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).     

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.     

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.     

Aminergic and Indoleamine Accumulating Neurons in the Retina of the River Lamprey (Lampetra fluviatilis)

Tissues were processed for fluorescence microscopy of biogenic amines according to the method of Falck and Hillarp. Normal animals, and animals injected with α-methylnoradrenaline or 5,6-dihydroxytryptamine were used. Catecholamine containing neurons (junctional cells) occur in the innermost rows of cell bodies of the inner nuclear layer (INL) and close to the vitreous surface. Catecholamine containing fibers occur in three layers: (1) an outer layer around the innermost perikarya of the INL, which is a condition not found in retinas of gnathostome chordates; (2) a middle layer within the outer third of the inner synaptic layer (ISL), separated from the outer layer by ganglion cell axons; (3) a sparse inner layer within the innermost third of the ISL. A few catecholamine containing fibers were seen to extend from the innermost region of the INL to the outer synaptic layer. The position of the junctional cells in the lamprey corresponds to that in gnathostome chordates, but whereas all catecholamine containing fiber layers in gnathostomes are located sclerally to the optic fiber layer and within the ISL, the middle and the inner fiber layers in the lamprey occur vitreally to the optic fiber layer. Indoleamine accumulating neurons occur in the innermost row of perikarya of the INL and close to the vitreous surface. Those of the INL send fine, varicose branches to the ISL forming a network which is somewhat denser at the inner and outer borders of the ISL than in its middle. The indoleamine accumulating terminals do not ramify within the INL in contrast to the catecholamine containing terminals.     

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.     

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.     

Displaced horizontal cells in the chick retina

The retina of the chick contains retinal cells of a morphology very similar to that of the horizontal cells, but the perikarya, axons, and axon terminals lie in the inner plexiform layer. The discovery of this neuronal ectopia appears to support the idea that some horizontal and amacrine cells derive from a common, freely migrating cell.     

Histochemical studies on catecholaminergic cells in the carp retina

Histochemical studies on catecholaminergic cells were conducted with the carp (Cyprinus carpio) retina. Catecholamine (CA)-containing cell bodies appear sparsely distributed among amacrine cells in the innermost cellular row of the inner nuclear layer (INL) and occasionally in the outer half part of the inner plexiform layer (IPL); only exceptionally are they found among ganglion cells. The fluorescent cells interspersed with the amacrine cells and in the IPL send their fiber processes toward both the outer plexiform layer (OPL) and the IPL; the fine fibers form dense networks in the INL and IPL. Pretreatment of the fish with intramuscular injection of reserpine (20 hr prior to enucleation) completely depleted CA from the retina. The fluorescence of catecholaminergic cells was enhanced, and the number of fluorescent cells visible was increased, by intravitreous injection ofl-DOPA, DA, and NA (3 hr prior to enucleation). A combination of pretreatment with intramuscular reserpine and intravitreous NA was particularly effective. These results indicate that catecholamines may play an important role in the modulation of the membrane potential of horizontal cells.     

Synaptic relationships in the plexiform layers of carp retina

Summary The synaptic contacts made by carp retinal neurons were studied with electron microscopic techniques. Three kinds of contacts are described: (1) a conventional synapse in which an accumulation of agranular vesicles is found on the presynaptic side along with membrane densification of both pre- and postsynaptic elements; (2) a ribbon synapse in which a presynaptic ribbon surrounded by a halo of agranular vesicles faces two postsynaptic elements; and (3) close apposition of plasma membranes without any vesicle accumulation or membrane densification.In the external plexiform layer, conventional synapses between horizontal cells are described. Horizontal cells possess dense-core vesicles about 1,000 Å in diameter. Membranes of adjacent horizontal cells of the same type (external, intermediate or internal) are found closely apposed over broad regions.In the inner plexiform layer ribbon synapses occur only in bipolar cell terminals. The postsynaptic elements opposite the ribbon may be two amacrine processes or one amacrine process and one ganglion cell dendrite. Amacrine processes make conventional synaptic contacts onto bipolar terminals, other amacrine processes, amacrine cell bodies, ganglion cell dendrites and bodies. Amacrine cells possess dense-core vesicles. Ganglion cells are never presynaptic elements. Serial synapses between amacrine processes and reciprocal synapses between amacrine processes and bipolar terminals are described. The inner plexiform layer contains a large number of myelinated fibers which terminate near the layer of amacrine cells.This work was supported by an N.I.H. grant NB 05404-05 and a Fight for Sight grant G-396 to P.W. and N.I.H. grant NB 05336 to J.E.D. The authors wish to thank Mrs. P. Sheppard and Miss B. Hecker for able technical assistance. P.W. is grateful to Dr. G. K. Smelser, Department of Ophthalmology, Columbia University, for the use of his electron microscope facilities.     

Indoleamine-accumulating neurons in the retina of rabbit,cat and goldfish

Summary Special neurons accumulating indoleamines have been detected in the retina of rabbit, cat and goldfish. They have their perikarya in the inner-most cell row of the inner nuclear layer, among the amacrine cells, and send their processes to various parts of the inner plexiform layer. The distribution of the processes is different in the different animals investigated. The neurons do not correspond to the previously known dopaminergic retinal neurons, which have a different distribution of their terminals and which can be demonstrated with a specially developed technique, simultaneously with the indoleamine-accumulating neurons.This work was supported by grants from the Swedish Medical Research Council (project 04X-2321), the Medical Faculty of the University of Lund, the Åke Wibergs Stiftelse and the Magn. Bergvalls Stiftelse     

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.     

Electron microscopy of the indoleamine-accumulating neurons in the retina of the rabbit

Summary The recently discovered indoleamine-accumulating retinal neurons were studied electron microscopically after destruction of the dopaminergic retinal neurons and subsequent labeling with 5,6-dihydroxytryptamine. These observations confirm earlier fluorescence microscopical studies on the distribution of the indoleamine-accumulating neurons in the rabbit retina. Their perikarya are known to be located in the inner nuclear layer (INL) among the amacrine cell bodies. Their processes are found only in the inner plexiform layer (IPL), most of them in the innermost third part of that layer. The indoleamine-accumulating terminals are pre- and postsynaptic to bipolar neurons in the innermost sublayer of the IPL. Reciprocal synapses are probably the rule. The synaptic vesicles of indoleamine-accumulating synapses onto bipolar cells are arranged in globular clusters around a central electron dense, round body. A number of synapses formed by unlabeled amacrine neurons with postsynaptic indoleamine-accumulating elements were also detected. These synapses were mainly found in the outermost third of the IPL. Synaptic contacts between presynaptic indoleamine-accumulating neurons and postsynaptic unlabeled processes of amacrine cells are very rare.     

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.     

Adrenergic Nerves in the Avian Eye and Ciliary Ganglion

Summary The distribution of adrenergic fibres to the eye and to the ciliary ganglion was studied in pigeons, chicken and ducks with the aid of the sensitive and highly specific fluorescence method of Falck and Hillarp. In some animals the intensity of the fluorescence was increased by treating the animals with Nialamide and 1-DOPA. The cornea contained no adrenergic fibres except at the limbus, where a plexus of adrenergic varicose fibres was seen, partly associated with vessels. In the chamber angle, adrenergic varicose fibres were common in the loose connective tissue covering the canal of Schlemm. The canal of Schlemm was supplied by only few adrenergic fibres, but such fibres appeared along the intrascleral aqueous drainage vessels. In the iris, adrenergic varicose fibres appeared immediately in front of the posterior layer of pigment cells, strongly indicating the presence of a dilator homologous with that seen in mammals. The frontal third of the stroma contained several adrenergic varicose fibres, many of which seemed to lack association with any vessel. Varicose adrenergic fibres were also sparsely seen in the striated muscle of the iris. The ciliary processes contained many adrenergic varicose fibres, at least part of which seemed to be associated with the ciliary epithelium. The striated muscles of the ciliary body contained adrenergic varicose fibres along the vessels only. The retina contained adrenergic varicose fibres in three layers in the inner plexiform layer. Adrenergic ganglion cells of two sizes were detected in the inner nuclear layer. The retinal vessels had no adrenergic nerve fibres. The pecten was also devoid of adrenergic nerve fibres, except along the vessels close to the papilla. The optic nerve contained adrenergic varicose nerve fibres along vessels only. In the ciliary ganglion, varicose adrenergic fibres appeared at the small ganglion cells, often forming baskets of synaptic character.Acknowledgements. The work has been supported by the United States Public Health Service (grant NB 06701-01), by the Swedish Medical Research Council (project B 67-12 X-712-02 A) and by the Faculty of Medicine, University of Lund, Sweden.     

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.     

Microscopic investigation of the comparative morphology of the retina

Morphological differences in the architectonics (the relations and composition of the layers and sublayers) of the retina are described in various vertebrates: pike, frog, and cat. These differences apply to both cellular and plexiform layers. The differences are particularly marked in the composition of the sublayers of the inner nuclear layer. In the frog the greatest degree of subdivision into layers of processes of the ganglion and amacrine cells is observed to correspond to the particularly complex differentiation of the inner plexiform layer of the retina (about 10 sublayers). In all the animals studied the ganglion cells can be divided into two principal types: symmetrical and asymmetrical, with many varieties. Asymmetrical amacrine cells are found in the pike and frog retina. The presence of vertical processes branching in the outer plexiform layer is confirmed for amacrine cells in the cat retina. The structural features of the retina are discussed in connection with physiological findings.     

Ocular adrenergic neurons of the flying fox,Pteropus giganteus brünn. (Megachiroptera)

Summary The distribution of adrenergic nerves in the eyes of the large fruit-bat (flying fox) Pteropus giganteus Brünn. was investigated with the histofluorographic method of Falck and Hillarp. The general pattern conforms to that seen in most mammalian eyes. The most notable observation was in the chamber angle, where the meshwork covering the outflow channels receives numerous adrenergic terminals, making possible a direct adrenergic nervous influence on the outflow of aqueous humour. As in other mammals, adrenergic terminals are noted in the cornea, in both iris muscles, and in association with the ciliary epithelium. In the normal retina, adrenergic neurons occur mainly at the border between the inner nuclear and inner plexiform layers. After the injection of -methylnoradrenaline, additional neurons become fluorescent. We do not know the true transmitter of these additional neurons.This work was supported by grants from the Swedish Medical Research Council (projects O4X-2321 and O4X712) and the Faculty of Medicine, University of Lund.     

Differential expression of syntaxin-1 and synaptophysin in the developing and adult human retina

Synaptophysin and syntaxin-1 are membrane proteins that associate with synaptic vesicles and presynaptic active zones at nerve endings, respectively. The former is known to be a good marker of synaptogenesis; this aspect, however, is not clear with syntaxin-1. In this study, the expression of both proteins was examined in the developing human retina and compared with their distribution in postnatal to adult retinas, by immunohistochemistry. In the inner plexiform layer, both were expressed simultaneously at 11–12 weeks of gestation, when synaptogenesis reportedly begins in the central retina. In the outer plexiform layer, however, the immunoreactivities were prominent by 16 weeks of gestation. Their expression in both plexiform layers followed a centre-to-periphery gradient. The immunoreactivities for both proteins were found in the immature photoreceptor, amacrine and ganglion cells; however, synaptophysin was differentially localized in bipolar cells and their axons, and syntaxin was present in some horizontal cells. In postnatal-to-adult retinas, synaptophysin immunoreactivity was prominent in photoreceptor terminals lying in the outer plexiform layer; on the contrary, syntaxin-1 was present in a thin immunoreactive band in this layer. In the inner plexiform layer, however, both were homogeneously distributed. Our study suggests that (i) syntaxin-1 appears in parallel with synapse formation; (ii) synaptogenesis in the human retina might follow a centre-to-periphery gradient; (iii) syntaxin-1 is likely to be absent from ribbon synapses of the outer plexiform layer, but may occur at presynaptic terminals of photoreceptor and horizontal cells, as is apparent from its localization in these cells, which is hitherto unreported for any vertebrate retina.     

Development of the ocular adrenergic nerve supply in man and guinea-pig

Summary The development of adrenergic nerves to the anterior eye segment was studied in human and guinea-pig embryos. Adrenergic terminals had already appeared in the earliest human embryos available (4–6 cm). They first appeared mainly in nerve trunks in the primitive chorioid, especially in the region of the developing ciliary body. Adrenergic nerves then grow into different structures of the eye as these develop, but typical terminals in contact with effector cells appeared late during the development, about the 25–30 cm stage. No adrenergic nerves were observed in the chamber angle. Corneal adrenergic nerves (also intraepithelial terminals) appeared much more frequently in embryos than in adults. No adrenergic neurons were observed in the retina. In the guinea-pig, the first adrenergic fibres were observed at about gestation day 35. The general principle of the development was very similar to that of the humans. At gestation day 45 to 50, the supply of adrenergic fibres was essentially that of the adult animal, except that the corneal adrenergic fibres were increasing until just before birth and that the adrenergic terminals of the chamber angle appeared shortly before term.This work was supported by grants from the Association for the Aid of Crippled Children, H. Hiertas Stiftelse, and the Swedish Medical Research Council (Project no. B71-14X-2321-05B).