Early stages of chick somite development

We report on the formation and early differentiation of the somites in the avian embryo. The somites are derived from the mesoderm which, in the body (excluding the head), is subdivided into four compartments: the axial, paraxial, intermediate and lateral plate mesoderm. Somites develop from the paraxial mesoderm and constitute the segmental pattern of the body. They are formed in pairs by epithelialization, first at the cranial end of the paraxial mesoderm, proceeding caudally, while new mesenchyme cells enter the paraxial mesoderm as a consequence of gastrulation. After their formation, which depends upon cell-cell and cell-matrix interactions, the somites impose segmental pattern upon peripheral nerves and vascular primordia. The newly formed somite consists of an epithelial ball of columnar cells enveloping mesenchymal cells within a central cavity, the somitocoel. Each somite is surrounded by extracellular matrix material connecting the somite with adjacent structures. The competence to form skeletal muscle is a unique property of the somites and becomes realized during compartmentalization, under control of signals emanating from surrounding tissues. Compartmentalization is accompanied by altered patterns of expression of Pax genes within the somite. These are believed to be involved in the specification of somite cell lineages. Somites are also regionally specified, giving rise to particular skeletal structures at different axial levels. This axial specification appears to be reflected in Hox gene expression. MyoD is first expressed in the dorsomedial quadrant of the still epithelial somite whose cells are not yet definitely committed. During early maturation, the ventral wall of the somite undergoes an epithelio-mesenchymal transition forming the sclerotome. The sclerotome later becomes subdivided into rostral and caudal halves which are separated laterally by von Ebner's fissure. The lateral part of the caudal half of the sclerotome mainly forms the ribs, neural arches and pedicles of vertebrae, whereas within the lateral part of the rostral half the spinal nerve develops. The medially migrating sclerotomal cells form the peri-notochordal sheath, and later give rise to the vertebral bodies and intervertebral discs. The somitocoel cells also contribute to the sclerotome. The dorsal half of the somite remains epithelial and is referred to as the dermomyotome because it gives rise to the dermis of the back and the skeletal musculature. The cells located within the lateral half of the dermomyotome are the precursors of the muscles of the hypaxial domain of the body, whereas those in the medial half are precursors of the epaxial (back) muscles. Single epithelial cells at the cranio-medial edge of the dermomyotome elongate in a caudal direction, beneath the dermomyotome, and become anchored at its caudal margin. These post-mitotic and muscle protein-expressing cells form the myotome. At limb levels, the precursors of hypaxial muscles undergo an epithelio-mesenchymal transition and migrate into the somatic mesoderm, where they replicate and later differentiate. These cells express the Pax-3 gene prior to, during and after this migration. All compartments of the somite contribute endothelial cells to the formation of vascular primordia. These cells, unlike all other cells of the somite, occasionally cross the midline of the developing embryo. We also suggest a method for staging somites according to their developmental age.     

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.     

Participation of individual brachial somites in skeletal muscles of the avian distal wing

In this paper we investigate the somitic origin of the individual muscles of the forearm and hand using quail-chick chimeras. Our results show that only somites 16–21 give rise to wing muscle, but they take part in muscle formation to different extents. Somite 21 does not always participate in the formation of muscle of the forearm and hand. The most cranial somite (16) takes part in the radial muscles and the most caudal somites (20, 21) in the ulnar muscles, reflecting their position with respect to the limb bud. The centrally located somites (17, 18, 19) are involved in all (18) or most (17, 19) muscle primordia. This pattern of distribution is clearest in the forearm, whereas the participation of somites in particular muscle groups is not so distinct in the hand. Hand muscles are mainly made up of cells from somites 18–20. All brachial somites participate in dorsal (extensor) as well as ventral (flexor) muscles of the forearm and hand. Each somite takes part in more than three muscle primordia in a reproducible fashion, and every muscle primordium is derived from at least three somites. Especially the M. ulnimetacarpalis ventralis takes origin from all somites involved in limb muscle formation (16–21). Apart from muscle cells, endothelial cells also and a few fibroblasts of quail origin are found in the limb bud after somite grafting.     

Pax-1 in the development of the cervico-occipital transitional zone

The Pax-1 gene has been found to play an important role in the development of the vertebral column. The cervico-occipital transitional zone is a specialized region of the vertebral column, and malformations of this region have frequently been described in humans. The exact embryonic border between head and trunk is a matter of controversy. In order to determine a possible role of Pax-1 in the development of the cervico-occipital transitional zone we studied the expression of this gene in a series of quail embryos and murine fetuses with in situ hybridization and immunohistochemistry. Pax-1 is expressed in all somites of the embryo, including the first five occipital ones. During embryonic days 3–5 the gene is down-regulated in the caudal direction within the first five somites, whereas more caudally Pax-1 is strongly expressed in the cells of the perinotochordal tube. In 5-day-old quail embryos, the cartilaginous anlage of the basioccipital bone has developed and there is no more expression of Pax-1 in this region. The fusion of the dens axis with the body of the axis also coincides with switching off of the Pax-1 gene. More caudally, the gene is continuously expressed in the intervertebral discs of murine embryos and therefore seems to be important for the process of resegmentation. Quail embryos do not possess permanent intervertebral discs. “Hyper-” or “hyposegmentation” defects may be explained by an over- or under-expression of Pax-1 during development. We also reinvestigated the border between the head and trunk in chick embryos by performing homotopical grafting experiments of the 5^th somite between chick and quail embryos. Grafted quail cells formed mainly the caudal end of the basioccipital bone. They were also located in the cranial half of the ventral atlantic arch, and only a few cells were found in the tip of the dens axis.     

New experimental evidence for somite resegmentation

According to the concept of resegmentation, the boundaries of vertebrae are shifted one half a segment compared with somite boundaries. This theory has been experimentally confirmed by interspecific transplantations of single somites. Due to the difficulty of exactly orientating individual somites in the host embryo, the outcome and interpretations of these experiments have occasionally been questioned. This is especially true for the formation of neural arches, their processes, and the ribs. We reinvestigated the formation of vertebrae in the avian embryo by grafting one and one half somites from quail to chick embryos. This method eliminates the possibility of a wrong somite orientation in the host embryo. Results show that the vertebral body, the neural arch and its processes are made up of material of two adjacent somites. This is also true for the rib, with the exception of the costal head, which is formed by only one somite. Whereas in the proximal part of the costal body the chick and quail cell regions border on each other in the middle of the rib, in its distal part quail cells gradually begin to mix with chick cells. The intersegmental muscles and their skeletal attachments sites are formed from the same somite. These results support and complete the data of previous studies and confirm the resegmentation concept. Accepted: 3 May 2000     

Segmentation in staged human embryos: the occipitocervical region revisited

The first seven somites, the rhombomeres, and the pharyngeal arches were reassessed in 145 serially sectioned human embryos of stages 9-23, 22 of which were controlled by precise graphic reconstructions. Segmentation begins in the neuromeres, somites and aortic arches at stage 9. The following new observations are presented. (1) The first somite in the human, unlike that of the chick, is neither reduced in size nor different in structure, and it possesses sclerotome, somitocoel and dermatomyotome. (2) Somites 1-4, unlike those of the chick, are related to rhombomere 8 (rather than 7 and 8) and are caudal to pharyngeal arch 4 (rather than in line with 3 and 4). (3) Occipital segment 4 resembles a developing vertebra more than do segments 1-3. (4) The development of the basioccipital resembles that of the first two cervical vertebrae in that medial and lateral components arise in a manner that differs from that in the rest of the vertebral column. (5) The two groups of somites, occipital 1-4 and cervical 5-7, each form a median skeletal mass. (6) An 'S-shaped head/trunk interface', described for the chick and unjustifiably for the mouse, was not found because it is not compatible with the topographical development of the otic primordium and somite 1, between which neural crest migrates without hindrance in mammals. (7) Occipital segmentation and related features are documented by photomicrographs and graphic interpretations for the first time in the human. It is confirmed that the first somite, unlike that of the chick, is separated from the otic primordium by a distance, although the otic anlage undergoes a relative shift caudally. The important, although frequently neglected, distinction between lateral and medial components is emphasized. Laterally, sclerotomes 3 and 4 delineate the hypoglossal foramen, 4 gives rise to the exoccipital and participates in the occipital condyle, 5 forms the posterior arch of the atlas and 6 provides the neural arch of the axis, which is greater in height than the arches of the other cervical vertebrae. Medially, the perinotochord and migrated sclerotomic cells give rise to the basioccipital as well as to the vertebral centra, including the tripartite column of the axis. Registration between (1) the somites and (2) the occipital and cervical medial segments becomes interrupted by the special development of the axis, the three components of which come to occupy the height of only 2 1/2 segments.     

A scanning electron microscope survey of the origin of the primordial pronephric duct cells in the avian embryo

In the avian embryo, the pronephric duct derives from the anterior part of a ridge that develops just lateral to the somites and segmental plate. The ridge extends from the sixth somite to Hensen's node and begins to form as the sixth somite is condensing. By the nine-somite stage, the cranial end of the ridge (for a length roughly equivalent to four or five somite diameters) is seen as a duct primordium of smooth, elongated cells that resemble the migrating cells of the caudal tip of the duct as it extends to the cloaca. These cells show a decreased attachment to the fibers of the interstitial matrix and an increased adhesion to other duct cells. By 10 somites, there is a well-formed pronephric duct rudiment at a time when the pronephric tubules have not yet begun to develop. Therefore, the avian pronephric duct has a separate origin from the pronephric tubules and may play an inductive role in the formation of pronephric tubules.     

Pax-1 in the development of the cervico-occipital transitional zone

The Pax-1 gene has been found to play an important role in the development of the vertebral column. The cervico-occipital transitional zone is a specialized region of the vertebral column, and malformations of this region have frequently been described in humans. The exact embryonic border between head and trunk is a matter of controversy. In order to determine a possible role of Pax-1 in the development of the cervico-occipital transitional zone we studied the expression of this gene in a series of quail embryos and murine fetuses with in situ hybridization and immunohistochemistry. Pax-1 is expressed in all somites of the embryo, including the first five occipital ones. During embryonic days 3–5 the gene is down-regulated in the caudal direction within the first five somites, whereas more caudally Pax-1 is strongly expressed in the cells of the perinotochordal tube. In 5-day-old quail embryos, the cartilaginous anlage of the basioccipital bone has developed and there is no more expression of Pax-1 in this region. The fusion of the dens axis with the body of the axis also coincides with switching off of the Pax-1 gene. More caudally, the gene is continuously expressed in the intervertebral discs of murine embryos and therefore seems to be important for the process of resegmentation. Quail embryos do not possess permanent intervertebral discs. Hyper- or hyposegmentation defects may be explained by an over- or under-expression of Pax-1 during development. We also reinvestigated the border between the head and trunk in chick embryos by performing homotopical grafting experiments of the 5^th somite between chick and quail embryos. Grafted quail cells formed mainly the caudal end of the basioccipital bone. They were also located in the cranial half of the ventral atlantic arch, and only a few cells were found in the tip of the dens axis.     

The relationship between limb muscle and endothelial cells migrating from single somite

Somites contribute myogenic and endothelial precursor cells to the limb bud. Transplantations of single somites have shown the pattern of muscle cell distribution from individual somites to individual limb muscles. However, the pattern of the endothelial cell distribution from individual somites to the limb has not been characterized. We have mapped quail muscle and endothelial cell distribution in the distal part of the chick limb after single somite transplantation to determine if there is a spatial relationship between muscle and endothelial cells originating from the same somite. Single brachial somites from quail donor embryos were transplanted into chick embryos, and, following incubation, serial sections were stained with a quail-endothelial cell-specific monoclonal antibody (QH-1), an anti-quail antibody (QCPN) and an anti-desmin antibody to distinguish the quail endothelial and muscle cells from chick cells. Our results show that transplants of somite 16-21 each gave rise to quail endothelial cells in the wing. The anterioposterior position of the blood vessels formed by somitic endothelial cells corresponded to the craniocaudal position of the somite from which they have originated. Endothelial cells were located not only in the peri- and endomysium but also in the subcutaneous, intermuscular, perineural and periost tissues. There was no strict correlation between the distribution of muscle and endothelial cell from a single transplanted somite. Blood vessels formed by grafted quail endothelial cells could invade the muscle that did not contain any quail muscle cells, and conversely a muscle composed of numerous quail muscle cells was lacking any endothelial cells of quail origin. Furthermore, a chimeric limb with very little quail muscle cells was found to contain numerous quail endothelial cells and vice versa. These results suggest that muscle and endothelial cells derived from the same somite migrate on different routes in the developing limb bud.     

背根神经节分节格式的形成和体节再分节

把分散的鹌鹑体节板细胞移植到鸡的体节板区。移植后１７ｈ，在移植区形成大小不等、排列杂乱的ＤＣ体节。有些体节靠近神经管，有些较靠外侧。移植后２９～３２ｈ，靠近神经管的ＤＣ体节向中壁破裂，外迁的间充质细胞在生肌节与神经管和脊索之间，形成生骨节（即原位生骨节）。每个生骨节再分为前后两半，位于外侧的ＤＣ体节，在移植后３３～３８ｈ，其侧壁或外侧壁破裂。外迁的间充质细胞在生肌节的外侧或生肌节之间，数量、大小和     

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.     

From somites to vertebral column.

We report on the development and differentiation of the somites with respect to vertebral column formation in avian and human embryos. The somites, which are made up of different compartments, establish a segmental pattern which becomes transferred to adjacent structures such as the peripheral nervous system and the vascular system. Each vertebra arises from three sclerotomic areas. The paired lateral ones give rise to the neural arches, the ribs and the pedicles of vertebrae, whereas the vertebral body and the intervening disc develop from the axially-located mesenchyme. The neural arches originate from the caudal half of one somite, whereas the vertebral body is made up of the adjacent parts of two somites. Interactions between notochord and axial mesenchyme are a prerequisite for the normal development of vertebral bodies and intervening discs. The neural arches form a frame for the neural tube and spinal ganglia. The boundary between head and vertebral column is located between the 5th and 6th somites. In the human embryo, proatlas, body of the atlas segment, and body of the axis fuse to form the axis.     

A resegmentation‐shift model for vertebral patterning

Segmentation of the vertebrate body axis is established in the embryo by formation of somites, which give rise to the axial muscles (myotome) and vertebrae (sclerotome). To allow a muscle to attach to two successive vertebrae, the myotome and sclerotome must be repositioned by half a segment with respect to each other. Two main models have been put forward: ‘resegmentation’ proposes that each half‐sclerotome joins with the half‐sclerotome from the next adjacent somite to form a vertebra containing cells from two successive somites on each side of the midline. The second model postulates that a single vertebra is made from a single somite and that the sclerotome shifts with respect to the myotome. There is conflicting evidence for these models, and the possibility that the mechanism may vary along the vertebral column has not been considered. Here we use DiI and DiO to trace somite contributions to the vertebrae in different axial regions in the chick embryo. We demonstrate that vertebral bodies and neural arches form by resegmentation but that sclerotome cells shift in a region‐specific manner according to their dorsoventral position within a segment. We propose a ‘resegmentation‐shift’ model as the mechanism for amniote vertebral patterning.     

Dynamics of zebrafish somitogenesis.

Vertebrate somitogenesis is a rhythmically repeated morphogenetic process. The dependence of somitogenesis dynamics on axial position and temperature has not been investigated systematically in any species. Here we use multiple embryo time-lapse imaging to precisely estimate somitogenesis period and somite length under various conditions in the zebrafish embryo. Somites form at a constant period along the trunk, but the period gradually increases in the tail. Somite length varies along the axis in a stereotypical manner, with tail somites decreasing in size. Therefore, our measurements prompt important modifications to the steady-state Clock and Wavefront model: somitogenesis period, somite length, and wavefront velocity all change with axial position. Finally, we show that somitogenesis period changes more than threefold across the standard developmental temperature range, whereas the axial somite length distribution is temperature invariant. This finding indicates that the temperature-induced change in somitogenesis period exactly compensates for altered axial growth.     

The rostral level of origin of sympathetic neurons in the chick embryo,studied in tissue culture

Groups of three consecutive somites from the first to the eleventh somite from chick embryos of stages 17–18 were grown in tissue culture for seven days. Sympathetic neurons, identified both by phase contrast microscopy and FIF histochemistry, occurred only in cultures which included the sixth, or more caudal, somites. If it is assumed that sympathetic precursor cells (neural crest cells) have not undergone a caudal shift prior to stages 17–18, and taking into account the loss of one or two rostral somites, then the anterior sympathetic ganglia are derived from neural crest caudal to the sixth or seventh somite Thus, the vagal zone (level with somites 1–7) contributes little to the sympathetic nervous system.     

Mitotic activity during somite segmentation in the early chick embryo

Summary The mitotic activity of the somites, segmental plate and posterior mesoderm were investigated in colchicine-treated and untreated chick embryos at st. 7-14. The mitotic figures in the somites are restricted to the proximity of the lumen and have their spindles orientated predominantly tangentially to the cavity. In the segmental plate there is no pattern in terms of the position or orientation of the mitotic spindles, but there is a single region, often found close to the cranial end of the segmental plate, with an elevated mitotic index. This may indicate a certain degree of synchrony among groups of segmental plate cells. These results are discussed in relation to the process of somite segmentation.     

Embryonic development of the house shrew (Suncus murinus)

Summary The embryonic development during the period from 1 to 12 pairs of somites was observed in an insectivore species, the house shrew (Suncus murinus), which has been bred within a closed colony. Embryos were staged by the number of somite pairs. Each stage was punctuated at every addition of three pairs of somites and numbered after the Carnegie system. The first somite became apparent between 8 and 9.0 days after fertilization, and the 12th somite appeared between 9.5 and 10.0 days. The rate of somite formation was one pair in every 3–4 h on average. The embryonic events during this period were as follows: 1. From the beginning of stage 9, the embryonic body consistently displayed a kyphosis, and as development progressed, the caudal portion of the embryo spiralled clockwise. 2. The first and second pharyngeal arches formed; their development was precocious among mammalian embryos in relation to somitic count. 3. The segmental pattern of the neural fold was similar to that of laboratory rodents and primates. The first fusion of the cranial neural folds took place in the occipital somite region, the second fusion in the diencephalic region, and the third at the end of the neural plate, thus leaving two neuropores in the cephalic region. 4. The timing of appearance of the optic sulcus was similar to that of human embryos but was delayed in comparison with that of laboratory rodents. 5. The heart always showed a more advanced state than that of other mammalian embryos. From the beginning of stage 9, an unpaired endocardial tube was seen in the bulbo-ventricular region, and deflection from a symmetrical appearance soon took place. 6. The differentiation of foregut was also precocious, and the thyroid and respiratory primordia appeared earlier than in other mammals. The present study emphasizes that there are considerable variations in timing and manner of morphogenesis among early mammalian embryos.     

Somitogenesis in cultured embryos of the Japanese quail,Coturnix coturnix japonica

The ability of unsegmented paraxial mesoderm from Japanese quail embryos to form somites was studied by culturing pieces of embryos, containing the segmental plates, on an agar medium. In the first experiments, two explants were prepared from each donor embryo. Both explants contained a segmental plate and neural tube, but only one contained notochord. The explants containing notochord formed 11.4 ± 2.1 somites, while the explants without notochord formed 11.1 ± 1.3 somites. It was concluded that explants containing Japanese quail segmental plates readily form somites in culture and that the continued presence of the notochord is not required for these somites to form. In a second series of experiments, one explant from each donor embryo contained neural tube and notochord along with the segmental plate, while the corresponding explant did not contain axial structures. The results, which were similar to those obtained in the first experiments, indicated that neither neural tube nor notochord is required for somitogenesis in vitro. Additional experiments demonstrated that bilateral symmetry extends to the unsegmented somite mesoderm, where there was a strong tendency for each segmental plate of a given embryo to form the same number of somites. It was also shown that over a three-fold range of segmental plate length, there was only a slight tendency for shorter segmental plates to make fewer somites. It was estimated that Japanese quail embryos having five to 21 pairs of somites have segmental plates that represent 11.3 ± 2.9 prospective somites each.     

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.