Colocalization of enkephalin-, glucagon-, and corticotropin-releasing factor-like immunoreactivity in GABAergic amacrine cells in turtle retina

Regional distribution of nitrergic neurons in the inner retina of the chicken

Using both NADPH diaphorase and anti-nNOS antibodies, we have identified-from retinal flatmounts-neuronal types in the inner retina of the chicken that are likely to be nitrergic. The two methods gave similar results and yielded a total of 15 types of neurons, comprising 9 amacrine cells, 5 ganglion cells, and 1 centrifugal midbrain neuron. Six of these 15 cell types are ubiquitously distributed, comprising 3 amacrine cells, 2 displaced ganglion cells, and a presumed orthotopic ganglion cell. The remaining nine cell types are regionally restricted within the retina. As previously reported, efferent fibers of midbrain neurons and their postsynaptic partners, the unusual axon-bearing target amacrine cells, are entirely confined to the ventral retina. Also confined to the ventral retina, though with somewhat different distributions, are the "bullwhip" amacrine cells thought to be involved in eye growth, an orthotopic ganglion cell, and two types of large axon-bearing amacrine cells whose dendrites and axons lie in stratum 1 of the inner plexiform layer (IPL). Intracellular fills of these two cell types showed that only a minority of otherwise morphologically indistinguishable neurons are nitrergic. Two amacrine cells that branch throughout the IPL are confined to an equatorial band, and one small-field orthotopic ganglion cell that branches in the proximal IPL is entirely dorsal. These findings suggest that the retina uses different processing on different regions of the visual image, though the benefit of this is presently obscure.

Synaptic inputs to identified color-coded amacrine and ganglion cells in the turtle retina

Previous studies have proposed models of the specific synaptic circuitry responsible for color processing in the turtle retina. To determine the accuracy of these models of the circuits underlying color opponency in the inner retina of the turtle (Pseudemys scripta), we have studied the physiology, morphology, and synaptic connectivity of identified amacrine and ganglion cells. These cells were first characterized electrophysiologically and were then stained with horseradish peroxidase. Postembedding electron immunocytochemistry for gamma-aminobutyric acid (GABA) and glycine was used to reveal the neurochemical identity of their synaptic inputs. The red-ON/green, blue-OFF small-field ganglion cell, classified as G24, branched primarily in strata S1, S4, and S5 of the inner plexiform layer (IPL). Ganglion cell G24 showed a complex receptive field organized into a red-ON center surrounded by an inhibitory region, which, in turn, was surrounded by a second excitatory region. Only the center responses were color opponent. The red-OFF/green, blue-ON large-field, stellate amacrine cell, classified as A23b, stratified exclusively in stratum S2, near the S2/S3 border. The color-coded center was surrounded by a luminosity, red-sensitive surround. Synaptic input to G24 and A23b was dominated by amacrine cells (89% and 87%, respectively). G24 received significant input from amacrine cell profiles with GABA (13% of total) as well as glycine (11% of total) immunoreactivity, mostly in the proximal stratum S5 of the IPL (64% and 67% of the total GABA- and glycine-immunoreactive input, respectively). Bipolar cell synaptic input was also found predominantly in S4 and S5 (89%). In contrast, we found no glycine-immunoreactive input to A23b, and the density of the GABA-immunoreactive amacrine cell synaptic input revealed a central (15%) to peripheral (3%) gradient within the dendritic tree. The results of the present study support the previous models of the synaptic circuitry responsible for color-opponent signal processing in the inner retina of the turtle.

Specialized neuropeptide Y- and glucagon-like immunoreactive amacrine cells in the peripheral retina of the turtle

There are many regional differences in cell morphology and neurochemistry in the retina. This study examined a specialized population of neuropeptide Y- and glucagon-like immunoreactive amacrine cells in the peripheral retina of the turtle. Some of the dendritic processes from these peptidergic amacrine cells formed a dense circumferentially oriented nerve fiber plexus which ran parallel to the ora serrata. Collaterals from this plexus projected into and innervated the nonpigmented ciliary epithelium in the pars plana region of the ciliary body. Electron microscopy revealed that the neuropeptide Y- and glucagon-like immunoreactive processes in the ciliary epithelium contained many labeled, large dense-cored vesicles. Small crystals of lipid-soluble fluorescent dye were implanted in the retina near the ora serrata in fixed retinal tissue to search for other peripheral retinal specializations. Numerous thick and thin cell processes oriented parallel to the ora serrata were labeled in the retina by the dye. In addition, many dye-labeled somata with circumferentially oriented dendritic arborizations were seen in the extreme periphery of the retina. Many of these dye-labeled cells and processes were clearly not associated with the neuropeptide Y- and glucagon-like immunoreactive cells described above. This study has shown that some peptidergic neurons in the peripheral retina have a unique morphology in comparison to more centrally located cells. The function of these specialized peripheral cells is not established, but the innervation of the ciliary epithelium by peptidergic amacrine cells suggests that they may be involved in control of aqueous inflow.

Amygdala-kindled seizures increase the expression of corticotropin-releasing factor (CRF) and CRF-binding protein in GABAergic interneurons of the dentate hilus

Kindling, a model of temporal lobe epilepsy, induces a number of neuropeptides including corticotropin-releasing factor (CRF). CRF itself can produce limbic seizures which resemble kindling in some aspects. However, tolerance to the convulsant effects of CRF develops rapidly. Hypothetically, this could be explained should seizures also induce the CRF-binding protein (CRF-BP), which has been postulated to restrict the actions of CRF. Therefore, in the present study, we used in situ hybridization to examine the effects of amygdala-kindled seizures on the mRNA levels of CRF and CRF-BP. Kindled seizures markedly elevated CRF and CRF-BP in the dentate gyrus of rats. CRF and CRF-BP were induced almost exclusively in GABAergic interneurons of the dentate hilus. The CRF and CRF-BP interneurons also expressed neuropeptide Y but not cholecystokinin. CRF appeared to have an excitatory role in the dentate gyrus as it decreased the afterhyperpolarization of dentate granule neurons. These results suggest that CRF may contribute to the development of amygdala kindling. However, the compensatory induction of CRF-BP may serve to limit the excitatory effects of CRF in the dentate gyrus.

Quantitative anatomy, synaptic connectivity and physiology of amacrine cells with glucagon-like immunoreactivity in the turtle retina

Although a wide variety of neuropeptides have been localized in vertebrate retinas, many questions remain about the function of these peptides and the amacrine cells that contain them. This is because many of these peptidergic amacrine cells have been studied using only immunocylochemical techniques. To address this limitation, the present study used a combination of quantitative anatomy, biochemistry and electrophysiology to examine amacrine cells in the turtle retina that contain the neuropeptide glucagon. In the turtle retina, there is a small population of 2500 glucagonergic amacrine cells, which probably represents < 1% of the total number of amacrine cells. Circular distribution statistics indicated that many of these tristratified amacrine cells had asymmetric dendritic arborizations that were radially oriented toward the retinal periphery. The cells were found to have similar dendritic coverage factors, to be distributed in a non-random arrangement in all regions of the retina, and to peak in density in the visual streak region. Electron microscopic studies indicated that glucagonergic amacrine cells made synaptic contacts primarily with other amacrine cells, and small numbers of bipolar cells. The synaptic inputs and outputs were balanced in the inner strata of the inner plexiform layer, and were biased toward synaptic outputs in the outer strata of the inner plexiform layer. These contacts involved small unlabelled synaptic vesicles, and not the large labelled dense core vesicles also found in these neurons. The biochemical studies indicated that glucagon could be released from the retina in a calcium dependent manner by high potassium stimulation. The electrophysiology found no color opponency, and the glucagonergic amacrine cells gave sustained hyperpolarizing responses to small stimulation spots and had antagonistic surrounds. The results of these studies suggest that there are significant regional specializations of glucagonergic amacrine cells, and that they may provide OFF-modulation in interactions between the ON-and OFF-centre visual pathways in the turtle retina.

Peptidergic transmission: from morphological correlates to functional implications

Like non-peptidergic transmitters, neuropeptides and their receptors display a wide distribution in specific cell types of the nervous system. The peptides are synthesized, typically as part of a larger precursor molecule, on the rough endoplasmic reticulum in the cell body. In the trans-Golgi network, they are sorted to the regulated secretory pathway, packaged into so-called large dense-core vesicles, and concentrated. Large dense-core vesicles are preferentially located at sites distant from active zones of synapses. Exocytosis may occur not only at synaptic specializations in axonal terminals but frequently also at nonsynaptic release sites throughout the neuron. Large dense-core vesicles are distinguished from small, clear synaptic vesicles, which contain "classical' transmitters, by their morphological appearance and, partially, their biochemical composition, the mode of stimulation required for release, the type of calcium channels involved in the exocytotic process, and the time course of recovery after stimulation. The frequently observed "diffuse' release of neuropeptides and their occurrence also in areas distant to release sites is paralleled by the existence of pronounced peptide-peptide receptor mismatches found at the light microscopic and ultrastructural level. Coexistence of neuropeptides with other peptidergic and non-peptidergic substances within the same neuron or even within the same vesicle has been established for numerous neuronal systems. In addition to exerting excitatory and inhibitory transmitter-like effects and modulating the release of other neuroactive substances in the nervous system, several neuropeptides are involved in the regulation of neuronal development.

Interaction between enkephalin and gamma-aminobutyric acid in the chicken retina: a double-label immunoelectron microscopic analysis

In the present study, double-label immunoelectron microscopy was used to examine the synaptic relationships between amacrine cell populations in the chicken retina that contain either enkephalin or gamma-aminobutyric acid (GABA) or both enkephalin and GABA. The objectives of the present study were twofold. First, the ultrastructural features and synaptic organization of enkephalin and enkephalin/GABA amacrine cells were compared. Second, the synaptic interactions between these populations and the population of GABA amacrine cells were examined. A total of 475 synaptic arrangements were observed to involved enkephalin or enkephalin/GABA amacrine cell processes. The synaptic relationships of enkephalin and enkephalin/GABA amacrine cells were quite similar. Each population was pre- and postsynaptic to amacrine cells, postsynaptic to bipolar cells, and presynaptic to processes possibly originating from ganglion cells. A substantial percentage of each population's pre- and postsynaptic relationships were with the processes of GABAergic amacrine cells. Moreover, when enkephalin and enkephalin/GABA amacrine cell processes were postsynaptic to bipolar cells, their dyadic partner was observed frequently to be a GABA amacrine cell process. The present study suggests a diversity in the population of chicken enkephalin amacrine cells with respect to their expression of the classical inhibitory transmitter GABA. Moreover, a functional relationship between enkephalinergic and GABAergic pathways is indicated by studies showing that both enkephalin and enkephalin/GABA amacrine cells exhibit substantial synaptic interaction with GABA amacrine cells.

A triple-label analysis demonstrating that enkephalin-, somatostatin- and neurotensin-like immunoreactivities are expressed by a single population of amacrine cells in the chicken retina

The combined results of previous double-label analyses provide evidence suggesting that the neuroactive peptides, enkephalin, somatostatin and neurotensin are expressed by a single population of amacrine cells in the chicken retina. In the present study, triple-label immunofluorescence histochemistry was used to confirm this relationship. An examination of more than fifteen thousand cells in sections collected from throughout the retina revealed that all labelled cells are immunopositive for endogenous enkephalin-, somatostatin- and neurotensin-like immunoreactivity. Therefore, these results reveal the presence of a single population of chicken amacrine cells, each member of which is characterized by its expression and presumed utilization of all three of these neuroactive peptides. However, the functional implications of the possibility of multiple signalling through these cells remain to be elucidated.

Interaction between enkephalin and GABA in the chicken retina: further analyses of coexisting relationships

Previous studies have indicated an interactive relationship between enkephalin and gamma-aminobutyric acid (GABA) in the vertebrate retina. Among these studies are those that have demonstrated the colocalization of enkephalin and GABA in retinal amacrine cells. In the present study, enkephalin immunocytochemistry was combined with either autoradiography of tritiated GABA high-affinity uptake or GABA immunocytochemistry to further investigate the coexistence of GABA in enkephalin-amacrine cells of the chicken retina. A regional analysis revealed that the percentage colocalization of GABA high-affinity uptake in enkephalin-amacrine cells did not vary appreciably throughout the retina. Overall, 15.2% of enkephalin-amacrine cells exhibited high-affinity GABA uptake. Double-label immunofluorescence histochemistry revealed that 15.1% of enkephalin-amacrine cells express endogenous GABA-like immunoreactivity. These double-labelled cells were observed throughout central and peripheral regions of the retina. In each of the double-label analyses, only less intensely labelled enkephalin-amacrine cells expressed markers of GABA activity. The two double-label analyses reveal almost identical percentages of coexistence of GABA markers in chicken enkephalin-amacrine cells and therefore, provide supportive evidence for the GABAergic nature of these cells. These results suggest a functional diversity in the population of chicken enkephalin-amacrine cells and imply the possibility of multiple signalling through amacrine cells which contain enkephalin and GABA.

Effects of excitatory amino acids on immunocytochemically identified populations of neurons in turtle retina

Excitatory amino acids play an important role in visual processing in the retinas of many species, but little is known about the identity of the specific postsynaptic cell types and the pharmacology of their receptors. To investigate which specific cell types were affected by excitatory amino acids, we examined the effects of exogenous aspartate, glutamate, kainic acid, N-methyl-D-aspartate, and MK-801 on retinal neurons. Specific populations of neurons were labelled using antibodies directed against glucagon, enkephalin, neurotensin, gamma-aminobutyric acid, glutamic acid decarboxylase, serotonin, glycine, glutamate or aspartate. We analyzed a combination of long-term in vivo injections (seven days following an intraocular injection of kainic acid) and short term in vitro incubations. There were changes in the labelling intensity and sometimes in the relative localization of all of the antigens in the drug treated retinas. Some observations suggested that the drugs were altering neurotransmitter metabolism. Differential responses were seen in specific cell types within the populations of neurons with neurotensin-, glutamate-, aspartate-, glycine, gamma-aminobutyric acid-, and glutamic acid decarboxylase-like immunoreactivity. The immunocytochemical approach used in these studies was able to determine specific retinal cell types which were influenced by particular excitatory amino acids. The broad extent of cell types influenced and the potential metabolic effects suggest that excitatory amino acids and their receptors play a complex role in visual processing.