Distribution of Three Enzymes of γ-Aminobutyric Acid Metabolism in Monkey Retina

Abstract: The distributions of glutamate decarboxylase (EC 4.1.1.15), γ-aminobutyric acid transaminase (EC 2.6.1.19), and succinate semialdehyde dehydrogenase (EC 1.2.1.24) were determined in monkey retina. The decarboxylase was almost restricted to the inner plexiform layer. The transaminase was also highest in this layer, but activities were 40% as high in the adjacent third of the inner nuclear layer and in the ganglion cell and fiber layers. Succinate semialdehyde dehydrogenase was distributed very differently. Although it also showed a peak of activity in the inner plexiform layer, there was a second equal peak in the photoreceptor inner segment layer and a smaller peak in the outer plexiform layer, regions where both γ-aminobutyric acid transaminase and glutamate decarboxylase were essentially absent.     

THE DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE ACTIVITY IN VERTEBRATE RETINA1

Abstract— Choline acetyltransferase (ChAc) activity was determined in retinal layers from 10 vertebrates. In all animals, the highest activity was in the inner plexiform layer, intermediate activity in the inner nuclear and ganglion cell layers, and very low activity in the photoreceptor and outer plexiform layers and optic nerve. The pattern of distribution of enzyme activity within the inner nuclear layer corresponds quantitatively to the distribution of amacrine cells within that layer. A species difference of almost 90-fold was found between the lowest and highest values for ChAc activity in inner plexiform layer. The variation in enzyme activity found among homeotherms in inner nuclear and inner plexiform layers is related to the number of amacrine cell synapses in the inner plexiform layer. But the differences in enzyme activity are generally greater than those which have been found in numbers of amacrine cell synapses between species. The data suggest that cholinergic neurons in retina are to be found predominantly among the amacrine cell types and that not all amacrine cells will be found to be cholinergic.     

GABA concentration and GAD activity levels in normal and degenerated retinas from mice

Freeze-dried sections (14 m thick) were prepared from mice with normal (C57BL strain) and degenerated (C3H strain) retinas. GABA concentration and GAD activity were determined in the microsamples (1.8–20 ng dry weight) of retinal layers and sublayers, using an enzymatic amplication reaction, NADP cycling. 1) GABA was distributed over all layers of normal retina with a broad concentration peak covering both inner nuclear and plexiform layers. In contrast, GAD activity was mostly localized in the inner plexiform layer. 2) GABA concentration was similar in one-fourth of the sublayers of each inner nuclear or plexiform layer. GAD activity was highest in the innermost sublayer of the inner nuclear layer. An increasing gradient of GAD activity was present in the inward direction in the inner plexiform layer. 3) In the degenerated retina, lacking in photoreceptors, the inner nuclear and plexiform layers remained, and GABA and GAD levels in these layers were similar to those in normal retina.Special Issue dedicated to Dr. O. H. Lowry.     

Morphology of calretinin and tyrosine hydroxylase-immunoreactive neurons in the pig retina

The morphology of calretinin- and tyrosine hydroxylase-immunoreactive (IR) neurons in adult pig retina was studied. These neurons were identified using antibody immunocytochemistry. Calretinin immunoreactivity was found in numerous cell bodies in the ganglion cell layer. Large ganglion cells, however, were not labeled. In the inner nuclear layer, the regular distribution of calretinin-IR neurons, the inner marginal location of their cell bodies in the inner nuclear layer, and the distinctive bilaminar morphologies of their dendritic arbors in the inner plexiform layer suggested that these calretinin-IR cells were AII amacrine cells. Calretinin immunoreactivity was observed in both A-and B-type horizontal cells. Neurons in the photoreceptor cell layer were not labeled by this antibody. The great majority of tyrosine hydroxylase-IR neurons were located at the innermost border of the inner nuclear layer (conventional amacrines). The processes were monostratified and ran laterally within layer 1 of the inner plexiform layer. Some of the tyrosine hydroxylase-IR neurons were located in the ganglion cell layer (displaced amacrines). The processes of displaced tyrosine hydroxylase-IR amacrine cells were also located within layer 1 of the inner plexiform layer. Some processes of a few neurons were located in the outer plexiform layer. A very low density of neurons had additional bands of tyrosine hydroxylase-IR processes in the middle and deep layers of the inner plexiform layer. The processes of tyrosine hydroxylase-IR neurons extended radially over a wide area and formed large, moderately branched dendritic fields. These processes occasionally had varicosities and formed "dendritic rings". These results indicate that calretinin- and tyrosine hydroxylase-IR neurons represent specific neuronal cell types in the pig retina.     

Adrenergic retinal neurons of some new world monkeys

Summary The retina of Aotes monkeys, Cebus monkeys, squirrel monkeys, and marmosets were investigated. Adrenergic perikarya were found in the innermost cell rows of the inner nuclear layer of all the investigated species. In addition, the Cebus monkey was found to have a special type of adrenergic neurons in the inner nuclear layer. This cell type was called the adrenergic pleomorph cell. Its processes ramify in the inner nuclear and inner plexiform layers. Adrenergic terminals occur in three more or less well developed sublayers of the inner plexiform layer, the layers being best developed in the Cebus monkey. Adrenergic terminals were also found around the cells of the inner nuclear layer and at the horizontal cells, where a scant sublayer is formed. More than one adrenergic sublayer of the inner plexiform layer has not been observed in primates previously, nor have the adrenergic terminals in the inner nuclear layer been observed previously in any species. The adrenergic pleomorph cells of the Cebus monkey also seem to be unique. The marked differences even between animals as closely related as some platyrhine monkeys call for caution when comparing the detailed function of the retina in different animals.This study was supported by grants from the Swedish Medical Research Council (B69-14X-2321-02) and the Faculty of Medicine, University of Lund, and was carried out within a research group sponsored by the Swedish Medical Research Council (projects No. B69-14X-56-05C and B69-14X-712-04C).     

Somatostatin and VIP neurons in the retina of different species

Neurons displaying somatostatin or vasoactive intestinal polypeptide (VIP) immunoreactivity were detected among the amacrine cells in the retina of baboon, cynomolgus monkey, squirrel monkey, cow, pig, cat, rabbit, guinea-pig, rat, mouse, frog and goldfish. Generally, immunoreactive cell bodies were located in the inner nuclear layer with processes ramifying in three more or less well-defined sublayers in the inner plexiform layer. The density of the sublayers and their location varied with the peptide and species investigated. In most cases there was a sublayer in the outermost part (Ramon y Cajal's sublamina 1) of the inner plexiform layer and this sublayer was usually the best developed. In some species a few somatostatin fibres were also detected in the outer plexiform layer, suggesting that some interplexiform cells contain somatostatin. In the baboon VIP was found exclusively in interstitial amacrine cells which have their cell bodies and processes entirely within the inner plexiform layer.     

Somatostatin and VIP neurons in the retina of different species

Summary Neurons displaying somatostatin or vasoactive intestinal polypeptide (VIP) immunoreactivity were detected among the amacrine cells in the retina of baboon, cynomolgus monkey, squirrel monkey, cow, pig, cat, rabbit, guinea-pig, rat, mouse, frog and goldfish. Generally, immunoreactive cell bodies were located in the inner nuclear layer with processes ramifying in three more or less well-defined sublayers in the inner plexiform layer. The density of the sublayers and their location varied with the peptide and species investigated. In most cases there was a sublayer in the outermost part (Ramon y Cajal's sublamina 1) of the inner plexiform layer and this sublayer was usually the best developed. In some species a few somatostatin fibres were also detected in the outer plexiform layer, suggesting that some interplexiform cells contain somatostatin. In the baboon VIP was found exclusively in interstitial amacrine cells which have their cell bodies and processes entirely within the inner plexiform layer.     

Typology and distribution of ganglion cells in the retina of lamprey (Lampetra fluviatilis)

Retinal ganglion cells (GC) of the Lamprey were studied after in vitro labeling of these cells by iontophoretic deposition of horseradish peroxidase into the optic nerve. The majority of GC are located at the boundary between the inner nuclear layer and the inner plexiform layer; a small proportion (20%) lies in the vitreous portion of the inner plexiform layer. Four types of GC were identified.     

Laminar Distributions of Choline Acetyltransferase and Acetylcholinesterase Activities in the Inner Plexiform Layer of Rat Retina

Choline acetyltransferase and acetylcholinesterase activities were measured in samples taken at 7-micron increments through the inner plexiform layer of rat retina. These enzyme activities were not uniformly distributed through the depth of the inner plexiform layer. Peaks of choline acetyltransferase activity occurred at about one-third and peaks of acetylcholinesterase activity at about one-fifth of the depth into the inner plexiform layer from either side. The positions of the two peaks of choline acetyltransferase activity most likely correspond to the locations of processes from cholinergic amacrine somata in the inner nuclear layer, which spread in sublamina a, and processes from cholinergic amacrine somata "displaced" in the ganglion cell layer which spread in sublamina b of the inner plexiform layer. The peaks of acetylcholinesterase activity may in addition correspond to the processes of cholinoceptive amacrine and ganglion cells. The magnitudes of choline acetyltransferase and acetylcholinesterase activities are as high as found anywhere in rat brain, emphasizing the important role of cholinergic mechanisms in visual processing through the rat inner plexiform layer.     

Light- and electron-microscopic study of substance P-immunoreactive neurons in the guinea pig retina

Substance P (SP) immunoreactivity in the guinea pig retina was studied by light and electron microscopy. The morphology and distribution of SP-immunoreactive neurons was defined by light microscopy. The SP-immunoreactive neurons formed one population of amacrine cells whose cell bodies were located in the proximal row of the inner nuclear layer. A single dendrite emerged from each soma and descended through the inner plexiform layer toward the ganglion cell layer. SP-immunoreactive processes ramified mainly in strata 4 and 5 of the inner plexiform layer. SP-immunoreactive amacrine cells were present at a higher density in the central region around the optic nerve head and at a lower density in the peripheral region of the retina. The synaptic connectivity of SP-immunoreactive amacrine cells was identified by electron microscopy. SP-labeled amacrine cell processes received synaptic inputs from other amacrine cell processes in all strata of the inner plexiform layer and from bipolar cell axon terminals in sublamina b of the same layer. The most frequent postsynaptic targets of SP-immunoreactive amacrine cells were the somata of ganglion cells and their dendrites in sublamina b of the inner plexiform layer. Amacrine cell processes were also postsynaptic to SP-immunoreactive neurons in this sublamina. No synaptic outputs onto the bipolar cells were observed.     

Neuropeptide Y (NPY) immunoreactive neurons in the retina of different species

Neurons displaying Neuropeptide Y (NPY) immunoreactivity were found among amacrine cells in the retina of baboon, pig, cat, pigeon, chicken, frog, trout, carp and goldfish. The immunoreactive cell bodies were located in the middle and the innermost cell rows of the inner nuclear layer with processes forming one, two or three more or less well-defined sublayers in the inner plexiform layer. The location and the density of the sublayers varied with the species investigated. In the frog retina, bipolar-like cell bodies were found in the middle of the inner nuclear layer as well as sparsely occurring ovoid cell bodies in the ganglion cell layer. Like the amacrine cells, these cells emitted processes ramifying in three sublayers in the inner plexiform layer.     

Neuropeptide Y (NPY) immunoreactive neurons in the retina of different species

Summary Neurons displaying Neuropeptide Y (NPY) immunoreactivity were found among amacrine cells in the retina of baboon, pig, cat, pigeon, chicken, frog, trout, carp and goldfish. The immunoreactive cell bodies were located in the middle and the innermost cell rows of the inner nuclear layer with processes forming one, two or three more or less well-defined sublayers in the inner plexiform layer. The location and the density of the sublayers varied with the species investigated. In the frog retina, bipolar-like cell bodies were found in the middle of the inner nuclear layer as well as sparsely occurring ovoid cell bodies in the ganglion cell layer. Like the amacrine cells, these cells emitted processes ramifying in three sublayers in the inner plexiform layer.     

Ageing transition of superoxide dismutase in rat retina

To examine the relationship between retinal ageing and superoxide dismutase, the distribution and expression of the dismutase was studied in the retina of 2-year-old Sprague--Dawley albino rats with immunohistochemistry and immunochemical quantitative analysis. Eight-week-old Sprague--Dawley albino rats were used as controls. In 2-year-old rats, manganese superoxide dismutase (Mn-SOD) immunoreactivities in the photoreceptor inner segments, the outer nuclear layer and the inner plexiform layer were stronger than those in 8-week-old rats. Copper--zinc superoxide dismutase (CuZn-SOD) immunoreactivities in the outer nuclear layer and inner plexiform layer of 2-year-old rats were stronger than those in 8-week-old rats. Faint CuZn-SOD immunoreactivity became visible in the photoreceptor inner segments of 2-year-old rats, whereas no CuZn-SOD immunoreactivity was observed in 8-week-old rats. Our immunochemical quantitative analysis also showed an increase in the immunoreactivities of superoxide dismutases in the sensory retina with age. The transition of the dismutases may have some relationship with retinal ageing. © 1998 Chapman & Hall     

Differential Alterations in the Expression of Neurotransmitter Receptors in Inner Retina following Loss of Photoreceptors in rd1 Mouse

Loss of photoreceptors leads to significant remodeling in inner retina of rd1 mouse, a widely used model of retinal degeneration. Several morphological and physiological alterations occur in the second- and third-order retinal neurons. Synaptic activity in the excitatory bipolar cells and the predominantly inhibitory amacrine cells is enhanced. Retinal ganglion cells (RGCs) exhibit hyperactivity and aberrant spiking pattern, which adversely affects the quality of signals they can carry to the brain. To further understand the pathophysiology of retinal degeneration, and how it may lead to aberrant spiking in RGCs, we asked how loss of photoreceptors affects some of the neurotransmitter receptors in rd1 mouse. Using Western blotting, we measured the levels of several neurotransmitter receptors in adult rd1 mouse retina. We found significantly higher levels of AMPA, glycine and GABAa receptors, but lower levels of GABAc receptors in rd1 mouse than in wild-type. Since GABAa receptor is expressed in several retinal layers, we employed quantitative immunohistochemistry to measure GABAa receptor levels in specific retinal layers. We found that the levels of GABAa receptors in inner plexiform layer of wild-type and rd1 mice were similar, whereas those in outer plexiform layer and inner nuclear layer combined were higher in rd1 mouse. Specifically, we found that the number of GABAa-immunoreactive somas in the inner nuclear layer of rd1 mouse retina was significantly higher than in wild-type. These findings provide further insights into neurochemical remodeling in the inner retina of rd1 mouse, and how it might lead to oscillatory activity in RGCs.     

Human retinal development: ultrastructure of the inner retinal layers

Studies of the developing human retina from 6.5 to 18 weeks' gestational age (16–156 mm) by light and electron microscopy are concerned with the morphogenesis of neuroblast cells, plexiform layers, and inner limiting membrane. The transient layer of Chievitz is formed posteriorly by 20 mm (7 weeks), inner plexiform by 48 mm (9 weeks), outer plexiform layer by 83 mm (12 weeks), identifiable cones by 83 mm, and rods by 120 mm (15 weeks). Mitotic activity continues posteriorly until 120 mm and was seen in inner layers of the retina until 103 mm (13 weeks). Outer neuroblastic differentiation is marked by diversification from a uniform cell population to one containing at least three cell types differing in their nuclear shape, chromatin pattern, and cytoplasmic characteristics. Differentiating ganglion cells accumulate polysomes, rough endoplasmic reticulum, Golgi complexes, microtubules, and dense bodies. Müller cell bodies in ganglion and inner nuclear layers extend processes between ganglion cells, and radial fibers, containing extensive smooth endoplasmic reticulum, to the vitreal surface. Synapses appear in the inner and outer plexiform layers by 83 mm (12 weeks), and by 120 mm (15 weeks) demonstrate a variety of conventional and ribbon forms similar to those found in the adult. Synaptogenesis therefore begins considerably before the development of photoreceptor outer segments.     

Electron microscopic observation of pituitary adenylate cyclase-activating polypeptide (PACAP)-containing neurons in the rat retina

The distribution and localization of pituitary adenylate cyclase-activating polypeptide (PACAP) in the rat retina were studied by immunocytochemistry with both light and electron microscopy. PACAP-like immunoreactivity (PACAP-LI) was detected in the amacrine and horizontal cells as well as in the inner plexiform layer, the ganglion cell layer and the nerve fiber layer. PACAP-LI seemed to be concentrated predominantly in the neuronal perikarya and their processes, but not in other cells in the retina. At the ultrastructural level, PACAP-LI was visible in the plasma membranes, rough endoplasmic reticulum, and cytoplasmic matrix in the PACAP-positive neurons in the inner nuclear layer. In the inner plexiform layer, PACAP-positive amacrine cell processes made synaptic contact with immunonegative amacrine cell processes, bipolar cell processes, and ganglion cell terminals. These findings suggest that PACAP may function as a neurotransmitter and/or neuromodulator.     

IMMUNOHISTOCHEMICAL LOCALIZATION OF GABA IN CHAMELEON RETINA (CHAMALEO CHAMALEO)

We used a policlonal antiserum against GABA and demonstated GABA-immunoreactivity (GABA-IR) in several populations of amacrine cells in the inner nuclear layer (INL), and other cells in the inner plexiform layer (IPL) of the central and peripheral retina of the chameleon. Horizontal cells do not contain GABA-IR and the chameleon retina is therefore an exception among non-mammals. GABA-IR was not seen in cell bodies in the position of photoreceptor, bipolar and interplexiform cells suggesting that GABA is not involved in synaptic transmission in the outer plexiform layer of chameleon retina.     

Adrenergic neurons in teleost retina

Summary The adrenergic retinal neurons of perch and trout were studied with the fluorescence microscopical method of Falck and Hillarp. Pilot studies were also performed on pike, plaice, cod, eel, goldfish, cunner, black moor, cichlid and carp. Only minor differences were noted between the species.Adrenergic varicose terminals occur in three sublayers of the inner plexiform layer. The layer adjacent to the ganglion cells is the most elaborate. Adrenergic perikarya occur in the innermost cell rows of the inner nuclear layer, sending branches to all sublayers of the inner plexiform layer. Adrenergic perikarya also occur among the ganglion cells, sending their branches to the innermost sublayer of adrenergic fibres in the inner plexiform layer. Weakly fluorescent adrenergic fibres can be seen running through the entire depth of the inner nuclear layer. They originate from the adrenergic perikarya of the inner nuclear layer, and they end in an elaborate plexus of adrenergic terminals among the horizontal cells. Either of the horizontal cell types can be in contact with adrenergic terminals, but the middle horizontal cells have the greatest density about them, being surrounded by baskets of adrenergic terminals of presumably synaptic character. It cannot be excluded that some horizontal cells contain a catecholamine.Microspectrofluometry revealed dopamine in the perch and trout retinal neurons.The research reported in this document has been sponsored by USPHS Grant No. 06092 and by a Research Professorship from Research to Prevent Blindness, Inc. to A.M.L. and by the Swedish Medical Research Council (B69-14X-712-04C and B68-14X-2321-01).     

Adrenergic retinal neurons

Summary Adrenergic retinal neurons have been studied in cynomolgus monkeys, cats, rabbits, guinea-pigs, rats, and mice with the fluorescence technique of Falck and Hillarp. With some species variations, three adrenergic fibre layers have been observed: an outer adrenergic fibre layer (all species) at the border between the inner nuclear and inner plexiform layers, a middle adrenergic fibre layer (rabbits, guinea-pigs, rats, and mice) in the middle of the inner plexiform layer, and an inner adrenergic fibre layer (rabbits) at the border between the inner plexiform layer and the ganglion cell layer. Similarly, three kinds of adrenergic nerve cells have been found: a somewhat heterogenous group of outer adrenergic cells (all species) situated in the innermost cell rows of the inner nuclear layer, eremite cells (rabbits, guinea-pigs, rats, and mice) within the inner plexiform layer and alloganglionic cells (all species) with a position and appearance resembling some of the ordinary non-adrenergic cells of the ganglion cell layer. All the adrenergic cells are star-shaped with slender branching processes running to the different adrenergic layers.The research reported in this document has been sponsored by the Air Force Office of Scientific Research under grant AF EOAR 66-14 through the European Office of Aerospace Research (OAR), United States Air Force, by the United States Public Health Service (grant no. NB 05236-02), by the Swedish Medical Research Council (grant no. B 66-320), and by the Faculty of Medicine, University of Lund, Sweden.     

Optical coherence tomography in parkinsonian syndromes

Background/Objective

Parkinson''s disease (PD) and the atypical parkinsonian syndromes multiple system atrophy (MSA), progressive supranuclear palsy (PSP) and corticobasal syndrome (CBS) are movement disorders associated with degeneration of the central nervous system. Degeneration of the retina has not been systematically compared in these diseases.

Methods

This cross-sectional study used spectral-domain optical coherence tomography with manual segmentation to measure the peripapillar nerve fiber layer, the macular thickness, and the thickness of all retinal layers in foveal scans of 40 patients with PD, 19 with MSA, 10 with CBS, 15 with PSP, and 35 age- and sex-matched controls.

Results

The mean paramacular thickness and volume were reduced in PSP while the mean RNFL did not differ significantly between groups. In PSP patients, the complex of retinal ganglion cell- and inner plexiform layer and the outer nuclear layer was reduced. In PD, the inner nuclear layer was thicker than in controls, MSA and PSP. Using the ratio between the outer nuclear layer and the outer plexiform layer with a cut-off at 3.1 and the additional constraint that the inner nuclear layer be under 46 µm, we were able to differentiate PSP from PD in our patient sample with a sensitivity of 96% and a specificity of 70%.

Conclusion

Different parkinsonian syndromes are associated with distinct changes in retinal morphology. These findings may serve to facilitate the differential diagnosis of parkinsonian syndromes and give insight into the degenerative processes of patients with atypical parkinsonian syndromes.