Expression of N-cadherin, N-CAM, fibronectin and tenascin is stimulated by TGF-beta1, beta2, beta3 and beta5 during the formation of precartilage condensations

Cell surface adhesion and extracellular matrix proteins are known to play a key role in the formation of cell condensations during skeletal development, and their formation is crucial for the expression of cartilage-specific genes. However, little is known about the relationship between adhesion molecules (N-cadherin and N-CAM), extracellular matrix proteins (fibronectin and tenascin) and TGF-beta1, TGF-beta2 and TGF-beta3 during in vitro precartilage condensations in mouse chondrogenesis. On these bases, we determined the participation of mammalian TGF-beta1, TGF-beta2 and TFG-beta3 and Xenopus TGF-beta5 on the expression of cell surface adhesion and extracellular matrix proteins during the formation of precartilage condensations. Also, we characterized the effects of TGF-betas on proteoglycan metabolism at different cellular densities in mouse embryonic limb bud mesenchymal cells. In TGF-beta1 and TGF-beta5-treated cultures, proteoglycan biosynthesis was higher than in controls, while there were no differences in proteoglycan catabolism, which caused the accumulation of cartilage extracellular matrix. When mesenchymal cells were seeded at three different cellular densities in the presence of TGF-betas, only high density cultures presented increased stimulation of proteoglycan biosynthesis, compared to low and intermediate densities. To determine whether the effect of TGF-betas on precartilage condensations is mediated through the expression of N-cadherin, N-CAM, fibronectin and tenascin, we evaluated their expression. Results showed that TGF-beta1, TGF-beta2, TGF-beta3, and TGF-beta5 differentially enhanced the expression of N-cadherin, N-CAM, fibronectin and tenascin in precartilage condensations, suggesting that TGF-beta isoforms play an important role in the establishment of cell-cell and cell-extracellular matrix interactions during precartilage condensations.     

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.     

Versican expression during synovial joint morphogenesis

The extracellular matrix (ECM) plays a critical role in governing cell behavior and phenotype during limb skeletogenesis. Chondroitin sulfate proteoglycans (Cspgs) are highly expressed in the ECM of precartilage mesenchymal condensations and are important to limb chondrogenesis and cartilage structure, but little is known regarding their involvement in formation of synovial joints in the embryonic limb. Matrix versican Cspg expression has previously been reported in the epiphysis of developing long bones and presumptive joint; however, detailed analysis has not yet been conducted. In the present study we immunolocalized versican and aggrecan Cspgs during chick elbow joint morphogenesis between HH st25-41 of development. In this study we show that versican and aggrecan expression initially overlapped in the incipient cartilage model of long bones in the wing, but versican was also highly expressed in the perichondrium and presumptive joint interzone during early stages of morphogenesis (HH st25-34). By HH st36-41 versican localization was restricted to the future articular surfaces of the developing joint and surrounding joint capsule while aggrecan localized in an immediately adjacent and predominately non-overlapping region of chondrogenic cells at the epiphyses. These results suggest a potential role for versican proteoglycan in development and maintenance of the synovial joint interzone.     

MicroRNA-375, a new regulator of cadherin-7, suppresses the migration of chondrogenic progenitors

Endochondral bone formation requires a complex interplay among immature mesenchymal progenitor cells to form the cartilaginous anlagen, involving migration, aggregation and condensation. Even though condensation of chondrogenic progenitors is an essential step in this process, the mechanism(s) by which this occurs has not been well studied. Here, we investigated the involvement of microRNAs (miRNAs) in this process and found that the expression of miR-375 decreased upon chondrogenic differentiation of limb mesenchymal cells. Blockade of miR-375 via peptide nucleic acid (PNA)-based antisense oligonucleotides (ASOs) increased the migration of chondrogenic progenitors, the formation of precartilage condensations and the expression level of cadherin-7. Furthermore, miR-375 was necessary and sufficient to down-regulate cell migration through negative regulation of cadherin-7 by the direct interaction with 3′ UTR of cadherin-7. In addition, miR-375 is also involved in the cell migration and precartilage condensation mediated by p38MAPK, a positive signaling in the chondrogenic differentiation. Collectively, our results suggest that miR-375 negatively modulates cell migration and subsequent precartilage condensation by targeting cadherin-7.     

Hyaluronan in limb morphogenesis

Hyaluronan (HA) is a large glycosaminoglycan that is not only a structural component of extracellular matrices, but also interacts with cell surface receptors to promote cell proliferation, migration, and intracellular signaling. HA is a major component of the extracellular matrix of the distal subapical mesenchymal cells of the developing limb bud that are undergoing proliferation, directed migration, and patterning in response to the apical ectodermal ridge (AER), and has the functional potential to be involved in these processes. Here we show that the HA synthase Has2 is abundantly expressed by the distal subridge mesodermal cells of the chick limb bud and also by the AER itself. Has2 expression and HA production are downregulated in the proximal central core of the limb bud during the formation of the precartilage condensations of the skeletal elements, suggesting that downregulation of HA may be necessary for the close juxtaposition of cells and the resulting cell-cell interactions that trigger cartilage differentiation during condensation. Overexpression of Has2 in the mesoderm of the chick limb bud in vivo results in the formation of shortened and severely malformed limbs that lack one or more skeletal elements. Skeletal elements that do form in limbs overexpressing Has2 are reduced in length, exhibit abnormal morphology, and are positioned inappropriately. We also demonstrate that sustained HA production in micromass cultures of limb mesenchymal cells inhibits formation of precartilage condensations and subsequent chondrogenesis, indicating that downregulation of HA is indeed necessary for formation of the precartilage condensations that trigger cartilage differentiation. Taken together these results suggest involvement of HA in various aspects of limb morphogenesis.     

A regulatory network of two galectins mediates the earliest steps of avian limb skeletal morphogenesis

Background  

The skeletal elements of vertebrate embryonic limbs are prefigured by rod- and spot-like condensations of precartilage mesenchymal cells. The formation of these condensations depends on cell-matrix and cell-cell interactions, but how they are initiated and patterned is as yet unresolved.     

Interplay between activator-inhibitor coupling and cell-matrix adhesion in a cellular automaton model for chondrogenic patterning

We present a stochastic cellular automaton model for the behavior of limb bud precartilage mesenchymal cells undergoing chondrogenic patterning. This "agent-oriented" model represents cells by points on a lattice that obey rules motivated by experimental findings. The "cells" follow these rules as autonomous agents, interacting with other cells and with the microenvironments cell activities produce. The rules include random cell motion, production and lateral deposition of a substrate adhesion molecule (SAM, corresponding to fibronectin), production and release of a diffusible growth factor ("activator," corresponding to TGF-beta) that stimulates production of the SAM, and another diffusible factor ("inhibitor") that suppresses the activity of the activator. We implemented the cellular automaton on a two-dimensional (2D) square lattice to emulate the quasi-2D micromass culture extensively used to study patterning in avian limb bud precartilage cells. We identified parameters that produce nodular patterns that resemble, in size and distribution, cell condensations in leg-cell cultures, thus establishing a correspondence between in vitro and in silico results. We then studied the in vitro and in silico micromass cultures experimentally. We altered the standard in vitro micromass culture by diluting the initial cell density, transiently exposing it to exogenous activator, suppressing the inhibitor, and constitutively activating fibronectin production. We altered the standard in silico micromass culture in each case by changing the corresponding parameter. In vitro and in silico experiments agreed well. We also used the model to test hypotheses for differences in the in vitro patterns of cells derived from chick embryo forelimb and hindlimb. We discuss the applicability of this model to limb development in vivo and to other organ development.     

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.     

MicroRNA-221 Regulates Chondrogenic Differentiation through Promoting Proteosomal Degradation of Slug by Targeting Mdm2

MicroRNAs (miRNAs) are small RNAs that fulfill diverse functions by negatively regulating gene expression. Here, we investigated the involvement of miRNAs in the chondrogenic differentiation of chick limb mesenchymal cells and found that the expression of miR-221 increased upon chondrogenic inhibition. Blockade of miR-221 via peanut agglutinin-based antisense oligonucleotides reversed the chondro-inhibitory actions of a JNK inhibitor on the proliferation and migration of chondrogenic progenitors as well as the formation of precartilage condensations. We determined that mdm2 is a relevant target of miR-221 during chondrogenesis. miR-221 was necessary and sufficient to down-regulate Mdm2 expression, and this down-modulation of Mdm2 by miR-221 prevented the degradation of (and consequently up-regulated) the Slug protein, which negatively regulates the proliferation of chondroprogenitors. These results indicate that miR-221 contributes to the regulation of cell proliferation by negatively regulating Mdm2 and thereby inhibiting Slug degradation during the chondrogenesis of chick limb mesenchymal cells.     

Loss of Eph-receptor expression correlates with loss of cell adhesion and chondrogenic capacity in Hoxa13 mutant limbs.

Mesenchymal patterning is an active process whereby genetic commands coordinate cell adhesion, sorting and condensation, and thereby direct the formation of morphological structures. In mice that lack the Hoxa13 gene, the mesenchymal condensations that form the autopod skeletal elements are poorly resolved, resulting in missing digit, carpal and tarsal elements. In addition, mesenchymal and endothelial cell layers of the umbilical arteries (UAs) are disorganized, resulting in their stenosis and in embryonic death. To further investigate the role of Hoxa13 in these phenotypes, we generated a loss-of-function allele in which the GFP gene was targeted into the Hoxa13 locus. This allele allowed FACS isolation of mesenchymal cells from Hoxa13 heterozygous and mutant homozygous limb buds. Hoxa13(GFP) expressing mesenchymal cells from Hoxa13 mutant homozygous embryos are defective in forming chondrogenic condensations in vitro. Analysis of pro-adhesion molecules in the autopod of Hoxa13 mutants revealed a marked reduction in EphA7 expression in affected digits, as well as in micromass cell cultures prepared from mutant mesenchymal cells. Finally, antibody blocking of the EphA7 extracellular domain severely inhibits the capacity of Hoxa13(GFP) heterozygous cells to condense and form chondrogenic nodules in vitro, which is consistent with the hypothesis that reduction in EphA7 expression affects the capacity of Hoxa13(-/-) mesenchymal cells to form chondrogenic condensations in vivo and in vitro. EphA7 and EphA4 expression were also decreased in the mesenchymal and endothelial cells that form the umbilical arteries in Hoxa13 mutant homozygous embryos. These results suggest that an important role for Hoxa13 during limb and UA development is to regulate genes whose products are required for mesenchymal cell adhesion, sorting and boundary formation.     

BMPs are required at two steps of limb chondrogenesis: formation of prechondrogenic condensations and their differentiation into chondrocytes

Formation of the long bones requires a cartilage template. Cartilage formation (chondrogenesis) proceeds through determination of cells and their aggregation into prechondrogenic condensations, differentiation into chondrocytes, and later maturation. Several studies indicate that members of the bone morphogenetic protein (BMP) family promote cartilage formation, but the exact step(s) in which BMPs are involved during this process remains undefined. To resolve this issue, we have used a retroviral vector to misexpress the BMP antagonist Noggin in the embryonic chick limb. Unlike previous reports, we have characterized the resulting phenotype in depth, analyzing histological and early chondrogenic markers, as well as the patterns of cell death and proliferation. Misexpression of Noggin prior to the onset of chondrogenesis leads to the total absence of skeletal elements, as previously reported (J. Capdevila and R. L. Johnson, 1998, Dev. Biol. 197, 205-217). Noggin inhibits cartilage formation at two distinct steps. First, we demonstrate that mesenchymal cells do not aggregate into prechondrogenic condensations, and additional results suggest that these cells persist in an undifferentiated state. Second, we show that differentiation of chondroprogenitors into chondrocytes can also be blocked, concurrent with expanded expression of a presumptive joint region marker. In addition, we observed alterations in muscle and tendon morphogenesis, and the potential role of BMPs in these processes will be discussed. Our studies therefore provide in vivo evidence that BMPs are necessary for different steps of chondrogenesis: chondroprogenitor determination and/or condensation and subsequent differentiation into chondrocytes.     

The effect of prostaglandins on in vitro limb cartilage differentiation

A variety of studies indicate that a key event in limb chondrogenic differentiation is a cellular condensation process during which an intimate cell-cell interaction occurs that triggers cartilage differentiation by elevating cAMP levels. It has recently been demonstrated that when limb mesenchymal cells are subjected to high density monolayer culture under conditions conducive to chondrogenesis, they synthesize several prostaglandins, including PGE2 and prostacyclin, which are important local modulators of cAMP formation in a number of cells and tissues. In the present study, we demonstrate that exogenous PGE2 stimulates the in vitro chondrogenic differentiation of the subridge mesoderm of the embryonic chick limb bud. The stimulatory effect of PGE2 is greatly potentiated by the phosphodiesterase inhibitor, theophylline, suggesting its influence on chondrogenesis is mediated by its ability to increase cAMP levels. The stimulatory effect of PGE2 is dose-dependent and can be detected at a concentration as low as 10(-8)M. PGE1 is just as effective as PGE2 in stimulating in vitro chondrogenesis, whereas PGA1 and PGF1 alpha are less than half as effective. Thromboxane B2 has no effect on chondrogenesis. On the basis of our results, the possibility that endogenous prostaglandins might regulate limb cartilage differentiation by acting as local regulators of cAMP content is discussed.     

Stage-related chondrogenic potential of avian mandibular ectomesenchymal cells

We have examined the in vitro stage-related chondrogenic potential of avian mandibular ectomesenchymal cells using micromass cultures. Our results indicate that mandibular ectomesenchymal cells as early as stage 16, soon after the formation of the mandibular arches and well before the initiation of in vivo chondrogenesis, have chondrogenic potential which is expressed in micromass culture. There is an increase in the total area of the cultures occupied by cartilage when cells from increasing stages of development are used. The nodular pattern of chondrogenesis in these cultures indicates that mandibular ectomesenchymal cells are a heterogenous population from the time of mandibular arch formation. In addition, we studied the temporal expression of the genes for extracellular matrix proteins during in vitro chondrogenesis and correlated the morphological changes with the pattern of gene expression. Low levels of type II collagen mRNA are present in the cultures prior to detection of any stainable cartilage matrix and increase 5 fold just before the onset of chondrogenesis in vitro. On the other hand mRNA for cartilage proteoglycan core protein was not detected until the second day of culture when stainable cartilage matrix was present and progressively increased thereafter. Messenger RNA for type I collagen was present at the time of initiation of cultures and continuously increased during the culture period. Our experiments also indicated that embryonic epithelia can inhibit the in vitro chondrogenesis of mandibular ectomesenchymal cells and that the inhibitory effect of embryonic epithelia is independent of its age and site of origin.     

Involvement of Frzb-1 in mesenchymal condensation and cartilage differentiation in the chick limb bud

In developing limb bud, mesenchymal cells form cellular aggregates called "mesenchymal condensations". These condensations show the prepattern of skeletal elements of the limb prior to cartilage differentiation. Roles of various signaling molecules in chondrogenesis in the limb bud have been reported. One group of signaling factors includes the Wnt proteins, which have been shown to have an inhibitory effect on chondrogenesis in the limb bud. Therefore, regulation of Wnt activity may be important in regulating cartilage differentiation. Here we show that Frzb-1, which encodes a secreted frizzled-related protein that can bind to Wnt proteins and can antagonize the activity of some Wnts, is expressed in the developing limb bud. At early stages of limb development, Frzb-1 is expressed in the ventral core mesenchyme of the limb bud, and later Frzb-1 expression becomes restricted to the central core region where mesenchymal condensations occur. At these stages, a chondrogenic marker gene, aggrecan, is not yet expressed. As limb development proceeds, expression of Frzb-1 is detected in cartilage primordial cells, although ultimately Frzb-1 expression is down-regulated. Similar results were obtained in the recombinant limb bud, which was constructed from dissociated and re-aggregated mesenchymal cells and an ectodermal jacket with the apical ectodermal ridge. In addition, Frzb-1 expression preceded aggrecan expression in micromass cultures. These results suggest that Frzb-1 has a role in condensation formation and cartilage differentiation by regulating Wnt activity in the limb bud.     

Indian hedgehog synchronizes skeletal angiogenesis and perichondrial maturation with cartilage development

A null mutation in the morphogen Indian hedgehog (IHH) results in an embryonic lethal phenotype characterized by the conspicuous absence of bony tissue in the extremities. We show that this ossification defect is not attributable to a permanent arrest in cartilage differentiation, since Ihh(-/-) chondrocytes undergo hypertrophy and terminal differentiation, express angiogenic markers such as Vegf, and are invaded, albeit aberrantly, by blood vessels. Subsequent steps, including vessel expansion and persistence, are impaired, and the net result is degraded cartilage matrix that is devoid of blood vessels. The absence of blood vessels is not because the Ihh(-/-) skeleton is anti-angiogenic; in fact, in an ex vivo environment, both wild-type and Ihh mutant vessels invade the Ihh(-/-) cartilage, though only wild-type vessels expand to create the marrow cavity. In the ex vivo setting, Ihh(-/-) cells differentiate into osteoblasts and deposit a bony matrix, without benefit of exogenous hedgehog in the new environment. Even more surprising is our finding that the earliest IHH-dependent skeletal defect is obvious by the time the limb mesenchyme segregates into chondrogenic and perichondrogenic condensations. Although Ihh(-/-) cells organize into chondrogenic condensations similar in size and shape to wild-type condensations, perichondrial cells surrounding the mutant condensations are clearly faulty. They fail to aggregate, elongate and flatten into a definitive, endothelial cell-rich perichondrium like their wild-type counterparts. Normally, these cells surrounding the chondrogenic condensation are exposed to IHH, as evidenced by their expression of the hedgehog target genes, patched (Ptch) and Gli1. In the mutant environment, the milieu surrounding the cartilage -- comprising osteoblast precursors and endothelial cells -- as well as the cartilage itself, develop in the absence of this important morphogen. In conclusion, the skeletal phenotype of Ihh(-/-) embryos represents the sum of disturbances in three separate cell populations, the chondrocytes, the osteoblasts and the vasculature, each of which is a direct target of hedgehog signaling.     

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.