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.     

Comparison of [3H]resiniferatoxin binding to spinal cord and dorsal root ganglia of newborn and adult rats

Capsaicin is frequently used in neurobiological investigations to selectively inhibit response by the primary sensory afferent neurons. The effectiveness of treatment depends significantly on the age of the animals; newborns are both quantitatively and qualitatively more sensitive than adults. In the present study, we used the [³H]resiniferatoxin binding assay to determine whether this different susceptibility to capsaicin between newborns and adult animals may reflect differences either in receptor affinity or density. We report here that whole spinal cord membranes of neonates bound [³H]RTX with similar affinity and positive cooperativity as did the spinal cord membranes from adult animals (K_d values were 24.8 ± 3.7 and 26.8 ± 4.8 pM, respectively; Hill coefficients were 2.25 ± 0.03 and 2.17 ± 0.05, respectively). However, the receptor density was three - fold higher in the spinal cord membranes of neonates than of adult rats (B_max values were 142 ± 13 and 43 ± 3 fmol/mg protein, respectively). We found no significant difference in the [³H]RTX binding properties of dorsal root ganglia membranes of newborn and adult animals. Our results suggest than a higher density of the vanilloid receptor in the spinal cord (but not in the dorsal root ganglia) of newborn animals may contribute to the quantitative differences between the sensitivity of adult animals and neonates.     

Immunohistochemical, Histochemical and Radioassay Analysis of Nitric Oxide Synthase Immunoreactivity in the Lumbar and Sacral Dorsal Root Ganglia of the Dog

Summary In this study, immunohistochemistry for neuronal nitric oxide synthase (bNOS-IR), nicotinamide adenine dinucleotide phosphate diaphorase histochemistry (NADPHd) and nitric oxide synthase radioassay were used to study the occurrence, number and distribution pattern of nitric oxide synthesizing neurons in the lumbar (L1–L7) and sacral (S1–S3) dorsal root ganglia of the dog. Nitric oxide synthase immunolabelling was present in a large number of small- (area <1000 μm²) and medium-sized (area 1000–2000 μm²) as well as in a limited number of large-sized (area >2000 μm²) neurons. Although neuronal nitric oxide synthase immunolabelling and histochemical staining provided intense staining of multiple small- and medium-sized neurons in all lumbar and sacral dorsal root ganglia, immunolabelled or histochemically stained somata exhibited little topographic distribution in individual dorsal root ganglia. Great heterogeneity was noticed in the immunolabelling of medium-sized nitric oxide synthase immunopositive neurons ranging from lightly immunolabelled somata to heavily immunoreactive ones with completely obscured nuclei. Both staining procedures proved to be highly effective in visualizing intraganglionic fibers of various diameters. In general, the largest fibers revealed at the peripheral end of lumbar and sacral dorsal root ganglia were larger, 6.49–9.35 μm in diameter, while those running centrally and proceeding into the dorsal roots were about 30% reduced, ranging between 5.32 and 8.67 μm in diameter. Peripherally, the occurrence of nitric oxide synthase detected in axonal profiles, and confirmed histochemically, in the specimens of the femoral and sciatic nerves, is the first indication of the presence of nitric oxide synthase in the peripheral processes of somata located in L4–S2 dorsal root ganglia. Large and thin central nitric oxide synthase immunoreactive processes of L1–S3 dorsal root ganglion neurons segregate shortly before entering the spinal cord, the former making a massive medial bundle in the dorsal root accompanied by a slim lateral bundle penetrating Lissauer's tract. Quantitative assessment of the distribution of bNOS-IR and/or NADPHd-stained neurons showed a peculiar pattern in relation to spinal levels. Apparent incongruity was found in the total number of NADPHd-stained versus bNOS-IR neurons, demonstrating a clear prevalence of small bNOS-IR somata in all lumbar ganglia, while medium-sized NADPHd-stained somata clearly prevailed all along the rostrocaudal axis with a peak in L5 ganglion. While the number of small bNOS-IR neurons clearly outnumbered NADPHd-stained and NADPHd-unstained somata in S1–S3 ganglia, an inverse relation appeared comparing the total number of medium-sized NADPHd-stained and NADPHd-unstained somata compared with the number of moderate and intense bNOS-IR neurons. Densitometry of bNOS-IR and NADPHd-stained neurons in lumbar and sacral ganglia revealed two distinct subsets of densitometric profiles, one relating to more often found medium-sized bNOS immunolabelled and the other, characteristic for moderately bNOS immunoreactive somata of the same cell size. Considerable differences in catalytic nitric oxide synthase activity, determined by conversion of [³H]arginine to [³H]citrulline were obtained in lumbosacral dorsal root ganglia all along the lumbosacral intumescence, the lowest (0.898± 0.2 dpm/min/μg protein) being in the L4 dorsal root ganglion and the highest (4.194± 0.2 dpm/min/μg protein) in the S2 dorsal root ganglion.     

COMPARISON OF LEVELS OF ADENOSINE 3'',5''-MONOPHOSPHATE IN HIGHLY PURIFIED AND MIXED PRIMARY CULTURES OF NEURONS AND NON-NEURONAL CELLS FROM EMBRYONIC CHICK SYMPATHETIC GANGLIA

Primary cultures containing ≥99% neurons, ≥99% non-neuronal cells (glia), or both cell types were prepared from the sympathetic ganglia of 12-day chick embryos. Levels of cyclic AMP in the non-neuronal cells (～14 pmol/mg protein) were approximately 3-fold higher than levels in the neurons (～4 pmol/mg protein). Mixed cultures had concentrations of cyclic AMP which fell between the values measured for pure neuronal and pure non-neuronal cultures. The measured cyclic AMP values of mixed cultures were indistinguishable from values predicted by summing the expected contributions of the neurons and non-neuronal cells. Thus, contact between the neurons and non-neuronal cells in these mixed cultures did not appear to alter the level of cyclic AMP in either cell type. Neuronal-glial interactions, such as the specific neuronal stimulation of non-neuronal cell proliferation, occurred independently of any changes in the level of cyclic AMP in the mixed cultures. Cell density was varied in both pure and mixed cultures, and both cyclic AMP concentrations and amounts of [³H]thymidine incorporation into DNA were measured. The cyclic AMP content of the non-neuronal cells varied inversely with cell density. [³H]Thymidine incorporation was independent of cell density in both neuronal and non-neuronal cultures. Parallel density-dependent decreases in cyclic AMP concentration and [³H]thymidine incorporation were observed in mixed cultures as cell density was increased. The data suggest that there is no relationship between changes in rate of non-neuronal cell proliferation and cyclic AMP levels in these cultures.     

A few axonal proteins distinguish ventral spinal cord neurons from dorsal root ganglion neurons

A series of proteins putatively involved in the generation of axonal diversity was identified. Neurons from ventral spinal cord and dorsal root ganglia were grown in a compartmented cell-culture system which offers separate access to cell somas and axons. The proteins synthesized in the neuronal cell somas and subsequently transported into the axons were selectively analyzed by 2-dimensional gel electrophoresis. The patterns of axonal proteins were substantially less complex than those derived from the proteins of neuronal cell bodies. The structural and functional similarity of axons from different neurons was reflected in a high degree of similarity of the gel pattern of the axonal proteins from sensory ganglia and spinal cord neurons. Each axonal type, however, had several proteins that were markedly less abundant or absent in the other. These neuron-population enriched proteins may be involved in the implementation of neuronal diversity. One of the proteins enriched in dorsal root ganglia axons had previously been found to be expressed with decreased abundance when dorsal root ganglia axons were co-cultured with ventral spinal cord cells under conditions in which synapse formation occurs (P. Sonderegger, M. C. Fishman, M. Bokoum, H. C. Bauer, and P.G. Nelson, 1983, Science [Wash. DC], 221:1294-1297). This protein may be a candidate for a role in growth cone functions, specific for neuronal subsets, such as pathfinding and selective axon fasciculation or the initiation of specific synapses. The methodology presented is thus capable of demonstrating patterns of protein synthesis that distinguish different neuronal subsets. The accessibility of these proteins for structural and functional studies may contribute to the elucidation of neuron-specific functions at the molecular level.     

Expression,localization, and function of transforming growth factor-βs in embryonic chick spinal cord,hindbrain, and dorsal root ganglia

We have studied the localizations of transforming growth factor-beta (TGF-β) 2 and 3 immunohistochemically using isoform-specific antibodies and TGF-β3 mRNA by in situ hybridization in the nervous system of the 3- to 15-day-old chick embryo with special reference to spinal cord, hindbrain, and dorsal root ganglia (DRG). At embryonic day (E) 3, TGF-β3 mRNA as well as TGF-β2 and 3 immunoreactivities (IRs) were most prominent in the notochord, wall of the aorta, and dermomyotome. At E5 and E7, strong TGF-β2 and 3 IR were seen in or on radial glia of spinal cord and hindbrain. Radial glia in the floor plate region and ventral commissure gave the most intense signal. In the DRG, fiber strands of intense IRs representing extracellular matrix or satellite cells were seen. Neuronal perikarya did not become IR for TGF-β2 and 3 until E11, but even then the moderate signals for TGF-β3 mRNA could not be specifically localized to the neuronal cell bodies. In E11 and older embryos, spinal cord glial or glial progenitor cells, but not neuronal cell bodies were labeled for TGF-β3 mRNA. Immunocytochemistry and western blot analysis indicated that E8 DRG neurons have the TGF-β receptor type II, and treatment of these cells with NGF induces expression of TGF-β3 mRNA. The TGF-β isoforms 1, 2, and 3 did not promote survival of E8 DRG neurons in dissociated cell cultures. All three TGF-β isoforms, however, promoted neurite growth from E8 DRG explants, but were less potent than nerve growth factor. Our data suggest identical localizations of TGF-β2 and -β3 IR in the developing chick and mammalian nervous systems, underscoring the general importance of TGF-βs in fundamental events of neural development. © 1996 John Wiley & Sons, Inc.     

Distribution of five peptides, three general neuroendocrine markers, and two synaptic-vesicle-associated proteins in the spinal cord and dorsal root ganglia of the adult and newborn dog: an immunocytochemical study

This study describes the immunocytochemical distribution of five neuropeptides (calcitonin gene-related peptide [CGRP], enkephalin, galanin, somatostatin, and substance P), three neuronal markers (neurofilament triplet proteins, neuron-specific enolase [NSE], and protein gene product 9.5), and two synaptic-vesicle-associated proteins (synapsin I and synaptophysin) in the spinal cord and dorsal root ganglia of adult and newborn dogs. CGRP and substance P were the only peptides detectable at birth in the spinal cord; they were present within a small number of immunoreactive fibers concentrated in laminae I-II. CGRP immunoreactivity was also observed in motoneurons and in dorsal root ganglion cells. In adult animals, all peptides under study were localized to varicose fibers forming rich plexuses within laminae I-III and, to a lesser extent, lamina X and the intermediolateral cell columns. Some dorsal root ganglion neurons were CGRP- and/or substance P-immunoreactive. The other antigens were present in the spinal cord and dorsal root ganglia of both adult and newborn animals, with the exception of NSE, which, at birth, was not detectable in spinal cord neurons. Moreover, synapsin I/synaptophysin immunoreactivity, at birth, was restricted to laminae I-II, while in adult dogs, immunostaining was observed in terminal-like elements throughout the spinal neuropil. These results suggest that in the dog spinal cord and dorsal root ganglia, peptide-containing pathways complete their development during postnatal life, together with the full expression of NSE and synapsin I/synaptophysin immunoreactivities. In adulthood, peptide distribution is similar to that described in other mammals, although a relative absence of immunoreactive cell bodies was observed in the spinal cord.     

Multiple roles of mouse Numb in tuning developmental cell fates.

BACKGROUND: Notch signaling regulates multiple differentiation processes and cell fate decisions during both invertebrate and vertebrate development. Numb encodes an intracellular protein that was shown in Drosophila to antagonize Notch signaling at binary cell fate decisions of certain cell lineages. Although overexpression experiments suggested that Numb might also antagonize some Notch activity in vertebrates, the developmental processes in which Numb is involved remained elusive. RESULTS: We generated mice with a homozygous inactivation of Numb. These mice died before embryonic day E11.5, probably because of defects in angiogenic remodeling and placental dysfunction. Mutant embryos had an open anterior neural tube and impaired neuronal differentiation within the developing cranial central nervous system (CNS). In the developing spinal cord, the number of differentiated motoneurons was reduced. Within the peripheral nervous system (PNS), ganglia of cranial sensory neurons were formed. Trunk neural crest cells migrated and differentiated into sympathetic neurons. In contrast, a selective differentiation anomaly was observed in dorsal root ganglia, where neural crest--derived progenitor cells had migrated normally to form ganglionic structures, but failed to differentiate into sensory neurons. CONCLUSIONS: Mouse Numb is involved in multiple developmental processes and required for cell fate tuning in a variety of lineages. In the nervous system, Numb is required for the generation of a large subset of neuronal lineages. The restricted requirement of Numb during neural development in the mouse suggests that in some neuronal lineages, Notch signaling may be regulated independently of Numb.     

Developmental changes in unique cell surface antigens of chick embryo spinal motoneurons and ganglion cells

The monoclonal antibody technique was used to investigate neuronal heterogeneity and its developmental changes in the chick embryo trunk especially at the thoracic level. We report here four monoclonal antibodies (called SC 1, SC 2, SC 3, and SC 4) that bound to cell surface antigens. These antigens appeared to be proteins or glycoproteins because of their susceptibility to trypsin. In the spinal cord, antibody SC 3 stained all cells, but antibody SC 1 specifically stained motoneurons and ventral epithelial cells. The staining of motoneurons by antibody SC 1 was transient. It appeared at early stages (stage 16-17; Hamburger and Hamilton), but decreased markedly in intensity at older stages (stage 30-31). Antibody SC 2 did not stain cells in the spinal cord. It stained only neurons in the dorsal root and sympathetic ganglia. Antibody SC 4 stained only cells derived from the neural crest at the early stages (stage 16-20). At later stages, it stained a wider population of cells, including sensory neurons, Schwann cells, and cells in the central nervous system. In the dorsal root ganglion, antibodies SC 1 and SC 2 stained only neuronal cells whereas antibodies SC 3 and SC 4 stained both neuronal and glial cells. The dorsal root ganglionic antigens recognized by these antibodies were not expressed concurrently but appeared in a developmental sequence. Staining with antibodies SC 3 and SC 4 appeared first, then SC 1, and finally SC 2. Among these four antigens, the antigens common to both neuronal and glial cells appeared earlier than the neuron specific antigens. Thus, our monoclonal antibodies revealed heterogeneities in cell surface neuronal molecules and their transient and sequential appearance during embryonic development.     

The cranial sensory ganglia in culture: Differences in the response of placode-derived and neural crest-derived neurons to nerve growth factor

Explants of cranial sensory ganglia and dorsal root ganglia from embryonic chicks of 4 to 16 days incubation (E4 to E16) were grown for 24 hr in collagen gels with and without nerve growth factor (NGF) in the culture medium. NGF elicited marked neurite outgrowth from neural crest-derived explants, i.e., dorsal root ganglia, the dorsomedial part of the trigeminal ganglion, and the jugular ganglion. This response was first observed in ganglia taken from E6 embryos, reached a maximum between E8 and E11, and gradually declined through E16. Explants in which the neurons were of placodal origin varied in their response to NGF. There was negligible neurite outgrowth from explants of the ventrolateral part of the trigeminal ganglion and the vestibular ganglion grown in the presence of NGF. The geniculate, petrosal, and nodose ganglia exhibited an early moderate response to NGF. This was first evident in ganglia taken from E5 embryos, reached a maximum by E6, and declined through later ages, becoming negligible by E13. Dissociated neuron-enriched cultures of vestibular, petrosal, jugular, and dorsal root ganglia were established from embryos taken at E6 and E9. At both ages NGF elicited neurite outgrowth from a substantial proportion of neural crest-derived neurons (jugular and dorsal root ganglia) but did not promote the growth of placode-derived neurons (vestibular and petrosal ganglia). Our findings demonstrate a marked difference in the response of neural crest and placode-derived sensory neurones to NGF. The data from dissociated neuron-enriched cultures suggest that NGF promotes survival and growth of sensory ganglionic neurons of neural crest origin but not of placodal origin. The data from explant cultures suggest that NGF promotes neurite outgrowth from placodal neurons of the geniculate, petrosal, and nodose ganglia early in their ontogeny. However, we argue that this fibre outgrowth emanates not from the placodal neurons but from neural crest-derived cells which normally give rise only to satellite cells of these ganglia.     

E-cadherin expression in a particular subset of sensory neurons.

We found that the dorsal root ganglia (DRG) and trigeminal ganglia of mouse embryos express the E-cadherin cell-cell adhesion molecule and analyzed its expression profile. E-cadherin expression began around Embryonic Day 12 (E12) in these ganglia, thereafter increased, and persisted to the adult stage. This cadherin was expressed by 10 and 30% of DRG neurons in E17 and postnatal animals, respectively, as well as by satellite cells and some Schwann cells. E-cadherin-positive primary sensory fibers terminated only in a narrow region of the dorsal horn of the spinal cord, which was identified as part of lamina II by double-staining for E-cadherin and substance P or somatostatin. This E-cadherin expressing area of the spinal cord extended to part of the trigeminal nucleus in the medulla. These results showed that E-cadherin is expressed in a particular subset of primary sensory neurons which may have specific functional properties. We suggest that this adhesion molecule may play a role in the selective adhesion of sensory neuronal fibers.     

Hot receptors in the brain

Background

The complex neuronal circuitry of the dorsal horn of the spinal cord is as yet poorly understood. However, defining the circuits underlying the transmission of information from primary afferents to higher levels is critical to our understanding of sensory processing. In this study, we have examined phosphodiesterase 1C (Pde1c) BAC transgenic mice in which a green fluorescent protein (GFP) reporter gene reflects Pde1c expression in sensory neuron subpopulations in the dorsal root ganglia and spinal cord.

Results

Using double labeling immunofluorescence, we demonstrate GFP expression in specific subpopulations of primary sensory neurons and a distinct neuronal expression pattern within the spinal cord dorsal horn. In the dorsal root ganglia, their distribution is restricted to those subpopulations of primary sensory neurons that give rise to unmyelinated C fibers (neurofilament 200 negative). A small proportion of both non-peptidergic (IB4-binding) and peptidergic (CGRP immunoreactive) subclasses expressed GFP. However, GFP expression was more common in the non-peptidergic than the peptidergic subclass. GFP was also expressed in a subpopulation of the primary sensory neurons immunoreactive for the vanilloid receptor TRPV1 and the ATP-gated ion channel P2X₃. In the spinal cord dorsal horn, GFP positive neurons were largely restricted to lamina I and to a lesser extent lamina II, but surprisingly did not coexpress markers for key neuronal populations present in the superficial dorsal horn.

Conclusion

The expression of GFP in subclasses of nociceptors and also in dorsal horn regions densely innervated by nociceptors suggests that Pde1c marks a unique subpopulation of nociceptive sensory neurons.     

The culture of chick embryo dorsal root ganglionic cells on polylysine-coated plastic

Polylysine-coated culture surfaces are strongly adhesive for neural cells, restrict locomotion on nonneuronal elements, but do not inhibit neurite elongation. In the present study, culture dishes were pre-treated with poly-d-lysine (PDL) at various concentrations, seeded with dissociates from 8-day chick embryo dorsal root ganglia, and incubated under conditions that normally support both neuronal survival and nonneuronal proliferation. Pretreatment with low (0.1 mg/ml) PDL concentrations had no effect on neuronal survival and neuritic growth, but entirely prevented an increase in ganglionic nonneurons, yielding a numerically stable culture greatly enriched in neurons. Higher PDL concentrations caused increasing losses in both cell classes. The 50% levels of cell loss were achieved at about the same PDL dose, but earlier for neurons than nonneurons and still with no impairment of neuritic growth from the surviving neurons. A procedure was developed to compare acid-soluble and acid-precipitable accumulation of radioactivity under 1-hr pulses of [³H]uridine, which was applicable even to poorly attached cells. The cytotoxic effects of higher PDL pretreatments was revealed as early as 6 hr after seeding by 2- to 4-fold lower radioaccumulation. The data are discussed in terms of possible regulations of cell permeability and metabolism by adhesive interactions between cells and their substratum, or other cells.     

Supersensitivity of the GABA receptor in the frog spinal cord, as induced by kainic acid

In the isolated frog spinal cord perfused with kainic acid (KA, 5 X 10(-4) M) containing Ringer's solution, within 2 hr there were increases in the amplitude of the dorsal root depolarization, as induced by the GABA-agonists. KA perfusion produced increases in the specific binding of [3H]muscimol to crude synaptic membranes and incubation with KA for 3 hr did not increase [3H]muscimol binding. [3H]GABA was released from KA-treated spinal cord slices in the presence of high K+. KA-induced supersensitivity of the dorsal root to GABA may relate to direct actions on primary afferent terminals and not to denervation of GABAergic neurons.     

Analysis of high PSA N-CAM expression during mammalian spinal cord and peripheral nervous system development.

Using a monoclonal antibody that recognizes specifically a high polysialylated form of N-CAM (high PSA N-CAM), the temporal and spatial expression of this molecule was studied in developing spinal cord and neural crest derivatives of mouse truncal region. Temporal expression was analyzed on immunoblots of spinal cord and dorsal root ganglia (DRGs) extracts microdissected at different developmental stages. Analysis of the ratio of high PSA N-CAM to total N-CAM indicated that sialylation and desialylation are independently regulated from the expression of polypeptide chains of N-CAM. Motoneurons, dorsal root ganglia cells and commissural neurons present a homogeneous distribution of high PSA N-CAMs on both their cell bodies and their neurites. Sialylation of N-CAM can occur in neurons after their aggregation in peripheral ganglia as demonstrated for dorsal root ganglia at E12. Furthermore, peripheral ganglia express different levels of high PSA N-CAM. With in vitro models using mouse neural crest cells, we found that expression of high PSA N-CAM was restricted to cells presenting an early neuronal phenotype, suggesting a common regulation for the expression of high PSA N-CAM molecules, neurofilament proteins and sodium channels. Using perturbation experiments with endoneuraminidase, we confirmed that high PSA N-CAM molecules are involved in fasciculation and neuritic growth when neurons derived from neural crest grow on collagen substrata. However, we demonstrated that these two parameters do not appear to depend on high PSA N-CAM molecules when cells were grown on a fibronectin substratum, indicating the existence of a hierarchy among adhesion molecules.     

Rat mesencephalic neuronal cells cultured for different periods as a model of dopamine transporter ontogenesis

Ventral mesencephalic neurons contained only low-affinity and sodium-independent binding sites of [³H]WIN 35,428 (marker of dopamine transporter) during the first 10d in primary cultures. These sites were present in cytosol, and they are not very probably related to dopamine transporter. After 12 d in culture, membrane-bound, high-affinity, and sodium-dependent [³H]WIN 35,428 binding sites were detected. In membranes prepared from cells 14 d in culture, cocaine displaced [³H]WIN 35,428 binding with similar potency to that in striatal membranes of adult rat brain. The high-affinity [³H]WIN 35,428 binding sites in mesencephalic neuronal cell cultures are very probably related to dopamine transporter. The development of high-affinity [³H]WIN 35,428 binding sites in neurons cultured for different time periods could be a useful model of dopamine transporter ontogenesis.     

Neuronal acquisition of tetanus toxin binding sites: Relationship with the last mitotic cycle

In an earlier study on the developing nervous system, the existence of a temporal correlation between the appearance of tetanus toxin-binding cells and neurogenesis was reported (A. Koulakoff, B. Bizzini, and Y. Berwald-Netter (1982). Using a combined approach of immunocytochemistry and [³H]thymidine autoradiography it is shown that, in the fetal mouse central nervous system, dividing cells do not express membrane binding sites for tetanus toxin. A time-course quantitative autoradiography revealed that the toxin-binding sites become apparent within 7 ± 1 hr, following the last S phase, on cells undergoing the conversion from dividing to postmitotic state. The acquisition of surface binding sites for tetanus toxin may thus be an early property of nascent central neurons, marking the transition from cycling precursor neuroblasts to postmitotic neuronal cells. Parallel studies on in vivo-developing dorsal root ganglia disclosed that at least some peripheral nervous system cells are endowed with tetanus toxin-binding capacity while still capable of DNA synthesis and undergo one or more divisions.     

Nerve growth factor-induced stimulation of dorsal root ganglion/spinal cord co-grafts in oculo: enhanced survival and growth of CGRP-immunoreactive sensory neurons

Intraocular co-grafts of rat fetal spinal cord and dorsal root ganglia were used to examine the enhanced survival, growth, and differentiation of sensory neurons by nerve growth factor. E14 lumbar spinal segments were implanted into the anterior eye chamber of capsaicin-pretreated rats. Two weeks later, an E14 dorsal root ganglion was implanted beside the spinal cord graft. Nerve growth factor or vehicle was injected weekly for 4 weeks into the anterior eye chamber. Co-grafts were examined weekly and, at 6 weeks, processed for calcitonin gene-related peptide (CGRP) immunofluorescence. No differences in overall size were determined for the grafts. Co-grafts treated with nerve growth factor contained many more CGRP neurons (19.4 cells/20 microm) that were significantly larger (mean 764 microm2) than neurons from control co-grafts (8.6 cells/20 microm; mean 373 microm2). In co-grafts treated with nerve growth factor, CGRP-immunoreactive fibers were extensive in the dorsal root ganglion, adjacent iris, and spinal cord compared to control co-grafts. A few CGRP-positive motoneurons were observed in the spinal cord, but no differences in number or size of motoneurons were found. The current report demonstrates that spinal cord and dorsal root ganglia can be co-grafted in oculo for long periods of time. Many dorsal root ganglion neurons survive and send peripheral processes into the iris and central processes into the spinal cord under the influence of exogenous nerve growth factor. The intraocular graft paradigm can be of use to further examine the role of neurotrophic factors in regulating or modulating dorsal root ganglion and spinal cord neurons.     

Expression of phosphorylated high molecular weight neurofilament protein (NF-H) and vimentin in human developing dorsal root ganglia and spinal cord

The expression of vimentin and the phosphorylated variant of high molecular weight neurofilament protein (NF-H) was studied in developing human fetal dorsal root ganglia and spinal cord. The technique used for examination of cryosections was double-label fluorescence with monoclonal antibodies. Both proteins were present in the nerve fibres inside the ganglia of 6- and 8-week-old embryos. During further development the expression of vimentin continued to increase in the satellite cells, but was found to be decreasing in the ganglion cells. Phosphorylated NF-H was found in the processes of ganglion cells, as well as in the perikarya at all developmental stages. In the spinal cord of 6- and 8-week-old embryos, phosphorylated NF-H protein was found in the longitudinal fibres of the marginal layer and in processes of the mantle zone; some of the fibres also contained vimentin. Later the co-expression of the two proteins ceased and vimentin was found only in glial and mesenchymal derivatives. Phosphorylated NF-H was located, at all developmental stages, in the axons of both white and grey matter, but not in the neuronal perikarya. The results indicate that phosphorylation of the NF-H in human dorsal root ganglia starts in the perikarya of the ganglion cells while in the ganglion cells of the spinal cord it takes place in the axons.