GABA-like immunoreactivity in the macaque monkey retina: a light and electron microscopic study

The distribution of GABA-like immunoreactivity in the macaque monkey retina was studied by using postembedding techniques on semithin and ultrathin sections. At the light microscopic level, both inner and outer plexiform layers showed strong GABA-like immunoreactivity in the central retina. All the horizontal cells, some bipolar cells, 30-40% of amacrine cells, occasional interplexiform cells, and practically all displaced amacrine cells were labeled. In the peripheral retina (beyond 5 mm eccentricity), the outer plexiform layer and the horizontal cells were not labeled, but all other cell types showed the same labeling pattern as in the central retina. Synapses of the inner plexiform layer involving a pre- or postsynaptic GABA-labeled process were studied electron microscopically. Synapses involving a GABA-labeled presynaptic amacrine cell process made up 80% of the synapses observed. These GABA-labeled amacrine processes synapsed onto amacrine, bipolar, and ganglion cell processes as well as onto amacrine and ganglion cell bodies. Synapses involving a postsynaptic GABA-labeled process made up 20% of the synapses studied. The GABA-like immunoreactive processes were postsynaptic to bipolar cells at the dyads and to amacrine cells at conventional synapses.     

Retinal structure in the smooth dogfish Mustelus canis: electron microscopy of serially sectioned bipolar cell synaptic terminals

Portions of axons of bipolar cells in the retina of the smooth dogfish Mustelus canis were sectioned serially and examined by electron microscopy. The studied axons generally could be related to a bipolar cell sub-type identified by light microscopy. Bipolar cell axons make ribbon synapses onto amacrine processes and ganglion cell dendrites, and onto ganglion cell perikarya. Bipolar cell ribbon synaptic complexes varied as to the number of post-synaptic processes (1–3) and the orientation of the ribbon with respect to the post-synaptic membrane. Amacrine processes made numerous conventional synapses onto bipolar cell axons, but reciprocal synapses between amacrine and bipolar cells constituted only 3–25% of all synapses observed. The number of ribbon synapses per unit area of bipolar cell axon membrane differed little among bipolar cell sub-classes. However, the density of amacrine cell conventional synapses was markedly lower for thin, horizontally-oriented bipolar cell axons than for axons of other bipolar cell types. Gap junctions were noted between bipolar cell axons of the same sub-type. They are structurally similar to gap junctions between horizontal cells in Mustelus retina and to those found elsewhere in the nervous system.     

Bipolar cells specific for blue cones in the macaque retina.

A distinct subpopulation of bipolar cells in macaque monkey retina was labeled with antisera that recognize glycine-extended cholecystokinin precursors. The labeled bipolar cells were found throughout the retina and had dendrites contacting a subpopulation of cone pedicles and axons ramifying in the fifth stratum of the inner plexiform layer. Several lines of evidence indicate that the labeled bipolar cells are a single type despite some variations in their morphology. First, the density of perikarya and their diameters varied continuously as a function of eccentricity. Second, the positions of perikarya within the inner nuclear layer and the level at which the axons branched in the inner plexiform layer were constant at all eccentricities. Bipolar cells with similar morphology have been described previously as "blue cone bipolar cells" (Mariani, 1984b), but there was no direct evidence that this was the case. In this study, we show by light microscopy that labeled bipolar cells have dendrites ending exclusively upon presumptive blue cones labeled by Procion black dye. All blue cones were contacted by labeled bipolar cells, and virtually all bipolar cells contacted blue cones, the only exceptions being in regions where blue cones had been lost. Approximately 20% more labeled bipolar cells than blue cones were found at every eccentricity; thus, connections between blue cones and labeled bipolar cells were not strictly one to one. The mean number of cones presynaptic to each bipolar cell was 1.2, and the mean number of bipolar cells postsynaptic to each cone was 1.8. By an electron microscopic study of labeled bipolar cell dendrites, we determined that they became central elements of ribbon synapses in blue cones. Some of their ribbon synapses were unusual: in one type, a single, large labeled dendrite was postsynaptic to two or more ribbons, while in the other type, ribbons had two or more central elements. The presence of these invaginating contacts and the axonal terminals in the proximal inner plexiform layer suggest that the labeled bipolar cells depolarize to short-wavelength stimuli and function to relay information from blue cones to the inner plexiform layer. There were also other, unlabeled bipolar cell dendrites that received inputs from blue cones at basal junctions and triad-associated flat contacts, which suggests that there are additional types of bipolar cells conveying information from short-wavelength cones in the primate retina.     

Synaptic organization of the cone horizontal cells in the catfish retina

Horizontal cells of the vertebrate retina are known to contribute to the formation of the receptive field surrounds of photoreceptor and bipolar cells. However, few synapses have been described anatomically that might mediate these interactions. We have observed in the catfish retina that cone horizontal cell perikarya and dendrites make conventional chemical synapses onto photoreceptor terminal telodendria and onto bipolar cell dendrites, while horizontal cell axon terminals make chemical synapses onto the perikarya and processes of amacrine cells. The synapses are characterized by clusters of round vesicles aggregated close to the site of contact, as well as by electron-dense material associated with both pre- and postsynaptic membranes. The three kinds of synapses observed anatomically correspond to the synaptic pathways involving cone horizontal cells that have been suggested by the physiology of these cells.     

Morphology and distribution of catecholaminergic amacrine cells in the cone-dominated tree shrew retina.

The tree shrew (Tupaia belangeri) has a cone-dominated retina with a rod proportion of only 5%. This is in contrast to the usual mammalian pattern of rod-dominated retinae. Rod bipolar cells are present at relatively low densities in the tree shrew retina, suggesting that a reduced, but normal, rod pathway might be preserved. The present study investigated another common constituent of the rod pathway, the dopaminergic amacrine cells, and analysed their morphology and distribution by light and electron microscopy. Catecholaminergic (presumed dopaminergic) amacrine cells were labelled with an antibody against tyrosine hydroxylase (TH). Intense TH-immunoreactivity was found in perikarya and dendrites of a uniform amacrine cell population. TH-immunoreactive amacrine cell density varies across the retina from 10 cells/mm2 in the periphery to 40 cells/mm2 in more central regions (mean cell density about 25 cells/mm2). The relatively large cell bodies are located exclusively in the innermost part of the inner nuclear layer. The dendrites form a dense plexus at the border between the inner plexiform layer and the inner nuclear layer. The finer dendritic processes contain many varicosities and form characteristic dendritic "rings" like those seen in other mammals. TH-immunoreactive processes also run between cell bodies in the vitread inner nuclear layer; a few extend into the sclerad inner nuclear layer and occasionally reach the outer plexiform layer (possible interplexiform cells). A few TH-immunoreactive processes are seen in the middle of the inner plexiform layer. Electron microscopy of TH-immunoreactive processes revealed conventional synapses onto somata and processes of unlabelled amacrine cells.     

Synaptic connections of DB3 diffuse bipolar cell axons in macaque retina

In primate retinas, the dendrites of DB3 diffuse bipolar cells are known to receive inputs from cones. The goal of this study was to describe the synaptic connections of DB3 bipolar cell axons in the inner plexiform layer. DB3 bipolar cells in midperipheral retina were labeled with antibodies to calbindin, and their axons were analyzed in serial, ultrathin sections by electron microscopy. Synapses were found almost exclusively at the axonal varicosities of DB3 axon terminals. There were 2.14 synaptic ribbons per varicosity. There were 33 varicosities per DB3 cell, giving an average of 71 ribbons per axon terminal. Because there were 1.5 postsynaptic ganglion cell dendrites per DB3 axonal varicosity, we estimate that there is at least 1 synapse per varicosity onto a parasol ganglion cell dendrite. There were 3.4 input synapses from amacrine cells per axonal varicosity. Among these were feedback synapses to the DB3 bipolar cell axon varicosities, which were made by 47% of the postsynaptic amacrine cell processes. Some of the feedback synapses could be from amacrine cells immunoreactive for cholecystokinin precursor or choline acetyltransferase, because both types of amacrine cells costratify with parasol cells and are known to be presynaptic to bipolar cells. AII amacrine cells were both presynaptic and postsynaptic to DB3 axons, a finding consistent with the large rod input to parasol ganglion cells reported in physiological experiments. DB3 bipolar cell axons also made frequent contacts with neighboring DB3 axons, and gap junctions were always found at these sites.     

Distribution and spatial geometry of dopamine interplexiform cells in the retina. II. External arborizations in the adult rat and monkey

The morphology and distribution of dopaminergic interplexiform cells in adult rat and monkey retinas were analyzed to determine any correlation with the function of dopamine in the outer retinal layers. The retinas were processed as whole mounts for tyrosine hydroxylase immunohistochemistry. There was a network formed by the sclerally directed processes of interplexiform cells in the inner nuclear, outer plexiform, and outer nuclear layers running throughout the retina. Their density was higher in the superior retina than in the inferior retina of the rat and was especially high in the superior temporal quadrant. The external network in this quadrant was significantly less dense in the monkey than in the rat, as are the interplexiform cells. The somata of interplexiform and other dopaminergic cells were about the same size in both rats and monkeys. Computer-assisted reconstruction of external arborizations of individual cells showed that external processes lay very close to horizontal and photoreceptor cells and also to blood capillaries. Because they were long, thin, and highly varicose; branched at right angles; and often arose from an axon hillock, the external processes were identified as axons. Therefore, we define the dopaminergic interplexiform cells as multiaxonal neurons, with at least one outwardly directed axon that reaches the outer plexiform layer. The function of the network of external processes from the interplexiform dopaminergic cells is discussed in terms of modulating the release of dopamine to external layers.     

Immunocytochemical localization of the amino acid neurotransmitters in the chicken retina

Postembedding immunocytochemistry was used to determine the cellular localization of the amino acid neurotransmitters glutamate, aspartate, gamma-aminobutyric acid (GABA), and glycine in the avian retina. The through retinal pathway was glutamatergic, with all photoreceptors, bipolar cells, and ganglion cells being immunoreactive for glutamate. Bipolar cells displayed the highest level of glutamate immunoreactivity, with the cell bodies terminating just below the middle of the inner nuclear layer. All lateral elements, horizontal cells, amacrine cells, and interplexiform cells were immunoreactive for glycine or GABA. The GABAergic neurons consisted of two classes of horizontal cells and amacrine cells located in the lower part of the inner nuclear layer. GABA was also localized in displaced amacrine cells in the ganglion cell layer, and a population of ganglion cells that co-localize glutamate and GABA. Both the horizontal cells and GABAergic amacrine cells had high levels of glutamate immunoreactivity, which probably reflects a metabolic pool. At least two types of horizontal cells in the avian retina could be discriminated on the basis of the presence of aspartate immunoreactivity in the H2 horizontal cells. Glycine was contained in a subclass of amacrine cells, with their cell bodies located between the bipolar cells and GABAergic amacrine cells, two subclasses of bipolar cells, displaced amacrine cells in the ganglion cell layer, and ganglion cells that colocalize glutamate and glycine. Glycinergic amacrine cells had low levels of glutamate. We have also identified a new class of glycinergic interplexiform cell, with its stellate cell body located in the middle of the inner nuclear layer among the cell bodies of bipolar cells. Neurochemical signatures obtained by analyzing data from serial sections allowed the classification of subclasses of horizontal cells, bipolar cells, amacrine cells, and ganglion cells. © 1993 Wiley-Liss, Inc.     

Serotoninergic neurons in the retina of Xenopus laevis: selective staining, identification, development, and content

Uptake of 3H-serotonin followed by autoradiography, and uptake of the serotonin analog 5,7-dihydroxytryptamine (5,7-DHT), with subsequent staining, were each used to define a unique set of neurons in the retina of the African clawed frog, Xenopus laevis. Both techniques demonstrated the same population of neurons, on the basis of perikaryal size, shape, and position within the retina. Two classes of amacrine cells accumulated 5,7-DHT at the proximal (vitread) margin of the inner nuclear layer; the two classes were distinguished by the size of their perikarya. Two similar populations of cells, observed in the ganglion cell layer with lower frequency, may represent "displaced" counterparts of these two amacrine cell types. A class of bipolar cells whose perikarya were located in middle-to-distal regions of the inner nuclear layer also accumulated 5,7-DHT and 3H-serotonin. Processes of these cells contributed to a dense plexus of fine fibers that appeared evenly distributed throughout the inner plexiform layer. 3H-Serotonin-accumulating cells first appeared in the developing retina at stage 35/36, a time immediately after retinal stratification but before elaboration of either plexiform layer. Electron microscopic analysis permitted an identification of 3H-serotonin-accumulating terminals in the inner plexiform layer. Serotonin-labeled terminals containing conventional contacts, suggestive of amacrine cells, were presynaptic to unidentified processes and postsynaptic to bipolar cells. Labeled terminals containing ribbon contacts, indicative of bipolar cells, were postsynaptic to amacrine cells. The amount of serotonin contained in isolated retinas was 15 pmol/mg protein as measured by HPLC with electrochemical detection. We attempted to stimulate the release of accumulated 3H-serotonin from mature retinas by increasing the K+-concentration in the bathing medium. Although preloaded glycine is readily released from 14C-glycine-accumulating neurons, from the same retinas there was no calcium-dependent, K+-stimulated release of 3H-serotonin. This finding suggests that serotonin and glycine are processed differently by retinal neurons, the consequence of which results in differing responses to 40 mM K+.     

Uptake of 3H-glycine in the outer plexiform layer of the retina of the toad, Bufo marinus

The uptake of 3H-glycine in the retina of the toad, Bufo marinus, was investigated by light and electron microscopical autoradiography. Uptake of 3H-glycine was very prominent in large cell bodies in the inner nuclear layer as well as in discrete clusters in both the outer plexiform layer (OPL) and the inner plexiform layer. This pattern in similar to that described for 3H-glycine-accumulating putative interplexiform cells in goldfish, frog, and Xenopus retinas. Electron microscopical autoradiography of the OPL revealed large, grain-containing varicosities which had electron-lucent cytoplasm and contained both small, agranular and large, dense-core vesicles. The varicosities made extensive en passant and spine synapses in the OPL. Definitive identification of their postsynaptic targets was not achieved. However, autoradiographic analysis with 3H-GABA uptake as well as electrophysiological evidence suggests that axons but not cell bodies or dendrites of 3H-GABA-accumulating horizontal cells (H1 cells) are postsynaptic targets of the varicosities. The presence of dense-core vesicles in the varicosities suggested co-occurrence of glycine and a biogenic amine or neuropeptide. The indirect immunofluorescence technique was used to determine whether any such substances were present in the OPL of the toad retina. However, no specific labeling was found in the OPL for any of 19 substances tested. The extensive synaptic output provided by glycine-accumulating varicosities in the toad OPL may indicate an important role of glycine in the synaptic function of the distal toad retina. We suggest that these varicosities derive from a presumably glycinergic interplexiform cell.     

Fluorescence and electron microscopical observations on the amine-accumulating neurons of the cebus monkey retina

The organization of the Cebus monkey regina was analysed after the intraocular injection of 5,6-dihydroxytryptamine. This amine was taken up not only by the previously known dopaminergic neurons, but also by a set of indoleamine-accumulating neurons, whose processes are confined to the inner plexiform layer. The synaptic contacts of the dopaminergic neurons were analysed in the electron microscope after the processes of the indoleamine-accumulating neurons were destroyed by the intravitreal injection of the neurotoxic indoleamine, 5,7-dihydroxytryptamine. The subsequent injection of 5,6-dihydroxytryptamine induces certain changes in the dopaminergic neurons which accumulate the substance: electron-dense cores appear in the synaptic vesicles, and increased electron-density of mitochodrial and cellular membranes is often observed. The dopaminergic neurons were found to be presynaptic to amacrine cell perikarya and processes in the inner plexiform layer. In the outer plexiform layer they were presynaptic to both bipolar and horizontal cells, but they did not contact photoreceptors. The dopaminergic neurons received synapses only in the inner plexiform layer, from amacrine cell processes. It is inferred that in Cebus most dopaminergic neurons belong to a special class of retinal neuron, the interplexiform cells, which appear to transmit information centrifugally within the retina, from the inner to the outer plexiform layers. There are considerable similarities between the synaptology of the dopaminergic interplexiform neurons in the Cebus monkey and the goldfish retina, and the function of interplexiform neurons may therefore be similar in these two species.     

Somatostatin-like immunoreactivity and glycine high-affinity uptake colocalize to an interplexiform cell of the Xenopus laevis retina

Antibodies directed against somatostatin have been used to label a population of interplexiform cells (IPCs) in the Xenopus laevis retina. These cells have spherical soma which lie in the inner nuclear layer (INL), adjacent to or one cell distal to the inner plexiform layer (IPL). Processes from these cells project throughout the IPL, with a fairly dense accumulation of labeled dendrites in the upper two-fifths of the IPL and a dense, narrow band of labeled dendrites adjacent to the ganglion cell layer. These cells also have finer processes, originating at the cell body, that traverse the INL and ramify in the outer plexiform layer (OPL). Double label experiments show that all of the cells that contain somatostatin-like immunoreactivity (SOM-LI) in the INL are also labeled by high-affinity uptake with 3H-glycine. Immunocytochemistry of retinal whole mounts shows that these cells are evenly distributed across the retina at a density of 542 +/- 65 cells/mm2. On the basis of the colocalization experiments and the morphological homogeneity of these cells, we suggest that they represent a single cell type. Interplexiform cell processes were further characterized by electron microscopy after immunocytochemistry or 3H-glycine autoradiography. In the IPL, IPC processes are seen to be postsynaptic at both ribbon and conventional synapses. This input is found almost entirely in the distal two-fifths of the IPL. Interplexiform cell processes are presynaptic to unlabeled processes in both the distal and proximal IPL. In the OPL, labeled processes are found near or contiguous with photoreceptor bases, and are often presynaptic to small-diameter processes. The postsynaptic processes have been identified as bipolar cell dendrites in six cases. Interplexiform cell processes may also contact horizontal cell processes in the OPL.     

Localization of putative GABAergic neurons in the larval tiger salamander retina by immunocytochemical and autoradiographic methods

Putative GABAergic neurons in the larval tiger salamander retina were localized by a comparative analysis of glutamate decarboxylase immunoreactivity (GAD-IR), GABA-like immunoreactivity (GABA-IR), and high-affinity 3H-GABA uptake at the light microscopical level. Preliminary data showed that all GAD-IR neurons were double labeled for GABA-IR. However, because the weak somatic labeling with GAD-IR, we could not determine if the converse were true. Neurons commonly labeled with GABA-IR and 3H-GABA uptake include horizontal cells, type I (outer) and type II (inner) bipolar cells, type I (inner) and type II (outer) amacrine cells, and cell bodies in the ganglion cell layer (GCL). In addition, interplexiform cells were identified with GABA-IR. The presence of GABA-IR ganglion cells was indicated by GABA-IR fibers in the optic fiber layer and optic nerve as well as by a GABA-IR cell in the GCL that included a labeled axon. The percentage of labeled somas in the inner nuclear layer (INL) compared to all cells in each layer was similar for the two methods: 30% in INL 1 (outer layer of somas), 15% in INL 2 (middle layer), 43-52% in INL 3 (inner layer), and about 21-26% in the GCL. Labeled processes were found in three bands in the inner plexiform layer, with the densest band located in the most proximal part. Postembedding labeling of 1-micron Durcupan resin sections for GABA-IR showed the same general pattern as obtained with 10-microns cryostat sections, with additional staining, however, of type II (inner) bipolar cell Landolt's clubs. Extensive colocalization of labeling was indicated, and we conclude that GABA-IR can serve as a valid and reliable marker for GABA-containing neurons in this retina and suggest that GABA serves as a transmitter for horizontal cells, several types of amacrine cell, a type of interplexiform cell, and perhaps a small percentage of type I and type II bipolar cells and ganglion cells.     

Observations on the synaptic organization of the retina of the albino rat: a light and electron microscopic study

An electron microscopic study of the retina of the albino rat, with particular emphasis on the synaptic organization of the inner and outer plexiform layers, has been correlated with specimens impregnated with a modified Golgi technique. The central element of the photoreceptor “triad” in the outer plexiform layer is a bipolar cell dendrite. Two types of synaptic contacts were observed in the inner plexiform layer, the “dyad” ribbon synapse and the conventional synapse. The postsynaptic elements of the “dyad” consisted of an amacrine process and a ganglion cell dendrite. Conventional synapses were made by amacrine processes which were usually presynaptic to bipolar terminals. Reciprocal synapses between processes making ribbon synapses and those making conventional synapses were seen. Golgi technique revealed the presence of two types of bipolar cells, three types of amacrine cells, and one type each of horizontal and ganglion cell. These findings are discussed in relation to reported receptive field organization.     

GABA-like immunoreactivity in the cat retina: electron microscopy

The synaptic organization of the cat retina was studied with antibodies against the GABA-GA (glutaraldehyde)-BSA (bovine serum albumin) complex. The postembedding technique combined with immunogold labelling ensured ultrastructural preservation and made identification of synapses possible. The most common putative GABA-ergic synapses in the inner plexiform layer were amacrine-to-bipolar-cell synapses followed by amacrine-to-ganglion-cell and amacrine-to-amacrine-cell synapses. GABA-immunoreactive amacrine cells received most of their synaptic input from bipolar cells followed by other amacrine cells. Synapses between two labelled amacrine cells were common. Rod bipolar cells were the predominant input source and also the preferred output target of GABA-labelled amacrine cells. OFF- and ON-ganglion cells received putative GABA-ergic synapses at their dendrites in laminas a and b, respectively, and also at their somata. In the outer plexiform layer, synapses of interplexiform cells onto bipolar cell dendrites expressed GABA-like immunoreactivity. In both the cone pedicles and the rod spherules, GABA-like immunoreactivity was observed in horizontal cell processes.     

An ultrastructural study of interplexiform cell synapses in the human retina

Using serial sections and electron microscopy, we have found several morphological types of synapses within the outer plexiform layer (OPL) of the human retina. The most conspicuous of these is described in this paper. They have a unique morphology and form synapses with rod and cone bipolar cells in the OPL and onto bipolar and amacrine cell bodies in the inner nuclear layer (INL). Because they occur in processes that extend across the INL, we believe these synapses are made by interplexiform cells (IPCs). These same processes also contact cone pedicles with specialized cell junctions like those made between cones and flat bipolars. These junctions have densification of both cell membranes and widening of the extracellular cleft, but no accumulation of synaptic vesicles. Similar-appearing processes in the inner plexiform layer are thought to belong to IPCs but their contacts were less completely identified. Possible circuitry for these IPCs is described and the possibility that there are different classes of IPCs in the human retina is discussed. The OPL forms in the posterior retina during the tenth fetal week. Our observations suggest that different types of synapses including those of the IPCs are present in this layer from the time of its first appearance.     

Tyrosine hydroxylase immunoreactivity in the rhesus monkey retina reveals synapses from bipolar cells to dopaminergic amacrine cells

The synaptic organization of dopamine-containing amacrine cells in the rhesus monkey retina was studied using immunohistochemistry of tyrosine hydroxylase (TH), the rate-limiting enzyme in the catecholamine synthetic pathway. Cell bodies of the TH-containing neurons were primarily in the innermost tier of the inner nuclear layer. Their synaptic processes, confined to the outermost stratum of the inner plexiform layer, contained mostly small, clear vesicles and were presynaptic to unlabeled amacrine cell processes and cell bodies at junctions that were symmetrical. Synapses onto the TH-immunoreactive neurons were from bipolar cell axon terminals, nonimmunoreactive amacrine cell processes, and other TH-containing amacrine cells in a decreasing order of predominance. The bipolar cells were presynaptic to the TH-containing neuronal processes at ribbon synapses. The size, structure, and position of the bipolar cell axon terminals, which, like the TH-reactive processes, were narrowly confined to the outermost stratum of the inner plexiform layer, indicate that they are recently described giant bistratified bipolar cells. The identification of this bipolar cell input now provides evidence for a pathway from the outer plexiform layer to dopaminergic amacrine cells in the inner plexiform layer via a type of cone bipolar cell.     

Synaptogenesis in the retina of the cat

We have studied the development of synapses in the retina of the cat from E(embryonic day)21 to adulthood. The inner plexiform layer (IPL) could be distinguished by E36, but at this age no synapses had formed, although compact processes had formed in the IPL and membrane specialisations had developed in adjacent processes. Conventional synapses form in the IPL from E45 and become increasingly numerous and differentiated over subsequent weeks. Extracellular space and cellular debris were prominent during the formation of these synapses. The conventional synapses appear to form principally between amacrine cells until E56, when ganglion cell dendrites could be identified as postsynaptic processes. Ribbon synapses characteristic of bipolar cells were identified around birth, suggesting that bipolar cells do not form synapses until that age. The outer plexiform layer (OPL) could be distinguished in central retina at E56. Extracellular space, debris of degenerating cells and mounds of agranular vesicles were prominent at this age but synapses were not observed until E59, when cone pedicles formed ribbon synapses onto horizontal cell processes. The first synapses clearly formed by spherules, also onto horizontal cells, were seen at E62. The central process of the postsynaptic triad, considered to be the dendrite of a bipolar cell, was first observed in both cone pedicles and rod spherules around birth, again suggesting that bipolar cells do not enter into synaptic arrangements until that age. Synaptogenesis in the OPL shows a strong centro-peripheral gradient; its initial stages were observed centrally in the late E50's but synapse formation was not complete in the retinal periphery until P(postnatal day)7 or later. We could not detect a centro-peripheral gradient in the formation of conventional synapses in the IPL, but the formation of ribbon synapses in this layer began centrally at birth and in the mid-periphery at P5. In summary, the first synapses to form in the retina are those which spread information laterally within the plexiform layers, between amacrine cells and from receptor to horizontal cells. The cells which carry information centrally, in particular bipolar cells, enter into synaptic arrangements considerably later. Further, retinal cells seem to form synapses in a distinct sequence: first amacrines, then receptors and lastly bipolar cells.     

Tyrosine hydroxylase-immunoreactive elements in the distal retina of Bufo marinus: a light and electron microscopic study.

Tyrosine hydroxylase-immunoreactive elements in the distal retina of Bufo marinus were investigated using light and electron microscopic immunocytochemistry. At the light microscopic level, immunoreactive somas were seen in the proximal part of the inner nuclear layer, and immunoreactive processes projected both to the inner and outer plexiform layers. In some instances stained axon-like processes traveled from the inner plexiform layer, across the inner nuclear layer to the distal retina. Immunolabeled elements formed basket-like structures around the photoreceptor inner segments. At the ultrastructural level immunostained fibers were observed in close contact with the necks, lateral walls, bases and the outer surfaces of rod outer segments. Synaptic specializations were neither observed at rod contacts nor at other possible contact sites such as bipolar dendrites and horizontal cell somata and processes in the outer plexiform layer. In contrast, synaptic specializations between immunolabeled profiles and amacrine, bipolar and ganglion cells were regularly present in the inner plexiform layer. These findings suggest that a population of dopaminergic interplexiform cells is present in the Bufo retina and sends axon-like processes towards the distal retina. It is assumed that dopamine is probably released non-synaptically from the immunolabeled terminals in the distal retina influencing rods directly, by which the quality of photopic vision is enhanced in the anuran retina.     

Glycinergic contacts in the outer plexiform layer of the Xenopus laevis retina characterized by antibodies to glycine, GABA and glycine receptors

Electrophysiological experiments have predicted a direct synaptic input from glycinergic interplexiform cells (IPCs) to GABAergic horizontal cells in the Xenopus retina. However, previous ultrastructural studies failed to demonstrate this input. Here, we used three immunocytochemical approaches to investigate this issue. First, double-label postembedding immunocytochemistry with GABA- and glycine-like immunoreactivity (GABA-LI and glycine-LI) was used to study possible interactions of the glycinergic IPC with GABAergic horizontal cells. Processes postsynaptic to glycine-LI IPC terminals in the outer plexiform layer (OPL) fell into two groups, small microtubule-filled processes and larger electron-lucent processes with sparse microtubules and occasional mitochondria. In no case did we find glycine-LI synapses onto GABA-LI cells or processes. Second, pre-embedding immunocytochemistry was used to label GABA-LI cells and processes in the OPL. GABA-LI was sparse in horizontal cell axons and more intense in horizontal cell somas and in small processes. In agreement with our first set of experiments, GABA-LI profiles did not receive input from conventional synapses. Third, we localized glycine-receptor-like immunoreactivity (GlyR-LI) to several types of apparent synapses in the OPL. As expected, it was found at IPC synapses. Unexpectedly, GlyR-LI was also subsynaptic at photoreceptor synapses onto second order neurons, both at ribbon and basal junction type synapses. At least some of the GlyR-LI photoreceptor synapses were from cones. Also, GlyR-LI was apposed to photoreceptors and to unidentified small diameter processes, where no other indication of synaptic input was evident. Because glycine-LI is not found in photoreceptors, we suggest that glycine receptors at photoreceptor synapses are stimulated by glycine that diffuses from other sites, possibly from IPCs. This interpretation is consistent with available physiological studies of glycinergic effects in this retina.