The ventralizing effect of the notochord on somite differentiation in chick embryos

The dorso-ventral pattern formation of the somites becomes manifest by the formation of the epithelially organized dorsal dermomyotome and the mesenchymal ventrally situated sclerotome. While the dermomyotome gives rise to dermis and muscle, the sclerotome differentiates into cartilage and bone of the axial skeleton. The onset of muscle differentiation can be visualized by immunohistochemistry for proteins associated with muscle contractility, e.g. desmin. The sclerotome cells and the epithelial ventral half of the somite express Pax-1, a member of a gene family with a sequence similarity to Drosophila paired-box-containing genes. In the present study, changes of Pax-1 expression were studied after grafting an additional notochord into the paraxial mesoderm region. The influence of the notochord and the floor-plate on dermomyotome formation and myotome differentiation has also been investigated. The notochord is found to exert a ventralizing effect on the establishment of the dorso-ventral pattern in the somites. Notochord grafts lead to a suppression of the formation and differentiation of the dorsal somitic derivatives. Simultaneously, a widening of the Pax-1-expressing domain in the sclerotome can be observed. In contrast, grafted roof-plate and aorta do not interfere with dorso-ventral patterning of the somitic derivatives.     

The development of the avian vertebral column

Segmentation of the paraxial mesoderm leads to somite formation. The underlying molecular mechanisms involve the oscillation of ”clock-genes” like c-hairy-1 and lunatic fringe indicative of an implication of the Notch signaling pathway. The cranio-caudal polarity of each segment is already established in the cranial part of the segmental plate and accompanied by the expression of genes like Delta1, Mesp1, Mesp2, Uncx-1, and EphA4 which are restricted to one half of the prospective somite. Dorsoventral compartmentalization of somites leads to the development of the dermomyotome and the sclerotome, the latter forming as a consequence of an epithelio-to-mesenchymal transition of the ventral part of the somite. The sclerotome cells express Pax-1 and Pax-9, which are induced by notochordal signals mediated by sonic hedgehog (Shh) and noggin. The craniocaudal somite compartmentalization that becomes visible in the sclerotomes is the prerequisite for the segmental pattern of the peripheral nervous system and the formation of the vertebrae and ribs, whose boundaries are shifted half a segment compared to the sclerotome boundaries. Sclerotome development is characterized by the formation of three subcompartments giving rise to different parts of the axial skeleton and ribs. The lateral sclerotome gives rise to the laminae and pedicles of the neural arches and to the ribs. Its development depends on signals from the notochord and the myotome. The ventral sclerotome giving rise to the vertebral bodies and intervertebral discs is made up of Pax-1 expressing cells that have invaded the perinotochordal space. The dorsal sclerotome is formed by cells that migrate from the dorso-medial angle of the sclerotome into the space between the roof plate of the neural tube and the dermis. These cells express the genes Msx1 and Msx2, which are induced by BMP-4 secreted from the roof plate, and they later form the dorsal part of the neural arch and the spinous process. The formation of the ventral and dorsal sclerotome requires directed migration of sclerotome cells. The regionalization of the paraxial mesoderm occurs by a combination of functionally Hox genes, the Hox code, and determines the segment identity. The development of the vertebral column is a consequence of a segment-specific balance between proliferation, apoptosis and differentiation of cells. Accepted: 25 May 2000     

The eventful somite: patterning, fate determination and cell division in the somite

The segmental somites not only determine the vertebrate body plan, but also represent turntables of cell fates. The somite is initially naive in terms of its fate restriction as shown by grafting and rotation experiments whereby ectopically grafted or rotated tissue of newly formed somites yielded the same pattern of normal derivatives. Somitic derivatives are determined by local signalling between adjacent embryonic tissues, in particular the neural tube, notochord, surface ectoderm and the somitic compartments themselves. The correct spatio-temporal specification of the deriving tissues, skeletal muscle, cartilage, endothelia and connective tissue is achieved by a sequence of morphogenetic changes of the paraxial mesoderm, eventually leading to the three transitory somitic compartments: dermomyotome, myotome and sclerotome. These structures are specified along a double gradient from dorsal to ventral and from medial to lateral. The establishment and controlled disruption of the epithelial state of the somitic compartments are crucial for development. In this article, we give a synopsis of some of the most important signalling events involved in somite patterning and cell fate decisions. Particular emphasis has been laid on the issue of epithelio-mesenchymal transition and different types of cell division in the somite.     

A segmented pattern of cell death during development of the chick embryo

Summary During the early development of the chick embryo, specific groups of cells die in characteristic patterns. In this study, Nile Blue sulphate staining was used to reveal a novel pattern of segmentally repeated cell death in the paraxial mesoderm of the chick prior to stage 23. This pattern varies according to the developmental stage of the embryo and shifts rostrocaudally, corresponding to progressing somite differentiation. Initially, during early somite differentiation, cell death is restricted to the rostral half of the somite (the rostral pattern of cell death). After the somite has differentiated into dermomyotome and sclerotome, dead cells appear in superficial tissues in a pyramidal pattern which lies in register (rostrocaudally) with the central part of the sclerotome. Finally, small bands of dying cells are seen between the neural tube and the expanding sclerotome. This third pattern (the ventral path) lies in register with the rostral part of the caudal half of the sclerotome. We show by fluorescent labelling of the migrating neural crest that these patterns of cell death correspond to the routes of neural crest migration. In addition, serial sectioning of stage 23 chick embryos confirms that the position of dying cells correlates with the known routes of neural crest migration and with the sites of development of certain neural crest-derived tissues.     

Regeneration following somite removal in chick embryos

A technique was developed for ensuring complete removal of single somites with minimal damage to surrounding tissues in 2-day-old chick embryos. Histological examination of the site of somite removal at various time intervals after operation revealed that a regeneration mechanism could be triggered. Replacement of the cells that had been removed could occur, but the extent of the replacement was dependent on the immediate fate of the gap created. If the gap was closed by enlargement of the adjacent somites, no replacement of the cells occurred. If the gap remained, then cells invaded the gap and were able to produce a normal sclerotome and dermomyotome. By labelling adjacent cells with the carbocyanine dye. DiI, it was shown that the replacement cells could come from the adjacent somites, as well as the intermediate mesoderm. Use of an antibody to HNK-1 established that the replacement cells did not come from the neural crest and that the neural crest cell distribution was little affected. Staining with peanut agglutinin showed that the replacement cells were able to adopt the characteristics associated with rostral and caudal halves of the normal sclerotome. These results provide possible explanations for the variety of vertebral anomalies produced by removal of somites and for the production of some congenital vertebral anomalies.     

Expression pattern of VEGFR-2 (Quek1) during quail development

The growth and maintenance of the blood and lymphatic vascular systems is to a large extent controlled by members of the vascular endothelial growth factor (VEGF) family via the tyrosine kinase receptors (VEGFRs) expressed in angioblastic cells. Here, we analyzed the Quek1 (VEGFR-2) expression pattern by whole mount in situ hybridization during quail development. During early embryogenesis, Quek1 expression was detected at the caudal end of the blastoderm and primitive streak and in the head paraxial mesoderm. In somites, expression was observed from HH-stage 9 onwards in the dorsolateral region of both the forming and recently formed somites. During somite maturation, expression persists in the lateral portion of the somitic compartments, the dermomyotome and the sclerotome. Additionally, a second expression domain in the maturing somite was observed in the medial part of the sclerotome adjacent to the neural tube. This expression domain extended medially and dorsally and surrounded the neural tube during later stages. In the notochord, expression was observed from HH-stage 23 onwards. In the limb bud, expression was initiated in the mesenchyme at HH-stage 17. During organogenesis, expression was detected in the pharyngeal arches and in the anlagen of the esophagus, trachea, stomach, lungs, liver, heart and gut. Expression was also seen in feather buds from day 7 onwards. Our results confirm the angiogenic potential of the mesoderm and suggest that VEGFR-2 expressing cells represent multiple pools of mesodermal precursors of the hematopoietic and angiopoietic lineages.     

Formation and differentiation of the avian dermomyotome

During somite maturation, the ventral half of the epithelial somite disintegrates into the mesenchymal sclerotome, whereas the dorsal half forms a transitory epithelial sheet, the dermomyotome, lying in between the sclerotome and the surface ectoderm. The dermomyotome is the source of most of the mesodermal tissues in the body, giving rise to cell types as different as muscle, connective tissue, endothelium, and cartilage. Thus, the dermomyotome is the most important turntable of mesodermal cell fate choice in the vertebrate embryo. Here, we discuss the current knowledge on the formation of the dermomyotome and the mechanisms leading to the development of the various dermomyotomal derivatives, with special emphasis on the development of musculature and dermis.     

Origin of the epaxial and hypaxial myotome in avian embryos

The myotome originates from the dermomyotome. Controversy surrounds the location of myotome precursor cells within the dermomyotome and their segregation from the dermomyotome. Here we addressed the problem of myotome formation by labeling dermomyotome cells using the quail-chick marking technique. We carried out five series of transplantation and replaced: (1) the medial third, (2) the intermediate third, (3) the lateral third, (4) the cranial half, (5) the caudal half of a thoracic dermomyotome. The grafting procedures were performed in HH-stages 15–17 of quail and chick embryos. The chimeras were reincubated for 2 days up to HH-stages 24–25. All of the grafted parts contributed to the myotome. The epaxial myotome is derived from the medial third of the dermomyotome, while the hypaxial myotome is formed by both the intermediate and lateral third of the dermomyotome. Ep- and hypaxial myotome domains meet in the thickest part of the myotome that is situated in the middle of its ventrolateral axis. Myotome growth in the epaxial domain begins earlier than in the hypaxial domain. Cranial and caudal edges of the dermomyotome contribute equally to both the epaxial and hypaxial myotomes. The first born myotome cells are located in the lateral part of the epaxial myotome and development then proceedes in medial and lateral directions. Accepted: 27 June 2000     

Contribution of single somites to the skeleton and muscles of the occipital and cervical regions in avian embryos

Controversy has surrounded the process of resegmentation of cervico-occipital somites. We have reinvestigated this topic by grafting single somites of quail embryos homotopically into chick embryos. Somites one to five contribute to the skull. Somites one and two contribute to the parasphenoid, which develops by direct ossification in a non-segmental fashion. All cartilaginous derivatives of the somites are segmental. Somite two forms a stripe of cells in the basioccipital, exoccipital and supraoccipital. Somites three to five give rise to the subsequent caudal parts of the basioccipital and exoccipital. Somite five forms the first motion segment including the occipital condyle, the cranial part of the atlas and the tip of the dens axis. Therefore, the border between head and neck is in the centre of somite five, and corresponds to the expression boundary of Choxb-3. Somite six forms the caudal part of the atlas and the cranial part of the axis. Somites two to eight all contribute to the cranio-cervical muscles with the exception of the Mm. rectus capitis dorsalis and ventralis and the M. biventer cervicis, which do not receive contributions from somite two. In contrast, the M. cucullaris capitis is exclusively formed by myogenic cells from somite two, which parallels its exclusive innervation by the accessory nerve. Our data confirm the segmental nature of the occiput, and show that resegmentation is a very regular process involving all except the four cranialmost somites. Except for somites one and two, all of the somites contribute to the muscles located at the appropriate levels. Accepted: 5 July 2000     

Rostro-caudal polarity in the avian somite related to paraxial segmentation

Segmental organization of the vertebrate body is one of the major patterns arising during embryonic development. Somites that play an important role in this process show intrinsic patterns of gene expression and differentiation. The somites become polarized in all three dimensions, rostrocaudal, mediolateral and dorsoventral, the quadrants giving rise to several tissue components. The timing of polarization was studied by means of antibodies against HNK-1, tenascin and neurofilament. Whole mounts and serial sections of quail and chick embryos show that somites are already polarized at the moment of their segregation from the segmental plate. The rostral hemisomite carries the HNK-1 epitope preferentially, while the caudal hemisomite stains more strongly for tenascin. HNK-1-stained areas in the segmental plate strongly relate to the notochordal sheath, suggesting that axial structures determine the fate of paraxial structures. Neural crest cells were only seen to colonize the rostral part of a somite after they had differentiated into HNK-1 positive cells. Their colonization pattern seems to be guided by the segmental organization of the somite. Moreover, this somite organization probably dictates the organization of both sensory and motor fibres converging towards the segmental dorsal root ganglia, justifying a shift in the connections between neural tube and somites. This segmental shift takes place over one quarter of a somite length in a rostral direction.     

Development of somites,muscle, and skeleton is independent of signals from the wolffian duct

Background : In the vertebrate embryo, skeletal muscle and the axial skeleton arise from the somites. Patterning of the somites into the respective somite compartments, namely dermomyotome, myotome, and sclerotome, depends on molecular signals from neighboring structures, including surface ectoderm, neural tube, notochord, and lateral plate mesoderm. A potential role of the intermediate mesoderm, notably the Wolffian or nephric duct, in somite development is poorly understood. Results : We studied somite compartmentalization as well as muscular and skeletal development after surgical ablation of the early Wolffian duct anlage, which lead to loss of the Wolffian duct and absence of the mesonephros, whereas Pax2 expression in the nephrogenic mesenchyme was temporarily maintained. We show that somite compartments, as well as the somite derivatives, skeletal muscle and the cartilaginous skeleton, develop normally in the absence of the Wolffian duct. Conclusions : Our results indicate that development of the musculoskeletal system is independent of the Wolffian duct as a signaling center. Developmental Dynamics 242:941–948, 2013. © 2013 Wiley Periodicals, Inc.     

Sonic hedgehog enhances somite cell viability and formation of primary slow muscle fibers in avian segmented mesoderm

 Primary skeletal muscle fibers first form in the segmented portions of paraxial mesoderm called somites. Although the neural tube and notochord are recognized as crucial in patterning myogenic cell lineages during avian and mammalian somitic myogenesis, the source, identities, and actions of the signals governing this process remain controversial. It has been shown that signals emanating from the ventral neural tube and/or notochord alone or Shh alone serve to activate MyoD expression in somites. However, beyond a role in initiating MyoD expression, little is known about the effects of Shh on primary muscle fiber formation in somites of higher vertebrates. The studies reported here investigate how the ventral neural tube promotes myogenesis and compare the effects of the ventral neural tube with those of purified Shh protein on fiber formation in somites. We show that purified Shh protein mimics actions of the ventral neural tube on somites including initiation of muscle fiber formation, enhancement of numbers of primary muscle fibers, and particularly, the formation of primary fibers that express slow myosin. There is a marked increase in slow myosin expression in fibers in response to Shh as somites mature. The effects of ventral neural tube on fiber formation can be blocked by disrupting the Shh signaling pathway by increasing the activity of somitic cyclic AMP-dependent protein kinase A. Furthermore, it was demonstrated that apoptosis is a dominant fate of somite cells, but not somitic muscle fibers, when cultured in the absence of the neural tube, and that application of Shh protein to somites reduced apoptosis. The block to apoptosis by Shh is a manifestation of the maturity of the somite with a progressive increase in the block as somites are displaced rostrally from somite III forward. We conclude that purified Shh protein in mimicking the effects of the ventral neural tube on segmented mesoderm can exert pleiotropic effects during primary myogenesis, including: control of the proliferative expansion of myogenic progenitor cells, antagonism of cell death pathways within the precursors to muscle fibers, and during the crucial process of primary myogenesis, can exert an effect on diversification of muscle fiber types. Accepted: 1 March 1999     

Morphological analysis of the role of the neural tube and notochord in the development of somites

The differentiation of avian somites and skeletal muscles, which themselves are derived from somites, was studied in ovo after the isolation of the unsegmented segmental plate from the notochord and/or neural tube by surgical operations at the level of the segmental plate. In each experiment, the newly formed somites had a normal histological structure, with an outer epithelial somite and core cells in the somitocoeles. Thereafter, the three derivatives of the somites (dermatome, myotome and sclerotome) reacted differently to the different operations. When the somites developed without the notochord, only somitocoele cells showed massive cell death, and muscles developed regardless of the presence or absence of the neural tube. On the contrary, no cell death was observed in any part of the somites that were formed with the neural tube or the notochord present, and muscle cells developed. However, in those embryos that retained only the notochord, striated muscles developed only in the lateral body wall. In each of the experimental operations, the surface ectoderm always covered the somites, and, regardless of the state of sclerotome and/or myotome differentiation, the dermatome always survived. These histological observations indicate that the first step in somite formation is independent of axial structures. The results further suggest that the notochord may produce diffusible factors that are necessary for the survival and further development of sclerotomal cells, and that both the neural tube and notochord can support muscle differentiation. However, it is likely that each structure has a relationship to the development of epaxial muscles and hypaxial muscles respectively. Furthermore, an intimate relationship may also exist between the surface ectoderm and the development of the dermatome.     

Kinetics and differentiation of somite cells forming the vertebral column: studies on human and chick embryos

We have studied the kinetics of somite cells with an antibody against proliferating cell nuclear antigen (PCNA/cyclin) in human and chick embryos, and with the BrdU anti-BrdU method in chick embryos, to investigate whether the metameric pattern of the developing vertebral column can be explained by different proliferation rates. Furthermore we applied antibodies against differentiation markers of chondrogenic and myogenic cells of the somites in order to study the correlation between proliferation and differentiation. There are no principal differences in the proliferation pattern of the vertebral column between human and chick embryos. In all stages examined, the cell density is higher in the caudal sclerotome halves than in the cranial halves. Laterally, the caudal sclerotome halves, which give rise to the neural arches, are characterized by a higher proliferative activity than the cranial halves. Although there is a high variability, the labelling indices show significant differences between the two halves with both proliferation markers. With the onset of chondrogenic differentiation, only the perichondrial cells retain a high proliferation rate. During fetal development, the neural arches and their processes grow appositionally. Even at the earliest stages, there is practically no immunostaining for PCNA or BrdU in the desmin-positive myotome cells of human and chick embryos. Axially, a higher proliferation rate is found in the condensed mesenchyme of the anlagen of the intervertebral discs than in the anlagen of the vertebral bodies. During fetal development, cells at the borders between vertebral bodies and intervertebral discs proliferate, indicating appositional growth. Our results show that local differences in the proliferation rates of the paraxial mesoderm exist, and may be an important mechanism for the establishment of the metameric pattern of the vertebral column in human and chick embryos.