Migration and synaptogenesis of cone photoreceptors in the developing mouse retina.

Mouse retinal photoreceptor cell generation and morphogenesis take place in a well-characterized temporal sequence. Both rod and cone photoreceptor differentiation and synaptogenesis occur postnatally, but the relative timing of these events has been difficult to document due to the paucity of cell-specific markers. We have found that antibodies to neuron-specific enolase (NSE) preferentially label a subpopulation of photoreceptors in the outer nuclear layer (ONL) of the mouse retina in addition to labeling ganglion, amacrine, bipolar, and horizontal cells within the inner layers of the retina. The appearance of NSE immunoreactivity in the different classes of retinal neurons during development showed a close temporal relationship to the onset of expression of the synaptic vesicle-associated protein SV2 and clearly preceded the sequential development of synaptic connections in both inner and outer synaptic layers. The NSE-immunoreactive photoreceptors were identified as cones by dual labeling of their inner segments with the lectin peanut agglutinin or by colabeling with antisera to cone photopigments. Axonal extensions of NSE-labeled cone cells were shown to interact with those of differentiating horizontal cells as early as postnatal day 3 (P3). Colocalization of NSE with SV2 indicated that cone cells began to make synaptic contacts with horizontal cell processes several days prior to the development of rod synaptic terminals. Between P4 and P11, cone photoreceptor cell nuclei were observed to be scattered at various levels throughout the ONL and thus appeared to have become displaced from their previous position directly beneath the outer limiting membrane (OLM). By P12, the cone nuclei had migrated sclerad once again and were now observed to be neatly aligned adjacent to the OLM. In the rd mouse mutant, this migratory process was delayed, so that, at P12, positioning of the cone cell nuclei within the ONL was still quite irregular. Thus, we have identified a late migratory phase for cone photoreceptors during the second week after birth that correlates with the timing of maturation of the rod synaptic terminals just prior to eye opening. The types of cues used by maturing cone cells for their eventual sclerad location remain to be elucidated.

Lineage study of degenerating photoreceptor cells in the rd mouse retina.

PURPOSE: A retroviral marker was used to label daughter cells arising from individual neuroblasts in the rd mouse retina, in order to investigate the hypothesis that a clonal relationship exists among degenerating photoreceptor cells. METHODS: On the day of birth, a single injection of retrovirus with a lac Z (beta-galactosidase) reporter construct was injected into the retina in the vicinity of the subretinal space. Descendants of single neuroblasts were identified histochemically by examining the retinas at P14 (postnatal day 14). Light and electron microscopic studies were used to identify the retrovirally-induced marker beta-galactosidase using Bluo-gal dye. Double-labeling of degenerating cone cells was accomplished by taking 100 microns vibratome sections of retrovirally-injected eyes and using either FITC-PNA or HRP-PNA to visualize clusters of degenerating cones as well as Bluo-gal labeled clones of photoreceptor cells on the same tissue section. RESULTS: A relatively large number of clones of primarily photoreceptor cells were observed in the peripheral retinas of both normal and rd mice. In a few cases in the rd, photoreceptor cells in a given clone consisted of both PNA- and Bluo-gal-labeled cells as well as of only Bluo-gal-labeled cells. CONCLUSION: These results suggest that during the period of intense cell death in the rd retina, a single dying photoreceptor cell can be surrounded by photoreceptors (either rods or cones) from the same clone that appear morphologically normal without evidence of degeneration.

Aberrant expression of c-Fos accompanies photoreceptor cell death in the rd mouse.

Selective degeneration of rod photoreceptor cells in the retinal degenerative (rd) mouse prior to their complete maturation is thought to result from elevated cyclic guanosine monophosphate (cGMP) levels owing to the inherited defect in cGMP-phosphodiesterase. To investigate potential signaling pathways which might lead to apoptotic death of photoreceptors in the rd retina, the expression of immediate-early genes (IEG) of the activating protein-1 transcription factor (AP-1) family was examined. Increasing numbers of apoptotic photoreceptor nuclei were observed in the outer nuclear layer of the rd mouse beginning at postnatal day (P) 10. The peak incidence of apoptotic cells was observed at P13; by P16, almost the entire population of photoreceptors had been lost. Although c-Fos-like immunoreactivity was absent in photoreceptors of normal retinas, we observed that commencing at around P10, increasing numbers of rod photoreceptors in the rd retina exhibited nuclear staining for c-Fos protein. While no change in the distribution patterns of other members of the AP-1 family (c-Jun, JunB, and JunD) was observed in photoreceptors, Müller cell nuclei were transiently immunoreactive for c-Jun on P11. The incidence of c-Fos-positive photoreceptors peaked sharply at P12, 1 day earlier than the peak in apoptosis. Furthermore, the population of c-Fos-positive photoreceptors was distinct from apoptotic photoreceptors exhibiting chromatin condensation. The aberrant expression of c-Fos protein in rod photoreceptors immediately prior to their death in the rd mouse raises the possibility that c-Fos may be directly or indirectly involved in triggering the apoptotic cascade. Furthermore, the additional finding of c-Jun induction in Müller glia suggests that the IEG response to photoreceptor degeneration involves both intra- and intercellular signal transduction pathways.

Retinal light damage in rats with altered levels of rod outer segment docosahexaenoate.

PURPOSE: To compare retinal light damage in rats with either normal or reduced levels of rod outer segment (ROS) docosahexaenoic acid. METHODS: Weanling male albino rats were maintained in a weak cyclic light environment and fed either a nonpurified control diet or a purified diet deficient in the linolenic acid precursor of docosahexaenoic acid (DHA). Half the rats on the deficient diet were given linseed oil, containing more than 50 mol% linolenic acid, once a week to maintain ROS DHA at near normal levels. Diets and linseed oil supplementation were continued for 7 to 12 weeks. To replenish DHA in their ROS, some 10-week-old rats on the deficient diet were given linseed oil three times a week for up to 3 additional weeks. Groups of animals were killed at various times for ROS fatty acid determinations or were exposed to intense green light using intermittent or hyperthermic light treatments. The extent of retinal light damage was determined biochemically by rhodopsin or photoreceptor cell DNA measurements 2 weeks after exposure and morphologically by light and electron microscopy at various times after light treatment. RESULTS: Rats maintained for 7 to 12 weeks on the linolenic acid-deficient diet had significantly lower levels of DHA and significantly higher levels of n-6 docosapentaenoic acid (22:5n-6) in their ROS than deficient-diet animals supplemented once a week with linseed oil or those fed the nonpurified control diet. As determined by rhodopsin levels and photoreceptor cell DNA measurements, deficient diet rats exhibited protection against retinal damage from either intermittent or hyperthermic light exposure. However, the unsaturated fatty acid content of ROS from all three dietary groups was the same and greater than 60 mol%. In 10 week-old deficient-diet rats given linseed oil three times a week, ROS DHA was unchanged for the first 10 days, whereas 22:5n-6 levels declined by 50%. After 3 weeks of treatment with linseed oil, ROS DHA and 22:5n-6 were nearly the same as in rats supplemented with linseed oil from weaning. The time course of susceptibility to retinal light damage, however, was different. Hyperthermic light damage in rats given linseed oil for only 2 days was the same as for rats always fed the deficient diet. Six days after the start of linseed oil treatment, retinal light damage was the same as in rats given the linseed oil supplement from weaning. Morphologic alterations in ROS of linseed oil-supplemented rats immediately after intermittent light exposure were more extensive than in either the deficient-diet animals or those fed the control diet. The deficient-diet rats also exhibited better preservation of photoreceptor cell nuclei and structure 2 weeks after exposure. CONCLUSIONS: Rats fed a diet deficient in the linolenic acid precursor of DHA are protected against experimental retinal light damage. The relationship between retinal light damage and ROS lipids does not depend on the total unsaturated fatty acid content of ROS; the damage appears to be related to the relative levels of DHA and 22:5n-6.

Use of a retroviral vector with an internal opsin promoter to direct gene expression to retinal photoreceptor cells.

PURPOSE: Viral-mediated gene transfer to retina, as well as to other tissues, is evolving rapidly. We have evaluated the potential of a retroviral vector with an internal opsin promoter fragment to direct gene expression to retinal photoreceptor cells. METHODS: Two recombinant retroviral vectors were prepared; in each Vector, a 1.4 kb fragment of the mouse opsin promoter was placed downstream from the neoR gene in the Moloney murine leukemia virus-based vector G1Na. The opsin promoter fragment was linked either to the cDNA for mouse rod photoreceptor phosphodiesterase (PDE) beta-subunit or to the bacterial lacZ reporter gene. These vectors were tested for their ability to direct gene expression after transduction of 3T3 and Y79 cells, or of dissociated retinal cell cultures or retinal explants from neonatal mice. RESULTS: As expected, PDE beta-subunit and beta-galactosidase mRNAs were expressed only at low levels in 3T3 fibroblasts and Y79 retinoblastoma cells. Northern blot analysis indicated that expression was derived from the viral long terminal repeat (LTR) promoter. Infection of primary retinal cell cultures or explants from neonatal mice with BAG retrovirus, in which beta-galactosidase is driven by the viral LTR, resulted in expression in many cell types, while the opsin-lacZ vector mediated the expression of the lacZ reporter gene specifically in photoreceptor cells. CONCLUSIONS: The internal opsin promoter fragment appears capable of selectively directing gene expression to photoreceptor cells after retroviral-mediated gene transfer. These findings serve as a basis for future studies using the opsin promoter-beta PDE retroviral vector to rescue photoreceptor cells in the rd mutant mouse, in which the beta-PDE gene is mutated resulting in degeneration of photoreceptor cells during the early postnatal period.

Retinal pathology in Alzheimer's disease. II. Regional neuron loss and glial changes in GCL.

Detailed analyses of neuronal and astrocyte cell numbers in the ganglion cell layer (GCL) of whole-mounted peripheral retinas from 16 Alzheimer's disease (AD) and 11 control eyes (11 and 9 cases, respectively) demonstrate extensive neuronal loss throughout the entire retina in AD as compared to control eyes. The observed neuronal loss is most pronounced in the superior and inferior quadrants, ranging between 40 and 49% throughout the midperipheral regions, and reaching 50-59% in the far peripheral inferior retina, while the overall neuronal loss throughout the entire retina amounts to 36.4% (p < 0.004). Although the 16% increase in astrocyte numbers is not significant, the ratio of astrocytes to neurons is significantly higher (82%; p < 0.0008) in AD as compared to normal retina (0.238 +/- 0.070 vs. 0.131 +/- 0.042). These results are strengthened by the close agreement (within +/- 15% of respective means) found between fellow eyes. Analysis of glial fibrillary acidic protein immunoreactivity (GFAP-ir) in sections of retinas from an additional 12 AD and 19 control cases show increased GFAP-ir with more extensive labeling of astrocytes in the GCL as well as increased labeling of Müller cell end-feet and radial processes in AD as compared to control retinas. The extensive loss of neurons documented in these retinas, accompanied by an increased astrocyte/neuron ratio, provides further support for the substantial involvement of the retina in AD.

Retinal pathology in Alzheimer's disease. I. Ganglion cell loss in foveal/parafoveal retina.

Morphometric analysis of the numbers of neurons in the ganglion cell layer (GCL) of the central retina (fovea/foveola/parafoveal retina) in eyes from 9 Alzheimer's disease (AD) and 11 age-matched control cases revealed an overall decrease of 25% in total numbers of neurons in AD as compared with control eyes. Detailed analyses of GCL neurons at various eccentricities from the foveola showed that the greatest decrease in neuronal density (43% decrease) occurred in the central 0-0.5 mm (foveal region), while at 0.5-1 mm and at 1-1.5 mm eccentricities, neuronal loss amounted to 24 and 26%, respectively. The temporal region of the central retina appeared most severely affected, with up to 52% decrease in neuronal density near the foveola (central 0-0.5 mm eccentricity). There was close agreement between fellow eyes analyzed separately for three AD and three control cases. Analysis of neuronal sizes showed that all sizes of neurons were similarly affected in AD. In the GCL of control retinas, neurons decreased with age (coefficient of correlation = -0.67), while in AD retinas no such relationship was evident. Since in the central 0-2 mm region of the retina 97% of neurons in the GCL are ganglion cells (while the remaining 3% consist of displaced amacrine cells), these results demonstrate extensive ganglion cell loss in the central retina in AD.

Somatostatin-immunoreactive neurons in the adult rabbit retina.

Somatostatin (SRIF) is a neuroactive peptide that is distributed throughout the nervous system, including the retina. This peptide has been localized to populations of amacrine cells in a variety of vertebrate species. In the rabbit retina, SRIF immunoreactivity is present in a sparse population of medium to large neurons (13.72 microns in diameter, or 147.84 mu 2) in the ganglion cell layer and in a small number of neurons in the inner nuclear layer. These cells display a preferential distribution to the inferior retina, with the highest density near the ventral and ventrolateral retinal margins (11.33 cells/mm2). SRIF-immunoreactive cells have two to five primary processes that arborize in the proximal inner plexiform layer (IPL). These give rise to a plexus of finer processes in the distal IPL. Occasional immunoreactive processes are also present in the outer plexiform layer. In the IPL, these laminar networks are present in all retinal regions. In addition, SRIF-immunoreactive cells often have a fine-caliber axonlike process that eminates from the soma or perisomal region. These processes travel for great distances across the retina in either the nerve fiber layer or in the distal IPL but are never seen to enter the optic nerve head. In addition, the number of SRIF-immunoreactive somata remains unchanged following transection of the optic nerve. Taken together, these data indicate that SRIF-immunoreactive neurons of the rabbit retina are displaced amacrine cells. Furthermore, the sparse distribution of SRIF-immunoreactive somata, the wide-ranging, asymmetric arborization of their cellular processes, and previous pharmacological studies suggest that these neurons mediate a broad modulatory role in retinal function.

Effects of Müller cell disruption on mouse photoreceptor cell development.

Müller cells have been proposed to play an important role in photoreceptor cell development during the final stages of retinal maturation. The effect of disrupting Müller cells during mouse retinal development was investigated using the specific glial cell toxin, DL-alpha-aminoadipic acid (AAA). By giving multiple systemic injections over several days, impairment of Müller cell function was maintained during the period of photoreceptor migration and differentiation. Following three consecutive days of AAA treatment [commencing on post-natal (P) day 3, 5, 7 or 9, and examined at P8-P14], clumps of photoreceptor nuclei were displaced through the inner segments, lying immediately beneath the retinal pigment epithelium (RPE). Apart from the scalloped appearance of the outer retina, the overall lamination pattern of the retina was relatively well preserved. Even when AAA treatment commenced as early as P3, several days prior to the formation of the outer nuclear layer, the majority of photoreceptors migrated to their correct position and formed inner and outer segments. Therefore, the signals for photoreceptor migration are either provided by the Müller cells prior to P3, or, alternatively, are derived from different intrinsic or extrinsic cues. Disruption of Müller cell function was evidenced by decreased glutamine synthetase activity as well as by increased glial fibrillary acidic protein (GFAP) and decreased cellular retinaldehyde-binding protein (CRALBP) immunoreactivity. Immunocytochemistry with an antibody to CD44, which labels the microvilli of Müller cells at the outer limiting membrane, coupled with electron microscopic analysis, demonstrated that the zonulae adherentes between Müller cells and photoreceptors were either irregular or absent in areas adjacent to displaced clumps of photoreceptors. Thus AAA treatment of early post-natal mice results in localized disruption of the contacts between Müller cells and photoreceptors. These pathologic changes persist into adulthood since at P28, while short stretches of photoreceptors appeared relatively normal with fully developed outer segments, periodic clumps of displaced photoreceptor nuclei were still present adjacent to the RPE. In conclusion, Müller cell processes at the outer limiting membrane appear to play a critical role in providing a barrier to aberrant photoreceptor migration into the subretinal space.

Hyperthermia accelerates retinal light damage in rats.

PURPOSE: To study the time course of visual cell damage resulting from hyperthermic light exposure and the possible involvement of rod outer segment (ROS) lipids in the process. METHODS: Rats were acclimated in darkness for 2 hours in a hyperthermic chamber to elevate core body temperature and then exposed to intense green light for up to 4 hours during hyperthermia. After light exposure, the animals were either sacrificed immediately for biochemical or morphologic analysis of retinal light damage or returned to darkness for up to 2 weeks at ambient temperature before analysis. Rod outer segment lipid profiles were characterized, and visual cell loss was determined by rhodopsin and visual cell DNA measurements. Morphology was performed at the light and electron microscopic level. RESULTS: Retinal damage resulting from hyperthermic light exposure was found to be temperature, time, and light intensity dependent. At an elevated environmental temperature of 34.5 degrees, 50% visual cell loss was found after 1.5 hours of 1100 lux light exposure; the same degree of visual cell loss occurred after only 1 hour when rats were maintained at 37 degrees C. At ambient temperatures, 4 hours of light exposure had no effect on visual cell loss. Irrespective of environmental temperature, when rats were maintained in darkness no visual cell loss occurred. Whereas docosahexaenoic acid (22:6) was unchanged in the purest fraction of ROS isolated immediately after light treatment, a 5 mol% loss of the polyunsaturated fatty acid was found in ROS isolated 2 or 24 hours after light exposure. Rod outer segment lipid composition was largely unaffected by hyperthermic light exposure, but the density of some ROS increased. Morphologically, the ROS appeared to be nearly normal immediately after hyperthermic light exposure and structurally more abnormal 2 and 24 hours later. The retinal pigment epithelium exhibited damage immediately after exposure, which also increased 2 and 24 hours later. CONCLUSIONS: Hyperthermia in rats dramatically accelerates retinal light damage compared with light exposure under euthermic conditions. Over loss of ROS 22:6 does not occur during hyperthermic light exposure, but it is apparent during the 24-hour period after light treatment. This suggests that the disappearance of 22:6 from ROS occurs in tandem with the process of visual cell death resulting from retinal light damage.

Cytoplasmic retinal localization of an evolutionary homolog of the visual pigments.

A rhodopsin-related protein is preferentially expressed at high levels in retinal pigment epithelium (RPE) and in Müller cells. The putative RPE-retinal G protein-coupled receptor (RGR) was localized in light-adapted bovine retina by means of electron microscopic immunocytochemistry. In the RPE, the protein was localized to a widespread intracellular compartment. Except for the region adjacent to the basal surface, the RPE cytoplasm was labeled throughout the cell including the apical surface. In Müller cells also RGR was found in the intracellular compartment, especially in the cytoplasm in the region of the Müller cell endfeet and proximal cell processes. Subcellular fractionation studies of bovine RPE and neural retina indicated that RGR is a membrane-bound protein. The intracellular localization of RGR is a unique variation in the subcellular distribution of seven-transmembrane-domain receptors and suggests an unconventional role for RGR in the signal transduction process.

Stage-specific binding of peanut agglutinin to aggregates of degenerating photoreceptor cells in the rd mouse retina.

Peanut agglutinin, a lectin with high binding affinity for galactose-galactosamine disaccharide, was used to monitor changes in the photoreceptor cell layer of mice with inherited retinal degeneration. Mice homozygous for the retinal degeneration (rd) gene exhibit a rapid loss of rod photoreceptor cells in the first postnatal month. Previous studies have shown that aggregates of peanut agglutinin-binding cells are observed in the outer nuclear layer in the retinal degenerative mouse at between postnatal days 10 and 18, a period during which massive photoreceptor degeneration occurs in this mutant. This study was performed to determine whether these peanut agglutinin-positive cell clusters represent degenerating photoreceptor cells or, alternatively, macrophages that have migrated into the photoreceptor cell layer. Electron microscopic cytochemistry, using horseradish-peroxidase-conjugated peanut agglutinin, was used to trace cellular processes of peanut-agglutinin-stained cell clusters. Additionally, macrophage-specific antibodies were employed to determine whether macrophages were present in the clusters. The cell clusters did not react with macrophage-specific antibodies. However, processes of cells in peanut-agglutinin-bound clusters could be traced by electron microscopic serial sections to both the outer limiting membrane and the outer synaptic layer. These results provide strong evidence that peanut-agglutinin-bound cells seen during this stage of degeneration in the rd mouse are degenerating photoreceptor cells. Since peanut agglutinin has been shown to bind preferentially to cone, but not to rod, photoreceptor cells, the results also suggest that the clusters may be aggregates of degenerating cones.

Ascorbate treatment prevents accumulation of phagosomes in RPE in light damage.

In dark-reared albino rats, exposure to 2 or 3 hr of intense light interrupted by 2 hr dark periods resulted in extensive degeneration of photoreceptor cells and degeneration of the retinal pigment epithelium (RPE). Ascorbate (ie, vitamin C) administration prior to light exposure protected photoreceptors and the RPE from light damage. In the present study, ascorbate-treated and untreated rats were exposed to various cycles of intermittent light. Immediately after this light exposure, phagosome frequency in the RPE was morphologically evaluated in comparable 50 microns sections. In untreated rats, exposure to 2 or 3 hr of intermittent light resulted in a five- to sixfold increase in phagosome density compared to unexposed controls. In contrast, no increase in phagosome density was observed in ascorbate-treated rats. In these animals, under all lighting regimens, phagosome levels remained essentially identical to those in rats not exposed to light. After a single nondamaging light exposure, phagosome density remained at the level of dark controls in ascorbate-treated and untreated rats. These results indicate that phagosome frequency may serve as an index for light damage and that the protective effect of ascorbate may be linked to its capacity to prevent rod outer segment shedding and phagocytosis under intense light conditions.

Retinal degeneration in the pcd/pcd mutant mouse: accumulation of spherules in the interphotoreceptor space.

The Purkinje cell degeneration (pcd) mutant mouse rapidly loses cerebellar Purkinje cells and about 50% of its retinal photoreceptor cells at between 3 and 5 weeks of age, and thereafter slowly loses the remaining photoreceptor cells during the first year of life. An ultrastructural study of the developing photoreceptor cells of the pcd/pcd retina was undertaken using both transmission and scanning electron microscopy to characterize further the previously reported retinal vesicles associated with this mutation. Transmission electron microscopy (TEM) revealed an abundance of 'bead-like' vesicles or excrescences in the extracellular matrix surrounding the inner segment region at post-natal day (P) 25. The vesicles are membrane bound, amorphous in appearance and vary in size from 125 to 370 nm. Scanning electron microscopy suggests that the vesicles seen with TEM are actually spherules formed from outpocketing and pinching off of the plasma membrane in the mitochondria-rich region of the rod inner segment. At P25, the spherules are concentrated in the interphotoreceptor space at the level of rod inner segments; at P40, however, they are displaced from their origin and appear mostly at the level of rod outer segments and in the subretinal space.

Protection by dimethylthiourea against retinal light damage in rats.

The protective effect of dimethylthiourea (DMTU) against retinal light damage was determined in albino rats reared in darkness or in weak cyclic light. Rats maintained under these conditions were treated with DMTU at different concentrations and dosing schedules and then exposed for various times to intense visible light, either intermittently (1 hr light and 2 hr dark) or continuously. The extent of retinal light damage was determined 2 weeks after light exposure by comparing rhodopsin levels in experimental rats with those in unexposed control animals. To determine the effect of DMTU on rod outer segment (ROS) membrane fatty acids, ROS were isolated immediately after intermittent light exposure, and fatty acid compositions were measured. The time course for DMTU uptake and its distribution in serum, retina, and the retinal pigment epithelium (RPE)/choroid complex was determined in other rats not exposed to intense light. After intraperitoneal injection of the drug (500 mg/kg body weight), DMTU appeared rapidly in the serum, retina, and the RPE and choroid. In the ocular tissues, it was distributed 70-80% in the retina and 20-30% in the RPE and choroid. This antioxidant appears to have a long half-life because it was present in these same tissues 72 hr after a second intraperitoneal injection. For rats reared in the weak cyclic light environment, DMTU (two injections) provided complete protection against rhodopsin loss after intense light exposures of up to 16 hr. Only 15% rhodopsin loss was found in cyclic-light DMTU-treated rats after 24 hr of intermittent or continuous light. For rats reared in darkness, DMTU treatment resulted in a rhodopsin loss of less than 20% after 8-16 hr of continuous light and approximately 40% after similar exposure to intermittent light. Irrespective of the type of light exposure, rhodopsin loss in the dark-reared DMTU-treated rats was nearly identical to that found in uninjected cyclic light-reared animals. In rats from both light-rearing environments, DMTU treatment prevented the light-induced loss of docosahexaenoic acid from ROS membranes. As measured by rhodopsin levels 2 weeks later, DMTU was most effective when given as two doses administered 24 hr before and just before intense light exposure. As a single dose given during continuous light exposure, DMTU protected cyclic light-reared rats for at least 4 hr after the start of exposure but was ineffective in dark-reared animals if injected 1 hr after the start of light. It was also ineffective in both types of rats when given after light exposure.(ABSTRACT TRUNCATED AT 400 WORDS)

Subretinal perfluorocarbon liquids. An experimental study.

Perfluorocarbon liquids (PFCL) are fully fluorinated, synthetic, transparent compounds with a high specific gravity. These compounds are being increasingly used as an intraoperative tool for repair of complicated retinal detachments. A known complication of their use, however, is liquid entering the subretinal space via a retinal break. The purpose of this study was to evaluate the effects of two of these liquids when placed subretinally in the rabbit eye. Vitrectomy, retinotomy, and subretinal injection of 0.03 cc of either perfluoroctane, perfluorotributylamine, or balanced salt solution (control eyes) were performed on 36 rabbit eyes. Animals were monitored clinically by indirect ophthalmoscopy and fundus photography for up to 21 days. After the 21-day observation period, electroretinograms (ERG) were taken before the rabbits were killed. Histopathologic studies were done at 3 hours, 24 hours, 3 days, 7 days, 14 days, and 21 days after injection. Three eyes demonstrated tearing of the retinotomy site due to downward migration of the PFCL droplet. Results of the ERGs were normal in all animals tested. Phagocytosis of PFCL droplets by the retinal pigment epithelium (RPE) was observed in 1 eye 3 hours after injection. Three of the eyes that received PFCL injections and all of the control eyes demonstrated moderate intracellular edema of both inner and outer nuclear layers as early as 24 hours after injection. In one eye injected with PFCL, these changes progressed to swelling and cystic formation of the inner nuclear layer and mild degeneration of the outer photoreceptor segments 3 days after injection. It was assumed that these effects occurred on a mechanical basis and were not related to PFCL toxicity.(ABSTRACT TRUNCATED AT 250 WORDS)

Retinal degeneration in the macula of patients with Alzheimer's disease.

Recent reports (Hinton et al. 1986; Blanks et al. 1989) document the involvement of the retina in the constellation of neurodegenerative changes present in Alzheimer's disease (AD). These studies demonstrate the degeneration of large numbers of optic nerve axons and loss of retinal ganglion cells (RGCs) in patients with AD, but the quantitative changes in the retina of patients with AD compared with age-matched controls have not been examined. An important question is whether the lesion affects the macula, the area of highest visual acuity and the region of the greatest density of cone photoreceptor cells and RGCs. Additionally, it is unknown if patients with AD have a uniform thinning of cells in the ganglion cell layer (GCL) or if there is a differential loss of the medium- to large-sized cells, as suggested earlier (Bassi et al. 1987) and documented histopathologically in some areas of the central nervous system of patients with AD (Kemper 1984). If patients with AD were to show a differential loss of large versus small RGCs with characteristic differences in density, distribution, central projections, and physiologic properties (see review by Rowe and Stone 1977), then a loss of the visual functions normally ascribed to these classes of mammalian RGCs might be expected. This quantitative study of the retinal lesions in the macula of patients with AD provides important data on the progression of the disease and may eventually be the basis for diagnostic procedures for assessing the severity of AD.

Novel localization of a G protein, Gz-alpha, in neurons of brain and retina.

Recently, a cDNA coding for a novel G protein alpha-subunit, Gz-alpha, was isolated from a human retinal cDNA library and shown by Northern blot analysis to be expressed at high levels in neural tissues. We have prepared affinity-purified antibodies specifically directed against synthetic Gz-alpha peptides and employed immunohistochemical methods to map the localization of Gz-alpha in human, bovine, and murine retina and brain. By light microscopy, Gz-alpha was localized to the cytoplasm of neurons, with predominant reactivity in ganglion cells of the retina, Purkinje cells of the cerebellum, and most neurons of the hippocampus and cerebral cortex. Reactivity was confined to perikaryon, dendrites, and a very short segment of proximal axons, except for the retinal ganglion cells, in which the axons in the nerve fiber layer showed intense Gz-alpha immunoreactivity proximal to the lamina cribrosa. Pre-embedding immunoelectron microscopy demonstrated the presence of focal Gz-alpha immunoreactivity on the nuclear membranes, endoplasmic reticulum, and plasma membranes of Purkinje cell perikarya and in association with microtubules in their proximal dendrites. Subcellular fractionation studies confirmed the association of Gz-alpha with plasma and intracellular membranes. The localization of Gz-alpha and its unique amino acid sequence suggest that it may have a specialized function in neural tissues.

Uptake of tritiated thymidine in mitochondria of the retina.

Light microscopic autoradiography with 3H-thymidine was used as a probe for DNA synthesis on the retinas of the guinea pig, rabbit, and monkey. Relatively heavy labeling was found in the ganglion cell and inner nuclear layers as well as in the photoreceptor inner segments in the guinea pig and monkey. Electron microscopic autoradiography demonstrated that in the ganglion cells and photoreceptor inner segments in the monkey, 89% of silver grains, representing thymidine uptake, were on or near the mitochondria.

Retinal ganglion cell degeneration in Alzheimer's disease.

This study documents the light-microscopic and ultrastructural characteristics of ganglion cell degeneration in the retinas of patients with Alzheimer's disease (AD). The results show degeneration in the retinal ganglion cells (RGCs) characterized by a vacuolated, 'frothy' appearance of the cytoplasm. The degeneration is unique in AD because of the absence of neurofibrillary tangles within the RGCs, or of neuritic plaques or amyloid angiopathy in the retinas or optic nerves of any of the cases examined. These results suggest that neuronal degeneration in the ganglion cell layer (GCL) should be added to the constellation of neuropathologic changes found in patients with Alzheimer's disease.