Organization of cytoskeletal elements and organelles preceding growth cone emergence from an identified neuron in situ

The purpose of this study was to investigate the arrangement of cytoskeletal elements and organelles in an identified neuron in situ at the site of emergence of its growth cone just before and concurrent with the onset of axonogenesis. The Ti1 pioneer neurons are the first pair of afferent neurons to differentiate in embryonic grasshopper limbs. They arise at the distal tip of the limb bud epithelium, the daughter cells of a single precursor cell, the Pioneer Mother Cell (PMC). Using immunohistochemical markers, we characterized the organization of microtubules, centrosomes, Golgi apparatus, midbody, actin filaments, and chromatin from mitosis in the PMC through axonogenesis in the Tils. Just before and concurrent with the onset of axonogenesis, a characteristic arrangement of tubulin, actin filaments, and Golgi apparatus is localized at the proximal pole of the proximal pioneer neuron. The growth cone of the proximal cell stereotypically arises from this site. Although the distal cell's axon generally grows proximally, occasionally it arises from its distal pole; in such limbs, the axons from the sister cells extend from mirror symmetric locations on their somata. In the presence of cytochalasin D, the PMC undergoes nuclear division but not cytokinesis and although other neuronal phenotypes are expressed, axongenesis is inhibited. Our data suggest that intrinsic information determines the site of growth cone emergence of an identified neuron in situ.     

Embryogenesis of peripheral nerve pathways in grasshopper legs. I. The initial nerve pathway to the CNS

The founding of the first nerve path of the grasshopper metathoracic leg was examined at the level of identified neurons, using intracellular dye fills, immunohistochemistry, Nomarski optics, and scanning and transmission electron microscopy. The embryonic nerve is established by the axonal trajectory of a pair of afferent pioneer neurons, the tibial 1 (Ti1) cells. Following a period of profuse filopodial sprouting, the Ti1 axonal growth cones, possessing 75- to 100-microns-long filopodia, navigate a stereotyped path across the limb bud epithelium to the base of the appendage and into the CNS. The Ti1 axons grow from cell to cell along a chain of preaxonogenesis neurons spaced at intervals along the pathway, forming dye-passing junctions with them. The contacted neurons subsequently undergo axonogenesis and follow the pioneer axons into the CNS. Later arising neurons project their axons onto the cell bodies of the chain, thereby establishing the principal branch points of the nerve. Among the later arising afferents are the sensory neurons of the femoral chordotonal and subgenual organs. The morphology of the adult nerve appears to be determined by the stereotyped positioning of neurons in the differentiating limb bud and by the resultant axonal trajectories established during the first 10% of peripheral neurogenesis.     

Programmed death of peripheral pioneer neurons in the grasshopper embryo

The Ti1 pioneer neurons arise at the distal tip of the metathoracic leg in the grasshopper embryo, and are the first neurons in the limb bud to extend axons to the central nervous system (C. M. Bate (1976) Nature (London) 260, 54-56; H. Keshishian (1980) Dev. Biol. 80, 388-397). By providing a neural pathway along which growth cones of later arising neurons migrate, these pioneer axons establish the route of one of the major nerve trunks in the leg (Keshishian, 1980; R. K. Ho and C. S. Goodman (1982) Nature (London) 297, 404-406; D. Bentley and H. Keshishian (1982) Science 218, 1082-1088). Here, we demonstrate that at the 55-59% stage of development, the two Ti1 pioneer neurons undergo programmed death. The role which these pioneers serve in establishing a nerve route appears to be their only function, and may be important for the normal development of the peripheral nervous system. The Ti1 pioneers provide an example of a previously hypothesized class (J. W. Truman (1984) Annu. Rev. Neurosci. 7, 171-188) of programmed neuron death: obsolete neurons whose function was developmental rather than behavioral.     

Pathfinding by pioneer neurons in isolated, opened and mesoderm-free limb buds of embryonic grasshoppers

The Ti1 afferent neurons are the first neurons to undergo axonogenesis in limb buds of embryonic grasshoppers. Their growth cones pioneer a stereotyped pathway through the limb which becomes the route of one of the major leg nerve trunks. The growth cones appear to be oriented by several kinds of guidance cues, including guidepost neurons, a developing limb segment boundary, and an additional proximally orienting cue(s). In the experiments reported here, we have investigated the possible nature and source of proximally orienting and segment boundary cues by surgical manipulations of the limb. Before the onset of pioneer axonogenesis, limbs were isolated from the body, opened longitudinally and pinned out flat, or stripped of mesoderm. Pioneer axon routes in cultured, surgically manipulated limb buds were compared to routes in cultured control limbs. The results indicate that proximal extension of pioneer growth cones along the limb axis does not require (during the period of growth) tissue extrinsic to the limb, contact guidance by the limb contour, an axial electrical field, a diffusion gradient generated by a localized source, mesodermal cells, or guidepost neurons; adequate guidance information for proximal growth apparently can be provided by the limb epidermal epithelium (including the basal lamina) and/or by internal polarity of the pioneer neurons. Adequate guidance information for the segment boundary portion of the pioneer route apparently can be provided by the limb epithelium.     

Analysis of migratory behavior of neural crest and fibroblastic cells in embryonic tissues

The precise migration of neural crest cells is apparently controlled by their environment. We have examined whether the embryonic tissue spaces in which crest cells normally migrate are sufficient to account for the pattern of crest cell distribution and whether other migratory cells could also distribute themselves along these pathways. To this end, we grafted a variety of cell types into the initial crest cell migratory pathway in chicken embryos. These cell types included (a) undifferentiated neural crest cells isolated from cultured neural tubes, intact crest from cranial neural folds, and crest derivatives (pigment cells and spinal ganglia); (b) normal embryonic fibroblastic cells from somite, limb bud, lateral plate, and heart ventricle; and (c) a transformed fibroblastic cell line (Sarcoma 180). Crest cells or their derivatives grafted into the crest migratory pathway all distributed normally, although in contrast to the result when neural tubes were graftedin situ, fewer cells were observed in the epithelium and few or none were localized in the nascent spinal ganglia. Grafted quail somite cells contributed to normal somitic structures and did not migrate extensively in the chicken host. Other fibroblasts did not migrate along cranial or trunk crest pathways, or invade adjacent tissues, but remained intact at the graft site. Sarcoma 180 cells, however, distributed themselves along the normal trunk crest pathway. Cranial and trunk crest cells and crest derivatives grafted ectopically in the limb bud or somite also dispersed, and were found along the ventral migratory pathway. Fibroblastic cells grafted into ectopic sites again remained intact and did not invade host tissue. We conclude (1) that neural crest cells and their derivatives are highly motile and invasive in their normal pathway, as well as in unfamiliar embryonic environments; and (2) that the crest pathway does not act solely to direct neural crest cells, since at least one transformed cell can follow the crest migratory route.     

Embryonic development of a peripheral nervous system: nerve tract associated cells and pioneer neurons in the antenna of the grasshopper Schistocerca gregaria

The grasshopper antenna is an articulated appendage associated with the deutocerebral segment of the head. In the early embryo, the meristal annuli of the antenna represent segment borders and are also the site of differentiation of pioneer cells which found the dorsal and ventral peripheral nerve tracts to the brain. We report here on another set of cells which appear earlier than the pioneers during development and are later found arrayed along these tracts at the border of epithelium and lumen. These so-called nerve tract associated cells differ morphologically from pioneers in that they are bipolar, have shorter processes, and are not segmentally organized in the antenna. Nerve tract associated cells do not express horseradish peroxidase and so are not classical neurons. They do not express antigens such as repo and annulin which are associated with glia cells in the nervous system. Nerve tract associated cells do, however, express the mesodermal/mesectodermal cell surface marker Mes-3 and putatively derive from the antennal coelom and then migrate to the epithelium/lumen border. Intracellular recordings show that such nerve tract associated cells have resting potentials similar to those of pioneer cells and can be dye coupled to the pioneers. Similar cell types are present in the maxilla, a serially homologous appendage on the head. The nerve tract associated cells are organized into a cellular scaffold which we speculate may be relevant to the navigation of pioneer and sensory axons in the early embryonic antennal nervous system.     

Embryogenesis of peripheral nerve pathways in grasshopper legs. II. The major nerve routes

In the preceding paper (H. Keshishian and D. Bentley, 1983a, Dev. Biol. 96, 89-102) the events leading to the morphogenesis of nerve 5B1 in the grasshopper embryonic metathoracic leg were presented. Here the role of later differentiating peripheral neurons in establishing the other major nerves of the leg is examined. In addition to the (tibial 1) (Ti1) pioneer neuron cell pairs that establish nerve 5B1 in the tibia femur, and coxa-trochanter, six later differentiating cells and/or cell pairs were identified and examined with respect to their role in peripheral nerve ontogeny. Nerve path pioneering was observed in two cell pairs of the distal tarsus (Ta1 and Ta2), by neurons of the posterior proximal tibia (Ti2), the posterior midfemur (neurons F3 and F4), and by an additional cell pair in the anterior coxal-trochanteral region of the limb bud (cell pair, CT2). In addition, efferent projections onto limb and epithelia played an important role in establishing nerve branches. In two nerves the axonal trajectory from the periphery to the CNS is established by afferent and efferent pathfinding axons meeting halfway and overgrowing each other's established projections. For each nerve branch examined it was found that axons projected initially to the cell bodies of previously arising neurons along the trajectory. The location along the limb bud ectoderm where neurons arise, and hence their ultimate cell body positions, played an important role in organizing the fasciculation of follower axons and establishing branch points.     

Embryogenesis of peripheral nerve pathways in grasshopper legs. III. Development without pioneer neurons

We have examined the consequence of deleting the first pathfinding neurons to differentiate in the metathoracic leg, cell pair tibial 1 (Ti1) (C. M. Bate, 1976, Nature (London) 260, 54-56; H. Keshishian, 1980, Dev. Biol. 80, 388-397) on the development of two uniquely identifiable follower sensory neurons, and upon the subsequent development of nerve 5B1 in the leg. Following the equivalent of 10-15% of embryonic development in culture the follower sensory neurons were found to have formed topologically normal axonal trajectories in the leg, and to have established contacts with later differentiating sensory and motor axons in an essentially normal fashion. The results show that followers can navigate the route normally taken by the pioneers, and suggest that the pioneers do not have unusual pathfinding capabilities.     

Pioneer neurones use basal lamina as a substratum for outgrowth in the embryonic grasshopper limb

During axonogenesis, contacts made by the growth cone with its substratum are important in guiding the direction of neurone outgrowth. This study examines the contacts made by the growth cones of pioneer neurones in the embryonic grasshopper limb. Individual pioneer neurones at different stages of development were injected with horseradish peroxidase and the contacts made by the filopodia at the tip of their growth cones were examined by electron microscopy. Filopodia made few contacts with mesodermal cells, some contacts with ectodermal cells and very frequent contacts with basal lamina underlying the ectoderm. Components of the basal lamina may therefore play a role in guiding pioneer axon outgrowth.     

Analysis of the embryonic lineage of vertebrate taste buds

In all vertebrates, taste buds are the last sensory receptorsto appear late in embryonic development. They are thought toarise locally from the oropharyngeal epithelium, although thishypothesis has not been tested experimentally. Alternatively,taste buds have been proposed to arise from neurocctodermalcells that migrate from peripheral neurogenic sources to theoropharyngeal epithelium and give rise to taste bud precursorcells. In order to determine the exact embryonic lineage ofthe cells of vertebrate taste buds, we have employed a combinationof endogenous and exogenous cell marking techniques to followneuroectodermal and endodermal cells through development. Wefind, in the ambystomatid salamander used in our studies, tastebuds arise locally within the endodermally-derived epitheliumlining the oropharyngeal cavity, and do not receive a contributionfrom neuroectodermal sources, i.e. ectodermal placodes or cephalicneural crest.     

The embryonic development of the triclad <Emphasis Type="Italic">Schmidtea polychroa</Emphasis>

Triclad flatworms are well studied for their regenerative properties, yet little is known about their embryonic development. We here describe the embryonic development of the triclad Schmidtea polychroa, using histological and immunocytochemical analysis of whole-mount preparations and sections. During early cleavage (stage 1), yolk cells fuse and enclose the zygote into a syncytium. The zygote divides into blastomeres that dissociate and migrate into the syncytium. During stage 2, a subset of blastomeres differentiate into a transient embryonic epidermis that surrounds the yolk syncytium, and an embryonic pharynx. Other blastomeres divide as a scattered population of cells in the syncytium. During stage 3, the embryonic pharynx imbibes external yolk cells and a gastric cavity is formed in the center of the syncytium. The syncytial yolk and the blastomeres contained within it are compressed into a thin peripheral rind. From a location close to the embryonic pharynx, which defines the posterior pole, bilaterally symmetric ventral nerve cord pioneers extend forward. Stage 4 is characterized by massive proliferation of embryonic cells. Large yolk-filled cells lining the syncytium form the gastrodermis. During stage 5 the external syncytial yolk mantle is resorbed and the embryonic cells contained within differentiate into an irregular scaffold of muscle and nerve cells. Epidermal cells differentiate and replace the transient embryonic epidermis. Through stages 6–8, the embryo adopts its worm-like shape, and loosely scattered populations of differentiating cells consolidate into structurally defined organs. Our analysis reveals a picture of S. polychroa embryogenesis that resembles the morphogenetic events underlying regeneration.Edited by D. Tautz     

Pioneer growth cone behavior at a differentiating limb segment boundary in the grasshopper embryo

The first neurons to extend axons through embryonic grasshopper limbs are a pair of sibling pioneer neurons. After migrating proximally along the limb axis, the pioneer growth cones normally make an abrupt ventral turn. In some cases (less than 20%) this turn is directly toward the proximo-ventrally located Cx1 guidepost neurons. However, in the majority of cases (greater than 80%) the pioneer growth cones make a more acute ventral turn along a single circumferential line which lies distal to the Cx1 neurons. Growth cones from other afferent neurons orient along the same line. Growth cones can extend along this line around more than half of the circumference of the limb and can grow in either direction along it. The circumferential line appears to be the prospective trochanter-coxa segment boundary. Afferent axons on the segment boundary leave it and contact the proximo-ventrally located Cx1 neurons. The site at which pioneer growth cones leave the boundary is variable and appears to be the point from which filopodial contact with Cx1 cells is first established. In addition to the trochanter-coxa segment boundary, the pioneer growth cones and axons also respond to the tibia-femur and femur-trochanter segment boundaries. The role of segment boundaries as barriers to growth cone movement and the effect of such barriers on the timing and placement of differentiation of pioneer neurons are discussed.     

Embryonic development of the sensory innervation of the clypeo-labral complex: further support for serially homologous appendages in the locust

The clypeo-labrum, or upper lip, of insects is intimately involved in feeding behavior and is accordingly endowed with a rich sensory apparatus. In the present study we map the temporal appearance of all major clusters of sensory cells on this structure in the locust during the first half of embryogenesis. The identities of these sensory cell clusters were defined according to the origin of the branching point of their axons from the labral sensory nerve as seen at mid-embryogenesis. The first sensory cells to differentiate from the labral epithelium do so at stereotypic sites beginning at around 32% of embryogenesis. Bilaterally symmetrical clusters of differentiated neurons rapidly appear and pioneering of the labral sensory nerve on each side is performed by a specific cell from each cluster. This cell directs its axon anteriorly towards a bilaterally symmetrical pair of cells, the frontal commissure pioneers, on either side of the developing frontal ganglion. The final trajectory of the sensory nerve within the labrum closely matches the pattern of Repo-expressing glial cells. The majority of the sensory cell clusters differentiate during embryogenesis, but the number of sensory cells in some clusters are modified significantly during postembryonic development. Comparing the innervation pattern of the clypeo-labrum with that of other mouthparts and the leg at mid-embryogenesis, we find a striking similarity in organization which we interpret as support for the homologous appendage hypothesis.     

Pioneer neuron pathfinding from normal and ectopic locations in vivo after removal of the basal lamina

The contribution of the basal lamina to Ti1 pioneer axon guidance in grasshopper limb buds was investigated by allowing growth cones to migrate in 30%-31% stage limbs from which the basal lamina had been removed by enzymatic treatment. When the Ti1 axons extended from their normal location, the pathways established in the absence of basal lamina were normal. This indicates that the basal lamina is not required for initial proximal axon outgrowth, recognition of limb segment boundaries, or selective interaction with neuronal somata. Removal of the basal lamina from slightly older (32% stage) embryos resulted in displacement of the Ti1 somata to ectopic locations in approximately 50% of the limbs. Pathfinding from ectopic locations was aberrant in 45% of the cases observed. This demonstrates that if orienting information is present in the basal lamina-free epithelium at this stage, it is not the predominant factor in determining growth cone orientation from ectopic locations.     

Ciliogenesis and centriole formation in the mouse embryonic nervous system. An ultrastructural analysis

Serial ultrathin sections were used to study the formation of the primary cilium and the centriolar apparatus, basal body, and centriole in the neuroepithelial primordial cell of the embryonic nervous system in the mouse. At the end of mitosis, the centrioles seem to migrate toward the ventricular process of the neuroepithelial cell, near the ventricular surface. One of these centrioles, the nearest to the ventricular surface, begins to mature to form a basal body, since its tip is capped by a vesicle probably originating in the cytoplasm. This vesicle fuses with the plasmalemma and the cilium growth by the centrifugal extension of the 9 sets of microtubule doublets. These 9 sets invade the thick base of the cilium which is initially capped by a ball-shaped tip with the appearance of a mushroom cilium. The secondary extension of 7, then 5, and finally 2 sets of microtubule doublets contribute to form the tip of the mature cilium, which is associated with a mature centriolar apparatus formed by a basal body and a centriole. Centriologenesis occurs before mitosis and is concomitant with the progressive resorption of the cilium. The daughter centriole, or procentriole, begins to take form near the tips of fibrils that extend perpendicularly and at a short distance from the wall of the parent centriole. Osmiophilic material accumulates around these fibrils, and gives rise to the microtubules of the mature daughter centriole. These centrioles formed by a centriolar process are further engaged in mitosis, after the total resorption of the cilium. This pattern of development suggests that in the primordial cells of the embryonic nervous system, centriologenesis and ciliogenesis are 2 independent phenomena.     

Neuronal determination during embryonic development of the grasshopper nervous system

We have examined the roles of cell lineage and interactions in the determination of individual identified neurons in the grasshopper embryo by selective ablations of individual cells and/or their neighbors at successive stages following their birth. The neurons in the grasshopper central nervous system (CNS) are produced by two types of identifiable neuronal precursor cells: neuroblasts (NBs), which generate most of the neurons, and midline precursors (MPs), which generate only a few. NBs divide asymmetrically in a stem cell fashion to generate a chain of ganglion mother cells (GMCs) which then divide once more symmetrically to produce pairs of sibling neurons: MPs cleave once to generate a single pair of sibling neurons. We analyzed the determination of (1) the pair of sibling progeny produced by midline precursor 3 (MP3) and the determination of (2) the pair of sibling progeny produced by the first GMC from neuroblast 1-1 (NB 1-1); in each case the siblings normally differentiate into morphologically distinct neurons. Our results indicate that both pairs of neuronal progeny (1) are born equivalent, (2) become determined by cell interactions early in their development before axonogenesis, and (3) demonstrate a hierarchy of fates with one fate dominant over the other. These results suggest a common pattern of neuronal determination in the grasshopper and possibly all insect embryos.     

Pigment cell development in rhesus monkey eyes: an electron microscopic and histochemical study

The ontogeny of pigment cells in the eyes of rhesus monkeys was studied by electron microscopy and histochemistry.In 60- to 80-day-old fetuses, the pigment epithelium of the iris and retina has already differentiated whereas stromal melanocytes of the uveal tract differentiate much later. The morphological and histochemical difference between melanocytes of the iris stroma and the choroid suggests that during embryonic development melanocytes migrate from the iris toward the ciliary body and choroid.Similarly, melanosomes of pigmented epithelial cells may have their origin in the epithelium of the anterior layer of the iris, which is metabolically more active than both the posterior layer and the pigment epithelium of the ciliary body and retina.     

Production of plasminogen activator by migrating cephalic neural crest cells.

Neural crest cells migrate extensively during embryonic development and differentiate into a wide variety of cell types. Our working hypothesis is that during migration, embryonic cells secrete proteases which modify local microenvironments, thereby facilitating directed cellular movements. In this communication, we report studies on the migration of cephalic neural crest cells in the avian embryo. We demonstrate that these cells produce high levels of the serine protease, plasminogen activator (PA), at the time of their initial migration from the neural tube and during their migration to and colonization of the developing head and neck.     

Chemotactic behavior of myoblasts

Earlier studies have suggested that myogenic cells of somite origin migrate into the developing limb, but little is known about the factors affecting the pattern of migration. In order to understand the migratory behavior of myogenic cells, embryonic skeletal muscle cells were tested for their ability to migrate chemotactically using a modified Boyden chamber assay system. It is shown here, for the first time, that embryonic skeletal muscle cells have the capacity to migrate toward a gradient of platelet-derived growth factor (PDGF) and PDGF-like factors present in serum and chick embryo extract (CEE). On the other hand, nonmyogenic limb mesenchyme cells do not exhibit such a response. A hypothesis is proposed here that chemotactic factors from the already patterned vasculature might influence the distribution of skeletal muscle cells during early limb development.