The Diversity of Ganglion Cells in a Mammalian Retina

doi:20026369

PeproTech - Your Source for Neuroscience Research Reagents

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

A correction has been published

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (70)

Citing Articles via Google Scholar

Google Scholar

Articles by Rockhill, R. L.

Articles by Masland, R. H.

Search for Related Content

PubMed

PubMed Citation

Articles by Rockhill, R. L.

Articles by Masland, R. H.

Pubmed/NCBI databases
Compound via MeSH
Substance via MeSH

Previous Article

The Journal of Neuroscience, May 1, 2002, 22(9):3831-3843

The Diversity of Ganglion Cells in a Mammalian Retina
Rebecca L. Rockhill, Frank J. Daly, Margaret A. MacNeil, Solange P. Brown, and Richard H. Masland
Howard Hughes Medical Institute, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02114

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We report a survey of the population of ganglion cells in the rabbit retina. A random sample of 301 neurons in the ganglioncell layer was targeted for photofilling, a method in which thearbors of the chosen neurons are revealed by diffusion of a photochemicallyinduced fluorescent product from their somas. An additional 129cells were labeled by microinjection of Lucifer yellow. One hundredand thirty-eight cells were visualized by expression of the geneencoding a green fluorescent protein, introduced by particle-mediatedgene transfer. One hundred and sixty-six cells were labeled byparticle-mediated introduction of DiI. In the total populationof 734 neurons, we could identify 11 types of retinal ganglioncell. An analysis based on retinal coverage shows that this numberof ganglion cell types would not exceed the available total numberof ganglion cells. Although some uncertainties remain, this sampleappears to account for the majority of the ganglion cells presentin the rabbit retina. Some known physiological types could easilybe mapped onto structural types, but half of them could not; alarge set of poorly known codings of the visual input is transmittedto thebrain.

Key words: anatomy; green fluorescent protein; photofill; gene gun; neuron; photochemistry

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The central issue of this study was the question: how many different representations of the visual input are transmitted bythe mammalian retina to the brain? This simple but fundamentalissue has not yet been resolved. For most mammalian retinas, twocodings are well known: one is represented by a small receptivefield with relatively sustained responses to light and linearspatial summation (X-cell), another by a cell with a larger receptivefield, phasic responses, and nonlinear spatial summation (Y-cell).However, these are not the only types of ganglion cell known toexist. In the retina of the cat, ~50% of all ganglion cells areseen anatomically to be non- $beta$ , non- $alpha$ cells (the anatomical correlatesof X and Y cells). A series of meticulous papers by Berson andhis colleagues (Pu et al., 1994; Berson et al., 1998, 1999; Isayamaet al., 2000) has now used microinjection to describe 8 typesof non- $alpha$ , non- $beta$ ganglion cells. Away from the fovea of the monkey,a similar proportion of non-midget, non-parasol cells exists.With only a few exceptions, the physiology of these differentcell types is unknown (for review, see Dacey, 1994; Rodieck, 1998).This represents a gap in our understanding of the biological basisofvision.

The physiological classification of ganglion cells has been the most detailed in rabbit of any mammalian species. The rabbiteye is large but contains only a moderate number (380,000) ofganglion cells (Vaney, 1980). Because the ganglion cells are widelyspaced over much of the retina, direct recording from this retinaminimizes the sampling error introduced by metal microelectrodes.The rabbit retina has been the subject of many studies, most systematicallythe classic work by Levick and his colleagues, more formal studiesby Daw and colleagues, and a modern analysis using multielectrodesand reverse correlation by DeVries and Baylor (Barlow et al.,1964; Barlow and Levick, 1965; Levick, 1967; Cleland and Levick,1974b; Caldwell and Daw, 1978; Vaney et al., 1981; Levick andThibos, 1983; DeVries and Baylor, 1997). Levick and his colleaguesdescribed 11 physiological types of ganglion cells. The most famousare the directionally selective cells, but other types respondedto narrowly defined stimuli, such as local contrast within thereceptive field or very rapid movements within it. Although thereare areas of disagreement (see Discussion) all workers confirmthisdiversity.

A goal in the present work was to see how well the types of cell classified physiologically match those defined by modernanatomical methods. The underlying belief is that cells with distinctmorphologies have distinct physiological functions. The evidencefor this is now overwhelming, in monkey, cat, and rabbit (Perryet al., 1984; Amthor et al., 1989b; Watanabe and Rodieck, 1989;Bloomfield, 1994; Dacey and Lee, 1994; Yang and Masland, 1994;He and Masland, 1998; Rodieck, 1998; ). Thus far, the functionsof 22 of the ~55 morphological types of neuron in the rabbit retinaare known; in every case a cell with a distinct structure hasa distinct function (for review, see Masland, 2001).

The best of the previous anatomical studies were detailed examinations of a single type of ganglion cell. Our approach herewas somewhat different. We sought to achieve a global view ofthe entire cell population in the rabbit, with less detail aboutany particular type of cell but a more systematic effort to understandat least the rough boundaries of the total population. For thiswe needed survey tools. Most ways of filling retinal ganglioncells show preferences for one or more types of neurons. Our strategywas to use a panel of methods with entirely different mechanisticbases, hoping thus to achieve a representativesample.

One was microinjection, which reveals the cells brightly but creates a diffusion gradient from cell body to periphery andhas unpredictable selectivity (some types of cells are harderto microinject than others). The second was particle-mediatedinsertion of the gene coding for the green fluorescent protein(Lo et al., 1994; Wong et al., 1998). The fluorescent proteinfills cells very evenly, so that the distal dendrites are unusuallywell seen, but has unknown selectivity. The third was a particle-mediatedintroduction of DiI, which then diffuses throughout the lipidbilayer of the cell (Gan et al., 2000). The fourth was photofilling(MacNeil and Masland, 1998; MacNeil et al., 1999), which fillsganglion cells less brightly but rapidly yields a large numberof filledcells.

The four methods were found to confirm each other. Although the frequency and clarity of a particular type of cell varied,most of them were independently revealed by each of the four methods.As expected, we encountered a large number of different morphologicaltypes of ganglion cell. Here we describe 11 of them. For reasonsthat will be discussed later, one group of cells remains incompletelycharacterized, but the 11 types clearly represent the large majorityof all ganglion cells in thisretina.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Each method used here has been described previously (Yang and Masland, 1992; Lo et al., 1994; MacNeil and Masland, 1998; Ganet al., 2000). All protocols were approved by the Subcommitteeon Research Animal Care of the Massachusetts GeneralHospital.

Photofilling. One day before the experiment, adult New Zealand white rabbits were intramuscularly anesthetized with a mixtureof ketamine (50 mg/kg) and xylazine (10 mg/kg). A local anesthetic(proparacaine hydrochloride; 2-3 drops) was applied to the eyesbefore intraocular injection of 4',6-diamidino-2-phenylindole(DAPI, 10 µg; Sigma, St. Louis, MO). Rabbits recovered overnightand were reanesthetized the next day for isolation of the retina.Each eye was removed and hemisected in oxygenated Ames medium(Sigma). The retina was dissected free from the sclera, and choroidand pieces were cut from the mid-periphery of the ventral retina,6-10 mm inferior to the optic disk. Retinal pieces were mountedonto black, nonfluorescent filter membrane (HABP; Millipore, Bedford,MA) ganglion cell side up. The membrane and attached retina werebathed in an open dish of Ames medium that was continually gassedwith 75% N₂, 20% O₂, and 5% CO₂. The animal was killed with anoverdose of anesthetic in accordance with institutionalguidelines.

Dihydrorhodamine-123 (H₂R123; Molecular Probes, Eugene, OR) was added to the bath to achieve a final concentration of 15-20µM, and the dish was placed on a microscope stage (Axioplan; Zeiss,Thornwood, NY). The retina was viewed using a 40× water-immersionobjective [Plan-Neofluar; numerical aperture (NA) 0.90; Zeiss]with filters appropriate for DAPI (excitation 340-380 nm; dichroic395 nm; emission 420 nm long-pass). Single cells in the retinalganglion cell layer were selected by using an indexed grid reticlereferred to randomly generated grid coordinates. The stage wasrepositioned so that the randomly selected cell was in the centerof the field of view. A 100 µm pinhole was placed into the backfocal plane of the epifluorescent light path to produce a spotof light, nominally 2.5 µm in diameter, directly over the selectedsoma. When the selected cell was irradiated for 5-10 min, thenonpolar, nonfluorescent H₂R123 was oxidized to the polar, fluorescentrhodamine123 (R123). Fluorescent R123 diffused throughout thecytoplasm of the irradiated cell. Several cells per piece of retinawere filled, after which the tissue was rinsed and coverslippedin fresh Amesmedium.

The cells were imaged using a Zeiss Axioplan microscope equipped with high numerical aperture objectives (20×, NA 0.75, Plan-Apochromat;40×, NA 1.0 oil, Plan-Apochromat; 40× and 63×, NA 1.2 water, C-Apochromat;Zeiss), a sensitive digital camera (MicroMax cooled CCD camera;Princeton Instruments, Trenton, NJ) and image acquisition andprocessing software (MetaMorph; Universal Imaging Corporation,West Chester, PA). The imaging software drove an external shutter(Vincent Associates, Rochester, NY) and a z-axis focus motor (LudlElectronic Products, Hawthorn,NY).

Two sets of images were collected for each cell. Photofilled cells were imaged using a narrow band width filter set specificfor rhodamine (excitation 488-512 nm, dichroic 545 nm, emission526-562 nm). Subsequently, a through-focus of the DAPI-stainednuclei was collected, to measure the thickness of the inner plexiformlayer and determine the level of stratification of the photofilledcells.

Cell injection. Pieces of isolated retina were mounted ganglion cell side up on a glass coverslip previously coated with 3-15µl of Cell-Tak (40240, Collaborative Biomedical Products, Bedford,MA). In some cases, pieces of retina were mounted ganglion cellside up on filter paper and held in place with mesh and a platinumring (Yang and Masland, 1992). Retinal ganglion cells labeledwith DAPI, Fast blue, or acridine orange were visualized for injectionin fixed (Tauchi and Masland, 1985) or living (Yang and Masland,1992) tissue, as previously described. Cells were filled with4% Lucifer yellow using a 40× water-immersion objective (ZeissAchroplan, NA 0.75). The tissue was then fixed for 1 hr in 4%paraformaldehyde (Ted Pella, Redding, CA) or overnight in 2%paraformaldehyde.

The tissue was mounted in Vectashield (Vector Laboratories, Burlingame, CA) and photographed. Alternatively, to convert theLucifer Yellow into a permanent reaction product, the tissue wasprocessed with immunohistochemistry by first incubating the tissueovernight in 0.5% Triton X-100 and 4% normal goat serum overnight.The tissue was then incubated for 3 d in the same solution withbiotinylated anti-Lucifer yellow (1:200, A-5750; Molecular Probes,Eugene, OR) followed by 1 d in ABC solution (Vectastain EliteABC kit; Vector). Diaminobenzidine (Kirkegaard and Perry Laboratories,Gaithersburg, MD) was used to visualize thecells.

Gene transfer. Transformation of the plasmid pEGFP (GenBank accession number 6084; Clontech, Palo Alto, CA) into Escherichiacoli (DH5 $alpha$ ) and bacterial cell culture was performed accordingto standard procedures (Sambrook et al., 1989). For large-scalepreparations of purified plasmid, the Qiagen (Valencia, CA) MaxiPrep kit wasused.

Gold particles were coated with the green fluorescent protein (GFP) plasmid using the protocol of Lo et al. (1994) and Wonget al. (1998). For each preparation, 12.5 µg of plasmid, 100 µlof 1 M CaCl, and 100 µl of 0.05 M spermidine stock solution wereadded to 12.5 mg of gold particles (0.6 µm; Bio-Rad, Hercules,CA) under continuous, slow vortex. Plasmid was allowed to attachto the gold particles for 10 min before recentrifugation and resuspensionin absolute ethanol. The gold-plasmid suspension was then appliedto the inner surface diameter of plastic tubing using a tube prepstation (Bio-Rad) and dried in place withnitrogen.

Young New Zealand White rabbits (P15-P17) were studied, because some components of the procedure (either gene transfer orthe subsequent time in vitro) are more successful in young animalsthan in adults (Wong et al., 1998). At this age the retina isstill expanding in diameter, but the ganglion cells show theiradult physiological types (Masland, 1977). The gene gun (Bio-Rad)was loaded with the gold plasmid-coated tubing. A nylon mesh (R-CMN-90;Small Parts Inc., Miami Lakes, FL) was placed at the nozzle ofthe gun to obtain better gold particle dispersion. The gun wasprimed to 100 psi, and the retina was flattened out on an agarplate. The nozzle was placed over the entire retina and fired.The retina was immediately rinsed in fresh Ames medium and thensuperfused in oxygenated Ames for 6 hr on a rocker inside an incubatedchamber (30°C). After this initial incubation, the GFP-transfectedretina was further incubated in fresh Ames medium for an additional12 hr at room temperature. GFP-expressing cells were imaged thenextday.

Particle-mediated introduction of DiI. This was performed as described by Gan et al. (2000). In brief, ~50 µl of methylenechloride was added to 50 mg of 1.6 µm or 0.6 µm gold particles(Bio-Rad), and the mixture quickly spread evenly onto a glassslide. One hundred microliters of a 20 mM solution of DiI (MolecularProbes) in methylene chloride was spread evenly over the driedgold beads. The gold beads were scraped off the glass slide, placedin 3 ml of distilled water, and sonicated for 10 min. Tubing ina Bio-Rad tubing prep station was pretreated with Polyvinyl-pyrrolidone(Sigma) in isopropyl alcohol (10 mg/ml), and the beads were driedonto the inside. The retinas were shot at 80-100 psi without theuse of a mesh screen, then incubated in Ames medium for 30 minto 1 hr at room temperature while rocking. After incubation, theretinas were fixed in 4% PFA, washed three times for 10 min eachin 0.1 M phosphate buffer, mounted in Vectashield, and immediatelyviewed and/orimaged.

Measurement of dendritic field area. The total number of cells required to achieve a retinal coverage (Table 1) was computedfrom the measured dendritic field area for each of the 11 celltypes. This was done from printed images similar to those shownin Figures 1 and 2. For each cell type, a series of 5-10 especiallywell filled cells was chosen. The dendritic field was definedby a convex polygon (Rodieck, 1998) connecting the distalmosttips of the dendrites. Because this is the way most of the previouslypublished values have been obtained, the diameter was taken asthe mean of the longest and shortest diameters, and the dendriticfield area was computed from that value. All of the cells studiedby photofilling and most by the other methods were from a definedeccentricity 6-10 mm ventral to the optic fiber bundles.


View this table:
[in this window]
[in a new window]
Table 1. Cell numbers as predicted from dendritic field size and an assumed coverage factor of 1.8 (see Results)

View larger version (132K):
[in this window]
[in a new window]
Figure 1. ON-OFF directionally selective ganglion cells (G7 in this nomenclature) as shown by each of our cell-filling methods. The cells are distinguished by their bistratified, medium-field, arbor and recurving dendrites (Amthor et al., 1989b; Vaney, 1994; Yang and Masland, 1994). The cells are bistratified, and an out-of-focus arbors can be glimpsed for the Lucifer-filled cell, which was photographed using an objective with low numerical aperture.

View larger version (642K):
[in this window]
[in a new window]
Figure 2. The major types of ganglion cells identified in our series. Methods of filling were as follows: G1, Top, Lucifer, immunolabeled to diaminobenzidine; bottom, DiI; G2, top and bottom, DiI; G3, ON and OFF Arbor, DiI; G4 ON, Lucifer immunolabeled to diaminobenzidine; G4 OFF, DiI; G5, top, GFP; bottom, DiI; G6, top, DiI; bottom, photofill; G8, top and bottom, photofill; G9, top and bottom, GFP; G10, top and bottom, GFP; G11 ON, Lucifer yellow; G11 OFF, DiI. Scale bars, 100 µm. (Figure 2 continues.)

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The appearance of cells filled by each of our methods is illustrated, for the well known ON-OFF directionally selective cell,in Figure 1. Photofilling and injection of Lucifer yellow yielda bright soma and a gradient of brightness from proximal dendritesto distal. Their greatest limitations are for the largest andsmallest cells, the largest because it is hard to fill the distaldendrites of large (>400 µm dendritic field diameter) neurons,and the smallest because the dendrites are obscured by flare fromthe bright cell body. Labeling by GFP expression was more uniform.The cell body was only slightly brighter than the dendrites, andthe proximal dendrites were only slightly brighter than the distalones. GFP often filled the dendrites brightly to their tips; atleast for small and medium-sized cells, it was often possibleto cleanly visualize the distalmost end of the dendrites, somethingless consistent with photofilling or Lucifer injection. Particle-mediatedintroduction of DiI gave, in many cases, striking filling of thecells with excellent visualization of dendritic detail. Its drawbackswere obscuring of detail in the vicinity of the DiI-coated particleand a tendency for several cells to be labeled at once by a singleparticle.

Brief descriptions of the cells follow, in order of their dendritic field diameters. The descriptions use a neutral nomenclature.The previous literature is large and sometimes contradictory,and it consists primarily of drawings of cells, which embody aninherent step of interpretation by the artist. More important,names that intrinsically suggest homology between ganglion celltypes in different species are risky (for instance, controversyabout the homology of cat $beta$ and monkey midget cells). We willseparately point out cross-species correspondences in specificindividual instances where they seem especiallyclear.

Eleven types of ganglion cell

G1 cells were flatly arborizing neurons with a dense, narrow, dendritic field (Fig. 2). The dendritic arbors were 150-200µm in diameter and branched narrowly in stratum S3 of the innerplexiform layer. The primary dendrites were thick and taperedfrom soma to periphery. They branched frequently along their courseand exhibited abrupt bends and turns. The dendritic field containedmany short (8-10 µm) dendritic branches. The distalmost branchesalmost uniformly ended in one or more short dendrites that exitedthe primary dendrite at a flat angle. Commonly there was a pairof such terminal dendrites. Cardinal features of the arbor ofthe G1 cell were thus a tapering primary dendrite and distal dendritesterminating in a pair of short dendrites, like a flattened "y".

These cells have been identified as local edge detectors (Levick, 1967) on the basis of cells with that physiology injectedafter recording (Amthor et al., 1989b; Roska and Werblin, 2001).Their size, level of stratification, and branching pattern leavelittle doubt as to the morphologicalmatch.

G2 cells shared some morphological features with the G1 cells and also stratify narrowly in S3 but had larger, sparser, dendriticarbors and fewer short processes. In addition, they exhibiteda distinctive branching pattern. G2 cells had three to five majordendrites. These emitted many much smaller branches. The secondarybranches could exit the primary dendrites at various angles, notuncommonly exiting at almost a 90° angle. The primary dendritesoften traversed the field with a smooth curve, but sometimes exhibiteda single sharp bend 30-40 µm from the soma, so that a primarydendrite began with a straight course then made an abrupt bend.The dendritic arbor of the G2 cells, like that of the G1 cells,was flat; most of the arbor could usually be captured within asingle optical plane. The dendritic arbor was often asymmetric.For many of these neurons, many dendrites were present to oneside of the soma of the cell, whereas the other side containedfewer. Often there was a substantial dendrite-free zone. Sometimesthis zone constituted only a narrow (45-90°) sector, but in otherinstances the dendritic field covered an arc of only 180°.

The G2 cells have features in common with the zeta cells of Berson et al. (1998) in the cat. Both have narrow dendritic arbors(zeta cells were ~350 µm, at 5 mm retinal eccentricity from thevisual streak of the cat). The branching pattern is similar. Agap in dendritic arbor is observed in both species (Berson etal., 1998, their Fig. 1). These cells appear not to have beenidentified physiologically in either the rabbit orcat.

G3 cells had small, bistratified dendritic arbors. They have three or four primary dendrites that arborize near the borderbetween S4 and S5. These dendrites show few specializations. Processesdescend from the primary dendrites to a second arbor, locatedin S2 and consisting of frequently branching dendrites. Many short(5-10 µm), thin dendrites give the outer (OFF) arbor a delicateappearance. The dendritic field diameter of the cell ranges from200 to 300 µm.

No cells of this morphological type have been injected after recording. They would be predicted to have ON and OFF responses.Conceivably they could be chromatically coded cells analogousto the blue-yellow cell extensively studied in the monkey (Calkinset al., 1998; Dacey, 2000). Blue-sensitive, chromatically opponentganglion cells have been described in recordings from ganglioncells of the rabbit (Caldwell and Daw, 1978; Vaney et al., 1981).

G4 cells had dendritic arbors only slightly larger than G2 cells and G3 cells; but they had a dramatically different patternof branching and stratification. They had two to four thick primarydendrites, which emitted a profusion of thinner and shorter (1-5µm) branches. Secondary dendrites exited the primary dendritesat no consistent angle; they could branch acutely away from thesoma, nearly perpendicularly, or point back toward the soma. Theyoften ended with a swelling or varicosity at the tip. Becauseof the great profusion of these fine dendrites, they dominatedthe visual appearance of the dendritic arbor and the large numberof varicosities that they bore caused an easily recognizable phenotype.G4 cells came in ON and OFF varieties. Their stratification withinthe inner plexiform layer was thick, occupying the strata betweenS3 and S4 or S2 and S3, respectively, of the inner plexiform layer.This contributed to the dense appearance of their arbor when viewedin single opticalplanes.

These cells have features suggesting homology to the $beta$ cell of the cat (Boycott and Wässle, 1974). They are narrowly branchingcells, although size alone is not definitive because G1, G2, andG3 have dendritic field diameters in the same approximate range.More important are the pattern of extremely thin dendrites, withtheir characteristic multitude of varicosities, and their branchingwithin several sublaminas of the inner plexiform layer. This wouldsuggest that they should be brisk-sustained cells, also indicatedby injection after recording (Amthor et al., 1989b; Roska andWerblin, 2001).

G5 cells had dendritic field diameters ~300 µm in diameter, substantially larger than those of G1-G4. They had four to sixprimary dendrites. The primary dendrites tapered little from somato periphery. Secondary dendrites could exit the primary dendriteat any point along its course. Whereas there were usually branchpoints near the ends of the primary dendrites, secondary dendritescould also exit from intermediate points, closer to the soma ofthe cell, from which point they could extend to the perimeterof the dendritic field. The secondary dendrites were remarkablyuniform in diameter. A common observation was a short (~10 µm)terminal dendrite that fishhooked back toward the cell body, sothat its tip pointed toward the interior of the dendritic field.A distinctive feature of these cells was that almost all of thedendrites-primary and secondary-exhibited frequent smooth curves,with radii of ~5-15 µm. Secondary dendrites effectively filledthe potentially empty spaces in the dendritic arbor so that thedendritic arbor covered the dendritic field very evenly. All ofthese cells appeared to be OFF cells; their dendritic arbors occupieddepths at 20-40% of the thickness of the inner plexiform layer(S2).

A medium-field cell termed eta has been described by Berson et al. (1999) in the cat, but the eta cell lacks the smoothlycurving appearance of the G5 cell and is more broadly stratified.None of the cells injected after recording (Amthor et al., 1989a,b;Yang and Masland, 1994; He and Masland, 1998) had thismorphology.

G6 cells were medium-field neurons characterized by an irregular, disorganized-looking dendritic arbor. They had three tosix primary dendrites and a dendritic arbor spanning 300-500 µmof the retina. Their dendritic branching lacked the orderly, radiatingpattern evident for most wide-field neurons of the retina. Secondarydendrites could be emitted at almost any distance from the cellbody and at any possible angle. Sometimes they ran at 90° to aprimary dendrite. Because of this lack of regularity, the dendritesoften crossed one another. There were few side branches. One resultwas that the dendritic field was a very uneven one, in which somepatches of the retina were covered by many dendrites and otherpatches were not covered at all (our laboratory nickname for themwas "drunk" cells.) Had only a few examples been encountered,one might be tempted to interpret these cells as developmentalaccidents, but they were repeatedly seen in the photofilled andGFP samples and have been observed by others, as discussed below.The dendrites had a uniform caliber. This again contrasts withmany other ganglion cells, whose dendrites taper from cell bodyto periphery. The dendrites bore fewspecializations.

These cells were multistratified in layers S4 and S5. Their branching very much resembles that of epsilon cells stained inthe monkey retina (Rodieck, 1998). An apparently similar cellwas injected after recording in the rabbit retina (Amthor et al.,1989b, their Fig. 19) and identified with the "uniformity detector"described in physiological experiments by Levick (1967). Suchcells have a high maintained rate of firing. It is suppressedby changes in the pattern or amount of light falling anywherewithin the receptive field, be the change a brightening, dimming,or movement of thestimulus.

G7 cells are the ON-OFF directionally selective cells (Fig. 1) that have been extensively described in the rabbit retina (Amthoret al., 1989b; Famiglietti, 1992; Vaney, 1994; Yang and Masland,1994). They are medium-field neurons with bistratified dendriticarbors. The pattern of dendrites contains many recurving loops,giving the whole arbor a distinctive honeycombedappearance.

G8 cells had large, sparsely branched dendritic arbors. Because the arbors had an irregular shape, and because we were unlikelyto have filled the dendrites to their tips, an average total dendriticfield diameter could only be approximately measured. From whatcould be seen, although, the extent of their dendrites was surelynot <400 µm. These neurons commonly had a fusiform soma, emittingone major dendrite at each pole. Sometimes a third dendrite wasemitted at 90° to the long axis of the cell. In another variant,two large dendrites exited the soma at 180° from each other. However,after 50-100 µm, a third major branch was emitted from one ofthe original two, often at a 90° angle. The arbor of primary dendritesin such cases thus consisted of three major dendrites, two directlyexiting the soma and a third exiting one of the primary dendritesat 90°. The cells were sparsely branched and each branch was relativelystraight; it was common for a primary or secondary dendrite totraverse >300 µm without significant curvature. The dendriteswere smooth and had few of the fine-scale specializations observedfor many other types of retinal ganglioncells.

Amacrine cells with this general appearance were observed, but axons of the G8 cells were sometimes visualized. Most of theG8 cells stratified in S4, but wide-field cells stratifying inother layers were also seen (see below). In the monkey a similarganglion cell was termed a gamma cell (Rodieck, 1998). These cellsappear not to have been identifiedphysiologically.

G9 cells look similar to G10 cells but stratify at the border of S1 and S2 of the inner plexiform layer (IPL) in the OFF sublamina.The G9 cells were morphologically similar to the OFF delta ganglioncells studied in cats, which can be visualized as a populationby their accumulation of dihydroxytryptamine (Wässle et al.,1987; Dacey, 1989). In neither species has an OFF delta cell beeninjected after recording; their physiological function thereforeremainsunknown.

G10 cells somewhat resembled $alpha$ (G11) cells but were smaller in size, arborized at different levels of the IPL, and had a differentbranching pattern. Their proximal dendrites were thinner thanthose of $alpha$ cells. Their primary dendrites often gave rise to longsecondary dendrites, which sometimes ran to the perimeter of thedendritic field. This contrasts with $alpha$ cells, whose dendritesusually divide into daughters of more or less equallength.

G10 cells are clearly the ON delta cells previously studied in detail (Buhl and Peichl, 1986; Pu and Amthor, 1990; Famiglietti,1992). The ON delta cells project selectively to the medial terminalnucleus of the accessory optic system. Recording from these cellsshowed them to be the ON-type directionally selective cell (Oysteret al., 1980; Amthor et al., 1989b; He and Masland, 1998).

G11 cells are the $alpha$ cells, a constant feature of most mammalian retinas (Peichl et al., 1987a). They were the largest cellsin our sample and came in ON and OFF varieties. Physiologically,these are the brisk transient cells of Cleland and Levick (1974a),otherwise known as Y cells (Enroth-Cugell and Robson, 1966; Hochsteinand Shapley, 1976a,b; Caldwell and Daw, 1978).

Unclassified cells

A trivial kind of unclassifiable cell is represented by scarce cells that appear to be developmental accidents. An exampleis shown in Figure 3A. Sometimes we had only a single clear example.Our primary reason for believing that this apparent type of cellis a developmental accident is its scarcity. To cover the retina,a cell with this narrow a dendritic field would need to be presentin high numbers. Even if one of our methods had a selectivityagainst this particular type of cell, it is not likely that allfour methods would select against it and a sample as large asours should have revealed multiple examples. Reproducible developmental"accidents" have been shown to occur; such cells can have reproduciblemorphologies, but the numbers of cells varies widely from animalto animal and they have absolute densities that leave large gapsin the retinal coverages (Wässle and Boycott, 1991; Masland etal., 1993).

View larger version (122K):
[in this window]
[in a new window]
Figure 3. Unclassified cells. A shows a small cell, clearly filled but rarely encountered by any of our methods; these appear to be developmental accidents. B-D show medium-field cells that we were unable confidently to assign to one of the other types. All are labeled with DiI. Scale bars, 100 µm.

More problematic are cells that could be transition cases among clearer types or that lacked sufficiently distinctive differencesin morphology and stratification to allow them to be reproduciblyidentified by morphological criteria alone. Delta-like cells (Fig.3B-D) resembled the G9 and G10 cells in dendritic field size andoverall density of dendrites but had distinctive features thatmade us hesitate to force them into a single type. As describedabove, our canonical G10 cell was the ON-DS cell, recognized inall four of our samples and independently shown as a functionaltype by injection after recording (Amthor et al., 1989b; He andMasland, 1998) and by retrograde tracing from its terminal axonalprojection (Buhl and Peichl, 1986). However, we also encounteredmedium-sized cells that varied in morphology from the previouslydescribed G10 cells. In their overall appearance, and their heterogeneity,these resemble a group of cells previously injected in the cat(Stanford, 1987, their Fig. 4). One group had radiating branchessomewhat like those of an $alpha$ cell (G11), but were smaller than $alpha$ cells and had oval rather than multipolar somata. However, variantson this plan existed and we could not find features clear enoughto decide whether these represent one additional cell type, severaltypes, or a variant of the standard G9 or G10cells.

The second group of unclassifiable cells were sparsely branched wide-field cells. Whereas the G10 and G11 cells describedabove are unambiguously clear wide-field entities, there wereother wide-field cells that were not readily classifiable. Asfor amacrine cells, (MacNeil and Masland, 1998; MacNeil et al.,1999) wide-field cells vary more in their level of stratificationthan they do in their dendritic morphology. However, distinguishingamong types of cells on the basis of stratification alone is perilousfor wide-field cells; it often requires an absolute judgment ofthe depth of a few thin dendrites, with no reference point indepth except the margins of the inner plexiform layer. For amacrinecells, there appears to be at least one wide-field cell for eachof the five strata of the inner plexiform layer. Conceivably asimilar situation exists for ganglion cells, but we cannot becertain because these cells, which can span 1-2 mm in dendriticdiameter, can achieve coverage of the retina using a very lowabsolute frequency of neurons of each type, and few examples weresampled.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have divided the observed ganglion cells into 11 types (Fig. 4), and this seems to be a minimum. Conventional practicewould make this 13 types, because ON and OFF versions of G4 andG11 would be counted as separate entities. Marc and Jones (2002)made a multivariate analysis of the amino acid content of rabbitganglion cell somas. They distinguished 14 types, a number closeto ours. There may well be one or more other medium-field celltype, among the cells we have called "delta-like." There may alsobe further functional divisions among the wide-field cells, althoughthese cells are relatively few and poorly understood-they couldserve similar functions despite differing stratification. Withthese exceptions, our four different methods seem to have revealedmost of the types that exist, at least with any frequency; bythe end of the experiments we were no longer encountering "new"types.

View larger version (37K):
[in this window]
[in a new window]
Figure 4. The branching and level of stratification for the 11 types of neuron identified. Scale bar, 100 µm.

Eleven types of ganglion cell could cover the retina within the known ganglion cell density

Retinal ganglion cells cover the retina evenly; they tile its surface (Wässle and Riemann, 1978; Wässle et al., 1981, 1983;Rockhill et al., 2000). This principle, which has been confirmedfor at least 20 retinal neurons of various types, allows us toanswer, at least to a first approximation, the following question:are there enough ganglion cells in the rabbit retina to accommodate11 functional types of ganglion cells? If we have artificiallycreated too many types, the requirement that each cover the retinawould dictate that the total number of ganglion cells exceed thenumber of ganglion cells known toexist.

The coverage factor of a retinal neuron is given by the product of its dendritic field area and spatial density (Wässle andRiemann, 1978). For simplicity, we assumed a uniform coveragefactor of 1.8 for all cells (DeVries and Baylor, 1997). From thedendritic field area and coverage, we computed the spatial densityat which each cell should be present. The analysis is summarizedin Table 1, which shows each of the cell types described heretogether with its dendritic field area. The individual densitiesare summed to reach a predicted total of 307 cells/mm². This may be compared with the independently known density ofretinal ganglion cells at this eccentricity, 540 cells/mm² (Vaney, 1980; Masland et al., 1984).

The largest uncertainty in this analysis is the assumed value of the coverage factor, which was taken as 1.8 on the basisof work by DeVries and Baylor (1997). They measured the physiologicalcoverage, which should closely match the dendritic field area(Peichl and Wässle, 1983; Yang and Masland, 1994): the advantageof their study is that many different types of ganglion cell weresurveyed by a single set of criteria. Anatomical estimates ofdendritic field coverage range from 1.4 for DS cells (Vaney, 1994)to 3.2 for $alpha$ cells (Peichl et al., 1987b), and the predicted totalnumber of ganglion cells would scale linearly with the assumedcoverage factor. Because of this uncertainty, the absolute coveragesshown in Table 1 are not definitive. Even if one assumes a universalcoverage of as high as 3, however, the predicted number of cells(564 cells/mm²) is close to the number of ganglion cellsavailable.

The match between morphological types and physiological types is only partial

Three generations of physiological results are summarized in Table 2, beginning with the classic studies by Levick (1967).The comparison brings good news and bad news. The good news isthat a substantial group of ganglion cells of the rabbit retinaare now fairly securely understood. There is agreement among physiologistsand the structural counterpart can be identified with reasonableconfidence. These include the brisk transient and brisk sustainedcells, two types of directionally selective cells, the local edgedetector, and the uniformity detector. The bad news is that thereexists a substantial group of neurons whose properties are farless clear. Caldwell and Daw (1978) found sluggish transient andsluggish sustained groups of neurons, whereas DeVries and Baylor(1997) did not find a distinction between the two, nor did theydetect a uniformity detector or orientation sensitive neurons.On the other hand, DeVries and Baylor (1997) identified neuronsthat they termed OFF delayed and OFF eta, which were not observedby the earlier workers. Not included in Table 2 is an importantrecent study by Roska and Werblin (2001) that uses an entirelydifferent physiological taxonomy. Because this has not yet beendescribed in detail, matching their results to the present onesremains a future task. Presumably G2 and G8, for which we cannotfind a ready counterpart, will be identified with some types ofcells included in these groups; another possible source of cellsis the delta-like neurons, which we ourselves had difficulty resolving.In the end, however, this matching cannot take place without adefinitive physiological classification. The match of physiologicalwith morphological types is thus incomplete. There are morphologicaltypes for which a physiological counterpart cannot yet be identifiedand physiological types that (even if there were complete agreementamong electrophysiologists) cannot be morphologically identified.As noted at the outset (in introductory remarks), it appears thata similar situation pertains for the retinas of the cat and monkey.


View this table:
[in this window]
[in a new window]
Table 2. Taxonomies of receptive field types in the rabbit retina

Implications for function: non-X, non-Y codings of the visual input

These results show that the flow of information from retina to brain has been incompletely described even for the rabbit,one of the most intensively studied and experimentally tractableof mammalian retinas. Some of the gaps were described in the precedingsection. But substantial questions are also raised among thoseganglion cell types whose receptive field type isknown.

For example, which type of ganglion cell is used for high-acuity (form) vision? The traditional view would be that a $beta$ -likecell, presumably G4, with brisk sustained (X-like) responses doesthis job. But two other monostratified neurons, G1 and G2, havenarrower dendritic arbors than G4. Ganglion cell G1, the "localedge detector", has been treated as rare because of low encounterfrequencies in electrophysiological experiments, but this is almostcertainly because of its small soma size. There is every reasonto think that these are more numerous than the $beta$ -like cells: despitetheir small size they were encountered by all four of our cell-fillingmethods, and cells this small would, from first principles, needto be numerous to cover the retina. If so, what do they contributeto vision? The local edge detector responds to local contours,but responds best if they occupy only a fraction of the receptivefield center. Why is this neuron-a narrower filter than a $beta$ cell-themost numerous ganglion cell in this retina? And what is the codingtransmitted by G2, which should be nearly aspopulous?

By contrast, what is the role of the moderately wide-spreading "uniformity detectors," G6 in our listing? These cells arereported to be suppressed by contrast; they have a relativelyhigh maintained rate of firing that is silenced by any form ofstationary or moving contour. Perhaps they are some sort of primitive"early warning system" that does not participate in higher visualfunction, but there is no a priori reason for this to be so: theyappear to be more numerous than the $alpha$ (Y) cells, which are believedcritical for higher visualprocessing.

Where do we go from here?

As evident from Table 2, even skilled electrophysiologists have failed to achieve a consensus on the types of receptive fieldin the rabbit retina-the set of codings transmitted by the rabbitretina to the brain. An alternative approach is to base a typologyon ganglion cell structure-the cells are immutable, physical objectsthat do not change with the variations of observational technique(type of electrode, choice of stimulus sets, method of data analysis).Newly developed methods for backfilling living neurons from definedcentral targets should speed the characterization of the morphologicaltypes whose physiology remains unknown; the cells can now be specificallytargeted for recording in isolated retinas (Yang and Masland,1992; Dacey and Lee, 1994; Pu et al., 1994; Dacey et al., 2001).The same method will also reveal the central targets of the cellsand thus inform as to theirfunction.

However, this will only build a platform for future work (quantitative modeling, knock-out experiments) in those cases wherethe type of neuron is very distinctive morphologically. Despitemuch experience with the identification and classification ofretinal cell types (Tauchi and Masland, 1984, 1985; Sandell andMasland, 1986; Sandell et al., 1989; Tauchi et al., 1990; Maslandet al., 1993; Jeon and Masland, 1995; He and Masland, 1998; MacNeiland Masland, 1998; He et al., 1999; Brown and Masland, 1999; MacNeilet al., 1999) a fraction of ganglion cells could not be confidentlydistinguished by us from morphology alone. Such distinctions couldprobably be made, by measuring the depth of stratification moreprecisely, using fiducial marks such as the depth of the ChATbands. However, such methods are far too cumbersome for routineuse. For systematic progress, cell-type-specific marker proteinswill probably need to be found or created (Gustincich et al.,1997; Feng et al., 2000; Puopolo et al., 2001) (L. Huang, M. Max,R. F. Margolskee, H. Su, R. H. Masland, and T. Euler, unpublishedobservations).

  FOOTNOTES

Received Jan. 16, 2002; revised Feb. 19, 2002; accepted Feb. 21, 2002.

R.H.M. is a Senior Investigator of Research to PreventBlindness.

Correspondence should be addressed to Dr. Richard H. Masland, Wellman 429, Massachusetts General Hospital, 50 Blossom Street,Boston, MA 02114. E-mail: masland{at}helix.mgh.harvard.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Amthor FR, Takahashi ES, Oyster CW (1989a) Morphologies of rabbit retinal ganglion cells with concentric receptive fields. J Comp Neurol 280:72-96[ISI][Medline].
Amthor FR, Takahashi EH, Oyster CW (1989b) Morphologies of rabbit retinal ganglion cells with complex receptive fields. J Comp Neurol 280:97-121[ISI][Medline].
Barlow HB, Levick WR (1965) The mechanism of directionally selective units in rabbit's retina. J Physiol (Lond) 178:477-504[Free Full Text].
Barlow HB, Hill RM, Levick WR (1964) Retinal ganglion cells responding selectively to direction and speed of image motion in the rabbit. J Physiol (Lond) 173:377-407.
Berson DM, Pu M, Famiglietti EV (1998) The zeta cell: a new ganglion cell type in cat retina. J Comp Neurol 399:269-288[ISI][Medline].
Berson DM, Isayama T, Pu M (1999) The eta ganglion cell type of the cat retina. J Comp Neurol 408:204-219[ISI][Medline].
Bloomfield S (1994) Orientation-sensitive amacrine and ganglion cells in the rabbit retina. J Neurophysiol 71:1672-1691[Abstract/Free Full Text].
Boycott BB, Wässle H (1974) The morphological types of ganglion cells of the domestic cat's retina. J Physiol (Lond) 240:397-419[Abstract/Free Full Text].
Brown SP, Masland RH (1999) Costratification of a population of bipolar cells with the direction selective circuitry of the rabbit retina. J Comp Neurol 408:97-106[ISI][Medline].
Buhl EH, Peichl L (1986) Morphology of rabbit retinal ganglion cells projecting to the medial terminal nucleus of the accessory optic system. J Comp Neurol 253:163-174[ISI][Medline].
Caldwell JH, Daw NW (1978) New properties of rabbit retinal ganglion cells. J Physiol (Lond) 276:257-276[Abstract/Free Full Text].
Calkins DJ, Tsukamoto Y, Sterling P (1998) Microcircuitry and mosaic of a blue-yellow ganglion cell in the primate retina. J Neurosci 18:3373-3385[Abstract/Free Full Text].
Cleland BG, Levick WR (1974a) Brisk and sluggish concentrically organized ganglion cells in the cat's retina. J Physiol (Lond) 240:421-456[Abstract/Free Full Text].
Cleland BG, Levick WR (1974b) Properties of rarely encountered types of ganglion cells in the cat's retina and an overall classification. J Physiol (Lond) 240:457-492[Abstract/Free Full Text].
Dacey DM (1989) Monoamine-accumulating ganglion cell type of the cat's retina. J Comp Neurol 288:59-80[ISI][Medline].
Dacey DM (1994) Physiology, morphology and spatial densities of identified ganglion cell types in the primate retina. Ciba Found Symp 184:12-34[Medline].
Dacey DM (2000) Parallel pathways for spectral coding in primate retina. Annu Rev Neurosci 23:743-775[ISI][Medline].
Dacey DM, Lee BB (1994) The "blue-on" opponent pathway in primate retina originates from a distinct bistratified ganglion cell type. Nature 367:731-735[Medline].
Dacey DM, Peterson BB, Gamlin PD, Robinson FR (2001) Retrograde photofilling reveals the complete dendritic morphology of diverse new ganglion cell types that project to the lateral geniculate nucleus in macaque monkey. Invest Ophthalmol Vis Sci 42:S114.
DeVries SH, Baylor DA (1997) Mosaic arrangement of ganglion cell receptive fields in rabbit retina. J Neurophysiol 78:2048-2060[Abstract/Free Full Text].
Enroth-Cugell C, Robson JG (1966) The contrast sensitivity of retinal ganglion cells of the cat. J Physiol (Lond) 187:517-552.
Famiglietti EV (1992) New metrics for analysis of dendritic branching patterns demonstrating similarities and differences in ON and ON-OFF directionally selective retinal ganglion cells. J Comp Neurol 324:295-321[Medline].
Feng G, Mellor RH, Bernstein M, Keller-Peck C, Nguyen QT, Wallace M, Nerbonne JM, Lichtman JW, Sanes JR (2000) Imaging neuronal subsets in transgenic mice expressing multiple spectral variants of GFP. Neuron 28:41-51[ISI][Medline].
Gan W-B, Grutzendler J, Wong WT, Wong ROL, Lichtman JW (2000) Multicolor "DiOlistic" labeling of the nervous system using lipophilic dye combinations. Neuron 27:219-225[ISI][Medline].
Gustincich S, Feigenspan A, Wu DK, Koopman LJ, Raviola E (1997) Control of dopamine release in the retina: a transgenic approach to neural networks. Neuron 18:723-736[ISI][Medline].
He S-G (1994) Further investigations of direction selective ganglion cells of the rabbit retina. In: PhD thesis Australian National University, Canberra.
He S-G, Masland RH (1998) ON direction-selective ganglion cells in the rabbit retina: dendritic morphology and pattern of fasciculation. Vis Neurosci 15:369-375[ISI][Medline].
He S-G, Levick WR, Vaney DI (1998) Distinguishing direction selectivity from orientation selectivity in the rabbit retina. Vis Neurosci 15:439-447[ISI][Medline].
He S-G, Jin ZF, Masland RH (1999) The non-discriminating zone of directionally selective retinal ganglion cells: comparison with dendritic structure and implication for mechanism. J Neurosci 19:8049-8056[Abstract/Free Full Text].
Hochstein S, Shapley RM (1976a) Quantitative analysis of retinal ganglion cell classifications. J Physiol (Lond) 262:237-264[Abstract/Free Full Text].
Hochstein S, Shapley RM (1976b) Linear and nonlinear spatial subunits in Y cat retinal ganglion cells. J Physiol (Lond) 262:265-284[Abstract/Free Full Text].
Isayama T, Berson DM, Pu M (2000) Theta ganglion cell type of the cat retina. J Comp Neurol 417:32-48[ISI][Medline].
Jeon C-J, Masland RH (1995) A population of wide-field bipolar cells in the rabbit's retina. J Comp Neurol 360:403-412[ISI][Medline].
Levick WR (1967) Receptive fields and trigger features of ganglion cells in the visual streak of the rabbit's retina. J Physiol (Lond) 188:285-307[Abstract/Free Full Text].
Levick WR, Thibos LN (1983) Receptive fields of cat ganglion cells: classification and construction. Prog Retin Res 2:267-319.
Lo DC, McAllister AK, Katz LC (1994) Neuronal transfection in brain slices using particle-mediated gene transfer. Neuron 13:1263-1268[ISI][Medline].
MacNeil MA, Masland RH (1998) Extreme diversity among amacrine cells: implications for function. Neuron 20:971-982[ISI][Medline].
MacNeil MA, Heussy JK, Dacheux R, Raviola E, Masland RH (1999) The shapes and numbers of amacrine cells: matching of photofilled with Golgi-stained cells in the rabbit retina and comparison with other mammalian species. J Comp Neurol 413:305-326[ISI][Medline].
Marc RE, Jones BW (2002) Molecular phenotyping of retinal ganglion cells. J Neurosci 22:413-427[Abstract/Free Full Text].
Masland RH (1977) Maturation of function in the developing rabbit retina. J Comp Neurol 175:275-286[ISI][Medline].
Masland RH (2001) Neuronal diversity in the retina. Curr Opin Neurobiol 11:431-436[ISI][Medline].
Masland RH, Mills JW, Hayden SA (1984) Acetylcholine-synthesizing amacrine cells: identification and selective staining by using autoradiography and fluorescent markers. Proc R Soc Lond B Biol Sci 223:79-100[Medline].
Masland RH, Rizzo JF, Sandell III JH (1993) Developmental variation in the structure of the retina. J Neurosci 13:5194-5202[Abstract].
Oyster CW, Simpson JI, Takahashi ES, Soodak RE (1980) Retinal ganglion cells projecting to the rabbit accessory optic system. J Comp Neurol 190:49-61[ISI][Medline].
Peichl L, Wässle H (1983) The structural correlate of the receptive field centre of alpha ganglion cells in the cat retina. J Physiol (Lond) 341:309-324[Abstract/Free Full Text].
Peichl L, Ott H, Boycott BB (1987a) Alpha ganglion cells in mammalian retinae. Proc R Soc Lond B Biol Sci 231:169-197[Medline].
Peichl L, Buhl EH, Boycott BB (1987b) Alpha ganglion cells in the rabbit retina. J Comp Neurol 263:25-41[ISI][Medline].
Perry VH, Oehler R, Cowey A (1984) Retinal ganglion cells that project to the dorsal lateral geniculate nucleus in the macaque monkey. Neuroscience 12:1101-1123[ISI][Medline].
Pu M, Amthor FR (1990) Dendritic morphologies of retinal ganglion cells projecting to the nucleus of the optic tract in the rabbit. J Comp Neurol 302:657-674[ISI][Medline].
Pu M, Berson DM, Pan T (1994) Structure and function of retinal ganglion cells innervating the cat's geniculate wing: an in vitro study. J Neurosci 14:4338-4358[Abstract].
Puopolo M, Hochstetler SE, Gustincich S, Wightman RM, Raviola E (2001) Extrasynaptic release of dopamine in a retinal neuron: activity dependence and transmitter modulation. Neuron 30:211-225[ISI][Medline].
Rockhill RL, Euler T, Masland RH (2000) Spatial order within but not between types of retinal neurons. Proc Natl Acad Sci USA 97:2303-2307[Abstract/Free Full Text].
Rodieck RW (1998) In: The first steps in seeing. Sunderland, MA: Sinauer.
Roska B, Werblin F (2001) Vertical interactions across ten parallel, stacked representations in the mammalian retina. Nature 410:583-587[Medline].
Sambrook J, Fritch EF, Maniatis T (1989) In: Molecular cloning: a laboratory manual. New York: Cold Spring Harbor Laboratory.
Sandell JH, Masland RH (1986) A system of indoleamine-accumulating neurons in the rabbit retina. J Neurosci 6:3331-3347[Abstract].
Sandell JH, Masland RH, Raviola E, Dacheux RF (1989) Connections of indoleamine-accumulating cells in the rabbit retina. J Comp Neurol 283:303-313[ISI][Medline].
Stanford LR (1987) W-cells in the cat retina: correlated morphological and physiological evidence for two distinct classes. J Neurophysiol 57:218-244[Abstract/Free Full Text].
Tauchi M, Masland RH (1984) The shape and arrangement of the cholinergic neurons in the rabbit retina. Proc R Soc Lond B Biol Sci 223:101-119[Medline].
Tauchi M, Masland RH (1985) Local order among the dendrites of an amacrine cell population. J Neurosci 5:2494-2501[Abstract].
Tauchi M, Madigan NM, Masland RH (1990) Shapes and distributions of the catecholamine-accumulating neurons in the rabbit retina. J Comp Neurol 293:178-189.
Vaney DI (1980) A quantitative comparison between the ganglion cell populations and axonal outflows of the visual streak and periphery of the rabbit retina. J Comp Neurol 189:215-233[ISI][Medline].
Vaney DI (1994) Territorial organization of direction-selective ganglion cells in rabbit retina. J Neurosci 14:6301-6316[Abstract].
Vaney DI, Levick WR, Thibos LN (1981) Rabbit retinal ganglion cells. Exp Brain Res 44:27-33[ISI][Medline].
Wässle H, Boycott BB (1991) Functional architecture of the mammalian retina. Physiol Rev 71:447-480[Free Full Text].
Wässle H, Riemann HJ (1978) The mosaic of nerve cells in the mammalian retina. Proc R Soc Lond B Biol Sci 200:441-461[Medline].
Wässle H, Peichl L, Boycott BB (1981) Dendritic territories of cat retinal ganglion cells. Nature 292:344-345[Medline].
Wässle H, Peichl L, Boycott BB (1983) Mosaics and territories of cat retinal ganglion cells. Prog Brain Res 58:183-190[ISI][Medline].
Wässle H, Voigt T, Patel B (1987) Morphological and immunocytochemical identification of indoleamine-accumulating neurons in the cat retina. J Neurosci 7:1574-1585[Abstract].
Watanabe M, Rodieck RW (1989) Parasol and midget ganglion cells of the primate retina. J Comp Neurol 289:434-454[ISI][Medline].
Wong WT, Sanes JR, Wong ROL (1998) Developmentally regulated spontaneous activity in the embryonic chick retina. J Neurosci 18:8839-8852[Abstract/Free Full Text]<