Peptide-containing neurons in the chicken retina

Correlation between small-scale methylation changes and gene expression during the development of myopia

Visually induced changes in the expression of early growth response-1 (EGR1), FBJ osteosarcoma oncogene (FOS), and NGFI-A binding protein-2 (NAB2) appear to form a part of a retinal network fundamental to ocular growth regulation, and thus, the development of myopia (short-sightedness). However, it is unclear how environmental (visual) cues are translated into these molecular changes. One possibility is through epigenetic modifications such as DNA methylation, a known regulator of such processes. By sequencing bisulfite-converted DNA amplicons, this study examined whether changes in DNA methylation occur within specific regulatory and promoter regions of EGR1, FOS, and NAB2 during the periods of increased and decreased ocular growth in chicks. Visually induced changes in ocular growth rates were associated with single-point, but not large-scale, shifts in methylation levels within the investigated regions. Analysis of methylation pattern variability (entropy) demonstrated that the observed methylation changes are occurring within small subpopulations of retinal cells. This concurs with previous observations that EGR1 and FOS are differentially regulated at the peptide level within specific retinal cell types. Together, the findings of this study support a potential role for DNA methylation in the translation of external visual cues into molecular changes critical for ocular growth regulation and myopia development.

Characterization of glucagon-expressing neurons in the chicken retina

We recently identified large glucagon-expressing neurons that densely ramify neurites in the peripheral edge of the retina and regulate the proliferation of progenitors in the circumferential marginal zone (CMZ) of the postnatal chicken eye (Fischer et al. [2005] J Neurosci 25:10157-10166). However, nothing is known about the transmitters and proteins that are expressed by the glucagon-expressing neurons in the avian retina. We used antibodies to cell-distinguishing markers to better characterize the different types of glucagon-expressing neurons. We found that the large glucagon-expressing neurons were immunoreactive for substance P, neurofilament, Pax6, AP2alpha, HuD, calretinin, trkB, and trkC. Colocalization of glucagon and substance P in the large glucagon-expressing neurons indicates that these cells are the "bullwhip cells" that have been briefly described by Ehrlich et al. ([1987] J Comp Neurol 266:220-233). Similar to the bullwhip cells, the conventional glucagon-expressing amacrine cells were immunoreactive for calretinin, HuD, Pax6, and AP2alpha. Unlike bullwhip cells, the conventional glucagon-expressing amacrine cells were immunoreactive for GABA. While glucagon-immunoreactive amacrine cells were negative for substance P in central regions of the retina, a subset of this type of amacrine cell was immunoreactive for substance P in far peripheral regions of the retina. An additional type of glucagon/substance P-expressing neuron, resembling the bullwhip cells, was found in far peripheral and dorsal regions of the retina. Based on morphology, distribution within the retina, and histological markers, we conclude that there may be four different types of glucagon-expressing neurons in the avian retina.

Glucagon-expressing neurons within the retina regulate the proliferation of neural progenitors in the circumferential marginal zone of the avian eye

Glucagon-expressing retinal amacrine cells have been implicated in regulating postnatal ocular growth. Furthermore, experimentally accelerated rates of ocular growth increase the number of neurons added to the peripheral edge of the retina. Accordingly, we assayed whether glucagon-expressing neurons within the retina regulate the proliferation of progenitors in the circumferential marginal zone (CMZ) of the postnatal chicken eye. We found that glucagon-containing neurites are heavily clustered within the CMZ at the peripheral edge of the retina. Many of these neurites originate from a cell type that is distinct from other types of retinal neurons, which we termed large glucagon-expressing neurons (LGENs). The LGENs are immunoreactive for glucagon and glucagon-like peptide 1 (GLP1), have a unipolar morphology, produce an axon that projects into the CMZ, and are found only in ventral regions of the retina. In dorsal regions of the retina, a smaller version of the LGENs densely ramifies neurites in the CMZ. Intraocular injections of glucagon or GLP1 suppressed the proliferation of progenitors in the CMZ, whereas a glucagon-receptor antagonist promoted proliferation. In addition, we found that glucagon, GLP1, and glucagon antagonist influenced the number of progenitors in the CMZ. We conclude that the LGENs may convey visual information to the CMZ to control the addition of new cells to the edge of the retina. We propose that glucagon/GLP1 released from LGENs acts in opposition to insulin (or insulin-like growth factor) to regulate precisely the proliferation of retinal progenitors in the CMZ.

Expression of angiotensin-converting enzyme (ACE) in the developing chicken retina

Angiotensin-converting enzyme (ACE) performs two contrasting enzymatic effects: as part of the renin-angiotensin system it converts angiotensin I into physiologically active angiotensin II, and it inactivates a number of peptides, e.g. substance P. These peptides are well known neurotransmitters in the retina and recently angiotensin II was described in retinal neurons. We therefore investigated a possible involvement of ACE in retinal metabolism by determining the mRNA and protein expression of ACE in the developing and mature chicken retina. ACE-mRNA expression was investigated by RT-PCR in the iris/ciliary body, the choroid, the optic nerve head, pecten, and the retina. Levels of ACE-mRNA were quantified by competitive PCR with heterologous competitor fragments in the retina at different developmental stages. To localize protein expression of ACE in the mature chicken retina an antibody directed against ACE was used. ACE-mRNA was present in all ocular tissues examined. Quantification of ACE-mRNA in avascular retinas of developing chickens revealed small amounts (0.13 attomol microl(-1)) at embryonic day 7 and values of about 0.6 attomol microl(-1)during embryonic days 7-17. ACE-mRNA expression transiently increased ten-fold (7.3 attomol microl(-1)) on postnatal day 1, decreased again to about 1.4 attomol microl(-1)on postnatal day 6, and remained constant thereafter. ACE-immunohistochemistry revealed labeling of photoreceptors, bipolar cells, amacrine cells, and cells in the ganglion cell layer as well as of Müller glia. Our data show that ACE-mRNA is an intrinsic component of the retina and that ACE itself has a widespread but distinct cellular distribution. The transient high expression of ACE-mRNA directly after hatching indicate, that ACE may be involved in fine tuning the neuropeptidergic equipment of the retinal network during the initial phase of visual experience.

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.

Immunohistochemical localization of neuropeptide Y and somatostatin in human fetal retina

The localization of neuropeptide Y and somatostatin in the retina of six prenatal human specimens was determined by the utilization of light microscopic immunoperoxidase and immunofluorescence methods. The age of the prenatal fetuses ranged from 15 to 40 weeks of gestation. At 15 weeks, round or pear-shaped neuropeptide Y-immunopositive cells were observed in the inner nuclear layer and somatostatin immunoreactivity was only detected in the ganglion cell layer. Positive neuropeptide Y ganglion cells were observed by 17 weeks of gestation and by 28 weeks neuropeptide Y-immunopositive cells were demonstrated in the ganglion cell layer and inner nuclear layer. At 26-28 weeks, neuropeptide Y-immunopositive cells exhibited approximately the same shape as at 15 weeks of gestation, but the appearance of one or two processes was detected extending from the somata. By 38-40 weeks of gestation, neuropeptide Y-immunopositive cells were detected in the ganglion cell layer, inner nuclear layer and an immunopositive fibrous configuration in the inner plexiform layer. During this same period (38-40 weeks), somatostatin-positive cells were located in the ganglion cell layer, inner nuclear layer and the inner segments layers. Due to the difficulty of obtaining fetal materials, the exact time of initiation in the expression of neuropeptide Y and somatostatin is presently hard to delineate; however, it is safe to state that the peptides appear early in development.

Endogenous dopamine inhibits the release of enkephalin-like immunoreactivity from amacrine cells of the chicken retina in the light

The activity of the enkephalin-immunoreactive (ENSLI) amacrine cells of the chicken retina is low in the light and high in the dark, resulting in parallel increases and decreases in the levels of the enkephalins. In vivo, the selective dopaminergic D1 antagonist SCH23390 increased the activity of the ENSLI amacrine cells in the light (ED50; 20 pmol), but had a much lesser effect in the dark, whereas the selective dopaminergic D2 antagonist sulpiride had effects only at very high concentrations (ED50; 39 nmol). In contrast, the non-selective dopamine agonist ADTN hardly affected the activity of the ENSLI amacrine cells in the light, but markedly reduced their activity in the dark. This pattern of effects suggests that dopamine actively inhibits the ENSLI amacrine cells in the light, but exerts much less inhibitory activity in the dark, consistent with the idea that dopamine is released during the exposure of the retina to light. Thus dopaminergic controls over the ENSLI amacrine cells appear to contribute to the light:dark differences in activity of the ENSLI amacrine cells. Results obtained on the dopaminergic control of enkephalin release in vitro were generally consistent with this model, except that ADTN appeared to stimulate the ENSLI amacrine cells in the dark.

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.

[Leu5]enkephalin-like immunoreactive amacrine cells are under nicotinic excitatory control during darkness in chicken retina

Based on the principle that retinal levels of [Leu5]enkephalin-like immunoreactivity (LELI) are set by the rate of release and thus reflect neural activity, we partially defined the dark-associated increase in excitatory control of LELI amacrine cells in chicken. Retinal levels of LELI were measured by radioimmunoassay (RIA). Intravitreal injection of cholinergic antagonists decreased the rate of depletion of LELI during the dark phase, suggesting the presence of cholinergic excitatory control of the LELI neurons. This cholinergic control involves nicotinic rather than muscarinic receptors, as tubocurarine appeared over 100 times more effective than atropine in inhibiting the decrease in retinal levels of LELI in the dark. (The ED50s were estimated at 3.2 and 450 nmol, respectively.) The lack of effect of the antagonists when applied during the light phase, suggest that there is little cholinergic input to the LELI amacrine cells in the light. Superfusing isolated retinas with buffer containing tubocurarine (10 microM) decreased the efflux of LELI by 35%, compared to the spontaneous release during the dark. Atropine (10 microM) had no effect on the release of LELI, and pilocarpine (100 microM) increased the release of LELI from retinas superfused in the light by 20%. We conclude that, in addition to previously reported glycinergic and dopaminergic inhibition, the LELI amacrine cells receive cholinergic excitatory input. A shift in balance between glycinergic and dopaminergic inhibitory, and cholinergic excitatory control may underly the light-driven variation in activity of the LELI neurons in chicken retina.

Different relative abundance of neurotensin and neuromedin N in bovine ocular tissues

Neurotensin (NT) and neuromedin N (NN) are regulatory peptides encoded by the same gene and located in tandem within a common precursor. Using specific radioimmunoassays for both peptides, their relative abundance in extracts of bovine ocular tissues has been examined. Within the retina, the molar concentration of NN was significantly higher (P less than 0.001) than that of NT. In contrast, within both choroid/sclera and iris/ciliary bodies, the molar concentration of NT was significantly higher (P less than 0.001) than that of NN. These data demonstrate that the theoretical molar ratio of 1:1, which would result from complete processing of both peptides from the common precursor, does not occur in any of the ocular tissues examined. Reverse phase HPLC of extracts of each ocular tissue confirmed the differential abundance of NT and NN. These data would suggest that the common NT/NN precursor is differentially-processed within bovine ocular tissues, a finding which may be of physiological significance.

A double-label analysis demonstrating that all enkephalin-immunoreactive amacrine cells in the chicken retina express neurotensin immunoreactivity

A previous study demonstrated less than 50% co-existence between the populations of enkephalin- and neurotensin-like immunoreactive amacrine cells in the chicken retina. The present study was undertaken with the intent of re-examining this relationship using a more sensitive double-label paradigm. An examination of retinal cryosections collected throughout the retina revealed that all labelled cells express both enkephalin and neurotensin-like immunoreactivity. Therefore, these results indicate the presence of a single population of chicken amacrine cells the members of which express both these neuropeptides.

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)

Coexistence of somatostatin and neurotensin in amacrine cells of the chicken retina

A comparison of previous immunocytochemical studies reveals a striking similarity in the morphologies of the populations of somatostatin-like and neurotensin-like immunoreactive amacrine cells in the chicken retina. A double-label analysis was performed to determine if these two neuroactive peptides coexist in chicken amacrine cells. An examination of retinal cryosections collected throughout the retina revealed that all labelled cells express both somatostatin- and neurotensin-like immunoreactivity. Therefore, these results indicate the presence of a single population of chicken amacrine cells whose members contain both of these neuroactive peptides.

Transient expression of somatostatin receptors in the rat visual system during development

The ontogeny of somatostatin receptors in the rat visual system was studied by auto-radiography, using [125I-Tyr0,DTrp8]S14 as a radioligand. The binding sites showed high affinity for somatostatin and somatostatin analogues, and were regulated by GTP as early as day 16 of fetal life (E16), indicating that they represent functional somatostatin receptors. The density of somatostatin receptors was quantified by computerized image-analysis of film autoradiograms, and by grain counting on emulsion-coated slides. During fetal life, somatostatin receptors were observed in the retina, optic nerve, optic chiasma, optic tract, and lateral geniculate nucleus. The highest densities of somatostatin receptors were measured from E16 to E18 in the retina and primary optic pathways. During the first postnatal days, the density of somatostatin receptors decreased dramatically in the retina. In both the optic pathways and dorsal lateral geniculate nucleus, somatostatin receptors gradually disappeared, and the levels of somatostatin receptors were almost undetectable at postnatal day 21 (P21). Conversely, the density of somatostatin receptors remained stable in the ventral lateral geniculate nucleus during the early postnatal life (P0-P7). The timing of expression and the localization of somatostatin receptors in the developing visual system suggest that the immature ganglion cells are responsible for the expression of these evanescent somatostatin receptors. After eye opening, the distribution patterns of somatostatin receptors in the retina and the lateral geniculate nucleus were similar to those observed in adults. In particular, from P14 onwards, somatostatin receptors were concentrated in the inner plexiform layer and, to a lesser extent, in the ganglion cell and photoreceptor layers. In the ventral lateral geniculate nucleus, a heterogeneous distribution of somatostatin receptors was noted, the highest densities being found in the intergeniculate leaflet and the medial zone limiting the parvo-magnocellular interface. The distribution of somatostatin receptors in the retina and the ventral lateral geniculate nucleus after the second postnatal week, together with the presence of somatostatin-like immunoreactive elements in these structures, provide support for the involvement of somatostatin as a neurotransmitter or neuromodulator in the visual system of the adult rat. Conversely, the transient expression of somatostatin receptors observed before maturation and complete organization of the optic pathways suggests that somatostatin plays a trophic role during development of the visual system.

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.

Glycine high-affinity uptake labels a subpopulation of somatostatin-like immunoreactive cells in the Rana pipiens retina

Somatostatin-like immunoreactivity (Som-LI) and glycine high-affinity uptake have been characterized in the Rana pipiens retina. These labels are found in both the outer and inner plexiform layers (OPL and IPL), suggesting that interplexiform cells (IPCs) contain both Som and glycine in this retina. In double-label experiments these labels colocalize to an abundant population of cells in the mid-inner nuclear layer (INL), in the second or third cell layer distal from the IPL. These cells have medium sized spherical or oval somas, each with a single thin descending dendrite which ramifies in the distal IPL. Processes ascending from cells at this location were not visualized by immunocytochemistry, but could be seen by autoradiography of tissue processed for glycine high-affinity uptake. In autoradiographs apparent IPCs were the most intensely labeled cell type in this retina. Som-LI is also found in two types of probable amacrine cells in the proximal INL adjacent to the IPL, neither of which is labeled by glycine high-affinity uptake. One of these is rare (about 10 cells/mm2), and has a large pyriform soma with a thick dendrite that branches in the proximal IPL. The other type is more common (324 +/- 20 cells/mm2), has medium-sized spherical or horizontally elongated elliptical somas, and has multiple thin dendrites projecting into the distal IPL. In addition to the above cell types, faint Som-LI was seen in cells of the ganglion cell layer, possibly indicating the presence of somatostatinergic ganglion cells or displaced amacrine cells.

Localization of neurotensin-like immunoreactive amacrine cells in the larval tiger salamander retina

Light microscopic immunocytochemistry was used to localize the populations of NT-like immunoreactive amacrine cells in the larval tiger salamander retina. Seventy-nine percent of NT-immunostained cells observed in transverse cryo-prepared sections were classified as Type 1 amacrine cells. Another 6% were classified as Type 2 amacrine cells, while 15% of the NT-cells had their cell bodies situated in the ganglion cell layer and were tentatively designated as displaced amacrine cells. Each type of NT-like immunoreactive cell was observed in the central and peripheral retina. NT-immunostained processes were observed to ramify in sublayers 3 and 5 of the inner plexiform layer. An examination of retinal whole mounts revealed that NT-amacrine cells were distributed throughout the center and periphery of the retina at a density of 82 +/- 24 cells/mm2. The dendritic fields of NT-immunostained amacrine and displayed amacrine cells were observed to be either symmetrically or asymmetrically distributed about their somas. Symmetrical dendritic fields were generally oval-shaped and ranged in diameter from 250 to 500 micron (major axis) by 150 to 250 micron (minor axis). Asymmetrical dendritic fields were observed to encompass one-half or less of an imaginary circle surrounding their soma of origin and were orientated in all directions. The processes forming asymmetrical dendritic fields ranged from 75 to 260 micron in length. Furthermore, partial overlap was often observed between the dendritic fields of adjacent NT-amacrine cells.

Somatostatin-like immunoreactive material in the rabbit retina: immunohistochemical staining using monoclonal antibodies

Two mouse monoclonal antibodies to somatostatin-14 were used with avidin-biotin-peroxidase immunohistochemical technique to examine the rabbit retina. In agreement with a previous study using a polyclonal anti-serum, a sparse population (about 1,000 per retina) of neurons in the ganglion cell layer are immunoreactive for somatostatin; the vast majority of these cells are inferior to the myelinated fiber bundle. In addition, the monoclonal antibodies disclose a second neuronal population that forms a circumferential band of immunoreactive neurons around the extreme periphery of the retina. The cells in the body of the inferior retina have dendrites that ramify in the inner plexiform layer. Both the circumferential band of cells and the cells in the body of the inferior retina give off axonlike processes that run in the inner plexiform layer and do not enter the optic nerve. These long, straight varicose fibers form a meshwork that covers the entire retina. The superior retina, which contains only rare immunoreactive cell bodies, has a plexus of stained fibers comparable to that of the inferior retina. The circumferential band of cells is relatively resistant to the neurotoxin kainic acid, explaining a previously reported observation that this toxin depletes only about 50% of the content of somatostatin-like immunoreactivity from the rabbit retina. Moreover, the somatostatin immunoreactive neurons are not labeled by the intraocular injection of the fluorescent dye DAPI, which labels the cholinergic displaced amacrine cells of the rabbit retina. These observations imply that somatostatin-like immunoreactivity is localized to two populations of associational ganglion cells, neurons with cell bodies in the ganglion cell layer, the axons of which remain within the retina.

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.

Cholinergic amacrine cells of the chicken retina: a light and electron microscope immunocytochemical study

Cholinergic amacrine cells of the chicken retina were detected by immunohistochemistry using an antiserum against affinity-purified chicken choline acetyltransferase. Three populations of cells were detected: type I cholinergic amacrine cells had cell bodies on the border of the inner nuclear and inner plexiform layers and formed a prominent laminar band in sublamina 2 of the inner plexiform layer, while type II cholinergic amacrine cells had cell bodies in the ganglion cell layer, and formed a prominent laminar band in sublamina 4 of the inner plexiform layer. Type III cholinergic amacrine cell bodies were located towards the middle of the inner nuclear layer, and their processes were more diffusely distributed in sublaminas 1 and 3-5 of the inner plexiform layer. Type I and type II cells were present at densities of over 7000 cells/mm2 in central areas declining to less than 2000 cells/mm2 in the temporal retinal periphery. The cells were organized locally in a non-random mosaic, with regularity indices ranging from 3 peripherally to over 5 centrally. Neither at the light nor electron microscopic levels was a lattice of cholinergic dendrites of the kind reported by Tauchi and Masland [J. Neurosci. 5, 2494-2501 (1985)] detectable. Within the two prominent dendritic plexuses, a major feature of the synaptic interactions of the type I and type II cholinergic cells was extensive synaptic interaction between cholinergic processes. Apart from this, there was little, if any, input to cholinergic processes from non-cholinergic amacrine cells, but there was input from bipolar cells. Output from the cholinergic amacrine cell processes was directed towards non-cholinergic amacrine cells as well as other cholinergic amacrine cells, and ganglion cells.

Enkephalin in the goldfish retina

Enkephalin-like immunoreactive amacrine cells were visualized using the highly sensitive avidin-biotin method. The somas of these cells were situated in the inner nuclear and ganglion cell layers. Enkephalin-stained processes were observed in layers 1, 3, and 5 of the inner plexiform layer. The biosynthesis of sulfur-containing compounds in the goldfish retina was studied by means of a pulse-chase incubation with 35S-methionine. A 35S-labeled compound, which comigrated with authentic Met5-enkephalin on high-performance liquid chromatography (HPLC), was synthesized and was bound competitively by antibodies to enkephalin and by opiate receptors. This compound was tentatively identified as "Met5-enkephalin." The newly synthesized 35S-Met5-enkephalin was released upon depolarization of the retina with a high K+ concentration. This K+-stimulated release was greatly suppressed by 5 mM Co2+, suggesting that the release was Ca2+ dependent. Using a double-label technique, enkephalin immunoreactivity and gamma-aminobutyric acid (GABA) uptake were colocalized to some amacrine cells, whereas others labeled only for enkephalin or GABA. The possible significance of enkephalin-GABA interactions is also discussed.

Somatostatin-immunoreactive amacrine cells of chicken retina: retinal mosaic, ultrastructural features, and light-driven variations in peptide metabolism

Somatostatin-like immunoreactive amacrine cells of the chicken retina have been characterized by immunohistochemistry at the light and electron microscope levels. The cell bodies were set back from the junction of the inner nuclear and inner plexiform layers, and prominent fibre plexuses were found in sublaminas 1 and 3-5 of the inner plexiform layer. The cells were distributed across the retinal surface with a centroperipheral gradient of cell density. Locally, the cells were organized in a non-random mosaic. Ultrastructurally, immunohistochemical reaction product was found throughout the cytoplasm of the cell bodies, particularly associated with membranous structures, including the cytoplasmic surfaces of the Golgi apparatus, and within large dense-core vesicles. In dendritic varicosities in the inner plexiform layer, reaction product was associated with the external surfaces of small, clear synaptic vesicles. The synaptic relationships of the somatostatin-immunoreactive terminals in sublamina 1 were distinct from those in sublaminas 3-5. Those in sublamina 1 received input predominantly, possibly exclusively, from bipolar cells. Feedback synapses onto bipolar terminals or to the other amacrine cell process at a synaptic dyad were observed. In sublaminas 3-5, input came predominantly, possibly exclusively, from other, non-immunoreactive amacrine cells, and output was primarily onto other amacrine cells. No synaptic contacts with ganglion cells or with other somatostatin-immunoreactive amacrine cells were identified. Changes in levels of somatostatin-like immunoreactivity in retinas of chicks kept on 12:12 light:dark cycles were detected by radioimmunoassay, and by light and electron microscopic immunohistochemistry. Levels of retinal somatostatin-like immunoreactivity increased in the light and decreased in the dark. The changes appear to be light-driven rather than circadian, since with prolonged exposure to light or dark, the levels of somatostatin-like immunoreactivity continued to increase or decrease until plateaus were reached. The light-driven change in levels of somatostatin-like immunoreactivity may be related to the predominance of bipolar input to the immunoreactive processes in sublamina 1 of the inner plexiform layer. The reduction in peptide levels in the dark may indicate greater release of somatostatin-like immunoreactivity from the amacrine cells in the dark, resulting in an inability of peptide synthesis to keep pace with breakdown. In the light, release of somatostatin-like immunoreactivity may be lower, leading to a net synthesis of peptide.

Retinal neurochemistry of three elasmobranch species: an immunohistochemical approach

We surveyed retinas of Raja erinacea, Mustelus canis, and Squalus acanthias for neurotransmitter substances by using antisera directed against the substances themselves or against their synthesizing enzymes. Both the peroxidase-antiperoxidase (PAP) and indirect fluorescent techniques were employed to visualize the primary antisera. In all three species positive results were obtained with antisera directed against tyrosine hydroxylase (TOH), glutamic acid decarboxylase (GAD), serotonin (5-HT), and leucine enkephalin (Lenk). Antisera directed against glucagon, neurotensin, beta-endorphin, vasoactive intestinal peptide, or bombesin failed to show any specific staining. Immunoreactivity was located in amacrine, interplexiform, and horizontal cells as well as in axons of the optic fiber layer. The four antisera labelled different amacrine cell classes, distinguished on the bases of perikaryal morphology and the distribution of cell processes in the inner plexiform layer (IPL). Amacrine cells that labelled with the same marker were seen to have different morphologies in the species studied. Thus, TOH-like immunoreactivity was distributed in layers 1, 3, and 5 of the IPL in Mustelus but only in layers 1 and 3 in Raja retina. GAD-like immunoreactivity was found diffusely over all layers of the IPL in Raja, but in Mustelus it was confined primarily to layers 1, 3, and 5 of the IPL. Lenk- and 5-HT-like immunoreactivities showed similar species variations. Two neurochemical classes of interplexiform cell were identified in this study. In Mustelus GAD-like and Lenk-like immunoreactive interplexiform cells were seen whereas in Raja only GAD-positive interplexiform cells were detected. In squalus no unequivocal demonstration of any interplexiform cell was made with these antisera. The GAD antiserum also labelled a subset of the horizontal cells in the dorsal retina of Raja. TOH and 5-HT-antisera labelled axons in the optic fiber layer of all three species but reactive ganglion cell perikarya were not identified.

The presence of three neuroactive peptides in putative glycinergic amacrine cells of an avian retina

Amacrine cells are retinal interneurons which serve to mediate transmission between bipolar and ganglion cells. To date, in addition to several classical neurotransmitters, a number of neuroactive peptides have been localized to these cells. We have previously demonstrated in the chicken that both peptide-transmitter and peptide-peptide colocalization exists in some amacrine cells. In this report, we show that 3 neuroactive peptides (enkephalin, neurotensin and somatostatin) are present in subpopulations of amacrine cells which also possess a high affinity uptake system for glycine. These observations suggest that the simultaneous visualization by autoradiography of [3H]glycine-uptake and immunocytochemistry of peptides may be useful for distinguishing between different types of putative glycinergic amacrine cells.

The coexistence of two neuroactive peptides in a subpopulation of retinal amacrine cells

Amacrine cells are axonless interneurons of the vertebrate retina. Over the past few years many neuroactive peptides have been localized to these cells. We have previously demonstrated that a neuropeptide and a classical transmitter are colocalized in some amacrine cells. In this report, we show that two neuroactive peptides, which probably arise from different precursors, also coexist in some amacrine cells. Although some amacrine cells contain only enkephalin or neurotensin, others contain both of these neuroactive peptides.

Co-existence of glucagon- and substance P-like immunoreactivity in the chicken retina

This immunohistochemical study of chicken retina using flat-mounts shows that pancreatic glucagon- and substance P-like immunoreactive amacrine cells have more heterogeneous subpopulations than was previously understood to be the case. Using double-staining immunohistochemical procedures we demonstrate that a substantial proportion of all subtypes of glucagon-like immunoreactive cells contain substance P-like immunoreactivity and that the ratio of the amacrine cells containing both peptides to total immunoreactive cells varies according to position in the retinal and cell type. These results suggest that retinal cells may have different functions according to position or cell type.

Neurotransmitter release by certain neuropeptides in the chicken retina

The ability of certain neuropeptides (glucagon, somatostatin, leu-enkephalin and neurotensin) to release known neurotransmitters (glycine, GABA, dopamine and 5-hydroxytryptamine) was tested in the chicken retina. Tritiated neurotransmitters were injected intravitreally in chicken eyes. After excision, the retina was stimulated in vitro with the neuropeptide in micromolar concentrations while monitoring the efflux of radioactivity from the retina. A rise of the efflux represents a stimulus dependent release. Neurotensin release [3H] glycine, [3H]dopamine and [3H]5-hydroxytryptamine. Leu-enkephalin released [3H]dopamine and somatostatin released [3H]5-hydroxytryptamine. Glucagon was without effect. [3H]GABA was not released by any of the neuropeptides.

Glucagon-like immunoreactivity in mouse and rat retina

Mouse and rat retinae were examined by the peroxidase-anti-peroxidase technique of immunocytochemistry using an antiserum against glucagon. The immunoreactivity was found in the cells of the ganglion cell layer and inner nuclear layer, including Müller cells. These observations may indicate that glucagon or a similar peptide is important in neuromodulation and/or metabolism of retinal cells.

Retinal neuropeptides in the skates, Raja clavata, R. radiata, R. oscellata (Elasmobranchii)

The distribution of immunoreactive neuropeptides was investigated in the retina of three species of skates (Raja clavata, R. radiata, R. oscellata), elasmobranch fish often used in electrophysiological work on the retina. Enkephalins, neuropeptide Y (NPY), substance P and glucagon were found in different types of amacrine cells. All four peptides appeared in cell bodies in the innermost part of the inner nuclear layer. Processes from the cells containing enkephalins were numerous and ramified throughout the inner plexiform layer. Processes from the cells containing glucagon were thick and rare, and were found throughout the inner plexiform layer, at times with a predominance in sublaminae 1 and 4. NPY-immunoreactive fibres appeared mainly in sublamina 1 but also in 2 or 3, and substance-P-immunoreactive fibres in sublaminae 1, 4 and 5. Antisera against somatostatin, VIP or neurotensin did not show any immunoreactivity in the skate retina.

Immunoreactive somatostatin in the rat retina: light microscopic immunocytochemistry and chromatographic characterization

The retinas of adult, male Long-Evans rats contain somatostatin-like immunoreactive material (SLI) as detected by radioimmunoassay. The SLI co-chromatographs with synthetic somatostatin-14 on both gel permeation chromatography and reversed phase high performance liquid chromatography; no somatostatin-28-like material or higher molecular weight forms have been detected. Immunocytochemical methods detect SLI in at least two cell populations. The more abundant stained cells are at the inner margin of the inner nuclear layer and give off processes which form a dense meshwork of fine, varicose fibers at the outer border of the inner plexiform layer, as well as processes which pass into other sublaminas of the inner plexiform layer. Varicose immunoreactive fibers run vertically or obliquely through the inner nuclear layer and bifurcate at its outer margin, giving rise to horizontally running fibers in the outer plexiform layer. These observations are consistent with rat retinal SLI being contained within amacrine cells, at least some of which are interplexiform cells. With cholchicine pretreatment, a more sparse population of stained cells is detected in the ganglion cell layer. These cells give rise to processes which enter the inner plexiform layer. It is not known if these are ganglion cells or displaced amacrine cells.

Immunohistochemical localization of chick retinal 24 kdalton protein (visinin) in various vertebrate retinae

Antiserum against a protein (24,000 daltons, visinin) of chick retina has been provided for immunohistochemical study on the localization of visinin in chick retinae during development, as well as in various vertebrate retinae. The photoreceptor cells were stained with anti-visinin serum from 7th day embryonic retinae and its intensity was gradually increased with embryonic age. In addition, visinin-like immunoreactivity was found in some kinds of amacrine and displaced amacrine cells from 11th-day embryonic retinae. When human, cat, frog and carp retinae which contain both rods and cones were examined, staining of cone cells was clearly observed in the photoreceptor cell layer, but not in the rods. Furthermore visinin-like immunoreactivity was barely detectable in the photoreceptor cells of bovine, rat and mouse retinae containing mostly rod cells. These results suggest that visinin is mainly located in the cone cells in various vertebrate retinae and is a good marker for the cone cells.

Distribution and localization of regulatory peptides

A new group of modulatory substances present in both endocrine cells and central and peripheral nerves has been described in the past few years. These substances are biochemically recognized as peptides and their actions affect many bodily functions. They are now widely known as regulatory peptides. The development of new immunocytochemical techniques, closely allied to radioimmunoassay, has disclosed that the regulatory peptides are present either in cells or in nerves, in almost every tissue of the body. The presence of peptides (the classical hormones) in endocrine cells was already known at the beginning of the century, but the presence of similar substances in nerve fibers, where they probably act as neurotransmitters, is a recent and revolutionary discovery. More than 30 peptides (neuropeptides) have been found to be present in nerves, to which the term "peptidergic" has been applied, although it is now known that in certain cases a neuropeptide can be present in the same nerves as a classical neurotransmitter, for example acetylcholine with VIP, or noradrenaline with NPY. Little is known about the physiological role of these neuropeptides. It is not yet fully accepted that they act as neurotransmitters although there is strong evidence for this, particularly in the case of substance P and VIP. The investigation of the regulatory peptides is now in an initial phase. The involvement of new disciplines, such as molecular biology, in this field is producing new and very exciting discoveries, including the isolation of novel peptides and precursors, the study of which will further contribute to the understanding of the basic control mechanisms.

Interactions between enkephalin and GABA in avian retina

In addition to conventional neurotransmitters such as acetylcholine, dopamine, glycine and gamma-aminobutyric acid (GABA), a number of peptide-immunoreactive substances have recently been localized in the vertebrate retina. The functional roles of these retinal peptides and their interactions with conventional neurotransmitters are largely unknown. We have previously shown that exogenous opiates affect both the release of GABA and the firing patterns of ganglion cells in the goldfish retina, and we have now begun a systematic characterization of the opioid pathways in the chicken retina, because, among vertebrate retinas, avian retinas contain the highest concentration of enkephalins. Monoclonal antibodies specific for enkephalin have been used to demonstrate that a subpopulation of enkephalin-containing amacrine cells exists in the chicken retina. This retina also synthesizes Met-enkephalin and releases it on cell depolarization. The enkephalin-induced inhibition of GABA release in goldfish retina led us to examine whether similar interactions occur in chicken, and if so, whether enkephalins and GABA coexist in the same amacrine cells. Our results, presented here, indicate that exogenous enkephalins do indeed inhibit GABA release in the chicken retina. Surprisingly, we found that although some amacrine cells contain both enkephalin and GABA, others contain only one or the other.

The concentration of enkephalin-like material in the chick retina is light dependent

The enkephalin-like immunoreactivity in the retina of chicks has been studied using immunohistochemical and radioimmunoassay techniques. The histochemical experiments showed that the immunoreactivity was confined to a subpopulation of amacrine cells in the inner nuclear layer which projected processes into sublaminae 1 and 3-5 of the inner plexiform layer. The distribution of the immunoreactivity was markedly influenced by the ambient lighting conditions: it was reduced in the dark and restored by a period in the light. The reactivity was lost from both cell soma in the inner nuclear layer and from the processes. Radioimmunoassays showed that the quantity of enkephalin-like material was reduced by more than 60% after 12 h in the dark. Attempts to entrain a rhythm by keeping chicks on 12/12 h light/dark cycles for up to 4 days were largely unsuccessful. A rhythm may have been partially entrainable, but the major factor involved was light. These results highlight the lability of the neuropeptide in the retina and the need for controlled lighting conditions in studies of this kind. They also indicate that this system may be a fruitful model to explore two important issues: (i) it could allow studies of neuropeptide metabolism in a physiologically intact system; (ii) the role of particular amacrine cells in visual processing could be determined by depleting them of their neurotransmitter/neuromodulator.

Putative dopamine-containing cells in the retina of seven species demonstrated by tyrosine hydroxylase immunocytochemistry

Immunocytochemistry with antibodies to catecholamine synthesizing enzymes has revealed cells in the retina of chick, mouse, hamster, rat, guinea-pig, piglet and marmoset which contain tyrosine hydroxylase but not dopamine beta-hydroxylase. These findings suggest that the cells in question produce dopamine but that catecholamine synthesis does not proceed further to noradrenaline. Tyrosine hydroxylase-containing amacrine cells, located in the innermost part of the inner nuclear layer, were present in all the species studied. Some species showed atypically located amacrine cells in the inner plexiform or ganglion cell layer. In the rodents, the existence of tyrosine hydroxylase-containing interplexiform cells was suggested by the presence of a few short immunoreactive ascending processes. Three different morphological types of putative dopamine-containing cells were classified according to the level of ramification.

Interaction of neuropeptides and cultured glial (Müller) cells of the chick retina: elevation of intracellular cyclic AMP by vasoactive intestinal peptide and glucagon

Vasoactive intestinal peptide (VIP) and, to a lesser extent, glucagon were found to increase intracellular cyclic AMP rapidly in cultured glial (Müller) cells of the chick embryo retina. Although VIP elicited higher cyclic AMP accumulation than glucagon at each concentration tested, the half-maximal concentrations were similar, i.e., 6 X 10(-8) M for VIP and 8 X 10(-8) M for glucagon. Secretin had a minimal effect on cyclic AMP accumulation even at a very high (5 X 10(-6) M) concentration. Several other peptide and nonpeptide putative agonists also had little effect on cyclic AMP accumulation. The cultured Müller cell may thus be a useful model for examining VIP and glucagon effects on glial elements of the CNS.

Corticotropin releasing factor-like immunoreactive neurons in the rat retina

Corticotropin releasing factor (CRF)-like immunoreactive neurons have been identified in the rat retina by immunohistochemical methods using antisera directed against ovine and rat CRF. CRF-like immunoreactivity was observed in both amacrine and ganglion cells which projected fine varicose processes to the inner plexiform layer of the retina. It is suggested that CRF may play a role in retinal function.

Synaptic contacts of somatostatin-immunoreactive amacrine cells in goldfish retina

Retinal amacrine cells containing somatostatinlike immunoreactivity (SLI) were labeled by the peroxidase-antiperoxidase technique and their connections were analyzed by light and electron microscopy. The labeled processes were found in two distinct plexuses--one near the most proximal border of the inner plexiform layer and the other near the most distal border. They received most (89%) of their input from amacrine cells and the remainder from bipolar cells. A majority (56%) of their output synapses go to processes of amacrine cells, a substantial proportion (38%) go to ganglion cell dendrites, and the remainder go to bipolar cell axon terminals. The relative frequencies of each of the types of contacts were nearly identical in the distal and proximal plexuses. The cells containing SLI are different in their morphology and synaptic connections from any goldfish amacrine cells containing conventional neurotransmitters, but one type of amacrine cell containing SLI resembles certain other peptidergic amacrine cells in the goldfish retina.

Enkephalin immunoreactivity in iris nerves: distribution in normal and grafted irides, persistence and enhanced fluorescence after denervations

The morphology and distribution of nerve fibers showing enkephalin-like immunoreactivity was studied in rat and mouse iris whole mounts. In adult rat, a relatively dense network of varicose fibers was seen throughout the iris. Individual, long, usually smooth fibers were observed running together with non-fluorescent fibers in bundles. Positive nerve fibers were also seen in the ciliary body and the choroid membrane. The fluorescence intensity was normally low. No enkephalin-positive fibers were detected in adult mouse iris. Extirpation or lesioning either one or all the three ganglia known to supply the rat iris with nerve fibers, the superior cervical, the ciliary and the trigeminal ganglia, caused no detectable decrease in amount of enkephalin-positive fibers. However, in irides grafted to the anterior eye chamber of adult recipients, no enkephalin-positive fibers could be observed 2-12 days postoperatively, strongly suggesting that degeneration of these fibers had occurred. When iris grafts were left longer in the eye, nerve fibers with enkephalin-like immunoreactivity reappeared. An increased fluorescence intensity was observed both in the ipsilateral and contralateral iris following extirpation or lesioning all three ganglia and in the ipsilateral iris after extirpation of the ciliary ganglion. Three days after a systemic injection of capsaicin, which causes a permanent disappearance of substance P fibers, the same phenomenon was often observed. This raises the possibility of an interaction between the enkephalin-positive and the substance P fiber systems in the iris.(ABSTRACT TRUNCATED AT 250 WORDS)

A comparison of the effects of kainic acid on somatostatin, substance P and dopamine in the rabbit retina

Groups of adult, male Dutch belted rabbits received intravitreal injections of varying doses (30-240 nmol) of the excitatory neurotoxin kainic acid (KA) into one eye and saline vehicle into the other. One week later a segment of each retina was examined histologically and the remainder was assayed for somatostatin-like immunoreactivity (SLI), substance P-like immunoreactivity (SPLI), dopamine (DA) and protein. Histologically, KA at doses of 120 and 240 nmol produced destruction of the inner layers of the retina, with preservation of the photoreceptors. This damage is correlated with a dose-related depletion of retinal protein content. At KA doses of 120 and 240 nmol, both SPLI and DA content were reduced to 5-10% of control values. Although KA significantly reduced the retinal content of SLI even at a dose of 30 nmol, the greatest mean depletion of SLI observed at any dose was 50%. This failure of KA to reduce retinal SLI content by more than 50% at doses of KA which produce severe histologic damage to the neural retina and dramatic depletions of SPLI and DA content demonstrates that the SLI-containing structures of the rabbit retina are partially resistant to the neurotoxic action of KA. We hypothesize that SLI in the rabbit retina is contained in two pharmacologic types of cells in about equal abundance; one type is sensitive to and one type resistant to KA. In contrast, substance P- and dopamine-containing retinal neurons are uniformly sensitive to destruction by KA.

The action of peptides on the mudpuppy electroretinogram (ERG)

Two neuropeptide substances were applied to the mudpuppy retina while the electroretinogram (ERG) was recorded. A low concentration of somatostatin (10(-9)M) was found to be a potent agent in increasing the amplitudes of all the oscillatory potentials (OPs) of the ERG. There was no appreciable change of the threshold sensitivity or the stimulus response curve of the b-wave. The highest concentration tested (10(-6)M) reduced the first OP to about the same amplitude as at the start of the experiment and attenuated the later OPs. A decrease of the suprathreshold b-wave was induced by the highest concentrations (10(-7), 10(-6)M) of somatostatin. A low concentration of substance P (10(-11)M) selectively and differentially decreased the earlier OPs (O1O2). Higher concentrations (10(-10), 10(-9)M) diminished the earlier OPs further, reduced the later OPs and decreased the supra-threshold a- and b-waves. The results support previous suggestions that the OPs reflect activities in feedback circuits initiated by the amacrines and indicate that somatostatin and substance P through separate mechanisms seem to interact with the inhibitory neuronal circuits which have been suggested to give rise to the OPs. Secondly, in agreement with previous work, the OPs appear to have a different origin from the b-wave. Thirdly, two separate classes of amacrines, each with a different transmitter, seem to be associated with different physiological roles.

VIP (vasoactive intestinal polypeptide)-like immunoreactive amacrine cells in the retina of the rat

Vasoactive intestinal polypeptide (VIP)-like immunoreactivity was demonstrated in the rat retina, using the peroxidase anti-peroxidase (PAP) method. VIP-like immunoreactivity was observed in the cytoplasm of amacrine cells of the inner nuclear layer (INL) and their varicose processes ramifying in the inner plexiform layer (IPL). VIP-like immunoreactive amacrine cells were present in both central and peripheral retinal regions. In some sections fine ramifications of varicose processes in the IPL could be clearly traced. VIP-like immunoreactivity was detected in both 'stratified' and 'diffuse' amacrine cells. VIP-like immunoreactive amacrine cells were classified into four types.

Dopaminergic cell differentiation in the developing chick retina

The distribution and morphology of dopaminergic (DA) neurons in the chick retina was studied in the course of development. Fluorescent DA cells were first detected on the 13th day of incubation. They were always found in positions two or three cell rows externally from the junction between the inner plexiform layer (IPL) and inner nuclear layer (INL). On the 14th day, DA cells were found in the innermost row of the INL. Subsequently their processes extended not only bilaterally along the IPL-INL junction but also vertically into the IPL. As a result, three fiber layers were formed as laminae 1, 3 and 5 in the IPL. In the newly-hatched chick retina, a number of growth cone-like fluorescent structures with fine spikes were seen at the IPL-INL junction, indicating that DA fibers were still growing and elongating at least at hatching. On the 4th postnatal day, the ramification of dendritic processes was very prominent and they often showed a spiral configuration.

Glucagon immunoreactive neurons in the retina of different species

Neurons displaying glucagon immunoreactivity were detected among the amacrine cells in the retina of goldfish, frog and pigeon. Nerve cell bodies were located in the inner nuclear layer with their processes ramifying in 2-3 more or less well-defined sublayers in the inner plexiform layer. The distribution of cell bodies and processes varied with the species. In pigeon retina two separate populations of glucagon immunoreactive neurons were found among the amacrine cells. In frog retina glucagon immunoreactivity was also discerned in cell bodies in the ganglion cell layer. These cell bodies sent processes outwards to the inner plexiform layer. No glucagon immunoreactive neurons were detected in the retina of the rat, rabbit, cat, pig or cow.