Onset of troponin synthesis in the chick wing bud.

Indirect antibody labeling techniques were used to determine when cells in the chick embryo wing bud begin to synthesize troponin. Frozen sections of stage 22 through stage 27 wing buds were treated with antibodies to the troponin complex and fluorescein-labeled antiimmunoglobulin. Cells producing detectable quantities of troponin were found first in late stage 24 or early stage 25 wing buds; all wing buds stage 25 and older contained labeled cells. Cells synthesizing troponin were initially localized in the muscle-forming areas of the wing bud nearest to the body wall. As the wing bud developed, cells located in more distal areas of the wing bud became labeled with fluorescent antibody, and the number of cells engaged in troponin synthesis increased in all areas. At all stages in which labeling occurred, some cells contained fluorescent cross-striations. When placed in the context of recent studies on the appearance of myofibrillar proteins, these results indicate that myogenic cells in the chick limb bud begin to synthesize large quantities of troponin at approximately the same time as the other muscle contractile proteins.     

Separation of the myogenic and chondrogenic progenitor cells of undifferentiated limb mesenchyme

Undifferentiated limb bud mesenchyme consists of at least two separate, possibly predetermined, populations of progenitor cells, one derived from somitic mesoderm that gives rise exclusively to skeletal muscle and one derived from somatopleural mesoderm that gives rise to the cartilage and connective tissue of the limb. In the present study, we demonstrate that the inherent migratory capacity of myogenic precursor cells can be used to physically separate the myogenic and chondrogenic progenitor cells of the undifferentiated limb mesenchyme at the earliest stages of limb development. When the undifferentiated mesenchyme of stage 18/19 chick embryo wing buds or from the distal subridge region of stage 22 wing buds is placed intact upon the surface of fibronectin (FN)-coated petri dishes, a large population of cells emigrates out of the explants onto the FN substrates and differentiates into an extensive interlacing network of bipolar spindle-shaped myoblasts and multinucleated myotubes that stain with monoclonal antibody against muscle-specific fast myosin light chain. In contrast, the cells of the explants that remain in place and do not migrate away undergo extensive cartilage differentiation. Significantly, there is no emigration of myogenic cells out of explants of stage 25 distal subridge mesenchyme, which lacks myogenic progenitor cells. Myogenic precursor cells stream out of mesenchyme explants in one or occasionally two discrete locations, suggesting they are spatially segregated in discrete regions of tissue at the time of its explantation. There are subtle overall differences in the morphologies of the myogenic cells that form in stage 18/19 and stage 22 distal subridge mesenchyme explants. Finally, groups of nonmyogenic nonfibroblastic cells which are fusiform-shaped and oriented in distinct parallel arrays characteristically are found along the periphery of stage 18/19 wing mesenchyme explants. Our observations provide support for the concept that undifferentiated limb mesenchyme consists of independent subpopulations of committed precursor cells and provides a system for studying the early determinative and regulatory events involved in myogenesis or chondrogenesis.     

On the role of the connective tissue in the patterning of the chick limb musculature

Summary By modifying the temporal relationship between connective tissue and myogenic cell invasion during early limb bud development new evidence of the organizing role of the connective tissue was obtained.Muscle cell-deprived wing buds were allowed to grow up to stages 22 to 27 of Hamburger and Hamilton, when they received a transplant of quail myogenic cells (somitic mesoderm or wing premuscular mass) into the dorsal face of their presumptive upper arm. Muscular arrangement in forearm and hand was analyzed 4 days later. In 8 out of 14 of those cases which had received a graft of premuscular mass before stage 25 of Hamburger and Hamilton, muscle development took place distally to the graft-site in accordance with the wing segment.     

The independence of myogenesis and chondrogenesis in micromass cultures of chick wing buds

Micromass cultures prepared from stage 23, 24, or 25 chick wing buds and cultured under identical conditions produce similar numbers of myoblasts. After treatment with the DNA synthesis inhibitor cytosine-1-beta-D-arabinofuranoside, [3H]thymidine labeling and autoradiography of the cultures show that the increase in myoblast number during the first 48 hr of culture is due primarily to cell division. Micromass cultures prepared from proximal and distal portions of stage 23 or 24 wing buds have very different chondrogenic potentials in vitro (B.J. Swalla, E.M. Owens, T.F. Linsenmayer, and M. Solursh (1983). Dev. Biol. 97, 59-69) but a similar myogenic potential under these culture conditions. Medium supplements that significantly enhance chondrogenesis by proximal cell cultures, such as low serum or 1 mM db cyclic AMP, do not affect the number of myoblasts per unit area of culture during the first 3 days. Muscle cells are eventually reduced in number in whole limb micromass cultures, yet persist as long as 6 days in proximal and distal cultures. These results suggest that myogenic cells are already committed in the early limbs but are inhibited from differentiation in situ until a later time. Myogenesis and chondrogenesis occur independently in culture, consistent with the idea that these two differentiated cells are derived from two separate cell populations. Furthermore, treatments which enhance chondrogenesis do not act indirectly by killing the myoblast population in these cultures.     

A comparative study of myogenic cell invasion of the avian wing and leg bud.

The borders of myogenic cell invasion of avian wing and leg buds were determined using the interspecific grafting technique between quail and chick embryos. Distal parts of quail limb buds were grafted ectopically into the coelomic cavity of chick embryos. The presence or absence of skeletal muscle was investigated in histological sections of the reincubated grafts. A comparison between the borders of myogenic cell invasion of the wing and leg buds showed that the differences in the position of the distal most muscles in the adult avian limbs could be a consequence of the cranio-caudal sequence of development.     

Vital labelling of somite-derived myogenic cells in the chicken limb bud

Summary In order to understand how myogenic cells migrate in the limb bud, it is indispensable to distinguish undifferentiated myogenic cells from other mesenchymal cells. Thus, a suitable method for this purpose has been sought. A method to exchange the somites of a chicken and a quail microsurgically has widely been used, since the nuclei of the two species are morphologically distinguishable. However, microsurgery is accompanied by disturbances at the operated locus, and introducing cells of different species might induce unexpected effects. We report a new method for labelling chicken myogenic cells without transplantational operations, and describe their migration pattern in limb buds. Injection of a fluorescent carbocyanine dye into the somite lumen intensely labelled the somitic cells. Myogenic cells derived from the somite were clearly detected in limb buds. Before stage 20, the labelled cells were diffusely distributed in the proximal region of the limb bud. At about stage 21 in both wing and leg buds, labelled cells began to form dorsal and ventral masses. The label was followed until the cells differentiated and expressed myosin. This vital labelling method has advantages over the somite transplantation method: it does not include surgical operations that may disturb the normal development, and the cells are labelled intensely enough to be detected in a whole mount preparation. Offprint requests to: K. Hayashi     

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

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

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.     

Spatial analysis of limb bud myogenesis: Elaboration of the proximodistal gradient of myoblasts requires the continuing presence of apical ectodermal ridge

Myogenic tissue from embryonic chick wing and leg buds is composed of several subpopulations of myoblasts. These clonally distinct subpopulations first appear at different developmental stages, and are distributed differently along the proximo-distal axis of the buds, giving the appearance of a gradient of myoblast cell types. This myoblast distribution pattern has been utilized to investigate the dependence of muscle tissue outgrowth and development on the presence of the apical ectodermal ridge (AER). Wing buds which have had the AER removed at stages 17–18 (2 days) subsequently develop normal proximal regions, but fail to elaborate skeletal structures distal to the humerus. The myoblast pattern of operated buds is also normal proximally, but distal portions of the pattern are not observed. Removal of the AER at stage 20 (3 days) results in buds which develop slightly more distal skeletal structures and the coinciding portions of the myoblast pattern, but in which the more distal portions of the normal myoblast gradient are truncated. These data suggest that elaboration of the myogenic pattern in early limb buds is dependent on the continuing presence of the AER, and that early removal of the AER leads to the subsequent cessation of myoblast pattern specification.     

Temporal and spatial expression of a position specific antigen, AV-1, in chick limb buds

In a previous study, we demonstrated the presence of a position-specific antigen (AV-1) in chick limb buds at an early developmental stage. Here, we reported the temporal and spatial expressions and the biochemical characterization of the AV-1 antigen. Indirect immunofluorescence staining and immunoblot analysis clearly showed that the AV-1 antigen is a glycoprotein that is localized on the plasma membrane and that it is expressed from stage 19 and highly expressed at stages 22-26 in some middle-distal to anterior-distal region of limb buds. In the wing bud, at stage 28, the AV-1 antigen was faintly detected in the restricted space between the precartilaginous regions of the radius and the ulna, and those of the metacarpals 2 and 3, but not those of the metacarpals 3 and 4. Such stage-specific and "position-specific" expressions of the AV-1 antigen in limb buds strongly suggest that the AV-1 antigen or cells containing it are involved in determination of the limb pattern formation.     

Clonal analysis of vertebrate myogenesis. VIII. Fibroblasts growth factor (FGF)-dependent and FGF-independent muscle colony types during chick wing development

The effect of bovine fibroblast growth factor (FGF) on the in vitro differentiation of various stage-specific populations of skeletal muscle colony-forming (MCF) cells from the developing chick wing bud was examined. The results show that bovine FGF (3 ng/ml daily) delays the onset of differentiation of MCF cells obtained from Day 4-12 wing buds by about 1 day; but, in addition, the results demonstrate that a subset of colony-forming cells derived from stage 23-27 (Day 4-5) embryos require FGF for myogenic differentiation. The FGF-dependent MCF cells attach and grow in the absence of FGF, but do not differentiate unless given FGF within 1-3 days after inoculation. Thus, between stages 23 and 27 the myogenic population contains discrete subclasses that are FGF dependent and others that are FGF independent. Both subclasses are found within two of the previously classified MCF cell populations, the early and late MCF cells. FGF-dependent and independent early MCF cells are present within the wing bud until stage 25, after which only the FGF-independent early MCF subclass persists. Similarly, both FGF-dependent and -independent late MCF cells are present between stages 25 and 27, but only the FGF-independent late MCF subclass remains after stage 31. The mechanisms responsible for relative changes in the proportions of MCF cell subclasses and for the FGF requirements are not understood. In addition, while FGF is required, there is no evidence suggesting that FGF triggers skeletal muscle terminal differentiation within the FGF-dependent MCF cell subclasses.     

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.     

Inhibitory and stimulatory effects of limb ectoderm on in vitro chondrogenesis

Previous studies have indicated possible dual effects of the limb ectoderm in cartilage differentiation. On one hand, explants from early (stage 15) wing buds are dependent on contact with the limb ectoderm for cartilage differentiation (Gumpel-Pinot, J. Embryol. Exp. Morph. 59:157-173, 1980). On the other hand, limb ectoderm from stage 23/24 wing buds inhibits cartilage differentiation by cultured limb mesenchyme cells even without direct contact (Solursh et al., Dev. Biol. 86:471-482, 1981). In the present study, ectoderms from both stage 15/16 and stage 23/24 wings are cultured under the same conditions, and ectoderms from each source are shown to have two effects. Each stimulates chondrogenesis in stage 15 wing bud mesenchyme, and each inhibits chondrogenesis in older wing mesenchyme. The results suggest that the limb ectoderm has at least dual effects on cartilage differentiation, depending on the stage of the mesenchyme. One effect involves an early mesenchymal dependence on the ectoderm. This effect requires contact between the ectoderm and mesoderm (Gumpel-Pinot, J. Embryol. Exp. Morphol. 59:157-173, 1980) but also can be observed at a distance from the ectoderm. Later, the ectoderm can act without direct contact between the ectoderm and mesoderm to inhibit chondrogenesis over some distance.     

Analysis of type II collagen RNA localization in chick wing buds by in situ hybridization

Type II collagen is a major component of cartilage extracellular matrix. Differentiation of mesenchyme into cartilage involves the cessation of type I collagen synthesis and the onset of type II collagen synthesis. Solution hybridization of mRNA isolated from chick limb buds with a cDNA probe to type II collagen mRNA showed the presence of small amounts of type II collagen message in mesenchymal chick limbs. We have examined the localization of type II collagen mRNA in mesenchymal chick wing buds by in situ hybridization using single stranded RNA probes. Our results show a small but detectable amount of type II collagen RNA distributed uniformly in early limbs until the first precartilage condensations form at stage 22. This is interesting because it is known that mesenchyme isolated from chick wing buds has the capacity to undergo chondrogenesis in culture, even if taken from nonchondrogenic areas of the limb. At stage 23, type II collagen mRNA is found at significantly increased levels in the cells of the precartilage condensation when compared to the other limb cells. As chondrogenesis proceeds, the amount of type II collagen RNA increases even more in cells of the cartilage elements. The signal in the peripheral tissue is indistinguishable from background. These results show that type II collagen message exists at low levels in cells throughout the mesenchymal chick wing bud, until the formation of the condensation results in an elevation of type II mRNA in the prechondrogenic cells found in the core of the limb.     

Hyaluronic acid influences the migration of myoblasts within the avian embryonic wing bud.

Myoblasts migrate in a proximodistal direction within the avian embryonic wing bud during normal limb development. Since the presence and distribution of hyaluronic acid within the wing bud coincide with the time and with the direction of the migration of myoblasts, we microinjected hyaluronic acid into chicken wing buds that had received grafts containing quail myoblasts. It was found that injected hyaluronic acid has a strong positive effect on the migration of myoblasts: it causes a migration of myoblasts in donor-host combinations in which this is normally not the case, and it can cause migration in a proximal direction, a phenomenon not observed during normal development. From this it may be concluded that hyaluronic acid can influence myoblast migration in vivo. A similar effect could be observed after the microinjection of dextran sulfate, a synthetic compound having similar physicochemical properties. Hyaluronic acid, therefore, may play an important role in the control of the migration of myogenic cells in vivo by its physiocochemical properties.