Immunocytochemical localization of the postsynaptic density protein PSD-95 in the mammalian retina

Synapse-associated proteins are the scaffold for the selective aggregation of ion channels at synapses; they provide the link to cytoskeletal elements and possibly are involved with the regulation of synaptic efficacy by electrical activity. The localization of the postsynaptic density protein PSD-95 was studied in different mammalian retinae (rat, monkey, and tree shrew) by using immunocytochemical methods. Immunofluorescence for PSD-95 was most prominent in the outer plexiform layer (OPL). The axon terminals of rods and cones, the rod spherules and cone pedicles, were strongly labeled. Electron microscopy, using preembedding immunocytochemistry, showed PSD-95 localized presynaptically within the photoreceptor terminals. Distinct PSD-95 labeling was also present in the inner plexiform layer (IPL). It had a punctate appearance suggesting the synaptic clustering of PSD-95 in the IPL. Electron microscopy showed that PSD-95 was concentrated in processes that were postsynaptic at bipolar cell ribbon synapses (dyads). As a rule, only one of the two postsynaptic members of the dyad was labeled for PSD-95. Double-labeling experiments were performed for PSD-95 and for SAP 102 or PSD-93, respectively, two other members of the family of synapse-associated proteins. All three were found to be colocalized in the synaptic hot spots in the IPL. In the OPL, however, PSD-95 and PSD-93 were found presynaptically, whereas SAP 102 was located postsynaptically at photoreceptor synapses. Double-labeling experiments also were performed for PSD-95 and for the NR1 subunit of the NMDA receptor. They were found to be colocalized in synaptic hot spots in the IPL.     

Identification and localization of an immunoreactive AMPA-type glutamate receptor subunit (GluR4) with respect to identified photoreceptor synapses in the outer plexiform layer of goldfish retina

L-glutamate, the main excitatory synaptic transmitter in the retina, is released from photoreceptors and evokes responses in second-order retinal neurons (horizontal, bipolar cells) which utilize both ionotropic and metabotropic types of glutamate receptors. In the present study, to elucidate the functional roles of glutamate receptors in synaptic transmission, we have identified a specific ionotropic receptor subunit (GluR4) and determined its localization with respect to photoreceptor cells in the outer plexiform layer of the goldfish retina by light and pre-embedding electron-microscopical immunocytochemistry. We screened antisera to mammalian AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate)-preferring ionotropic glutamate receptors (GluR 1-4) of goldfish retina by light- and electron-microscopical immunocytochemistry. Only immunoreactive (IR) GluR4 was found in discrete clusters in the outer plexiform layer. The cones contacted in this manner were identified as long-wavelength ("red") and intermediate-wavelength ("green") cones, which were strongly immunoreactive to monoclonal antibody FRet 43 and antisera to goldfish red and green-cone opsins; and short-wavelength ("blue") cones, which were weakly immunoreactive to FRet 43 but strongly immunoreactive with antiserum to blue-cone opsin. Immunoblots of goldfish retinal homogenate with anti-GluR4 revealed a single protein at M(r) = 110 kDa. Preadsorption of GluR4 antiserum with either the immunizing rat peptide, or its goldfish homolog, reduced or abolished staining in retinal sections and blots. Therefore, we have detected and localized genuine goldfish GluR4 in the outer plexiform layer of the goldfish retina. We characterized contacts between photoreceptor cells and GluR4-IR second-order neurons in the electron microscope. IR-GluR4 was localized to invaginating central dendrites of triads in ribbon synapses of red cones, semi-invaginating dendrites in other cones and rods, and dendrites making wide-cleft basal junctions in rods and cones; the GluR4-IR structures are best identified as dendrites of OFF-bipolar cells. The results of our studies indicate that in goldfish retina GluR4-expressing neurons are postsynaptic to all types of photoreceptors and that transmission from photoreceptors to OFF-bipolars is mediated at least in part by AMPA-sensitive receptors containing GluR4 subunits.     

Group II and group III metabotropic glutamate receptors in the rat retina: distributions and developmental expression patterns

We have studied the distributions of group II metabotropic glutamate receptors, mGluR2 and mGluR3, and a group III metabotropic glutamate receptor, mGluR4, in the adult rat retina and during postnatal development using receptor specific anti-peptide antisera. Of the three receptors examined, mGluR3 was not expressed in the retina. MGluR2 showed a distinct stratification pattern in the inner plexiform layer (IPL). Double-labelling immunocytochemistry revealed that mGluR2 was localized in the processes of cholinergic amacrine cells. MGluR4 was found throughout the entire IPL. At the subcellular level, both mGluR2 and mGluR4 were found to be localized exclusively in processes postsynaptic to bipolar cell synapses in the IPL. During postnatal development, labelling for mGluR2 was detected at around postnatal day five. MGluR4 was already present at postnatal day one, prior to the establishment of synaptic connections in the IPL. The differential expression patterns of individual metabotropic glutamate receptors in the adult and developing rat retina suggest distinct roles for these receptors in retinal synaptic circuitry.     

The kinesin motor KIF3A is a component of the presynaptic ribbon in vertebrate photoreceptors

Kinesin motors are presumed to transport various membrane compartments within neurons, but their specific in vivo functions, cargoes, and expression patterns in the brain are unclear. We have investigated the distribution of KIF3A, a member of the heteromeric family of kinesins, in the vertebrate retina. We find KIF3A at two distinct sites within photoreceptors: at the basal body of the connecting cilium axoneme and at the synaptic ribbon. Immunoelectron microscopy of the photoreceptor ribbon synapse shows KIF3A to be concentrated both at the ribbon matrix and on vesicles docked at the ribbon, a result that is consistent with the presence of both detergent-extractable and resistant KIF3A fractions at these synapses. KIF3A is also present in the inner plexiform layer, again at presynaptic ribbons. These findings suggest that within a single cell, the photoreceptor, one kinesin polypeptide, KIF3A, can serve two distinct functions, one specific for ribbon synapses.     

Comparison of immunolocalization patterns for the synaptic vesicle proteins p65 and synapsin I in macaque monkey retina

The distributions of the two synaptic vesicle proteins p65 [Matthew et al. (1981) J. Cell Biol., 91:257-269] and synapsin I [De Camilli et al. (1983) J. Cell Biol., 96:1337-1354] were compared in macaque monkey retina using pre-embedding immunocytochemistry for both light and electron microscopy. The monoclonal antibody AB-48 against p65 labeled ribbon-containing synaptic terminals of cone, rod, and bipolar cells as well as many conventional synapses of amacrine cells. In contrast, a polyclonal antiserum against synapsin I (SYN I) labeled many amacrine conventional synapses but no photoreceptor or bipolar ribbon synaptic terminals. Horizontal cell pre- and post-synaptic profiles in the outer plexiform layer were not labeled by either antibody. At the light microscopic level, the banding patterns in the inner plexiform layer also differed for the two antibodies, with four bands of AB-48 immunoreactivity in sublayers S1, S2, S4, and S5 but only three bands of SYN I immunoreactivity in S1, S3, and S5. SYN I also labeled varicose fibers in both the inner nuclear layer and the outer plexiform layer that are probably processes of dopaminergic and GABAergic interplexiform cells. Varicose fibers in the ganglion cell layer were labeled by both antibodies. These results provide the first electron microscopic immunocytochemical labeling for AB-48 and SYN I in intact retina and confirm that AB-48 labels both ribbon and conventional synaptic terminals, whereas SYN I labels only conventional synapses.     

Presynaptic and postsynaptic localization of GABA(B) receptors in neurons of the rat retina

The recently cloned GABA(B) receptors were localized in rat retina using specific antisera. Immunolabelling was detected in the inner and outer plexiform layers (IPL, OPL), and in a number of cells in the inner nuclear layer and the ganglion cell layer. Double-labelling experiments for GABA (gamma-aminobutyric acid) and GABA(B) receptors, respectively, demonstrated a co-localization in horizontal cells and amacrine cells. Electron microscopy showed that GABA(B) receptors of the OPL were localized presynaptically in horizontal cell processes invaginating into photoreceptor terminals. In the IPL, GABA(B) receptors were present presynaptically in amacrine cells, as well as postsynaptically in amacrine and ganglion cells. The postnatal development of GABA(B) receptors was also studied, and immunoreactivity was observed well before morphological and synaptic differentiation of retinal neurons. The present results suggest a presynaptic (autoreceptor) as well as postsynaptic role for GABA(B) receptors. In addition, the extrasynaptic localization of GABA(B) receptors could indicate a paracrine function of GABA in the retina.     

N-methyl-D-aspartate receptors containing the NR2D subunit in the retina are selectively expressed in rod bipolar cells

N-methyl-D-aspartate receptor subunit messenger RNAs are widely expressed in the retina and several types of second and third order neurons are responsive to N-methyl-D-aspartate. Functional N-methyl-D-aspartate receptors are assembled from the NR1 subunit with at least one of the four NR2 subunit variants (NR2A-2D). We have analysed immunohistochemically the cellular distribution of N-methyl-D-aspartate receptors containing the NR2D subunit in the rat and rabbit retina. Using a subunit-specific NR2D antiserum, exclusively bipolar cells with somata localized close to the outer plexiform layer were labelled in both species. The axons were immunoreactive and arborized in the innermost inner plexiform layer. The morphology and localization of these cells, which were much more numerous in rat than in rabbit, suggested that they are rod bipolar cells. This was confirmed in both species by co-localization of the NR2D subunit immunoreactivity with protein kinase C-alpha, a selective marker for rod bipolar cells. At the subcellular level, a distinct polarization in the distribution of NR2D immunoreactivity was demonstrated by confocal laser scanning microscopy: staining was moderate in dendrites arborizing within the outer plexiform layer, intense at that pole of the soma facing the outer plexiform layer, and low in the portion of the soma embedded in the inner nuclear layer. Proximal axonal segments and axonal end-feet in the inner plexiform layer displayed the strongest NR2D subunit immunoreactivity. The axonal staining suggests that neurotransmission of the rod bipolar cells is modulated within the inner plexiform layer by N-methyl-D-aspartate receptors containing the NR2D subunit.     

Synaptic inputs mediating bipolar cell responses in the tiger salamander retina

Postsynaptic receptors in bipolar cells were studied by focal application of glutamate and GABA to the outer and inner plexiform layers (OPL and IPL) under visual guidance in living retinal slices of the tiger salamander. Two different types of conductance change could be elicited in bipolar cells by applying glutamate to the OPL. In off-center cells, which had axon telodendria ramifying in the distal 55% of the IPL, glutamate elicited a conductance increase associated with a reversal potential near -5 mV. In on-center cells, which had telodendria stratified in the proximal 45% of the IPL, glutamate caused a conductance decrease associated with a reversal potential near -11 mV. These observations suggest that glutamate gates relatively nonspecific cation channels at synapses between photoreceptors and bipolar cell dendrites. Application of glutamate to the IPL elicited no conductance change in Co2+ Ringer's solution, but in normal Ringer's it generated a conductance increase associated with a reversal potential near the chloride equilibrium potential (ECl). These findings are consistent with the notion that glutamate receptors exist in GABAergic and/or glycinergic amacrine cells, and that glutamate in the IPL depolarizes these cells, causing GABA and/or glycine release and the opening of chloride channels in bipolar cell axon terminals. In Co2+ Ringer's, application of GABA at the OPL elicited no conductance changes in bipolar cells, suggesting that GABA receptors do not exist on bipolar cell dendrites. Applied at the IPL, GABA elicited large conductance increases associated with a reversal potential near ECl. Implications of these results for the functional circuitry of the tiger salamander retina are discussed.     

A fine structural and E-PTA study of photoreceptor synaptogenesis in the chick retina

Photoreceptor synaptogenesis in the embryonic and hatchling chick retina was studied with conventional EM techniques and ethanolic phosphotungstic acid (E-PTA). The photoreceptors line up between 11 and 13 embryonic days with their undifferentiated synaptic bases facing the outer plexiform layer (OPL). E-PTA staining at 11 embryonic days does not reveal any para-membranous specializations of the receptors but numerous stained punctae adhaerentes are observed in the OPL. At 13 embryonic days neurites of presumed bipolar and horizontal neurons are aligned parallel to the bases of the receptors and cytoplasmic protrusions of the receptors project between some of these neurites to form dyad appositions. An osmiophilic undercoating, which is not E-PTA positive at this time, is present on the cytoplasmic face of the receptor membrane in these apposition regions. Between 13 and 15 embryonic days the filopodial protrusions of the receptors continue to elongate further and become aligned with neurites in dyad and triad appositions. The osmiophilic undercoating now extends along the entire inner surface of the receptor pedicle protrusions and becomes E-PTA positive. Between 15 and 17 embryonic days focal aggregations of osmiophilic and E-PTA stained material appear along the membranes of the protrusions and there is some E-PTA staining of the postsynaptic densities and intervening cleft material. Between 17 and 21 embryonic days mature ribbon synapses are observed on the surfaces of the conical-shaped, receptor pedicles where the ribbons and their synaptic vesicles are associated with the dense aggregations (arciform densities), seen earlier as isolated focal aggregations, and the receptor undercoating is restricted to non-synaptic regions. E-PTA staining shows that ribbons are positively stained around their borders only and that they are contiguous with the intensely stained arciform densities. The cleft material and postsynaptic densities of some synapses first stain as V-shaped junctions and later as Y-shaped junctions. These observations suggest that ribbon synaptic junction formation begins with an alignment of pre- and postsynaptic membranes and the presence of the receptor presynaptic membrane undercoating, followed by the appearance of the presynaptic arciform densities and some staining of the cleft material and postsynaptic densities. These events are followed by the appearance of synaptic ribbons which are associated with the presynaptic arciform densities and by a further differentiation of the cleft material and postsynaptic densities.     

Localization of HRG4, a photoreceptor protein homologous to Unc-119, in ribbon synapse

PURPOSE: To characterize further HRG4, a novel photoreceptor protein recently identified by subtractive cDNA cloning, by sequence analysis and immunolocalization. METHODS: The rat homolog of HRG4, RRG4 was expressed and used to prepare an antibody. The antibody was used in Western blot analysis, and immunofluorescent localization at the light and electron microscopic levels of HRG4-RRG4 protein. The HRG4-RRG4 sequence was also analyzed for homologies. RESULTS: HRG4-RRG4 showed 57% homology with unc-119, a Caenorhabditis elegans neuroprotein causing defects in locomotion, feeding, and chemosensation when mutated. By Western blot analysis, the HRG4-RRG4 protein was demonstrable only in retina and was soluble in nature. Immunofluorescence microscopic study of human and rat retinas, using the HRG4-RRG4 antibody, and other rod and cone photoreceptor-specific antibodies showed that the HRG4-RRG4 protein is localized in the outer plexiform layer of the retina in the synaptic termini of rod and cone photoreceptors. Electron microscopic immunolocalization showed the protein in the cytoplasm and on the presynaptic membranes of the photoreceptor synapses. CONCLUSIONS: The homology to unc-119 and localization to the photoreceptor synapse are suggestive of a function for HRG4-RRG4 in photoreceptor neurotransmission. HRG4 is the first photoreceptor-enriched synaptic protein to be reported, suggesting that its function may be unique to the specialized ribbon synapses formed between photoreceptors and the horizontal and bipolar cells of the retina.     

Differential distribution of beta-dystroglycan in rabbit and rat retina

The distribution of the dystrophin-associated glycoprotein complex was investigated in rabbit and rat retina by using the monoclonal antibody 43DAG/8D5, which specifically recognizes beta-dystroglycan, a central component of the complex. In cryostat sections of retinae from both species, the authors observed staining of blood vessels, continuous labeling around the vitreal border, and strong immunoreactivity in the outer plexiform layer (OPL). Electron microscopy showed that the immunoreactivity associated with the vitreal border of the retina was the result of a subcellular concentration of beta-dystroglycan in the endfeet of Müller glial cells. A similar concentration was observed in endfeet of perivascular astrocytes in the region of contact with the capillary basal lamina. In the OPL, beta-dystroglycan was associated with the terminals of both rods and cones. The label was almost exclusively found outside the synaptic area and was particularly strong in the extensions of the photoreceptor terminals protruding into the OPL. In the OPL of the rabbit retina, the authors found additional immunoreactivity associated with the tips of postsynaptic horizontal and bipolar cell processes. These results show that the dystrophin-associated glycoprotein complex is subcellularly concentrated in photoreceptor terminals and glial cell endfeet, and that the rabbit retina differs from the rat retina by the additional expression of this complex in bipolar and horizontal cells.     

Glycine receptors in the retinas of normal and spastic mutant mice

PURPOSE: Spastic mutant mice have abnormal gait and righting behavior, and the responses of their retinal ganglion cells have recently been shown to be abnormal. The former defects have been linked to a reduction of glycine-receptor density in the spinal cord of spastic mutants, but the cause of the retinal defects has not yet been determined. The authors thus tested for reduced glycine-receptor density in the mutant retina by comparing the levels of glycine receptors in the retinas of spastic mutant mice with those found in normal mice. METHODS: Indirect immunofluorescence histochemistry was employed, using monoclonal antibodies directed against the alpha- and beta-subunits of the receptor and against the 93-kd cytoplasmic receptor-associated protein, gephyrin. RESULTS: In normal mice, all glycine-receptor antibodies labeled two laminae of the inner plexiform layer (IPL): a broad band in the distal third of the IPL and a narrow band in the middle of the IPL. Lighter labeling was also seen in the outer plexiform layer with these antibodies. In spastic mutant mice, the glycine-receptor labeling of the IPL was reduced markedly. However, the overall structure of the spastic mutant retina was not disrupted because the distribution and intensity of both a presynaptic marker (synaptophysin) and a marker for the rod bipolar cell (protein kinase C) in the mutant retina were indistinguishable from those in normal retinas. CONCLUSIONS: The glycine-receptor distribution in normal mice was consistent with that previously reported for the rat and with the distribution of glycine responsiveness of dissociated rodent bipolar cells. The reduced levels of glycine receptors in spastic mice help explain the abnormal ganglion cell responses in the spastic mutant.     

Microsomal electron transfer in higher plants: cloning and heterologous expression of NADH-cytochrome b5 reductase from Arabidopsis

The mechanisms underlying the conversion of prolonged glutamate release from ribbon synapses in bipolar cells to sustained and transient excitatory postsynaptic responses in identified retinal amacrine cells were studied in tiger salamander (Ambystoma tigrinum) retina. A retina slice preparation with whole cell patch recording techniques under voltage- and current-clamp conditions was used to assay the electrical properties of bipolar and amacrine cells. Amacrine cells were categorized into two basic forms: (i) transient amacrine cells that respond to a step of light with a burst of spikes only at the transitions of the step; and (ii) sustained amacrine cells that respond with continuous spiking during the entire light step. The two cell types each had a characteristic morphology: transient amacrine cells possessed wide dendritic fields (chi = 375 microns), while sustained cells had much more narrowly confined dendritic fields (chi = 85 microns). Whole cell voltage-gated currents of the transient and sustained cell types were not significantly different. Both cell types had spikes that were sensitive to tetradotoxin (TTX, 0.3 microM) with voltage deflections of up to 100 mV. Light-evoked excitatory synaptic currents relaxed rapidly in transient neurons (tau 1/2 = 100 ms) and more slowly in sustained neurons (tau 1/2 = 1.2 s). EPSCs in both cells reversed near 0 mV. Rapid application of glutamate or kainate elicited rapidly desensitizing ionic currents (tau 1/2 = 85 ms) followed by a slowly desensitizing component. Cyclothiazide, a drug that eliminates rapid desensitization, lengthened the time course of the glutamate gated current from tau 1/2 = 85 ms to about 3 s, and the relaxation kinetics of the glutamatergic EPSC from tau 1/2 = 85 ms to about 1.0 s. These data suggest that a key determinant in forming transient versus sustained responses in amacrine cells of vertebrate retina is the differences in their excitatory, glutamatergic synaptic inputs, and that rapid desensitization of glutamate receptors plays a role in converting the presynaptic signal associated with sustained glutamate release into a postsynaptic, transient signal at the ribbon synapse.     

Neurokinin 1 receptor expression in the rat retina

Tachykinin (TK) peptides influence neuronal activity in the inner retina of mammals. The aim of this investigation was to determine the cellular localization of the neurokinin 1 receptor (NK1), whose preferred ligand is the TK peptide substance P (SP), in the rat retina. These studies used a polyclonal antiserum directed to the C-terminus of rat NK1. The majority of NK1-immunoreactive (IR) cells were located in the proximal inner nuclear layer (INL), and very rarely they were found in the distal INL. Some small and large NK1-IR somata were present in the ganglion cell layer. NK1-IR processes were densely distributed across the inner plexiform layer (IPL) with a maximum density over lamina 2 of the IPL. Immunoreactive processes also crossed the INL and ramified in the outer plexiform layer where they formed a sparse meshwork. NK1-IR processes were rarely observed in the optic nerve fiber layer. Double-label immunofluorescence studies with different histochemical markers for bipolar cells indicated that NK1 immunoreactivity was not present in bipolar cells. Together, these observations indicate that NK1 immunoreactivity is predominantly expressed by amacrine, displaced amacrine, interplexiform, and some ganglion cells. Double-label immunofluorescence experiments were also performed to characterize NK1-containing amacrine cells. Sixty-one percent of the gamma-aminobutyric acid (GABA)-IR cells, 71% of the large tyrosine hydroxylase (TH)-IR cells, and 100% of the small TH-IR cells contained NK1 immunoreactivity. In addition, most (91%) of the NK1-IR cells had GABA immunoreactivity. In contrast, vasoactive intestinal polypeptide-, TK-, choline acetyltransferase-, and parvalbumin-IR amacrine tells did not express NK1 immunoreactivity. Overall, the present findings suggest that SP acts directly upon several cell populations, including GABA-containing amacrine cells and ganglion cells, to influence visual information processing in the inner retina.     

OFF-alpha and OFF-beta ganglion cells in cat retina: II. Neural circuitry as revealed by electron microscopy of HRP stains

An OFF-center alpha and an OFF-center beta ganglion cell in cat retina, which had been recorded from and intracellularly stained with horseradish peroxidase (HRP) were examined by serial section electron microscopy. We counted synapses and identified presynaptic neurons to the HRP-stained cells in 20 microns radial slices through the centers of their dendritic trees. Presynaptic amacrine and bipolar cells were identified on cytological criteria known from previous studies. The OFF-beta cell with a 62 microns dendritic arbor, restricted to S1 and S2 (sublamina a) of the inner plexiform layer (IPL), received 38% bipolar and 62% amacrine cell synapses. The bipolar input was from both cb1 and cb2 cone bipolar types. Input from three distinct amacrine cell types occurred upon the dendrites, namely from: (1) AII amacrine lobular appendages, (2) large pale amacrine profiles (possibly A2 or A3 cells), and (3) small, dark amacrine types (possibly A8 cells). Large pale amacrine profiles (possibly A13) were found on the cell body and apical dendrite in sublamina b of the IPL. In addition, several amacrine profiles synapsed directly on the sides and base of the cell body in the ganglion cell layer. We estimate that the complete dendritic tree of this beta cell received about 1,000 synapses contributed by 12-14 bipolar cells, 7-10 AII amacrines and 28-41 other amacrine cells. The OFF-alpha cell had a dendritic tree size of 680 x 920 microns. A 250 microns length of two major dendrites stratifying narrowly in S2 of the IPL was reconstructed. Amacrine cells provided most of the synaptic input (80%). This input came from: (1) AII amacrine lobular appendages, (2) amacrines exhibiting large, pale synaptic profiles (possibly A2 or A3 cells), (3) pale amacrines with large mitochondria and a few neurotubules (unknown type), and (4) densely neurotubule-filled amacrine profiles (possibly A19 cells). A large pale amacrine cell type (possibly A13) provided synaptic input to the cell body as a serial synaptic intermediary with rod bipolar cells. Cone bipolar synapses were from only one type of cone bipolar, the cb2 type and formed 20% of the total synaptic input. We estimate that a minimum of 142 bipolar cells, 256 AII amacrine cells and 1,011 other amacrine cells, altogether providing 6,000-10,000 synapses, converged on the dendritic tree of this OFF-alpha cell.     

Differential regional expression and ultrastructural localization of alpha-actinin-2, a putative NMDA receptor-anchoring protein, in rat brain

Fast chemical neurotransmission is dependent on ionotropic receptors that are concentrated and immobilized at specific postsynaptic sites. The mechanisms of receptor clustering and anchoring in neuronal synapses are poorly understood but presumably involve molecular linkage of membrane receptor proteins to the postsynaptic cytoskeleton. Recently the actin-binding protein alpha-actinin-2 was shown to bind directly to the NMDA receptor subunits NR1 and NR2B (), suggesting that alpha-actinin-2 may function to attach NMDA receptors to the actin cytoskeleton. Here we show that alpha-actinin-2 is localized specifically in glutamatergic synapses in cultured hippocampal neurons. By immunogold electron microscopy, alpha-actinin-2 is concentrated over the postsynaptic density (PSD) of numerous asymmetric synapses where it colocalizes with NR1 immunoreactivity. Thus alpha-actinin-2 is appropriately positioned at the ultrastructural level to function as a postsynaptic-anchoring protein for NMDA receptors. alpha-Actinin-2 is not, however, exclusively found at the PSD; immunogold labeling was also associated with filaments and the spine apparatus of dendritic spines and with microtubules in dendritic shafts. alpha-Actinin-2 showed marked differential regional expression in rat brain. For instance, the protein is expressed at much higher levels in dentate gyrus than in area CA1 of the hippocampus. This differential regional expression implies that glutamatergic synapses in various parts of the brain differ with respect to their alpha-actinin-2 content and thus, potentially, the extent of possible interaction between alpha-actinin-2 and the NMDA receptor.     

SAP97 is associated with the alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid receptor GluR1 subunit

Rapid glutamatergic synaptic transmission is mediated by ionotropic glutamate receptors and depends on their precise localization at postsynaptic membranes opposing the presynaptic neurotransmitter release sites. Postsynaptic localization of N-methyl-D-aspartate-type glutamate receptors may be mediated by the synapse-associated proteins (SAPs) SAP90, SAP102, and chapsyn-110. SAPs contain three PDZ domains that can interact with the C termini of proteins such as N-methyl-D-aspartate receptor subunits that carry a serine or threonine at the -2 position and a valine, isoleucine, or leucine at the very C terminus (position 0). We now show that SAP97, a SAP whose function at the synapse has been unclear, is associated with alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA)-type glutamate receptors. AMPA receptors are probably tetramers and are formed by two or more of the four AMPA receptor subunits GluR1-4. GluR1 possesses a C-terminal consensus sequence for interactions with PDZ domains of SAPs. SAP97 was present in AMPA receptor complexes immunoprecipitated from detergent extracts of rat brain. After treatment of rat brain membrane fractions with the cross-linker dithiobis(succinimidylpropionate) and solubilization with sodium dodecylsulfate, SAP97 was associated with GluR1 but not GluR2 or GluR3. In vitro experiments with recombinant proteins indicate that SAP97 specifically associates with the C terminus of GluR1 but not other AMPA receptor subunits. Our findings suggest that SAP97 may be involved in localizing AMPA receptors at postsynaptic sites through its interaction with the GluR1 subunit.     

Development of serotoninergic chick retinal neurons

Numerous neurotransmitters have been studied in detail in the developing retina. Almost all known neurotransmitters and neuromodulators were demonstrated in vertebrate retinas using formaldehyde-induced fluorescence, uptake autoradiography or immunohistochemistry procedures. Serotoninergic (5HT) amacrine neurons were described in the inner nuclear layer (INL) of the retina with their dendrites spreading within the inner plexiform layer (IPL). The present work describes the morphological pattern of development of serotoninergic amacrine neurons with a stratified dendritic branching pattern in the chick retina from embryonic day 12 to postnatal day 7. Serotoninergic-bipolar neurons are also described. SHT-amacrine neurons have round or pear-shaped somata and primary dendritic trees oriented toward the IPL that runs through the INL, showing several varicosities. Secondary dendrites then go through the INL, without any collateral branch. At the outer and inner margin of the IPL the primary and secondary dendrites originate an outer and an inner serotoninergic network, respectively. When the primary dendritic tree reaches the IPL it deflects laterally in sublayer 1-the outer serotoninergic network. Tertiary branches then arise from the secondary dendrite and deflect in the innermost sublayer of the IPL-the inner serotoninergic network. The final pattern of branching of 5HT amacrine cells was present at embryonic day 14 and was completely developed at hatching. Serotoninergic (5HT) bipolar neurons were also present in the INL at hatching. They are weakly immunoreactive and are probably a subset of bipolar cells that accumulate serotonin from the intersynaptic cleft and are not "true" 5HT neurons.     

L-glutamic acid decarboxylase- and gamma-aminobutyric acid-immunoreactive bipolar cells in tiger salamander retina are of ON- and OFF-response types as inferred from Lucifer Yellow injection

The bipolar cells in vertebrate retinas are considered to be excitatory in nature and use L-glutamate as their neurotransmitter. Our earlier studies have provided evidence demonstrating that a small but significant population of orthotopic bipolar cells in salamander retina may be gamma-aminobutyric acid (GABA)ergic. In this work, the stratification levels of axon terminals in the inner plexiform layer (IPL) of single L-glutamic acid decarboxylase-immunoreactive (GAD-IR) and GABA-immunoreactive (GABA-IR) bipolar cells in the salamander retinal slices were studied. GAD-IR and GABA-IR bipolar cells marked by a fluorescent probe, Texas Red, were injected with Lucifer Yellow (LY) through a patch pipette under visual control. A total number of 42 GAD-IR bipolar cells in 24 slices and 84 GABA-IR bipolar cells in 56 slices were injected. Among these, terminals of nine GAD-IR bipolar cells and 22 GABA-IR bipolar cells were sufficiently filled with LY for determination of the stratification levels in the IPL. The stratification patterns and levels of GAD-IR and GABA-IR bipolar cells were very similar. GAD-IR and GABA-IR orthotopic type I and type II bipolar cells (soma located in the most distal or middle of the inner nuclear layer [INL], respectively), had their axon terminals stratified in sublamina a and sublamina b of the IPL with comparable frequency. Axonal processes were restricted largely to either the distal or the proximal region within sublaminae a and b. In addition, three of the bipolar cells had their terminals located in the middle region of the IPL. The similarities of stratification patterns and levels between GAD-IR and GABA-IR type I and type II bipolar cells indicate that they represent the same population of presumed GABAergic bipolar cells. Based on comparative stratifications of GABA bipolar cells reported here and those derived from electrophysiological studies (Hensley et al. [1993] J. Neurophysiol. 69:2086-2098), it is suggested that putative GABAergic bipolar cells represent cone-dominated and rod-dominated ON- and OFF-bipolar cells and that they subserve a broad role in the ON- and OFF-visual pathways in the retina.     

Morphology and distribution of Müller cells in the retina of the toad Bufo marinus

We have previously shown that an antibody against neuron-specific enolase (NSE) selectively labels Müller cells (MCs) in the anuran retina (Wilhelm et al. 1992). In the present study the light- and electron-microscopic morphology of MCs and their distribution were described in the retina of the toad, Bufo marinus, using the above antibody. The somata of MCs were located in the proximal part of the inner nuclear layer and were interconnected with each other by their processes. The MCs were uniformly distributed across the retina with an average density of 1500 cells/mm2. Processes of MCs encircled the somata of photoreceptor cells isolating them from each other by glial sheath, except for those of the double cones. Some of the photoreceptor pedicles remained free of glial sheath. Electron-microscopic observations confirmed that MC processes provide an extensive scaffolding across the neural retina. At the outer border of the ganglion cell layer these processes formed a non-continuous sheath. The MC processes traversed through the ganglion cell layer and spread beneath it between the neuronal somata and the underlying optic axons. These processes formed a continuous inner limiting membrane separating the optic fibre layer from the vitreous tissue. Neither astrocytic nor oligodendrocytic elements were found in the optic fibre layer. The significance of the uniform MC distribution and the functional implications of the observed pattern of MC scaffolding are discussed.