Neurite outgrowth traced by means of horseradish peroxidase inherited from neuronal ancestral cells in frog embryos

Outgrowing neurites in Xenopus embryos were labeled with horseradish peroxidase which had been injected into a single blastomere at the 32-cell stage and had been inherited by all the descendants, including neurons. Neurite outgrowth was traced from labeled trigeminal ganglion cells and most or all types of neurons present in the spinal cord at embryonic stages 20-30: primary motoneurons, commissural, dorsal longitudinal, ventral longitudinal, and Rohon-Beard neurons. All types of nerve fibers grew by the most direct pathway, apparently without errors of initial outgrowth, pathway selection, or target selection. An initial transient phase of outgrowth of filopodial processes from neuronal cell bodies and shafts of short neurites was observed which disappeared after further elongation of the neurites. The first pioneer fibers grew out from all types in a 2-hr period, from stage 20 to 22, and these fibers arrived at the targets within 3.5 hr after initial outgrowth. Additional fibers grew later in contact with the pioneers to form fascicles. Nerve fibers elongated without branching until they neared or contacted their targets. The rate of elongation at 20 degrees C was 30-75 micron/hr. The rapid, unbranched, error-free initial outgrowth and elongation of neurites to their targets is discussed in relation to theories of development of nerve pathways.     

In vitro studies on the control of nerve fiber growth by the extracellular matrix of the nervous system

1. Cultured neurons from embryonic chick sympathetic ganglia or dorsal root ganglia grow nerve fibers extensively on simple substrata containing fibronectin, collagens (types I, III, IV), and especially laminin. 2. The same neurons cultured on substrata containing glycosaminoglycans grow poorly. Glycosaminoglycans (heparin) inhibit nerve fiber growth on fibronectin substrata. 3. Proteolytic fragments of fibronectin support nerve fiber growth only when the cell attachment region is intact. For example, a 105 kD fragment, encompassing the cell attachment region, supports growth when immobilized in a substratum, but a 93 kD subfragment, lacking the cell attachment region, is unable to support fiber growth. When it is added to the culture medium, the 105 kD fragment inhibits fiber growth on substrata containing native fibronectin. 4. In culture medium lacking NGF, DRG neurons extend nerve fibers only on laminin and not on fibronectin, collagen or polylysine. Studies with radioiodinated laminin indicate that laminin binds with a relatively high affinity (kd approximately equal to 10(-9) M) to DRG neurons, and to a variety of other neural cells (NG108 cells, PC12 cells, rat astrocytes, chick optic lobe cells). We have isolated a membrane protein (67 kD) by affinity chromatography on laminin columns and are characterizing this putative laminin receptor. 5. Dissociated DRG neurons or ganglionic explants cultured on complex substrata consisting of tissue sections of CNS or PNS tissues extend nerve fibers onto the PNS (adult rat sciatic nerve) but not CNS (adult rat optic nerve) substrata. Other tissue substrata which support fiber growth in vivo (embryonic rat spinal cord, goldfish optic nerve) support growth in culture. While substrata from adult CNS, which support meager regeneration in vivo (adult rat spinal cord) support little fiber growth in culture. 6. Ganglionic explants cultured in a narrow space between a section of rat sciatic nerve and optic nerve grow preferentially onto the sciatic nerve suggesting that diffusible growth factors are not responsible for the differential growth on the two types of tissues. 7. Dissociated neurons adhere better to sections of sciatic nerve than optic nerve. Laminin, rather than fibronectin or heparan sulfate proteoglycan, is most consistently identifiable by immunocytochemistry in tissues (sciatic nerve, embryonic spinal cord, goldfish optic nerve) which support nerve fiber growth. Taken together, these data suggest that ECM adhesive proteins are important determinants of nerve regeneration.     

Growth of axons through a lesion in the intact CNS of fetal rat maintained in long-term culture.

The ability of neurons in the central nervous system (CNS) to grow through a lesion and restore conduction has been analysed in developing spinal cord in vitro. The preparation consists of the entire CNS of embryonic rat, isolated and maintained in culture. Conduction of electrical activity and normal morphological appearance (light microscopical and electron microscopical) were maintained in the spinal cord of such preparations for up to 7 d in culture. A complete transverse crush of the spinal cord abolished all conduction for 2 d. After 3-5 d, clear recovery had occurred: electrical conduction across the crush was comparable with that in uninjured preparations. Furthermore, the spinal cord had largely regained its gross normal appearance at the crush site. Axons stained in vivo by carbocyanine dyes had, by 5 d, grown in profusion through the lesion and several millimetres beyond it. These experiments, like those made in neonatal opossum (Treherne et al. 1992) demonstrate that central neurons of immature mammals, unlike those in adults, can respond to injury by rapid and extensive outgrowth of nerve fibres in the absence of peripheral nerve bridges or antibodies that neutralize inhibitory factors. However, unlike the opossum, in which outgrowth occurred at 24 degrees C, although there was prolonged survival of rat spinal cords at this temperature, outgrowth of axons across the lesion required a temperature of 29 degrees C. With rapid and reliable regeneration in vitro it becomes practicable to assay the effects of molecules that promote or inhibit restoration of functional connections.     

Anatomical specificity of regenerated muscle sensory afferents in the spinal cord of the bullfrog

The specificity of central projections made by regenerated muscle sensory fibers in the brachial spinal cord was studied with anatomical tracing methods. Sensory fibers were interrupted by freezing dorsal roots in postmetamorphic bullfrogs. After several months, regenerated sensory fibers were labeled with horseradish peroxidase applied to the triceps brachii muscle nerve, and their arborizations within the spinal cord were reconstructed from serial cross sections. Most of the regenerated projections from triceps muscle sensory afferents ended in or near their normal terminal field. A few branched and appeared to terminate more dorsally than normal, however, sometimes within the region where cutaneous afferents normally terminate. In contrast to the normal pathway followed by muscle afferents within the spinal cord, many regenerated afferents grew along the circumference of the spinal cord, just under the pial surface, and then turned abruptly toward the midline and into their appropriate terminal region. This suggests that regenerating afferents may actively seek out their appropriate targets and are not simply passively guided to them.     

低温保存许旺细胞对周围神经再生的作用

目的：比较原代培养许旺细胞（Schwann cells,SCs)和冷冻保存的SCs移植对损伤后坐骨神经再生的作用。方法：原代培养和液氮保存的SCs分别移植到桥接缺损坐骨神经的硅胶管内。在移植后不同时间（第6和8周末）,硅胶管远端神经干内注射HRP,逆行追踪背根神经节和脊髓前角的标记神经元数量;测量再生神经纤维的复合动作电位传导速度;电镜观察再生神经纤维的髓鞘形成。结果：原代培养和冷冻保存SCs在移植后不同时间其背根神经节和脊髓前角神经元HRP标记细胞数量、再生神经纤维的复合动作电位传导速度基本一致,再生神经纤维髓鞘的形成未见明显差别。结论：冷冻保存的SCs仍具有促进损伤后周围神经再生的能力。     

Anatomical and functional recovery following spinal cord transection in the chick embryo

Following complete transection of the thoracic spinal cord at various times during embryonic development, chick embryos and posthatched animals exhibited various degrees of anatomical and functional recovery depending upon the age of injury. Transection on embryonic day 2 (E2), when neurogenesis is still occurring and before descending or ascending fiber tracts have formed, produced no noticeable behavioral or anatomical deficits. Embryos hatched on their own and were behaviorally indistinguishable from control hatchlings. Similar results were found following transection on E5, an age when neurogenesis is complete and when ascending and descending fiber tracts have begun to project through the thoracic region. Within 48 h following injury on E5, large numbers of nerve fibers were observed growing across the site of transection. By E8, injections of horse-radish peroxidase (HRP) administered caudal to the lesion, retrogradely labelled rostral spinal and brainstem neurons. Embryos transected on E5 were able to hatch and could stand and locomote posthatching in a manner that was indistinguishable from controls. Following spinal cord transections on E10, anatomical recovery of the spinal cord at the site of injury was not quite as complete as after E5 transection. Nonetheless, anatomical continuity was restored at the site of injury, axons projected across this region, and rostral spinal and brainstem neurons could be retrogradely labelled following HRP injections administered caudal to the lesion. At least part of this anatomical recovery may be mediated by the regeneration or regrowth of lesioned axons. Although none of the embryos transected on E10 that survived to hatching were able to hatch on their own, because several sham-operated embryos were also unable to hatch, we do not attribute this deficit to the spinal transection. When E10-transected embryos were aided in escaping from the shell, they were able to support their own weight, could stand, and locomote, and were generally comparable, behaviorally, to control hatchlings. Repair of the spinal cord following transection on E15 was considerably less complete compared to embryos transected on E2, E5, or E10. However, in some cases, a degree of anatomical continuity was eventually restored and a few spinal neurons rostral to the lesion could be retrogradely labelled with HRP. By contrast, labelled brainstem neurons were never observed following E15 transection. E15 transected embryos were never able to hatch on their own, and when aided in escaping from the shell, the hatchlings were never able to stand, support their own weight or locomote.(ABSTRACT TRUNCATED AT 400 WORDS)     

Anatomical and functional recovery folloing spinal cord transection in the chick embryo

Following complete transection of the thoracic spinal cord at various times during embryonic development, chick embryos and posthatched animals exhibited various degrees of anatomical and functional recovery depending upon the age of injury. Transection on embryonic day 2 (E2), when neurogenesis is still occurring and before descending or ascending fiber tracts have formed, produced no noticeable behavioral or anatomical deficits. Embryos hatched on their own and were behaviorally indistinguishable from control hatchlings. Similar results were found following transection on E5, an age when neurogenesis is complete and when ascending and descending fiber tracts have begun to project through the thoracic region. Within 48 h following injury on E5, large numbers of nerve fibers were observed growing across the site of transection. By E8, injections of horseradish peroxidase (HRP) administered caudal to the lesion, retrogradely labelled rostral spinal and brainstem neurons. Embryos transected on E5 were able to hatch and could stand and locomote posthatching in a manner that was indistinguishable from controls. Following spinal cord transections on E10, anatomical recovery of the spinal cord at the site of injury was not quite as complete as after E5 transection. Nonetheless, anatomical continuity was restored at the site of injury, axons projected across this region, and rostral spinal and brainstem neurons could be retogradely labelled following HRP injections administered caudal to the lesion. At least part of this anatomical recovery may be mediated by the regeneration or regrowth of lesioned axons. Although none of the embryos transected on E10 that survived to hatching were able to hatch on their own, because several shamoperated embryos were also unable to hatch, we do not attribute this deficit to the spinal transection. When E10-transected embryos were aided in escaping from the shell, they were able to support their own weight, could stand, and locomote, and were generally comparable, behaviorally, to control hatchlings. Repair of the spinal cord following transection on E15 was considerably less complete compared to embryos transected on E2, E5, or E10. However, in some cases, a degree of anatomical continuity was eventually restored and a few spinal neurons rostral to the lesion could be retrogradely labelled with HRP. By contrast, labelled brainstem neurons were never observed following E15 transection. E15 transected embryos were never able to hatch on their own, and when aided in escaping from the shell, the hatchlings were never able to stand, support their own weight or locomote. We conclude that successful anatomical and functional recovery occurs following a complete spinal cord transection in the chick embryo made any time between E2 and E10. By E15, however, there is an altered response to the transection such that anatomical continuity is not restored sufficiently to mediate behavioral or functional recovery. Although the altered response of the chick embryo spinal cord to injury between E10 and E15 could be due to a variety of factors, we favor the notion that cellular or molecular changes associated with axonal growth and guidance occur at this time that are responsible for the transition from successful to unsuccessful recovery.     

The formation of the segmental projections of the primary afferents of the wing and leg in the chick embryo spinal cord]

A comparative HRP study of formation of connections between primary sensory nerve fibers and motoneurones in brachial and lumbosacral cord segments has been made on chick embryos between the 6.5th and 10th days of incubation. HRP was applied to the cut ends of the appropriate nerves via suction pipettes on isolated superfused spinal cord preparation. The first contacts between primary sensory collaterals and motoneuronal dendrites were found to appear both in lumbosacral and branchial cord segments at the same stage, i.e. at the 7.5-8th days of development. This observation does not confirm the widely accepted belief on rostrocaudal sequence of development of the spinal cord, indicating that exceptions from this developmental gradient are quite possible.     

Changes in Rapid Transport of Phospholipids in the Rat Sciatic Nerve During Axonal Regeneration

Abstract: Axonal transport of phospholipids in normal and regenerating sciatic nerve of the rat was studied. At various intervals after axotomy of the right sciatic nerve in the midthigh region and subsequent perineurial sutures of the transected fascicles, a mixture of 60 μCi [Me-^HC]choline and 15 μCi [2-³H]glycerol in the region of the spinal motor neurons of the L5 and L6 segments was injected bilaterally. The amount of radioactive lipid (and in certain cases its distribution in various lipid classes) along the nerve was determined as a function of time. Three days after fascicular suture and 6 h after spinal cord injection of precursors, there was an accumulation of labeled phospholipids and sphingolipids in the transected sciatic nerve in the region immediately proximal to the site of suture. Nine days after, there was a marked increase in the accumulation of radioactivity in the distal segments of the injured nerve, which increased up to 14 days after cutting and disappeared as regeneration proceeded (21–45 days). In all segments of both normal and regenerating nerve fibers, as well as in L5 and L6 spinal cord segments, only phosphatidylcholine and sphingomyelin were labeled with [¹⁴C]choline. These results suggest that the regeneration process in a distal segment of a peripheral neuron, following cutting and fascicular repairing by surgical sutures, is sustained in the first 3 weeks by changes in the amount of phospholipids rapidly transported along the axon towards the site of nerve fiber outgrowth.     

Light-optic, electron microscopic and electrophysiological study of centrifugal fibers of the retina in the lamprey Lampetra fluviatilis

Light and electronmicroscopic studies have been made on retinal structures in the lamprey labeled by horseradish peroxidase injected into the peripheral end of the cut optic nerve or to the midbrain tectum. On total retinal preparations, labeled axons were revealed together with dendrites and ganglionic cell bodies, as well as branching (presumably retinopetal) fibers, fine endings of which come closely to the labeled dendrites of the ganglionic cells. Electron microscopic data indicate that the labeled terminations of afferent fibers from synapses with both labeled and unlabeled dendrites, as well as with unlabeled neuronal bodies. It is concluded that centrifugal fibers in lamprey retina form contacts with the bodies and dendrites of the amacrine cells and dendrites of the ganglionic cells. Results of intracellular registration of responses of various retinal elements to the electrical stimulation of the optic nerve support this conclusion.     

Spinal projections from the rhombencephalon in the toad

Rhombencephalic cell groups projecting to the spinal cord are demonstrated following single pressure injections and/or iontophoretic ejections of HRP solution in either cervical or lumbar enlargements of the toad spinal cord. A group uptake and transport of HRP were obtained with both application techniques, when sufficiently long survival times (8-11 days) were used. Following injections in the cervical cord labeled cells are located mostly in the ventral nucleus of the VIIIth nerve and in the medial zone of the rhombencephalic reticular formation, i.e. the nucleus reticularis inferior, medius and superior. Following injections in the lumbar enlargement the majority of labeled cells are situated in the caudalmost portion of the ventral nucleus of the VIIIth nerve and in the nucleus reticularis inferior. These observations indicate that in the toad the main supraspinal descending pathways from the rhombencephalon originate in the ventral nucleus of the VIIIth nerve and the medial zone of the reticular formation, and that both these pathways are somatotopically organized.     

Minimal essential length of Clostridium botulinum C3 peptides to enhance neuronal regenerative growth and connectivity in a non-enzymatic mode

C3 ADP-ribosyltransferase is a valuable tool to study Rho-dependent cellular processes. In the current study we investigated the impact of enzyme-deficient peptides derived from Clostridium botulinum C3 transferase in the context of neuronal process elongation and branching, synaptic connectivity, and putative beneficial effects on functional outcome following traumatic injury to the CNS. By screening a range of peptidic fragments, we identified three short peptides from C3bot that promoted axon and dendrite outgrowth in cultivated hippocampal neurons. Furthermore, one of these fragments, a 26-amino acid peptide covering the residues 156-181 enhanced synaptic connectivity in primary hippocampal culture. This peptide was also effective to foster axon outgrowth and re-innervation in organotypical brain slice culture. To evaluate the potential of the 26mer to foster repair mechanisms after CNS injury we applied this peptide to mice subjected to spinal cord injury by either compression impact or hemisection. A single local administration at the site of the lesion improved locomotor recovery. In addition, histological analysis revealed an increased serotonergic input to lumbar motoneurons in treated compared with control mice. Pull-down assays showed that lesion-induced up-regulation of RhoA activity within the spinal cord was largely blocked by C3bot peptides despite the lack of enzymatic activity.     

Anatomical Studies of the Spinocervical Tract of the Rat

The retrograde transport of horseradish peroxidase (HRP) was used to identify and examine the cells of origin of the spinocervical tract (SCt) in the rat. Initially, precise data on the boundaries of the rat lateral cervical nucleus (LCn) were gathered after injecting HRP into the ventrobasal thalamus. These data indicated that the LCn of the rat is restricted to a region on the extreme lateral edge of the dorsalmost portion of the lateral funiculus (DLf) within spinal segment C₂ Following small iontophoretic injections of HRP that were restricted to this area, labeled SCt neurons were found in the ipsilateral nucleus proprius at all levels of the spinal cord but were most numerous in the cervical enlargement. Lesion studies indicated that the overwhelming majority of SCt axons ascend to the LCn within the DLf. In an attempt to determine whether our injection techniques labeled a significant number of cells through axons of passage, HRP injections were made in the DLf ventral to the LCn. Such injections labeled, presumably through axons of passage, cells in several areas of the spinal cord gray matter, including a large number in the contralateral marginal zone Injections in areas immediately rostral to the LCn labeled 20% or less of the total number of cells within the enlargements that were labeled by injections into the LCn. Thus, the majority of cells labeled by injections of HRP into the LCn were labeled through preterminal fibers or terminals themselves. The cells of origin of the SCt in the rat are similar in location to those in the cat but far fewer in number.     

Nogo-66 receptor prevents raphespinal and rubrospinal axon regeneration and limits functional recovery from spinal cord injury

Axon regeneration after injury to the adult mammalian CNS is limited in part by three inhibitory proteins in CNS myelin: Nogo-A, MAG, and OMgp. All three of these proteins bind to a Nogo-66 receptor (NgR) to inhibit axonal outgrowth in vitro. To explore the necessity of NgR for responses to myelin inhibitors and for restriction of axonal growth in the adult CNS, we generated ngr(-/-) mice. Mice lacking NgR are viable but display hypoactivity and motor impairment. DRG neurons lacking NgR do not bind Nogo-66, and their growth cones are not collapsed by Nogo-66. Recovery of motor function after dorsal hemisection or complete transection of the spinal cord is improved in the ngr(-/-) mice. While corticospinal fibers do not regenerate in mice lacking NgR, regeneration of some raphespinal and rubrospinal fibers does occur. Thus, NgR is partially responsible for limiting the regeneration of certain fiber systems in the adult CNS.     

Ultrastructural analysis of spinal primary afferent fibers within the circular muscle of the cat lower esophageal sphincter

We have analyzed the ultrastructural characteristics and environment of spinal primary afferent fibers that run within the circular muscle of the cat lower esophageal sphincter. These were selectively labeled by anterogradely transported cholera toxin B subunit conjugated with horseradish peroxidase. Most of the labeled fibers were perpendicular to the muscle cells but some ran sinuously or parallel to the muscle cells. All the labeled fibers were unmyelinated and exhibited relatively rare varicosities. Most of the fibers were in large nerve fiber bundles surrounded by perineurium and probably project to the mucosa. Only some fibers that were in small nerve fiber bundles with no perineurium ran parallel to the musculature and established close relationships with smooth muscle cells. They might be a small subpopulation of the spinal tension receptors, most of the other spinal tension receptors being located in the myenteric plexus area, between the circular and longitudinal muscle. Accepted: 2 December 1999     

Neuroanatomical and functional analysis of neural tube formation in notochordless Xenopus embryos; laterality of the ventral spinal cord is lost.

Notochordless Xenopus embryos were produced by u.v. irradiation of the uncleaved fertilized egg. The spinal cords were examined using intermediate filament staining for glial cells, retrograde HRP staining for neuronal morphology and an anti-glycinergic antibody to reveal commissural cells and axons. The floorplate cells of the normal cord appear to be absent and their position along the ventral midline of the cord is occupied by motor neurones, Kolmer-Agduhr cells, radial glial cells and a ventrally placed marginal zone containing the longitudinal axons. Motor neurone number is reduced to 15% of control values, and the sensory extramedullary cell number is increased twentyfold. Commissural axons are still able to cross the ventral cord but do so at abnormal angles and some commissural axons continue to grow circumferentially up the contralateral side of the cord rather than turning to grow longitudinally. Extracellular electrophysiological recordings from motor axons reveal that the normal alternation of locomotor activity on the left and right side of the embryo is lost in notochordless animals. These results suggest that the notochord and/or the normal floor plate structure are important for the development of the laterality of spinal cord connections and may influence motor neurone proliferation or differentiation.     

Primary projections of the trigeminal nerve in two species of sturgeon: Acipenser oxyrhynchus and Scaphirhynchus platorynchus

Horseradish peroxidase histochemical studies of afferent and efferent projections of the trigeminal nerve in two species of chondrostean fishes revealed medial, descending and ascending projections. Entering fibers of the trigeminal sensory root project medially to terminate in the medial trigeminal nucleus, located along the medial wall of the rostral medulla. Other entering sensory fibers turn caudally within the medulla, forming the trigeminal spinal tract, and terminate within the descending trigeminal nucleus. The descending trigeminal nucleus consists of dorsal (DTNd) and ventral (DTNv) components. Fibers of the trigeminal spinal tract descend through the lateral alar medulla and into the dorsolateral cervical spinal cord. Fibers exit the spinal tract throughout its length, projecting to the ventral descending trigeminal nucleus (DTNv) in the medulla and to the funicular nucleus at the obex. Retrograde transport of HRP through sensory root fibers also revealed an ascending bundle of fibers that constitutes the neurites of the mesencephalic trigeminal nucleus, cell bodies of which are located in the rostral optic tectum. Retrograde transport of HRP through motor root fibers labeled ipsilateral cells of the trigeminal motor nucleus, located in the rostral branchiomeric motor column.     

Complete penetration of antibodies into vibratome sections after glutaraldehyde fixation and ethanol treatment: light and electron microscopy for neuropeptides.

To develop a method for quantitative electron microscopic immunocytochemistry on neural tissue of CNS, we tested the extent to which ethanol treatment would improve the penetration of immunoreagents through vibratome sections fixed in high concentrations of glutaraldehyde without compromising ultrastructure. Transverse or sagittal vibratome sections (60-80 microns) of spinal cord perfused with 1% formaldehyde plus 1% or 2.5% glutaraldehyde were washed in 50% ethanol for 0-70 min and stained to reveal immunoreactivity for neuropeptide Y (NPY). Semi-thin (1 micron) or ultra-thin sections were used to assess the depth to which NPY nerve fibers in the dorsal horn were stained. Without ethanol washing, immunoreactive nerve fibers were visualized only in the surface 5-10 microns of transverse or sagittal vibratome sections. In transverse vibratome sections, NPY nerve fibers, which ran perpendicular to the cut surfaces of the sections, were entirely stained after a 30-min wash in 50% ethanol. The numbers of NPY-immunoreactive varicosities and synapses were comparable at the surfaces and in the centers of the vibratome sections. In sagittal sections, where NPY nerve fibers ran parallel to the cut surfaces, fibers in the centers of vibratome sections could not be labeled even after 70 min in 50% ethanol. Substance P- and enkephalin (Enk)-immunoreactive nerve fibers could also be completely stained in transverse sections of spinal cord or medulla oblongata after 30-min exposure to ethanol. Ethanol washing had no significant deleterious effects on ultrastructure, although the amount of cytoplasmic matrix in neurons decreased with increasing exposure. These results indicate that washing with 50% ethanol for at least 30 min allows immunoreagents to penetrate completely through nerve fibers fixed with high concentrations of glutaraldehyde, as long as the fibers have cut ends at both surfaces of a vibratome section. This technique makes possible quantitative electron microscopic immunocytochemical studies and is proving a useful tool for defining synaptic connections in the CNS.     

Stem cell growth becomes predominant while neural plate progenitor pool decreases during spinal cord elongation

The antero-posterior dispersion of clonally related cells is a prominent feature of axis elongation in vertebrate embryos. Two major models have been proposed: (i) the intercalation of cells by convergent-extension and (ii) the sequential production of the forming axis by stem cells. The relative importance of both of these cell behaviors during the long period of elongation is poorly understood. Here, we use a combination of single cell lineage tracing in the mouse embryo, computer modeling and confocal video-microscopy of GFP labeled cells in the chick embryo to address the mechanisms involved in the antero-posterior dispersion of clones. In the mouse embryo, clones appear as clusters of labeled cells separated by intervals of non-labeled cells. The distribution of intervals between clonally related clusters correlates with a statistical model of a stem cell mode of growth only in the posterior spinal cord. A direct comparison with published data in zebrafish suggests that elongation of the anterior spinal cord involves similar intercalation processes in different vertebrate species. Time-lapse analyses of GFP labeled cells in cultured chick embryos suggest a decrease in the size of the neural progenitor pool and indicate that the dispersion of clones involves ordered changes of neighborhood relationships. We propose that a pre-existing stem zone of growth becomes predominant to form the posterior half of the axis. This temporal change in tissue-level motion is discussed in terms of the clonal and genetic continuities during axis elongation.     

Autoradiographic labeling of spinal cord neurons with high affinity choline uptake in cell culture

Embryonic chick spinal cord neurons grown in dissociated cell culture have a high affinity uptake mechanism for choline. We find that, in addition to acetylcholine synthesis, the accumulated choline is used for the synthesis of metabolites such as lipids that are retained in part by conventional fixation techniques. As a result autoradiographic methods can be used to identify the cells that have the uptake mechanism in spinal cord cultures. About 60% of the neurons are labeled by [³H]choline uptake in cultures prepared with spinal cord cells from 4-day-old embryos, and about 40% are labeled in cultures prepared with cord cells from 7-day-old embryos. Neurons that innervate skeletal myotubes in spinal cord-myotube cultures are consistently labeled by [³H]choline uptake. Neurons unlabeled by the procedure are viable: they exclude the dye trypan blue and accumulate ¹⁴C-amino acids for protein synthesis. Most of the neurons unlabeled by [³H]choline uptake can instead be labeled by uptake of γ-[³H]aminobutyric acid, and vice versa. These results suggest that high affinity choline uptake can be used to label cholinergic neurons in cell culture, and that at least some populations of noncholinergic neurons are not labeled by the procedure. It cannot yet be concluded, however, that all labeled neurons are cholinergic since more labeled neurons are obtained per cord than would be expected from the number of neurons making up identified cholinergic populations in vivo. A three- to fourfold increase in the amount of high affinity choline uptake is observed between Days 3 and 15 in culture for spinal cord cells obtained from 4-day-old embryos. The number of [³H]choline-labeled neurons in such cultures decreases slightly during the same period, suggesting that the increase in uptake reflects neuronal growth or development rather than an increase in population size. Both the magnitude of the uptake and the number of [³H]choline-labeled neurons are the same for spinal cord cells grown with and without skeletal myotubes.