The metameric pattern of the head mesoderm — does it exist?

It is a long-standing question whether the paraxial head mesoderm of vertebrate embryos is segmentally organized into somites like the trunk or not. On the one hand, no somites are seen in the anterior head mesoderm in vertebrate embryos, on the other hand, such a segmental pattern has been described under the name of somitomeres. In order to investigate the patterning of mesodermal cells in the head of avian embryos we performed scanning electron microscopy, computer assisted reconstructions of the head mesoderm and density analyses of head mesoderm cells. We observed regional differences within the head mesoderm of avian embryos, but we could not see a consistent somitomeric pattern in the head mesoderm. In sum, we consider that the avian head mesoderm is not arranged in a metameric pattern.     

Amniote somite derivatives.

Somites are segments of paraxial mesoderm that give rise to a multitude of tissues in the vertebrate embryo. Many decades of intensive research have provided a wealth of data on the complex molecular interactions leading to the formation of various somitic derivatives. In this review, we focus on the crucial role of the somites in building the body wall and limbs of amniote embryos. We give an overview on the current knowledge on the specification and differentiation of somitic cell lineages leading to the development of the vertebral column, skeletal muscle, connective tissue, meninges, and vessel endothelium, and highlight the importance of the somites in establishing the metameric pattern of the vertebrate body.     

On the histogenetic potency of the tailhud mesoderm

Summary The caudalmost part of the tailbud mesoderm (terminal paraxial tailbud mesoderm) does not develop into somites. It is not clear whether this terminal paraxial tailbud mesoderm can be considered to be a part of the segmental plate. To elucidate the nature of the tailbud mesoderm, grafts containing caudal somites, caudal prospective somitic mesoderm and the terminal paraxial tailbud mesoderm were grafted from quail embryos into the wing bud mesoderm of chick embryos. The distinct nuclear difference between quail and chick allows the identification of the grafts on a cellular level. The grafts containing caudalmost somites and the prospective somitic mesoderm differentiate into muscle and cartilage. The terminal paraxial tailbud mesoderm, on the other hand, did not give rise to either of these tissues. From this it can be concluded that the terminal paraxial tailbud mesoderm cannot be considered to be a part of the segmental plate.     

Characterization of two amphioxus Wnt genes (AmphiWnt4 and AmphiWnt7b) with early expression in the developing central nervous system.

Full-length sequences and developmental expression patterns of two amphioxus Wnt genes (AmphiWnt4 and AmphiWnt7b) are described for the first time. The dynamic expression pattern of AmphiWnt4 suggests roles in the development of the posterior mesoderm, central nervous system, muscular somites, heart, and endostyle (a homolog of the vertebrate thyroid). The less diverse expression domains of AmphiWnt7b indicate that this gene may be involved only in the development of the central nervous system and the endostyle. In contrast to amphioxus, vertebrate embryos do not express Wnt4 homologues in the posterior mesoderm, somites, or heart; instead, Wnt genes of other subfamilies are expressed in these developing vertebrate organs. Because the developmental genetic programs of amphioxus may approximate those in the invertebrate chordate ancestor of the vertebrates, it is possible that some developmental functions of an ancestral Wnt4 gene may have been assumed by genes of other Wnt subfamilies during vertebrate evolution, possibly as a result of functional redundancy among Wnt subfamilies.     

Emergence of the endothelial network during embryonic development]

The avian model provides an experimental approach for dissecting the origin, migrations, and differentiation of cell lineages in early embryos. In this model, the endothelial network was shown to stem from both the somites and the splanchnopleural mesoderm. The somite line age produces only endothelial cells, whereas the splanchnopleural line age also produces hematopoietic stem cells. Potentialities of the mesoderm are determined by a positive influence from the endoderm and a negative influence from the ectoderm. A novel mode of blood-borne angiogenesis is also described.     

Signals that instruct somite and myotome formation persist in Xenopus laevis early tailbud stage embryos

Somite formation is a lengthy process that begins at gastrulation and continues through tailbud stages to form approximately 50 pairs of somites in the frog, Xenopus laevis. In Xenopus, the somite primarily gives rise to myotome. We sought to determine whether the formation of somites and myotome requires a transient signal active during gastrulation or a constitutive signal active throughout development to instruct dorsal mesodermal cells to form the posterior somites. Previous work from our lab revealed that cells from the neural ectoderm are capable of responding to mesoderm-inducing signals [Domingo and Keller: Dev Biol 2000;225:226-240]. Thus, to test for the presence of somite-inducing signals, we performed a series of grafting experiments in which we used gastrula cells from the anterior neural ectoderm (ANE). Fluorescently labeled ANE cells were grafted to the posterior paraxial mesoderm of progressively older host embryos between stages 11 (mid gastrula) and 23 (early tailbud). Our results showed that signals within the paraxial mesoderm can instruct prospective ANE cells, which normally give rise to head structures, to instead differentiate into myotome cells. We found that the grafted cells adopted the local paraxial mesoderm cell behaviors, which consists of mediolateral intercalation, segmentation, somite cell rotation, and differentiation to myotome. In addition, we show that the grafted ANE cells that adopt a myotome morphology also express the muscle-specific marker, 12/101. Through a series of heterochronic grafts, we determined that the duration of somite-inducing signals extends from the early gastrula (stage 11) through the early tailbud (stage 23) stage embryos. These results demonstrate that somite induction is not a transient event that occurs during gastrulation, but that it is instead a continuous event that can occur as new somites are added to the posterior axis.     

Positional control of mesoderm movement and fate during avian gastrulation and neurulation.

Segments of primitive streak from donor quail embryos at stages of gastrulation and neurulation were transplanted heterotopically and isochronically to primitive streaks of host chick embryos. The subsequent movement and fate of grafted cells was determined using the quail nucleolar marker to define grafted cells. The pattern of movement of grafted cells depended on their new position within the primitive streak, not on their original position. When cells of cranial regions were placed more caudally, they moved to mesodermal subdivisions that were located lateral to those they would have populated if left in their original position. When caudal segments were placed more cranially, they moved to more medial mesodermal subdivisions. Whether the fate of grafted cells corresponded to their original location or their new location depended on both their level of origin and their new position. Cells from heterotopically transplanted Hensen's nodes, which migrated to the somitic and more lateral mesoderm, self-differentiated notochords. Similarly, in some cases, heterotopically transplanted prospective somitic cells, which migrated to lateral plate mesoderm, formed ectopic somites. In other cases, however, grafted cells contributed to the host's somites, intermediate mesoderm, and lateral plate mesoderm. Moreover, prospective somitic cells, which migrated to the extraembryonic lateral plate mesoderm, changed their fate and formed extraembryonic lateral plate mesoderm; and prospective lateral plate mesoderm cells, which migrated to the somitic mesoderm, formed somites as well as intermediate mesoderm and lateral plate mesoderm.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the differentiation and origin of myoid cells in the avian thymus

Summary The avian thymus and its myoid cells were investigated paying special attention to the developmental and morphological differences between chick and quail.By means of light- and electron microscopy, and immunofluorescence technique using an anti-myosin antibody, the myoid cells were found to express characteristics corresponding to those of skeletal muscle cells. They change their appearance during embryonic development. In the chick the myoid cells become located singly and rounded, and their cross-striation disappears. In the quail they remain small, elongated, cross-striated, and become arranged in long cords.The origin of myoid cells was studied using the quailchick marking technique: Cranial somites and the prechordal mesoderm were grafted from quail into chick embryos. After somite transplantation the host thymus does not contain graft-derived cells. The myoid cells are exclusively derived from the chick. After implantation of prechordal mesoderm, graft-derived quail cells are found in the central cores of all visceral arches and also within the early epithelial anlage of chimeric thymus. These findings indicate that the thymus myoid cells are derived from the axially located prechordal head mesoderm.Supported by the Deutsche Forschungsgemeinschaft (Ch 44/8-1)