Migratory and organogenetic capacities of muscle cells in bird embryos

Summary The migratory and organogenetic capacities of muscle cells at different stages of differentiation were tested in heterospecific chick/quail recombinants. Grafts containing muscle cells were taken from the premuscular masses from 4- to 5-day quail embryos, from the limb or trunk muscles of 12-day embryonic and 4-day post-natal quails, and from experimentally produced bispecific premuscular masses in which the myoblasts are of quail origin and the connective tissue cells of chick origin. Grafts were implanted into 2-day chick embryos in place of the somitic mesoderm at the limb level. Hosts were examined 4 to 7 days after operation.After implantation of a piece of premuscular mass, quail cells were found at and around the site of the graft in the truncal region and within the limb as far as the autopod. Quail cells participated predominantly in the trunk and limb musculature, which contained a number of quail myotubes and of bispecific quail/chick myotubes. Apart from skeletal muscles, quail cells contributed sporadically to nerve envelopes and blood vessel walls in the limb.When the graft was of bispecific constitution, quail nuclei in the limb and the trunk were found exclusively in monospecific and bispecific myotubes.After implantation of differentiated embryonic or post-natal muscle tissue, quail cells in the limb contributed only sporadically to nerve envelopes and blood vessel walls, while in the trunk they also participated in the formation of muscles and tendons.It is concluded that the myogenic cells in 4 to 5-day quail premuscular masses are still able to undergo an extensive migration into the limb buds and there participate in the formation of myotubes and anatomically normal muscles. They display developmental potentialities equivalent to those of the somitic myogenic stem cells. These capacities are lost in 12-day embryonic muscles.     

Cellular retinoic acid binding protein type II was preferentially localized in medium and posterior parts of the progress zone of the chick limb bud.

The expression and distribution of cellular retinoic acid binding protein II (CRABP II) was examined in chick limb buds. CRABP II was detected in the limb buds at Hamburger and Hamilton (1) stage 21 and the amount of CRABP II was gradually increased during stages 21-27 and thereafter decreased. CRABP II was mainly located in the progress zone, and the dorsal and ventral premuscular mass in the proximal region of the limb buds at stage 23. CRABP II was preferentially localized in the medium and posterior parts rather than the anterior part of the progress zone; The content of CRABP II in the medium and posterior parts was 8-9 times more than that in the anterior part.     

Ontogeny of avian extrinsic ocular muscles

Summary Light- and electron-microscopic studies were performed on those tissues that are supposed to deliver the anlagen of the extrinsic ocular muscles. Since the blastemata of the ocular muscles can be traced back into the prechordal mesoderm, it can be concluded that this tissue is the source of these muscles. In embryos from stage 8–10 according to Hamburger and Hamilton (HH) cells are found to detach from the lateral border of the prechordal mesoderm. These cells are assumed to give rise to the trochlearis and abducens musculature. In stage-14 embryos the paired premandibular cavity arises within the lateral wings of the prechordal mesenchyme. In 4-day embryos the lateral wall of each premandibular cavity becomes denser forming a premuscular mass, which is subdivided into the anlagen of the oculomotorius muscles in 5-day embryos. The head cavities are not homologous to somites because their structures, origins and sites are very different.This work was supported by a grant from the Deutsche Forschungsgemeinschaft (CH 44/6-1).This paper is dedicated to Prof. Dr. med. Dr. h.c. Hermann Voss on the occasion of his 90th birthday.     

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.     

Invited review: mesenchymal progenitor cells in intramuscular connective tissue development

The abundance and cross-linking of intramuscular connective tissue contributes to the background toughness of meat, and is thus undesirable. Connective tissue is mainly synthesized by intramuscular fibroblasts. Myocytes, adipocytes and fibroblasts are derived from a common pool of progenitor cells during the early embryonic development. It appears that multipotent mesenchymal stem cells first diverge into either myogenic or non-myogenic lineages; non-myogenic mesenchymal progenitors then develop into the stromal-vascular fraction of skeletal muscle wherein adipocytes, fibroblasts and derived mesenchymal progenitors reside. Because non-myogenic mesenchymal progenitors mainly undergo adipogenic or fibrogenic differentiation during muscle development, strengthening progenitor proliferation enhances the potential for both intramuscular adipogenesis and fibrogenesis, leading to the elevation of both marbling and connective tissue content in the resulting meat product. Furthermore, given the bipotent developmental potential of progenitor cells, enhancing their conversion to adipogenesis reduces fibrogenesis, which likely results in the overall improvement of marbling (more intramuscular adipocytes) and tenderness (less connective tissue) of meat. Fibrogenesis is mainly regulated by the transforming growth factor (TGF) β signaling pathway and its regulatory cascade. In addition, extracellular matrix, a part of the intramuscular connective tissue, provides a niche environment for regulating myogenic differentiation of satellite cells and muscle growth. Despite rapid progress, many questions remain in the role of extracellular matrix on muscle development, and factors determining the early differentiation of myogenic, adipogenic and fibrogenic cells, which warrant further studies.     

Immunohistological study of the expression of glucagon in dorsal pancreatic endoderm in the early chick embryo

An immunohistological study demonstrated that glucagon first appears in the dorsal pancreatic endoderm of the chick embryo at stage 16 of Hamburger and Hamilton during normal development. It was also shown that the self-differentiation potency of the isolated dorsal endoderm to express glucagon in vitro in the absence of adjoining tissues appears at stage 11.     

Teratogenic effects of retinoic acid and dimethylsulfoxide on embryonic chick wing and somite

In order to document the stage(s) at which the embryonic chick wing bud is sensitive to vitamin A teratogenesis and the kinds of defects produced by vitamin A insult to the embryonic chick wing, 1-microgram doses of retinoic acid (1 microliter RA in 90% DMSO at a concentration of 1 microgram/microliter) were locally applied to the right wing bud of chick embryos at stages 17-23 (Hamburger and Hamilton: J. Morphol., 88:49-92, '51), and the resulting limb skeleton anatomy was observed at 10 days of incubation. Local application of RA at stages 17-20 resulted in distal wing skeleton defects. There were significantly more wing skeleton defects among embryos treated at these stages with RA solution than among solvent (DMSO)-treated control embryos and than among untreated control embryos. Wings of embryos treated with RA at stages 21-23 were always normal. Scapular and vertebral defects were seen at 10 days of incubation among embryos which had been treated prior to stage 21 with both the RA solution and the solvent control. Statistical analysis and histological data suggest that scapular and vertebral defects were caused by DMSO-induced damage to somites.     

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.     

Attempt to produce a chick/mouse heteroclass musculature

Summary Heteroclass chick/mouse chimaeras were prepared by transplanting somitic presumptive myogenic cells or limb bud myoblasts from donor mouse embryos into chick hosts, to replace (1) previously extirpated brachial somitic mesoderm or (2) experimentally deleted limb premuscular masses. Since mouse and chick cells can be distinguished by differential staining affinities, this parameter was used to verify the viability of the implant and to assess its fate. Our analyses showed that transplanted mouse somitic myogenic stem cells or limb bud myoblasts did not participate in the host brachial musculature, whatever the experimental conditions.     

The spatial pattern and temporal sequence in which feather germs arise in the white Leghorn chick embryo

Feather germs arise in a specific sequence and spatio-temporal pattern within each of 10 feather areas on the White Leghorn chick embryo. The time of feather germ initiation was determined by histological and gross macroscopic analyses. Protruding feather germs are sequentially visualized in the dorsal, thigh, breast, head, humoral, ventral, wing, eye, and external auditory meatus feather areas, respectively, from stage 31- to stage 39+ [V. Hamburger and H.L. Hamilton (1951) J. Morphol. 88, 49-92]. The rate at which successive feather tracts appear was found to differ for different feather areas and was not simply due to the size of a feather area. Feather germ histogenesis was examined in the dorsal, thigh, breast, ventral, wing, and tail feather areas. The stages of feather germ histogenesis, examined on the wing feather area, are similar to those previously described for the dorsal surface. Gross and histological analyses gave different times and temporal sequences of feather germ visualization. Some feather areas were readily visualized at the time of feather germ initiation, while others showed a lag between the histological appearance of feather germs and their macroscopic visualization. Thus, macroscopic observations do not accurately reflect the pattern of histogenesis.     

Early in-vitro histological chondral differentiation.

In vitro chondrogenesis is possible in the chick embryo from stage 4 of Hamburger and Hamilton (1951), only 18-19 hours of incubation, before somite formation. In stage 4 of Hamburger and Hamilton (1951) the chondroblasts are placed laterally to the primitive streak and notochord cells are not necessary for cartilage differentiation.     

The distal boundary of myogenic primordia in chimeric avian limb buds and its relation to an accessible population of cartilage progenitor cells

Using chimeras consisting of chick embryos that had received substitution grafts of quail somites, we have determined the distalmost extension of the myogenic primordia in the outgrowing wing bud at 5 days of incubation. At Hamburger-Hamilton stage 25 the most distal premuscle cell is consistently 300 mum or more from the apex of the wing mesoblast. The stage 25 wing tip resembles very early whole limb buds in not having proceeded beyond the mesenchymal state or having expressed markers of terminal differentiation. However, unlike early whole limb buds it is free of a myogenic subpopulation. We therefore propose that the stage 25 wing tip is the appropriate system for in vitro and molecular studies of cartilage differentiation.     

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.     

Effect of cyclic nucleotides on the morphogenetic and ultrastructural characteristics of the primitive knot in the chick embryo in organotypic cultures

The isolated Hensen's nodes of chick embryos (stage 4 after Hamburger and Hamilton) were cultivated in organotypic cultures after the treatment with 0.5 mM solutions of cAMP and cGMP. Both the control and treated explants were characterized by a wide variability of differentiation of various tissue rudiments. cGMP inhibited reliably the differentiation of notochord. At the ultrastructural level the control and cAMP-treated cultures were characterized by an increased autophagia whereas the treatment with cGMP inhibited the yolk utilization and resulted in the appearance of vast regions of partial necrosis.     

Diversification of Cardiomyogenic Cell Lineages in Vitro

The ability of undifferentiated cardiogenic mesoderm to generate diversified myogenic phenotypes was assayed in a minimal culture system. During cardiogenesis in vivo, the anterior and posterior segments of the avian heart have distinct patterns of contractile protein gene expression when they first differentiate. To assess the potential of undifferentiated cardiogenic tissue to diversify into distinct anterior and posterior lineages prior to heart formation, cardiogenic mesoderm and endoderm were removed together from the embryo at Hamburger and Hamilton stages 4-8. Explants from each of these stages differentiated in defined medium as indicated by the expression of muscle-specific genes. However, the ability to express the atrial-specific myosin heavy chain (AMHC1) mRNA was confined to posterior cardiac progenitors. Diversification was not dependent on anterior endoderm, suggesting that inductive interactions between the mesoderm and endoderm are not necessary to maintain diversified cardiac lineages after stage 4. The diversified potential of explanted cardiogenic tissue was altered with retinoic acid treatment, resulting in the activation of AMHC1 gene expression in the anterior progenitors. Anterior cardiogenic cells removed from the embryo at stage 8, when the heart begins to differentiate in vivo, are not susceptible to the alteration of diversified phenotype by retinoic acid treatment. Therefore, the potential to form distinct cardiomyogenic cell lineages is present in the anterior lateral plate mesoderm soon after gastrulation and the maturation of these lineages in a positionally dependent manner is maintained in a simple defined culture system in vitro.     

The relationship of the zone polarizing activity to supernumerary limb formation (twinning) in the chick wing bud.

The role of the polarizing zone mesoderm in development of supernumerary distal wing parts after 180° rotation of the wing tip was investigated. Postaxial mesoderm with and without polarizing tissue was repositioned preaxially in the wing bud and duplications occurred only when polarizing zone tissue was included. When the polarizing zone was removed and the distal tip of the wing reoriented, no duplication resulted. Similarly when the polarizing zone was removed, the distal tip reoriented and postaxial, nonpolarizing mesoderm introduced to restore the tissue mass of the stump, no twinning occurred. However, with the distal aspect reoriented on a stump from which postaxial, nonpolarizing mesoderm was removed, twinning occurred in 92.9% of the cases. Further, when the polarizing zone was removed, the distal aspect reoriented and a small piece of polarizing tissue returned, twinning resulted in 93.5% of the cases. These results indicate that polarizing zone tissue is required for the twinning that results after 180° rotation of the wing tip.