Neonatal neuronal loss in rat superior cervical ganglia: retrograde effects on developing preganglionic axons and Schwann cells

SPARC triggers a cell-autonomous program of synapse elimination

Elimination of the excess synaptic contacts established in the early stages of neuronal development is required to refine the function of neuronal circuits. Here we investigate whether secreted protein acidic and rich in cysteine (SPARC), a molecule produced by glial cells, is involved in synapse removal. SPARC production peaks when innervation of the rat superior cervical ganglion and the tail of Xenopus tropicalis tadpoles are remodeled. The formation of new cholinergic synapses in autaptic single-cell microcultures is inhibited by SPARC. The effect resides in the C-terminal domain, which is also responsible for triggering a concentration- and time-dependent disassembly of stable cholinergic synapses. The loss of synaptic contacts is associated with the formation of retracted axon terminals containing multivesicular bodies and secondary lysosomes. The biological relevance of in vitro results was supported by injecting the tail of Xenopus tropicalis tadpoles with peptide 4.2, a 20-aa sequence derived from SPARC that mimics full-length protein effects. Swimming was severely impaired at ∼5 h after peptide application, caused by the massive elimination of neuromuscular junctions and pruning of axonal branches. Effects revert by 6 d after injection, as motor innervation reforms. In conclusion, SPARC triggers a cell-autonomous program of synapse elimination in cholinergic neurons that likely occurs when protein production peaks during normal development.

Lysophosphatidic acid promotes survival and differentiation of rat Schwann cells

Lysophosphatidic acid (LPA; 1-acyl-sn-glycerol-3-phosphate), an abundant constituent of serum, mediates multiple biological responses via G protein-coupled serpentine receptors. Schwann cells express the LPA receptors (Edg receptors), which, once activated, have the potential to signal through G(alphai) to activate p21(ras) and phosphatidylinositol 3-kinase, through G(alphaq) to activate phospholipase C, or through G(q12/13) to activate the Rho pathway. We found that the addition of serum or LPA to serum-starved Schwann cells rapidly (10 min) induced the appearance of actin stress fibers via a Rho-mediated pathway. Furthermore, LPA was able to rescue Schwann cells from apoptosis in a G(alphai)/phosphatidylinositol 3-kinase/MEK/MAPK-dependent manner. In addition, LPA increased the expression of myelin protein P(0) in Schwann cells in a Galpha(i)-independent manner but dependent on protein kinase C. By means of pharmacological and overexpression approaches, we found that the novel isozyme protein kinase Cdelta was required for myelin P(0) expression. Thus, the multiple effects of LPA in Schwann cells (actin reorganization, survival, and myelin gene expression) appear to be mediated through the different G protein-dependent pathways activated by the LPA receptor.

Reduced rearing temperature augments responses in sympathetic outflow to brown adipose tissue

Sympathetic outflow to brown adipose tissue (BAT) contributes to both thermoregulation and energy expenditure in rats through regulation of BAT thermogenesis. Acute cold exposure in mature animals augments BAT thermogenesis; however, the enhanced BAT thermogenic response returns to normal shortly after cessation of the cold exposure. In this study, we sought to determine whether cold exposure in early neonatal life could induce enhanced responses in the sympathetic outflow to BAT and whether this altered sympathetic regulation would be sustained after the cold stimulus was removed. BAT sympathetic nerve activity (SNA) was recorded in urethane-chloralose-anesthetized, artificially ventilated rats that were raised from birth in either 18 or 30 degrees C environments and then, at 8 weeks of age, were maintained in 23 degrees C for at least 4 weeks. An acute hypothermic stimulus, disinhibition of a brainstem thermogenic network in the raphe pallidus, or electrical stimulation in this raphe site produced increases in BAT SNA that were twice as great in rats reared at 18 degrees C as in those reared at 30 degrees C. The norepinephrine content of the interscapular BAT (IBAT) and the number of sympathetic ganglion cells projecting to interscapular BAT were 70% greater in the 18 degrees C-reared rats. We conclude that neonatal exposure to a cold environment induces a permanent developmental alteration in the capacity for sympathetic stimulation of BAT thermogenesis that may be mediated, in part, by a greater number of sympathetic ganglion cells innervating BAT in cold-reared animals.

Differences in developmental cell death between somatic and autonomic motor neurons of rat spinal cord

Considerable knowledge concerning developmental cell death has come from the study of somatic motor neurons (SMNs), but a related set of spinal neurons, the autonomic motor neurons (AMNs), have been studied less extensively in this respect. In the present study, we used three different approaches to determine the amount of AMN cell death during normal development in the rat. First, target dependency was studied in organotypic slice cultures, and it was found that AMNs survived for at least 12 days after removal of their postsynaptic targets. No factors were added to the serum-free medium to substitute for the ablated targets, indicating that AMNs were able to survive without target-derived trophic factors. Such target-independent survival is not characteristic of neurons that undergo typical developmental cell death. Second, AMNs were counted in double-stained choline acetyltransferase immunocytochemical and NADPH diaphorase histochemical preparations at ages (postnatal days 4-22) encompassing the period when AMN postsynaptic target cells undergo developmental death. Neuron numbers were essentially identical at all ages examined, indicating that no AMN cell death occurred postnatally. Finally, from embryonic day 13 to postnatal day 22, animals were analyzed by using terminal transferase-mediated nick-end labeling to identify dying cells. Many fewer labeled cells were observed among AMNs than among SMNs. Thus, all three approaches indicated that there is a significant SMN/AMN difference in developmental cell death. The phenotypic trait(s) that underlies this difference may also be important in the relative resistance of AMNs to pathological conditions that induce death of SMNs, e.g., those involved in amyotrophic lateral sclerosis and excitotoxicity.

Ultrastructural changes of sympathetic neurons following neurotrophin 3 antiserum treatment in young rat

We have previously demonstrated that neurotrophin-3 antiserum administration to rats during the first 2 postnatal weeks results in a massive reduction of neurons in the superior cervical ganglion. In the present study, an ultrastructural analysis was undertaken to elucidate the mechanism by which neurotrophin-3 deprivation causes neuronal death. Newborn and 4-week-old rats were injected with either neurotrophin-3 antiserum or normal rabbit serum or used without injection. Superior cervical ganglia from each animal were examined by routine electron microscopy. Most neurons in the ganglia from untreated rats had a large and round nucleus with one or two nucleoli. Chromatin within the nucleus was evenly distributed. A double-layer nuclear membrane could be distinguished and the cytoplasm contained abundant organelles. Treatment with neurotrophin-3 antiserum for 24 h in neonates resulted in chromatin clumping in the nucleus of many neurons. The nuclear membrane became rough and occasionally folded. In the cytoplasm, the Golgi apparatus was disrupted. Three days after treatment, these changes became more obvious. The chromatin in the nucleus was often aggregated and marginalized. Vacuolation was present in many membranous organelles throughout the cytoplasm. Although neurotrophin-3 antiserum given to 4-week-old rats had little effect on overall neuronal numbers (Tafreshi, Zhou, and Rush, unpublished), a few neurons, undergoing either apoptotic or cytolytic cell death, were identified 7 days later. Most affected neurons were located near small blood vessels or capillaries and were associated with numerous nonneuronal cells. The debris of degenerating neurons were surrounded by the processes of glia cells. These findings support the view that loss of endogenous neurotrophin-3 following neutralization with specific antibody leads to activation of apoptotic pathways within the affected neurons. However, the presence of neurons dying as a result of cytolysis suggests that other mechanisms may also be involved.

The ratio of pre- to postganglionic neurons and related issues in the autonomic nervous system

The motor outflow of the autonomic nervous system (ANS) is differentiated into two major divisions, parasympathetic (PSNS) and sympathetic (SNS). Both are organized hierarchically into pre- and postganglionic levels, but classically the two divisions have been assumed to differ in their ratios of pre- to postganglionic neurons. The PSNS been characterized as having lower ('one-to-few') ratios, whereas the SNS has been described as possessing higher ('one-to-many') ratios. These patterns have been assumed to measure differing divergences of the outflows. In this review, a ratio of pre- to postganglionic neurons is called a ratio index, and the idea that the PSNS and SNS have characteristically different ratio indexes and divergences is called the ratio rule. The putative differences in the ratio indexes of the two divisions - as well as Fulton's influential proposal that they form one of the bases of contrasting functional capacities of the PSNS and SNS - have been widely accepted for nearly for nearly three quarters of a century. A survey of the original observations yielding the concept of the ratio rule as well as the more recent estimates of pre- and postganglionic numbers, however, challenges both the generality and the adequacy of the ratio rule and indexes. The originally formulated differences between the PSNS and SNS represent an overgeneralization since they were based on observations of only two ganglia, the ciliary ganglion in the PSNS and the superior cervical ganglion in the SNS. Furthermore, these original estimates were based on limited samples and were subject to a number of counting artifacts. A survey of the literature suggests that ratio indexes vary much more within each ANS division than they do between the two divisions. When ganglia other than the ciliary and superior cervical are examined, the two divisions of the ANS have broad, largely overlapping ranges of ratio indexes. Additionally, other PSNS-SNS pairs can be found in which the relative sizes of their respective indexes are completely contrary to the ratio rule. For a given ganglion, there are substantial differences in the ratio index between species, between individuals of the same species, and between stages of development in the same species. Furthermore, both divisions of the ANS have wide and largely overlapping ranges of physiological effects varying from specific to diffuse, from local to widespread. Finally, the ratio index measure ignores the degree of convergence found in different ganglia, and it is insensitive to the fact that many ganglia have multiple functionally distinct motor neuron pools, each with separate inputs varying in their degrees of divergence and/or convergence. Thus ratio indexes do not differentiate the PSNS from the SNS, and conclusions based on such putative distinctions are questionable.

Transcellular retrograde labeling of radial glial cells with WGA-HRP and DiI in neonatal rat and hamster

Topographically distinct populations of radial glial cells in the diencephalon and mesencephalon of neonatal rats and hamsters were transcellularly labeled with wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) and with the lipophilic tracer DiI. A comparison of the histological distribution of the two tracers is suggestive of two different mechanisms of transcellular labeling. Intraocular injections of WGA-HRP resulted in the uptake of exogenously applied WGA-HRP by retinal ganglion cells, followed by anterograde axonal transport and exocytosis within the optic target nuclei. In addition to the transneuronal labeling, which is typical of such injections, we observed the transcellular labeling of the processes and somata of radial glial cells that were topographically associated with the terminal fields of the labeled axons. Similar transcellular labeling of radial glial cells associated with the axon terminal fields of the colliculogeniculate projection to the medial geniculate nucleus was observed following injections of WGA-HRP in the inferior colliculus. The transcellular labeling within the radial glial cells was discontinuous and somatopetally concentrated, indicating the existence of a retrograde active transport mechanism within the radial glial processes subsequent to its uptake following release of tracer from axons. This type of labeling can be referred to as transcellular retrograde glioplasmic transport. In contrast, DiI was used as a tracer through its capacity to diffuse within the plasmalemma. Topographically distinct populations of radial glial cells were transcellularly labeled following placements of DiI in the retina, inferior colliculus, or dorsal thalamus of fixed brains. The radial processes of labeled radial glial cells consistently extended into regions that also contained labeled axons. It is likely that the transcellular radial glial labeling with DiI occurred via transmembranous diffusion. These data indicate that a close structural and functional relation exists between axons and glial cells in the developing brain.

Peptide-immunoreactive neurons and nerve fibres in lumbosacral sympathetic ganglia: selective elimination of a pathway-specific expression of immunoreactivities following sciatic nerve resection in kittens

The distributions of peptide-immunoreactive nerve fibres and cell bodies in lumbosacral paravertebral sympathetic ganglia of young cats were analysed with antibodies to calcitonin gene-related peptide, enkephalin, neurotensin, somatostatin, substance P, galanin, neuropeptide Y and vasoactive intestinal polypeptide. Fairly dense networks of nerve fibres showing enkephalin-, neurotensin-, somatostatin- or substance P-like immunoreactivity were observed in the ganglia. Double-staining experiments revealed that enkephalin- and somatostatin-immunoreactive nerve fibres preferentially surrounded calcitonin gene-related peptide- and/or vasoactive intestinal polypeptide-immunoreactive cell bodies. Neurotensin- and substance P-immunoreactive nerve fibres were mainly associated with neurons showing neuropeptide Y and/or galanin-like immunoreactivity. Occasional nerves containing calcitonin gene-related peptide-, galanin-, neuropeptide Y- or vasoactive intestinal polypeptide-like immunoreactivity were observed. These fibres did not seem to have any direct regional distribution within the ganglia. In kittens surviving for three months after early postnatal sciatic nerve resection, no calcitonin gene-related peptide-immunoreactive cell bodies could be detected in ganglia ipsilateral to the operation. In contrast, vasoactive intestinal polypeptide-like immunoreactivity, which partly co-exists with calcitonin gene-related peptide, was observed to the same extent as in control ganglia. Furthermore, almost all of the somatostatin-immunoreactive varicose nerve fibres had disappeared, whereas a fairly dense network of calcitonin gene-related peptide-immunoreactive nerve fibres could be observed. This change was paralleled by an increased content of nerve fibres that were immunoreactive to antibodies against the growth-associated protein GAP-43 (also known as B-50). The present findings suggest that experimental perturbations where postganglionic neurons are separated from their target areas by axotomy, not only induce differential changes in neurotransmitter expression in the principal ganglion cells, but also in preganglionic sympathetic neurons projecting to the ganglia. One possible explanation for the occurrence of an axotomy-induced network of calcitonin gene-related peptide-immunoreactive nerve fibres, is that extrinsic sensory nerve fibres grow into the ganglia after the sciatic nerve lesion. Thus, these findings seem to suggest one additional possibility with regard to the question of a possible interaction between sympathetic and sensory neurons after peripheral nerve injury.

Neuron-Schwann cell signals are conserved across species: purification and characterization of embryonic chicken Schwann cells

A monoclonal antibody, 1E8, which recognizes the peripheral myelin protein, P0, specific for chicken Schwann cells and their precursors (Bhattacharyya et al., Neuron 7:831-844, 1991), was used to immunoselect Schwann cells from embryonic day 14 (E14) chicken sciatic nerve. When cultured, these immunoselected cells displayed properties characteristic of perinatal rodent Schwann cells, including S100-immunoreactivity and O4 antigen-immunoreactivity. In addition, the purified chicken Schwann cells divided slowly when cultured alone, but when co-cultured with chicken or rat sensory neurons, they bound to axons and proliferated. Proliferation was also stimulated by the addition of bovine brain membrane extracts or chicken brain membranes. The 1E8 monoclonal antibody was also used to test the effect of axonal contact on P0 expression. Chicken Schwann cells purified using the 1E8 monoclonal antibody gradually lost P0 when cultured alone. These cells remained 1E8-negative even after prolonged co-culture with embryonic rat dorsal root ganglion neurons or chicken sensory ganglia. These results demonstrate that chicken Schwann cells behave like rodent Schwann cells in their expression of specific antigens, interactions with axons, and regulation of P0 expression. In addition, chicken Schwann cells respond to neuronal signals from the rat and cow, illustrating the cross-species conservation of these signals.

Neurofibromin, a predominantly neuronal GTPase activating protein in the adult, is ubiquitously expressed during development

The onset of manifestations of the common, autosomal dominantly inherited disease type 1 neurofibromatosis (NF1) is usually in childhood. To begin to understand the pathogenesis of NF1, we analyzed the developmental pattern of expression of the protein product of the NF1 gene, neurofibromin, by Western blotting and immunohistochemistry using the rat as a model system. Neurofibromin is uniformly distributed throughout embryonic day 10 and 12 rat embryos. By embryonic day 16, neurofibromin immunoreactivity is enriched in neurons of the cortical plate, in peripheral ganglia, and in developing CNS and PNS fiber tracts, but remains detectable outside the nervous system. Expression decreases in nonneural tissues by postnatal day 6, and neurofibromin is greatly decreased (lung, adrenal cortex, skin) or absent (skeletal muscle, cartilage) in adult tissues except for brain, spinal cord, peripheral nerve, and adrenal medulla. Transient expression of neurofibromin during development in many tissues suggests the importance of this GTPase-activating protein in morphogenesis and organ growth. A separate role is proposed for neurofibromin in growing axons and in the mature nervous system.

Division and migration of satellite glia in the embryonic rat superior cervical ganglion

While distinct precursors committed to a neuronal or glial cell fate are generated from neural crest cells early in peripheral gangliogenesis, little is known about the subsequent generation and maturation of young satellite glia from restricted glial precursor cells. To examine the division and migration of glial precursor cells and their satellite cell progeny, morphological, immunocytochemical and culture techniques were applied to the developing rat superior cervical ganglion. At embryonic day (E)18.5, numerous clusters of nonneuronal cells appeared transiently in the ganglion. Individual cells with a similar morphology were present in E16.5 ganglia, and are likely to represent the precursor cells which generate these clusters. The clustered cells were distinguishable from neighbouring neurons as well as from endothelial cells and fibroblasts. Morphologically similar cells were present in nerve bundles at E18.5 and surrounding principal neurons and nerve bundles in the adult ganglion. Double-label studies of the E18.5 ganglion with tyrosine hydroxylase to identify noradrenergic neurons and propidium iodide counterstaining to visualize all cell nuclei revealed that the cells in clusters stained with propidium iodide but lacked tyrosine hydroxylase immunoreactivity. To determine if cell clusters arose from division, bromodeoxy-uridine, a thymidine analogue, was administered to pregnant mothers between E16.5-E18.5, and ganglionic cells examined at E18.5 both in vivo and in vitro. Numerous non-neuronal cells divided during this period in situ and composed portions of clusters. When dissociated, superior cervical ganglion satellite glia reacted with an NGF-receptor antibody (MAb 217c) and possessed a flattened shape, in contrast to bipolar Schwann cells. Over half of the 217c-immunoreactive glia at E18.5 had incorporated bromodeoxyuridine during E16.5-18.5 in vivo. At birth, non-neuronal cells were no longer grouped in clusters, but were associated with neuronal cell bodies and processes. These findings suggest that, between E16.5-E18.5, glial precursors divide rapidly to form clusters, and that, after the peak of neurogenesis, daughter cells migrate within the ganglion to associate with nerve cell bodies and processes where proliferation continues at a slower rate. Distinct cellular and molecular interactions are likely to trigger the initial rapid division of glial precursors, initiate their migration and association with neuron cell bodies, and control their subsequent slower division.

Schwann cells and cells in the oligodendrocyte lineage proliferate in response to a 50,000 dalton membrane-associated mitogen present in developing brain

The neuronal cell surface is believed to carry a mitogenic signal for peripheral glial cells. We have purified a mitogen from fetal bovine brain membranes that, in common with the PNS neuronal mitogen, stimulates the proliferation of Schwann cells in vitro and binds heparin. The purified mitogen has an apparent molecular weight of 50,000 daltons as estimated by elution of activity from non-reducing polyacrylamide gels. Since the developing central nervous system is a rich source of mitogen, we tested whether the protein is mitogenic for one or more cell types isolated from the developing brain. Purified mitogen was added to enriched cultures of astrocytes or developing oligodendrocytes, or to microglial cells. The analyses demonstrated that the protein is mitogenic for developing oligodendrocytes but not astrocytes or microglial cells. These results suggest that during development a membrane-associated mitogen present in the brain might regulate the proliferation of developing oligodendrocytes, and consequently, the population size of oligodendrocytes in the brain.

Evidence for the colocalization of the axonal mitogen for Schwann cells and oligodendrocytes

Axons that normally will encounter either CNS or PNS glia have been shown to contain a powerful mitogen for both Schwann cells and oligodendrocytes. The normally nonmyelinated, nonglial ensheathed cerebellar granule cells have been shown to possess a proliferative signal for Schwann cells, suggesting that a glial mitogen is common to all axons. To determine if a glial mitogen capable of stimulating both Schwann cells and oligodendrocytes is colocalized on all types of axons we have (1) cocultured granule cells with oligodendrocytes, (2) incubated oligodendrocytes with granule cell membranes, and (3) evaluated the ability of heparin extracts of granule cell membranes, splenic nerve microsomes, and axolemma-enriched fractions isolated from rat and bovine CNS to stimulate mitosis of cultured oligodendrocytes. Neither the intact granule cells nor the granule cell membrane fraction stimulated cultured oligodendrocytes to divide. However, heparin extracts of the granule cell membranes were significantly mitogenic to the cultured oligodendrocytes. Heparin extracts of splenic nerve microsomes were more mitogenic than the comparable extract obtained from bovine CNS axolemma-enriched fractions. These results suggest that the neuronal mitogen for oligodendroglia is colocalized with the neuronal mitogen for Schwann cells.

Influence of an experimental hindlimb maldevelopment on axon number and nodal spacing in the rat sciatic nerve

In neonatal rat pups the femoral and tibial epiphyseal cartilages on the left side were coagulated with a microcautery device. The subsequent femoral and tibial growth in length was markedly restricted on the left side, but the foot and the pelvic region exhibited normal longitudinal growth. After 6 months the sciatic nerves were removed from both sides. Electron microscopic analysis of nerve specimens from the stunted side revealed that the number of axons was 20% less compared to control specimens. Light microscopic examination of teased preparations showed a normal nodal spacing in the pelvic segment but abnormally short internodes in the femoral segment of the left sciatic nerve. These results suggest that the number of axons in the rat sciatic nerve adapts to a target maldevelopment that sets in neonatally, and that internodal elongation during development proceeds according to the local growth in length of the nerve rather than to the length growth of the whole nerve.

A role for glia in the development of organized neuropilar structures

Intercellular interactions are critical in the development of the nervous system. In the olfactory system of a moth, sensory axons induce the formation of large synaptic glomeruli, each surrounded by a glial envelope, in the antennal lobe of the brain. During development, the sensory axons cause changes in glial shape and disposition one day before glomeruli are recognized. Early removal of glial cells prevents the development of glomeruli despite the presence of afferent axons. Thus, the glial cells appear to play a role as intermediaries in the induction of glomeruli by afferent axons. Recent findings in the mammalian somatosensory cortex suggest a similar role for glia there.

Cerebellar granule cells contain a membrane mitogen for cultured Schwann cells

Proliferation of Schwann cells is one of the first events that occurs after contact with a growing axon. To further define the distribution and properties of this axonal mitogen, we have (a) cocultured cerebellar granule cells, which lack glial ensheathment in vivo with Schwann cells; and (b) exposed Schwann cell cultures to isolated granule cell membranes. Schwann cells cocultured with granule cells had a 30-fold increase in the labeling index over Schwann cells cultured alone, suggesting that the mitogen is located on the granule cell surface. Inhibition of granule cell proteoglycan synthesis caused a decrease in the granule cells' ability to stimulate Schwann cell proliferation. Membranes isolated from cerebellar granule cells when added to Schwann cell cultures caused a 45-fold stimulation in [3H]thymidine incorporation. The granule cell mitogenic signal was heat and trypsin sensitive and did not require lysosomal processing by Schwann cells to elicit its proliferative effect. The ability of granule cells and their isolated membranes to stimulate Schwann cell proliferation suggests that the mitogenic signal for Schwann cells is a ubiquitous factor present on all axons regardless of their ultimate state of glial ensheathment.

The neuronal cell-surface molecule mitogenic for Schwann cells is a heparin-binding protein

The cell surface of embryonic peripheral neurons provides a mitogenic stimulus for Schwann cells. We report (i) the solubilization of this mitogenic activity from rat dorsal root ganglion neurons grown in tissue culture and (ii) the solubilization and partial purification of mitogenic activity from neonatal rat brains. Extracted mitogenic activity is peripheral rather than intrinsic to the membrane, stable after extraction, and active as a mitogen in the absence of serum (the most stringent criterion defining the neuronal mitogen). We have previously provided evidence suggesting that a neuronal cell-surface heparan sulfate proteoglycan is required for expression of the neurons' mitogenic activity. We now show that mitogenic activity can be extracted from the membrane dissociated from proteoglycan as assayed by its ability to bind to immobilized heparin. After dissociation, low concentrations of heparin (1 micrograms/ml) inhibit the ability of the mitogen to stimulate Schwann cell division. Basic fibroblast growth factor (FGF) is weakly mitogenic for Schwann cells, but it is not present in mitogenic brain extracts (based on immunoblotting). Immunodepletion experiments with specific antibodies to FGF indicate that the mitogenic activity extracted from neurons is not a form of this heparin-binding mitogen. Acidic FGF is not mitogenic for Schwann cells and is not present in mitogenic brain extracts. We suggest that these and previous data indicate the neurite mitogen is a proteoglycan-growth factor complex that limits mitogenic activity to the axonal surface, protects mitogen against inactivation by other proteoglycans, and provides for effective presentation of mitogen to the Schwann cell.

Embryonic somatic nerve destruction with beta-bungarotoxin

The effects and time course of a single injection of beta-bungarotoxin into E14 rat embryos were examined with an electron-microscopic study of development of the internal intercostal somatic nerve. Within 24 h of injection, axons in this nerve became swollen and fused at points along their length. By 48 h after injection no component of the nerve remained in distal segments of ribcage; complete loss of axons and components of the nerve sheath from proximal regions took slightly longer. At later times, no trace of peripheral nerve axons, Schwann cells or elements of the nerve sheath remained. beta-Bungarotoxin applied on E17 destroyed developing axons in a similar manner, but the perineurium remained in place, and axons regenerated within the original nerve trunk. The study confirms that sensory and motor neurons are much less able to survive axon degeneration on E14 than after the major period of normal cell death (which is nearly over by E18), and that the maintenance and continued development of the perineurium during E14-E16 depends on the presence of peripheral nerve axons.

Nerve growth factor modification of the ethylnitrosourea model for multiple schwannomas

The administration of ethylnitrosourea (ENU) to pregnant rats late in gestation or to neonatal rats results in the induction of Schwann cell tumors in a high percentage of perinatally exposed animals. Exogenous administration of nerve growth factor (NGF) significantly reduces the number of Schwann cell tumors and other neurogenic tumors developing in ENU-treated rats. Administration of antibodies directed against NGF prior to neonatal ENU exposure results in a substantial increase in the incidence of Schwann cell tumors, particularly in the trigeminal nerves of both rats and mice. Transplacental ENU treatment causes early neoplastic proliferation (ENP) at 90 days of age in the Schwann cell population of trigeminal nerves in nearly all exposed rats. A variety of NGF treatment protocols (single or multiple inoculations or microinfusion prior to or following ENU exposure) resulted in a significant reduction in ENU-induced ENP in trigeminal nerves. These results indicate that NGF may convey protection either directly or indirectly, by an unknown mechanism, to Schwann cells and other supportive neural cells by reducing their sensitivity to ENU-induced neoplastic transformation.

Effects of neuron-conditioned medium and fetal calf serum content on glial growth in dissociated cultures

The influence of the microenvironment as assessed by medium conditioned by 6-day-old chick embryo neurons in culture and of the nutrients derived from fetal bovine serum was evaluated in cultures of primary chick embryo glial cells. Glia-enriched cultures from 15-day-old chick embryo were incubated from culture days 3-9 with various concentrations of neuron-conditioned medium, with or without 10% fetal bovine serum in the final culture medium. Also, glial growth was studied in cultures with 5%, 10% or 20% fetal bovine serum in the medium. Glutamine synthetase and 2',3',-cyclic nucleotide 3'-phosphohydrolase were used as astrocytic and oligodendrocytic markers, respectively. Cultures were harvested at day 9. The presence of neuron-conditioned medium in the cultures was associated with persistence of immature glioblast-like cells. This persistence of glial immature cells was also reflected by the lower glutamine synthetase activity in the cultures with neuron-conditioned medium as compared to cultures with neuron-conditioned medium and fetal calf serum. In cultures with 5% neuron-conditioned medium without fetal bovine serum, cyclic nucleotide phosphohydrolase activity was increased. We are assuming that the input of neurons to the microenvironment is partially mediated through the neuron-conditioned medium. Thus, the present findings show that neurons influence the growth and differentiation of glial cells in culture.

Differences in horseradish peroxidase labeling of sensory, motor and sympathetic neurons following chronic axotomy of the rat sural nerve

In an attempt to clarify the ultimate fate of permanently axotomized adult primary neurons, horseradish peroxidase (HRP) was used as a cell marker to label the motor, sensory and postganglionic sympathetic neurons of rat sural nerves which had been sectioned at the ankle and prevented from regenerating for periods of up to 80 weeks. Axotomy did not affect sympathetic neurons, but resulted 4 weeks later in a sudden reduction in the number of labeled sensory and motor cells which persisted to the end of the study. The missing neuronal population amounted to 44.4% and 45.9% respectively of the normal sensory and motor contingent and included most of the large afferent and efferent neurons. However, examination of sural nerves at the thigh, 30 mm proximal to the neuroma, revealed marked axonal atrophy but no change in the number of myelinated and unmyelinated fibers up to 52 weeks after axotomy. Such prolonged survival of the peripheral processes is indirect evidence that axotomized neurons can endure long-term detachment from their end organs and suggests that the lack of HRP labeling in certain sensory and motor neurons does not imply their degeneration, but expresses one of many retrograde dysfunctions triggered by axotomy.

The density of reinnervation of adult rat superior cervical sympathetic ganglionic neurons is limited by the number of available postsynaptic sites

The adult rat superior cervical ganglion has about 27,000 neurons and is innervated by about 9000 preganglionic axons which make a total of nearly 11 million synapses. Surgical removal of the upper part of the ganglion, reducing the number of neurons to about 20%, causes an overall reduction of the number of synapses to about 30%, but has no effect on the numbers of preganglionic axons. Thus, a 5-fold increase in the axon/neuron ratio causes an increase of only about 50% in the number of synapses per cell. Axotomy followed by regeneration of the preganglionic axons causes no further increase in the number of synapses per cell, even though the average number of synapses per axon is reduced to about one-quarter of the normal. This suggests that the ganglionic neurons can only accept a limited number of synapses, and that in the normal situation there is only possibility for a relatively minor increase before this limit is reached. This study is complementary to a previous one in which the numbers of preganglionic axons were surgically reduced and it was found that, when allowed to regenerate into an entire denervated ganglion, the remaining axons could not increase their numbers of synapses. Thus, in the normal rat superior cervical sympathetic ganglion the total number of synapses is such that while the preganglionic axons are probably expressing close to their full synaptogenic potential, the ganglionic neurons express only about two-thirds of their ability to receive synapses.

Specialized neuroglial arrangement may explain the capacity of vomeronasal axons to reinnervate central neurons

The neurosensory cells of the primary olfactory and vomeronasal projections are in a state of continuous replacement throughout adult life. Since their axons form synaptic terminals with neurons in the olfactory and accessory olfactory bulbs, this system is an apparent exception to the rule that peripheral axons cannot grow into the central nervous system of adult mammals. Electron microscopy of sections (especially in a plane tangential to the surface of the accessory olfactory bulb) shows a unique glial arrangement. By virtue of their greater electron density and "secretory-type" organelle content (Golgi apparatus and dense-core vesicles) the glial cells of the superficial layers of the accessory olfactory bulb are distinguished both from the glia of the vomeronasal nerves and from the astrocytes of the deeper bulbar layers. The synapses between the vomeronasal axons and the postsynaptic elements are formed in glomeruli which are encapsulated by an inner layer of glial cytoplasm derived from the superficial glia, and an outer layer derived from the astrocytes. The principle of the organization is that the superficial glial processes are reflected off the axons before they reach the synaptic terminal zone. Conversely, for the postsynaptic elements, the astrocytic processes are reflected off the dendrites of the accessory olfactory bulb neurons before they enter the core of the glomeruli. In effect, the synapses are formed in a "no-man's-land" between the two glial cell types. This peculiar glial arrangement may be important for the unique regenerative capacity of this system.

Glial cell growth in culture: influence of living cell substrata

The role of the microenvironment in the growth of glial cells in culture has been the topic of ongoing research in this laboratory. Recently, we reported a study on the contribution of fibroblast cell substratum and extracellular matrix in glial cell growth. In the present study we report data concerning a) the influence of a neuronal-enriched living substratum from chick embryo on the growth of glial cells derived from chick embryonic brain and plated onto the substratum; b) the influence of dissociated cells derived from chick embryonic brain on the growth of established glial cells in culture, and c) the influence of dissociated cells derived from adult rat spinal cord on the growth of established glial cells from newborn rat in culture. The activities of glutamine synthetase (GS) and 2', 3'-cyclic nucleotide 3'-phosphohydrolase (CNP) were the biochemical probes determined for astrocytes and oligodendrocytes, respectively. We found that glial growth as assessed by both enzyme activities, was enhanced when a nervous tissue derived cell population was plated onto a glial-enriched substratum, whereas glial growth was inhibited when the neuronal-enriched population was the cell substratum.

Mitogenic growth factors and nerve dependence of limb regeneration

Regeneration of the amphibian limb after amputation depends on division of blastemal cells, the progenitor cells of the regenerate. This division is controlled, at least in the early stages of regeneration, by the nerve supply to the blastema. A monoclonal antibody to newt blastema cells has provided evidence that Schwann cells and muscle fibers contribute to the blastema, and identifies blastemal cells whose division is persistently dependent on the nerve. Glial growth factor, a molecule identified by its action on rat Schwann cells, is present in the newt blastema and is lost on denervation.

Functional elimination of afferent pathways and decreased safety factor during postembryonic development of cockroach giant interneurons

The giant interneurons (GIN) from the cockroach CNS undergo two major physiological changes during the postembryonic developmental period: (A) a marked decrease in the number of afferent pathways innervating the GIN at the metathoracic ganglion (Ts); and (B) a gradual decrease in the safety factor for impulse propagation along the intraganglionic segment in T3. In 100% of the experiments (n greater than 100) performed on GIN from early developmental stages, spontaneous postsynaptic potentials (SPSPs) were recorded; in adults, on the other hand. SPSPs have been recorded in only 34% of the experiments (n = 74). Evoked synaptic potentials can be elicited in nymphal stages by stimulation of 8 nerves of T3, the contralateral connectives, ipsi- and contralateral nerve roots 2, 3, 5, and by stimulation of adjacent GINs. In adult, PSPs can be evoked by stimulation of adjacent GINs, and contralateral thoracic connectives, but not from nerves 2, 3 and 5. The functional disappearance of synaptic inputs to the GINs does not reflect a general phenomenon of reduction in synaptic transmission efficacy. In previous studies it was demonstrated that high frequency stimulation of adult GIN leads to blockage of impulse propagation in T3. In nymphal stages, the safety factor for propagation of impulses along T3 is higher. The reduction in safety factor appears gradually during the postembryonic developmental period. From analysis of the mechanisms underlying the elimination of functional afferent pathways and the appearance of low safety factor (see consecutive paper by Yarom and Spira) it is concluded that the functional elimination of afferents is a consequence of decreased transmission efficacy, while the appearance of low safety regions for impulse propagation is a consequence of morphological changes of the GIN segment within ganglion T3.

Morphological and electrophysiological properties of giant interneurons during the postembryonic development of the cockroach CNS

The giant interneurons (GIN) of the central nervous system of the cockroach undergo two major physiological changes during the postembryonic development period: (A) a gradual decrease in the safety factor for action potential propagation across the GIN in the metathoracic ganglion (T3); and (B) a marked decrease in the number of afferent pathways innervating the GIN in T3 (Spira and Yarom). Analysis of the morphological structure of the GINs, by intracellular injection of cobalt ions and by cross-sections prepared for light and electron microscope, reveals that despite the extensive growth of the GINs during the postembryonic developmental period, the main structural outline of the fibers is not altered. In adult preparations, however, the GIN diameter narrows 25-26% in ganglion T3, while in early nymphal stages the reduction is only 8-10%. The difference in the extent of narrowing of the fibers in adult and nymphal stages is the major factor that accounts for the development of a low safety factor region for impulse propagation across T3. Analysis of the passive membrane properties of the GIN reveals that the electrotonic length of the GIN segment in T3 is identical in adult and nymphal stages. It is concluded that the functional disappearance of afferents innervating the GINs in T3 is a consequence of decreased transmission efficacy along the afferent pathways.

Retrograde transneuronal regulation of the afferent innervation to the rat superior cervical sympathetic ganglion

The superior cervical sympathetic ganglion of the rat receives its preganglionic afferent innervation through the cervical sympathetic trunk, and sends most of its postganglionic axons through two major nerves, the internal (ICN) and external carotid nerves (ECN). In the present study, the ICN alone or both the ICN and the ECN were cut in neonatal and adult rats. Two months after these lesions, ganglionic neurons, synapses and preganglionic axons were counted and compared with unoperated control values. After cutting the ICN alone in neonatal rats, ganglionic neurons were reduced in number by 70% and synapses were reduced by 50%, but there was no change in the number of preganglionic axons. Cutting both the ICN and ECN in neonates resulted in an 88% reduction of ganglionic neurons and an 83% reduction of synapses. In this case there was a 63% reduction in the number of preganglionic axons. After cutting either the ICN alone or both the ICN and the ECN in neonates, there was a hyperinnervation (increased number of synapses) of the remaining ganglionic neurons. In the adult rat, cutting either the ICN alone or both the ICN and ECN resulted in a smaller loss of ganglionic neurons, and there was no loss of preganglionic axons. There was no hyperinnervation of surviving neurons in adult rats. Thus, the response by preganglionic axons to a reduced number of ganglionic neurons differs in the neonate and adult rat. In the developing animal, the degenerative response to injury is much more severe than in the adult, but the reorganizational response is also greater.

Competitive reinnervation of the rat superior cervical ganglion by foreign nerves

The efficacy of foreign nerves to form synapses was studied morphologically and physiologically in the superior cervical ganglion of the rat. The denervated ganglion was anastomosed to the central stump of either the vagus, the hypoglossal or both nerves together. The degree of reinnervation was assessed two to ten months later. We measured the strength of contraction of the nictitating membrane after each type of operation and compared this to the number, type and distribution of synapses in the same ganglion. Both the vagus and hypoglossal nerves preferentially reinnervated a population of neurones that are situated in the cranial pole of the superior cervical ganglion and supply the nictitating membrane. When both nerves were connected to the ganglion only the vagus nerve could be shown to reinnervate it, and no reinnervation by the hypoglossal nerve was detected. However, in this experiment neither foreign nerve did as well in competition as each did alone and the overall result was reduced functional efficiency. We conclude that not all sympathetic neurones are equivalent and that, just like sympathetic afferents, the foreign nerves are capable of selectively reinnervating preferred target cells.

An electron microscopical study of neuronal cell clustering in postnatal mouse striatum, with special emphasis on neuronal cell death

In this study, electron microscopy was used to study cell clustering in the postnatal mouse striatum. From the date of birth (PO) through postnatal day 7 (P7), groupings of eight to ten striatal neurons were delimited easily in low magnification electron micrographs. Often, within individual groupings, adjacent neurons were separated only by a thin, 10 nm gap, and formed cell pairs or cell triads. Coincident with marked expansion of the striatal neuropil in the second postnatal week, striatal neurons formed more dispersed cell clusters consisting only occasionally of cell pairs or triads. Single, pyknotic neuronal nuclei were seen in clusters of normal neurons exhibiting different stages of maturation but were absent from clusters consisting only of well-differentiated neurons. The neuropil surrounding cell clusters with pyknotic neurons or that adjacent to neighboring cell clusters often contained degenerating dendrites and axon terminals. Whereas this naturally occurring neuronal cell death was present in the tissue throughout the first postnatal week, only degenerating dendritic and axonal profiles were seen in the P15 striatum. This latter fact suggests that the occurrence of pyknotic neuronal somata does not account entirely for the more localized degeneration of other neuronal profiles and raises the possibility that other degenerative processes may be occurring simultaneously in the tissue.

Developmental morphometry and physiology of the rabbit vagus nerve

The morphological and physiological features of the rabbit vagus nerve were studied at different ages after birth. The total fibre count is about 37,500 of which at birth 1-2% and in the adult animal approximately 10% are myelinated. In the postnatal period the cross-sectional area of the vagus grows to 5 times its perinatal size due to an increase of endoneural collagen, fibre growth and myelinization. The myelinization is most pronounced in the first 2 weeks after birth, axonal growth is predominant thereafter. The available data suggest that the begin of myelinization as well as the subsequent development of the myelin sheath are not dependent on axonal size. There seems to be no fundamental difference between the morphological development of the vagus and other peripheral nerves, e.g. the sciatic nerve of the rat. At birth the vagus nerve contains 2 fibre groups as can be measured from the compound action potential with conduction velocities of 11.4 and 0.9 m.s-1 respectively. Upon subsequent development the conduction velocity of these fibres increases to 31.9 and 1.2 m.s-1 in full-grown animals. THe compound action potential of the adult nerve implies 2 additional fibre groups with conduction velocities of 12.3 and 4.6 m.s-1 respectively. These two fibre populations develop gradually from 1 to 2 weeks after birth and arise probably from the slowest conducting, non-myelinated or C-fibres. It is concluded that the functional innervation of the sinoauricular node may be operational at birth as far as the cervical vagus nerve is concerned.

A morphometric study of mouse trigeminal ganglion after unilateral destruction of vibrissae follicles at birth

A morphometric study of the trigeminal ganglion after unilateral vibrissae follicles' coagulation in newborn mice has shown the following: (a) a 42.8% decrease of the total volume of the ganglion on the deafferented side with reference to the normal side; a 61.5% decrease of the ophthalmic-maxillary part of the ganglion where neurons whose axons innervate vibrissae follicles are located, and only a 24.1% decrease in the common part; (b) a 54.8% decrease of the neuronal cell body volume in the ophthalmic-maxillary part and practically no change in the common part, and (c) a 64.5% decrease of the volume occupied by the nerve fibers in the ophthalmic-maxillary part and only a 28.1% decrease in the common part. A comparison of the section areas in ganglion and of the bulk area of neuronal cell bodies at different levels has also been performed. Counting of the neuronal cell bodies in the ophthalmic-maxillary part of the ganglion indicated a mean neuronal loss of 36.5%. Peripheral reinnervation of the common fur by regenerated axons of neurons which previously innervated vibrissae, although unlikely, cannot be completely excluded.

The ratio of preganglionic axons to postganglionic cells in the sympathetic nervous system of the rat

Previously reported preganglionic-postganglionic ratios for the sympathetic system are a major part of the evidence for the widely accepted idea that the sympathetic innervation of the viscera is diffuse. Unfortunately, the previous reports did not assess the non-preganglionic fibers in the nerves examined, and the limitations of light microscopy precluded accurate unmyelinated fiber counts. Thus, a recalculation of these ratios is necessary. The present study recalculates these ratios for the cervical sympathetic system of the rat. All fiber counts are done with the electron microscope which has the resolution necessary for accurately determining axon numbers. Selective surgical procedures establish that 84% of the axons in the cervical sympathetic trunk are preganglionic, 11% are postganglionic, and 5% are sensory. Thus, the numbers of preganglionic fibers can now be accurately assessed and compared to the number of postganglionic neurons in the superior cervical ganglion. When this is done, a preganglionic/postganglionic ratio of approximately 1:4 is obtained. This ratio differs considerably from those previously published.

The elimination of redundant preganglionic innervation to hamster sympathetic ganglion cells in early post-natal life

The superior cervical ganglion of adult and neonated hamsters has been studied with intracellular recording. 1. Neurones in adult hamster ganglia are innervated by an average of 6-7 preganglionic axons. During the first week of post-natal life, however, these cells are innervated by at least eleven to twelve axons. Ganglion cells in animals 2-3 weeks old are innervated to an intermediate degree, indicating that these neurones lose a substantial portion of their initial synaptic contacts during the first weeks after birth. 2. The over-all innervation of the superior cervical ganglion in adult hamsters arises from thoracic segments T1-T5; no additional segments contribute significantly to the innervation of neonatal ganglia. 3. The average number of segments innervating each adult ganglion cell is 2 . 8 compared to 3 . 7 segments innervating neonatal neurones. Throughout post-natal development the innervation of individual neurones arises from a contiguous subset of the spinal segments that innervate the ganglion as a whole. 4. We conclude that the elimination of redundant innervatin in early life is not limited to those nerve and muscle cells contacted by a sigle axon in maturity, but also occurs in sympathetic ganglia where adult neurones remain multiply innervated. Moreover, the loss of some synaptic contacts during development refines the selective innervation of individual neurones.

Synapse formation in the rat superior cervical ganglion during normal development and after neonatal deafferentation

Ten per cent of the adult number of synapses are present in the neonatal rat superior cervical sympathetic ganglion on day 1 (day of birth taken as day 0). Synapses are formed rapidly over the first postnatal week, and then more slowly, reaching 80% of adult numbers by the end of the third week. Adult numbers are present at the end of the third month. Prominent axosomatic synapses are present for the first two weeks of life, but disappear later. Of the adult numbers of synapses, 20-40% are already present on days 2 and 4, and transection of the preganglionic chain on these days causes disappearance of all synapses by 2 days after operation. However, by 2 months after operation the numbers of synapses are the same as in unoperated ganglia from rats of the same age. Unoccupied postsynaptic densities were not seen either in normal development or after lesions.

Regeneration and myelination in autonomic ganglia transplanted to intact brain surfaces

Fragments of superior cervical ganglia (SCG) from donor rats between newborn and three months of age were transplanted either into the fourth ventricle, onto the dorsal surface of the medulla or in contact with the area postrema of recipient rats aged 6--14 days (allografts) and 3--4 weeks (autografts). Except for the meninges, the entire brain surface and parenchyma was undisturbed. The regenerative capacity of the transplanted ganglia and its interaction with the brain surfaces was followed for post-operative periods between 1 h and six months. Both ependymal and glial cells reacted to the transplant even though there was no mechanical damage to the brain. Ependymal cells developed luminal fronds that projected into the ventricle and the subpial glia displayed a very subtle gliosis in the form of thin multi-laminated processes. Schwann cells from the transplant tended to cover the free surfaces of the brain. The transplants, often incorporated into the stroma of the choroid plexus, received an extensive vascular supply of both fenestrated and non-fenestrated vessels. In contrast to SCG in tissue culture, the perinatal explants quickly degenerated while all those from older donors, at least 3--4 weeks of age, regenerated briskly in the ambient cerebrospinal fluid. Thriving SCG neurons, which diminished in number over time, sprouted numerous neurites as early as one week; growth cones and synaptic contacts between cell processes were still evident at six months. The trasplanted mature SCG fragment underwent a redevelopment after an initial period of degeneration. It seems likely that the survival of the allografted ganglion cells depends on their acquisition of a target site in their new environment. By four to six months many axons became enclosed by myelin produced by SCG Schwann cells that normally do not form myelin in situ. Other Schwann cells appeared reactive in that they had a great increase in cytoplasmic filaments and formed gap junctions, two characteristics of C.N.S. astrocytes. It is possible that the proximity to the C.N.S. changes the character of certain Schwann cells or, alternatively, resulted in the migration of glial cells out of the brain. If the glial cells have migrated into the transplant, they may support alien neural tissue. This system in which the transplantation site is easily accessible with a minimum of trauma could lend itself to the study of some underlying mechanisms of the growth and regulation of both central and autonomic neurons and their supporting cells.

The effect of destroying the whisker follicles in mice on the sensory nerve, the thalamocortical radiation and cortical barrel development

Electrolytic destruction of whisker follicles in mice on the day of birth has been found to cause degeneration in the sensory nerve fibres supplying the follicles. The severity of the degeneration has been assessed in animals between 2 and 20 days old by counting the total number of myelinated fibres in the maxillary nerves on both normal and lesioned sides. The degeneration is apparent after 2 days and by 20 days the nerve on the lesioned side contains only 38% of the normal fibre content. This degeneration has also been shown to involve the trigeminal root, central to the ganglion. In addition, the lesioning procedure modifies the terminations of thalamocortical fibres in the barrel region of the sensory cortex. These terminations are normally in clusters, each corresponding to a barrel, but, after lesioning the follicles, the terminals appear to be evenly distributed in layer IV and cortical barrel structures no longer develop. In postnatal mice, electrolytic destruction of whisker follicles had less effect upon maxillary nerve fibres and cortical barrels. The number of myelinated axons surviving until day 20 increased progressively with later lesioning to reach nearly 80% of the control level when lesions were made on day 10. Cortical barrels became secure earlier than the maxillary nerve, for a normal number of cortical barrels was present at day 12 when follicles were destroyed on day 4. The implications of these results for the formation of cortical barrels is discussed.

Quantitative studies of sympathetic ganglia and spinal cord intermedio-lateral gray columns in familial dysautonomia

In adult patients with familial dysautonomia the mean volume of superior cervical sympathetic ganglia is reduced to 34% of the normal of 222 mm3. Packing density of neurons is reduced to 37% of normal. The mean total number of ganglionic neurons is 120,000 as compared to 1,060,000 in controls. The mean totals of preganglionic neurons in the first three thoracic cord segments are 13,600 in patients and 25,150 in controls. Deficits in sympathetic neurons account for many of the clinical, pharmacological and biochemical manifestations of familial dysautonomia.

The fate of Schwann cells isolated from axonal contact

Chronically denervated rat and rabbit tibial nerve distal stumps were studied 3-58 weeks following nerve transection. Schwann cells, macrophages and possibly fibroblasts participated in myelin removal which was largely complete by seven weeks. Degenerating myelinated and unmyelinated fibres developed respectively into circular and flattened columns of Schwann cell processes each delimited by a basal lamina. Schwann cell columns became encircled by fibroblasts and later by cells of perineurial type, underwent shrinkage with time and eventually were replaced by connective tissue. In another experiment, endoneurial tissue was removed from rabbit tibial nerve stumps seven weeks after transection and transplanted between the corneal stroma of the same animal for 2-6 weeks. In this locus, Schwann cells developed a thickened basal lamina and then underwent necrosis. It was concluded that the maintenance of Schwann cells in bands of Büngner is in part dependent on axonal contact and that failure of reinnervation eventually causes the columns of Schwann cells to disappear.

The Schwann cell: a reappraisal of its role in the peripheral nervous system

The Schwann cell is clearly essential for the maintenance of axonal integrity--yet we know little of the regulatory mechanisms governing its behaviour at any point in its life cycle, or of the nature of its interaction with the axons with which each Schwann cell is associated. In this article, the involvement of the Schwann cell in myelinogenesis, aspects of Schwann cell-axon recognition, the experimentally-demonstrable 'bipotentiality' of the Schwann cell and the possible functional significance of the proliferative response of the Schwann cell that occurs after injury are discussed. The isolation and preparation of pure populations of Schwann cells which can be injected or implanted into a damaged nerve, coupled possibly with the localized application of drugs to manipulate the cellular responses to injury within the nerve, represent interesting areas of recent research which may be applied in planning methods of therapeutic intervention in the treatment of peripheral nerve injury.