The Effects of Prenatal Intracranial Infusion of Tetrodotoxin on Naturally Occurring Retinal Ganglion Cell Death and Optic Nerve Ultrastructure

Activity-dependent neuron-glial signaling by ATP and leukemia-inhibitory factor promotes hippocampal glial cell development

Activity-dependent signaling between neurons and astrocytes contributes to experience-dependent plasticity and development of the nervous system. However, mechanisms responsible for neuron-glial interactions and the releasable factors that underlie these processes are not well understood. The pro-inflammatory cytokine, leukemia-inhibitory factor (LIF), is transiently expressed postnatally by glial cells in the hippocampus and rapidly up-regulated by enhanced neural activity following seizures. To test the hypothesis that spontaneous neural activity regulates glial development in hippocampus via LIF signaling, we blocked spontaneous activity with the sodium channel blocker tetrodotoxin (TTX) in mixed hippocampal cell cultures in combination with blockers of LIF and purinergic signaling. TTX decreased the number of GFAP-expressing astrocytes in hippocampal cell culture. Furthermore, blocking purinergic signaling by P2Y receptors contributed to reduced numbers of astrocytes. Blocking activity or purinergic signaling in the presence of function-blocking antibodies to LIF did not further decrease the number of astrocytes. Moreover, hippocampal cell cultures prepared from LIF -/- mice had reduced numbers of astrocytes and activity-dependent neuron-glial signaling promoting differentiation of astrocytes was absent. The results show that endogenous LIF is required for normal development of hippocampal astrocytes, and this process is regulated by spontaneous neural impulse activity through the release of ATP.

Vesicular apparatus, including functional calcium channels, are present in developing rodent optic nerve axons and are required for normal node of Ranvier formation

P/Q-type calcium channels are known to form clusters at the presynaptic membrane where they mediate calcium influx, triggering vesicle fusion. We now report functional P/Q channel clusters in the axolemma of developing central axons that are also associated with sites of vesicle fusion. These channels were activated by axonal action potentials and the resulting calcium influx is well suited to mediate formation of a synaptic style SNARE complex involving SNAP-25, that we show to be located on the axolemma. Vesicular elements within axons were found to be the sole repository of vesicular glutamate in developing white matter. The axonal vesicular elements expressed the glutamate transporter V-ATPase, which is responsible for vesicular glutamate loading. The P/Q channel alpha(1A) subunit was found to be present within the axolemma at early nodes of Ranvier and deleterious mutations of the alpha(1A) subunit, or an associated alpha(2)delta-2 subunit, disrupted the localization of nodal proteins such as voltage-gated sodium channels, beta IV spectrin and CASPR-1. This was associated with the presence of malformed nodes of Ranvier characterized by an accumulation of axoplasmic vesicles under the nodal membrane. The data are consistent with the presence of a vesicular signalling pathway between axons and glial cells that is essential for proper development of the node of Ranvier.

Neurotransmitter receptors in the life and death of oligodendrocytes

Oligodendrocytes are crucial to the function of the mammalian brain: they increase the action potential conduction speed for a given axon diameter and thus facilitate the rapid flow of information between different brain areas. The proliferation and differentiation of developing oligodendrocytes, and their myelination of axons, are partly controlled by neurotransmitters. In addition, in models of conditions like stroke, periventricular leukomalacia leading to cerebral palsy, spinal cord injury and multiple sclerosis, oligodendrocytes are damaged by glutamate and, contrary to dogma, it has recently been discovered that this damage is mediated in part by N-methyl-D-aspartate receptors. Mutations in oligodendrocyte neurotransmitter receptors or their interacting proteins may cause defects in CNS function. Here we review the roles of neurotransmitter receptors in the normal function, and malfunction in pathological conditions, of oligodendrocytes.

Axonal transport blockade in the neonatal rat optic nerve induces limited retinal ganglion cell death

Optic nerve section in the newborn rat results in a rapid apoptotic degeneration of most axotomized retinal ganglion cells (RGCs). This massive process of neuronal death has been ascribed mainly to the interruption of a trophic factor supply from target structures rather than to the axonal damage per se. To distinguish between these two possibilities, we induced a reversible axonal transport blockade in the developing optic nerve by topical application of a local anesthetic (lidocaine). Light and electron microscopy showed no alterations in the fine structure of treated optic nerves. Retinae of treated and control rats were stained with cresyl violet and examined at different times after surgery. We found that axonal transport blockade induced only a limited number of pyknotic RGCs. Degeneration of these cells was completely prevented by inhibiting protein synthesis during lidocaine application. We conclude that the rapid degeneration of RGCs after axotomy can be ascribed only partly to the loss of retrogradely transported trophic factors.

Dendritic development of retinal ganglion cells after prenatal intracranial infusion of tetrodotoxin

The dendritic form of a cell may be established by many factors both intrinsic and environmental. Blockade of action potentials along the course of axons and in their postsynaptic targets dramatically alters the development of axonal morphology. The extent to which blockade of target cell activity retrogradely alters the dendritic morphology of the presynaptic cells is unknown. To determine whether the establishment of dendritic form by developing retinal ganglion cells depends on activity within their targets, the sodium channel blocker, tetrodotoxin (TTX), was administered via minipumps to the diencephalon of cat fetuses from embryonic day 43 (E43) to E57. At E57 retinae were removed and living retinal ganglion cells injected in vitro with Lucifer yellow to reveal their dendritic morphology. In the TTX-treated animals both alpha and beta types of retinal ganglion cells were present, as were putative gamma cells. Overall, the dendrites of retinal ganglion cells in TTX-treated animals appeared qualitatively and quantitatively similar to those of untreated animals. The only significant change in the TTX-treated cases was a small increase in the number of dendritic spines on the non-beta cells. These results indicate that the acquisition of basic dendritic form of developing ganglion cells is not influenced by the action potential activity within their targets, and that it is also independent of the terminal branching patterns of their axons.

Increased serotonin in the developing superior colliculus does not alter the number or distribution of retinotectal ganglion cells

Administration of a single subcutaneous dose of 5,7-dihydroxytryptamine (5,7-DHT) to newborn hamsters results in a significant increase in the density of serotoninergic (5-HT) fibers in the superficial layers of the superior colliculus (SC) and marked abnormalities in both the crossed and uncrossed retinotectal projections when these animals reach adulthood (R. Rhoades, C. Bennett-Clarke, R. Lane, M. Leslie, and R. Mooney, 1993, J. Comp. Neurol. 334:397-409). The present study was undertaken to determine whether changes in the retinotectal projection of 5,7-DHT-treated animals were associated with alterations in the number or distribution of retinal ganglion cells in these animals. Nissl staining of retinae from normal adult and 5,7-DHT-treated hamsters revealed no differences between them in the number or average diameter of cells in the retinal ganglion cell layer. Retrograde labeling with horseradish peroxidase (HRP) demonstrated no effect of 5,7-DHT treatment on the number or distribution of ipsilaterally or contralaterally projecting ganglion cells. Neonatal 5,7-DHT administration also had no effect on the distribution of soma diameters for HRP-labeled retinal ganglion cells. Electron microscopic analysis demonstrated no significant difference between the number of optic nerve fibers in the normal and 5,7-DHT-treated hamsters. The results are consistent with the conclusion that the effect of 5,7-DHT on the retinotectal projection may primarily be a function of this toxin, or the increase in 5-HT it induces, on the terminal arbors of retinotectal axons rather than on their parent cells.

Severity of ganglion cell death during early postnatal development is modulated by both neuronal activity and binocular competition

The influence of postnatal neuronal activity on the magnitude of retinal ganglion cell death has been studied in cats. A constant blockade of activity in one eye starting just after birth does not change the severity of naturally occurring ganglion cell death, and as in normal animals, the ganglion cell population declines from 250,000 to 160,000 over a 4- to 6-week period. However, the population of retinal ganglion cells in the active untreated eye of monocularly deprived cats is increased 12% above normal (180,000 vs. 160,000 in each of four cases). This increase of 20,000 cells is permanent, and presumably reflects the competitive advantage in their target nuclei that the still active axons have over their silenced companions from the treated eye. Surprisingly, in one animal treated successfully for long duration with TTX in both from the population of ganglion cells was elevated in both eyes (200,000 and 208,000 ganglion cells). This increase matches that achieved by early unilateral enucleation (Williams et al., 1983). Our results demonstrate that the complete blockade of activity reduces the severity of naturally occurring cell death in a population of CNS sensory neurons. The effects of unilateral blockade emphasize that the activity-dependent modulation of neuron death only occurs under conditions that do not place the inactive population of neurons at a competitive disadvantage.

Death of neurons in the neonatal rodent and primate globus pallidus occurs by a mechanism of apoptosis

We have examined the developing rat, mouse and marmoset globus pallidus for evidence of cells dying by a process of "naturally occurring" or programmed cell death. We have demonstrated that cells in the developing mammalian globus pallidus die by a process of apoptosis and that by day 7 after birth many of the apoptotic cells possess a neuronal phenotype. Light microscopic and ultrastructural evidence of apoptotic cell death included cell shrinkage, blebbing of the extracellular membrane and condensation of the nuclear chromatin. Additionally we used an in situ nick translation method to assess the integrity of the DNA within the dying cells. This revealed that cells with the morphological characteristics of apoptosis also possessed fragmented DNA typical of cells undergoing Type 1 programmed or apoptotic cell death. The lack of lysosomal enzyme activity within the dying cells and the frequent observations of phagocytosis by neighbouring cells also suggest that the form of programmed cell death is apoptosis and not Type 2 autophagic degeneration. We found no evidence for cells dying by Type 3 non-lysosomal degeneration since all dying cells examined under the electron microscope possessed intact intracellular organelles and cell membranes. We developed a sensitive silver stain which detected balls of condensed chromatin within the apoptotic cells. This enabled identification of apoptotic cells in the developing globus pallidus at low magnification and so allowed us to map the numbers and distribution of dying cells with time. The incidence of apoptotic cells in the neonatal globus pallidus was greatest at birth and then declined such that few cells were detected at one week and none was seen in the adult rat. Although the loss of large numbers of cells in the developing nervous system is a well documented phenomenon, there are only a limited number of reports of the mechanism by which neuronal cells die, and few of these are in the developing mammalian brain. There are at least four different morphological categories of neuronal cell death which are discriminated on morphological and biochemical criteria. Our analysis suggests that apoptotic or Type 1 cell death is the major form of programmed cell death occurring in the mammalian globus pallidus in the first week of life. This report also describes the use of two methods for the ready identification of apoptotic cells at the light microscope level. Because these methods are suitable for use on tissue sections they provide a means to assess the incidence of apoptotic cell death, in parallel with other analyses of the expression of gene products which control cell fate.

Neurotransmitter-mediated signaling between axons and glial cells

Neurotransmitter-mediated signaling is not restricted to the synaptic regions of the nervous system but also takes places along fiber tracts lacking vesicular means of releasing neuroactive substances. The first demonstration for dynamic signaling of this type came in the early 1970s from studies by Villegas and co-workers in squid axons and their satellite Schwann cells. In this invertebrate system, glutamate has been identified as the mediator of this signaling in being first released from the active axons thus setting off a series of cascades, leading to a cholinergic activation of the Schwann cell membrane. Recent evidence suggests that receptor-mediated signaling also exists between glial cells and axons in vertebrates. In the frog optic nerve, axonal activity facilitated the activity of glial ion channels. In the neonatal rat optic nerve, electrical activity of axons triggered oscillations in intracellular calcium in a subset of glial cells. These observations have been postulated to reflect receptor-mediated signaling, including a mechanism in which glutamate is released from axons via the reversal of a transporter and induces intracellular calcium spiking in glial cells via metabotropic glutamate receptors. The efficacy of "axon-to-glia" transmission may, like that in "neuron-to-neuron" transmission, be modulated by co-release of multiple neuroactive substances. One possibility is that adenosine, which is known to be released from fiber tracts, can modulate glutamate signaling in white matter by modulating the periaxonal glutamate concentration through an effect on the glial glutamate uptake system.

The effects of monocular enucleation on ganglion cell number and terminal distribution in the ferret's retinal pathway

Anterograde and retrograde tracing techniques were used to examine the effects of removing one eye at birth on the remaining uncrossed retinal pathway in adult ferrets. After enucleation, the adult number of labelled ganglion cells projecting ipsilaterally changed from an average of 6068 in normal pigmented ferrets to an average of 7813 (29% increase) in pigmented enucleates. The change in albino ferrets was from 1455 in normals to 2319 in enucleates (59% increase). Labelled cells scattered across nasal retina accounted for over half the increase in the uncrossed population. After neonatal enucleation, the volume of lateral geniculate nucleus occupied by the uncrossed projection increased substantially: five-fold in pigmented animals and 20-fold in albinos. These results suggest that neonatal removal of one eye has a greater effect on the distribution of uncrossed terminals than on the survival of uncrossed ganglion cells. There was also an increase in the total number of axons in the surviving optic nerve of both pigmented and albino ferrets (93,000 in enucleates compared with 79,000 in normal animals), which cannot be simply explained as a disruption of binocular competition.

Delay of ganglion cell death by tetrodotoxin during retinal development in chick embryos

Neuronal activity plays an important role in the formation of topographic projection in the nervous system. In order to examine the role of neuronal activity on the retinotectal projection system, tetrodotoxin (TTX) was injected into one eye ball of the chick embryo once between day 9 and 14 of incubation and the number of dying retinal ganglion cells (RGCs) stained with Nile blue in the whole-mounted retinae were counted. In the control retinae, dying RGCs first appeared at stage 36 and disappeared after stage 43. The peak of RGC death was at stage 38 in the temporal and the central parts and at stage 39 in the nasal part. The total amount of dying RGCs in the temporal part was less than that in the central and the nasal parts. After injection of TTX into one eye ball, the peak of RGC death was at stage 40, which was 2 days later than that in the control retinae. TTX treatment did not affect the total amount of dying RGCs in the treated eye, but resulted in their decrease in the vehicle-treated eye which was contralateral to TTX treatment. These findings indicate that inhibition of neuronal activity of RGCs by TTX treatment delays the timing of RGC death.

Proliferation of oligodendrocyte precursor cells depends on electrical activity in axons

Oligodendrocytes myelinate axons in the vertebrate central nervous system. It would, therefore, make sense if axons played a part in controlling the number of oligodendrocytes that develop in a myelinated tract. Although oligodendrocytes themselves normally do not divide, the precursor cells that give rise to them do. Here we show that the proliferation of oligodendrocyte precursor cells in the developing rat optic nerve depends on electrical activity in neighbouring axons, and that this activity-dependence can be circumvented by experimentally increasing the concentration of platelet-derived growth factor, which is present in the optic nerve and stimulates these cells to proliferate in culture. These findings suggest that axonal electrical activity normally controls the production and/or release of the growth factors that are responsible for proliferation of oligodendrocyte precursor cells and thereby helps to control the number of oligodendrocytes that develop in the region.

Cell death and the creation of regional differences in neuronal numbers

Regional variations in cell death are ubiquitous in the nervous system. In the retina, cell death in retinal ganglion cells is elevated in the retinal periphery and may be important in setting up the initial conditions that produce central retinal specializations such as an area centralis or visual streak. In central visual system structures, pronounced spatial and spatiotemporal inhomogeneities in cell death are seen both in layers and regions of the lateral geniculate nucleus and superior colliculus; similar indications of inhomogeneities are seen in those nonvisual structures that have been examined. Cell death in the cortex is highly nonuniform, by layer and by cortical area. A variety of possible functions for these regional losses are proposed, in the context of a uniform mechanism for cell death that allows it to assume multiple functions.

Chronic drug infusion into the scala tympani of the guinea pig cochlea

This research describes a unique, effective and inexpensive delivery system to provide discrete quantities of drugs on a chronic basis to the inner ear. The amount of the drug administered and specific timing of each administration are under investigator control. A micro-injection system mounted atop an animal's head is shown to permit repeated application of agents which effectively block neural responsiveness (tetrodotoxin) on a daily basis for periods up to 2 weeks. Cannulation of the inner ear and chronic delivery of control substances (artificial perilymph) do not affect function. This system may be used to administer drugs to other compartments of the body (e.g., the brain) on a chronic basis for neurophysiologic and neuropharmacologic investigations.

Changes in lamination and neuronal survival in the isthmo-optic nucleus following the intraocular injection of tetrodotoxin in chick embryos

We have studied how the development of the isthmo-optic nucleus (ION) is affected by electrical activity in the ION's axonal target territory, the contralateral retina. Electrical activity was blocked or reduced in the retina for various periods by tetrodotoxin injected intraocularly in different doses. The effects on the morphology of the retina appear to have been minor. During the ION's period of naturally occurring neuronal death (embryonic days 12 to 17), the injections substantially reduced this neuronal death and disrupted the development of lamination in the contralateral ION; there was also a lesser reduction in neuronal death in the ipsilateral ION. The dose of tetrodotoxin required to affect lamination was lower than that affecting neuronal death. Thus, the effects on neuronal death and on lamination were independent, since either could occur without the other. These effects were mediated by retrograde signals (probably two or more) from the eye; they occurred too early for the alternative anterograde route via the optic tectum (which projects to the ION) to be responsible. After embryonic day 17, the ION's response to intraocular tetrodotoxin changes abruptly from increased survival to total and rapid degeneration.

Infraorbital nerve blockade from birth does not disrupt central trigeminal pattern formation in the rat

We tested the hypothesis that patterned primary afferent impulse activity during early postnatal periods is necessary for central trigeminal pattern formation. Newborn rats had their whiskers trimmed daily and new slices of slow release polymer containing the sodium channel blocker, tetrodotoxin, were placed under the infraorbital nerve every 8 h for up to 9 days. Electrophysiological recordings indicated that trigeminal ganglion cells were unresponsive to peripheral stimuli and chronically silenced. Trigeminal ganglion cell numbers were unaffected by nerve blockade. Cytochrome oxidase staining patterns in the trigeminal brainstem complex, thalamus, and barrel cortex were normal on postnatal day 1, 3, 5, 7, or 9 (n = 4 each). Whisker-related patches were of normal sizes and staining densities. Similar negative results were obtained in 9 rats in which whiskers were trimmed daily and the long-acting local anesthetic bupivacaine was injected into the whisker pad at 2.5- to 4-h intervals from birth to sacrifice on postnatal day 5-9. Cytochrome oxidase staining patterns and patch properties again did not differ from normal. Thus, trigeminal pattern formation occurs even when the entire infraorbital nerve is silenced from birth.

Reduction in the death and cytolamination of developing neurons by tetrodotoxin in the axonal target region

Tetrodotoxin was injected into one eye of chick embryos so as to block activity in the target territory of the isthmo-optic nucleus (ION) during its period of neuronal death. This markedly reduced the neuronal death and thereby prolonged the survival of some 'aberrantly' projecting neurons which would normally all die. In addition, the cytoarchitecture of the ION developed abnormally. Since these two effects differ markedly in their dose-dependence and in other ways, they cannot both be explained by changes in the strength of a single retrograde signal.

Ion channel expression by white matter glia: the O-2A glial progenitor cell

We describe electrophysiological properties of the O-2A glial progenitor cell in a new serum-free culture system. O-2A progenitors have many properties characteristic of neurons: they have glutamate-activated ion channels, express the neuronal form of the sodium channel, fire single regenerative potentials, and synthesize the neurotransmitter GABA by an alternative synthetic pathway. Nearly identical properties were observed in acutely isolated O-2A progenitors, indicating that this phenotype is not an artifact of culture. The O-2A did not express a simple subset of channel types found in its descendant cells, the type-2 astrocyte and oligodendrocyte, studied in the same culture system. During development, these electrophysiological properties may contribute to O-2A function in vivo.