Reduced redox state allows prolonged survival of axotomized neonatal retinal ganglion cells.

Axonal injury to CNS neurons results in apoptotic cell death. The processes by which axotomy signals apoptosis are diverse, and may include deprivation of target-derived factors, induction of injury factors, bursts of reactive oxygen species (ROS), and other mechanisms. Our previous studies demonstrated that death of a dissociated retinal ganglion cell, an identified CNS neuron, is ROS-dependent. To better define the mechanisms by which ROS induce retinal ganglion cell death after axotomy, we studied their effects in dissociated neonatal rat retinal cultures. Postnatal day 2-4 Long-Evans rat retinal ganglion cells were retrogradely labeled with the fluorescent tracer 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine (DiI). Postnatal day 7-9 retinas were dissociated and cultured in the presence of specific ROS generating systems, scavengers, or redox modulators. Retinal ganglion cells were identified by DiI positivity and viability determined by metabolism of calcein-acetoxymethyl ester. We found that ROS scavengers protected against retinal ganglion cell death after acute dissociation, and the effects of ROS appeared to be due to shifts in the redox potential, as retinal ganglion cell survival was critically dependent on redox state, with greatest survival under mildly reducing conditions. Culture of retinal ganglion cell with the non-thiol-containing reducing agent tris(carboxyethyl)phosphine resulted in long-term survival equivalent to or better than with neurotrophic factors. Our data suggest that axotomy-associated neuronal death induced by acute dissociation may be partly dependent on ROS production, acting to shift the redox state and oxidize one or more key thiols. Understanding the mechanisms by which ROS signal neuronal death could result in strategies for increasing their long-term survival after axonal injury.

Differential susceptibility of retinal ganglion cells to reactive oxygen species.

PURPOSE: Retinal light exposure is a source of oxidative stress, and retinal cells contain molecules that scavenge or inactivate reactive oxygen species (ROS). Yet, ROS also play a role in signal transduction, and some retinal cells (e.g., neurotrophin-dependent retinal ganglion cells, RGCs) may use ROS as part of the signaling process for cell death. RGCs might therefore have specialized mechanisms for regulating ROS levels. The hypothesis that RGCs might regulate ROS differently from other retinal cells was tested by studying their differential response to oxidative stress in vitro. METHODS: RGCs were retrogradely labeled by injecting the fluorescent tracer DiI into the superior colliculi of postnatal day 2 through 4 Long-Evans rats. At postnatal days 7 through 9 the retinas were dissociated with papain and cultured with and without specific ROS-generating systems and/or scavengers. RGCs were identified by their DiI positivity using rhodamine filters. Living cells, determined by metabolism of calcein-AM viewed with fluorescein filters, were counted in triplicate. Degenerate reverse transcription-polymerase chain reaction (RT-PCR) using primers specific to peroxidase homology regions was used to survey for novel peroxidases expressed within normal retinas. RESULTS: Compared with other retinal cells, RGCs were remarkably resistant to cell death induced by superoxide anion, hydrogen peroxide, or hydroxyl radical. Catalase counteracted the effect of each ROS-generating system on retinal cells, consistent with damage occurring via a hydrogen peroxide intermediate. Aminotriazole, L-buthionine sulfoximine, and sodium azide partly abrogated the RGC resistance to oxidative stress, suggesting that this resistance may be mediated by catalase and/or glutathione peroxidase. A limited expression survey within the retina using degenerate RT-PCR did not demonstrate novel peroxidases. CONCLUSIONS: These data suggest a role for one or more endogenous peroxidases within RGCs, which could possibly be protective under conditions of axonal damage. Exploration of the unique characteristics of RGC resistance and susceptibility to injury may help in better understanding the pathophysiology of diseases associated with primary axonal damage.

An anatomic atlas of the medulla oblongata of the adult goat.

An anatomic atlas of the goat brain stem was developed for use in studies that analyze medullary neuronal groups, and factors that influence variability in the location of neuronal groups were determined. The medullas of 31 adult goats (weight, 17-88 kg) were fixed, harvested, frozen, serially sectioned, stained with 0.5% neutral red, and examined with a light microscope. Obex, the point at which the central canal opens into the fourth ventricle, was taken as the zero reference point from which the rostrocaudal and mediolateral coordinates of medullary neuronal groups were determined, whereas dorsoventral coordinates were calculated from the medullary surface. Histological variations with goat body weight were quantified, and linear regression analysis provided adjustment factors for weight in all three dimensions. Similar analysis of percentage of shrinkage on fixation and processing provided adjustment factors for precise coordinates of medullary neuronal groups. For accurate location of neuronal groups, body weight and histological procedure should be taken into account. The present study provided adjustment factors for body weight and standard histological processing to locate most major medullary neuronal groups in the adult goat.