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.     

Epithelia are interchangeable between facial primordia of chick embryos and morphogenesis is controlled by the mesenchyme

The embryonic chick face is composed of a series of facial primordia, epithelium-covered buds of mesenchyme, which surround the presumptive mouth. The protruding adult upper beak containing the prenasal cartilage is formed from the frontonasal mass, the paired maxillary primordia form the sides of the face, while the lower beak is derived from the paired mandibular primordia which contain the two Meckel's cartilages. When grafted to a host wing bud, the frontonasal mass and the mandibular primordia both form elongated outgrowths, whereas the maxillary primordium forms a ball of tissue. Facial epithelium is required for growth and morphogenesis of all primordia. Recombinations between epithelium and mesenchyme from different primordia show that the epithelia are interchangeable and appear to be equivalent. Even the epithelium from the maxillary primordium that does not grow out in a polarized fashion can support outgrowth of the frontonasal mass and mandibular mesenchyme. The form of the recombined graft is determined by the mesenchymal component.     

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.     

Formation of chondrous and osseous tissues in micromass cultures of rat frontonasal and mandibular ectomesenchyme

Rat frontonasal and mandibular mesenchyme was isolated from day-12 1/2 (stage-22) rat embryos and cultured at high density for up to 12 days. The stage chosen was based on the observation that mandibular mesenchyme at this stage became independent of its epithelium with respect to the production of both cartilage and bone. Frontonasal cultures developed aggregates of anastomosing columns of cells within 2 days. These grew as the cells enlarged, laying down an Alcian-blue-positive matrix by day 3 of culture. Significant mineral was detected by von Kossa staining by day 5 at which time the aggregates covered a large portion of the culture, eventually covering the entire micromass by day 10-12. Mandibular cultures developed centrally located nodular aggregates by 3 days of culture. These nodules increased in number, spreading outwards as the cells enlarged, laying down an Alcian-blue-positive matrix by day 4 and mineral by days 6-7. At this time the nodules began to elongate and coalesce, but never covered the entire culture over the 12-day period. Antibody staining revealed that in both cultures the cells were initially positive for type I collagen. Subsequently, the aggregates began expressing type II collagen, followed by type X, which coincided with the onset of mineralization. At this time some cells were negative for these cartilage markers, but positive for osteoblast markers, bone sialoprotein II, osteocalcin and type I collagen. In addition osteonectin and alkaline phosphatase were demonstrable in all of the aggregate cells late in the culture period. This provided clear evidence that chondroblast and osteoblast differentiation was proceeding within these cultures. The culture of rat facial mesenchyme should prove very useful, not only for the analysis of bone and cartilage induction and lineage relationships, but also in furthering our knowledge of craniofacial differentiation, growth and pattern formation by extending our analysis to a mammalian system.     

Epithelial-mesenchymal interactions in the development of chick facial primordia and the target of retinoid action

The development of the chick face involves outgrowth of buds of tissue, accompanied by the differentiation of cartilage and bone in spatially defined patterns. To investigate the role of epithelial-mesenchymal interactions in facial morphogenesis, small fragments of facial tissue have been grafted to host chick wing buds to continue their development in isolation. Fragments of the frontonasal mass give rise to typical upper-beak-like structures: a long central rod of cartilage, the prenasal cartilage and an egg tooth. Meckel's cartilage, characteristic of the lower beak, develops from fragments of the mandible. Removal of the ectoderm prior to grafting leads to truncated development. In fragments of frontonasal mass mesenchyme only a small spur of cartilage differentiates and there is no outgrowth. The mandible is less affected; a rod of cartilage still forms but the amount of outgrowth is reduced. Retinoid treatment of chick embryos specifically affects the development of the upper beak and outgrowth and cartilage differentiation in the frontonasal mass are inhibited. The mandibles, however, are unaffected and develop normally. In order to investigate whether the epithelium or the mesenchyme of the frontonasal mass is the target of retinoid action, recombinations of retinoid-treated and untreated facial tissue have been grafted to host wing buds. Recombinations of retinoid-treated frontonasal mass ectoderm with untreated mesenchyme develop normally whereas recombinations of untreated ectoderm with retinoid-treated mesenchyme lead to truncations. The amount of outgrowth in fragments of mandibular tissue is slightly reduced when either the ectoderm or the mesenchyme has been treated with retinoids. These recombination experiments demonstrate that the mesenchyme of the frontonasal mass is the target of retinoid action. This suggests that retinoids interfere with the reciprocal epithelial-mesenchymal interactions necessary for outgrowth and normal upper beak development.     

Environmental regulation of type X collagen production by cultures of limb mesenchyme, mesectoderm, and sternal chondrocytes

We have examined whether the production of hypertrophic cartilage matrix reflecting a late stage in the development of chondrocytes which participate in endochondral bone formation, is the result of cell lineage, environmental influence, or both. We have compared the ability of cultured limb mesenchyme and mesectoderm to synthesize type X collagen, a marker highly selective for hypertrophic cartilage. High density cultures of limb mesenchyme from stage 23 and 24 chick embryos contain many cells that react positively for type II collagen by immunohistochemistry, but only a few of these initiate type X collagen synthesis. When limb mesenchyme cells are cultured in or on hydrated collagen gels or in agarose (conditions previously shown to promote chondrogenesis in low density cultures), almost all initiate synthesis of both collagen types. Similarly, collagen gel cultures of limb mesenchyme from stage 17 embryos synthesize type II collagen and with some additional delay type X collagen. However, cytochalasin D treatment of subconfluent cultures on plastic substrates, another treatment known to promote chondrogenesis, induces the production of type II collagen, but not type X collagen. These results demonstrate that the appearance of type X collagen in limb cartilage is environmentally regulated. Mesectodermal cells from the maxillary process of stages 24 and 28 chick embryos were cultured in or on hydrated collagen gels. Such cells initiate synthesis of type II collagen, and eventually type X collagen. Some cells contain only type II collagen and some contain both types II and X collagen. On the other hand, cultures of mandibular processes from stage 29 embryos contain chondrocytes with both collagen types and a larger overall number of chondrogenic foci than the maxillary process cultures. Since the maxillary process does not produce cartilage in situ and the mandibular process forms Meckel's cartilage which does not hypertrophy in situ, environmental influences, probably inhibitory in nature, must regulate chondrogenesis in mesectodermal derivatives. (ABSTRACT TRUNCATED AT 250 WORDS)     

Epithelial-mesenchymal interactions in the outgrowth of limb buds and facial primordia in chick embryos.

The facial primordia in the chick embryo begin as rounded swellings that surround the primitive mouth and these grow out to form the beak. The control of proximodistal outgrowth is not well understood but may involve similar mechanisms to the limb bud. In order to test this hypothesis, combinations were made between epithelium and mesenchyme from facial primordia and limb buds. Signals from all three types of facial mesenchyme (frontonasal mass, mandibular, and maxillary) maintained the thickened apical ectodermal ridge of limb epithelium for up to 48 h. Combinations of tissues from the frontonasal mass mesenchyme and limb epithelium underwent substantial and correct morphogenesis. In contrast, poor development was observed in combinations with mandibular mesenchyme. Signals from frontonasal mass epithelium promoted outgrowth and morphogenesis of limb mesenchyme whereas mandibular and maxillary epithelium did not support joint morphogenesis. The results suggest that signals employed in the epithelial-mesenchymal interactions in facial primordia are similar but not identical to those signals used in the limb bud.     

The effects of retinoids on cartilage differentiation in micromass cultures of chick facial primordia and the relationship to a specific facial defect

Retinoids produce facial defects in chicken embryos. Outgrowth of the frontonasal mass with accompanying cartilage differentiation and pattern formation is inhibited. In contrast, the development of the mandibular primordia that give rise to the lower beak proceeds normally. To investigate whether the upper beak defect is based on the inhibition of cartilage differentiation specifically in the frontonasal mass, the effects of retinoids on chondrogenesis in micromass (high density) cultures of cells from facial primordia have been studied. When either 10(-6) M retinoic acid or 10(-8) M (E)-4-[2-(5,6,7,8-tetrahydro-5,5,8,8-tetramethyl-2-napthalenyl-1- propenyl]benzoic acid (TTNPB; a stable retinoid) is added to the culture medium, cartilage differentiation is inhibited. Both frontonasal mass and mandible cultures are equally affected. The concentration of TTNPB found in both facial primordia in vivo, after a treatment that produces the defect, is also about 10(-8) M. This rules out preferential accumulation of the retinoid by the frontonasal mass as an explanation for the defect. In fact, the concentration of retinoid found in vivo, should, from the culture studies, be sufficient to markedly inhibit chondrogenesis in both the frontonasal mass and mandibles. The effects of exposure to retinoids in the intact face appear to be different to those in culture. Furthermore, when cells from retinoid-treated facial primordia are cultured in micromass, the extent and pattern of chondrogenesis in frontonasal mass cultures is identical to that of cells from untreated primordia. Cartilage differentiation in mandible cultures is slightly affected. These findings suggest that retinoids do not produce the specific facial defect by directly interfering with cartilage differentiation.     

Chondrogenesis and myogenesis in micromass cultures of mesenchyme from mouse facial primordia

Summary The face develops from small buds of tissue positioned around the primitive mouth. The chondrogenic and myogenic cell populations contained within these facial primordia in mouse embryos have been investigated in short-term micromass culture. Chondrogenesis occurred in frontonasal mass mesenchyme from E11-E13 embryos, in maxillary mesenchyme from E12.5 embryos and was absent in mandibular mesenchyme. Myogenesis was greatest in mandibular mesenchyme, moderate in maxillary mesenchyme and low in the frontonasal mass. When compared with chick embryos the mouse facial primordia have lower chondrogenic potential, which in the case of the frontonasal mass may be related to the relative outgrowth of the primordia in the two species. Chondrogenesis in the mouse mandibular mesenchyme may be affected by the presence of a large population of odontogenic mesenchyme. The behavior of myogenic cell populations is related to the pattern of the musculature of the face, as the mandible contains the most muscle, the maxilla some, and the frontonasal mass none. However, the presence of myoblasts in early mesenchyme of all primordia may indicate that, as with chick, facial primordia are initially seeded with muscle cells and that the size of the cell population is subsequently controlled according to the development of the musculature within the primordia.     

An immunofluorescence study of chondrogenesis in murine mandibular ectomesenchyme

The temporal and spatial distribution of type I collagen, type II collagen, cartilage-specific proteoglycan (CSPG) and fibronectin in mouse mandible is described. CD-1 mouse embryos of 12-, 15-, and 18-day gestation were used, and matrix molecules were localized using indirect immunofluorescence. On day 12, accumulation of type II collagen, CSPG, and fibronectin within regions of condensed mesenchyme was noted. On day 15, intense staining for type II collagen and CSPG occurred. Fibronectin was less brilliant with its greatest concentration near the perichondrium. On day 18, the cartilage matrix was undergoing osseous replacement concurrent with loss of type II collagen and CSPG. Type I collagen was seen in the perichondrium, membranous bone and sub-basement membrane region in specimens of all ages. Synthesis and expression of extracellular matrix molecules reflect patterns of differentiation in mandibular mesenchyme.     

Two distinct regulatory steps in cartilage differentiation

The effect of developmental stage on chondrogenic capacity in high-density cell cultures of chick embryonic wing bud mesenchyme is examined. Mesenchyme from stage 19 embryos forms aggregates of closely associated cells which do not form cartilage matrix, nor contain significant levels of type II collagen that are detectable by immunofluorescence, unless they are treated with dibutyryl cyclic AMP. Mesenchyme from stage 24 embryonic wing buds in high-density cell cultures will spontaneously form cartilage, as defined by electron microscopy and immunofluorescence with antibody to type II collagen. Cultures prepared from stage 26 wings form numerous aggregates which fail to accumulate an Alcian blue-staining matrix and which resemble mesenchyme cells morphologically. However, because these cells show considerable intracellular immunofluorescence for type II collagen, they are actually unexpressed cartilage cells. Several treatments, including exposure to dibutyryl cyclic AMP, ascorbic acid and an atmosphere of 5% oxygen, or mixture with small numbers of stage 24 wing mesenchyme cells, stimulate expression, as determined by the accumulation of an Alcian blue-staining matrix and an ultrastructurally recognizable cartilage matrix. Since the addition of similar numbers of differentiated cartilage cells does not stimulate expression of stage 26 cells, it is proposed that initial cartilage expression is dependent on a mesenchyme-specific influence which might be removed by cell dissociation. These studies demonstrate that there are at least two distinct transitions in cartilage differentiation: one involves the conversion of mesenchyme to unexpressed chondrocytes and the second involves mesenchyme-dependent expression of chondrogenic differentiation.     

Osteogenin (bone morphogenetic protein-3) stimulates cartilage formation by chick limb bud cells in vitro.

Osteogenin is a protein isolated from demineralized bovine bone matrix. When implanted in rats, osteogenin induces the differentiation of cartilage and formation of endochondral bone. When added to stage 24 and 25 chick limb bud mesoderm cells in culture, it stimulated synthesis of sulfated proteoglycans by over 10-fold without stimulating cell division. The increase was detected after only 2 days in culture. Morphologically, in the presence of osteogenin, all cells in the culture appeared to form cartilage, rather than the nodules of cartilage surrounded by noncartilage areas in control cultures. The distribution of type II collagen correlated with the morphological differentiation of cartilage. When nonchondrocyte and chondrocyte cell populations were separated, osteogenin stimulated sulfated proteoglycan synthesis in all populations of cells. However, the greatest stimulation (24-fold) was seen in the originally nonchondrocyte population, which apparently still had some potential to form cartilage. In this study, chick limb bud mesoderm cells in vitro responded to osteogenin, a protein derived from adult bovine bone matrix. The cells that were responsive included those that initially did not form cartilage. Osteogenin belongs to a superfamily of proteins, many of which are important in development. It is possible that osteogenin has a role in embryonic cartilage development.     

Extent of cell differentiation and capacity for cartilage synthesis in human adult adipose‐derived stem cells: Comparison with fetal chondrocytes

This study evaluated the extent of differentiation and cartilage biosynthetic capacity of human adult adipose‐derived stem cells relative to human fetal chondrocytes. Both types of cell were seeded into nonwoven‐mesh polyglycolic acid (PGA) scaffolds and cultured under dynamic conditions with and without addition of TGF‐β1 and insulin. Gene expression for aggrecan and collagen type II was upregulated in the stem cells in the presence of growth factors, and key components of articular cartilage such as glycosaminoglycan (GAG) and collagen type II were synthesized in cultured tissue constructs. However, on a per cell basis and in the presence of growth factors, accumulation of GAG and collagen type II were, respectively, 3.4‐ and 6.1‐fold lower in the stem cell cultures than in the chondrocyte cultures. Although the stem cells synthesized significantly higher levels of total collagen than the chondrocytes, only about 2.4% of this collagen was collagen type II. Relative to cultures without added growth factors, treatment of the stem cells with TGF‐β1 and insulin resulted in a 59% increase in GAG synthesis, but there was no significant change in collagen production even though collagen type II gene expression was upregulated 530‐fold. In contrast, in the chondrocyte cultures, synthesis of collagen type II and levels of collagen type II as a percentage of total collagen more than doubled after growth factors were applied. Although considerable progress has been achieved to develop differentiation strategies and scaffold‐based culture techniques for adult mesenchymal stem cells, the extent of differentiation of human adipose‐derived stem cells in this study and their capacity for cartilage synthesis fell considerably short of those of fetal chondrocytes. Biotechnol. Bioeng. 2010;107: 393–401. © 2010 Wiley Periodicals, Inc.     

Inhibition of limb chondrogenesis in vitro by vitamin A: alterations in cell surface characteristics

Mesenchyme cells derived from embryonic mouse limb buds were cultured at high cell density. During the first 24 h in culture, groups of mesenchyme cells condensed and formed cell contacts and specialized junctions. These condensations were the nodule primordia which gave rise to cartilage nodules. The cell contacts were lost as the mesenchyme cells in the primordia developed into cartilage nodules. The mature nodules contained chondrocytes isolated from one another by an extensive extracellular matrix consisting of cartilage type collagen fibrils and proteoglycan granules. The differentiation of the mesenchyme cells to chondrocytes was also characterized by the loss of a 240,000-MW cell surface glycoprotein and the appearance of an 80,000-MW surface protein. The addition of vitamin A to the medium on Day 1 inhibited chondrogenesis. The cells were closely packed together, and the limited extracellular space contained thick, banded collagen fibrils with no proteoglycan granules. The cells exhibited extensive areas of close membrane contact and specialized junctions. Vitamin A-treated cultures also retained the 240,000-MW surface glycoprotein and retarded the appearance of the 80,000-MW cell surface protein. The results of this study suggest that cell surface features normally present on mesenchyme cells are maintained and exaggerated by vitamin A.