Synaptic Inputs to ON Parasol Ganglion Cells in the Primate Retina

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Volume 16, Number 24, Issue of December 15, 1996 pp. 8041-8056
Copyright ©1996 Society for Neuroscience

Synaptic Inputs to ON Parasol Ganglion Cells in the Primate Retina

Roy Jacoby, Donna Stafford, Nobuo Kouyama, and David Marshak
Department of Neurobiology and Anatomy, The University of Texas Medical School, Houston, Texas 77225

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

In primates, the retinal ganglion cells that project to the magnocellular layers of the lateral geniculate nucleus have distinctiveresponses to light, and one of these has been identified morphologicallyas the parasol ganglion cell. To investigate their synaptic connections,we injected parasol cells with Neurobiotin in lightly fixed baboonretinas. The five ON-center cells we analyzed by electron microscopyreceived ~20% of their input from bipolar cells. The major synapticinput to parasol cells was from amacrine cells via conventionalsynapses and, in this respect, they resembled $alpha$ ganglion cellsof the cat retina. We also found the gap junctions between amacrinecells and parasol ganglion cells that had been predicted fromtracer-coupling experiments. To identify the presynaptic amacrinecells, ON-center parasol cells were injected with Neurobiotinand Lucifer yellow in living macaque retinas, which were thenfixed and labeled by immunofluorescence. Two kinds of amacrinecells were filled with Neurobiotin via gap junctions: a large,polyaxonal cell containing cholecystokinin and a smaller one withoutcholecystokinin. There were also appositions between cholecystokinin-containingamacrine cell processes and parasol cell dendrites. Cholinergicamacrine cell processes often followed parasol cell dendritesand made extensive contacts. In other mammals, the light responsesof polyaxonal amacrine cells like these and cholinergic amacrinecells have been recorded, and the effects of acetylcholine andcholecystokinin on ganglion cells are known. Using this information,we developed a model of parasol cells that accounts for some propertiesof their light responses.
Key words: monkey; amacrine cell; bipolar cell; gap junction; cholecystokinin; acetylcholine

INTRODUCTION

Parasol ganglion cells have been recognized as a distinct morphological type in the primate retina for more than 100 years(for review, see Rodieck et al., 1985), and they make up ~10%of the retinal ganglion cells (Perry et al., 1984). They are alsocalled M cells because they project to the magnocellular layersof the lateral geniculate nucleus (Bunt et al., 1975; Leventhalet al., 1981; Casagrande and DeBruyn, 1982; Itoh et al., 1982;Perry et al., 1984; Perry and Silveira, 1988; Naito, 1989). Themagnocellular cells, in turn, provide a major input to the primaryvisual cortex that ultimately contributes to many aspects of visualperception, but is particularly important for the perception ofmotion (for review, see Merigan and Maunsell, 1993). The ON-parasolganglion cells respond with an increase in firing rate at theonset of light in the center of the receptive field and a decreaseto light in the surround. OFF cells have the opposite responses.ON-parasol cells ramify in the fourth stratum of the inner plexiformlayer (IPL), and OFF parasol cells ramify in the second stratum(Dacey and Lee, 1994).

Parasol cells are more sensitive to luminance contrast than the color-opponent ganglion cells that project to the parvocellularlayers, and they respond more transiently to light stimuli atall levels of adaptation (for review, see Kaplan et al., 1990).One possible explanation for these differences is that the localcircuit neurons presynaptic to parasol cells have these characteristics,but very little was known about them. The first step in identifyingthese presynaptic neurons was to determine the relative contributionsof amacrine cells and bipolar cells in an electron microscopicstudy of Neurobiotin-injected ON-parasol cells from the peripheralretina. Approximately 80% of the input to parasol cells was fromat least two types of amacrine cells. Amacrine cells are labeledwhen parasol cells are injected with Neurobiotin (Dacey and Brace,1992; Ghosh et al., 1996), but the mechanism of this tracer couplingwas uncertain. We also found that parasol cells make gap junctionswith proximal dendrites of amacrine cells.

We then did light microscopic double-labeling experiments to study the interactions of injected parasol ganglion cells withtwo types of amacrine cells that costratified with parasol cellsand were known to make synapses onto ganglion cells (Mariani andHersh, 1988; Marshak et al., 1990). The first was a large cellimmunoreactive for the glycine-extended cholecystokinin precursor(G6-gly-IR) that resembles one of the amacrine cells tracer-coupledto parasol cells. We confirmed this by double labeling and foundnumerous contacts between G6-gly-IR amacrine cells and parasolcells. We also found that choline acetyltransferase-immunoreactive(ChAT-IR) displaced amacrine cells contacted parasol ganglioncells. Based on results in other species, we predict that acetylcholinecontributes to the transient excitation at the beginning of parasolcell light responses, that cholecystokinin contributes to theinhibition that follows and that gap junctions from amacrine cellsenhance both components.

MATERIALS AND METHODS
Labeling of parasol cells for correlated light and electron microscopy. Eyes were enucleated within 20 min postmortem frombaboons (Papio cynocephalus anubis) that had been overdosed withsodium pentobarbital (50-100 mg/kg, i.v.) by other investigatorsat the conclusion of experiments that did not involve the eyes.The baboon eyes were hemisected and fixed by immersion for 30min at 20°C in 0.1% glutaraldehyde and 2% paraformaldehyde in0.1 M sodium phosphate, pH 7.4, rinsed, and stored in the samebuffer (PB) at 4°C. The retinas were divided into three regions:central, within 5 mm of the fovea; mid-peripheral, 5-10 mm fromthe fovea; and far-peripheral, further than 10 mm from the fovea.Only mid-peripheral and far-peripheral pieces were used for theseexperiments. Using fine forceps, the vitreous humor was removedand the retina was dissected free of the retinal pigment epithelium.

The procedure for intracellular injection of Neurobiotin into parasol cells under visual control was a modification of thetechnique first described by Tauchi and Masland (1984) and similarto that described by Dacey and Brace (1992) except that the tissuewas fixed and PB was substituted for Ames medium. The retinaswere treated with acridine orange (4 min, 10 µM) and mounted onthe stage of a Zeiss Standard upright, fixed-stage microscopewith a 30× long-working-distance objective. Microelectrodes madefrom thin-walled borosilicate glass (50-100 M $Omega$ ) were filled with2.5% Lucifer yellow (Molecular Probes, Eugene, OR) and 5% Neurobiotin(Vector Laboratories, Burlingame, CA) in 20 mM 3-[N-morpholino]propanesulfonicacid (MOPS; Sigma, St. Louis, MO), pH 7.6. Retinal ganglion cellswith the largest perikarya were injected with Lucifer yellow for1-2 min with 400 msec square-wave pulses at 2 Hz with 5-10 nAof negative current until the cell was confirmed to be a parasolcell, and then they were filled with Neurobiotin using positivecurrent of the same amplitude, frequency, and duration for 3-6min, depending on the electrode resistance. The retinas were post-fixedovernight with 2% glutaraldehyde and 4% paraformaldehyde in 0.1M PB, pH 7.4, and rinsed in PBS after this and all other stepsunless noted otherwise. The retinas were processed to visualizethe parasol cells, as described previously (Marshak et al., 1990).The tissue was treated with 1% sodium borohydride in PBS (60 min)and an ascending and descending series of graded ethanol solutionsin PBS (10 min each in 10, 25, and 40%; 30 min in 50%; 10 mineach in 40, 25, and 10%). The Neurobiotin was visualized usingVector avidin-biotin-peroxidase (1:100, overnight at 4°C) anddiaminobenzidine (0.5 mg/ml) with hydrogen peroxide (0.005%, 60min). The retinas were then osmicated (1% in PB, 60 min) and embeddedin Epon on glass slides with the ganglion cells upward. The injectedcells were identified again, and cells were drawn with a cameralucida or photographed. Areas containing amacrine cells that mayhave been labeled by tracer coupling were not used. Four cellswere cut out and reembedded whole, and one cell was cut with asliding microtome into 60 µm sections, which were mounted on Eponblanks. Approximately 100-nm-thick sections were collected onformvar-coated, single-hole grids and stained with uranyl acetate(2% in 50% methanol, 60 min). Labeled parasol cell dendrites fromall five were first photographed at 2000× to verify that theybranched in the inner half of the inner plexiform layer (IPL).We photographed 100 or more profiles with synaptic specializationsfrom each of 5 cells, and we examined additional sections of thesecells to look for gap junctions. The presynaptic cells were typicallyfollowed through sets of 5-10 serial sections at 10,000×, andthey were identified using established, ultrastructural criteria(Dowling and Boycott, 1966; Koontz and Hendrickson, 1987). Usinga goniometer stage to optimize the orientation of the membranes,synapses were photographed at 20,000× and, in the case of gapjunctions, also at 50,000× or 100,000×. The negatives containinggap junctions were scanned at 2400 dpi using a UMAX scanner witha transparency adapter. Pixel intensity values were measured ina rectangular area 15 pixels wide and spanning the junctions usingSigmascan Pro (Jandel Scientific, Corte Madera, CA).

Double labeling for confocal laser scanning microscopy. For light microscopic double-labeling experiments, macaque eyes (Macacamulatta) were enucleated within 10 min after an overdose of sodiumpentobarbital (50-100 mg/kg, i.v.) and transported to the laboratoryinside glass jars packed in ice. They were dissected within 10-15min of enucleation in oxygenated Ames medium (Sigma) at room temperature.The eyes were hemisected, and the posterior halves were cut intoquarters. Using fine forceps, the vitreous and the sclera wereremoved, and the retina-pigment epithelium-choroid preparationwas superfused with oxygenated Ames medium in dim, white lightat 20°C. The protocols for injection of Neurobiotin and Luciferyellow were the same as described above except that the tissuewas alive. The preparations were fixed overnight in 2% paraformaldehydein PB, and the retina was isolated. In the first experiments,only Lucifer yellow was injected, and the retinas were choppedinto 90 µm sections with a McIlwain Tissue Chopper (The MickleLaboratory Engineering Co.). The sections were then labeled with1:1000 rabbit anti-G6-gly (provided by Dr. John DelValle, Universityof Michigan, Ann Arbor, MI), biotinylated goat anti-rabbit IgG(Vector) at 1:100 for 2 d and 1:100 Streptavidin-Cy3 (JacksonImmunoResearch Laboratories, West Grove, PA) for 2 d. In laterexperiments, the retinas were incubated for 1-2 d in Cy3-conjugatedStreptavidin (1:100 in PBS with 0.3% sodium azide and 0.3% TritonX-100, (Jackson ImmunoResearch Laboratories, West Grove, PA).The isolated retinas were then labeled with 1:500 to 1:1000 anti-G6-glycontaining 0.3% Triton X-100 as described previously (Kouyamaand Marshak, 1992) or 1:200 affinity-purified anti-choline acetyltransferase(Chemicon, Temecula, CA). The second antibodies were Cy5-conjugatedto either goat anti-rabbit IgG or horse anti-goat IgG, both at1:100 in PBS with 0.3% sodium azide (Jackson ImmunoResearch Laboratories,West Grove, PA ). The retinas were mounted ganglion cell sideupward in glycerol (3 parts) to PBS (1 part) with 0.3% sodiumazide and 0.1% paraphenylenediamine (Sigma) and examined in aZeiss confocal laser scanning microscope with a krypton-argonlaser. Excitation was at 488 nm for Lucifer yellow, 568 nm forCy3, and 647 nm for Cy5. The filter blocks were 515-540 for Luciferyellow, 590-610 for Cy3, and 670-810 for Cy5. The diameters ofthe perikarya of labeled amacrine cells were determined usingZeiss LSM software.

Photoshop 3.0 (Adobe Systems, Mountain View, CA) was used to process the confocal images for publication and for statisticalanalysis. Whole-mount preparations contained immunoreactive processes,which were designated green, and injected parasol cells, whichwere designated red. We superimposed the two images, which wereeach reconstructed from a stack of 10-15 optical sections, andidentified sites of apposition, where the labeled processes werewithin 0.6 µm, the z-axis resolution. We confirmed that the appositionswere not separated by more than 0.6 µm using the individual opticalsections. The pixels in these areas appeared yellow, but therewas a wide range of yellow values in each image because of variationin the size and intensity of labeled processes. Therefore, yellowwas defined for each image by sampling a typical site of appositionbetween red and green processes of intermediate intensity. Allof the similarly colored pixels in each image and its correspondingcontrol images were selected using the ``select color range'' commandin Photoshop. To extend the range of yellow hues that were counted,a tolerance factor of 200 was used when selecting pixels. Thisvalue included areas of overlap between parasol cell dendritesand G6-gly-IR processes of intermediate to high intensity, butnot lower-level background labeling. The pixels were counted usingthe ``histogram'' function. The yellow pixels were also countedin three control images that we created for each analyzed areaby rotating the Neurobiotin signal relative to the immunoreactivesignal (Vardi et al., 1989; Massey et al., 1996). The Neurobiotinsignal was rotated 90°, 180°, and 270°, the yellow pixels werecounted in each control image, and the three were averaged. Thepixel counts from the control and original images were comparedusing a paired t test.

RESULTS

Morphology of ON-parasol ganglion cells
The ganglion cells that were injected in lightly fixed baboon retina were clearly identifiable as parasol cells. Like theparasol cells labeled by intracellular injection in living retinasillustrated in Figure 1 and by other groups previously (Watanabeand Rodieck, 1989; Dacey and Petersen, 1992; Goodchild et al.,1996), their perikarya, axons, and proximal dendrites were largein diameter. Many smaller dendrites were also filled, and in theelectron microscope, synapses were observed on processes as narrowas 0.25 µm in diameter. Their dendrites branched densely withina narrow stratum of the IPL; the ON subtypes used in this studyramified just below the center of the IPL, at 60-65% of the distancebetween the inner nuclear layer (INL) and the ganglion cell layer(GCL).
Fig. 1. Fluorescence micrograph of three ON-parasol cells injected with Lucifer yellow in a living macaque retina. Note that virtuallyall of the dendrites are in a single plane of focus, which indicatesthat they are in the same narrow stratum of the IPL. Preparationslike this were used for double-labeling experiments. Scale bar,50 µm.
[View Larger Version of this Image (79K GIF file)]

It was particularly important to distinguish the injected cells from garland cells because they receive a majority of theirinputs from amacrine cells (Sterling et al., 1994), like the cellsin our study (Table 1). We identified our injected cells as parasolcells rather than garland cells based on morphological criteriaestablished using the Golgi method. Polyak (1941) found that garlandcells had smaller perikarya and much less densely branched dendriticarbors than parasol cells. Although the two types could stratifyat the same levels of the inner plexiform layer, the garland cellshad larger dendritic arbors than parasol cells at the same eccentricity.Boycott and Dowling (1969) compared a garland cell, which theycalled unistratified, with a parasol cell, their stratified diffusetype, at the same eccentricity and confirmed these findings. Kolbet al. (1992) described two ganglion cells similar to garlandcells, G8 and G16, in whole-mount preparations of the human retina.They proposed that both correspond to Polyak's garland cells andshowed that they were different from parasol cells, which theycalled M cells.

Table 1. Synaptic inputs to ON-parasol ganglion cells

Animal Cell number Inputs from bipolar cells Inputs from amacrine cells

1 1 proximal 9 21% 34 79%

distal 85 24% 265 76%

1 2 36 17% 172 83%

2 3 41 17% 198 83%

2 4 19 13% 122 87%

2 5 21 18% 95 82%

Synaptic connections of 5 ON-parasol ganglion cells from two baboons. Cell 1 was first sectioned with a sliding microtome,and the sections containing the perikaryon and proximal dendriteswere compared with those containing only distal dendrites. Amacrinecells provided the major input to both regions. The remaining4 cells were not sampled systematically. They received 83% oftheir input from amacrine cells on average. No significant differencesamong these 4 cells were observed using a $chi$ ² test ( $chi$ ² = 1.3, p = 0.73).

Synaptic inputs to ON-parasol ganglion cells
The ganglion cell dendrites were always postsynaptic; the synaptic inputs to 5 ON-parasol cells are summarized in Table 1.The first parasol cell was sectioned in a sliding microtome. Thesections were remounted, and sections containing the proximaland distal dendrites were compared. Both regions received a verysimilar proportion of their input from amacrine cells (see Table1, cell 1). Weber and Stanford (1994) had shown that there wasno change in the proportion of amacrine cell input in variousregions of the dendritic trees of $alpha$ ganglion cells in the catretina using three-dimensional reconstruction. Because the sameappeared to be true for the parasol cells, the remaining cellswere not sampled systematically.

Figure 2 shows a bipolar cell synapse onto a labeled parasol cell dendrite. Rod bipolar cell axons do not costratify withparasol cell dendrites, and Grünert and Martin (1991) did notsee direct synapses from rod bipolar cells onto ganglion cellsin the macaque retina. Kolb and Dekorver (1991) have shown thatmidget bipolar cells in the parafovea provide input only to midgetganglion cells. The presynaptic bipolar cells, therefore, arelikely to be diffuse cone types. DB4 or DB5 are expected basedon the depth of their axonal arbors in the IPL (Boycott and Wässle,1991).
Fig. 2. A large bipolar cell axon terminal contacts a labeled parasol ganglion cell dendrite (arrowhead). The amacrine cell that isthe other member of the dyad makes a feedback synapse (arrow)onto the bipolar cell axon (60,000×).
[View Larger Version of this Image (186K GIF file)]

A majority of inputs to parasol cells were from amacrine cells at conventional synapses. One type of presynaptic amacrinecell was relatively electron-dense and irregularly shaped (Fig.3). Because we had selected ganglion cells from areas where therewere no labeled amacrine cells, we were confident that this electrondensity did not result from tracer coupling. It is possible thatthese processes originated from AII amacrine cells because theyare also relatively electron-dense. Wässle et al. (1995) sawtwo examples of unidentified processes receiving synapses fromAII amacrine cells in stratum 3 of the macaque IPL, and thesemight have been ON parasol ganglion cell dendrites. Because >98%of the output synapses of AII amacrine cells were found in theouter two strata of the IPL, however, it is more likely that anothertype of amacrine cell is the source of the electron-dense processescontacting parasol cells. Other presynaptic amacrine cells weremore electron-lucent (Fig. 4).
Fig. 3. A dark, irregularly shaped amacrine cell process is presynaptic to a parasol ganglion cell dendrite (arrowhead); more electron-lucentamacrine cell processes are found on either side of the presynapticprocess (60,000×).
[View Larger Version of this Image (149K GIF file)]

Fig. 4. An electron-lucent amacrine cell process is presynaptic to a large, labeled parasol ganglion cell dendrite (arrowhead; 60,000×).
[View Larger Version of this Image (156K GIF file)]

In some cases, synaptic inputs appeared to be clustered on parasol ganglion cell dendrites, but this was not analyzed quantitatively(Fig. 5). In some instances, a bipolar cell presynaptic to a parasolganglion cell and an amacrine cell received a feedback synapsefrom the same amacrine cell (Fig. 2). There were also feedforwardsynapses, that is, amacrine cells that received input at the sameribbon synapse as the parasol ganglion cell dendrite and alsomade a synapse onto the same ganglion cell dendrite. Figure 6shows two amacrine cell processes that are presynaptic to a labeledparasol ganglion cell dendrite, and one of these amacrine cellprocesses also makes a synapse onto the other. In addition, therewere amacrine cells that made synapses onto parasol ganglion celldendrites and also onto the bipolar cells that provided inputto those ganglion cell dendrites.
Fig. 5. Three synaptic inputs and, possibly, a fourth onto a labeled parasol ganglion cell dendrite are indicated by arrowheads. Abipolar cell makes a dyad synapse on the left, and two amacrinecells, one pale and one dark, are presynaptic below. The synapticdensity at the top right is less well defined (60,000×).
[View Larger Version of this Image (181K GIF file)]

Fig. 6. Two amacrine cell processes make synapses onto a labeled parasol ganglion cell dendrite (arrowheads). The upper amacrine cellprocess also makes a synapse onto the lower cell (arrow; 60,000×).
[View Larger Version of this Image (164K GIF file)]

Gap junctions of ON-parasol ganglion cells
The ON-parasol ganglion cell dendrites also made gap junctions with amacrine cell processes. These were typical of gap junctionsin the IPL and elsewhere in the CNS (Marc et al., 1988). Figure7 shows one of these gap junctions onto the proximal dendriteof an electron-lucent amacrine cell that contains microtubules.The inner leaflets of the membranes were straight, parallel, andhad a higher electron density than unspecialized membrane. Thejunctions were ~20 nm in width (Fig. 8). There were cytoplasmicdensities associated with the junctions in both the amacrine cellsand the parasol ganglion cells. Figure 9 shows another gap junctiononto an amacrine cell process with very similar ultrastructure.These resembled the dendrites of wide-field amacrine cells suchas the A19 type that have been shown to contact $alpha$ ganglion cellsin the cat retina (Kolb and Nelson, 1993; Freed et al., 1996).The gap junctions were made by relatively electron-lucent amacrinecells that did not resemble AII amacrine cell processes. Thus,we agree with Wässle et al. (1995), who found no gap junctionsbetween AII amacrine cells and ganglion cells in macaque retina.
Fig. 7. A gap junction (arrowhead) between a labeled parasol ganglion cell dendrite and an electron-lucent amacrine cell process containingmicrotubules (arrow) cut in a longitudinal section. A, The largediameter of the process at the junction and the ribosomes nearbyindicates that this is a proximal amacrine cell dendrite (40,000×).B, The portion of the dendrite near the gap junction containingribosomes (arrow) is shown at 75,000×. C, The junction is shownat 150,000×; note the cytoplasmic densities on both sides.
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Fig. 8. Densitometric scan of the gap junction illustrated in Figure 7. The peaks (arrows) indicate the densest portions of the innerleaflets. The outer leaflets (arrowheads) were not as well definedas they would have been with conventional fixation and en blocstaining, however, and it was not always possible to visualizethe gap between them. The baseline is higher on the right becauseof the peroxidase reaction product in the labeled parasol cell.
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Fig. 9. A large parasol cell dendrite receives both a chemical synapse from an amacrine cell (arrow) and a gap junction from anotheramacrine cell (arrowheads). A, Both synapses are found on a largedendrite, ~1.2 µm in diameter (30,000×). B, The amacrine cellmaking the gap junction resembles the one from Figure 7 but iscut in cross section (50,000×). C, The junction is shown at highermagnification (150,000×).
[View Larger Version of this Image (183K GIF file)]

The amacrine cell processes were relatively large in diameter at the points where the gap junctions were found, averaging1.12 ± 0.39 (SD) µm when measured in their short axes. This findingsuggests that gap junctions were located on the proximal amacrinecell dendrites, as does the observation of ribosomes in the amacrinecell dendrite in Figure 7. In both instances illustrated here,the amacrine cell and ganglion cell dendrites were approximatelyperpendicular, but there were also examples in which the two dendriteswere more nearly parallel, as would be expected if the dendritescofasciculated as described by Dacey and Brace (1992). Chemicalsynapses from other amacrine cells were often observed in thevicinity of gap junctions as in Figure 9, but there were no examplesof mixed synapses, that is, single amacrine cells making bothgap junctions and conventional synapses onto the parasol ganglioncells.

The gap junctions were 0.34 µm long, on average. Assuming that the junctions are circular and that the density of connexonsis the same as in a freeze-fracture micrograph from the macaqueIPL (Peters et al., 1991), 359 connexons would be expected perjunction. If each of these had a conductance of 50 pS, as theydo elsewhere in the retina (McMahon et al., 1989), the conductanceof each junction would be 17.9 nS when it was fully open. Becauseparasol cells typically have an input resistance of ~200 M $Omega$ (Z.Zhou, personal communication), each junction could produce upto a 3.6 mV change in the membrane potential of the parasol ganglioncell for each millivolt of transjunctional voltage.

G6-gly-IR amacrine cells
As we described previously (Marshak et al., 1990), antisera to the glycine-extended cholecystokinin precursor (G6-gly) labeledtwo distinct types of amacrine cells. Their processes formed twoplexuses centered at 30 and 65% of the IPL depth, the same levelsas parasol ganglion cell dendrites (Watanabe and Rodieck, 1989).One type of G6-gly-IR amacrine cell had ovoid perikarya ~ 10-15µm in diameter and two to three short, primary dendrites thattypically branched once and gave rise to longer, unbranched dendriteswith a large diameter. One population had perikarya in the INLand processes in stratum 2 of the IPL, and the second had perikaryain the GCL and processes in stratum 4 of the IPL. In whole mounts(Fig. 10), thin, axon-like processes were seen arising from thetips of the dendrites and occasionally from other parts of thedendrites, but it was not possible to follow these to their terminations.These large, unistratified cells were virtually identical in theirmorphology and stratification to the large, polyaxonal amacrinecells that were found to be tracer-coupled to parasol ganglioncells by Dacey and Brace (1992). These cells have also been describedin three studies using the Golgi method, the first by Boycottand Dowling (1969), who called them unistratified amacrine cells.Mariani (1990) described a cell called ``wispy'' that ramified inthe center of the IPL but was otherwise very similar, and Kolbet al. (1992) described semilunar type 3 cells that were similarto the G6-gly-IR cell ramifying in stratum 4. The second typeof G6-gly-IR amacrine cell was smaller and also had approximatelyhalf of its perikarya in the INL and half in the GCL. Regardlessof the positions of the perikarya, these amacrine cells contributedthin, varicose dendrites to both plexuses. These smaller, bistratifiedG6-gly-IR cells resembled the wavy, multistratified type 2 cellsof Mariani (1990) and the A14 cells of Kolb et al. (1992). Wehave also shown previously that the G6-gly-IR amacrine cells direct41% of their output to ganglion cells and make gap junctions (Marshaket al., 1990).
Fig. 10. Camera lucida drawings of two of the large subtypes of G6-gly-IR amacrine cells from the peripheral retina of Macaca fascicularis.The retinas were isolated, fixed in periodate-lysine-paraformaldehyde,and labeled as described previously (Marshak et al., 1990). Notethe large diameter of the dendrites. The axons (arrowheads) typicallyarose from the tips of the dendrites, but they can also arisemore proximally, as indicated in the lower drawing. The axonscould only be followed for a short distance through the plexusof labeled processes. Scale bar, 10 µm.
[View Larger Version of this Image (9K GIF file)]

To determine whether the G6-gly-IR amacrine cells and parasol cells were costratified, we analyzed 4 ON-parasol cells in double-labeledvertical sections from macaque retina. Figure 11 is a verticalsection showing that Lucifer yellow-labeled ON-parasol cell dendritesare very narrowly costratified with the inner set of G6-gly-IRprocesses. The parasol cell dendrites traveled among the G6-gly-IRprocesses, apparently making many contacts. We could not differentiatethe dendrites of the small, bistratified G6-gly-IR amacrine cellsfrom the axons of the larger labeled amacrine cells, however,because both ramified at the same level in the IPL. Because noamacrine cells were labeled after Lucifer yellow injections intoparasol cells, Neurobiotin was used for the remainder of the experimentsin order to identify the tracer-coupled amacrine cells.
Fig. 11. Top. Lucifer yellow-injected ON-parasol ganglion cell dendrites (red) were narrowly costratified with the inner setof G6-gly-IR processes (green) in a double-labeled vertical sectionof macaque retina. G6-gly-IR perikarya (arrows) were found inthe inner nuclear layer and the ganglion cell layer. Dendritesfrom blue cone bipolar cells were also visible in the distal innernuclear layer and outer plexiform layer. This confocal image representsa stack of optical sections spanning 4.5 µm. Scale bar, 25 µm.
Fig. 12. Bottom. A, Left, Green processes indicate G6-gly immunoreactivity in a whole-mount preparation. Arrows indicate theprimary dendrites of a large G6-gly-IR amacrine cell. Note thatmost of the other processes are smaller in diameter. B, Right,The same volume of tissue as A, containing a Neurobiotin-injectedON-parasol ganglion cell (top right) with a large, tracer-coupledamacrine cell (bottom left). Arrows indicate the same dendritesas in A, which are double-labeled. Both images represent a reconstructedstack of optical sections spanning from the ganglion cell layerto the middle of the IPL. Scale bar, 25 µm.
[View Larger Version of this Image (156K GIF file)]

When Neurobiotin was injected, heterotypic tracer-coupling was observed in 12 ON-parasol cells from 3 living retinas, eachfrom a different macaque. As described by Dacey and Brace (1992),both large and small amacrine cells were labeled after parasolcells were injected. Some of the tracer-coupled cells were alsolabeled with antiserum to G6-gly. The perikarya and primary dendritesof the double-labeled amacrine cells were completely filled withNeurobiotin. The G6-gly labeling was distributed differently thanthe Neurobiotin in some of these cells. G6-gly labeling was consistentlyobserved in the Neurobiotin-labeled large dendrites, but not alwaysin their perikarya (Fig. 12). All but one of the double-labeledamacrine cells were found in the ganglion cell layer or the innerhalf of the IPL. Other tracer-coupled amacrine cells were notG6-gly-IR, and most of them were found in the inner nuclear layeror the outer half of the IPL (Fig. 13). Double-labeled cells (n= 41) had a mean soma diameter of 10.8 ± 1.0 µm, and G6-gly-negativetracer-coupled amacrine cells (n = 15) had a mean soma diameterof 8.8 ± 1.2 µm (Fig. 14). The tracer-coupled amacrine cells alsofell into two distinct groups (t test, p < 0.001). Therefore,the larger tracer-coupled amacrine cells are likely to containcholecystokinin, but the smaller ones are not. The double-labeledamacrine cells were classified as the larger of the two typesof G6-gly-IR amacrine cells, but the smaller tracer-coupled amacrinecells were not labeled sufficiently to observe the morphologicaldetails necessary to classify them.
Fig. 13. The same parasol cell as in Figure 12 from a different scan of a larger area of retina showing only the Neurobiotin signal(white). The smaller tracer-coupled cells (arrowheads) were G6-gly-negative,and in this area were all located in the inner nuclear layer.The larger tracer-coupled cells (arrows) were G6-gly-IR and werefound in the ganglion cell layer or the lower half of the IPL.This image represents a reconstructed stack of optical sectionsspanning from the ganglion cell layer to the inner nuclear layer.Scale bar, 25 µm.
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Fig. 14. Soma size histogram of amacrine cells tracer-coupled to Neurobiotin-injected parasol ganglion cells. Double-labeled, G6-gly-IRamacrine cells (filled bars, n = 41) formed a distinct group (ttest, p < 0.001) based on soma size, with a mean diameter of 10.8± 1.0 µm. Tracer-coupled amacrine cells that were not G6-gly-IR(open bars, n = 14) had a soma diameter of 8.8 ± 1.2 µm.
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The primary dendrites of double-labeled cells ranged from 0.79 to 1.52 µm in diameter, but these made up only a small fractionof the dense meshwork of G6-gly-IR processes that surrounded thedendritic trees of injected parasol cells (Fig. 12A). Many of theseother processes were narrower than the dendrites of the double-labeledcells and, therefore, were the axons of the larger amacrine cellsand the dendrites of the smaller, bistratified amacrine cells.We were certain that the large G6-gly-IR dendrites were in contactwith parasol cell dendrites because of the tracer coupling. Wealso wanted to determine whether there was more contact betweenG6-gly-IR processes and parasol cell dendrites than would be expectedby chance. We used 13 reconstructed stacks consisting of 0.3-0.5µm optical sections spanning ~5 µm. Control images had 6.1% feweryellow pixels than the original images. The differences were smallbut consistent; control images had significantly less contact,as measured by the number of yellow pixels, than the originals(paired t test, p = 0.006).

Cholinergic amacrine cells
The cholinergic, or starburst, amacrine cells are also likely to contact parasol ganglion cells based on their stratificationpattern and synaptic connections (Mariani and Hersh, 1988; Rodieckand Marshak, 1992). To analyze the interactions between cholinergicamacrine cells and parasol cells, we labeled tissue containingNeurobiotin-filled parasol cells with antiserum to choline acetyltransferase(ChAT). First, we examined vertical sections of this materialto determine whether the cholinergic processes ramified at thesame level of the IPL as parasol cell dendrites. We found thatdendrites from ON-parasol cells were narrowly costratified withthe innermost set of cholinergic processes (Fig. 15).
Fig. 15. Top. A double-labeled vertical section containing a Neurobiotin-injected ON-parasol ganglion cell (red) and amacrinecell processes labeled with antisera to ChAT (green). The innerset of cholinergic processes was narrowly costratified with theON-parasol cell dendrites. This confocal image represents a reconstructedstack of optical sections spanning 1 µm in depth. Scale bar, 25µm.
Fig. 16. Bottom left. A double-labeled whole mount with Neurobiotin-filled parasol ganglion cell dendrites (red) and ChAT-IRamacrine cell processes (green). The parasol cell dendrites appearto follow the cholinergic processes, making repeated contacts(arrows). Areas of overlap between the two sets of processes appearyellow. The number of yellow pixels was counted to determine theamount of contact. This confocal image represents a reconstructedstack of optical sections through the inner IPL. Scale bar, 25µm.
Fig. 17. Bottom right. Control image for Figure 16 at the same scale. The Neurobiotin-filled parasol cell dendrites (red image)have been rotated 90° clockwise relative to the cholinergic processes(green image), which are in the same orientation as Figure 16.The yellow pixels in this image represent random overlap of thetwo sets of processes. The average amount of contact attributableto chance was 28.1 ± 11.9% less than in the original images.
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We used whole-mount preparations to examine the interactions of the ChAT-IR amacrine cell processes and the parasol ganglioncell dendrites in greater detail. We used stacks of 10-15 opticalsections like Figure 16 rather than single sections so that wecould see the two sets of dendrites in their entirety. We hadshown that parasol cell dendrites and ChAT-IR processes were confinedto the same narrow stratum of the IPL and, therefore, we wereconfident that the dendrites were not artifactually superimposed.This was confirmed in the individual optical sections that madeup the reconstructed stack. In some instances, a parasol celldendrite and a cholinergic process were intertwined and made severalappositions. The appositions were frequently located on the ChAT-IRvaricosities. The cholinergic processes do not cofasciculate withparasol cell dendrites as extensively as they do with $alpha$ ganglioncell dendrites in cat (Vardi et al., 1989), but there appear tobe selective contacts in both species. We analyzed 9 areas from3 ON-parasol cells, and control images (Fig. 17) had 28.1% feweryellow pixels than the original images. The controls were significantlylower than the original images (p = 0.001).

These results indicate that there is more total area of contact between the cholinergic and G6-gly-IR processes and the parasolcell dendrites than would be expected from chance. It is likelythat some of the appositions with the ChAT-IR and G6-gly-IR processesare sites of synapses onto parasol ganglion cell dendrites, butthis can only be proven by electron microscopic double-labelingexperiments. It is also uncertain what percentage of the amacrinecell synapses we observed in the electron microscope were fromthese identified amacrine cells.

DISCUSSION

Synaptic inputs to ON-parasol cells
ON-parasol cells in peripheral retina received the majority of their synaptic inputs from amacrine cells, but they are reportedto receive most of their input from bipolar cells in the parafovea(Sterling et al., 1994). This would not be expected simply onthe basis of size, based on studies of cat retinal ganglion cellsat different eccentricities (Kier et al., 1995). It may resultfrom the higher density of bipolar cells relative to amacrinecells in the parafovea (Krebs and Krebs, 1989; Curcio and Allen,1990; Martin and Grünert, 1992), but Dubin (1970) found thatthe ratio of amacrine cell to bipolar cell synapses does not changewith eccentricity. It is more likely that the differences in thenumber of bipolar cell inputs reflect the different pattern ofsynaptogenesis in the central macaque retina (for review, seeCrooks et al., 1995). Bipolar cell synapses are the first onesto form in the macaque fovea, but amacrine cells form first moreperipherally. Thus, if parasol cells receive synapses from thefirst presynaptic cells available, their patterns of input wouldbe different in central and peripheral retina.

The synaptic connections of parasol cells in the peripheral baboon retina and $alpha$ ganglion cells in the cat retina were quitesimilar. Three groups found that $alpha$ cells receive 80% or more oftheir input from amacrine cells (Watanabe et al., 1985; Freedand Sterling, 1988; Kolb and Nelson, 1993). Weber and Stanford(1994) found only 62% amacrine cell input, however, probably becausetheir $alpha$ cells were very densely labeled and postsynaptic densitiescould not be used to identify synapses (Freed and Sterling, 1988).One of the amacrine cells presynaptic to parasol cells in ourstudy was relatively electron-lucent and contained microtubules,like the wide-field amacrine cells that contact $alpha$ cells (Kolband Nelson, 1993; Freed et al., 1996). We also found that parasolcells make extensive contacts with cholinergic amacrine cellslike $alpha$ cells (Vardi et al., 1989). Finally, we confirmed thatparasol cells, like $alpha$ cells, are tracer-coupled to amacrine cells,and we found the gap junctions that mediate this effect. Thesefindings add to the growing body of evidence that parasol cellsand $alpha$ cells are homologous (for review, see Peichl, 1991; Rodiecket al., 1993).

Identity and functions of amacrine cells presynaptic to ON-parasol cells
One of the amacrine cells coupled to the ON-parasol cells was the large G6-gly-IR type that we described previously (Marshaket al., 1990). These are very similar to the long-range neurofibrillar-stainingcells of the cat, which are labeled after Neurobiotin injectionsinto $alpha$ ganglion cells (Vaney, 1991). Like Dacey and Brace (1992),we saw numerous contacts between their dendrites and parasol celldendrites in these experiments. Cholecystokinin has potent, inhibitoryeffects on the activity of brisk sustained and brisk transientretinal ganglion cells in cats (Thier and Bolz, 1985), and parasolcells would be expected to respond similarly. A19 and A22 amacrinecells in the cat retina are also quite similar to the large G6-gly-IRtype (Kolb et al., 1981; Vaney et al., 1988), and they make chemicalsynapses onto $alpha$ ganglion cells (Kolb and Nelson, 1993; Freed etal., 1996). The A19 and A22 cells have transient ON-OFF responsesto light (Kolb and Nelson, 1985; Freed et al., 1996), and so shouldthe large, G6-gly-IR amacrine cells. There are transient hyperpolarizationsin parasol cells, one producing a discontinuity in firing afterthe initial response and another at the offset of the stimulus(deMonasterio, 1978), and these may represent input from G6-gly-IRamacrine cells.

The ChAT-positive displaced amacrine cells also costratified with the ON-parasol cells and made extensive contacts. The cholinergicsynapses are likely to be excitatory (for review, see Kaneda etal., 1995). Cholinergic displaced amacrine cells respond to lightstimuli in the receptive field center with a transient depolarizationfollowed by a sustained depolarization (Bloomfield, 1992; Taylorand Wässle, 1995; Peters and Masland, 1996). These cholinergiccells, therefore, should excite ON-parasol cells, particularlyat the beginning of the light responses. In other mammals, cholinergicamacrine cells respond well to moving and other rapidly changingstimuli (for review, see O'Malley and Masland, 1993). Their inputscould account, at least in part, for the high sensitivity of parasolcells to the same kinds of stimuli (Scobey and Horowitz, 1976;Scobey, 1981).

There is a major GABAergic input to parasol cells. The two strata of the IPL where the parasol cells ramify contain the highestdensity of synapses from GABA-IR amacrine cells onto ganglioncells (Koontz and Hendrickson, 1990), and synapses have been observedfrom GABA-IR amacrine cells onto parasol cells identified by three-dimensionalreconstruction (Kolb and Crooks, 1992). GABA_A receptors of ON-parasolcells have been described in both anatomical (Grünert et al.,1993) and physiological (Zhou et al., 1994) experiments. Someof these synapses might be made by amacrine cells that also containChAT-IR or G6-gly-IR. Others may be made by the smaller, tracer-coupledamacrine cells or additional types of amacrine cells.

Gap junctions between amacrine cells and parasol ganglion cells
We also found gap junctions between parasol cells and amacrine cells. Gap junctions had been observed between the two postsynapticelements at dyad synapses (Reale et al., 1978; Raviola and Raviola,1982), of which a majority have one process from an amacrine celland another from a ganglion cell (Dowling, 1968; Koontz and Hendrickson,1987). Although it is possible that gap junctions serve some metabolicfunction, they may also contribute directly to the light responsesof parasol cells.

The net effect of the coupled amacrine cells might be excitatory, even though their chemical synapses onto the ganglion cellsare inhibitory (Vaney, 1994). Axon-bearing amacrine cells likethe large G6-gly-IR type would be particularly well suited forthis purpose if the gap junctions were located on their dendritesand the output synapses on their axons. In that case, the ganglioncells that fell within the dendritic field of an amacrine cellwould be excited by that amacrine cell, but those falling outsidewould be inhibited. According to this hypothesis, action potentialscould propagate from one parasol ganglion cell to the G6-gly-IRamacrine cells and then to other parasol ganglion cells via thegap junctions, producing synchronous firing in the ganglion cells,as observed in cat (Mastronarde, 1983; Neuenschwander and Singer,1996) and rabbit (DeVries and Baylor, 1996) retinas. Dacey andBrace (1992) also proposed that input from amacrine cells throughthe gap junctions enlarges the receptive-field centers of theparasol cells, thereby increasing their sensitivity to luminancecontrast. The receptive-field centers of parasol cells match thedendritic fields, however (Crook et al., 1988; Croner and Kaplan,1995). The diameter of the receptive-field center increases withdark adaptation (Gouras, 1967), and Vaney (1994) has proposedthat the effect of coupling between amacrine cells and ganglioncells might be larger or more apparent in dim light. Alternatively,the gap junctions might provide additional excitation withoutincreasing the receptive-field-center size. This would occur ifthe inputs via gap junctions alone were insufficient to bringthe ganglion cell membrane potential to threshold and concomitantbipolar cell inputs were also required.

A second possibility is that the gap junctions enhance the inhibition of the parasol ganglion cells by the amacrine cells.This would occur if the gap junctions between the amacrine cellsand the parasol ganglion cells were rectified so that they conductmore when the ganglion cells are depolarized relative to the amacrinecells (Peters et al., 1991). When the ganglion cells depolarize,the amacrine cells would also depolarize via the gap junctionsand, after a brief synaptic delay, the amacrine cells would inhibitthe ganglion cells. There is electrophysiological evidence foran inhibitory role for the gap junctions. Gouras (1969) saw inhibitionafter antidromic stimulation of the optic nerve in parasol cellsbut not in midget cells, which have no gap junctions (Dacey andBrace, 1992). The results of Neurobiotin injection experimentsare also consistent with this hypothesis. Amacrine cells can belabeled after ganglion cell injections with positive current,but ganglion cells are rarely labeled after amacrine cell injections(Vaney, 1994; Xin et al., 1995). Because there are two types ofcoupled amacrine cells, our two hypotheses are not mutually exclusive.Indeed, the most parsimonious explanation is that gap junctionsfrom the large G6-gly-IR amacrine cells mediate the excitatoryinteractions and gap junctions from the smaller amacrine cellsmediate the inhibitory interactions.

Our model is summarized in Figure 18. There are two excitatory inputs that increase the sensitivity of parasol cells, one fromthe dendrites of cholecystokinin-containing cells via gap junctionsand another from cholinergic cells via chemical synapses. Theaxons of cholecystokinin-containing amacrine cells and other typesof amacrine cells make inhibitory synapses with the parasol cells.Feedback to the amacrine cells via gap junctions makes this inhibitionmore effective and the light responses of parasol cells more transient.
Fig. 18. Summary diagram of the proposed synapses from amacrine cells to ON-parasol ganglion cells. The synapses of bipolar cells andthe synapses between amacrine cells have been omitted. The displacedamacrine cell labeled ChAT (light gray) probably contains bothacetylcholine and GABA (Rodieck and Marshak, 1992). Based on theactions of acetylcholine in cat retina, it is expected to makeexcitatory synapses (filled triangles) onto the ganglion cells(1). The larger displaced amacrine cell labeled CCK (dark gray)is G6-gly-positive and makes gap junctions (resistors) with theproximal dendrites of the ON-parasol cell at (2). It containscholecystokinin and, possibly, GABA. Its axons make inhibitorysynapses (filled circles) onto parasol ganglion cell dendrites,mainly those outside of its dendritic field (3). The amacrinecell labeled GABA in the inner nuclear layer (black) representsthe smaller tracer-coupled amacrine cell. It might make both inhibitorysynapses and rectified gap junctions (diodes) with the parasolganglion cell dendrites (4). Dacey and Brace (1992) suggestedthat it might make gap junctions with the CCK amacrine cells ratherthan the parasol ganglion cells.
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FOOTNOTES

Received Aug. 5, 1996; revised Sept. 23, 1996; accepted Sept. 27, 1996.

This work was supported by Grants R01 EY06472, P30 EY10608, T32 EY07024, and F32 EY06471 from the National Eye Institute,F31 MH10957 from the National Institute of Mental Health, PD 92040from Fight for Sight, Inc., and 011618027 from the Texas HigherEducation Coordinating Board. We thank Mrs. Lillemor Krosby forexcellent technical assistance, Dr. Alice Chuang for assistancewith the statistical analysis, Dr. Charles Sims for drawing Figure10, and Mrs. Rama Grenda for drawing Figure 18. We also thank Dr.David Hall, Dr. Garrett Kenyon, Dr. Helga Kolb, and Dr. StephenMassey for helpful comments on this manuscript. We are also gratefulto Dr. James Willerson, Dr. Roger Price, and Ms. Janice McNattfor providing the tissue used in these experiments.

Correspondence should be addressed to David W. Marshak, Department of Neurobiology and Anatomy, The University of Texas MedicalSchool, Box 20708, Houston, TX 77225.

Dr. Stafford's present address: Department of Biological Structure, University of Washington, Seattle, WA 98195.

Dr. Kouyama's present address: Department of Physiology, Tokyo Women's Medical College, Tokyo 162, Japan.

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