Confocal Analysis of Reciprocal Feedback at Rod Bipolar Terminals in the Rabbit Retina

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The Journal of Neuroscience, December 15, 2002, 22(24):10871-10882

Confocal Analysis of Reciprocal Feedback at Rod Bipolar Terminals in the Rabbit Retina
Jian Zhang, Wei Li, E. Brady Trexler, and Stephen C. Massey
Department of Ophthalmology and Visual Science, University of Texas-Houston Medical School, Houston, Texas 77030

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Amacrine cells in the mammalian retina are famously diverse in shape and function. Here, we show that two wide-field GABAamacrine cells, S1 and S2, have stereotyped synaptic contactswith the appropriate morphology and distribution to perform specificfunctions. S1 and S2 both supply negative feedback to rod bipolarterminals and thus provide a substrate for lateral inhibitionin the rod pathway. Synapses are specialized structures, and thepresynaptic compartment is normally characterized by a swellingor varicosity. Each S1 amacrine cell has ~280 varicosities, whereasan S2 cell has even more, ~500 per cell. Confocal analysis showsthat essentially all varicosities aggregate around rod bipolarterminals where they are apposed by postsynaptic GABA receptors.Each rod bipolar terminal is contacted by varicosities from ~25different S1 and 50 different S2 amacrine cells. In fact, rodbipolar cells are the only synaptic target for S1 and S2 amacrinecells: all of the output from these two wide-field GABA amacrinecells goes to rod bipolar terminals. It has long been a puzzlewhy two amacrine cells, apparently with the same connections,are required. However, an analysis of the distribution of varicositiessuggests that S1 and S2 amacrine cells provide different signals.S2 amacrine cells dominate within 200 µ from a rod bipolar terminaland can provide an inhibitory input with spatial characteristicsthat match the size of the surround signal recorded from AII amacrinecells in the rod pathway. In contrast, the larger, better-coupledS1 amacrine cells may provide a more distant networksignal.

Key words: retina; S1 amacrine cell; S2 amacrine cell; rod bipolar cell; AII amacrine cell; confocal microscopy; Neurobiotin

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

There are multiple rod and cone pathways through the mammalian retina (for review, see Sterling, 1998; Bloomfield and Dacheux,2001). Cones diverge to multiple types of ON and OFF cone bipolarcells, which synapse directly with ganglion cells. In contrast,many rods converge onto a single morphological type of rod bipolarcell (RBC), which makes excitatory dyad synapses predominantlywith two postsynaptic amacrine cells (Strettoi et al., 1990).Synapses with one amacrine cell, the AII, are conventional. Inturn, the AII makes gap junctions with ON cone bipolar cells andglycinergic synapses with OFF cone bipolar cells (Strettoi etal., 1992). Alternative rod pathways via rod-cone coupling ordirect connections between rods and OFF cone bipolar cells havealso been reported (DeVries and Baylor, 1995; Soucy et al., 1998).

The other postsynaptic element at each rod bipolar dyad makes a reciprocal synapse and is derived from one of two wide-fieldGABA amacrine cells known as S1 and S2 (Sandell and Masland, 1986;Vaney, 1986; Strettoi et al., 1990). Although there is not muchendogenous serotonin in the rabbit retina, these cells accumulateserotonin, which provides a simple way to label the mosaic ofS1 and S2 amacrine cells. Both GABA_A and GABA_C receptors havebeen localized to the rod bipolar terminal at a proportion ofS1 and S2 contacts (Fletcher and Wässle, 1999), and GABA-mediatednegative feedback seems to be a common feature of bipolar cellterminals (Marc and Liu, 2000).

The S1 is a wide-field amacrine cell with straight radiating dendrites decorated with large varicosities (Sandell and Masland,1986; Vaney, 1986). The S2 is smaller, and the dendrites are moretangled and bear smaller varicosities. Both cell types contributeto a dense overlapping plexus at the level of rod bipolar terminals.Recordings show that rabbit S1 amacrine cells have depolarizingresponses and produce spikes (Bloomfield, 1996). Furthermore,AII amacrine cells in the rod pathway have an inhibitory surroundthat is mediated by GABA and blocked by tetrodotoxin, which ledto the suggestion that S1 cells contribute surround signals tothe rod pathway via feedback to the rod bipolar terminal (Bloomfieldand Xin, 2000).

There are several outstanding questions concerning the role of S1/S2 amacrine cells. First, are there contacts with otherbipolar cells besides rod bipolar cells? Second, why is therean apparent mismatch in the small size of the AII surround (~100µm) and the large extent of the S1 dendritic field (>1 mm). Third,why is it necessary to have two closely related amacrine celltypes with apparently identical connections to do the same job?In this paper, we have used confocal microscopy to analyze S1and S2 amacrine cells in detail. We find that S1 and S2 varicositiesare synaptic sites, apposed by GABA receptors and always in contactwith rod bipolar cells. We have also modeled the distributionof S1 and S2 amacrine cells contacting a single rod bipolar cell.These calculations suggest that nearby surround inputs are dominatedby S2, whereas S1 has relatively few and distantcontacts.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation. The isolation of rabbit retina has been described previously (Massey and Mills, 1996). In brief, adult New ZealandAlbino rabbits of either sex were anesthetized with urethane (loadingdose, 1.5 gm/kg, i.p.), and the orbit was infused with 2% lidocainehydrochloride before enucleation. The eyes were removed and hemisected,and the retina was isolated from the inverted eye cup while immersedin oxygenated Ames medium (Ames and Nesbett, 1981). The isolatedretina was flattened onto filter paper, photoreceptor down, andincubated in fresh Ames medium containing 10 µM serotonin (5-hydroxytryptamine;Sigma, St. Louis, MO) for 30 min. Then, the preparation was fixedfor 30-60 min with 4% formaldehyde in phosphate buffer. Alternatively,for intracellular dye injection, pieces of isolated retina weresubmersed with 5 µM 6-diamino-2-pheylindole (DAPI) together with10 µM serotonin for 30 min to prelabel amacrine cell nuclei inthe inner nuclear layer (INL). S1 and S2 cells could be identifiedby their large and lightly stainedsomas.

Antibodies. A rabbit or goat polyclonal antibody to calretinin (Chemicon, Temecula, CA) was used at a dilution of 1:10,000.A rabbit polyclonal (Chemicon) or mouse monoclonal antibody (TransductionLaboratories, San Diego, CA) against protein kinase C (PKC) wasdiluted at 1:1000. A goat polyclonal antibody against serotonin(Incstar, Stillwater, MN) was diluted at 1:1000. An antibody againstsynaptophysin (Sigma) was diluted at 1:500. Antibody to the GABA_Creceptor was a generous gift from Dr. Heinz Wässle (Departmentof Neuroanatomy, Max Planck Institute for Brain Research, Frankfurtam Main, Germany) (1:100) (Enz et al., 1996). The monoclonal antibodyto synaptic vesicle 2 (SV2) (1:1000), developed by Dr. KathleenBuckley (Department of Neurobiology, Harvard Medical School, Boston,MA), was obtained from the Developmental Studies Hybridoma Bankdeveloped under the auspices of the National Institute of ChildHealth and Development and maintained by the Department of BiologicalSciences, University of Iowa. Secondary antibodies were obtainedfrom Jackson ImmunoResearch (West Grove, PA) and used at a dilutionof 1:200.

Intracellular dye injection. S1 and S2 amacrine cells were impaled under visual control with sharp electrodes. Electrode tipswere filled with a mixture of 1% Lucifer yellow-CH and 4% Neurobiotin(Vector Laboratories, Burlingame, CA) in 50% 0.05 M phosphatebuffer (PB), and then back-filled with 3 M lithium chloride. Afterpenetration, Lucifer yellow and Neurobiotin were iontophoresedinto the cell with biphasic current (1 nA, 3 Hz) for 1-4 min.After several cells were filled, the retina was fixed in 4% formaldehydefor 30 min, washed in 0.1 M PB/0.5% Triton X-100/0.1% sodium azide,and reacted overnight with 1:100 streptavidin/Cy3.

Immunocytochemistry. Immunolabeling was performed following previously established protocols (Massey and Mills, 1996). Fordouble- or triple-labeling experiments, flat-mount pieces of retinaor free-floating vibratome sections were blocked in 3% donkeyserum in PB with 0.5% Triton X-100/0.1% sodium azide for 2 hrto overnight to reduce nonspecific labeling. The tissue was incubatedin primary antibodies in the presence of 1% donkey serum/PB with0.5% Triton X-100/0.1% sodium azide for up to 1 week. The tissuewas washed with PB containing 0.5% Triton X-100/0.1% sodium azideand reacted with fluorescently labeled secondary antibodies overnight.Fluorochromes were Alexa 488 (Molecular Probes, Eugene, OR), Cy3,and Cy5. Preparations were mounted with Vectashield (Vector Laboratories)and viewed with a confocal microscope equipped with a krypton/argonlaser (Zeiss, LSM 410). Images were adjusted using Adobe Photoshop5.5.

Data analysis. Standard S1/S2 cells were defined based on averaged data from examples of dye-injected S1/S2 cells. Varicositieswere taken as large and obvious swellings along the S1/S2 dendrites.The dendritic diameter was measured at $<=$ 0.5 µm, and varicositieswere counted as >1 µm in diameter. At the low end of this range,particularly with the smaller S2 varicosities, there is some uncertaintybecause there are occasional dendritic thickenings that approachthis size, although they are not adjacent to rod bipolar terminals.However, objectivity could be maintained by turning off the rodbipolar channel when counting varicosities, and in addition, onlythe true varicosities were stained for synaptic markers and notthe intervening stretches ofdendrite.

The varicosities around a standard S1 or S2 were counted in a series of expanding shells. When divided by the number of rodbipolar cells in each shell, this gives the probability of contactbetween an RBC and a single S1/S2 at a given distance. Then, centeredaround an RBC, this probability times the number of S1/S2 cellsin each shell yields the number of S1/S2 cells that contact therod bipolar cell shell by shell (see Fig. 10). The distributionof S1/S2 somas was plotted as background, and a custom programwas used to place standard S1/S2 cells, according to the numberof S1/S2 cells calculated above that contact the central rod bipolarcell, in random positions with dendrites in random directions.The results are averaged from 30-40 trials. For model A, it wasassumed that regenerative dendritic properties allow signal transferfrom one varicosity to all others, passing through the soma ifnecessary. For model B, it was assumed that signal transfer islimited to a single dendritic branch and cannot pass the soma.On the basis of these assumptions, the program counted the numberof S1/S2 varicosities in each shell that could affect the centralRBCs via the dendritic structure. This also reflects the inputfrom other rod bipolar cells and is greater for close S1/S2 cellsbecause the proximal density of varicosities is much higher. Thedensity of effective varicosities was plotted against distancefrom a single RBC (see Fig. 11).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Triple labeling of the S1/S2 matrix, AII amacrine cells, and rod bipolar terminals

Although there is very little endogenous serotonin in the rabbit retina, once the cells are loaded with exogenous serotonina serotonin antibody may be used effectively to visualize theS1 and S2 amacrine cells. The vast majority of cell bodies arelocated in the INL from which fine dendrites descend diagonallyto form an extremely dense and overlapping meshwork at the bottomof the IPL (Fig. 1A). Although dendrites of S1 and S2 cannot bedistinguished, close examination of this meshwork reveals certainrepeated characteristics. Embedded within overlapping regionsof straight dendrites are clusters of varicosities. Double labelingwith an antibody against PKC to label rod bipolar cells showsthat the clusters of varicosities surround the terminals of rodbipolar cells (Fig. 1B). The rod bipolar terminals fill holesin the S1/S2 matrix, and every terminal, without exception, issurrounded by several varicosities. Visual inspection suggeststhat varicosities in the S1/S2 matrix only occur adjacent to rodbipolar terminals, but it is sometimes difficult to distinguishvaricosities from fasciculated dendrites.

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Figure 1. Triple-label imaging of rod bipolar contacts with the S1/S2 matrix and AII amacrine cells. A, The S1/S2 matrix, focus in sublamina 5, labeled with an antibody to serotonin after preloading. The matrix consists of many overlapping fine dendrites with clusters of varicosities (an example indicated by the arrow). Large holes in the matrix are protruding ganglion cells or Müller cells passing through. B, Double-label image, same field, shows that rod bipolar terminals, labeled with anti-PKC (blue), fill small holes in the S1/S2 matrix and are surrounded by several varicosities (same arrow as in A.). C, The matrix of AII dendrites (same field), labeled with anti-calretinin (red), is less dense than the S1/S2 matrix, but every rod bipolar terminal (blue) contacts an AII process. D, Triple-label image showing rod bipolar terminals (blue), inserted in the combined S1/S2 matrix and AII matrix (red). There is almost no overlap among the three labels: they stain separate neuronal types. Individual rod bipolar terminals (blue) are often enclosed completely by alternating S1/S2 contacts or AII contacts (red).

AII amacrine cells are also postsynaptic to rod bipolar cells, and the AII matrix can be visualized with an antibody againstcalretinin (Wässle et al., 1995; Massey and Mills, 1999). TheAII matrix is sparse compared with the S1/S2 matrix, but thisis expected because the overlap of AII dendrites in sublaminab ranges from 3 to 8, compared with >70 for S2 and >500 for S1amacrine cells (Vaney, 1986). Nevertheless, dendrites from AIIamacrine cells touch every rod bipolar terminal in the field (Fig.1C). There are no rod bipolar terminals that are not adjacentto AII dendrites. The AII and S1/S2 matrices appear to be complementary.In the triple-label image, alternating AII (calretinin, red) andS1/S2 (serotonin, green) labeling can be observed around the rimof the rod bipolar terminals (Fig. 1D). It appears that AII dendritesfrequently fill the gaps between multiple S1/S2 contacts withrod bipolar terminals. This is consistent with the postsynapticlocalization of AII and S1/S2 dendrites at rod bipolarterminals.

Image analysis

To avoid reliance on mere inspection, we developed a quantitative assessment of the relationship between the antibody labelsshown in Figure 1. A cursor was centered on each separate rodbipolar terminal, and a 50 × 50 pixel box was clipped from theimage. During this manual selection process, the red and greenchannels were turned off to reduce operator bias. These imagesections were then aligned and averaged. In effect, this is amethod to analyze the average distribution of labeling in theother two channels around a repeated neuronal structure. In otherwords, for this image, it is a method to assess the average distributionof AII and S1/S2 dendrites around rod bipolar terminals. The resultsare shown in Figure 2. Figure 2C shows the central peak of rodbipolar terminals with very low noise because these structureswere selected. Figure 2, A and B, shows the average distributionof AII and S1/S2 [indoleamine-accumulating amacrine cells (IACs)]processes around the rod bipolar terminals. In each case, a distinctvolcanic caldera occurs around a central cavity coincident withthe average rod bipolar peak from Figure 2C. The S1/S2 calderais smoother and more regular than the AII caldera. This may reflectthe greater density of the S1/S2 matrix and a larger number ofsynaptic contacts. In both cases, the height of the caldera immediatelyadjacent to the rod bipolar terminal far exceeds the local noiseat a distance from the central cavity. This indicates that, onaverage, there is a high probability of encountering AII and S1/S2processes immediately adjacent to a rod bipolar terminal. As acontrol, the S1/S2 image was rotated 180° from the rod bipolarimage. The same analysis then showed no peak with relation tothe rod bipolar signal (Fig. 2D). This analysis confirms thatthe visual impression is real and that we can reliably visualizethe contacts between rod bipolar terminals and their postsynapticelements using confocal microscopy.

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Figure 2. Image analysis of Figure 1. Surface plots show the average distribution of label in each channel around a repeated neuronal structure, in this case, rod bipolar terminals. A 50 × 50 image was clipped out around 35 rod bipolar terminals. This analysis shows that the apparent contacts observed in Figure 1 are real. A, The caldera of red pixels indicates a high probability of finding an AII process adjacent to a rod bipolar terminal. B, The caldera of green pixels indicates a high probability of finding an S1/S2 process adjacent to a rod bipolar cell. C, The average distribution of blue pixels. This peak is high and uniform with very low background because the selected structures were rod bipolar terminals. This coincides with the central cavity in A and B. D, As a control, the S1/S2 image was rotated 180° out of phase, and the same analysis was performed around rod bipolar terminals. There is no discernible structure in the plot indicating that the spatial relationship shown in B has been destroyed.

Localization of synaptophysin in S1/S2 varicosities

The analysis above suggests that the varicosities in the S1/S2 matrix are synaptic structures, and the intervening stretchesof fine dendrite do not specifically associate with rod bipolarterminals. Given that S1 and S2 amacrine cells make reciprocalsynapses, we examined the distribution of synaptic markers atthe rod bipolar cell synapse. Synaptophysin is a protein involvedin the docking of synaptic vesicles at the site of release (Brandstätteret al., 1996), and SV2 is another synaptic vesicle protein (Buckleyand Kelly, 1985; Yang et al., 2002). Thus, we triple labeled somematerial to determine whether the varicosities around rod bipolarterminals were associated with these synaptic markers (Fig. 3).

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Figure 3. Varicosities contain synaptic markers. A, A single prominent rod bipolar terminal stained with anti-PKC. B, Same field, stained for the synaptic vesicle protein SV2. The rod bipolar terminal is well stained, but there are additional lobes adjacent to the rod bipolar terminal that express SV2. C, Double-label image shows that the rod bipolar terminal contains both PKC and SV2 (purple), but the adjacent lobes contain only synaptophysin (red, outlined); they are not part of the rod bipolar terminal. D, Triple-label image. The rod bipolar terminal contains PKC and SV2 (purple), whereas the adjacent lobes are stained for serotonin and SV2 (yellow). The dendrites of the IACs are stained only for serotonin (green); they do not contain synaptic vesicles. Thus, the S1/S2 varicosities surrounding the rod bipolar terminal contain synaptic markers.

As reported previously, SV2 labeling was found in both plexiform layers (Brandstätter et al., 1996; Yang et al., 2002). Zoomingin on a single prominent example revealed that rod bipolar terminalsexpress high levels of SV2; this is consistent with the immensenumber of synaptic vesicles packed into a single terminal. However,at high magnification, it can be seen that there are additionalSV2-positive lobes adjacent to the rod bipolar terminal (Fig.3B; outlined in C is double labeling of A and B). The triple-labelin Figure 3D shows that the SV2-positive profiles adjacent tothe rod bipolar terminals are S1 and S2 varicosities. Importantly,the intervening S1/S2 dendrites were not stained for SV2. Thisimplies that only the S1/S2 varicosities, which cluster aroundrod bipolar terminals, make synaptic contacts. Similar resultswere found for synaptophysin (data notshown).

Intracellular injections

When isolated pieces of rabbit retina were incubated with 5 µM DAPI for 30 min, various cells were labeled. Compared withthe brightly labeled AII amacrine cells, somas of S1 and S2 amacrinecells were lightly stained and relatively large, 10-14 µm in diameter,and located near the proximal border of the INL. Labeled cellsin mid-inferior retina were chosen and dye injected with a mixtureof 4% Neurobiotin and 1% Lucifer yellow. Figure 4A shows partof a dye-injected S1 amacrine cell at 4 mm inferior. As reportedpreviously, S1 amacrine cells had large somas with 20-25 straightradiating dendrites that descended to the dense plexus in sublamina5, observed when the whole population was stained (Fig. 1). Thedendritic diameter of this cell was 1800 µm, but the diametervaried with eccentricity ranging from 1200 µm at the visual streakto >3000 µm in the periphery (Vaney, 1986). In complete fills,the terminal dendrites ended abruptly without a terminal varicosity(Vaney, 1986). Partially filled cells were excluded because thedendritic labeling tapered slowly and then disappeared, so shorterlengths of dendrite were filled. There were leaf-like varicosities(diameter, 1.9-5.9 µm; mean, 3.4 ± 1.2 µm) along the entire lengthof each dendrite. The inter-varicosity spacing was 58 ± 6 µm.

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Figure 4. Indoleamine-accumulating amacrine cells from whole-mount rabbit retina filled with Neurobiotin and subsequently visualized with Cy3. A, An S1 amacrine cell; focus in sublamina 5 of the inner plexiform layer, adjacent to the ganglion cell layer. The center part of the cell is shown, but the distal dendrites fall outside the frame. Note the fine radiating dendrites with large widely spaced varicosities. B, An S2 amacrine cell. Note the smaller cell with more crossed dendrites and numerous beaded varicosities spaced more closely together.

Although the structure of the S2 amacrine cell was similar to that of S1 amacrine cells, it was not hard to differentiatethese two cell types. S2 amacrine cells have a smaller dendriticfield (from 300 to 1000 µm) (Vaney, 1986) and tangled, ratherthan straight, radiating dendrites. One example of a Neurobiotin-injectedS2 amacrine cell is shown in Figure 4B. Viewed in flat mount,its dendrites had a high density of small beaded varicosities(diameter, 0.9-2.2 µm; mean, 1.4 ± 0.4 µm). The mean distancebetween varicosities was 21 ± 3 µm.

S1 and S2 varicosities are adjacent to rod bipolar terminals

Intracellular injection of single cells made it possible to visualize individual varicosities at high magnification in materialthat was also labeled for rod bipolar cells. An example of anS1 varicosity is shown in Figure 5A. It can be seen that the varicosityis immediately adjacent to a rod bipolar terminal. Within thisshort stack of confocal sections (6 × 0.5 µm sections), the S1varicosity and the rod bipolar terminal appear to overlap, andthe colocalized labels produce yellow (Fig. 5B). In fact, thetwo processes are separate in three-dimensional space as can beseen from another reconstructed example in Figure 5C. This volumerendering shows that the S1 varicosity is intimately wrapped aroundthe rod bipolar terminal, and the surfaces of these two processesare adjacent (Fig. 5D). This is consistent with previous studiesin which this synaptic complex was reconstructed from serial EMsections (Strettoi et al., 1990).

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Figure 5. All varicosities are adjacent to rod bipolar terminals. A, A high-resolution view of a single S1 varicosity. The fine process trailing from the varicosity is probably a dye-coupled dendrite from another S1 amacrine cell. B, Double-label image showing the same S1 varicosity (green) adjacent to a rod bipolar terminal stained for PKC (red). C, A reconstruction of another S1 varicosity. D, A three-dimensional reconstruction of the same S1 varicosity showing it wrapped intimately around a rod bipolar terminal (red). E, Several dendrites from a single Neurobiotin-filled S2 amacrine cell. Several varicosities are indicated by arrows. F, Double-label image showing that every S2 varicosity (green, arrows) contacts a rod bipolar terminal (red).

A similar analysis was conducted for dye-injected S2 amacrine cells, and an example is shown in Figure 5E, which shows a smallarea of radiating dendrites bearing prominent varicosities, someof which are marked by arrows. In the double-label image, allof the S2 varicosities (four of four) are adjacent to rod bipolarterminals (Fig. 5F).

A quantitative analysis was performed for three S1 and three S2 amacrine cells. Each cell was a completely filled example,as determined by the sudden end of labeling at the dendritic terminalsas opposed to the slow fade that indicates an incomplete fill.This material was also double labeled with anti-PKC so that thecontacts between varicosities and rod bipolar terminals couldbe assessed by confocal microscopy. S1 amacrine cells had a meanof 283 varicosities (individual values: 228, 257, 364; SD, 72),of which an average of 276 contacted a rod bipolar terminal. S2amacrine cells had a higher number of varicosities (mean, 508;individual values: 395, 554, 575; SD, 98), of which an averageof 499 were adjacent to a rod bipolar terminal. In total, forboth S1 and S2 amacrine cells, 98% of the varicosities contacteda rod bipolar terminal. This suggests that, within the limit ofexperimental error, essentially all of the varicosities are adjacentto rod bipolar terminals. If the varicosities are synaptic contacts,then the only output from S1 and S2 amacrine cells is to the terminalsof rod bipolarcells.

One varicosity per rod bipolar cell

S1 amacrine cells are larger but have fewer varicosities. Thus, the density of varicosities is higher in S2 amacrine cells.However, it was suggested previously that the intervaricosityspacing of even S2 amacrine cells exceeds the axonal field diameterof rod bipolar terminals, and therefore any given rod bipolarcell could be contacted by only one varicosity from a single S2amacrine cell (Vaney, 1986).

To test this idea systematically, we reconstructed a patch of retina stained for PKC to identify all individual rod bipolarcells and systematically identified the contacts of dye-injectedS1 or S2 amacrine cells. An example is shown in Figure 6, in whichthe somas of 26 rod bipolar cells were identified and followedto their axon terminal structures. Each axon terminal was outlinedand numbered, and a dye-injected S1 amacrine cell was overlaid.Even three unusually close varicosities on two parallel dendritescontacted different rod bipolar cells, numbers 3, 12, and 13.Similar data were obtained for S2 amacrine cells as illustratedin Figure 5, E and F. It was rare for a single rod bipolar terminalto receive more than one varicosity, even from closely paralleldendrites. These data were confirmed by calculations that showedthe intervaricosity distance to be ~58 µm for S1 and 20 µm forS2 in near-central retina where rod bipolar cells have an averageterminal area of 100-200 µm² and a calculated diameter of 12-16 µm (Young and Vaney, 1991).Thus, as a general rule, on average, each S1/S2 varicosity contactsa different rod bipolar terminal. This is an important point because,as we shall see, this directly affects the distribution of S1and S2 amacrine cells that can contact an individual rod bipolarcell.

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Figure 6. Each rod bipolar terminal is contacted by only one varicosity from a dye-injected S1 amacrine cell. A, The somas of PKC-stained rod bipolar cells, each identified and numbered. B, Same field, focus at the border of the IPL/INL, shows that individual axons can be followed until the terminal fields of each rod bipolar cell are outlined (C). Two parallel dendrites from a Neurobiotin-filled S1 amacrine cell are superimposed (black), and it can be seen that each varicosity contacts a separate rod bipolar terminal.

Further calculations indicate that an S1 amacrine cell contacts <5% of the rod bipolar cells within its dendritic field. Thisnumber is ~50% for S2 amacrine cells, obviously higher by a factorof 10. This reflects the smaller size and greater varicosity number,yielding a much higher density for S2 amacrinecells.

S1/S2 varicosities are apposed to GABA receptors

If a model of the S1/S2 synaptic output is to be based on the distribution of varicosities, then it is necessary to show thatall the varicosities adjacent to rod bipolar terminals are, infact, synapses. The above results showing the presence of synapticmarkers and the reliable juxtaposition between varicosities androd bipolar terminals suggest that this is the case. However,we also wanted to establish the presence of postsynaptic receptorsat these sites. Both S1 and S2 amacrine cells are wide-field GABAamacrine cells, so it was appropriate to look for the expressionof GABA receptors. Previous work has shown that bipolar cellsexpress GABA_A and GABA_C receptors, both of which may be postsynapticat some contacts with S1 and S2 amacrine cells (Fletcher et al.,1998; Shields et al., 2000; Pan, 2001). In this case, we choseto use antibodies against the GABA_C receptor to demonstrate thatpostsynaptic receptors are present at the appropriatelocation.

As shown before, varicosities in the S1/S2 matrix are clustered around rod bipolar terminals. Figure 7A shows the matrix ofS1 and S2 dendrites in sublamina 5. Much of the matrix is composedof overlapping dendrites that bear no synaptic specializations,but one particularly prominent ring of varicosities is indicatedby arrows. The GABA_C receptors are located inside the ring ofvaricosities. Within the limit of confocal resolution, the S1/S2varicosities appear to be partially colocalized, but it is stillclear that the GABA_C receptors extend within the circle of varicosities.Each circle of varicosities surrounds an individual rod bipolarterminal, and the triple-label image shows that rod bipolar terminalsare well labeled with GABA_C receptors (Fig. 7B, red puncta). Furthermore,the hotspots of GABA_C receptors are located exclusively withinthe limits of the rod bipolar terminals. Comparison of the twodouble-label images shows that the GABA_C receptors occur preciselyat the sites of apposition with S1/S2 varicosities. This indicatesthat the S1 and S2 contacts with rod bipolar cells are coincidentwith the location of postsynaptic GABA receptors.

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Figure 7. GABA_C receptors are found at contact points between S1/S2 varicosities and rod bipolar terminals. A, Confocal view in whole mount, focus in sublamina 5, shows the S1/S2 matrix (green) stained with a serotonin antibody after preloading. GABA_C receptors (red) are associated with a prominent cluster of S1/S2 varicosities (arrowheads), which surround one lobe of a rod bipolar terminal. B, Same field; the rod bipolar cells, stained for PKC, are shown in blue. The lobe that fills the hole in the S1/S2 matrix is labeled with GABA_C receptor clusters at the points of contact with S1/S2 varicosities (arrowheads). C, Vertical section shows a single S1 or S2 soma and numerous dendrites descending diagonally through the inner plexiform layer to form a dense matrix in sublamina 5 (green). There are many varicosities in the matrix and occasionally one high in the IPL above the level of the rod bipolar terminals (diagonal arrow). GABA_C receptors (red) are found throughout the IPL, but they are particularly associated with S1/S2 varicosities in sublamina 5 (vertical arrow) and those high in the IPL (diagonal arrow). D, Same field; double-label image showing rod bipolar cells (blue) and GABA_C receptors (red). It can be seen that the rod bipolar cell terminals are heavily labeled with GABA_C receptors at the contact points with S1/S2 varicosities, both in sublamina 5 and higher in the IPL (diagonal arrow). This indicates that all S1/S2 varicosities contact rod bipolar terminals coincident with the expression of GABA_C receptors.

When viewed in vertically sectioned material (Fig. 7C), S1 and S2 cells appear as somas in the inner nuclear layer, with dendritesdescending to a thick matrix in sublamina 5. The soma in Figure7C could be either an S1 or an S2 amacrine cell. The S1/S2 matrixcontains prominent holes, which are the sites of large rod bipolarterminals, and the insides of these holes are lined with GABA_Creceptors. It can also be seen that GABA_C receptors are locatedthroughout the IPL, as reported previously (Enz et al., 1996).Many of these sites represent the terminals of cone bipolar cells,which also express GABA_C receptors. Within the S1/S2 matrix, however,there are particularly large and prominent clusters of GABA_C receptors.In Figure 7D, we projected almost an entire rod bipolar cell froma stack of confocal images, and as reported previously, the rodbipolar terminals are heavily covered with GABA_C receptors. Comparisonof C and D in Figure 7 shows that the rod bipolar terminals occupythe holes in the S1/S2matrix.

Most of the GABA_C receptors above the S1/S2 matrix occur on cone bipolar cells, but occasionally there are GABA_C receptorshigh on a rod bipolar cell above the terminal branch point. TheS1/S2 descending dendrites appear as short cross sections in thisview, but occasionally a large varicosity occurs high in the innerplexiform layer (Fig. 7C, diagonal arrow). These varicositiesare also coincident with GABA_C receptors localized to the rodbipolar axon (Fig. 7D, diagonal arrow, samelocation).

In the immunolabeled material, we were unable to distinguish between S1 and S2 amacrine cells, so triple-label material wasalso prepared using dye-injected single cells. In this material,rod bipolar contacts with individual varicosities can be imagedat high resolution. Figure 8, A and C, shows the previously reportedexpression of GABA_C receptors in rod bipolar terminals. In Figure8B, it can be seen that where a single S1 varicosity is adjacentto a rod bipolar terminal, it is coincident with a GABA_C receptorcluster (arrow). In Figure 8D, there are five S2 varicosities,and each one is exactly aligned with a GABA_C receptor clusteron a rod bipolar terminal. This was invariably the case, as shownby high-power confocal images: 35 of 35 S1 varicosities contactedrod bipolar cells at GABA_C receptor clusters, and 46 of 46 S2varicosities were coincident with GABA_C receptors. We concludethat all S1 and S2 varicosities are apposed by GABA_C receptorsexpressed in rod bipolar terminals.

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Figure 8. S1 and S2 varicosities are apposed by GABA_C receptors on rod bipolar terminals. A, Rod bipolar terminals (blue) express GABA_C receptors (red). At this level of the IPL, sublamina 5, nearly all of the GABA_C clusters are associated with rod bipolar terminals. B, Triple-label image shows that individual varicosities from a Neurobiotin-injected S1 amacrine cell (green) overlie GABA_C receptors (red) at the point of contact (arrowhead) with the rod bipolar terminal (blue). C, Another field showing GABA_C receptors (red) on rod bipolar terminals (blue). D, Triple-label image shows that all varicosities from a Neurobiotin-injected S2 amacrine cell (green) are associated with GABA_C receptors at contact points (arrows) with rod bipolar cells.

High varicosities are adjacent to rod bipolar axons

One example of an S1 or S2 varicosity high in the inner plexiform layer occurred in Figure 7, C and D, but a much clearerpicture can be obtained by examining this material in whole mount.If the level of focus is at the midlevel of the inner plexiformlayer, above the branch point of the rod bipolar cells, it canbe seen that some of the descending dendrites of S1 and S2 amacrinecells bear varicosities. Double-label material shows that thesevaricosities are invariably apposed to the axons of rod bipolarcells, which appear as dots at this level (Fig. 9A). In fact,almost every axon is contacted in this way. Occasionally, thereis a cluster of two or three varicosities at the same axon (Fig.9A, arrows). In a double-label vertical section, a few varicositieson rod bipolar axons can be seen high in the inner plexiform layer(Fig. 9B, arrows). These varicosities are apposed to GABA_C receptorson the axons of rod bipolar cells (Fig. 7D).

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Figure 9. High S1/S2 varicosities are adjacent to rod bipolar axons. A, Confocal view of whole-mount retina at the midlevel of the inner plexiform layer shows the descending axons of rod bipolar cells, stained for PKC (red). At this level, S1 and S2 amacrine cells, stained with a serotonin (5HT) antibody after preloading (green), have sparse, diagonally descending dendrites and a few large varicosities. Without exception, these large varicosities are wrapped around the rod bipolar axons (arrowheads). B, Similar preparation; vertical section shows rod bipolar axons (red) contacted by occasional S1/S2 varicosities (green) at the midlevel of the IPL (arrows). Overlap in this confocal stack of images results in yellow, where the rod bipolar terminal are embedded in the S1/S2 matrix in sublamina 5, and at the contact points of varicosities with rod bipolar axons.

The distribution of S1 and S2 amacrine cells with input to a single rod bipolar cell

The above evidence, together with previous reconstructions of indoleamine-accumulating amacrine cells, suggests that the varicositiesof S1 and S2 amacrine cells are synaptic structures. On the basisof this assumption and with the knowledge of cell densities andthe number of varicosities, we can estimate the number and distributionof reciprocal inputs to rod bipolar terminals. Close to half ofthe total IACs are S1 cells, and the remainder are S2 amacrinecells. The density of IACs at 1 mm inferior was ~830 cells persquare millimeter. Multiplying by the average number of varicosities(280 for S1; 500 for S2) yields 120,000 S1 and 210,000 S2 fora total of 330,000 varicosities per square millimeter. Dividingby the rod bipolar density at 1 mm inferior (4400 per square millimeter)indicates that each rod bipolar cell, on average, receives contactsfrom 27 S1 and 48 S2 cells or 75 total varicosities (in roundnumbers, 25 S1 and 50 S2). This is in good agreement with a confocalestimate of total varicosities adjacent to a single rod bipolarterminal. Because, on average, each varicosity contacts a differentrod bipolar cell, this means that each rod bipolar cell receivesinput from ~25 different S1 amacrine cells and 50 different S2amacrinecells.

To construct an anatomically realistic model, we took the actual distribution of all S1 and S2 amacrine cells, identifiedby serotonin labeling, in a patch of retina at an eccentricityof 1 mm. Within this population, the S1 amacrine cells were identifiedby tracer coupling after the intracellular injection of severalS1 amacrine cells (Li et al., 2002b). The mosaics of S1 and S2amacrine cells are plotted in the background of Figure 10. Next,we calculated the number of varicosities in a series of expandingshells around an S1 and an S2 soma. Presuming that the dendritesare linear (very close to true for S1 and a reasonable approximationfor S2), these numbers are fairly constant but fall off dramaticallyin terms of density, yielding a falling probability of hittinga single rod bipolar cell. Now, considering a single rod bipolarcell and all the S1/S2 cells within a dendritic diameter, we cancalculate the probability of hits from the S1 and S2 cells inan expanding series of shells (Fig. 10A,B). This results in a relativelyeven distribution across the shells, because although the individualprobability falls, a far greater number of potential amacrinecells are in the farthest shells.

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Figure 10. Modeling of S1 and S2 inputs to a single rod bipolar cell. A, A single rod bipolar cell (axon terminal, black) is positioned at the center of the field containing S1 somas (light gray). The field is divided into a series of expending shells 100 µm wide. In each shell, a group of S1 cells that could reach the central rod bipolar cell is circled out. B, Same analysis for S2 cells (dark gray). The S2 cells that could contact the central rod bipolar cell are indicated by the squares. C, A combined image of A and B shows both S1 and S2 inputs to the central rod bipolar cell. D, An S1 cell (left) and an S2 cell (right) are presented in the same field. The varicosities from both cells are enlarged by black dots for illustration purpose. The comparison of two circles depicts the big difference in varicosity density between S1 and S2 cells.

Several immediate consequences arise from the size and geometry of S1 versus S2 amacrine cells. First, the contributing S2amacrine cells are more numerous and much closer because theyhave smaller dendritic trees. Second, because they also have morevaricosities, yielding a much higher density, nearly all of theS2 amacrine cells within 200 µm of a single rod bipolar cell contactthat cell (Fig. 10B). These two factors mean that inhibitory inputsfrom nearby S2 amacrine cells are numericallydominant.

Third, nearby varicosities are sites of excitatory input (from other rod bipolar cells), which will generate an antagonisticsurround. Therefore, we also calculated the distribution of varicositiesfor all of the S1 and S2 amacrine cells connected to a singlerod bipolar cell. This has a sharpening effect over the simpleoverlap of contributing cells, particularly for S2 amacrine cells,because of the high density of varicosities and their proximity.The density of close-in varicosities, near an S2 soma, is muchhigher than the density around a peripheral varicosity from thelarge dendritic tree of an S1 amacrine cell (Fig. 10D). With theassumption that a signal generated from one varicosity could passthrough the whole cell because of its dendritic regenerative property(Fig. 11A, inset), the calculation yields the curves shown in Figure11A. The S2 curve has a greater influence close to the rod bipolarcell but falls off rapidly, whereas the distant portion of thecurve is accounted for by S1 varicosities. The half-width at half-heightfor the combined curves is 210 µm.

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Figure 11. Profiles of feedback from S1 or S2 cells, or both, to a single rod bipolar cell. A, The density of varicosities from S1/S2 cells that give input to a single rod bipolar cell is plotted against the distance from that single rod bipolar cell, with the assumption that signal generated by a varicosity can pass through the whole cell as demonstrated by the inset. B, Density of varicosities from S1/S2 cells that give input to a single rod bipolar cell is plotted against the distance from that single rod bipolar cell, with the assumption that signal generated by a varicosity can only propagate along the dendrite that contains this varicosity (B, inset). For both A and B, black squares represents S1 input, open circles represents S2 input, and gray diamonds represents combined inputs from S1 and S2 cells. The contours of the plot represent the spatial profiles of the feedback surround from S1 and/or S2 cells to rod bipolar cell.

This presumes that all distant varicosities can contribute equally to the output at any site, an unlikely possibility giventhe wide-field morphology of these cells. If the contributingvaricosities are restricted to those on the dendrite that contactsthe rod bipolar cell (Fig. 11B, inset), the distribution curvesare sharpened further (Fig. 11B). Now the half-width at half-heightfor the combined curves is reduced to 100 µm. This calculationsuggests that the peak for lateral inhibitory input to a rod bipolarcell via S1 and S2 amacrine cells falls within a circle of 100µm radius. This is comparable with the size of the inhibitorysurround of AII amacrine cells in the rod pathway (Bloomfieldand Xin, 2000; Volgyi et al., 2002).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Varicosities are synaptic contacts

Chemical neurotransmission, the dominant form of communication in the CNS, occurs at synapses. These are specialized structures,and typically the presynaptic machinery resides in a swellingor out-pocketing of the presynaptic neuron. S1 and S2 varicositiesare synaptic structures because (1) they contain presynaptic markerssuch as SV2 (Fig. 3) and synaptophysin, and (2) essentially everyvaricosity is intimately associated with a rod bipolar terminal,like a hand grasping a wrist (Masland and Raviola, 2000). Thisis a systematic and repeated pattern of neuronal contacts indicatingsynaptic function. (3) GABA receptors are present on the rod bipolarterminal, postsynaptic to every varicosity. We chose to examinethe distribution of GABA_C receptors, but GABA_A receptors are alsopresent at these sites (Fletcher and Wässle, 1999). The closeassociation between S1/S2 varicosities and rod bipolar terminalsstrongly suggests an interaction, but the location of a thirdreceptor marker exactly at these contact points establishes thepresence of synaptic input (Masland and Raviola, 2000). (4) Intriple-label material, the S1 and S2 varicosities alternate withAII dendrites surrounding rod bipolar terminals, as in the majorityof postsynaptic pairs (Strettoi et al., 1990). (5) Rod bipolarcells use glutamate, and glutamate receptors are present at thecontacts between rod bipolar cells and S1/S2 amacrine cells (Ghoshet al., 2001; Li et al., 2002a). (6) Finally, the varicositiesare apposed to synaptic ribbons in the rod bipolar terminal (ourunpublishedobservation).

These results are entirely consistent with serial reconstructions in several species that show extensive reciprocal inputfrom GABA amacrine cells to rod bipolar terminals (Strettoi etal., 1990; Chun et al., 1993). Because of the intermediate resolutionof confocal microscopy, this analysis can now be extended to includeall of the varicosities made by S1 and S2 amacrine cells. Varicositiescan be recognized easily using the confocal microscope, and asthe hallmark of S1/S2 output, a model of all reciprocal inputto rod bipolar cells synapses may bedeveloped.

S1 and S2 amacrine cell output goes to rod bipolar terminals only

The identification of S1/S2 varicosities as presynaptic sites makes it possible to identify the total output from S1 and S2amacrine cells to rod bipolar cells. When the varicosities wereexamined in double-label material, we found that >98% of varicositiesare adjacent to rod bipolar terminals. Within the limit of experimentalerror, this means that essentially all of the S1 and S2 outputgoes to rod bipolarcells.

There are also occasional S1/S2 varicosities above the rod bipolar terminals. This location led to the suggestion that thesehigh varicosities could have input to another target, perhapsa subtype of cone bipolar cell (Fletcher and Wässle, 1999). However,double-label images show clearly that the high varicosities areadjacent to rod bipolar axons (Fig. 9), and, in addition, GABA_Creceptors are present at these sites (Fig. 7). In fact, nearlyevery rod bipolar axon is contacted in this way. However, theseinputs are relatively few in number: one or two varicosities of~75 inputs to the entire rod bipolar terminal. Thus, the inputsto the axon account for only 1-2% of the S1/S2 input to rod bipolarcells. Occasionally, such high synapses, above the branch pointof a rod bipolar terminal, were also noted in serial reconstructions(Strettoi et al., 1990). The significance of such GABA inputsto the rod bipolar axon is unknown; these synapses might be wellplaced to veto signal transfer to the rod bipolar terminal, orthey could merely be outliers from the majority of reciprocalsynapses. In either case, including the high varicosities, allof the output from S1 and S2 amacrine cells goes to rod bipolarcells. In summary, rod bipolar cells are the only postsynaptictarget for S1/S2 amacrinecells.

Role of reciprocal feedback

Serial reconstruction has established that S1 and S2 amacrine cells receive input from rod bipolar cells with which they makeextensive reciprocal contacts. The results in this paper directlyconfirm the previous EM results and, in addition, provide a numericalestimate of this inhibitory input as well as the relative contributionsof S1 and S2 amacrine cells. The estimate of 75 total S1/S2 inputsis in good agreement with previous work (Fletcher and Wässle,1999). There is additional conventional synaptic input to rodbipolar cells from unidentified amacrine cells (Strettoi et al.,1990; Bloomfield and Dacheux, 2001). However, depolarization ofrod bipolar terminals induced IPSCs blocked by GABA antagonists,suggesting that they are mediated by reciprocal synaptic inputssuch as those made by S1 and S2 amacrine cells (Protti and Llano,1998; Hartveit, 1999; Matsui et al., 2001).

Reciprocal input to the rod bipolar terminal is mediated by both GABA_A and GABA_C receptors apposed to S1/S2 varicosities.GABA_C receptors are located predominantly on bipolar cells wherethey mediate a powerful and sustained inhibitory input (Enz etal., 1996; Fletcher and Wässle, 1999; Shields et al., 2000).In contrast, GABA_A receptors are distributed more widely, andthey produce a rapid and transient response in bipolar cells (Shieldset al., 2000). However, there is no simple relationship such thatS1 input is mediated by one type of GABA receptor and S2 by another.Both GABA receptors occur postsynaptically at S1 and S2 varicosities,but probably not at the same synapse (Fletcher et al., 1998; Fletcherand Wässle, 1999).

Intracellular recordings from rod bipolar cells, perhaps surprisingly, showed no surround responses (Berntson and Taylor,2000; Bloomfield and Xin, 2000). However, rod signals in AII amacrinecells have a small inhibitory surround with interesting pharmacologicalproperties: it is blocked by GABA antagonists and reduced by tetrodotoxin(Bloomfield and Xin, 2000; Volgyi et al., 2002). Spiking amacrinecells in the inner retina have also been shown to generate surroundcomponents of retinal ganglion cells (Cook and McReynolds, 1998;Taylor, 1999; Flores-Herr et al., 2001). These results led Bloomfieldand Xin (2000) to suggest that a spiking GABA amacrine cell suchas S1 generates the AII surround. Furthermore, an internal blockof chloride channels in the AII did not block surround activity,implying that surround inhibition is mediated by reciprocal inputsto the rod bipolar terminal (Volgyi et al., 2002).

The present results support this suggestion in several ways. (1) We have demonstrated that all S1 and S2 output goes to rodbipolar terminals. (2) S1/S2 input to rod bipolar cells is mediatedby GABA receptors. (3) This is a large and powerful inhibitoryinput derived from a dense matrix of S1 and S2 processes. (4)Modeling the distribution of S1 and S2 varicosities shows thatnearby reciprocal synaptic input to rod bipolar cells is dominatedby S2 amacrine cells. This yields an estimate of 100 µm for theradius of the inhibitory surround, much smaller than the sizeof S1 amacrine cells in particular. This matches well with physiologicalmeasurements of the AII surround (Bloomfield and Xin, 2000; Volgyiet al., 2002).

S1 and S2 amacrine cells must provide different components

The presence of two amacrine cell types, seemingly with the same synaptic contacts, has always been puzzling. In every caseso far, however, retinal cells with different morphologies havedistinct functional roles (Masland and Raviola, 2000). The analysispresented in this paper indicates that there are substantial differencesbetween S1 and S2, summarized in Table 1, which indicate thatthey play different roles. In summary, the morphology and especiallythe distribution of varicosities suggest that S2 cells must dominatethe lateral inhibitory input close to the rod bipolar cell. Incontrast, the S1 cells provide a more distant signal that mayalso be distributed through a well coupled S1 network (Vaney,1994; Xin and Bloomfield, 1997; Li et al., 2002b).


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Table 1. Summary of important differences between S1 and S2

Thus, we propose that there are three components of GABA-mediated inhibitory input at rod bipolar terminals. The first, whichwe will call local reciprocal feedback, will be very rapid orimmediate because of the architecture of reciprocal synapses.It will be large, originating from all S1 and S2 varicosities,and transient, with the same spatial properties as the rod bipolarinput. It will not carry surround signals but instead will providethe classic attributes of negative feedback, stability, increasedfrequency, and wider bandwidth. The second component will operateat medium range, within ~200 µm. This component will be numericallydominated by S2 inputs and provide the inhibitory surround forthe rod pathway. The third component, which we will call globalor network inhibition, will arise from distant inputs. It willbe dominated by S1 amacrine cells because of their larger sizeand extensive coupling (Vaney, 1994; Xin and Bloomfield, 1997;Li et al., 2002). S2 amacrine cells will have little contributionbecause of their small size and weak coupling. Together, thesethree components will modulate the spatial and temporal propertiesof rod bipolar output. This analysis also suggests that the presenceof both S1 and S2 amacrine cells is not redundant, but each cellhas the appropriate morphology to contribute different spatialcomponents of lateral inhibition in the rodpathway.

  FOOTNOTES

Received July 31, 2002; revised Oct. 1, 2002; accepted Oct. 2, 2002.

This work was supported by National Eye Institute Grant EY06515, Vision Core Grant EY10608, Vision Training Grant EY07024(E.B.T.), and an unrestricted grant from Research to Prevent Blindnessto the Department of Ophthalmology and Visual Science. S.C.M.is a Hanse-Wissenschaftskolleg Fellow (Delmenhorst, Germany) andthe grateful recipient of a sabbatical award from Research toPrevent Blindness. We thank Dr. Stephen Mills for stimulatingdiscussions, Dr. Alice Chuang and Andrzej Zych for programmingand data analysis, and Sunny Liu for technicalassistance.

Correspondence should be addressed to Dr. Stephen C. Massey, Department of Ophthalmology and Visual Science, University ofTexas-Houston Medical School, 6431 Fannin Street, MSB 7.024, Houston,TX 77030. E-mail: steve.massey{at}uth.tmc.edu.

Dr. J. Zhang's present address: Department of Ophthalmology, Baylor College of Medicine, 6565 Fannin Street, NC-205, Houston,TX77030.

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DISCUSSION
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