Alexander K. Ball

Effects of GDNF on retinal ganglion cell survival following axotomy.

Recent evidence suggests that approximately 90% of retinal ganglion cells (RGCs) die by the process of apoptosis within 14 days of optic nerve transection. RGCs begin to disappear from the retina between 5 and 7 days postaxotomy when the highest percentage of RGCs show characteristics typical of apoptosis. A single intraocular injection of glial cell-line derived neurotrophic factor (GDNF) given at the time of axotomy resulted in a delay in the initiation of RGC death and increased the densities of surviving RGCs at 7, 10 and 14 days postaxotomy. The mean RGC densities in GDNF treated retinas at 7 (2381 +/- 144), 10 (1561 +/- 117) and 14 (1123 +/- 116) days postaxotomy were significantly higher than that of controls (1835 +/- 82, 835 +/- 272 and 485 +/- 39, respectively). The loss of RGCs was paralleled by increases in TUNEL positive staining in control retinas and a lower percentage of TUNEL positive cells in GDNF treated retinas at 5, 7 and 10 days postaxotomy. These results suggest that GDNF is capable of promoting RGC survival following injury, possibly by interfering with an essential step in apoptosis.

Functional‐Anatomical Studies on the Terminal Nerve Projection to the Retina of Bony Fishes

We have explored the structure and actions of terminal nerve (TN) fibers in the teleostean retina, the most accessible of TN projections. Using immunocytochemistry we have shown that the goldfish TN contains neuropeptides related to the molluscan cardioexcitatory peptide (FMRFamide) as well as luteinizing hormone-releasing hormone (LHRH). Retinal TN terminals were found upon major dendrites in the distal inner plexiform layer and neuronal cell bodies in the amacrine cell layer. Electron-microscopic double-labeling revealed TN terminals applied to the surface of [3H]-dopamine-, glycine-, and gamma-aminobutyric acid (GABA)-accumulating cells. Synthetic LHRH and FMRFamide at less than 1 microM modified spontaneous and light-evoked activity of ganglion cells in isolated superfused goldfish retina, especially during the active breeding season. Salmon(I)-LHRH was 10-30 times as potent as mammalian LHRH and caused rapid, prolonged desensitization. We conclude that LHRH- and FMRFamide-like peptides may be released by retinal TN endings, probably in concert with reproductive activity, and that they act independently through horizontal and/or amacrine cell pathways to modify visual information processing in the retina.

Nitric Oxide Synthase Inhibition Delays Axonal Degeneration and Promotes the Survival of Axotomized Retinal Ganglion Cells

Nitric oxide (NO) synthesized by inducible nitric oxide synthase (iNOS) has been implicated in neuronal cytotoxicity following trauma to the central nervous system. The aim of the present study was to examine the role of NO in mediating axotomy-induced retinal ganglion cell (RGC) death. We observed increases in iNOS expression by microglia and Müller cells in the retina after optic nerve transection. This was paralleled by the induced expression of constitutive NOS (cNOS) in RGCs which do not normally express this enzyme. In order to determine if NO is cytotoxic to axotomized RGCs, the nonspecific NOS inhibitors Nomega-nitro-L-arginine (NOLA) or N-nitro-L-arginine methyl ester (L-NAME) were delivered to the vitreous chamber by intraocular injections. Both NOLA and L-NAME significantly enhanced RGC survival at 7, 10, and 14 days postaxotomy. The separate contributions of iNOS and cNOS to RGC degeneration were examined with intraocular injections of the specific iNOS inhibitor L-N(6)-(I-iminoethyl)lysine hydrochloride or the specific cNOS inhibitor L-thiocitrulline. Our results suggest that cNOS plays a greater role in RGC degeneration than iNOS. In addition to enhancing RGC survival, NOS inhibitors delayed the retrograde degeneration of RGC axons after axotomy. We conclude that NO synthesized by retinal iNOS and cNOS plays a major role in RGC death and retrograde axonal degeneration following axotomy.

Neurturin enhances the survival of axotomized retinal ganglion cells in vivo: Combined effects with glial cell line-derived neurotrophic factor and brain-derived neurotrophic factor

In the present study we localized glial cell line-derived neurotrophic factor (GDNF), and the high affinity receptor for GDNF (GFRalpha-1) in the rat retina. We also examined the effects of neurturin on the survival of axotomized retinal ganglion cells (RGCs) and compared neurturin-mediated RGC rescue to GDNF and brain-derived neurotrophic factor (BDNF) neuroprotection. We administered combined injections of neurturin with BDNF or GDNF in order to determine if these factors rescue RGCs by different mechanisms. GDNF immunoreactivity was localized to RGCs, photoreceptors, and retinal pigment epithelial cells. GFRalpha-1 immunoreactivity was localized to RGCs, Müller cells, and photoreceptors. RGC densities in control retinas decreased from the original value of 2481+/-121 (RGCs/mm(2)+/-S.D.) to 347+/-100 at 14 days post-axotomy. Neurturin treatment significantly increased RGC survival after axotomy (745+/-94) similar to GDNF (868+/-110). BDNF treatment resulted in higher RGC survival (1109+/-156) than either neurturin or GDNF. Combined administration of neurturin with BDNF had additive effects on the survival of axotomized RGCs (1962+/-282), similar to combined administration of GDNF and BDNF (1825+/-269). Combined administration of neurturin and GDNF (1265+/-178) had an enhanced effect on RGC survival. These results suggest that neurturin, GDNF, and BDNF act independently to rescue injured RGCs. Our results also suggest that RGCs and retinal Müller cells may be responsive to GDNF because they both express GFRalpha-1. The present findings have implications for the rescue of injured retinal ganglion cells, as well as other CNS neurons that are responsive to neurturin, GDNF, and BDNF, including midbrain dopaminergic neurons and motor neurons.

Background illumination reduces horizontal cell receptive-field size in both normal and 6-hydroxydopamine-lesioned goldfish retinas.

The effect of background illumination on horizontal cell receptive-field size and dye coupling was investigated in isolated superfused goldfish retinas. Background illumination reduced both horizontal cell receptive-field size and dye coupling. The effect of light on horizontal cell receptive-field size was mimicked by treating the retina with 20 microM dopamine. To test the hypothesis that the effects of light were due to endogenous dopamine release, the effect of light was studied in goldfish retinas in which dopaminergic interplexiform cells were lesioned using 6-hydroxydopamine treatment. In lesioned retinas, background illumination reduced both horizontal cell receptive-field size and dye coupling. Furthermore, the effect of background illumination on unlesioned animals could not be blocked by prior treatment with the D1 dopamine receptor antagonist SCH-23390. These results suggest that, in goldfish retina, dopamine release is not the only mechanism by which horizontal cell receptive-field size could be reduced by light.

Effects of adenoviral-mediated gene transfer of interleukin-10, interleukin-4, and transforming growth factor-β on the survival of axotomized retinal ganglion cells

Nitric oxide, synthesized by reactive microglia and astrocytes has been implicated in promoting neuronal degeneration observed in many diseases and insults of the central nervous system. We have recently shown that inducible nitric oxide synthase is expressed by retinal glial cells following optic nerve transection and that inhibition of nitric oxide synthesis enhances the survival of injured retinal ganglion cells. Anti-inflammatory cytokines including interleukin-10 (IL-10), interleukin-4 (IL-4), and transforming growth factor-beta (TGF-beta) have been shown to prevent inducible nitric oxide synthase expression, and inhibit nitric oxide synthesis by microglia and astrocytes in culture. In the present study, we examined the effects of adenoviral mediated gene transfer of anti-inflammatory cytokines on the survival of axotomized retinal ganglion cells. Intraocular administration of adenoviral vectors encoding interleukin-10 (Ad.IL-10) and interleukin-4 (Ad.IL-4) enhanced the survival of axotomized retinal ganglion cells at 14 days after axotomy. Adenoviral vectors encoding TGF-beta (Ad.TGF-beta) had no effect on retinal ganglion cell survival. Separate animals were pretreated by injection of Ad.IL-10 or Ad.IL-4 into the superior colliculus (s.c.), the major target of ganglion cells, 7 days prior to axotomy. S.c. administration of Ad.IL-10 or Ad.IL-4 significantly increased ganglion cell survival compared with intraocular injection. IL-10 and IL-4 gene transfer also reduced the density of infiltrating ED1 positive monocytes in the nerve fiber layer at 14 days postaxotomy. Ad.TGF-beta increased the density of ED1 positive monocytes infiltrating the nerve fiber layer after axotomy. Vectors encoding IL-10 or IL-4 also decreased nitrotyrosine immunoreactivity in the inner retina at 7 days postaxotomy, suggesting that these cytokines protect retinal ganglion cells from peroxynitrite formation that results from nitric oxide synthesis by activated glial cells. The present study has implications for the treatment of CNS injury and diseases that involve reactive microglia and astrocytes. Our results suggest that interleukin-10 and interleukin-4 may help prevent neurodegeneration caused by the activation of glial cells after CNS injury.

Proliferating brain cells are a target of neurotoxic CSF in systemic autoimmune disease.

Brain atrophy, neurologic and psychiatric (NP) manifestations are common complications in the systemic autoimmune disease, lupus erythematosus (SLE). Here we show that the cerebrospinal fluid (CSF) from autoimmune MRL-lpr mice and a deceased NP-SLE patient reduce the viability of brain cells which proliferate in vitro. This detrimental effect was accompanied by periventricular neurodegeneration in the brains of autoimmune mice and profound in vivo neurotoxicity when their CSF was administered to the CNS of a rat. Multiple ionic responses with microfluorometry and protein peaks on electropherograms suggest more than one mechanism of cellular demise. Similar to the CSF from diseased MRL-lpr mice, the CSF from a deceased SLE patient with a history of psychosis, memory impairment, and seizures, reduced viability of the C17.2 neural stem cell line. Proposed mechanisms of cytotoxicity involve binding of intrathecally synthesized IgG autoantibodies to target(s) common to different mammalian species and neuronal populations. More importantly, these results indicate that the viability of proliferative neural cells can be compromised in systemic autoimmune disease. Antibody-mediated lesions of germinal layers may impair the regenerative capacity of the brain in NP-SLE and possibly, brain development and function in some forms of CNS disorders in which autoimmune phenomena have been documented.

Localization of gap junctions and tracer coupling in retinal müller cells

Physiological studies have demonstrated the existence of direct intercellular communication, presumably mediated by gap junctions, both between neurons and between glial cells in the vertebrate retina. We localized gap junctions in the retinas of rat, goldfish, and mudpuppy by using antisera directed against proteins that make up the connexon channels in two tissues from which connexins have been isolated: liver (connexin 32; CX32) and heart (connexin 43; CX43). Although the antiserum against CX32 stained liver gap junctions, it did not reveal any staining in rat or goldfish retina. The antiserum against CX43 stained gap junctions associated with the intercalated disk in rat heart and also stained gap junctions between pigment epithelium cells in rat, goldfish, and mudpuppy retina. Anti‐CX43 also stained gap junctions between Müller cells in goldfish and mudpuppy retina but not in rat retina. Intracellular injections of the tracer Neurobiotin into Müller cells in the mudpuppy retina revealed that these glial cells are extensively tracer coupled. Staining with the tracer formed a syncytium of thin processes surrounding every neuron from the outer limiting membrane to the inner limiting membrane. Confocal microscopy demonstrated that the Müller cells were in close apposition with one another at every level of the retina. However, CX43 immunoreactivity was heaviest at the outer limiting membrane, where the apical processes of Müller cells are located. Some anti‐CX43 staining was observed at the level of the outer nuclear layer and the inner plexiform layer but not in the ganglion cell layer or at the Müller cell end feet forming the inner limiting membrane. J. Comp. Neurol. 393:48–57, 1998.

Efferent Projections to the Goldfish Retina

The centrifugal innervation of the retina has been extensively described in birds (Cowan, 1970), but only recently has the existence of efferents been demonstrated in a variety of other species, including several species of fish (Witkovsky, 1971; Ebbesson and Meyer, 1981; Munz and Claas, 1981; Munz et al, 1982; Gerwerzhagen et al, 1982; Crapon de Caprona and Fritzsch, 1983; Meyer et al, 1983; Springer, 1983). Retrograde tracing methods have shown that there may be as many as five central sources of fish retinal efferents (Ebbesson and Meyer, 1981). Reports on the number and location of these efferent sources are inconsistent, but there is agreement that one source of retinal efferents is the terminal nerve (TN) (Springer, 1983).

Characterization of the optic nerve and retinal ganglion cell layer in the dysmyelinated adult Long Evans Shaker rat: Evidence for axonal sprouting

Myelin in the central nervous system (CNS) is hypothesized to help guide the growth of developing axons by inhibiting sprouting of aberrant neurites. Previous studies using animal models lacking CNS myelin have reported that increasing capacity for sprouting axons is negatively correlated with the degree of myelination. In the present study, we investigated the optic nerves of the recently identified Long Evans Shaker (LES) rat with prolonged dysmyelination of adult axons to determine whether the lack of myelin basic protein (MBP) in adult LES rats could manifest as increases in the population of CNS axons. We observed numerous small, unmyelinated axon profiles (<0.3 μm in diameter) clustered in bundles alongside normal caliber axons in dysmyelinated LES rats but not in normal myelinated Long Evans (LE) rats. These putative axon profiles resembled sprouting axons previously described in the CNS. Moreover, the high number of small putative axon profiles could not be accounted for by any significant increases in the number of ganglion cells and displaced amacrine cells in the ganglion cell layer when compared with normal rats as evaluated by using a variety of techniques. This finding suggests that the observed clusters of putative axon profiles were not due to developmental abnormalities in the retina but to the lack of myelin in the optic nerves of LES rats. The adult LES rat, therefore, may serve as a useful model to study the role of myelin in regulating axon development or axon regeneration after CNS injury in the adult mammalian system. J. Comp. Neurol. 451:213–224, 2002.