Chondrogenesis of limb bud mesenchyme in vitro: stimulation by cations

To analyze the nature of cell-cell interactions in chondrogenesis, two cations that influence these interactions, calcium and poly-L-lysine (PL), were tested for their effects on chondrogenesis in vitro. High density cultures of chick limb bud mesenchyme (Hamilton-Hamburger stages 23/24), were exposed to culture media containing calcium (0.6-3.3 mM) or PL (1-10 micrograms/ml). Both cations stimulated chondrogenesis in a dose-dependent manner, and also promoted cartilage formation in normally non-chondrogenic, low cell density cultures. Chondrogenesis was assayed based on cartilage nodule number, [35S]sulfate incorporation, and expression of type II collagen as detected by immunohistochemistry. The calcium effect was not mimicked by other divalent cations (Cd, Co, Ni, Mg, Mn, and Sr). The effect of PL was dependent on its Mr (greater than or equal to 14K) and charge, and was mimicked by poly-D-lysine but not by lysine or other analogs of PL or lysine (epsilon-amino caproic acid, lysozyme, poly-L-arginine, and spermidine). Calcium and PL probably act by different mechanisms since their effects were additive, and required their presence on different days of culture: calcium acted on Day 1, and PL on Day 2. It is proposed that calcium may play a role in the cell aggregation phase of chondrogenesis whereas PL, or a naturally occurring polypeptide of similar nature, may promote chondrogenesis by crosslinking specific anionic components of the cell surface or extracellular matrix.     

Characterization of bone-derived chondrogenesis-stimulating activity on embryonic limb mesenchymal cells in vitro

Demineralized bone matrix contains factors which stimulate chondrogenesis and osteogenesis in vivo. A water-soluble extract of bone has been shown to stimulate chondrogenesis in vitro in embryonic limb mesenchymal cells (Syftestad, Lucas & Caplan, 1985). The aim of this study was to analyse the cellular mechanism of the bone-derived chondrogenesis-stimulating activity, with particular attention on how normal requirements for chondrogenesis may be altered. The effects of bovine bone extract (BBE) on chondrogenesis in vitro were studied using micromass cultures of chick limb bud mesenchyme isolated from embryos at Hamburger-Hamilton (HH) stage 23/24, an experimental system which is capable of undergoing chondrogenic differentiation. Bovine diaphyseal long bones were demineralized and extracted with guanidine-HCl to prepare BBE (Syftestad & Caplan, 1984). High-density mesenchyme cultures (30 x 10(6) cells/ml) were exposed to different doses of BBE (0.01-1.0 mg ml-1) and chondrogenesis was quantified based on cartilage nodule number and [35S]sulphate incorporation. BBE was tested on micromass cultures of varying plating densities (2-30 x 10(6) cells/ml), on cultures of 'young' limb bud cells (HH stage 17/18), and on cultures enriched with chondroprogenitor cells obtained from subridge mesoderm. Since poly-L-lysine (PL) has recently been shown (San Antonio & Tuan, 1986) to promote chondrogensis, PL and BBE were introduced together in different doses, in the culture medium, to determine if their actions were synergistic. Our results show that BBE stimulates chondrogenesis in a dose-dependent manner and by a specific, direct action on the chondroprogenitor cells but not in normally non-chondrogenic, low density or 'young' limb bud cell cultures. The effects of PL and BBE are additive and these agents appear to act by separate mechanisms to stimulate chondrogenesis; PL primarily enhances nodule formation, and BBE appears to promote nodule growth.     

Evidence for histogenic interactions during in vitro limb chondrogenesis

The requirement for homotypic cell interaction was studied by making chimeric micromass cultures containing various proportions of chick and quail limb mesenchyme. Cultures made from limb mesenchyme from embryos of Hamburger and Hamilton stages 23–24 produce large clumps of cartilage cells, identified by the accumulation of an extracellular matrix which stains with alcian blue at pH 1 and by the ability of cells to take up ³⁵SO₄ rapidly, as demonstrated autoradiographically. Dissociated mesenchyme from stage 19 embryos did not produce cartilage in micromass cultures, but only precartilage cell aggregates. Micromass cultures prepared from mixtures of mesenchyme cells obtained from stage 19 and stages 23–24 embryos contained decreasing numbers of cartilage nodules as the proportion of stage 19-derived mesenchyme increased. At the same time the number of aggregates was not affected. When the ratio of stage 19- to stage 24-derived cells was 3:1 or greater, no nodules were detected. The actual number of cells from each stage was verified by using mixtures of quail and chick cells, which are microscopically distinguishable. Additional evidence suggests that the stage 19-derived mesenchyme inhibits chondrogenesis by passively preventing stage 24-derived cells from interacting. The results presented are consistent with the suggestions that (1) homotypic cell interaction plays a role in limb chondrogenesis and (2) the capacity to interact in the required manner is acquired after the embryos have reached stage 19. These phenomena might be involved in the normal histogenesis of cartilage tissue.     

Characterization of bone-derived chondrogenesis-stimulating activity on embryonic limb mesenchymal cells in vitro

Abstract. Demineralized bone matrix contains factors which stimulate chondrogenesis and osteogenesis in vivo. A water-soluble extract of bone has been shown to stimulate chondrogenesis in vitro in embryonic limb mesenchymal cells (Syftestad, Lucas & Caplan, 1985). The aim of this study was to analyse the cellular mechanism of the bone-derived chondrogenesis-stimulating activity, with particular attention on how normal requirements for chondrogenesis may be altered. The effects of bovine bone extract (BBE) on chondrogenesis in vitro were studied using micromass cultures of chick limb bud mesenchyme isolated from embryos at Hamburger-Hamilton (HH) stage 23/24, an experimental system which is capable of undergoing chondrogenic differentiation. Bovine diaphyseal long bones were demineralized and extracted with guanidine-HCl to prepare BBE (Syftestad & Caplan, 1984). High-density mesenchyme cultures (30 times 10⁶ cells/ml) were exposed to different doses of BBE (0–01-1-0 mg ml^-1) and chondrogenesis was quantified based on cartilage nodule number and [³⁵S]sulphate incorporation. BBE was tested on micromass cultures of varying plating densities (2–30 times 10⁶ cells/ml), on cultures of ‘young’ limb bud cells (HH stage 17/18), and on cultures enriched with chondroprogenitor cells obtained from subridge mesoderm. Since poly-L-lysine (PL) has recently been shown (San Antonio & Tuan, 1986) to promote chondrogensis, PL and BBE were introduced together in different doses, in the culture medium, to determine if their actions were synergistic. Our results show that BBE stimulates chondrogenesis in a dose-dependent manner and by a specific, direct action on the chondroprogenitor cells but not in normally non-chondrogenic, low density or ‘young’ limb bud cell cultures. The effects of PL and BBE are additive and these agents appear to act by separate mechanisms to stimulate chondrogenesis; PL primarily enhances nodule formation, and BBE appears to promote nodule growth.     

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.     

NuSerum,a synthetic serum replacement,supports chondrogenesis of embryonic chick limb bud mesenchymal cells in micromass culture

Summary In an effort to establish a more chemically defined culture system to study the regulation of chondrogenic differentiation in vitro, two commercially available serum replacements, NuSerum and NuSerum IV, were tested on embryonic limb mesenchyme. Limb bud (LB) mesenchymal cells were isolated from Hamilton-Hamburger stage 23–24 chick embryos and plated at various densities (1, 5, 10, or 20 × 10⁶ cells/ml) in micromass culture for 4 days in media supplemented with 10% fetal bovine serum (FBS), NuSerum or NuSerum IV. Cell growth was assessed by the incorporation of [³H]leucine and [³H]thymidine. Chondrogenesis was determined by the incorporation of [³⁵S]sulfate and by the number of Alcian blue-staining cartilage nodules. In high density (20 × 10⁶ cells/ml) cultures, which favored chondrogenic differentiation, both serum replacements supported protein synthesis and chondrogenesis equally well as FBS. In cultures plated at 5 × 10⁶ cells/ml, a cell density in which was chondrogenesis-limiting, both NuSerum and NuSerum IV significantly enhanced incorporation of [³⁵S]sulfate (2.6-fold), [³H]leucine (1.4-fold), and [³H]thymidine (1.9-fold), compared to FBS. Enhancement of chondrogenesis was also apparent by the increases in the number of Alcian blue-staining cartilage nodules and the ratio of sulfate: leucine incorporation in cultures plated at 5 × 10⁶ cells/ml. Interestingly, the localization of cartilage nodules was extended out to the periphery of micromass cultures fed with NuSerum or NuSerum IV. The observed effects of NuSerum and NuSerum IV may be attributed to a combination of factors, including lower concentrations of serum and its associated proteins, as well as supplemented growth factors and hormones known to promote cell proliferation and differentiation. Therefore, NuSerum and NuSerum IV are excellent, low-cost replacements for FBS in maintaining cellular growth and promoting chondrogenesis in LB mesenchymal cell cultures in vitro.     

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.     

Keratan sulfate epitopes exhibit a conserved distribution during joint development that remains undisclosed on the basis of glycosaminoglycan charge density.

Changes in glycosaminoglycan (GAG) content and distribution are vital for joint development. However, their precise character has not been established. We have used immunohistochemistry (IHC) and "critical electrolyte" Alcian blue staining to assess such changes in developing chick and rabbit joints. IHC showed chondroitin sulfate labeling in chick epiphyseal cartilage but not in interzones. In contrast, prominent labeling for keratan sulfate (KS) was restricted to chick cartilage-interzone interfaces. In rabbit knees, KS labeling was also prominent at presumptive cavity borders, but weak in interzone and cartilage. Selective pre-digestion produced appropriate loss of label and undersulfated KS was undetectable. Quantification of Alcian blue staining by scanning and integrating microdensitometry showed prominent hyaluronan-like (HA-like) interzone staining, with chondroitin sulfate and weaker KS staining restricted to epiphyseal cartilage. Hyaluronidase decreased HA-like staining in the interzone. Surprisingly, keratanases also reduced HA-like but not sulfated GAG (sGAG-like) staining in the interzone. Chondroitinase ABC had little effect on HA-like staining but decreased sGAG staining in all regions. Rabbit joints also showed HA-like but not KS staining in the interzone and strong chondroitin sulfate-like staining in epiphyseal cartilage. Our findings show restricted KS distribution in the region close to the presumptive joint cavity of developing chick and rabbit joints. Alcian blue staining does not detect this moiety. Therefore, it appears that although histochemistry allows relatively insensitive quantitative assessment of GAGs, IHC increases these detection limits. This is particularly evident for KS, which exhibits immunolabeling patterns in joints from different species that is consistent with a conserved functional role in chondrogenesis.     

Role of chondrogenic tissue in programmed cell death and BMP expression in chick limb buds

In the developing chick leg bud, massive programmed cell death occurs in the interdigital region. Previously, we reported the inhibition of cell death by separation of the interdigital region from neighboring digit cartilage. In this study, we examined the relationship between cell death and cartilaginous tissue in vitro. First, cell fate was observed with DiI that was used to examine cell movement in the distal tip of leg bud. Labeled cells in the prospective digital region were distributed only in the distal region as a narrow band, while cells in the prospective interdigital region expanded widely in the interdigit. In coculture of monolayer cells and a cell pellet tending to differentiate into cartilage, monolayer cells migrated into the cell pellet. These results suggested that digit cartilage tends to recruit neighboring cells into the cartilage during limb development. Next, we observed the relationship between cell death and chondrogenesis in monolayer culture. Apoptotic cell death that could be detected by TUNEL occurred in regions between cartilaginous nodules in mesenchymal cell culture. More apoptotic cell death was detected in the cell culture of leg bud mesenchyme of stage 25/26 than that of leg bud mesenchyme of stage 22 or that of stage 28. The most developed cartilaginous nodules were observed in the cell culture of stage 25/26. Finally, we observed Bmp expression in vitro and in vivo. Bmp-2, Bmp-4 and Bmp-7 were detected around the cartilage nodules. When the interdigit was separated from neighboring digit cartilage, Bmp-4 expression disappeared near the cut region but remained near the digit cartilage. This correlation between cell death and cartilaginous region suggests that cartilage tissue can induce apoptotic cell death in the developing chick limb bud due to cell migration accompanying chondrogenesis and Bmp expression.     

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.     

Tenascin is associated with chondrogenic and osteogenic differentiation in vivo and promotes chondrogenesis in vitro

The tissue distribution of the extracellular matrix glycoprotein, tenascin, during cartilage and bone development in rodents has been investigated by immunohistochemistry. Tenascin was present in condensing mesenchyme of cartilage anlagen, but not in the surrounding mesenchyme. In fully differentiated cartilages, tenascin was only present in the perichondrium. In bones that form by endochondral ossification, tenascin reappeared around the osteogenic cells invading the cartilage model. Tenascin was also present in the condensing mesenchyme of developing bones that form by intramembranous ossification and later was present around the spicules of forming bone. Tenascin was absent from mature bone matrix but persisted on periosteal and endosteal surfaces. Immunofluorescent staining of wing bud cultures from chick embryos showed large amounts of tenascin in the forming cartilage nodules. Cultures grown on a substrate of tenascin produced more cartilage nodules than cultures grown on tissue culture plastic. Tenascin in the culture medium inhibited the attachment of wing bud cells to fibronectin-coated substrates. We propose that tenascin plays an important role in chondrogenesis by modulating fibronectin-cell interactions and causing cell rounding and condensation.     

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.     

Transient expression of a cell surface heparan sulfate proteoglycan (syndecan) during limb development

Syndecan is an integral membrane proteoglycan that contains both heparan sulfate and chondroitin sulfate chains and that links the cytoskeleton to interstitial extracellular matrix components, including collagen and fibronectin. Immunohistochemistry with a monoclonal antibody directed to the core protein of the syndecan ectodomain has been used to analyze the distribution of this proteoglycan in the developing mouse limb bud and in high-density cultures of limb mesenchyme cells. By Day 9 of gestation when the limb buds are just apparent, syndecan is detected on cells throughout the limb region, including both ectodermal and mesenchymal components. This distribution does not change as the limb bud elongates along its proximodistal axis, except for its reduction in the apical ectodermal ridge. By Day 11, the intensity of immunofluorescence in the central core decreases relative to other regions. By Day 13 immunostaining is lost in the regions destined for chondrogenesis and myogenesis but persists in the limb ectoderm and peripheral and distal mesenchyme. In the limb mesenchyme cell cultures, syndecan is initially undetected, but is found throughout the culture by 24 hr. With further culture the antigen becomes reduced in chondrogenic foci and in association with myogenic cells. When chick limb ectoderm is placed on the high-density cultures, immunoreactivity in the mouse mesenchyme is enhanced suggesting that epithelial-mesenchymal interactions modulate syndecan expression in the limb bud. Based on analysis of 35S-labeled syndecan from the cultures, syndecan from limb mesenchyme cells contains more glycosaminoglycan chains and is larger in size than the previously described polymorphic forms of syndecan from various epithelia. The high affinity of syndecan for components of the extracellular matrix and its distribution in the early limb bud are consistent with a role in maintaining the morphologic integrity of the limb bud during the period of initiation and rapid outgrowth, and in preventing the onset of chondrogenesis.     

Ectodermal FGFs induce perinodular inhibition of limb chondrogenesis in vitro and in vivo via FGF receptor 2

The formation of cartilage elements in the developing vertebrate limb, where they serve as primordia for the appendicular skeleton, is preceded by the appearance of discrete cellular condensations. Control of the size and spacing of these condensations is a key aspect of skeletal pattern formation. Limb bud cell cultures grown in the absence of ectoderm formed continuous sheet-like masses of cartilage. With the inclusion of ectoderm, these cultures produced one or more cartilage nodules surrounded by zones of noncartilaginous mesenchyme. Ectodermal fibroblast growth factors (FGF2 and FGF8), but not a mesodermal FGF (FGF7), substituted for ectoderm in inhibiting chondrogenic gene expression, with some combinations of the two ectodermal factors leading to well-spaced cartilage nodules of relatively uniform size. Treatment of cultures with SU5402, an inhibitor FGF receptor tyrosine kinase activity, rendered FGFs ineffective in inducing perinodular inhibition. Inhibition of production of FGF receptor 2 (FGFR2) by transfection of wing and leg cell cultures with antisense oligodeoxynucleotides blocked appearance of ectoderm- or FGF-induced zones of perinodular inhibition of chondrogenesis and, when introduced into the limb buds of developing embryos, led to shorter, thicker, and fused cartilage elements. Because FGFR2 is expressed mainly at sites of precartilage condensation during limb development in vivo and in vitro, these results suggest that activation of FGFR2 by FGFs during development elicits a lateral inhibitor of chondrogenesis that limits the expansion of developing skeletal elements.     

Regulation of UDP‐glucose dehydrogenase is sufficient to modulate hyaluronan production and release,control sulfated GAG synthesis,and promote chondrogenesis

Glycosaminoglycans (GAGs) are critical for extracellular matrix (ECM) integrity in cartilage but mechanisms regulating their synthesis are not defined. UDP‐glucose dehydrogenase (UGDH) catalyses UDP‐glucose oxidation to UDP‐glucuronic acid, an essential monosaccharide in many GAGs. Our previous studies in articular surface (AS) cells from embryonic joints have established pivotal roles for mitogen‐activated protein kinases (MAPK) in synthesis of the unsulfated GAG, hyaluronan (HA). We investigated the functional significance of UGDH in GAG production and chondrogenesis, and determined roles for MEK–ERK and p38^MAPK pathways in regulating UGDH expression and function. Inhibitors of MEK and p38^MAPK reduced UGDH protein in AS cells. Treatment with TGF‐β (archetypal growth factor) increased UGDH expression, sulfated (s)‐GAG/HA release and pericellular matrix formation in a p38^MAPK‐dependent manner. Retroviral overexpression of UGDH augmented HA/sGAG release and pericellular matrix elaboration, which were blocked by inhibiting MEK but not p38^MAPK. UGDH overexpression increased cartilage nodule size in bone marrow culture, promoted chondrogenesis in limb bud micromass culture and selectively suppressed medium HA levels and modified GAG sulfation, as assessed by FACE analysis. Our data provide evidence that: (i) TGF‐β regulates UGDH expression via p38^MAPK to modulate sGAG/HA secretion, (ii) MEK–ERK, but not p38^MAPK facilitates UGDH‐induced HA and sGAG release, and (iii) increased UGDH expression promotes chondrogenesis directly and differential modifies GAG levels and sulfation. These results indicate a more diverse role for UGDH in the support of selective GAG production than previously described. Factors regulating UGDH may provide novel candidates for restoring ECM integrity in degenerative cartilage diseases, such as osteoarthritis.Arthritis Research Campaign. J. Cell. Physiol. 226: 749–761, 2011. © 2010 Wiley‐Liss, Inc.     

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.