The influence of epithelia on cartilage and loose connective tissue formation by limb mesenchyme cultures

Disrupted homeostasis of synovial hyaluronic acid and its associations with synovial mast cell proteases of rheumatoid arthritis patients and collagen-induced arthritis rats

Hyaluronic acid (HA) is the main component of the extracellular matrix (ECM) of joints, and it is important for a lubricating joint during body movement. Degradation is the main metabolic process of HA in vivo. Hyaluronidases (HAase) were known for HA degradation. The inflammation-induced HA rapid-metabolism can reduce HA viscosity and concentration in joints. Mast cells (MC) containing their specific proteases were found in synovium tissue. It is unclear if MC-proteases could be involved in HA degradation pathways. This study aims to explore the correlations between HA concentration vs mast cell proteases, or matrix metalloproteinase-2/9 (MMP-2/9) and to investigate the association of MC-specific proteases with disrupted synovial HA homeostasis in rheumatoid arthritis (RA) or collagen-induced arthritis rats. The synovial fluid samples from no-RA and RA patients were collected; the collagen-induced arthritis (CIA) rat model was established; HA concentration and the activities of MC-protease and MMP-2/9 in the samples were detected, and the correlations were analyzed. In vitro interaction experiment was carried out by mixing MC-proteases with HA to observe the degradation speed. The HA concentrations in synovial fluids were decreased in RA patients and CIA rats compared with those in no-RA subjects or normal rats respectively. The activities of mast cell proteases in synovial fluids were increased and positively correlated with MMP-9, but negatively correlated with HA concentrations. In vitro study, the addition of MC-chymase and tryptase promoted the speed in HA degradation. MC-proteases may influence HA degradation pathway.

MicroRNA-200a Regulates the Development of Mandibular Condylar Cartilage

Mandibular condylar cartilage (MCC) is classified as secondary cartilage, the histologic structure of which is unique from that of primary cartilage. MicroRNA (miRNA) is a small noncoding RNA that binds to the messenger RNA (mRNA) target to repress its translation and plays an important role in cell differentiation, proliferation, and death. Microarray analysis revealed that miR-200a was characteristically expressed during embryonic development. We hypothesized that miR-200a may be involved in regulating the formation of cartilage during MCC growth. We investigated the function of miR-200a by transfecting an inhibitor or mimic into MCC organ and cell cultures. A histologic examination revealed the localized inhibitory effects of the miR-200a mimic and widespread enhancing effects of the inhibitor on chondrocytic differentiation in the MCC organ culture system. An immunohistochemical examination and gene expression analysis demonstrated that the miR-200a inhibitor enhanced chondrogenesis, while the mimic had the opposite effect by enhancing cell proliferation. Quantitative reverse transcription polymerase chain reaction analysis revealed that miR-200a downregulated the gene expression of chondrocyte markers. Moreover, transfection of the miR-200a mimic into ATDC5 cells repressed the formation of the cartilaginous matrix. These results indicate that miR-200a contributed to chondrogenesis in developing MCC by controlling proliferation and differentiation in MCC cells.

Ectodermal Wnt6 is an early negative regulator of limb chondrogenesis in the chicken embryo

BACKGROUND

Pattern formation of the limb skeleton is regulated by a complex interplay of signaling centers located in the ectodermal sheath and mesenchymal core of the limb anlagen, which results, in the forelimb, in the coordinate array of humerus, radius, ulna, carpals, metacarpals and digits. Much less understood is why skeletal elements form only in the central mesenchyme of the limb, whereas muscle anlagen develop in the peripheral mesenchyme ensheathing the chondrogenic center. Classical studies have suggested a role of the limb ectoderm as a negative regulator of limb chondrogenesis.

RESULTS

In this paper, we investigated the molecular nature of the inhibitory influence of the ectoderm on limb chondrogenesis in the avian embryo in vivo. We show that ectoderm ablation in the early limb bud leads to increased and ectopic expression of early chondrogenic marker genes like Sox9 and Collagen II, indicating that the limb ectoderm inhibits limb chondrogenesis at an early stage of the chondrogenic cascade. To investigate the molecular nature of the inhibitory influence of the ectoderm, we ectopically expressed Wnt6, which is presently the only known Wnt expressed throughout the avian limb ectoderm, and found that Wnt6 overexpression leads to reduced expression of the early chondrogenic marker genes Sox9 and Collagen II.

CONCLUSION

Our results suggest that the inhibitory influence of the ectoderm on limb chondrogenesis acts on an early stage of chondrogenesis upsteam of Sox9 and Collagen II. We identify Wnt6 as a candidate mediator of ectodermal chondrogenic inhibition in vivo. We propose a model of Wnt-mediated centripetal patterning of the limb by the surface ectoderm.

Growth and patterning in the limb: signaling gradients make the decision

The vertebrate limb bud provides a unique system to investigate the coordinated regulation of growth and patterning, two key processes that govern the formation of a complex multicellular organism from a fertilized egg. Two studies have advanced our understanding of limb development by elucidating that signaling gradients from the limb ectoderm, including the apical ectoderm ridge (AER), act in concert to establish a basic pattern of tissue layers by coordinating cell proliferation and cell fate determination. These studies reveal that cell proliferation and fate determination in development can be two faces of the same coin in that they are regulated by the same signaling pathways. Alterations in the duration and range of the signaling gradients may underlie many of the morphological differences in the evolution of vertebrate limbs.

Wnt and FGF signals interact to coordinate growth with cell fate specification during limb development

A fundamental question in developmental biology is how does an undifferentiated field of cells acquire spatial pattern and undergo coordinated differentiation? The development of the vertebrate limb is an important paradigm for understanding these processes. The skeletal and connective tissues of the developing limb all derive from a population of multipotent progenitor cells located in its distal tip. During limb outgrowth, these progenitors segregate into a chondrogenic lineage, located in the center of the limb bud, and soft connective tissue lineages located in its periphery. We report that the interplay of two families of signaling proteins, fibroblast growth factors (FGFs) and Wnts, coordinate the growth of the multipotent progenitor cells with their simultaneous segregation into these lineages. FGF and Wnt signals act together to synergistically promote proliferation while maintaining the cells in an undifferentiated, multipotent state, but act separately to determine cell lineage specification. Withdrawal of both signals results in cell cycle withdrawal and chondrogenic differentiation. Continued exposure to Wnt, however, maintains proliferation and re-specifies the cells towards the soft connective tissue lineages. We have identified target genes that are synergistically regulated by Wnts and FGFs, and show how these factors actively suppress differentiation and promote growth. Finally, we show how the spatial restriction of Wnt and FGF signals to the limb ectoderm, and to a specialized region of it, the apical ectodermal ridge, controls the distribution of cell behaviors within the growing limb, and guides the proper spatial organization of the differentiating tissues.

Hyaluronate-cell interactions and growth factor regulation of hyaluronate synthesis during limb development

Hyaluronate is a major component of the intercellular matrix surrounding proliferating and migrating cells in embryonic tissues. When placed in culture, mesodermal cells from the early, proliferative stages of limb development produce high levels of hyaluronate and exhibit prominent hyaluronate-dependent pericellular coats. Cells from the subsequent stages of mesodermal condensation that precede differentiation to cartilage and muscle produce less hyaluronate and do not exhibit these coats. Also at this time, binding sites specific for hyaluronate appear on the surface of the mesodermal cells. These binding sites may participate in the mechanism of condensation by mediating cell aggregation and the endocytosis of hyaluronate. Further changes in hyaluronate-cell interaction occur during differentiation of the condensed mesoderm to cartilage and muscle. Hyaluronate synthesis and pericellular coat formation in the mesoderm are stimulated by a factor, related to transforming growth factor-beta, that is produced by the surrounding ectoderm. The early limb also contains high levels of basic fibroblast growth factor. Its concentration is highest at the earliest stages, when cell proliferation and hyaluronate synthesis are prominent activities, and this factor has been shown to stimulate both these activities in cultures of limb mesodermal cells. Thus fibroblast growth factor and transforming growth factor-beta may be important in the regulation of early growth and morphogenesis of the limb.

Dynamical mechanisms for skeletal pattern formation in the vertebrate limb

We describe a 'reactor-diffusion' mechanism for precartilage condensation based on recent experiments on chondrogenesis in the early vertebrate limb and additional hypotheses. Cellular differentiation of mesenchymal cells into subtypes with different fibroblast growth factor (FGF) receptors occurs in the presence of spatio-temporal variations of FGFs and transforming growth factor-betas (TGF-betas). One class of differentiated cells produces elevated quantities of the extracellular matrix protein fibronectin, which initiates adhesion-mediated preskeletal mesenchymal condensation. The same class of cells also produces an FGF-dependent laterally acting inhibitor that keeps condensations from expanding beyond a critical size. We show that this 'reactor-diffusion' mechanism leads naturally to patterning consistent with skeletal form, and describe simulations of spatio-temporal distribution of these differentiated cell types and the TGF-beta and inhibitor concentrations in the developing limb bud.

Wnt-5a inhibits the canonical Wnt pathway by promoting GSK-3-independent beta-catenin degradation

Wnts are secreted signaling molecules that can transduce their signals through several different pathways. Wnt-5a is considered a noncanonical Wnt as it does not signal by stabilizing beta-catenin in many biological systems. We have uncovered a new noncanonical pathway through which Wnt-5a antagonizes the canonical Wnt pathway by promoting the degradation of beta-catenin. This pathway is Siah2 and APC dependent, but GSK-3 and beta-TrCP independent. Furthermore, we provide evidence that Wnt-5a also acts in vivo to promote beta-catenin degradation in regulating mammalian limb development and possibly in suppressing tumor formation.

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.

Fibroblast growth factor-induced gene expression and cartilage pattern formation in chick limb bud recombinants

To clarify the roles of fibroblast growth factors (FGF) in limb cartilage pattern formation, the effects of various FGF on recombinant limbs that were composed of dissociated and reaggregated mesoderm and ectodermal jackets were examined. Fibroblast growth factor-soaked beads were inserted just under the apical ectodermal ridge (AER) of recombinant limbs and the recombinant limbs were grafted and allowed to develop. Control recombinant limbs without FGF beads formed one or two cartilage elements. Recombinants with FGF-4 beads formed up to five cartilage elements, which were aligned along the anteroposterior (AP) axis. Each cartilage element showed digit-like segmentation. In contrast, recombinants with FGF-2 beads showed formation of multiple thick and unsegmented cartilage rods, which elongated inside and outside the AP plane from the distal end of the recombinants. Recombinants with FGF-8 beads formed a truncated cartilage pattern and recombinants with FGF-10 beads formed a cartilage pattern similar to that of the control recombinants. The expression of the Fgf-8, Msx-1 and Hoxa-13 genes in the developing recombinant limbs were examined. FGF-4 induced extension of the length of the Fgf-8-positive epidermis, or AER, along the AP axis 5 days after grafting, at which time the digits are specified. FGF-2 induced expansion of the Msx-1-positive area, first in the proximal direction and then along the dorsoventral axis. The functions of these FGF in recombinant and normal limb patterning are discussed in this paper.

Involvement of Wnt-5a in chondrogenic pattern formation in the chick limb bud

Members of the Wnt family are known to play diverse roles in the organogenesis of vertebrates. The full-coding sequences of chicken Wnt-5a were identified and the role it plays in limb development was examined by comparing its expression pattern with that of two other Wnt members, Wnt-4 and Wnt-11, and by misexpressing it with a retrovirus vector in the limb bud. Wnt-5a expression is detected in the limb-forming region at stage 14, and in the apical ectodermal ridge and distal mesenchyme of the limb bud. The signal was graded along the proximal-distal axis at stages 20-28 and also along the anterior-posterior axis during early stages. It disappeared in the cartilage-forming region after stage 26, and was restricted to the region surrounding the phalanges at stage 34. Wnt-4 and Wnt-11, other members of the Wnt-5a-subclass, were expressed with a distinct spatiotemporal pattern during the later phase. Wnt-4 was expressed in the articular structure and Wnt-11 was expressed in the dorsal and ventral mesenchyme adjacent to the ectoderm. Wnt-5a expression was partially reduced after apical ectodermal ridge removal, whereas Wnt-11 expression was down-regulated by dorsal ectoderm removal. Therefore, expression of these Wnt was differentially regulated by the ectodermal signal. Misexpression of Wnt-5a in the limb bud with the retrovirus resulted in truncation of long bones predominantly in the zeugopod because of retarded chondrogenic differentiation. Distal elements, such as the phalanges and metacarpals, were not significantly reduced in size. These results suggest that Wnt-5a is involved in pattern formation along the proximal-distal axis by regulation of chondrogenic differentiation.

Syndecan-3 in limb skeletal development

Syndecan-3 is a member of a family of heparan sulfate proteoglycans that function as extracellular matrix receptors and as co-receptors for growth factors and signalling molecules. A variety of studies indicate that syndecan-3 is involved in several aspects of limb morphogenesis and skeletal development. Syndecan-3 participates in limb outgrowth and proliferation in response to the apical ectodermal ridge; mediates cell-matrix and/or cell-cell interactions involved in regulating the onset of chondrogenesis; may be involved in regulating the onset of osteogenesis and joint formation and, plays a role in regulating the proliferation of epiphyseal chondrocytes during endochondral ossification.

Morphogenesis of Doublefoot (Dbf), a mouse mutant with polydactyly and craniofacial defects

We report the morphogenesis of a new mouse mutant, Doublefoot (Dbf). The major phenotypic features involve the limb and craniofacial regions. There is polydactyly of all 4 limbs, with typically 6-8 digits per limb. All of the digits are triphalangeal; some show bifurcations and some are not attached to the carpus/tarsus. The carpus and tarsus are broader than normal, and their elements are partially fused. There are also tibial defects. Mutant embryos show a diencephalic bulge on d 10.0, with older animals exhibiting broadened and bulbous skulls sometimes with an additional midline skeletal element, shortened snouts and bulging eyes. Homozygotes, which do not survive beyond d 15, show midline facial clefting. In this study of the embryonic and fetal development of Dbf animals, we focus on the morphogenesis of the limbs and head, and discuss the possible molecular developmental mechanisms.

Msx1 expressing mesoderm is important for the apical ectodermal ridge (AER)-signal transfer in chick limb development

The apical ectodermal ridge (AER) is a specialized thickening of the distal limb ectoderm, and its signals are known to support limb morphogenesis. The expression of a homeobox gene, Msx1, in the distal limb mesoderm depends on signals from the AER. In the present paper it is reported that Msx1 expression in the distal mesoderm is necessary for the transfer of AER signals in chick limb buds. Interruption of AER-mesoderm interaction by insertion of a thick filter led to the inhibition of pattern specification in the mesoderm just under the filter. In such cases, the expression of Msx1 disappeared in the mesoderm under the filter, suggesting that AER is able to signal over short ranges. In advanced limb buds, Msx1 is also expressed in the proximal mesoderm under the anterior ectoderm. However, it was found that a grafted antero-proximal mesoderm shows no inhibitory effects on pattern specification of the host mesoderm, as is the case with the distal mesoderm. On the other hand, grafted mesoderms without potent Msx1 re-expression, even underneath AER, disturbed normal limb development. In such cases, the expression of Msx1 disappeared in the mesoderm under the grafts, whereas Fgf-8 expression was maintained in the AER above the graft. These results indicate that the expression of Msx1 in the mesoderm is important for the transfer of AER signals.

Apical ectodermal ridge-dependent expression of the chick 67 kDa laminin binding protein gene (cLbp) in developing limb bud

Apical ectodermal ridge (AER)-mesoderm interaction is important for morphogenesis in the developing chick limb bud. Genes whose expression is dependent upon the presence of AER, are likely to play important roles in the AER-mesoderm interaction. We report here the gene expression pattern of the chick homolog of the 67 kDa laminin binding protein (LBP), which is a non-integrin laminin receptor whose function relates to cell attachment, spreading, and polarization. Northern analysis showed that a single 1.4 kb transcript exists in stage 20 limb buds and which is dramatically reduced 24 hr after removal of AER. In situ hybridization analysis revealed that the chick 67 kDa laminin binding protein gene (cLbp) was expressed in the mesodermal region overlapping the Msx1-expressing domain and in the AER in early stage limb buds. Expression in the mesoderm was gradually restricted to the distal region underneath the AER as development proceeds. The expression in the limb mesoderm could be induced by local application of FGF-2 which could thus mimic the AER functions. These results indicated that the expression of cLbp depends on AER signals and that the 67 kDa non-integrin receptor binding to laminin plays a role in the AER-mesoderm interaction.

Inhibition of chondrogenesis by Wnt gene expression in vivo and in vitro

The Wnt family of secreted signaling proteins are implicated in regulating morphogenesis and tissue patterning in a wide variety of organ systems. Several Wnt genes are expressed in the developing limbs and head, implying roles in skeletal development. To explore these functions, we have used retroviral gene transfer to express Wnt-1 ectopically in the limb buds and craniofacial region of chick embryos. Infection of wing buds at stage 17 and tissues in the head at stage 10 resulted in skeletal abnormalities whose most consistent defects suggested a localized failure of cartilage formation. To test this hypothesis, we infected micromass cultures of prechondrogenic mesenchyme in vitro and found that expression of Wnt-1 caused a severe block in chondrogenesis. Wnt-7a, a gene endogenously expressed in the limb and facial ectoderm, had a similar inhibitory effect. Further analysis of this phenomenon in vitro showed that Wnt-1 and Wnt-7a had mitogenic effects only in early prechondrogenic mesenchyme, that cell aggregation and formation of the prechondrogenic blastema occurred normally, and that the block to differentiation was at the late-blastema/early-chondroblast stage. These results indicate that Wnt signals can have specific inhibitory effects on cytodifferentiation and suggest that one function of endogenous Wnt proteins in the limbs and face may be to influence skeletal morphology by localized inhibition of chondrogenesis.

FGF-stimulated outgrowth and proliferation of limb mesoderm is dependent on syndecan-3

The outgrowth of the mesoderm of the developing limb bud in response to the apical ectodermal ridge (AER) is mediated at least in part by members of the FGF family. Recent studies have indicated that FGFs need to interact with heparan sulfate proteoglycans in order to bind to and activate their specific cell surface receptors. Syndecan-3 is an integral membrane heparan sulfate proteoglycan that is highly expressed by the distal mesodermal cells of the chick limb bud that are undergoing proliferation and outgrowth in response to the AER. Here we report that maintenance of high-level syndecan-3 expression by the subridge mesoderm of the chick limb bud is directly or indirectly dependent on the AER, since its expression is severely impaired in the distal mesoderm of the limb buds of limbless and wingless mutant embryos which lack functional AERs capable of directing the outgrowth of limb mesoderm. We have also found that exogenous FGF-2 maintains a domain of high-level syndecan-3 expression in the outgrowing mesodermal cells of explants of the posterior mesoderm of normal limb buds cultured in the absence of the AER and in the outgrowing subapical mesoderm of explants of limbless mutant limb buds which lack a functional AER. These results suggest that the domain of high-level syndecan-3 expression in the subridge mesoderm of normal limb buds is maintained by FGFs produced by the AER. Finally, we report that polyclonal antibodies against a syndecan-3 fusion protein inhibit the ability of FGF-2 to promote the proliferation and outgrowth of the posterior subridge mesoderm of limb buds cultured in the absence of the AER. These results suggest that syndecan-3 plays an essential role in limb outgrowth by mediating the interaction of FGFs produced by the AER with the underlying mesoderm of the limb bud.

Perspective: a suggested role for basement membrane structures during newt limb regeneration

BACKGROUND

Interactions between epithelium and mesenchyme, which occur across a basement membrane (BM) zone, are essential to generate a growth bud, or blastema, from which a new limb regenerates. An intact BM at that interface is believed to inhibit regeneration, but that mechanism of inhibition is not understood.

METHODS

Interference contrast microscopy and antibodies to laminin have been used to describe reformation of the BM and the basal lamina (BL) and their relationships to wound epithelium and mesenchyme in successive stages of blastema formation.

RESULTS

The BL is initially absent from the amputation surface and is reestablished to continuity by the late bud stage of regeneration. It forms generally from base to apex, precedes reticular lamina (RL) formation, and is absent beneath most of the wound epithelium. Our inability to correlate mesenchymal cell accumulation exclusively with the area lacking BL apically and postaxially prompted rethinking of the significance of the BL.

CONCLUSIONS

Consistent with these and other observations, we suggest that the BL, when it forms during blastema formation, appears to function as in other developing systems to stabilize the phenotype of adjacent cells. Thus, epithelium becomes epidermis and adjacent mesenchyme synthesizes RL and becomes dermis. Accordingly, the feature that distinguishes regenerating from nonregenerating appendages is the ability of regenerating appendages to delay BL closure until after a critical mass of mesenchymal cells has accumulated.

Extracellular matrix modifications in the interdigital spaces of the chick embryo leg bud during the formation of ectopic digits

In previous studies we have observed that the interdigital mesenchyme of the chick leg bud, in the stages preceding the onset of cell death, retains a significant regulatory potential, forming ectopic extra digits under a variety of surgical manipulations. Most evidence suggests that interdigital extra digits are caused by the abolition of local antichondrogenic effects operating in the interdigital spaces under normal conditions rather than by modifications of the signalling mechanisms accounting for the normal patterning of the digits in early stages of development. The interdigital spaces exhibit a complex scaffold of extracellular matrix with well-defined domains of spatial distribution of type I and type VI collagens, tenascin, fibronectin, laminin and elastic matrix components that have been proposed to play a role in the establishment of the non-chondrogenic fate of the interdigital tissue in situ. In an attempt to analyze this possible role of the interdigital extracellular matrix (ECM), in the present work we have studied changes in the pattern of ECM distribution associated with the formation of extra digits. Extra digits were induced by making a T-cut in the third interdigital space of the leg but of stage 29 HH chick embryos. Subsequent modifications of the ECM were detected immunohistochemically in whole-mount specimens using laser confocal microscopy. Our results reveal that in the first hours after the operation, changes in the ECM apparently related to the healing of the wound cause a significant reorganization of the normal ECM scaffold of the interdigit. In addition, chondrogenesis of the interdigital tissue is preceded by disappearance of elastin fibers in the interdigital mesenchyme subjacent to the wound and by an intense deposition of tenascin. Tenascin deposition and loss of the elastin fibrillar scaffold were also observed preceding chondrogenesis in fragments of interdigital tissue explanted to culture conditions. The significance of these observations in relation to the establishment of the skeletal elements of the autopodium is discussed.

IGF-I, insulin and FGFs induce outgrowth of the limb buds of amelic mutant chick embryos

IGF-I, insulin, FGF-2 and FGF-4 have been implicated in the reciprocal interactions between the apical ectodermal ridge (AER) and underlying mesoderm required for outgrowth and patterning of the developing limb. To study further the roles of these growth factors in limb outgrowth, we have examined their effects on the in vitro morphogenesis of limb buds of the amelic mutant chick embryos wingless (wl) and limbless (ll). Limb buds of wl and ll mutant embryos form at the proper time in development, but fail to undergo further outgrowth and subsequently degenerate. Wl and ll limb buds lack thickened AERs capable of promoting limb outgrowth, and their thin apical ectoderms fail to express the homeobox-containing gene Msx-2, which is highly expressed by normal AERs and has been implicated in regulating AER activity. Here we report that exogenous IGF-I and insulin, and, to a lesser extent, FGF-2 and FGF-4 induce the proliferation and directed outgrowth of explanted wl and ll mutant limb buds, which in vitro, like in vivo, normally fail to undergo outgrowth and degenerate. IGF-I and insulin, but not FGFs, also cause the thin apical ectoderms of wl and ll limb buds to thicken and form structures that grossly resemble normal AERs and, moreover, induce high level expression of Msx-2 in these thickened AER-like structures. Neither IGF-I, insulin nor FGFs induce expression of the homeobox-containing gene Msx-1 in the subapical mesoderm of wl or ll limb buds, although FGFs, but not IGF-I or insulin, maintain Msx-1 expression in normal (non-mutant) limb bud explants lacking an AER. The implications of these results to the relationships among the wl and ll genes, IGF-I/insulin, FGFs, Msx-2 and Msx-1 in the regulation of limb outgrowth is discussed.

Ectodermal stimulation of the production of hyaluronan-dependent pericellular matrix by embryonic limb mesodermal cells

Interaction of ectoderm and underlying mesoderm is essential for normal vertebrate limb morphogenesis. One of the functions of limb bud ectoderm is its influence on the composition of extracellular matrix in subectodermal mesoderm, which in turn participates in morphogenesis of this region of the limb. This matrix is highly enriched in hyaluronan, even at the time when the level of hyaluronan in the chondrogenic and myogenic regions of the limb decreases, due to secretion of a stimulatory factor by the ectoderm. In this study we show that limb bud ectoderm not only stimulates hyaluronan synthesis but induces formation of large hyaluronan-dependent, pericellular matrices around cultured limb bud mesodermal cells. The ectodermal activity is mimicked in great part by fibroblast growth factor-2 and transforming growth factor-beta, and antibodies to these proteins inhibit induction of mesodermal pericellular matrix by the ectodermal factor. It has been shown by other investigators that fibroblast growth factor-2 is produced by limb ectoderm whereas transforming growth factor-2 is produced by limb ectoderm whereas transforming growth factor-beta is present in limb mesodermal tissues. Thus we conclude that the unique properties of mesodermally produced matrix underlying limb bud ectoderm are regulated, at least in part, by ectodermal fibroblast growth factor-2, probably in concert with mesodermal transforming growth factor-beta.

Parenchymal-stromal interactions in neoplasia. Theoretical considerations and observations in melanocytic neoplasia

The paper briefly reviews the reciprocal and continuous reciprocal interactions between epithelia, mesenchyme, and extracellular matrix in the development and maintenance of organismal form in multicellular organisms in the animal kingdom and describes the progressive changes in parenchymalstromal interactions in melanocytic neoplastic development and progression. In addition to the parenchymal stromal form in non-lesional skin seven different and unique stromal patterns are described. These have been termed: 1) The stroma (diff-regress) of programmed differentiation leading to lesional regression characteristic of common nevi; 2) concentric eosinophilic fibroplasia (cef), the hallmark of precursor nevi (dyplastic nevi) with and without melanocytic nuclear atypia; 3) Fibroplasia with angiogenesis (fa) commonly seen in superficial spreading melanoma without metastic competence (SSM); 4) Lamellar fibroplasia (lf) seen in precursor nevi and melanomas with and without metastatic competence; 5) Diffuse fibroplasia with angiogenesis (dfa), 6) Narrow, uniform concentric eosinophilic fibroplasia (nucef), 7) No parenchymal-stromal interaction (nopsi); the last three being seen in the heterogeneous stroma of melanomas of the superficial spreading type with metastatic competence. The changes in neoplastic stroma proceed in concert with the changes in the parenchyma characteristic of melanocytic tumor progression.

Studies on insulin-like growth factor-I and insulin in chick limb morphogenesis

The apical ectodermal ridge (AER) promotes the proliferation and directed outgrowth of the subridge mesodermal cells of the developing limb bud, while suppressing their differentiation. Insulin-like growth factor-I (IGF-I) and its receptor are expressed by the subridge mesodermal cells of the chick limb bud growing out in response to the AER, and specific insulin receptors are present in the limb bud during its outgrowth. To study the possible roles of IGF-I and insulin in limb outgrowth, we have examined their effects on the morphogenesis of posterior and anterior portions of the distal tip of stage 25 embryonic chick wing buds subjected to organ culture in serum-free medium in the presence or absence of the AER and limb ectoderm. The distal mesoderm of control posterior explants lacking an AER or all limb ectoderm ceases expressing IGF-I mRNA, exhibits little or no proliferation, fails to undergo outgrowth, and rapidly differentiates. Exogenous IGF-I and insulin promote the outgrowth and proliferation and suppress the differentiation of distal mesodermal cells in posterior explants lacking an AER or limb ectoderm, thus mimicking at least to some extent the outgrowth promoting and anti-differentiative effects normally elicited on the subridge mesoderm by the AER. Furthermore, IGF-I and insulin-treated posterior explants exhibit high IGF-I mRNA expression, indicating that IGF-I and insulin maintain the expression of endogenous IGF-I by the subridge mesoderm. We have also found IGF-I and insulin can affect the morphology and activity of the AER. When the posterior portion of the wing bud tip is cultured with the AER intact in control medium, on day 4-5 the AER flattens, ceases expressing high amounts of the AER-characteristic homeobox-containing gene Msx2, and concomitantly an elongated cartilaginous element differentiates in the subridge mesoderm. In contrast, in the presence of exogenous IGF-I or insulin the AER of such explants does not flatten, continues expressing high amounts of Msx2, and the subridge mesoderm remains undifferentiated and proliferative. Thus, exogenous IGF-I and insulin maintain the thickness of the AER and sustain its expression of Msx2, while sustaining the anti-differentiative effect normally elicited on the subridge mesoderm by a thickened functional AER. Notably, we have also found that exogenous IGF-I and insulin induce the formation of a thickened ridge-like structure that expresses high amounts of Msx2 from the normally thin distal anterior ectoderm of the limb bud, while promoting dramatic outgrowth and proliferation of the anterior mesoderm, which normally undergoes little outgrowth or proliferation.(ABSTRACT TRUNCATED AT 400 WORDS)

Influence of digits, ectoderm, and retinoic acid on chondrogenesis by mouse interdigital mesoderm in culture

We have cultured tissues isolated from the interdigital zones (IDZ) of the mouse footplate in the presence of the digits, ectoderm, and all-trans retinoic acid. The objective was to understand how these various factors influence the developmental fate of the interdigital tissues. Neutral red staining showed that these tissues normally differentiate by dying between day 12.5-14.5. However, if they were isolated from the footplate between day 12.5-13.5 (when cell death is not overtly obvious in the IDZ) and maintained in organ culture, these tissues would develop into cartilage and soft connective tissues. In culture, chondrogenesis is initiated very rapidly in the interdigital explants as revealed by in situ hybridization with riboprobes specific for type IIA and IIB procollagen mRNAs. The ability of interdigital tissues to form cartilage is not attributed to factors present in the serum of the culture medium as this phenomenon is also observed in serumless cultures. We have found that if all-trans retinoic acid, at concentrations of 10-50 ng/ml culture medium, were added to the explants it could inhibit chondrogenesis and promote cell death. Moreover, in some of the cultures, a single digit was left attached to the interdigital tissue. This also dramatically reduced the incidence of chondrogenesis. We have tried to determine whether the digits and ectoderm can produce a diffusible factor that can prevent cartilage from developing by culturing day 12.5 interdigital tissues in ectoderm and digit conditioned media. The ectoderm conditioned medium had no effects on interdigital growth or chondrogenesis. In contrast, the size of interdigital explants cultured in the presence of digit conditioned medium was shown to be significantly smaller than the control. These explants also produced a smaller quantity of cartilage as revealed by Alcian blue binding assay. In sum, our results showed that the fate of the interdigital tissues are not fully determined until after day 13.5. These tissues have the potentials to form cartilage and soft connective tissues. We tentatively propose that these interdigital tissues do not normally realize their histogenetic potentials because of the antichondrogenic influence of the digits and retinoic acid.

Elastin exhibits a distinctive temporal and spatial pattern of distribution in the developing chick limb in association with the establishment of the cartilaginous skeleton

In this work we have analyzed the presence of elastic components in the extracellular matrices of the developing chick leg bud. The distributions of elastin and fibrillin were studied immunohistochemically in whole-mount preparations using confocal laser microscopy. The association of these constituents of the elastic matrix with other components of the extracellular matrix was also studied, using several additional antibodies. Our results reveal the transient presence of an elastin-rich scaffold of extracellular matrix fibrillar material in association with the establishment of the cartilaginous skeleton of the leg bud. The scaffold consisted of elastin-positive fibers extending from the ectodermal surface of the limb to the central cartilage-forming regions and between adjacent cartilages. Fibrillin immunolabeling was negative in this fibrillar scaffold while other components of the extracellular matrix including: tenascin, laminin and collagens type I, type III and type VI; appeared codistributed with elastin in some regions of the scaffold. Progressive changes in the spatial pattern of distribution of the elastin-positive scaffold were detected in explant cultures in which one expects a modification in the mechanical stresses of the tissues related to growth. A scaffold of elastin comparable to that found in vivo was also observed in high-density micromass cultures of isolated limb mesodermal cells. In this case the elastic fibers are observed filling the spaces located between the cartilaginous nodules. The fibers become reoriented and attach to the ectodermal basal surface when an ectodermal fragment is located at the top of the growing micromass. Our results suggest that the formation of the cartilaginous skeleton of the limb involves the segregation of the undifferentiated limb mesenchyme into chondrogenic and elastogenic cell lineages. Further, a role for the elastic fiber scaffold in coordinating the size and the spatial location of the cartilaginous skeletal elements within the limb bud is also suggested from our observations.

Enhancement of avian mandibular chondrogenesis in vitro in the absence of epithelium

The roles of mandibular epithelium in chondrogenesis and growth of mandibular mesenchyme were examined in organ cultures. Epithelium and mesenchyme were separated from the mandibular arches of chick embryos at stages before and after the onset of chondrogenesis in vivo (stages 18-28). Isochronic and heterochronic tissue recombinations were prepared. Removal of the mandibular epithelium resulted in reduced growth of the explants and enhanced chondrogenesis, resulting in increased levels of mRNAs for type II collagen and aggrecan. The presence of mandibular epithelium promoted cell division in loosely arranged undifferentiated tissue from the mandibular mesenchyme and resulted in increased levels of type I collagen mRNA. Enhanced chondrogenesis was also observed in the mesenchyme isolated with basement membrane and isolated mesenchyme grown within Matrigel. These findings suggest that mandibular epithelium has mitogenic and chondrogenic-inhibitory effects on the underlying mesenchyme that are stage independent. Furthermore, the chondrogenic-inhibitory effect of mandibular epithelium on the underlying mesenchymal cells is not mediated by basement membrane.

Distribution of FGF-2 suggests it has a role in chick limb bud growth

We developed and characterized antibodies specific for FGF-2 and used them to locate FGF-2 during chick embryo development. A series of micrographs demonstrated the progression of FGF-2 staining during development of the different tissues and organs. FGF-2 was present in the ectoderm covering the entire embryo, muscle cells, nervous system, neural crest cells, and mesonephros. FGF-2 was also present in the limb from initiation of budding through differentiation. The limb ectoderm and subjacent mesoderm showed the strongest immunostaining, with lower levels in the center of the bud. However, the distribution of FGF-2 positive cells in the mesoderm was not homogeneous. This heterogeneity was not due to cell cycle specific distribution of FGF-2 protein, as flow cytometric analysis showed that FGF-2-positive cells were distributed throughout the cell cycle. However, the amount of anti-FGF-2 fluorescence varied most during G1, consistent with the possibility that FGF-2 is low after M phase and increases during G1. A bioassay was used to demonstrate FGF-2 levels in the wing ectoderm were approximately 2.7-fold greater than in the mesoderm. We propose that the location of FGF-2 in the embryo is consistent with a role in epithelial-mesenchymal interactions; in the limb bud it may prevent differentiation and permit limb outgrowth and subsequent expression of patterning events.

Selective expression of the chicken platelet-derived growth factor alpha (PDGF alpha) receptor during limb bud development

Platelet-derived growth factor (PDGF) affects proliferation and differentiation of chicken limb bud mesoderm in vitro. However, no PDGF receptor has been characterized in the chicken wing bud in vivo. In this study, we used reverse transcription PCR (rtPCR), Northern blot analysis, and Western blot analysis to identify a molecule, in the developing wing bud, which represents the chicken homolog of the PDGF alpha receptor. The chicken PDGF alpha receptor mRNA was present in both mesoderm and ectoderm and all stages of the developing limb bud examined. Cultured limb bud mesoderm also expressed the PDGF alpha receptor transcript. In addition, the PDGF alpha receptor protein was present in whole limb buds and cultured limb bud mesoderm. Expression of the PDGF alpha receptor in cultured mesoderm was independent of the presence of ectoderm cells. The relative sizes of both the mRNA and protein for the PDGF alpha receptor in the chicken limb bud were similar to mammalian counterparts. Using similar approaches, neither the mRNA nor protein representing the chicken homolog of the PDGF beta receptor was detected. These data demonstrate for the first time that a PDGF alpha receptor is present in the embryonic chicken limb bud and may help regulate growth and differentiation of the embryonic limb.

Histogenetic potential of rat hind-limb interdigital tissues prior to and during the onset of programmed cell death

The histogenetic potential of interdigital tissues isolated from the autopod of rat embryonic hind-limbs between 14.5 and 16.5 days was investigated. A wedge of tissue containing ectoderm and mesoderm was excised from between the developing digits and grafted beneath the kidney capsule of adult rats for two weeks. We have previously demonstrated that the renal capsule is an excellent site for permitting limb tissues to proliferate and differentiate (Chan et al.: J. Exp. Zool., 260:74-83, 1991). At 14.5 days, when cell death (revealed with neutral red stains) within the interdigital zone was limited to the apical ectodermal ridge (AER), the interdigital mesoderm was capable of developing into bone, cartilage, and loose connective tissue in the kidney. It was estimated that the skeletal elements occupied approximately 38% of the overall area of the grafts. In addition, the ectoderm was able to produce keratinized epithelium, hair follicles, and sebaceous glands. In 15.5 day autopod, necrosis was present both in the AER and the mesoderm between the AER and marginal sinus. Interdigital mesoderm obtained from this stage of development formed cartilage but not as extensively as that derived from 14.5 day autopod (4% as compared with 38%). Necrotic cells were present in all of the interdigital zones at 16.5 days. Ten explants were introduced into the kidney at this stage, but only 4 grafts were recovered after 2 weeks. In all cases, the explants did not produce cartilage. Only a small amount of keratinized epithelium and loose connective tissue was found. In summary the interdigital mesoderm has the potential to develop bone, cartilage, and loose connective tissue, but this ability is progressively lost during morphogenesis.

Maintenance of ZPA signaling in cultured mouse limb bud cells

The positional signal localized to the posterior (zone of polarizing activity or ZPA) region of the vertebrate limb is transiently expressed during development and a decline in ZPA signaling is accelerated when posterior cells are dissociated and cultured in vitro. The evidence that cultured posterior cells display a precocious decline in ZPA signaling when compared to in vivo studies suggests that a factor present in the limb bud maintains or stabilizes ZPA signaling during limb outgrowth and that this maintenance factor is lost and/or exhausted in in vitro studies. We have developed a new culture technique, ‘microdissociation’, which preserves extracellular components that we have found to be necessary for ZPA signal maintenance. Our data suggest that the limb bud ectoderm produces a maintenance activity that becomes stored in the extracellular matrix where it acts on limb bud cells to stabilize the activity of the ZPA signal. Using our initial characterization of this maintenance activity, we have identified a growth factor, FGF-2 (bFGF), that can replace all of the ZPA signaling maintenance activity observed in microdissociate cultures. The existence of various members of the FGF family in the developing limb strongly argues a role for FGF in stabilizing ZPA signaling in vivo.

The expression pattern of the chicken homeobox-containing gene GHox-7 in developing polydactylous limb buds suggests its involvement in apical ectodermal ridge-directed outgrowth of limb mesoderm and in programmed cell death

The limb buds of the polydactylous mutant embryos, talpid2 and diplopodia-5, possess expanded distal apexes surmounted by prolongated thickened apical ectodermal ridges that promote the outgrowth and formation of digits from both the anterior and posterior mesoderm of the mutant limb buds. The chicken homeobox-containing gene GHox-7 exhibits an expanded domain of expression throughout the expanded subridge mesoderm of the mutant limb buds, providing support for the hypothesis that GHox-7 expression by subridge mesenchymal cells is involved in the outgrowth-promoting effect of the apical ectodermal ridge. During normal limb development GHox-7 is also expressed by the mesoderm in the proximal anterior nonchondrogenic periphery of the limb bud, which includes, but is not limited to the anterior necrotic zone. GHox-7 is also expressed in the posterior necrotic zone at the mid-proximal posterior edge of the limb bud. In contrast, GHox-7 is not expressed in either the proximal anterior or posterior peripheral mesoderm of talpid2 and diplopodia-5 limb buds which lack proximal anterior and posterior necrotic zones. Furthermore, retinoic acid-coated bead implants, which diminish cell death in the anterior necrotic zone, elicit a local inhibition of GHox-7 expression in the proximal anterior peripheral mesoderm. These results support the suggestion that GHox-7 may be involved in defining regions of programmed cell death during limb development. Furthermore, these studies indicate that the distal subridge and proximal anterior nonchondrogenic mesodermal domains of GHox-7 expression are independently regulated.

Expression of Hox-7.1 in myoblasts inhibits terminal differentiation and induces cell transformation

The terminal differentiation of myogenic cells initiates in the proximal portion of the limb bud whereas the distal region remains undifferentiated and proliferative. The apical ectodermal ridge maintains the progress zone in an undifferentiated state and induces proliferation of limb mesenchymal cells. Hox-7.1, a homeobox-containing gene, is expressed throughout the limb bud when limb outgrowth begins, whereas transcripts are later restricted to distal limb mesenchyme which is the proposed site of positional specification. Transplantation of proximal limb bud tissue into the distal portion of the limb results in a re-expression of Hox-7.1 in the transplanted mesenchyme. Similar grafts result in a positional reassignment to distal structures as well as de-differentiation of the grafted proximal tissue. Because of the association of Hox-7.1 expression with proliferative and undifferentiated cells, we tested whether Hox-7.1 regulates differentiation by transfection of Hox-7.1 complementary DNA into determined myogenic cells which represent one mesenchymal lineage in the limb. Here we report that forced expression of Hox-7.1 blocks terminal differentiation and results in a corresponding decrease in steady-state levels of MyoD1. Consistent with the association of Hox-7.1 with proliferation, Hox-7.1-expressing cells also acquire a transformed phenotype. Forced expression of Hox-8.1, a related Hox-gene, does not affect terminal differentiation indicating that the effects of Hox-7.1 are specific.

Two distal-less related homeobox-containing genes expressed in regeneration blastemas of the newt

Urodeles, like the newt, are able to replace their limbs and tail following amputation by the formation of a blastema, a mass of proliferating mesenchymal cells originating from the tissue adjacent to the cut surface. As this capacity may involve genetic control, we investigated in adult tissues the expression of genes controlling embryonic development. We screened a newt cDNA library with a redundant oligonucleotide specific to the highly conserved third helix of the DNA-binding domain of homeobox genes. Five classes of cDNA have been isolated. We report the nucleotide sequence and the tissue distribution of two of them, NvHBox-4 and NvHBox-5. The amino acid sequences of both homeodomains are highly homologous (83 and 87% identity) to distal-less, a Drosophila homeobox gene expressed during the development of appendages. NvHBox-4 and NvHBox-5 express respectively 2.8 and 2 kb transcripts. The pattern of expression of both genes is identical in adult tissues of the newt. Polyadenylated transcripts are detectable in the forelimbs, hindlimbs, the tail, flank, and brain as well as in limb and tail blastemas. Analysis of dissected tissue from the hindlimbs indicated that the expression of both genes is restricted to the skin. This work is a first step toward understanding the possible relation between sustained expression of homeobox-containing genes in adult newt tissues and regeneration potential.

Transforming growth factor beta 1 is an epithelial-derived signal peptide that influences otic capsule formation

Interactions between epithelial and mesenchymal tissues in the developing inner ear direct the formation of its cartilaginous capsule. Recent work indicates that many growth factors are distributed in the early embryo in vivo in a temporal-spatial pattern that correlates with sites of ongoing morphogenetic events. We report here that the localization of transforming growth factor beta 1 (TGF-beta 1) in both epithelial and mesenchymal tissues of the mouse inner ear between 10 and 16 days of embryonic development (E10-E16). In addition, utilizing a high-density culture system as an in vitro model of otic capsule chondrogenesis, we show that modulation of chondrogenesis by TGF-beta 1 in cultured mouse periotic mesenchyme mimics the in vitro effects of otic epithelium on the expression of chondrogenic potential. We provide evidence of a causal relationship of this growth factor to otic capsule formation in situ by demonstrating that the actual sequence of chondrogenic events that occur in the developing embryo is reproduced in culture by the addition of exogenous TGF-beta 1 peptide. Furthermore, in cultures of mesenchyme containing otic epithelium, we demonstrate the localization of endogenous TGF-beta 1, first within the epithelial tissue and later within both the epithelium and its surrounding periotic mesenchyme, contrasted to an absence of endogenous TGF-beta 1 in cultures of mesenchyme alone. Our results suggest that TGF-beta 1 is one of the signal molecules that mediate the effects of otic epithelium in influencing the formation of the cartilaginous otic capsule.

Molecular aspects of regeneration in developing vertebrate limbs

We review embryological as well as molecular evidence that emphasizes the idea that both the regenerate and the developing vertebrate limb bud utilize a similar set of signals that regulate pattern formation. Evidence is presented to implicate the Hox-7.1 gene in the developmental regulation of growth, differentiation, and positional assignment during limb outgrowth and the proposal is made that the expression of this gene governs the cellular activities within the progress zone during limb outgrowth. Finally, we review the limited information known about the regenerative capabilities of limb buds in organisms that cannot regenerate as adults. We content that a solution to the problem of regenerative failure among higher vertebrates will come progressively through a stepwise analysis of impaired regeneration associated with increasing developmental age.

Sequential induction of syndecan, tenascin and cell proliferation associated with mesenchymal cell condensation during early tooth development

The cell surface proteoglycan, syndecan, and the extracellular matrix glycoprotein, tenascin, are expressed in the mesenchyme during early development of many organs. We have studied the expression patterns of syndecan and tenascin during initiation of tooth development and in association with mesenchymal cell condensation and compared these with cell proliferation. Syndecan, tenascin and bromodeoxyuridine (BrdU) incorporation were localized by triple-labelling immunohistochemistry in serial sections of molar tooth germs of mouse embryos. Prior to formation of the epithelial tooth bud, syndecan accumulated in the mesenchymal cells which underlie the presumptive dental epithelium, but tenascin was not detected at this stage. Tenascin appeared during initiation of the epithelial down-growth at the lingual aspect of the tooth germ. During subsequent formation of the epithelial bud, at the late bud stage, syndecan and tenascin became exactly colocalized in the condensed mesenchyme which was clearly demarcated from other jaw mesenchyme. The expression of syndecan and tenascin was accompanied by rapid cell proliferation as indicated by marked BrdU incorporation. When development advanced to the cap stage, syndecan staining intensity in the dental papilla mesenchyme increased further whereas tenascin became reduced. In conclusion, the results demonstrate that the expression patterns of syndecan and tenascin overlap transiently during the period of mesenchymal cell condensation and that this is accompanied by cell proliferation. Syndecan and tenascin may play a role in growth control and in compartmentalization of the dental mesenchymal cells in the condensate.

Interdigital chondrogenesis and extra digit formation in the duck leg bud subjected to local ectoderm removal

In the chick embryo the interdigital tissue in the stages previous to cell death exhibits in vitro a high chondrogenic potential, and forms extra digits when subjected in vivo to local ectodermal removal. In the present work we have analyzed the chondrogenic potential both in vivo and in vitro of the interdigital mesenchyme of the duck leg bud. As distinct from the chick, the interdigital mesenchyme of the duck leg bud exhibits a low degree of degeneration, resulting in the formation of webbed digits. Our results show that duck interdigital mesenchyme exhibits also a high chondrogenic potential in vitro until the stages in which cell death starts. Once cell death is finished chondrogenesis becomes negative and the interdigital mesenchyme forms a fibroblastic tissue. In vivo the interdigital mesenchyme of the duck leg bud subjected to ectoderm removal forms ectopic foci of chondrogenesis with a range of incidence similar to that in the chick. Unlike those of the chick the ectopic cartilages of the duck are rounded and smaller, and appear to be located at the distal margin of the interdigital mesenchyme. Formation of extra digits in the duck occurs with a lower incidence than in the chick. It is concluded that ectopic chondrogenesis and formation of extra digits is related to the intensity of interdigital cell death. The non-degenerating interdigital mesenchymal cells destined to form the interdigital webs of the duck appear to contribute very little to the formation of interdigital cartilages.

The pattern of expression of the chicken homolog of HOX1I in the developing limb suggests a possible role in the ectodermal inhibition of chondrogenesis

Homeobox-containing genes have been implicated in a variety of patterning events during vertebrate limb development. In an attempt to isolate cDNAs corresponding to 5' members of the chicken HOX 4 cluster of homeobox-containing genes, a cDNA library constructed from mRNAs expressed during early stages of chick limb development was screened with probes generated by the polymerase chain reaction (PCR) using oligonucleotide primers corresponding to sequences in the homeoboxes of the human HOX4C and HOX4F genes, the human homologs of Hox-4.4 and Hox-4.6. This screening resulted in the isolation of full length cDNAs for the chicken homolog of HOX4F (cognate of mouse Hox-4.6), which we have termed GHox-4.6, and the chicken homolog of human HOX1I, which we have named GHox-1i, a paralog of Hox-4.6 in the HOX 1 cluster. The homeodomains encoded by GHox-4.6 and GHox-1i differ by only three amino acids, and the two proteins show extensive similarity along their entire lengths. Despite their sequence similarity, in situ hybridization analysis has revealed that GHox-4.6 and GHox-1i exhibit strikingly different spatial patterns of expression during embryonic chick limb development. At early stages of limb development (stages 20-22), GHox-4.6 transcripts are present in high amounts throughout the posterior half of the limb mesoderm and are absent from the anterior half of the mesoderm, an expression pattern consistent with the possible involvement of GHox-4.6 in the specification of posterior positional identity. In contrast, GHox-1i exhibits no distinct anterior-posterior polarity of expression at stage 22, but rather is expressed in high amounts throughout the mesenchyme of the limb bud. At later stages of development (stage 25), GHox-1i continues to be expressed in high amounts throughout the undifferentiated mesenchyme subjacent to the apical ectodermal ridge, and, in addition, is expressed in the mesodermal cells in the proximal peripheral regions of the limb bud subjacent to the ectoderm which are differentiating into nonchondrogenic lineages. Conversely, little or no expression of GHox-1i is detectable in the proximal central core of the limb bud where chondrogenic differentiation is occurring. Thus, GHox-1i is expressed by the undifferentiated subridge mesenchymal cells and proximal peripheral mesenchymal cells of the limb bud that are being inhibited from undergoing chondrogenesis by the apical ectodermal ridge and nonridge ectoderm.(ABSTRACT TRUNCATED AT 400 WORDS)

A variant limb deformity transcript expressed in the embryonic mouse limb defines a novel formin

The formins constitute a set of protein isoforms encoded by the alternatively spliced transcripts arising from the limb deformity (ld) locus of the mouse. Mutations in this locus disrupt formation of the anteroposterior axis of the embryonic limb. Although ld transcripts are widely expressed during embryogenesis, we have identified a novel transcript that is expressed in the mesenchyme and apical ectodermal ridge of the developing limb. This pattern of expression coincides with the earliest morphological defects observed in ld mutant limb buds. Moreover, the formin encoded by this transcript bears a highly acidic amino terminus, as distinguished from the basic amino terminus encoded by other ld transcripts suggesting that it may have a distinct biochemical function.

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.

Promotion of embryonic limb cartilage differentiation in vitro by staurosporine, a protein kinase C inhibitor

Phorbol 12-myristate 13-acetate (PMA), a protein kinase C-activating phorbol ester, is known to inhibit chondrogenic differentiation by embryonic limb mesenchyme cells in vitro. The present study demonstrates that staurosporine, a potent inhibitor of protein kinase C, conversely stimulates cartilage differentiation in cultures of limb mesenchyme cells isolated from whole wing buds of stage 23/24 chick embryos or from the distal subridge region of stage 25 wing buds. In high density micromass cultures, in which limb mesenchyme cells undergo extensive spontaneous cartilage differentiation, exposure to 5-20 nM staurosporine promotes an accelerated accumulation of type II collagen and cartilage proteoglycan mRNA transcripts and a 2- to 3-fold increase in matrix glycosaminoglycan deposition. Even in low density, monolayer cultures in which the mesenchymal cells do not normally form cartilage, treatment with 5 nM staurosporine induces extensive Alcian blue-positive matrix production, a striking 4- to 18-fold rise in sulfated glycosaminoglycan accumulation, and a dramatic elevation of cartilage-characteristic gene transcript expression. Moreover, concurrent treatment with staurosporine overcomes the inhibitory effects of PMA on in vitro limb cartilage differentiation. The results suggest the hypothesis that protein kinase C might function as a negative modulator of chondrogenic differentiation during embryonic limb development.

Gap junctional communication during limb cartilage differentiation

The onset of cartilage differentiation in the developing limb bud is characterized by a transient cellular condensation process in which prechondrogenic mesenchymal cells become closely apposed to one another prior to initiating cartilage matrix deposition. During this condensation process intimate cell-cell interactions occur which are necessary to trigger chondrogenic differentiation. In the present study, we demonstrate that extensive cell-cell communication via gap junctions as assayed by the intercellular transfer of lucifer yellow dye occurs during condensation and the onset of overt chondrogenesis in high density micromass cultures prepared from the homogeneous population of chondrogenic precursor cells comprising the distal subridge region of stage 25 embryonic chick wing buds. Furthermore, in heterogeneous micromass cultures prepared from the mesodermal cells of whole stage 23/24 limb buds, extensive gap junctional communication is limited to differentiating cartilage cells, while the nonchondrogenic cells of the cultures that are differentiating into the connective tissue lineage exhibit little or no intercellular communication via gap junctions. These results provide a strong incentive for considering and further investigating the possible involvement of cell-cell communication via gap junctions in the regulation of limb cartilage differentiation.

Epithelial control of periotic mesenchyme chondrogenesis

Morphogenesis of the cartilaginous otic capsule is directed by interactions between the epithelial anlage of the membranous labyrinth (otocyst) and its associated periotic mesenchyme. Utilizing a developmental series of high-density (micromass) cultures of periotic mesenchyme to model capsule chondrogenesis, we have shown that the early influence of otic epithelium in cultures of 10.5- or 14-gestation day (gd) periotic mesenchyme results in initiation or suppression of chondrogenesis, respectively. Furthermore, we have shown that introduction of otic epithelium at two distinct times during in vitro development to cultures of 10.5-gd mesenchyme cells results first in an initiation and then in an inhibition of their chondrogenic response. These influences of epithelial tissue on chondrogenic differentiation by periotic mesenchyme are not tissue specific but are characterized by temporal selectivity. The ability of otic epithelium to influence chondrogenesis and the competence of the periotic mesenchyme to respond to its signals are dependent upon the developmental stage of both tissues. This study provides conclusive evidence that otic epithelium acts as a developmental "switch" during otic capsule morphogenesis, signaling first the turning on and then the turning off of chondrogenic programs in the responding cephalic mesenchyme.

Fibroblast growth factor and culture in monolayer rescue mesoderm cells destined to die in the developing avian wing

In an effort to elucidate control mechanisms for developmentally programmed cell death, conditions were sought that rescue the cells destined to die. Three areas of mesodermal cell death in the chick wing were examined: the posterior necrotic zone (PNZ), the opaque patch (OP), and apical mesoderm. The PNZ and OP are areas of normally programmed cell death, whereas the apical mesoderm undergoes cell death only after the overlying apical ectodermal ridge is excised. Cell death in vitro was quantitated using the chromium-release assay. While these tissues undergo apparently normal cell death in organ culture, in monolayer culture almost all are rescued. In addition, the cells are rescued by the addition of fibroblast growth factor to organ cultures. Since fibroblast growth factor is present in decreasing amounts in the limb at this stage of development, normal cell death may occur upon withdrawal of growth factor.

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.