The effect of somite manipulation on the development of motoneuron projection patterns in the embryonic chick hindlimb

Although the formation of motoneuron projections to individual muscles in the embryonic chick hindlimb has been shown to involve the specific recognition of environmental cues, the source of these cues and their mode of acquisition are not known. I show in the accompanying paper (C. Lance-Jones, 1988, Dev. Biol. 126, 394-407) that there is a correlation between the segmental level of origin of motoneurons and the somitic level of origin of the muscle cells of their targets in the chick hindlimb. These data are compatible with the hypothesis that the developmental basis for specific recognition is a positional one. Motoneurons and myogenic cells may be uniquely labeled in accord with their axial level of origin early in development and subsequently matched on the basis of these labels. To test this hypothesis, I have assessed motoneuron projection patterns in the embryonic chick hindlimb after somitic tissue manipulations. In one series of embryos, somitic mesoderm at levels 26-29 or 27-29 was reversed about the anteroposterior axis prior to myogenic cell migration and axon outgrowth. Since previous studies have shown that cells migrate from the somites in accord with their position and that somites 26-29 populate anterior thigh musculature, this operation will have reversed the somitic level of origin of anterior thigh muscles. Retrograde HRP labeling of projections to anterior thigh muscles at stage (st) 30 and st 35-38 showed that motoneuron projections were largely normal. This finding suggests that limb muscle cells or their source, the somites, do not contain the cues responsible for specific recognition prior to myogenic cell migration and axon outgrowth. To confirm that specific guidance cues were still intact after somitic mesoderm reversal, I also assessed motoneuron projections in embryos where somitic tissue plus adjacent spinal cord segments at levels 26-29 were reversed in a similar manner. Analyses of the distribution of retrogradely labeled motoneurons in reversed cord segments at st 35-36 indicated that motoneuron projections were reversed. This finding suggests that motoneurons have altered their course to project to correct targets despite the altered somitic origin of their targets and, thus, that specific guidance cues were intact. I conclude that if cues governing target or pathway choice are encoded positionally then they must be associated with other embryonic tissues such as the connective tissues or that guidance cues are acquired by myogenic cells after the onset of migration and motoneuron specification.     

The lateral somitic frontier: dorso-ventral aspects of anterio-posterior regionalization in avian embryos

Patterning events along the anterior-posterior (AP) axis of vertebrate embryos result in the distribution of muscle and bone forming a highly effective functional system. A key aspect of regionalized AP patterning results from variation in the migratory pattern of somite cells along the dorsal-ventral (DV) axis of the body. This occurs as somite cell populations expand around the axis or migrate away from the dorsal midline and cross into the lateral plate. The fate of somitic cells has been intensely studied and many details have been reported about inductive signaling from other tissues that influence somite cell fate and behavior. We are interested in understanding the specific differences between somites in particular AP regions and how these differences contribute to the global pattern of the organism. Using orthotopic transplants of segmental plate between quail and chick embryos, we have mapped the interface of the somitic and lateral plate mesoderm during the formation of the body wall in cervical and thoracic regions. This interface does not change dramatically in the mid-cervical region, but undergoes extensive changes in the thoracic region. Based on this regional mapping and consistent with the extensive literature, we suggest a revised method of classifying regions of the body wall that relies on embryonic cell lineages rather than adult functional criteria.     

The specificity of motor innervation of the chick wing does not depend upon the segmental origin of muscles

In vertebrate embryos, motor axons originating from a particular craniocaudal position in the neural tube innervate limb muscles derived from myoblasts of the same segmental level. We have investigated whether this relationship is important for the formation of specific nerve-muscle connections, by altering the segmental origin of muscles and examining their resulting innervation. First, by grafting quail wing somites to a new craniocaudal position opposite the chick wing, we established that the segmental origin of a muscle can be altered: presumptive muscle cells migrated according to their new, rather than their original, somitic level, colonizing a different subset of muscles. However, after reversal of a length of brachial somitic mesoderm along the craniocaudal axis, or exchange or shift of brachial somites, the craniocaudal position of wing muscle motoneurone pools within the spinal cord was undisturbed, despite the new segmental origin of the muscles themselves. While not excluding the possibility that muscles and their motor nerves are labelled segmentally, we conclude that specific motor axon guidance in the wing does not depend upon the existence of such labels.     

A positive correlation between permissiveness of mesoderm to neural crest migration and early DRG growth.

The microenvironment created by grafting rostral somitic halves in place of normal somites leads to the formation of nonsegmented peripheral ganglia (Kalcheim and Teillet, 1989; Goldstein and Kalcheim, 1991) and is mitogenic for neural crest (NC) cells that become dorsal root ganglia (DRG) (Goldstein et al., 1990). We have now extended these studies by using three surgical manipulations to determine how additional mesodermal tissues affected DRG growth in chick embryos. The following experimental manipulations were performed: (1) unilateral deletion of epithelial somites, similar deletions followed by replacing the somites with (2) a three-dimensional collagen matrix, or (3) fragments of quail lateral plate mesoderm. When somites were absent or replaced by collagen matrix, ganglia were unsegmented, and their volumes were decreased by 21% and 12%, respectively, compared to contralateral intact DRG. In contrast, when lateral plate mesoderm was transplanted in place of somitic mesoderm, NC cells migrated into the grafted mesoderm and formed unsegmented DRG whose volumes were increased by 62.6% compared to the contralateral ganglia. These results suggest that although DRG precursors do not require sclerotome to begin migration and condensation processes, DRG size is modulated by the properties of the mesoderm. Permissiveness to migration is positively correlated with an increase in DRG volume. This volume increase observed in grafts of lateral plate mesoderm is likely to result from enhanced proliferation of neural crest progenitors, previously demonstrated for DRG cells in rostral somitic grafts.     

Body wall morphogenesis: Limb-genesis interferes with body wall-genesis via its influence on the abaxial somite derivatives

The vertebrate body wall is regionalized into thoracic and lumbosacral/abdominal regions that differ in their morphology and developmental origin. The thoracic body wall has ribs and intercostal muscles, which develops from thoracic somites, whereas the abdominal wall has abdominal muscles, which develops from lumbosacral somites without ribs cage. To examine whether limb-genesis interferes with body wall-genesis, and to test the possibility that limb generation leads to the regional differentiation, an ectopic limb was induced in the thoracic region by transplanting prospective limb somatopleural mesoderm of Japanese quail between the ectoderm and somatopleural mesoderm of the chick prospective thoracic region. This ectopic limb generation induced the somitic cells to migrate into the ectopic limb mesenchyme to become its muscles and caused the loss of distal thoracic body wall (sterno-distal rib and distal intercostal muscle), without causing any significant effect on the more proximal region (proximal rib, vertebro-distal rib and proximal intercostal muscle). According to a new primaxial–abaxial classification, the proximal region is classified as primaxial and the distal region, as well as limb, is classified as abaxial. We demonstrated that ectopic limb development interfered with body wall development via its influence on the abaxial somite derivatives. The present study supports the idea that the somitic cells give rise to the primaxial derivatives keeping their own identity and fate, whereas they produce the abaxial derivatives responding to the lateral plate mesoderm.     

THE DIFFERENTIAL SENSITIVITY OF CULTURED CHICK MESODERMAL CELLS TO ACTINOMYCIN D

Cells were isolated from the somite mesoderm and from the unsegmented (presomite) mesoderm of early chick embryos and exposed to actinomycin D in single cell culture. Actinomycin D inhibited proliferation in cell cultures derived from the unsegmented mesoderm, although the same concentrations of this antibiotic did not inhibit cultures derived from the somite mesoderm. This differential sensitivity parallels the regionally specific necrosis and degeneration observed in the unsegmented mesoderm of intact chick embryos exposed to actinomycin D. In culture, both cell types exhibited approximately the same permeability to labeled actinomycin D and showed comparable inhibition of RNA, DNA, and protein syntheses in the presence of the antibiotic. However, freshly isolated mesodermal cells from the somite region had a higher content of RNA than did cells from the unsegmented region, and the somite cells maintained a higher rate of macromolecular synthesis in untreated cultures.     

Fate maps of the primitive streak in chick and quail embryo: ingression timing of progenitor cells of each rostro-caudal axial level of somites

Developmental fates of cells emigrating from the primitive streak were traced by a fluorescent dye Dil both in chick and in quail embryos from the fully grown streak stage to 12-somite stage, focusing on the development of mesoderm and especially on the timing of ingression of each level of somitic mesoderm. The fate maps of the chick and quail streak were alike, although the chick streak was longer at all stages examined. The anterior part of the primitive streak predominantly produced somites. The thoracic and the lumbar somites were shown to begin to ingress at the 5 somite-stage and 10 somite-stage in a chick embryo, and 6 somite-stage and 9 somite-stage in a quail embryo, respectively. The posterior part of the streak served mainly as the origin of more lateral or extra embryonic mesoderm. As development proceeded, the fate of the posterior part of the streak changed from the lateral plate mesoderm to the tail bud mesoderm and then to extra embryonic, allantois mesoderm. The fate map of the primitive streak in chick and quail embryo presented here will serve as basic data for studies on mesoderm development with embryo manipulation, especially for transplantation experiments between chick and quail embryos.     

Etude de la migration des cellules somitiques dans le mésoderme somatopleural de l'ébauche de l'aile

Summary In chick embryos, observations were made on serial semithin transverse sections of the wing level. In addition homo- or heterotopic replacements of the wing or leg somitic mesoderm by labelled somitic or nonsomitic mesoderm were made in 2-to 2.5-day embryos. The nuclear label used was either natural (quail donor embryos in heterotopic transplantations) or isotopic (chick donors labelled with tritiated thymidine).Histological examination revealed that the first somitic cells to leave somite 15 apparently did so at the 20 to 22 somite stage, while the last ones to leave somite 20 apparently did so shortly before the 36 somite stage.Transplantation experiments with labelled donor cells revealed the routes of migratory somitic cells and the time-course of their invasion into the outgrowing limb bud (non-somitic graft cells did not noticeably invade the limb anlage). They showed furthermore that the somitic mesoderm is not regionalized with respect to its limb myogenic properties.These results are compared with those obtained in other classes of vertebrates.

Ce travail a été subventionné en partie par la D.G.R.S.T. et le C.N.R.S.     

Pax3 functions in cell survival and in pax7 regulation

In developing vertebrate embryos, Pax3 is expressed in the neural tube and in the paraxial mesoderm that gives rise to skeletal muscles. Pax3 mutants develop muscular and neural tube defects; furthermore, Pax3 is essential for the proper activation of the myogenic determination factor gene, MyoD, during early muscle development and PAX3 chromosomal translocations result in muscle tumors, providing evidence that Pax3 has diverse functions in myogenesis. To investigate the specific functions of Pax3 in development, we have examined cell survival and gene expression in presomitic mesoderm, somites and neural tube of developing wild-type and Pax3 mutant (Splotch) mouse embryos. Disruption of Pax3 expression by antisense oligonucleotides significantly impairs MyoD activation by signals from neural tube/notochord and surface ectoderm in cultured presomitic mesoderm (PSM), and is accompanied by a marked increase in programmed cell death. In Pax3 mutant (Splotch) embryos, MyoD is activated normally in the hypaxial somite, but MyoD-expressing cells are disorganized and apoptosis is prevalent in newly formed somites, but not in the neural tube or mature somites. In neural tube and somite regions where cell survival is maintained, the closely related Pax7 gene is upregulated, and its expression becomes expanded into the dorsal neural tube and somites, where Pax3 would normally be expressed. These results establish that Pax3 has complementary functions in MyoD activation and inhibition of apoptosis in the somitic mesoderm and in repression of Pax7 during neural tube and somite development.     

Segmentation of sensory and sympathetic ganglia: interactions between neural crest and somite cells.

The segmental pattern of peripheral ganglia in higher vertebrates is generated by interactions between neural crest and somite cells. Each mesodermal somite is subdivided into at least two distinct domains represented by its rostral and caudal halves. Most migratory pathways taken by neural crest cells in trunk regions of the axis, as well as the outgrowth of motoneuron fibers are restricted to the rostral domain of each somite. Experimental modification of the somites, achieved by constructing a mesoderm composed of multiple rostral half-somites, results in the formation of continuous and unsegmented nerves, dorsal root ganglia (DRG) and sympathetic ganglia (SG). In contrast, both neurites and crest cells are absent from a mesoderm composed of multiple-caudal half somites. However, the mechanisms responsible for gangliogenesis within the rostral half of the somite, appear to be different for DRG and SG. Vertebral development from the somites is also segmental. In implants of either multiple rostral or caudal somite-halves, the grafted mesoderm dissociates normally into sclerotome and dermomyotome. However, the morphogenetic capabilities of each somitic half differ. The lateral vertebral arch is continuous in the presence of caudal half-somite grafts and is virtually absent in rostral half-somite implants. Therefore, the rostrocaudal subdivision of the sclerotome determines the segmental pattern of neural development and is also important for the proper metameric development of the vertebrae.     

The contribution made by cells from a single somite to tissues within a body segment and assessment of their integration with similar cells from adjacent segments

Somites represent the first visual evidence of segmentation in the developing vertebrate embryo and it is becoming clear that this segmental pattern of the somites is used in the initial stages of development of other segmented systems such as the peripheral nervous system. However, it is not known whether the somites continue to contribute to the maintenance of the segmental pattern after the dispersal of the somitic cells. In particular, the extent to which cells from a single somite contribute to all of the tissues of a single body segment and the extent to which they mix with cells from adjacent segments during their migration is not known. In this study, we have replaced single somites in the future cervical region of 2-day-old chick embryos with equivalent, similarly staged quail somites. The chimerae were then allowed to develop for a further 6 days when they were killed. The cervical region was dissected and serially sectioned. The sections were stained with the Feulgen reaction for DNA to differentiate between the chick and quail cells. The results showed that the cells from a single somite remained as a clearly delimited group throughout their migration. Furthermore, the sclerotome, dermatome and myotome portions from the single somites could always be recognised as being separate from similar cells from other somites. The somitic cells formed all of the tissues within a body segment excluding the epidermis, notochord and neural tissue. There was very little mixing of the somitic cells between adjacent segments. The segmental pattern of the somites is therefore maintained during the migration of the somitic cells and this might be fundamental to a mechanism whereby the segmentation of structures, such as the peripheral nervous system, is also maintained during development.     

Determination of somite cells: independence of cell differentiation and morphogenesis

Somites are mesodermal structures which appear transiently in vertebrates in the course of their development. Cells situated ventromedially in a somite differentiate into the sclerotome, which gives rise to cartilage, while the other part of the somite differentiates into dermomyotome which gives rise to muscle and dermis. The sclerotome is further divided into a rostral half, where neural crest cells settle and motor nerves grow, and a caudal half. To find out when these axes are determined and how they rule later development, especially the morphogenesis of cartilage derived from the somites, we transplanted the newly formed three caudal somites of 2.5-day-old quail embryos into chick embryos of about the same age, with reversal of some axes. The results were summarized as follows. (1) When transplantation reversed only the dorsoventral axis, one day after the operation the two caudal somites gave rise to normal dermomyotomes and sclerotomes, while the most rostral somite gave rise to a sclerotome abnormally situated just beneath ectoderm. These results suggest that the dorsoventral axis was not determined when the somites were formed, but began to be determined about three hours after their formation. (2) When the transplantation reversed only the rostrocaudal axis, two days after the operation the rudiments of dorsal root ganglia were formed at the caudal (originally rostral) halves of the transplanted sclerotomes. The rostrocaudal axis of the somites had therefore been determined when the somites were formed. (3) When the transplantation reversed both the dorsoventral and the rostrocaudal axes, two days after the operation, sclerotomes derived from the prospective dermomyotomal region of the somites were shown to keep their original rostrocaudal axis, judging from the position of the rudiments of ganglia. Combined with results 1 and 2, this suggested that the fate of the sclerotomal cells along the rostrocaudal axis was determined previously and independently of the determination of somite cell differentiation into dermomyotome and sclerotome. (4) In the 9.5-day-old chimeric embryos with rostrocaudally reversed somites, the morphology of vertebrae and ribs derived from the explanted somites were reversed along the rostrocaudal axis. The morphology of cartilage derived from the somites was shown to be determined intrinsically in the somites by the time these were formed from the segmental plate. The rostrocaudal pattern of the vertebral column is therefore controlled by factors intrinsic to the somitic mesoderm, and not by interactions between this mesoderm and the notochord and/or neural tube, arising after segmentation.     

Dynamic expression of lunatic fringe suggests a link between notch signaling and an autonomous cellular oscillator driving somite segmentation

The metameric organization of the vertebrate trunk is a characteristic feature of all members of this phylum. The origin of this metamerism can be traced to the division of paraxial mesoderm into individual units, termed somites, during embryonic development. Despite the identification of somites as the first overt sign of segmentation in vertebrates well over 100 years ago, the mechanism(s) underlying somite formation remain poorly understood. Recently, however, several genes have been identified which play prominent roles in orchestrating segmentation, including the novel secreted factor lunatic fringe. To gain further insight into the mechanism by which lunatic fringe controls somite development, we have conducted a thorough analysis of lunatic fringe expression in the unsegmented paraxial mesoderm of chick embryos. Here we report that lunatic fringe is expressed predominantly in somite -II, where somite I corresponds to the most recently formed somite and somite -I corresponds to the group of cells which will form the next somite. In addition, we show that lunatic fringe is expressed in a highly dynamic manner in the chick segmental plate prior to somite formation and that lunatic fringe expression cycles autonomously with a periodicity of somite formation. Moreover, the murine ortholog of lunatic fringe undergoes a similar cycling expression pattern in the presomitic mesoderm of somite stage mouse embryos. The demonstration of a dynamic periodic expression pattern suggests that lunatic fringe may function to integrate notch signaling to a cellular oscillator controlling somite segmentation.     

Origin of cutaneous smooth muscles in birds (author's transl)

The origin of smooth muscles in the skin of bird embryos has been analyzed in heterospecific quail/chick recombinants. The somitic mesoderm of the wing level of 2-day chick embryos was replaced by homotopic or heterotopic somitic mesoderm from quail embryos. The cellular constitution of tissues was observed in twelve recombinant embryos at 17 or 18 days of incubation. Results show that feather smooth muscles and vascular smooth muscles have the same origin as the cutaneous mesenchyme in which they differentiate. They are of somatopleural origin in the wing integument and of somitic (dermatomal) origin in the dorsal integument. This study further reveals that the muscular and connective tissue wall of blood vessels does not have the same embryonic origin as the endothelium. It is suggested that the latter originates from the primitive aorta.     

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.     

Hox genes and morphological identity: axial versus lateral patterning in the vertebrate mesoderm

The successful organization of the vertebrate body requires that local information in the embryo be translated into a functional, global pattern. Somite cells form the bulk of the musculoskeletal system. Heterotopic transplants of segmental plate along the axis from quail to chick were performed to test the correlation between autonomous morphological patterning and Hox gene expression in somite subpopulations. The data presented strengthen the correlation of Hox gene expression with axial specification and focus on the significance of Hox genes in specific derivatives of the somites. We have defined two anatomical compartments of the body based on the embryonic origin of the cells making up contributing structures: the dorsal compartment, formed from purely somitic cell populations; and the ventral compartment comprising cells from somites and lateral plate. The boundary between these anatomical compartments is termed the somitic frontier. Somitic tissue transplanted between axial levels retains both original Hox expression and morphological identity in the dorsal compartment. In contrast, migrating lateral somitic cells crossing the somitic frontier do not maintain donor Hox expression but apparently adopt the Hox expression of the lateral plate and participate in the morphology appropriate to the host level. Dorsal and ventral compartments, as defined here, have relevance for experimental manipulations that influence somite cell behavior. The correlation of Hox expression profiles and patterning behavior of cells in these two compartments supports the hypothesis of independent Hox codes in paraxial and lateral plate mesoderm.     

Formation of the dorsal root ganglia in the avian embryo: Segmental origin and migratory behavior of neural crest progenitor cells

The segmental origin and migratory pattern of neural crest cells at the trunk level of avian embryos was studied, with special emphasis on the formation of the dorsal root ganglia (DRG) which organize in the anterior half of each somite. Neural crest cells were visualized using the quail-chick marker and HNK-1 immunofluorescence. The migratory process turned out to be closely correlated with somitic development: when the somites are epithelial in structure few labeled cells were found in a dorsolateral position on the neural tube, uniformly distributed along the craniocaudal axis. Following somitic dissociation into dermomyotome and sclerotome labeled cells follow defined migratory pathways restricted to each anterior somitic half. In contrast, opposite the posterior half of the somites, cells remain grouped in a dorsolateral position on the neural tube. The fate of crest cells originating at the level of the posterior somitic half was investigated by grafting into chick hosts short segments of quail neural primordium, which ended at mid-somitic or at intersomitic levels. It was found that neural crest cells arising opposite the posterior somitic half participate in the formation of the DRG and Schwann cells lining the dorsal and ventral root fibers of the same somitic level as well as of the subsequent one, whereas those cells originating from levels facing the anterior half of a somite participate in the formation of the corresponding DRG. Moreover, crest cells from both segmental halves segregate within each ganglion in a distinct topographical arrangement which reflects their segmental origin on the neural primordium. Labeled cells which relocate from posterior into anterior somitic regions migrate longitudinally along the neural tube. Longitudinal migration of neural crest cells was first observed when the somites are epithelial in structure and is completed after the disappearance of the last cells from the posterior somitic region at a stage corresponding to the organogenesis of the DRG.     

Proximal tissues and patterned neurite outgrowth at the lumbosacral level of the chick embryo: partial and complete deletion of the somite

The development of patterned axon outgrowth and dorsal root ganglion (DRG) formation was examined after partially or totally removing chick somitic mesoderm. Since the dermamyotome is not essential and a full complement of limb muscles developed, alterations in neural patterns could be ascribed to deletion of sclerotome. When somitic tissue was completely removed, axons extended and DRG formed, but in an unsegmented pattern. Therefore the somite does not elicit outgrowth of axons or migration of DRG precursors, it is not a manditory substratum and it is not required for DRG condensation. These results suggest that posterior sclerotome is relatively inhibitory to invasion, an inhibition that is released when sclerotome is absent. When somites were partially deleted, axonal segmentation was not lost proportionally with the amount of sclerotome removed, suggesting that properties that may vary with sclerotome volume (such as diffusible cues) do not play a primary role. Instead, spinal nerves lost segmentation only when ventral sclerotome was deleted, regardless of whether dorsal sclerotome was or was not removed. This strongly suggests that axonal segmentation is imposed by direct interactions between growth cones and extracellular matrices or surfaces sclerotome cells. While DRG tended to be normally segmented when ventral sclerotome was deleted and to lose segmentation when dorsomedial sclerotome was absent, a coordinate loss of DRG segmentation with sclerotome volume could not be ruled out. However it is clear that axonal and DRG segmentation are independent. Observations on a subset of embryos in which the notochord was displaced relative to the spinal cord suggest that the ventromedial sclerotome surrounding the notochord inhibits axon advance. Posterior and ventromedial sclerotome are hypothesized to act as barriers to axon outgrowth due to some feature of their common cartilaginous development. Specific innervation patterns were also examined. When the notochord was displaced toward the control limb, axons on this side made and corrected projection errors, suggesting that the notochord can influence the precision of axonal pathway selection. In contrast, motor axons that entered the limb on all operated sides innervated muscle with their normal precision despite the absence of the somite and axonal segmentation. Therefore, the somite and the process of spinal nerve segmentation are largely irrelevant to the specificity of motoneuron projection.