two distinct classes of prechondrogenic cell types in the embryonic limb bud

Differences are demonstrated in the chondrogenic potential of cells derived from the distal and proximal halves of chick wing buds from as early as stage 23, prior to the appearance of overt cartilage differentiation. In high cell density cultures, cells obtained from the distal portions of stage 23 or 24 limb buds are spontaneously chondrogenic in micromass cultures. Cells obtained from the proximal portions, however, become blocked in their differentiation as protodifferentiated cartilage cels, since these cells in micromass cultures make detectable type II collagen, but fail to synthesize significant levels of cartilage proteoglycan or to accumulate an extracellular matrix that will stain for sulfated glycosaminoglycans. Such cultures of proximal limb bud cells can be stimulated to form alcian blue staining nodules by the addition of 1 mM dbcAMP or 50 micrograms/ml ascorbate, or by mixing proximal cells with small numbers of distal cells (1 distal cell to 10 proximal cells). These results demonstrate the existence of two distinct stages among prechondrogenic mesenchyme cells. The earlier stage appears to be able to provide a chondrogenic stimulus to proximal cells.     

The patterns on chondrogenesis of cells from facial primordia of chick embryos in micromass culture

Chondrogenesis of mesenchymal cells from the frontonasal mass, mandibles and maxillae of stage-24 chick embryos has been investigated in micromass (high-density) cultures. Distinct differences in the amount and pattern of cartilage differentiation are found. In cultures of frontonasal mass cells, a central sheet of cartilage develops; in cultures of mandible cells, less cartilage differentiates and nodules form; while in cultures of maxillae cells, virtually no chondrogenesis takes place. The same patterns of cartilage are found in cultures established from stage-20 embryos. At stage 28, frontonasal mass cultures form cartilage nodules and the number of nodules in mandible cultures is markedly decreased. There are striking parallels between the chondrogenic patterns of cells from the face and limb buds in micromass culture. The frontonasal mass cell cultures of stage-20 and -24 chick embryos resemble those established from the progress zone of limb buds. The progress zone is an undifferentiated region of the limb in which positional cues operate. Cultures established from the frontonasal mass of stage-28 chick embryos and from the mandibles of all stages resemble cultures of whole limb buds. These contain a mixture of committed and uncommitted cells. Ectoderm from facial primordia locally inhibits chondrogenesis in micromass cultures and this could provide a positional cue. The differences in chondrogenic potential of cells from facial primordia may underlie the specific retinoid effects on the frontonasal mass.     

Promotion of embryonic chick limb cartilage differentiation by transforming growth factor-beta

This study represents a first step in investigating the possible involvement of transforming growth factor-beta (TGF-beta) in the regulation of embryonic chick limb cartilage differentiation. TGF-beta 1 and 2 (1-10 ng/ml) elicit a striking increase in the accumulation of Alcian blue, pH 1-positive cartilage matrix, and a corresponding twofold to threefold increase in the accumulation of 35S-sulfate- or 3H-glucosamine-labeled sulfated glycosaminoglycans (GAG) by high density micromass cultures prepared from the cells of whole stage 23/24 limb buds or the homogeneous population of chondrogenic precursor cells comprising the distal subridge mesenchyme of stage 25 wing buds. Moreover, TGF-beta causes a striking (threefold to sixfold) increase in the steady-state cytoplasmic levels of mRNAs for cartilage-characteristic type II collagen and the core protein of cartilage-specific proteoglycan. Only a brief (2 hr) exposure to TGF-beta at the initiation of culture is sufficient to stimulate chondrogenesis, indicating that the growth factor is acting at an early step in the process. Furthermore, TGF-beta promotes the formation of cartilage matrix and cartilage-specific gene expression in low density subconfluent spot cultures of limb mesenchymal cells, which are situations in which little, or no chondrogenic differentiation normally occurs. These results provide strong incentive for considering and further investigating the role of TGF-beta in the control of limb cartilage differentiation.     

The differentiation of normal and muscle-free distal chick limb bud mesenchyme in micromass culture

Distal chick wing bud mesenchyme from stages 19 to 27 embryos has been grown in micromass culture. The behavior of cultures comprising mesenchyme located within 350 microns of the apical ectodermal ridge (distal zone mesenchyme) was compared to that of cultures of the immediately proximal mesenchyme (subdistal zone cultures). In cultures of the distal mesenchyme from stages 21-24 limbs, all of the cells stained immunocytochemically for type II collagen within 3 days, indicating ubiquitous chondrogenic differentiation. At stage 19 and 20, this behavior was only observed in cultures of the distal most 50-100 microns of the limb bud mesenchyme. Between stages 25 and 27, distal zone cultures failed to become entirely chondrogenic. At all stages, subdistal zone cultures always contained substantial areas of nonchondrogenic cells. The different behavior observed between distal zone and corresponding subdistal zone cultures appears to be a consequence of the presence of somite-derived presumptive muscle cells in the latter, since no such difference was observed in analagous cultures prepared from muscle-free wing buds. The high capacity of the distal zone for cartilage differentiation supports a view of pattern formation in which inhibition of cartilage is an important component. However, its consistent behavior in vitro indicates that micromass cultures do not reflect the in vivo differences between the distal zones at different stages. The subdistal region retains a high capacity of cartilage differentiation and the observed behavior in micromass reflects interactions with a different cell population.     

Cell sorting and chondrogenic aggregate formation in micromass culture

A fundamental feature of cartilage differentiation in the developing limb is the formation of a prechondrogenic cell condensation. An apparently similar process of prechondrogenic cell aggregation occurs in micromass cultures of limb bud mesenchyme with the formation of cellular aggregates which often differentiate into cartilage nodules. We have investigated the process of aggregate formation in micromass culture using chimaeric mixtures of potentially chondrogenic and nonchondrogenic cell types. Two systems were studied: mixtures of distal and proximal limb mesenchyme cells and mixtures of distal limb cells with avian tendon fibroblasts. In both cases cultures of varying proportions of each cell type have been prepared. The results demonstrate that aggregate formation in vitro is the consequence of a cell sorting process which can involve prechondrogenic cells of widely different spatial origins within the developing limb. This contrasts with in vivo prechondrogenic condensation in which there is no evidence of cell sorting (Searls, R.L. (1967), J. Exp. Zool. 166, 39-50). However, our findings do indicate that cell surface differences occur in apparently undifferentiated limb mesenchyme. The results also suggest that mesenchymal cell aggregates must achieve a threshold size before chondrogenesis can proceed. In addition, the results show that under some culture conditions nonchondrogenic cells will form aggregates.     

Bone morphogenetic protein-2 modulation of chondrogenic differentiation in vitro involves gap junction-mediated intercellular communication

Undifferentiated mesenchymal cells in the limb bud integrate a complex array of local and systemic signals during the process of cell condensation and chondrogenic differentiation. To address the relationship between bone morphogenetic protein (BMP) signaling and gap junction-mediated intercellular communication, we examined the effects of BMP-2 and a gap junction blocker 18 alpha glycyrrhetinic acid (18alpha-GCA) on mesenchymal cell condensation and chondrogenic differentiation in an in vitro chondrogenic model. We find that connexin43 protein expression significantly correlates with early mesenchymal cellular condensation and chondrogenesis in high-density limb bud cell culture. The level of connexin43 mRNA is maximally upregulated 48 h after treatment with recombinant human BMP-2 with corresponding changes in protein expression. Inhibition of gap junction-mediated intercellular communication with 2.5 microM 18alpha-GCA decreases chondrogenic differentiation by 50% at 96 h without effects on housekeeping genes. Exposure to 18alpha-GCA for only the first 24-48 h after plating does not affect condensation or later chondrogenic differentiation suggesting that gap junction-mediated intercellular communication is not critical for the initial phase of condensation but is important for the onset of differentiation. 18alpha-GCA can also block the chondrogenic effects of BMP-2 without effects on cell number or connexin43 expression. These observations demonstrate 18alpha-GCA-sensitive regulation of intercellular communication in limb mesenchymal cells undergoing chondrogenic differentiation and suggest that BMP-2 induced chondrogenic differentiation may be mediated in part through the modulation of connexin43 expression and gap junction-mediated intercellular communication.     

Position-related capacity for differentiation of limb mesenchyme in cell culture.

A quantitative comparison (i.e., number of cartilage nodules) of cartilage differentiation was made between micromass cell cultures prepared with cells from different locations (core vs periphery) within prechondrogenic chick wing buds. Wing bud core cells in micromass culture exhibit a greater developmental bias toward cartilage differentiation than periphery cells from the same limbs. In addition, myogenic cells appear more frequently in cultures prepared from wing bud periphery than in those prepared from core tissue. Therefore a stage 23–24 wing bud is not a homogeneous population of multipotential mesenchymal cells. Instead, a stage 23–24 wing bud contains two classes of cells, each characterized by a bias for either cartilage or muscle differentiation, and a third class of uncharacterized mesenchymal cells.     

In vitro histogenic capacities of limb mesenchyme from various stage mouse embryos

Mesenchyme cells isolated from mouse embryo forelimb buds (stages 15 through 21) and placed in high-density micromass cultures are compared with respect to their in vitro histogenic capacities. Particular emphasis is placed on changes in in vitro chondrogenic capacity. Stage 15 mouse limb cultures form numerous aggregates which uniformly fail to differentiate into cartilage nodules. On the other hand, cartilage nodules are observed in cultures prepared from all subsequent stage limbs, although there is a linear decrease in the size of nodules between stage 16–17 and middle-late stage 21 cultures. This decrease correlates with simultaneous decreases in both the proportion of aggregating cells and the extent of dibutyryl cyclic AMP-stimulated cartilage formation. At the same time, observations indicate that the proportions of nonaggregating and nonchondrogenic mesenchyme, myogenic cells, and, perhaps, fibrogenic mesenchyme are increasing. The only exceptions to these patterns are observed in cultures from middle-late stage 21 limbs, when cartilage differentiation in situ is already extensive. Unlike earlier stage cultures, which form nearly identical numbers of aggregates and nodules, middle-late stage 21 cultures form variable numbers of aggregates, only a few of which differentiate into cartilage nodules. Middle-late stage 21 cultures also contain unexpectedly low numbers of myogenic cells/unit area of culture. Based on changes in the in vitro histogenic capacities, it is concluded that concurrent with a progression of morphogenic events in the limb, there is a progression of changes in the relative proportions of cell subpopulations. Both the existence of the different subpopulations and the changes in their relative proportions can be detected in vitro. Furthermore, it is concluded that cartilage formation in the limbs of both mouse and chick embryos probably occurs according to very similar developmental programs.     

Accelerated maturation of limb mesenchyme by the BrachypodH mouse mutation

Mesenchyme cell populations prepared from proximal and distal halves of stage 20 mouse forelimb buds are shown to behave under in vitro micromass culture conditions like analogous cell populations obtained from chick embryo limb buds. While the distal cells are spontaneously chondrogenic, the proximal cells make aggregates which are only potentially chondrogenic after treatment with dibutyryl cyclic AMP. In addition, stage 20 mouse whole limb bud cells homozygous for the brachypodismH (bpH) mutation are shown to behave similarly to 'normal' proximal cells. Both make fewer aggregates and nodules and both have faster aggregation rates (determined as the rate of disappearance of single cells over time) in rotation cultures than 'normal' distal or whole limb bud cells. These results support the hypothesis that the bpH mutation specifically decreases the proportion of spontaneously chondrogenic mesenchyme cells (that is, distal-like cells) present at certain developmental stages in the limb bud, resulting in a prematurely high proportion of proximal-like cells.     

Accelerated maturation of limb mesenchyme by the BrachypodH mouse mutation

Abstract. Mesenchyme cell populations prepared from proximal and distal halves of stage 20 mouse forelimb buds are shown to behave under in vitro micromass culture conditions like analogous cell populations obtained from chick embryo limb buds. While the distal cells are spontaneously chondrogenic, the proximal cells make aggregates which are only potentially chondrogenic after treatment with dibutyryl cyclic AMP. In addition, stage 20 mouse whole limb bud cells homozygous for the brachypodism^H ( bp ^H ) mutation are shown to behave similarly to 'normal' proximal cells. Both make fewer aggregates and nodules and both have faster aggregation rates (determined as the rate of disappearance of single cells over time) in rotation cultures than 'normal' distal or whole limb bud cells. These results support the hypothesis that the bp ^H mutation specifically decreases the proportion of spontaneously chondrogenic mesenchyme cells (that is, distal-like cells) present at certain developmental stages in the limb bud, resulting in a prematurely high proportion of proximal-like cells.     

Platelet-derived growth factor A modulates limb chondrogenesis both in vivo and in vitro

Cartilage formation in the chick limb follows rapid proliferation, condensation and differentiation of limb mesenchyme. The control of these early events is poorly understood. Platelet-derived growth factor receptor alpha (PDGFR-alpha) is present throughout the mesenchyme of early chick limb buds, while its ligand, PDGF-A, is expressed in the surrounding epithelium. PDGFR-alpha is down-regulated in areas that will not give rise to cartilage and is then lost from cartilage forming areas after they begin to differentiate. PDGF-A increases chondrogenesis in micromass cultures of stage-20-24 limb buds, but not stage 25, where it inhibits chondrogenesis. Ectopic PDGF-A in the chick wing can lead to either a localized increase in cartilage formation, or an inhibition. Inhibition of PDGF signalling in the chick limb results in the loss of cartilage. These data demonstrate that PDGF-A functions to promote chondrogenesis at early stages of limb development and suggest that it inhibits chondrogenesis at later stages.     

Fibronectin gene expression during limb cartilage differentiation

A critical event in limb cartilage differentiation is a transient cellular condensation process in which prechondrogenic mesenchymal cells become closely juxtaposed and interact with one another prior to initiating cartilage matrix deposition. Fibronectin (FN) has been suggested to be involved in regulating the onset of condensation and chondrogenesis by actively promoting prechondrogenic aggregate formation during the process. We have performed a systematic quantitative study of the expression of the FN gene during the progression of chondrogenesis in vitro and in vivo. In high-density micromass cultures of limb mesenchymal cells, FN mRNA levels increase about 5-fold coincident with the crucial condensation process, and remain relatively high during the initial deposition of cartilage matrix by the cells. Thereafter, FN mRNA levels progressively decline to relatively low levels as the cultures form a virtually uniform mass of cartilage. The changes in FN mRNA levels in vitro are paralleled closely by changes in the relative rate of FN synthesis as determined by pulse-labeling and immunoprecipitation analysis. The relative rate of FN synthesis increases 4- to 5-fold at condensation and the onset of chondrogenesis, after which it progressively declines to low levels as cartilage matrix accumulates. High levels of FN gene expression also occur at the onset of chondrogenesis in vivo. In the proximal central core regions of the limb bud in which condensation and cartilage matrix deposition are being initiated, FN mRNA levels and the relative rates of FN synthesis become progressively about 4-fold higher than in the distal subridge region, which consists of undifferentiated mesenchymal cells that have not yet initiated condensation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alterations in the spatiotemporal expression pattern and function of N-cadherin inhibit cellular condensation and chondrogenesis of limb mesenchymal cells in vitro

Cartilage formation in the embryonic limb is presaged by a cellular condensation phase that is mediated by both cell-cell and cell-matrix interactions. N-Cadherin, a Ca(2+)-dependent cell-cell adhesion molecule, is expressed at higher levels in the condensing mesenchyme, followed by down-regulation upon chondrogenic differentiation, strongly suggesting a functional role in the cellular condensation process. To further examine the role of N-cadherin, we have generated expression constructs of wild type and two deletion mutants (extracellular and intracellular) of N-cadherin in the avian replication-competent, RCAS retrovirus, and transfected primary chick limb mesenchymal cell cultures with these constructs. The effects of altered, sustained expression of N-cadherin and its mutant forms on cellular condensation, on the basis of peanut agglutinin (DNA) staining, and chondrogenesis, based on expression of chondrocyte phenotypic markers, were characterized. Cellular condensation was relatively unchanged in cultures overexpressing wild type N-cadherin, compared to controls on all days in culture. However, expression of either of the deletion mutant forms of N-cadherin resulted in decreased condensation, with the extracellular deletion mutant demonstrating the most severe inhibition, suggesting a requirement for N-cadherin mediated cell-cell adhesion and signaling in cellular condensation. Subsequent chondrogenic differentiation was also affected in all cultures overexpressing the N-cadherin constructs, on the basis of metabolic sulfate incorporation, the presence of the cartilage matrix proteins collagen type II and cartilage proteoglycan link protein, and alcian blue staining of the matrix. The characteristics of the cultures suggest that the N-cadherin mutants disrupt proper cellular condensation and subsequent chondrogenesis, while the cultures overexpressing wild type N-cadherin appear to condense normally, but are unable to proceed toward differentiation, possibly due to the prolonged maintenance of increased cell-cell adhesiveness. Thus, spatiotemporally regulated N-cadherin expression and function, at the level of both homotypic binding and linkage to the cytoskeleton, is required for chondrogenesis of limb mesenchymal cells.     

MEK-ERK signaling plays diverse roles in the regulation of facial chondrogenesis

The extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase pathway, also known as the MEK-ERK cascade, has been shown to regulate cartilage differentiation in embryonic limb mesoderm and several chondrogenic cell lines. In the present study, we employed the micromass culture system to define the roles of MEK-ERK signaling in the chondrogenic differentiation of neural crest-derived ectomesenchyme cells of the embryonic chick facial primordia. In cultures of frontonasal mesenchyme isolated from stage 24/25 embryos, treatment with the MEK inhibitor U0126 increased type II collagen and glycosaminoglycan deposition into cartilage matrix, elevated mRNA levels for three chondrogenic marker genes (col2a1, aggrecan, and sox9), and increased expression of a Sox9-responsive collagen II enhancer-luciferase reporter gene. Transfection of frontonasal mesenchyme cells with dominant negative ERK increased collagen II enhancer activation, whereas transfection of constitutively active MEK decreased its activity. Thus, MEK-ERK signaling inhibits chondrogenesis in stage 24/25 frontonasal mesenchyme. Conversely, MEK-ERK signaling enhanced chondrogenic differentiation in mesenchyme of the stage 24/25 mandibular arch. In mandibular mesenchyme cultures, pharmacological MEK inhibition decreased cartilage matrix deposition, cartilage-specific RNA levels, and collagen II enhancer activity. Expression of constitutively active MEK increased collagen II enhancer activation in mandibular mesenchyme, while dominant negative ERK had the opposite effect. Interestingly, MEK-ERK modulation had no significant effects on cultures of maxillary or hyoid process mesenchyme cells. Moreover, we observed a striking shift in the response of frontonasal mesenchyme to MEK-ERK modulation by stage 28/29 of development.     

Ethanol Exposure Stimulates Cartilage Differentiation by Embryonic Limb Mesenchyme Cells

Studies of neural, hepatic, and other cells have demonstrated thatin vitroethanol exposure can influence a variety of membrane-associated signaling mechanisms. These include processes such as receptor-kinase phosphorylation, adenylate cyclase and protein kinase C activation, and prostaglandin production that have been implicated as critical regulators of chondrocyte differentiation during embryonic limb development. The potential for ethanol to affect signaling mechanisms controlling chondrogenesis in the developing limb, together with its known ability to promote congenital skeletal deformitiesin vivo,prompted us to examine whether chronic alcohol exposure could influence cartilage differentiation in cultures of prechondrogenic mesenchyme cells isolated from limb buds of stage 23–25 chick embryos. We have made the novel and surprising finding that ethanol is a potent stimulant ofin vitrochondrogenesis at both pre- and posttranslational levels. In high-density cultures of embryonic limb mesenchyme cells, which spontaneously undergo extensive cartilage differentiation, the presence of ethanol in the culture medium promoted increased Alcian-blue-positive cartilage matrix production, a quantitative rise in³⁵SO₄incorporation into matrix glycosaminoglycans (GAG), and the precocious accumulation of mRNAs for cartilage-characteristic type II collagen and aggrecan (cartilage proteoglycan). Stimulation of matrix GAG accumulation was maximal at a concentration of 2% ethanol (v/v), although a significant increase was elicited by as little as 0.5% ethanol (approximately 85 mM). The alcohol appears to directly influence differentiation of the chondrogenic progenitor cells of the limb, since ethanol elevated cartilage formation even in cultures prepared from distal subridge mesenchyme of stage 24/25 chick embryo wing buds, which is free of myogenic precursor cells. When limb mesenchyme cells were cultured at low density, which suppresses spontaneous chondrogenesis, ethanol exposure induced the expression of high levels of type II collagen and aggrecan mRNAs and promoted abundant cartilage matrix formation. These stimulatory effects were not specific to ethanol, since methanol, propanol, and tertiary butanol treatments also enhanced cartilage differentiation in embryonic limb mesenchyme cultures. Further investigations of the stimulatory effects of ethanol onin vitrochondrogenesis may provide insights into the mechanisms regulating chondrocyte differentiation during embryogenesis and the molecular basis of alcohol's teratogenic effects on skeletal morphogenesis.     

Direct and progressive differentiation of human embryonic stem cells into the chondrogenic lineage

Treatment of common and debilitating degenerative cartilage diseases particularly osteoarthritis is a clinical challenge because of the limited capacity of the tissue for self‐repair. Because of their unlimited capacity for self‐renewal and ability to differentiate into multiple lineages, human embryonic stem cells (hESCs) are a potentially powerful tool for repair of cartilage defects. The primary objective of the present study was to develop culture systems and conditions that enable hESCs to directly and uniformly differentiate into the chondrogenic lineage without prior embryoid body (EB) formation, since the inherent cellular heterogeneity of EBs hinders obtaining homogeneous populations of chondrogenic cells that can be used for cartilage repair. To this end, we have subjected undifferentiated pluripotent hESCs to the high density micromass culture conditions we have extensively used to direct the differentiation of embryonic limb bud mesenchymal cells into chondrocytes. We report that micromass cultures of pluripotent hESCs undergo direct, rapid, progressive, and substantially uniform chondrogenic differentiation in the presence of BMP2 or a combination of BMP2 and TGF‐β1, signaling molecules that act in concert to regulate chondrogenesis in the developing limb. The gene expression profiles of hESC‐derived cultures harvested at various times during the progression of their differentiation has enabled us to identify cultures comprising cells in different phases of the chondrogenic lineage ranging from cultures just entering the lineage to well differentiated chondrocytes. Thus, we are poised to compare the abilities of hESC‐derived progenitors in different phases of the chondrogenic lineage for cartilage repair. J. Cell. Physiol. 224: 664–671, 2010. © 2010 Wiley‐Liss, Inc.     

Signaling Cascades Governing Cdc42-Mediated Chondrogenic Differentiation and Mensenchymal Condensation

Endochondral ossification consists of successive steps of chondrocyte differentiation, including mesenchymal condensation, differentiation of chondrocytes, and hypertrophy followed by mineralization and ossification. Loss-of-function studies have revealed that abnormal growth plate cartilage of the Cdc42 mutant contributes to the defects in endochondral bone formation. Here, we have investigated the roles of Cdc42 in osteogenesis and signaling cascades governing Cdc42-mediated chondrogenic differentiation. Though deletion of Cdc42 in limb mesenchymal progenitors led to severe defects in endochondral ossification, either ablation of Cdc42 in limb preosteoblasts or knockdown of Cdc42 in vitro had no obvious effects on bone formation and osteoblast differentiation. However, in Cdc42 mutant limb buds, loss of Cdc42 in mesenchymal progenitors led to marked inactivation of p38 and Smad1/5, and in micromass cultures, Cdc42 lay on the upstream of p38 to activate Smad1/5 in bone morphogenetic protein-2-induced mesenchymal condensation. Finally, Cdc42 also lay on the upstream of protein kinase B to transactivate Sox9 and subsequently induced the expression of chondrocyte differential marker in transforming growth factor-β1-induced chondrogenesis. Taken together, by using biochemical and genetic approaches, we have demonstrated that Cdc42 is involved not in osteogenesis but in chondrogenesis in which the BMP2/Cdc42/Pak/p38/Smad signaling module promotes mesenchymal condensation and the TGF-β/Cdc42/Pak/Akt/Sox9 signaling module facilitates chondrogenic differentiation.     

Successive formative stages of precartilaginous mesenchymal condensations in vitro: Modulation of cell adhesion by Wnt-7A and BMP-2

High-density chick limb bud cell culture is a useful model to study mesenchymal condensatifons and chondrogenesis. Most previous studies have focused on the effects of soluble reagents on terminal chondrogenic differentiation and have not defined the early cellular processes and signaling events. In this study, we defined five successive stages in the differentiation process: 1) dissociated cells, 2) small aggregates, 3) formation of cell clusters, 4) precartilaginous condensations, and 5) cartilage nodule. We used RCAS retrovirus-mediated Wnt-7a gene transduction to test the effect of Wnt-7a on the differentiation process. We found that Wnt-7a suppressed chondrogenic differentiation. Wnt-7a did not inhibit the initiation of condensation formation but blocked the progression of precartilaginous condensations to cartilage nodules. The Wnt-7a-transduced cultures showed characteristics of a less mature culture with persistent expression of NCAM, N-cadherin, wider distribution of integrin β1 and fibronectin, and suppression of tenascin-C. BMP-2 is known to enhance chondrogenic differentiation in these cultures by promoting cell clusters to form continuous sheet-like precartilaginous condensations. However, cultures exposed to both BMP-2 and Wnt-7a showed inhibition of chondrogenic differentiation. Different signaling molecules such as Wnt-7a and BMP-2 may have antagonistic effects on cartilage differentiation and the gradient of the two molecules may be involved in defining the boundaries of the initial precartilaginous condensation. We propose that the shape of the precartilaginous condensations may be modulated by local concentrations of signaling molecules, such as Wnt-7a and BMP-2, which act to alter cell-substrate and cell-cell adhesions. J. Cell. Physiol. 180:314–324, 1999. © 1999 Wiley-Liss, Inc.