The self-regulating synapse: a functional role for the co-existence of neuroactive substances

Quantitative immunoelectron microscopic colocalization of GABA and enkephalin in the ventrocaudal periaqueductal gray of the rat

In the present ultrastructural study in the ventrocaudal periaqueductal gray (PAG) of the rat, the relationship and the association between GABAergic and enkephalinergic neuronal elements were investigated using postembedding colocalization immunogold electron microscopic technique in order to establish the precise relationship between these two important neurotransmitters in this part of the brain stem. The GABA-like neuronal elements were immunoreacted with 20 nm gold particles and the enkephalin (ENK)-like immunoreactive neurons were labeled with 10 nm gold particles. Double labeling of sections with ENK and GABA produced colocalization in 23.3% and 1.2% of axon terminals and dendrites, respectively. Most of the double-labeled terminals contained more GABA-like than ENK-like immunolabeling. Approximately 19.4% of the labeled axon terminals and 8.5% of the labeled dendrites contained only GABA-like immunoreactivity, while 24% of the immunolabeled dendrites were immunoreactive with only ENK-like immunoreactivity. The synapses between the two kinds of immunolabeled neuronal profiles appear to be both asymmetrical and symmetrical. GABA-like immunolabeled terminals contained small, clear, pleomorphic or round vesicles and were found to make synapses with ENK-like immunolabeled and nonimmunolabeled dendrites, whereas most of the ENK-like immunolabeled axon terminals contained dense-cored vesicles. Approximately half of the axon terminals (51%) and dendrites (56%) in the ventrolateral PAG were not labeled for either GABA or for ENK immunoreactivity. The results are discussed in terms of GABAergic inhibition of antinociceptive mechanisms in the ventrolateral PAG and of the activation of these mechanisms by ENK neurotransmitter.

Preprotachykinin and preproenkephalin mRNA expression within striatal subregions in response to altered serotonin transmission

The effects of lowered serotonin (5-hydroxytryptamine; 5-HT) neurotransmission on preprotachykinin (PPT) and preproenkephalin (PPE) mRNA levels were examined in subregions of the striatum. Adult male rats were treated systemically with para-chlorophenylalanine (pCPA; 350 mg/kg single i.p. injection) which reduced forebrain 5-HT amounts to approximately 20% of saline-injected controls at 24 and 48 h. As measured by Northern analysis, PPT and PPE mRNA levels were elevated 50% and 160% respectively in the anterior ventromedial striatum (region included nucleus accumbens). PPT mRNA levels were raised 90% in posterior striatum (at the level of the globus pallidus) by 48 h post-pCPA injection. To determine if increased PPT and PPE mRNA levels represented a transient response to brief 5-HT inhibition, additional experiments were performed to provide continual suppression of 5-HT within the striatum. First, rats received daily intraperitoneal injections of saline or the 5-HT1A receptor agonist, 8-OH-DPAT (1 mg/kg), for 7 days to reduce 5-HT release from raphestriatal terminals. In a parallel experiment, the serotonin neurotoxin, 5,7-dihydroxytryptamine (5,7-DHT, 5 micrograms), was stereotaxically injected into the striatum as a means to permanently remove 5-HT terminals. Although levels of each mRNA species were differentially sensitive to 5,7-DHT or 8-OH-DPAT, PPT and PPE mRNAs were lowered between 30-55% within the anterior dorsolateral and ventromedial striatum. Although these results support previous studies suggesting an overall positive regulatory role of serotonin on striatal tachykinin biosynthesis, PPT and PPE gene regulation in certain striatal subregions may by differentially sensitive to lowered 5-HT neurotransmission. This suggestion is supported by observations that acute systemic stimulation of 5-HT2A/C receptors with DOI (7 mg/kg single i.p. injection) raised PPT and PPE mRNA levels within anterior dorsolateral (30-60%) and posterior (100-200%) striata, but not within the anterior ventromedial striatum.

Influence of neuropeptides on the processes of higher nervous activity in primates. The action of cyclic analogs of enkephalins on the behavior of the lower monkeys

The effect of two cyclic enkephalin analogs (IVS-43 and IVS-46) on the group and individual behavior of rhesus macaques and hamadryas baboons has been studied. A pronounced influence of IVS-46 on competitive and operant goal-directed behavior of the monkeys was identified.

Ultrastructural relationships between terminals immunoreactive for enkephalin, GABA, or both transmitters in the rat ventral tegmental area

The ventral tegmental area (VTA) receives extensive afferent input from neurons containing the opioid peptide enkephalin (Enk) and/or GABA. We examined the ultrastructural basis for known functional interactions between these inhibitory neuromodulators using a combined immunoperoxidase and immunogold-silver technique. As visualized with either marker in single sections, Enk-immunolabeled terminals contained numerous small clear vesicles and one or more intensely immunoreactive dense-cored vesicles. Enk-labeled terminals formed either symmetric or asymmetric synapses on small or large unlabeled dendrites. The immunoreactive dense-cored vesicles were usually detected away from these sites of synaptic contact. Terminals singly immunoreactive for GABA, or dually labeled for Enk and GABA, showed similar morphological features but formed primarily symmetric axo-dendritic synapses. In many instances, GABA- and/or Enk-immunolabeled terminals were in direct apposition to each other and formed synapses on immediately adjacent parts of a common dendrite. Close appositions were also noted between GABA- and Enk-immunoreactive axons and varicosities that did not form synapses with either common or divergent dendrites in single sections. Immunoreactive dense-cored vesicles were frequently detected at the apposed plasmalemmal surfaces between these axon terminals. The findings suggest that Enk and GABA are released from the same or convergent terminals and co-regulate the activity of common target neurons within the rat VTA. The results are also consistent with potential presynaptic interactions between these transmitters.

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.

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

The large number of amacrine cells which contain gamma-aminobutyric acid (GABA) in the turtle retina makes it difficult to examine specific GABAergic cell types. In order to selectively label subpopulations of GABAergic neurons, we have used fluorescent double-labeling immunocytochemical techniques to examine the localization of GABA-like immunoreactivity (LI) in amacrine cells which contain antigens resembling the neuropeptides glucagon (GLUC), corticotropin-releasing factor (CRF) or enkephalin (ENK). GABA-LI was found in 41% of the cells with GLUC-, 100% of the cells with CRF-, and 69% of the cells with ENK-LI. There were regional differences in the presence of GABA-LI in amacrine cell populations with ENK-LI. GABA-LI was present in about 80% of the cells with ENK-LI outside of the visual streak, while only 37% of the cells within the streak had GABA-LI. Based on the distinct morphologies and regional distributions of these peptidergic amacrine cells, we conclude that they represent different subpopulations of GABAergic amacrine cells in the turtle retina. Future studies can now utilize existing information regarding the synaptic connectivity of these peptidergic amacrine cells to help delineate the functions of GABAergic amacrine cells in the turtle retina.

Cellular basis for interactions between catecholaminergic afferents and neurons containing leu-enkephalin-like immunoreactivity in rat caudate-putamen nuclei

Dopaminergic afferents to the dorsal striatum, caudate-putamen nuclei, are known to modulate the levels and synthesis of endogenous opiate peptides (Leu5 and Met5-enkephalins). We examined the dual immunocytochemical localization of antisera raised against Leu5-enkephalin and the catecholamine-synthesizing enzyme, tyrosine hydroxylase (TH), to determine the cellular substrates for these and/or other functional interactions. The antisera were identified by combined immunogold-silver and immunoperoxidase labeling in single coronal sections through the caudate-putamen nuclei of adult rats. These animals were given intraventricular injections of colchicine, and the brains were fixed by acrolein perfusion prior to immunocytochemical labeling. By light microscopy, perikarya and processes containing enkephalin-like immunoreactivity (ELI) were seen in close proximity to varicose processes immunoreactive for TH. Electron microscopy further demonstrated that the ELI was localized to perikarya, dendrites, and axon terminals, whereas the TH was exclusively in axons and terminals. The dendrites containing ELI were postsynaptic to terminals that were either (1) without detectable immunoreactivity, or (2) immunoreactive for TH or enkephalin. Nonsynaptic portions of the dendrites containing ELI were covered with astrocytic processes or were in direct apposition to unlabeled dendrites. Terminals containing ELI were densely immunoreactive and were in direct contact with (1) unlabeled and occasionally enkephalin-labeled proximal dendrites, and (2) TH-labeled and unlabeled terminals. In comparison with the opiate terminals, most catecholaminergic terminals were lightly immunoreactive for TH and usually contacted more distal unlabeled dendrites or spines and, more rarely, dendrites containing ELI. In a few favorable planes of section, the terminals containing ELI and those containing TH (1) converged on common unlabeled dendrites, or (2) formed dual contacts on two different labeled or unlabeled targets. Junctions formed by terminals containing ELI and TH were sometimes characterized by symmetric synaptic densities. However, numerous other dendritic and all axonal appositions were without recognized membrane densities. The findings of the study provide anatomical substrates for multilevel interactions between catecholamines, mostly dopamine, and enkephalin in rat dorsal striatum. These include (1) monosynaptic input from dopaminergic terminals to neurons containing enkephalin, (2) presynaptic modulation of transmitter release through axonal appositions, and (3) dual regulation of common targets through convergent input. In addition, the findings suggest that both enkephalin and dopamine may have similar modulatory roles in synchronizing the activity of dual targets postsynaptic to individual axon terminals. Alterations in any one of these multiple types of interactions could account for noted motor or sensory symptoms in neurological disorders characterized by depletion of dopamine or endogenous opiate peptides, or both.

Glycinergic control of [Leu5]enkephalin levels in chicken retina

Retinal levels of [Leu5]enkephalin-like immunoreactivity (LE-LI) increase during the light and decrease during darkness, in vivo15. Intravitreal injection of the GABA antagonist picrotoxin had no effect on the accumulation of LE-LI during the light, suggesting the absence of significant GABAergic control over LE-LI cells. However, injection of the glycine antagonist strychnine, prevented the light-induced increase of retinal levels of LE-LI during 6 h exposure to light, indicating the presence of glycinergic control over the LE-LI neurons. When applied during the dark, strychnine increased the depletion of LE-LI by 34% compared to vehicle-injected eyes, suggesting that the LE-LI neurons receive some glycinergic input during the dark as well. The release of LE-LI from retinas superfused in vitro is depressed by exposing the preparation to light. Superfusing isolated retinas with physiological buffer containing picrotoxin (100 microM), GABA (50 mM), or the GABA agonists muscimol (100 microM), (+)-baclofen (200 microM), or 4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol (THIP) (100 mM), had no effect on the efflux of LE-LI. Strychnine (100 mM) however increased the efflux of LE-LI by 64%, compared to the spontaneous efflux during the light. Glycine (15 and 50 mM) decreased the spontaneous efflux of LE-LI from retinas superfused in darkness by 44-48% and by 31% at 5 mM. These data are consistent with the results from pharmacological manipulations in vivo. We conclude that the LE-LI amacrine cells are under inhibitory control from glycinergic but not from GABAergic neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

A re-examination of enkephalin's coexistence with gamma-aminobutyric acid in amacrine cells of the larval tiger salamander retina

Double-label immunocytochemistry was utilized to re-examine the colocalization of enkephalin and gamma-aminobutyric acid (GABA) in amacrine cells of the larval tiger salamander retina. A total of 465 enkephalin-immunoreactive amacrine cells were identified and in all cases these cells were GABA-immunoreactive. This finding corroborates a previous study that showed greater than 96% of enkephalin-amacrine cells in the tiger salamander retina to specifically accumulate [3H]GABA and provides additional evidence for the GABAergic nature of these enkephalin-amacrine cells.

Contribution of brainstem GABAergic circuitry to descending antinociceptive controls: II. Electron microscopic immunocytochemical evidence of GABAergic control over the projection from the periaqueductal gray to the nucleus raphe magnus in the rat

Pharmacological, physiological, and behavioral studies suggest that inhibitory GABAergic neurons influence the projection from the midbrain periaqueductal gray matter to the medullary nucleus raphe magnus. The present study used electron microscopic immunocytochemical techniques to examine the morphology and synaptic relationships of GABA-immunoreactive terminals in the ventrolateral periaqueductal gray. These putative GABAergic terminals comprise almost 40% of all axon terminals in the periaqueductal gray. GABA-immunoreactive terminals contain small, clear, pleomorphic or round, vesicles, and 46% also contain some dense-cored vesicles. In some experiments we also used a colloidal gold-conjugated retrograde tracer to label periaqueductal gray neurons that project to the nucleus raphe magnus. About half of the synaptic inputs onto the cell bodies and proximal dendrites of retrogradely labeled neurons are GABA-immunoreactive; these putative GABAergic synapses, which directly control activity in neurons projecting from the periaqueductal gray to the nucleus raphe magnus, might mediate the antinociception-related effects of exogenous GABAA receptor ligands.

Synaptic organization of neurotensin immunoreactive amacrine cells in the chicken retina

Immunohistochemistry was utilized to investigate the light and electron microscopic localization of neurotensinlike immunoreactive (NT) amacrine cells in the chicken retina. The NT cells possess oval cell bodies (7 microns in diameter) that are located in either the second or third tier of cells from the border of the inner nuclear and inner plexiform layers. The processes of such cells extend into the inner plexiform layer where they ramify as a narrow plexus in sublamina 1 and as a broad plexus in sublaminas 3 and 4. Additionally, stained processes are observed occasionally within sublamina 5. At the ultrastructural level, NT-positive somas exhibit a rather dense and evenly distributed peroxidase reaction product throughout their cytoplasm. The nucleus of NT amacrine cells possess a round, unindented nuclear membrane. NT-immunoreactive processes in the inner plexiform layer interact synaptically only with non-NT cells. NT processes receive synaptic input mainly from the processes of amacrine cells and to a lesser degree from bipolar cells. The large majority of NT-stained varicosities form presynaptic contacts onto the processes of amacrine cells, but are also presynaptic to bipolar cell axon terminals. Moreover, each of the above synaptic relationships can be identified in each of sublaminas 1 and 3 to 4 of the inner plexiform layer. In addition, NT processes are presynaptic to processes devoid of synaptic vesicles that may originate from ganglion cells. Finally, NT processes occasionally form synaptic contacts onto somas situated in the most proximal row of the inner nuclear layer.

GABA-like immunoreactivity of neurons in the chicken diencephalon and mesencephalon

The chick brain is a useful model system for studying the ontogeny and phylogeny of neural circuitry, especially that of the visual system. In this study the distribution of cells and processes showing GABA-like immunoreactivity (GABA+) in the diencephalon and mesencephalon of the posthatch chick was determined immunohistochemically with a polyclonal antibody to GABA and compared with the results of similar studies in mammals. Most of the small GABA+ cells were found in the chick visual centers such as the nucleus lateralis anterior, suprachiasmatic nucleus, ventral lateral geniculate, optic tract, dorsolateralis anterior pars lateralis, lentiformis mesencephali, ectomammillary nucleus, area pretectalis, and the optic tectum. Large GABA+ cells were found in the following nuclei: reticularis superior, posteroventralis thalami, subpretectalis, isthmi pars magnocellularis, interstitio-pretectosubpretectalis, mesencephalicus lateralis pars dorsalis. These large cell-containing nuclei receive projections from visual or auditory centers. GABA+ axons were found throughout the diencephalon and mesencephalon but were especially prominent in the ansa lenticularis, fasciculus medialis longitudinalis, and optic tract. The distribution of GABA+ cells in the chick is more widespread than in rodents and exhibits an increased association with the visual centers suggesting a correlation with the specialized visual requirements of the bird.

Synaptic connections in the buccal ganglia of Aplysia mediated by an identified neuron containing a CCK/gastrin-like peptide co-localized with acetylcholine

The identified neuron, B13, located bilaterally in the buccal ganglion of the marine mollusc Aplysia californica, contains a classical neurotransmitter (acetylcholine) and a cholecystokinin/gastrin-like (CCK/G-li) peptide. The following study demonstrates that B13 makes direct synaptic connections with several identifiable postsynaptic follower neurons. These follower neurons also receive convergent input from previously identified cholinergic neurons, B4 and B5, which do not contain a CCK/G-li peptide. The cholinergic responses mediated by B4/B5 and B13 are similar, including in at least one buccal follower, a two-component inhibitory response not seen in previous studies of the buccal ganglia circuits. However, when the cholinergic responses are blocked by appropriate antagonists, a residual, slow depolarizing, chemically-mediated response is observed in two of the identifiable followers when action potentials are evoked in B13 but not when action potentials are evoked in B4 or B5.

Enkephalin-like immunoreactivity in the cat superior colliculus: distribution, ultrastructure, and colocalization with GABA

The distribution of enkephalin (ENK) immunoreactivity has been examined in the cat superior colliculus (SC) by means of light and electron microscope immunocytochemistry. The antisera were directed against leucine enkephalin but also recognized methionine enkephalin. Colocalization of ENK with gamma aminobutyric acid (GABA) was studied with a two-chromagen double-labeling technique. Enkephalin antiserum labeling was highly specific. Dense neuropil labeling was found only in a thin band 75-100 microns wide within the upper superficial gray layer of SC. Negligible neuropil labeling was seen deeper, except for patches of label within the intermediate gray layer. Intensely labeled neurons also had a specific distribution. Forty-seven percent were located within the upper 200 microns of SC, 40% within the deep superficial gray layer, 11% in the optic layer, and only 2% below that layer. Almost all ENK-labeled cells were small (mean area of 117 microns2). Some of these had horizontal fusiform cell bodies and horizontally oriented dendrites. Others had small round somata and thin, obliquely oriented dendrites. In double-labeling experiments, 18% of anti-ENK-labeled cells were also immunoreactive for GABA. Four distinct types of ENK-labeled profile were identified with the electron microscope. Presynaptic dendrites (PSD) with loose accumulations of synaptic vesicles were densely labeled with the antiserum. Conventional dendrites were also labeled. Both types of labeled profile received input from unlabeled synaptic terminals, including those from the retina that contained pale mitochondria and round synaptic vesicles and formed asymmetric synaptic contacts. Retinal terminals were never labeled with the antisera. However, some axon terminals with round synaptic vesicles, dark mitochondria, and symmetric synaptic densities were labeled by the antisera, as were some thinly myelinated axons. These results show that there is a small population of enkephalinergic neurons in the cat SC, some of which also contain GABA. Because not all cells with identical morphologies were double labeled, it appears that neurons of like morphology are chemically heterogeneous.

Augmentation of natural cytotoxicity by leucine enkephalin in cultured peripheral blood mononuclear cells from patients infected with human immunodeficiency virus

Natural Killer (NK) activity of lymphocytes from acquired immunodeficiency syndrome (AIDS) patients is frequently below normal and declines as disease progresses. We studied the potential of leucine enkephalin (leu-enkephalin) to restore this immune parameter by incubating nylon wool nonadherent mononuclear cells from 14 patients in the presence or absence of leu-enkephalin, and measuring NK cytolysis in a standard 51Cr release assay. The NK activity of human immunodeficiency virus antibody positive (HIV+) individuals with some remaining NK lytic ability was significantly augmented by leu-enkephalin concentrations of 10(-10) and 10(-8) M (n = 7). HIV+ patients with no measurable basal level of NK activity (n = 3) were not responsive to stimulation with leu-enkephalin. Human immunodeficiency virus antibody negative (HIV-) individuals (n = 4) responded in a pattern similar to normals. In addition, naloxone, an antagonist of alkaloid and peptide opiates including leu-enkephalin, displayed the properties of an antagonist/agonist, reflecting the immunoregulatory capacities of the endogenous opiate system.

Synaptic organization of enkephalinlike-immunoreactive amacrine cells in the goldfish retina

Immunoelectron microscopy was used to examine the synaptic organization of enkephalinlike-immunoreactive amacrine cells in the goldfish retina. Enkephalin-immunostained processes sometimes contained dense-cored vesicles (115-145 nm) in addition to a generally homogeneous population of small, round, clear synaptic vesicles. A total of 194 synaptic relationships were observed that involved the immunostained processes of enkephalin-amacrine cells. The large majority of these were observed in sublayer 5 of the inner plexiform layer. In greater than 95% of the synaptic relationships, the enkephalin-immunostained profile served as the presynaptic element. In 58.8% of these relationships, enkephalin processes synapsed onto amacrine cell processes, while 30.4% of their synapses were onto processes that lacked synaptic vesicles. They also occasionally formed synaptic contacts (6.7%) onto the somas of cells located either in the inner nuclear or in the ganglion cell layers. Enkephalin profiles received synaptic input only from amacrine cells (4.1%), while no direct synaptic interaction was observed between enkephalin processes and bipolar cells. However, in sublayer 1, enkephalin profiles were found to synapse onto amacrine cell processes that were presynaptic to bipolar cell terminals. In the proximal inner plexiform layer, enkephalin processes were presynaptic to amacrine cell processes that as a group surrounded and sometimes provided synaptic input to extremely large and round bipolar cell endings.

Amacrine cells in the retina of a teleost fish, the roach (Rutilus rutilus): a Golgi study on differentiation and layering

We studied 250 amacrine cells in the retina of the tetrachromatic cyprinid Rutilus rutilus (roach) after rapid Golgi impregnation. All cells were recorded in camera lucida drawings from 50 -80 μm sections. For classifications we used independent criteria of presumed functional relevance, most of which could be quantified. These included ‘gross morphological’ features such as size, symmetry and orientation of the dendritic field, pattern of branching and number of ramification points as well as fine structural details like process diameter and the occurrence of spines and varicosities. We also took into account the pattern of radial distribution of dendrites. To obtain information about the subdivision of the inner plexiform layer, we used the relative stratification levels of stratified amacrine cells to plot a frequency distribution diagram showing that the dendrites of these cells are clustered in seven discrete sublayers of unequal width; four sublayers occupy the distal half of the inner plexiform layer (sublamina a) and three sublayers are present in the proximal half (sublamina b). The subdivision was compared with densitometric data of the inner plexiform layer after various staining methods and with previous observations about the location of bipolar terminals and neurochemical bandings. Our findings suggest that this layer is composed of complementary structural components, each of which is subject to a specific layering pattern. On this basis we could distinguish 43 different types of amacrine cell. If individual types occurred in more than one sublayer, they were considered as subtypes; of these, we found 70 different ones. Among the 43 types, 6 were observed only once. In comparison with amacrine cells described in other species, six ‘new’ types were identified. For each individual type, an identity chart was prepared summarizing camera lucida drawings of tangential views at low and high magnification, a semischematical drawing of the radial location of the dendrites, and the most relevant quantitative data. Our observations are discussed in the context of available evidence about light-evoked responses of identified amacrine types in other species, and possible transmitter content. They substantiate a functional concept according to which amacrine cells provide (i) a multicellular aggregate for coupled membrane potential; (ii) unit activity by the action of entire individual cells; and (iii) local microcircuits caused by isolated activation of single dendrites or parts thereof. The great variety of morphological differentiation, and the numerous transmitters found, suggest that within this basic framework individual amacrine types serve highly complex and sophisticated roles in retinal information processing. Our attempt towards a detailed classification and description of amacrine cell types is intended to provide a reference for future intracellular and neurochemical work, to facilitate precise identification.

The coexistence of three neuroactive substances in amacrine cells of the chicken retina

For the first time in the vertebrate retina, we have demonstrated that 3 neuroactive substances coexist in a single neuron. Using immunofluorescence, immunoperoxidase, and autoradiographic techniques, we found a subpopulation of amacrine cells in the chicken retina exhibited enkephalin- and neurotensin-like immunoreactivity and high-affinity uptake of glycine. Biochemical evidence showed that glycine release in this retina is inhibited by enkephalin and enhanced by neurotensin1.14. It is therefore possible that the two peptides form a push-pull system in self-regulating the glycine release from retinal amacrine cells.

Colocalization of substance P and gamma-aminobutyric acid in amacrine cells of the cat retina

Substance P and gamma-aminobutyric acid (GABA) were colocalized by immunocytochemistry in two subpopulations of amacrine cells in the cat retina. All of the cells which stained for substance P also showed GABA reactivity. However, there were many GABA-immunoreactive cells which did not stain for substance P. The presence of neuropeptides provides a basis for additional neurochemical characterization of the multiple populations of GABA immunoreactive cells.

Quantitative studies of enkephalin's coexistence with gamma-aminobutyric acid, glycine and neurotensin in amacrine cells of the chicken retina

Previous double-label studies demonstrate that enkephalin coexists with gamma-aminobutyric acid, glycine or neurotensin in amacrine cells of the chicken retina. The present study utilizes double- and triple-label paradigms to quantitatively analyze these coexisting relationships. Twenty-eight percent of enkephalin-like immunoreactive amacrine cells were found to exhibit high-affinity uptake of [3H]GABA, while 53% of enkephalin-amacrine cells specifically accumulate [3H]glycine. Moreover, the present study predicts that at least 26% of enkephalin-amacrine cells which accumulate [3H]glycine should also be immunoreactive for neurotensin.

Interaction between enkephalin and dopamine in the avian retina

Biochemical and pharmacological techniques were utilized to investigate the interaction between the enkephalinergic and dopaminergic systems in the chicken retina. Exogenously applied enkephalin and its analogues were observed to inhibit the release of preloaded dopamine from the retina. This inhibition was concentration-dependent and was suppressed by the opiate antagonist, naloxone. The relationship between enkephalinergic and dopaminergic amacrine cells was studied in retinas which were subjected to 6-hydroxydopamine (6-OHDA) treatments. 6-OHDA degenerated approximately 80-90% of those cells which exhibit high affinity uptake of [3H]dopamine. In 6-OHDA-treated retinas, the capacity of 3H-labelled [D-Ala2]methionine enkephalinamide to bind specifically to opiate receptors was substantially reduced (only 70-75% of the control). Scatchard analyses and ligand displacement studies indicated that this decrease in binding was due to a reduction in the number of opiate receptors. Taken together, these observations strongly indicate that a fraction of the opiate receptors in the chicken retina (25-30%) are closely associated with the population of dopaminergic amacrine cells.

Interactions between enkephalin and gamma-aminobutyric acid in the larval tiger salamander retina

Both double-label and intracellular electrophysiological recording techniques were utilized to investigate the interactions between enkephalin and gamma-aminobutyric acid in the larval tiger salamander retina. Double-label studies revealed that the vast majority (greater than 96%) of enkephalin-immunostained amacrine cells also exhibit high affinity uptake of [3H]gamma-aminobutyric acid. Electrophysiological evidence demonstrated that morphine and gamma-aminobutyric acid exert opposite effects on a population of On-Off ganglion cells. gamma-Aminobutyric acid decreased the activity of these cells, while enkephalin increased their activity. These findings support the idea that opiate-mediated pathways inhibit GABAergic pathways in the vertebrate retina.