Connections of indoleamine-accumulating cells in the rabbit retina

To study the connections of the neurons of the rabbit retina that accumulate indoleamines, we injected 5,7-dihydroxytryptamine into the vitreous body. It accumulated within a subset of amacrine cells and could be visualized there by aldehyde-induced fluorescence. The fluorescent labeling was photo-converted to an insoluble, osmiophilic product by irradiation in the presence of diaminobenzidine, and the tissue was examined by electron microscopy. Preservation of the structure of the tissue after photoconversion was satisfactory and the dendrites of the indoleamine-accumulating cells could easily be identified. They form a dense plexus near the junction of the inner plexiform and ganglion cell layers, where they exhibit large synaptic endings that occupy a substantial fraction of the surface of rod bipolar terminals. The dendrites of the indoleamine-accumulating cells receive input from rod bipolars at dyad synapses, where the other postsynaptic partner is a dendrite of a narrow-field, bistratified amacrine cell; in addition, they receive amacrine cell input throughout the inner plexiform layer. The only outputs we observed are reciprocal synapses onto the rod bipolar endings. Thus, these amacrine cells appear to exert an important effect on the transmission of scotopic information through the retina.     

Electron microscopical observations on the indoleamine-accumulating neurons and their synaptic connections in the retina of the cat

The distribution of indoleamine-accumulating amacrine cells and their synaptic connections in the retina of the cat were analyzed in the fluorescence, phase-contrast, and electron microscopes. The findings were compared to recently characterized morphological subclasses of amacrine cells. The indoleamine-accumulating neurons were visualized after labeling with an exogenous indoleamine, 5, 6-dihydroxytryptamine. The intravitreal injection of the labeling drug was preceded by treatment with the neurotoxic dopamine-analogue, 6-hydroxydopamine, in order to destroy the otherwise interfering dopaminergic processes. The analysis in the fluorescence and phase-contrast microscopes confirmed earlier reports that the indoleamine-accumulating cell bodies and processes have a distribution consistent with that of amacrine cells. A stratified branching pattern of the indoleamine-accumulating processes in the outer half of the inner plexiform layer was discovered. In the inner half of that layer the branching pattern is diffuse. In the electron microscope the indoleamine-accumulating neurons were seen to have synapses of the conventional type. Their main synaptic contacts are reciprocal synapses with rod bipolar terminals in sublamina b of the inner plexiform layer. They also have synapses with flat cone bipolar terminals in sublamina a, and occasionally with amacrine cells and ganglion cells throughout the inner plexiform layer. Synapses with invaginating cone bipolar terminals, in sublamina b, appear to be rare. The synaptic arrangement with reciprocal synapses with rod bipolar terminals is similar to that of the recently reported AI amacrine cells. It is also similar to that of the indoleamine-accumulating neurons in the retinae of other mammals investigated earlier.     

Synaptic connections of rod bipolar cells in the inner plexiform layer of the rabbit retina

We have reconstructed from electron micrographs of a continuous series of thin sections the synaptic connections of the axonal arborizations of all the rod bipolar cells contained in a small region of the retina of the rabbit. We observed that all rod bipolars share the same pattern of connectivity and are probably functionally equivalent. As a rule, they do not contact ganglion cells. Their prevalent synaptic output is on narrow-field, bistratified, and indoleamine-accumulating amacrine cells. Their dominant inputs are the reciprocal synapses from the indoleamine-accumulating amacrines, but they also receive a sizable number of synaptic contacts from other, non-reciprocal, amacrine cells. The lateral spread of scotopic signals at the synapse between rod bipolars and narrow-field, bistratified amacrines is small. Finally, in the rabbit, as in the cat, a narrow-field, bistratified amacrine is inserted in series along the rod pathway.     

Synaptic connections of the narrow-field, bistratified rod amacrine cell (AII) in the rabbit retina.

The synaptic connections of the narrow-field, bistratified rod amacrine cell (AII) in the inner plexiform layer (IPL) of the rabbit retina were reconstructed from electron micrographs of continuous series of thin sections. The AII amacrine cell receives a large synaptic input from the axonal endings of rod bipolar cells in the most vitreal region of the IPL (sublamina b, S5) and a smaller input from axonal endings of cone bipolar cells in the scleral region of the IPL (sublamina a, S1-S2). Amacrine input, localized at multiple levels in the IPL, equals the total number of synapses received from bipolar cells. The axonal endings of cone bipolar cells represent the major target for the chemical output of the AII amacrine cell: these synapses are established by the lobular appendages in sublamina a (S1-S2). Ganglion cell dendrites represent only 4% of the output of the AII amacrine and most of them are also postsynaptic to the cone bipolars which receive AII input. The AII amacrine is not presynaptic to other amacrine cells. Finally, the AII amacrine makes gap junctions with the axonal arborizations of cone bipolars that stratify in sublamina b (S3-S4) as well as with other AII amacrine cells in S5. Therefore, in the rabbit retina 1) the rod pathway consists of five neurons arranged in series: rod-->rod bipolar-->AII amacrine-->cone bipolar-->ganglion cell; 2) it seems unlikely that a class of ganglion cells exists that is exclusively devoted to scotopic functions. In ventral, midperipheral retina, about nine rod bipolar cells converge onto a single AII amacrine, but one of them establishes a much higher proportion of synaptic contacts than the rest. Conversely, each rod bipolar cell diverges onto four AII amacrine cells, but one of them receives the largest fraction of synapses. Thus, within the pattern of convergence and divergence suggested by population studies, preferential synaptic pathways are established.     

Indoleamine-accumulating amacrine cells are presynaptic to rod bipolar cells through GABA(C) receptors.

gamma-Aminobutyric acid (GABA), is a main source of inhibitory modulation of the rod pathway in the mammalian retina. The authors previously showed that rod bipolar cells express at least three types of ionotropic GABA receptors. Here, the authors sought to determine which neurons are the presynaptic partners at these synapses in the rabbit retina. Indoleamine-accumulating amacrine cells (IACs) were immunolabeled with an antiserum against serotonin (5HT) in vertical sections and wholemounts of rabbit retinae that had been preloaded with 5HT. The tissue was double labeled for the rho subunits of the GABA(C) receptor or the alpha3 subunit of the GABA(A) receptor. Punctate immunofluorescence was observed for both receptor subunits and was found to coincide with the dendrites and varicosities of IACs. The localization of rho subunits was examined at the ultrastructural level by using postembedding techniques on slam-frozen, cryosubstituted tissue. Double labeling at the electron microscopic level revealed that 5HT-immunoreactive processes were presynaptic to rod bipolar cells through GABA(C) receptors. Intracellular injection of the two morphologic subclasses of IAC amacrine cells, S1 and S2, with Lucifer yellow followed by immunolabeling for the alpha3 or rho subunits revealed that varicosities on the dendrites of both cell types were in register with alpha3- and rho-immunoreactive puncta. Taken together, these results suggest that IACs are presynaptic to rod bipolar cells through GABA(C) receptors and possibly through GABA(A) receptors.     

The actions of serotonergic agonists and antagonists on the activity of brisk ganglion cells in the rabbit retina

Extracellular electrophysiological recordings were obtained from rabbit retinal ganglion cells in either a superfused eyecup or an in vivo preparation. Selective antagonists or agonists of serotonin at the 5-HT2 or 5-HT1A receptors were applied, and the changes in light-evoked and spontaneous activity were studied. Both 5-HT1A agonists and 5-HT2 antagonists reduced the ON-components of the light-evoked responses of all classes of brisk ganglion cell; spontaneous activity was reduced in these cells as well. These results suggest that the indoleamine-accumulating amacrine cells of the rabbit retina serve to facilitate the output of the depolarizing rod bipolar cell and thereby increase the efficacy of transmission between this and other cells in the rabbit retina, and that this process is mediated by 5-HT2 receptors. On the basis of the similarity of the actions of the 2 classes of drug studied, we hypothesize further that 5-HT1A receptors mediate an inhibitory process that serves to terminate the indoleamine-induced facilitation. This process may be located either in the bipolar terminal or presynaptic to it in the terminal of the putative indoleaminergic cells.     

Glutamate receptors at rod bipolar ribbon synapses in the rabbit retina

In the mammalian retina, maximum sensitivity is achieved in the rod pathway, which serves dark-adapted vision. Rod bipolar cells carry the highly convergent rod input and make ribbon synapses with two postsynaptic elements in the inner retina. One postsynaptic neuron is the AII amacrine cell, which feeds the rod signal into the cone pathways. The other postsynaptic element is either an S1 or S2 amacrine cell. These two wide-field GABA amacrine cells both make reciprocal synapses with rod bipolar terminals but their individual roles are unknown. AII and S1/S2 dendrites come in close together and form a dyad opposing the presynaptic ribbon, which is the site of glutamate release. Therefore, two postsynaptic neurons sense the very same neurotransmitter yet serve different functions in the rod pathway. This functional diversity could be derived partly from the expression of different glutamate receptors on each postsynaptic element. In this study, we labeled all pre- and postsynaptic combinations and a signal-averaging method was developed to locate glutamate receptor subunits. In summary, GluR2/3 and GluR4 are expressed by AII amacrine cells but not by S1/S2 amacrine cells. In contrast, the orphan subunit delta1/2 is exclusively located on S1 varicosities but not on AII or S2 amacrine cells. These results confirm the prediction of divergence mediated by different glutamate receptors at the rod bipolar dyad. Each different amacrine cell type appears to express specific glutamate receptors. Finally, the differential expression of glutamate receptors by S1 and S2 may partly explain the need for two wide-field GABA amacrine cells with the same feedback connections to rod bipolar terminals.     

Electron microscopic analysis of the rod pathway of the rat retina

Two immunocytochemical markers were used to label the rod pathway of the rat retina. Rod bipolar cells were stained with antibodies against protein kinase C and AII-amacrine cells with antibodies against parvalbumin. The synaptic circuitry of rod bipolars in the inner plexiform layer (IPL) was studied. Rod bipolar cells make approximately 15 ribbon synapses (dyads) in the IPL. Both postsynaptic members of the dyads are amacrine cells; one is usually the process of an AII-amacrine cell and the other one frequently provides a reciprocal synapse. No direct output from rod bipolar cells into ganglion cells was found. AII-amacrine cells make chemical output synapses with cone bipolar cells and ganglion cells in sublamina a of the IPL. They make gap junctions with cone bipolar cells and other AII-amacrine cells in sublamina b of the IPL. The rod pathway of the rat retina is practically identical to that of the cat and of the rabbit retina. It is very likely that this circuitry is a general feature of mammalian retinal organization. © Wiley-Liss, Inc.     

Synaptic organization of the dopaminergic neurons in the rabbit retina.

A number of substances were tested for their ability to label amine-accumulating neurons in the rabbit retina after fixation with OsO₄ or glutaraldehyde and OsO₄. Useful results were obtained with 5,6-dihydroxytryptamine (5,6-DHT) and 6-hydroxydopamine (6-HDA). Labelled processes were characterized by small (40–50 mm) pleomorphic synaptic vesicles containing electron-dense cores, and at times by swelling of mitochondria and by increased electron density of membranes and cytoplasm. Fluorescence microscopy showed that 5,6-DHT labelled both dopaminergic and indoleamine-accumulating neurons. In most experiments, therefore, the indoleamine-accumulating neurons were removed with 5,7-dihydroxytryptamine. In such retinas the dopaminergic processes labelled by 5,6-DHT were found to make synapses of the conventional type, characterized by an accumulation of synaptic vesicles on the presumed presynaptic side and some aggregation of material on the cytoplasmic side of the synaptic membranes and within the synaptic cleft. The dopaminergic processes were found to contact each other and also non-dopaminergic amacrine cells and their processes. Conventional synapses onto dopaminergic processes were observed from both labelled and unlabelled amacrine processes. The input from labelled neurons was observed on varicose dopaminergic processes whereas input from non-labelled elements was found on the intervaricose parts of the dopaminergic processes. No Contacts of dopaminergic processes with bipolar or ganglion cells were observed. Injections of 6-HDA gave the same results, although this drug gave less distinct labelling which made the observations less decisive than with 5,6-DHT. In retinas treated with 5,6-DHT alone (i.e., in which the indoleamine-accumulating neurons remained) numerous processes were observed which were both pre- and postsynaptic to bipolar terminals. These observations suggest that the indoleamine-accumulating processes synapse with bipolar cells. The results show that the dopaminergic neurons form a network involving only amacrine cells, suggesting a regulatory function for them. By analogy with the dopaminergic interplexiform cells of the goldfish retina, it is suggested that the dopaminergic neurons in the rabbit may regulate lateral inhibitory effects mediated by amacrine cells. Furthermore, the finding that the dopaminergic and indoleamine-accumulating cells apparently have a different synaptic organization suggests that it is appropriate to categorize amacrine cells according to their transmitter content as well as their morphology.     

The rod pathway in the rabbit retina: a depolarizing bipolar and amacrine cell

Anatomical and electrophysiological techniques were combined to study the morphology, synaptic connections, and response properties of two neurons in the rod pathway of the rabbit retina: the rod bipolar cell and the narrow-field, bistratified (NFB) amacrine cell. Rod bipolars receive synaptic input from rod cells in the outer plexiform layer (OPL), where their dendrites end as central elements in the invaginating synapse of rod spherules. Their main synaptic output in the inner plexiform layer (IPL) is onto NFB amacrine cells and at least one other type of amacrine, which in turn feeds a reciprocal synapse back onto the bipolar endings. Rod bipolars, or a variety of them, respond to diffuse, white light stimulation with a transient-sustained depolarization dominated by rods; with high-intensity flashes, they generate a secondary depolarization at off, which is homologous to the rod aftereffect of horizontal cells, although opposite in polarity. NFB amacrine cells receive synaptic input from rod bipolars, cone bipolars, and other types of amacrine cells; they are presynaptic to ganglion cell dendrites and communicate via gap junctions with other processes, whose parent neuron has not yet been identified. They respond to light with a triphasic potential, characterized by a depolarizing transient at on, followed by a sustained plateau phase, and finally by a hyperpolarizing transient at off. Threshold of their responses is the same as in the depolarizing rod bipolars and saturation is reached with nearly the same stimulus intensity in both neurons. Furthermore, NFB amacrine cells exhibit a depolarizing rod aftereffect at the termination of high-intensity flashes. Thus, this amacrine cell type is inserted in series along the rod pathway in the rabbit retina and modulates the transfer of scotopic signals from rod bipolars to ganglion cells.     

Rod bipolar cells in the macaque monkey retina: immunoreactivity and connectivity.

Rod bipolar cells in the macaque monkey retina were labeled by three antibodies: an antibody against the alpha- and beta-subspecies of protein kinase C (PKC), a polyclonal antiserum against the L7 protein from mouse cerebellum, and a monoclonal antibody against rabbit olfactory bulb (MAb 115A 10). The MAb 115A10 antibody also labeled some cone bipolar and some amacrine cells. The antibody against PKC was used to study the synaptic connectivity of rod bipolar cells. Reconstructions of 28 rod spherules showed that usually two and up to four rod bipolar processes invaginate each rod spherule. Six rod bipolar axons in the inner plexiform layer were reconstructed; they all showed the same pattern of connectivity. Synaptic output at rod bipolar dyads usually was onto two amacrine cell profiles: one that resembled the All amacrine cell and another that frequently made a reciprocal synapse. Rod bipolar cells did not contact ganglion cells. Synaptic input to rod bipolar cells came from reciprocal amacrine cells at dyads and other amacrine cells. In these respects, the rod pathway in the monkey is very similar to that described in cat and rabbit. The density of rod bipolar cells was determined and compared with the density of rods. There is a maximum of 15,000-20,000 rod bipolar cells/mm2 at 1-3 mm eccentricity, close to where rod density is maximum. Rod density is 10 times higher than rod bipolar cell density within 2 mm of the fovea, and 30 times higher at 15 mm eccentricity. This change in relative density is compensated by an increase in the number of rods contacted by individual rod bipolar cells (seen in Golgi-stained whole-mount retina) so that the number of rod bipolar terminal boutons in each rod photoreceptor remains relatively constant with changing eccentricity. We estimate that each rod bipolar cell is contacted by about 20 rods at 2-4 mm eccentricity and about 60 rods at 6-7 mm eccentricity.     

Molecular specificity of defined types of amacrine synapse in cat retina

The inner plexiform layer of cat retina contains synaptic structures belonging to 50 or more types of "identified" neurons. To learn whether there are antigens confined to subsets of these synaptic structures, we raised monoclonal antibodies to homogenates of neural retina. Binding patterns of these antibodies were visualized by the peroxidase-antiperoxidase method and studied in serial, ultrathin sections by electron microscopy. Four antibodies stained the synaptic varicosities of certain amacrine cells. Many of the stained varicosities formed reciprocal synapses with a rod bipolar axon terminal, but only about half of the reciprocal synapses associated with a rod bipolar were stained. Other stained varicosities formed synapses with cone bipolar axons, ganglion cell dendrites, and unstained amacrine processes. The patterns were essentially the same for each antibody and were not altered by staining with the antibodies two at a time; therefore, it is likely that all four antibodies stain the same subset of synaptic structures. These patterns would be accounted for if there were staining of all the synaptic varicosities of three of the four types of identified amacrine reciprocally connected to the rod bipolar (A6, A8, A13). This localization suggests that the antigen responsible for the binding pattern is not associated with synaptic transmission. Staining is present in the inner plexiform layer during the period of synaptogenesis and consequently the antibodies are serving as markers for following the development of identified synapses in an identified neural circuit.     

Sequential course of uptake of intravitreal 5,7-dihydroxytryptamine by carp retinal cells

The sequential course of uptake by retinal cells of intravitreally injected 5,7-dihydroxytryptamine (5,7-DHT) together with dopamine (DA) was investigated in juvenile carp retinas, which were removed at various intervals (1-24 h) after injection. The cells taken up 5,7-DHT were visualized immunohistochemically with anti-serotonin (5-HT) antibody and FITC-conjugated IgG. After a mixture of 5,7-DHT and DA (2.5, 10 or 20 micrograms each) was given, large-sized indoleamine (IA) amacrine cells first (1-4 h), and then small-sized indoleamine-accumulating amacrine amacrine (IAA) cells (4-12 h), bipolar cells (8-12 h) and in some cases photoreceptor cells (12-24 h) were sequentially observed, and finally the immunoreactive structures almost disappeared around 24 h after injection. When the mixture of 5,7-DHT and DA (10 micrograms each) was injected into the eyes of reserpinized fish, the same sequential uptake of 5,7-DHT was seen in a faster time course, but additionally various classes of retinal cells (horizontal, ganglion and Müller cells) became visible as irregular clusters. However, DA cells were never visualized at any stages of all the experiments, indicating that DA cells do not take up 5,7-DHT in the carp retina, which was further confirmed by double labeling of 5-HT- and tyrosine hydroxylase-like immunoreactive cells. Double labeling also revealed that 5,7-DHT-accumulating bipolar cells appear to represent a subclass different from that of protein kinase C-like immunoreactive bipolar cells.     

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.     

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.     

Antibody to calretinin stains AII amacrine cells in the rabbit retina: Double-label and confocal analyses

The AII or rod amacrine cell is a critical interneuron in the rod pathway of mammalian retinae. In this report, it is shown that commercially available antibodies to the calcium binding protein calretinin may be used to label the population of AII amacrine cells selectively. Calretinin-positive amacrine cells had the morphological attributes of AII amacrine cells. Double-labeling procedures showed that calretinin-positive somata were surrounded by dopaminergic varicosities and that calretinin-positive dendrites enclosed rod bipolar terminals, both as previously described for AII amacrine cells. By analyzing the surrounding kernel for each labeled pixel in the rod bipolar image, it is shown here that AII processes are adjacent to rod bipolar terminals at a level that far exceeds the random overlap present in images in which one label was rotated out of phase. Such a spatial relationship is indicative of synaptic connections, as well described for rod bipolar input to AII amacrine cells. AII amacrine cells also were double-labeled for calretinin and parvalbumin; however, a scattergram analysis of red versus green intensity showed that the parvalbumin antibody stained additional unidentified amacrine cells. In conclusion, at the appropriate dilution, calretinin antibodies are a useful marker for AII amacrine cells in the rabbit retina. J. Comp. Neurol. 411:3–18, 1999. © 1999 Wiley-Liss, Inc.     

5-HT2 antagonists reduce ON responses in the rabbit retina

We have investigated the effects of serotonin (5-HT2) antagonists in the rabbit retina. These antagonists reduce the ON responses of ON-center cells as well as the surround (ON) responses of OFF-center cells, and enhance the center (OFF) responses of the latter cells. The result is consistent with the anatomy of the indoleamine-accumulating cells in the rabbit retina, which ramify in sublamina b (ON) of the inner plexiform layer and contact primarily bipolar cells that are depolarizing in the rabbit. This suggests that at least part of the surround (ON) responses to OFF-center cells is generated in the inner plexiform layer.     

Ultrastructural demonstration of L-glutamate decarboxylase and cysteinesulfinic acid decarboxylase in rat retina by immunocytochemistry

The gamma-aminobutyric acid (GABA) synthesizing enzyme, L-glutamate decarboxylase (GAD), and the taurine synthesizing enzyme, cysteinesulfinic acid decarboxylase (CSAD) have been localized in rat retina at the ultrastructural level by indirect immunoelectron microscopy. GAD immunoreactivity (GAD-IR) was seen only in some amacrine cells and their terminals. CSAD immunoreactivity (CSAD-IR) was found in most retinal neuronal types and their processes including photoreceptor cells (rod and cone cells), bipolar cells, amacrine cells and ganglion cells. The GAD-IR positive amacrine terminals have been found to make synaptic contact with other GAD-IR negative bipolar and amacrine terminals, and ganglion cell dendrites. Most of the GAD-IR positive terminals are presynaptic. Occasionally, GAD-IR positive amacrine terminals are postsynaptic to another amacrine terminal or ganglion cell body. In the inner plexiform layer, CSAD-IR positive amacrine terminals also make synaptic contacts with other nerve terminals, similar to that of GAD-IR positive amacrine terminals. In addition, CSAD-IR positive bipolar terminals make synaptic contact with some CSAD-IR positive as well as negative amacrine terminals. Both CSAD-IR positive amacrine and bipolar terminals are mostly presynaptic to other CSAD-IR negative terminals. In the outer plexiform layer, CSAD-IR was found to be associated with synaptic vesicles and the synaptic membrane in certain cone pedicles and rod spherules. It is concluded that only a fraction of amacrine cells in rat retina may use GABA as a neurotransmitter. The presence of CSAD-IR in some amacrine, bipolar, photoreceptor and ganglion cells in rat retina is compatible with the notion that taurine may play some important roles, such as those of neurotransmitter or neuromodulator in mammalian retina.     

Rod pathways in mammalian retinae.

A variety of recent experiments has resolved the way in which signals are transmitted from rod photoreceptors to ganglion cells in the mammalian retina. Rods connect to a single class of rod bipolar cell, which depolarize in response to light. Rod bipolar cells are not connected directly to ganglion cells: they synapse onto rod amacrine cells, which excite ON-centre ganglion cells via gap junctions, and inhibit OFF-centre ganglion cells via inhibitory glycine synapses. Monoamines have particular influences on the rod system, through synapses with rod amacrine and rod bipolar cells, and a function for dopamine and indoleamines within this system can be hypothesized from recent experiments. There is evidence to suggest that dopaminergic amacrine cells bring the surround response into the rod system through synapses with the rod amacrine cell, and that an indoleamine, probably serotonin, increases the signal in the ON pathway through a feedback synapse onto the rod bipolar terminal.     

Selective synaptic connections in the retinal pathway for night vision

The mammalian retina encodes visual information in dim light using rod photoreceptors and a specialized circuit: rods→rod bipolar cells→AII amacrine cell. The AII amacrine cell uses sign-conserving electrical synapses to modulate ON cone bipolar cell terminals and sign-inverting chemical (glycinergic) synapses to modulate OFF cone cell bipolar terminals; these ON and OFF cone bipolar terminals then drive the output neurons, retinal ganglion cells (RGCs), following light increments and decrements, respectively. The AII amacrine cell also makes direct glycinergic synapses with certain RGCs, but it is not well established how many types receive this direct AII input. Here, we investigated functional AII amacrine→RGC synaptic connections in the retina of the guinea pig (Cavia porcellus) by recording inhibitory currents from RGCs in the presence of ionotropic glutamate receptor (iGluR) antagonists. This condition isolates a specific pathway through the AII amacrine cell that does not require iGluRs: cone→ON cone bipolar cell→AII amacrine cell→RGC. These recordings show that AII amacrine cells make direct synapses with OFF Alpha, OFF Delta and a smaller OFF transient RGC type that co-stratifies with OFF Alpha cells. However, AII amacrine cells avoid making synapses with numerous RGC types that co-stratify with the connected RGCs. Selective AII connections ensure that a privileged minority of RGC types receives direct input from the night-vision pathway, independent from OFF bipolar cell activity. Furthermore, these results illustrate the specificity of retinal connections, which cannot be predicted solely by co-stratification of dendrites and axons within the inner plexiform layer.