Demonstration of Cholinergic Ganglion Cells in Rat Retina: Expression of an Alternative Splice Variant of Choline Acetyltransferase

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The Journal of Neuroscience, April 1, 2003, 23(7):2872

Demonstration of Cholinergic Ganglion Cells in Rat Retina: Expression of an Alternative Splice Variant of Choline Acetyltransferase
Osamu Yasuhara, Ikuo Tooyama, Yoshinari Aimi, Jean-Pierre Bellier, Tadashi Hisano, Akinori Matsuo, Masami Park, and Hiroshi Kimura
Molecular Neuroscience Research Center, Shiga University of Medical Science, Otsu 520-2192, Japan

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Acetylcholine acts as a neurotransmitter in the retina. Although previous physiological studies have indicated that some retinalganglion cells may be cholinergic, several immunohistochemicalstudies using antibodies to choline acetyltransferase (ChAT) havestained only amacrine cells but not ganglion cells. Recently,we identified a splice variant of ChAT mRNA, lacking exons 6-9,in rat peripheral nervous system. The encoded protein was designatedas ChAT of a peripheral type (pChAT), against which an antiserumwas raised. In the present study, we examined expression of pChATin rat retina, both at the protein level by immunohistochemistryusing the antiserum and at the mRNA level by RT-PCR. Immunohistochemistryrevealed that although no positive neurons were found in untreatedintact retinas, many neurons became immunoreactive for pChAT afterintravitreal injection of colchicine. Damage of the optic nervewas also effective in disclosing positive cells. Such positiveneurons were shown to be ganglion cells by double labeling witha retrograde tracer that had been injected into the contralateralsuperior colliculus. Western blot analysis and RT-PCR revealeda corresponding band to the pChAT protein and to the amplifiedpChAT gene fragment, respectively, in retinal samples. In addition,ChAT activity was definitely detected in retinofugal fibers ofthe optic nerve. These results indicate the presence of cholinergicganglion cells in ratretina.

Key words: retinal ganglion cells; immunohistochemistry; RT-PCR; neurotransmitter; alternative splicing; cholinergic transmission

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

So far, neurotransmitters of retinal ganglion cells are generally unknown. A body of evidence indicates that glutamate isa major neurotransmitter of retinal ganglion cells. Glutamateimmunoreactivity has been observed in these cells (Davanger etal., 1991; Crooks and Kolb, 1992; Kalloniatis and Fletcher, 1993;Jojich and Pourcho, 1996; Sun and Crossland, 2000) and their terminals(Montero, 1994; Ortega et al., 1995; Mize and Butler, 1996). Inaddition, glutamate receptors have been shown to be involved inthe synaptic transmission in the retinogeniculate and retico-collicularpathways (Sillito et al., 1990; Roberts et al., 1991). Nevertheless,the role of glutamate as a major neurotransmitter of retinal ganglioncells remains to be confirmed. First of all, only 5-10% of thecells in the ganglion cell layer (GCL) have been reported to belabeled with [³H]-D-aspartate, the uptake of which is an indicator of neuronsusing glutamate as a transmitter (Beaudet et al., 1981; Ehinger,1981). Second, glutamate has been proven not to be released fromoptic nerve terminals in a calcium-dependent manner (Sandbergand Corazzi, 1983; Tsai et al., 1990). The dipeptide N-acetylaspartylglutamatehas also been suggested as a candidate transmitter, but this isstill controversial (Anderson et al., 1987; Tsai et al., 1990;Tieman and Tieman, 1996). Some ganglion cells may have the syntheticcapability for several neuropeptides (Kuljis et al., 1984; Cuencaand Kolb, 1989), which are not the major neurotransmitters ofganglioncells.

Acetylcholine (ACh) acts as a neurotransmitter in the retina (for review, see Puro, 1985; Ehinger and Dowling, 1987). Theretina contains ACh and its biosynthetic enzyme, choline acetyltransferase(ChAT; E.C. 2.3.1.6). Although the cholinergic nature of retinalganglion cells has once been suggested in the toad (Oswald andFreeman, 1980), many morphological studies have failed to supportthis possibility. Because there is no good histochemical techniquefor ACh itself, immunohistochemistry for ChAT has been regardedas the most reliable method for cholinergic neurons. Previousimmunohistochemical studies using ChAT antibodies have constantlydemonstrated ChAT immunoreactivity in amacrine cells but not inganglion cells (Eckenstein and Thoenen, 1982; Tumosa et al., 1984;Schmidt et al., 1985; Pourcho and Osman, 1986a,b; Tumosa and Stell,1986; Voigt, 1986). Even with such data, however, the possibilitystill remains that retinal ganglion cells use a different formof ChAT for synthesizingACh.

Recently, Tooyama and Kimura (2000) cloned a different form of ChAT cDNA from rat pterygopalatine ganglion. This form of transcriptlacks exons 6-9, indicating an alternative splicing event. Anantiserum was raised against the peptide covering the splice jointof exons 5 and 10, which should be specific to the predicted protein.Immunohistochemistry using the antiserum clearly revealed peripheralcholinergic neurons, whereas it failed to reveal known cholinergicneurons in brain (Nakanishi et al., 1999; Nakajima et al., 2000;Tooyama and Kimura, 2000). Because of the preferential localizationin peripheral neurons, the protein was designated pChAT (ChATof a peripheral type), and the conventional or common form ofthe enzyme was termed cChAT (ChAT of the common type). The negativestaining of peripheral cholinergic neurons by conventional cChATantibodies suggests that epitopes of such cChAT antibodies preferentiallylie within exons 6-9, which are absent inpChAT.

In the present study, we examined the possible existence of cholinergic ganglion cells in rat retina by immunohistochemistryand Western blot analysis using the pChAT antibody. In addition,expression of ChAT mRNA in the retina was analyzed by RT-PCR,and ChAT enzyme activity was examined in the optic nerve and retinaofrats.

Finally, effects of light and darkness on the expression of pChAT were examined immunohistochemically in the retina, opticnerve, and optic tract. This is because concentrations of severalputative neurotransmitters in the retina are known to be regulatedby light/dark (Starr, 1973; Masland and Livingstone, 1976; Iuvoneet al., 1978; Millar and Chubb, 1984). In addition, accumulatinglines of evidence have shown that light stimuli induce the expressionof Fos, an immediate early gene product, in the retina (Sagarand Sharp, 1990; Koistinaho and Sagar, 1995). Fos has been suggestedto be among the transcription factors that regulate ACh synthesis(Koistinaho and Sagar, 1995). Thus, we were interested in studyingthe effect of light/dark adaptation on the expression of pChAT,possibly through the Fos-mediatedmechanism.

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Animals and surgical procedures. Male Wistar rats (Clea Japan, Tokyo, Japan), weighing 200-300 gm, were used. The animalswere generally kept on a 12 hr light/dark cycle with ad libitumaccess to food and water. The rats were handled in compliancewith the principles of the NIH Guide for the Care and Use of LaboratoryAnimals and the standards of animal experiments in ouruniversity.

All surgical procedures and intravitreal injections were performed under deep pentobarbital anesthesia (80 mg/kg). The firstgroup of rats (n = 5) was used as normal animals without any treatment.In the second group of rats (n = 4), the right eye was enucleated.After unilateral enucleation, the animals were kept on a 12 hrlight/dark cycle. They were perfused 14 or 28 d after the operation.In the third group of rats (n = 5), 10 µl of a solution of colchicine(Sigma, St. Louis, MO) (10 µg/µl dissolved in saline) was injectedintravitreally into the right eye. After a survival period of4-7 d, the animals were perfused. In the fourth group of rats(n = 6), the right optic nerve was damaged. Under deep anesthesia,the intraorbital portion of the optic nerve was approached bya skin incision on the cheek, and the Harderian gland and a partof the lacrimal gland were removed. The lateral and inferior rectusmuscles were parted by blunt dissection, and the optic nerve wasexposed. The nerve was then crushed twice for 30 sec each witha hemostatic forceps (n = 3) or pressure injected with 3 µl of100% ethanol through a heat-pulled glass micropipette (n = 3).In either case, care was taken to avoid injury to the retinalblood supply. The rats were allowed to survive for 4-7d.

Tissue preparations. Under pentobarbital anesthesia (80 mg/kg), the animals were perfused on crushed ice through the ascendingaorta with 10 mM PBS, pH 7.4, followed by a fixative of 4% paraformaldehydein 0.1 M phosphate buffer (PB), pH 7.4. After perfusion, bilateraleyes and the brain were removed. The brain tissues were immersedfor 2 d in the same fixative at 4°C and then cryoprotected byimmersion for 48 hr in 0.1 M PB containing 15% sucrose. They werefrozen and cut into 20-µm-thick sections in a cryostat. The sectionswere collected and stored in 10 mM PBS containing 0.3% TritonX-100 (0.3% PBST) untilstained.

The perfusion-fixed eye tissues were processed in two ways. First, gelatin-embedded transverse sections of the eye cup wereprepared. In brief, the corneas and vitreous bodies were carefullyremoved from the eye tissues. The resultant eye cups were postfixedfor 2 d with 4% paraformaldehyde in 0.1 M PB at 4°C. After rinsingwith 0.1 M PBS, they were immersed for 4 hr in 0.1 M PB containing10% gelatin at 37°C and then placed for 1 hr in a cold chamberat 4°C. The gelatin-embedded specimens were cut into 5- to 7-mm-thickblocks that were postfixed overnight with 4% paraformaldehydein 0.1 M PB at 4°C and then placed overnight in 0.1 M PB containing15% sucrose at 4°C. Transverse sections of 30 µm thickness werecut in a cryostat and collected in 0.3%PBST.

Second, retinal whole mounts were prepared. The retinas were dissected out from the eye cups. After cutting radially, eachretina was sandwiched between two sheets of filter paper and thenfixed by immersion for 2 d in 4% paraformaldehyde in 0.1 M PBat 4°C. The fixed retinal tissues were then placed for 2 d in0.1 M PB containing 15% sucrose at 4°C, before immunohistochemicalstaining. Bilateral eyes were simultaneously processed in allanimals, and the eye tissue of the side with no surgical treatmentor intraorbital injection always served as acontrol.

pChAT immunohistochemistry. Immunohistochemical staining was done in a free-floating state. The coronal sections of the brainand gelatin-embedded transverse sections of the eye cups wereincubated for 3 d with the pChAT antiserum (diluted 1:80,000)or a goat anti-cChAT antibody (Chemicon, Temecula, CA) (AB144p,polyclonal; diluted 1:20,000) (Bruce et al., 1985) at 4°C, for2 hr with biotinylated secondary antibody of appropriate species(Vector Laboratories, Burlingame, CA) (diluted 1:1000) at roomtemperature, and for 1 hr with the avidin-biotinylated peroxidasecomplex (Vector Laboratories; ABC Elite, diluted 1:2000) at roomtemperature. Dilution of the reagents and washing sections betweeneach step were done with 0.3% PBST. Color was developed by reactingthe sections for 20 min with a mixture containing 0.02% 3,3'-diaminobenzidine,0.0045% H₂O₂, and 0.3% nickel ammonium sulfate in 50 mM Tris-HClbuffer, pH 7.6. The stained sections were air dried, washed intap water, dried through a graded series of alcohol, cleared withxylene, and coverslipped with Entellan (Merck, Darmstadt,Germany).

To facilitate antibody penetration, the retinal whole mounts were freeze-thawed (Eldred et al., 1983) and then treated for10 min with the protease papain (0.1 IU/ml in 0.1 M PBS) at roomtemperature, followed by fixation for 20 min with 4% paraformaldehydeat 4°C. After washing, they were immunostained for pChAT as describedabove, except that 0.6% PBST was used as a buffersystem.

For immunohistochemical controls, the pChAT antiserum was replaced by the preimmune serum or by pChAT antiserum that had beenpreincubated overnight with the antigenic peptide of pChAT (41amino acids) (Tooyama and Kimura, 2000). No positive stainingwas observed in these control studies. The number of cells labeledfor pChAT was counted in 15 nonoverlapping areas (0.25 × 0.25mm each) in the central and peripheral regions of the retina inthree rats. The cell density in each region was calculated asthe number of labeled cells per square millimeter. An estimatewas also made for the total number of pChAT-positive cells inthe retina, through the measurement of total area of each regionand the mean pChAT-positive cell density per unitarea.

Double staining for pChAT and a retrograde tracer, fluorescent latex microspheres. While the rats were under deep anesthesiawith pentobarbital (80 mg/kg), 5 µl of a commercially availablesolution of red-fluorescent latex FluoSpheres (Molecular Probes,Eugene, OR) (mean diameter 40 nm; excitation 580 nm/emission 605nm) (Persson and Gatzinsky, 1993; Balthazart and Absil, 1997)was stereotaxically injected into two sites in the left superiorcolliculus. In rat retina, the overwhelming majority of ganglioncells in an eyeball are known to project to the contralateralsuperior colliculus (Linden and Perry, 1983). Three days later,each rat received an intravitreal colchicine injection into theright eye as described above. They were allowed to survive foran additional 4 d and then perfused. The preparation and pretreatmentof retinal whole mounts were performed as described. They werethen incubated for 5 d with the pChAT antiserum (diluted 1:80,000)in 0.6% PBST at 4°C and for 2 hr with fluorescein isothiocyanate(FITC)-conjugated goat anti-rabbit IgG (ICN Pharmaceutical, Aurora,OH) (diluted 1:100) in 0.6% PBST at room temperature. After washing,all retinas were mounted as flat mounts on glass slides and coverslippedwith glycerin. The retinal whole mounts were imaged on a laserscanning microscope (MRC- 600, Bio-Rad, Hercules, CA), and imageswere recorded and processed digitally. The numbers of double-labeledand single-labeled cells were counted on two representative compositeconfocal images of the mid-peripheral region covering a totalarea of 0.6 mm², and the percentage of double-labeled as compared with single-labeledcells wascalculated.

mRNA analysis by RT-PCR. Total RNA was isolated from rat striatum and retina using the acid guanidium thiocyanate-phenol method(Chomczynski and Sacchi, 1987). Before reverse transcription,the total RNA was incubated for 1 hr with 10 U of RNase-free DNase(Amersham Biosciences, Piscataway, NJ) and 20 U of recombinantRNase inhibitor (Wako Pure Chemicals, Osaka, Japan) at 37°C toeliminate any trace of DNA contamination. Five micrograms of eachtotal RNA were then reverse transcribed for the first-strand cDNAsynthesis using 80 U of SuperScript II (Invitrogen, Gaithersburg,MD) and 500 pmol of oligo dT_12-18 (Amersham Biosciences)asprimers.

Details of primers used for PCR in this study are shown in Table 1. At the first step, PCR was performed using the pair ofprimers, P1 and P3, and the first-strand cDNA as a template. Thereaction mixture consisted of 2 ng/µl of the template cDNA, 0.8µM each of the primers, 0.2 mM of each of four deoxynucleotidetriphosphates, 10 µM $beta$ $-$ mercaptoethanol (Wako Pure Chemicals),16.6 mM ammonium sulfate, 2 mM MgCl₂, and 2.0 U Taq polymerase(Toyobo, Osaka, Japan) in 67 mM Tris-HCl, pH 8.8. Thirty-six cyclesof PCR were performed with the profile of thermal cycles consistingof denaturation at 95°C for 1 min, annealing at 56°C for 1 min,and extension at 72°C for 2 min. The PCR products were dilutedat 1:100 in autoclaved water.


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Table 1. Primers used in the present study

The nested PCR of 24 cycles was then performed using another pair of primers, P2 and P4, and 0.5 µl of the diluted first PCRproducts as a template. The composition of the reaction mixtureand the profile of thermal cycles were similar to the first-stepPCR, except for the annealing temperature at 66°C. The optimalannealing temperature for each pair of primers was determinedpreliminarily using the RoboCycler (Stratagene, La Jolla, CA).The first-step and nested PCR products were electrophoresed ona 3% agarose gel and stained with ethidium bromide. After dissectingout the bands from the gel, the target DNA in each band was elutedand cloned using a TA cloning system (Invitrogen, San Diego, CA).The pCR 2.1 plasmid vector containing the target DNA insert wastransfected into the host Escherichia coli, IVF $alpha$ '. After minipreparationof plasmid DNA, each PCR product was sequenced using the ThermoSequenaseCycle Sequencing kit (Amersham Biosciences Corp) and a SequencerDDS-1 (Shimadzu, Kyoto,Japan).

Western blot analysis. Two rats were used. Each animal received a single intravitreal colchicine injection (100 ng) into theright eye. Four days later, they were perfused through the ascendingaorta with 10 mM PBS to clear blood. Tissues of the retina ofthe injected and uninjected sides were collected separately andhomogenized in 10 vol of ice-cold 50 mM Tris-HCl, pH 7.4, containing0.5% Triton X-100 and protease inhibitor mixture tablets, CompleteMini (Roche Diagnostics, Mannheim, Germany) (one tablet per 10ml). The fresh tissue of the striatum from each animal was alsoprocessed in parallel. The homogenates were centrifuged at 12,000× g for 20 min at 4°C. The supernatants were collected as a crudeprotein fraction. Approximately 25 µg of the crude extracted proteinand Prestained Precision Protein Standards (Bio-Rad) were electrophoresedon a 9% SDS-polyacrylamide gel containing 20 µM reduced cysteineunder a reducing condition and then transferred to a polyvinylidenedifluoride membrane (Immobilon-P, Millipore Japan, Tokyo, Japan).The membrane was incubated for 1 hr with 8% skim milk in 25 mMTris-buffered saline (TBS, pH 7.4) at room temperature, and furtherincubated overnight with the cChAT antibody (Chemicon) (AB144p,polyclonal; diluted 1:500) or the pChAT antiserum (diluted 1:40,000)in 25 mM TBS containing 1% skim milk at room temperature. Afterwashing with 25 mM TBS containing 0.1% Tween 20, the membranewas reacted for 2 hr with a peroxidase-coupled anti-rabbit IgGFab' fragment (Histofine; Nichirei Corporation, Tokyo, Japan)(diluted 1:50). The peroxidase labeling was detected by chemiluminescenceusing the ECL Western blotting analysis system (AmershamBiosciences).

Assay of ChAT activity. Rat retinas and optic nerves were processed for the assay of ChAT activity. Four rats received unilateralintracranial nerve crush to eliminate a possible contributionof retinopetal cholinergic fibers. For intracranial optic nervecrush, anesthesia was introduced in the rats with 2% halothaneand maintained with 1% halothane in a mixture of 70% nitrogenand 30% oxygen to allow the animals to breathe spontaneously.Each animal was placed in the lateral position in a stereotaxicapparatus (Model SH-8; Narishige, Tokyo, Japan), and a linearskin and muscle incision was made between the left eyeball andexternal ear. The temporal muscle was retracted on either sideof the middle of the muscle without removal of the muscle, zygomaticarch, or eyeball. Then a burr hole was opened in the basal surfaceof the temporal bone between the orbital fissure and the foramenovale. The optic nerve was approached through the hole and thencrushed twice for 30 sec each with a hemostatic forceps. At theend of the surgical operation, the incision was closed and anesthesiawas discontinued. The animals were allowed to survive for 4d.

The enzyme activity of ChAT was measured according to Fonnum's method (Fonnum, 1975) with a slight modification. Fresh opticnerves from intact and optic nerve-crushed rats as well as freshretinas from intact rats were homogenized in 10 vol of 1 mM EDTAplus 0.5% Triton X-100, pH 7.4, at 4°C. After centrifugation at10,000 × g for 30 min, the supernatant was collected. Proteinconcentration was assayed using Lowry's method (Lowry et al.,1951). Ten microliters of the supernatant (5-10 µg of protein)were added to 10 µl of a reaction mixture containing 50 mM sodiumphosphate buffer, pH 7.4, 300 mM sodium chloride, 0.2 mM eserinesalicylate (Sigma), 8 mM choline (Sigma), 300 µM acetyl-CoA (Sigma)and 2,220,000 dpm [³H] acetyl-CoA (20 Ci/mmol) (Amersham Biosciences Corp). Afterincubation for 25 min at 37°C, the reaction was terminated bycooling, and the resultant [³H] ACh was quickly extracted with 5 mg/ml sodium tetraphenylboronin acetonitrile/toluene. The radioactivity in the organic phasewas counted. To determine the efficiency of ACh extraction, [¹⁴C] ACh was used as an internal standard. The enzyme activity wasexpressed as picomoles of [³H] ACh formed per minute per milligram ofprotein.

Animal manipulation for dark and light adaptation. For dark adaptation, rats were kept in a black box in a dark room for 1or 4 d. They were anesthetized with pentobarbital (80 mg/kg) underinfrared illumination and then perfused. For light exposure, therats were placed in a cage and exposed to 300 lux of white lightfor 4 or 16 hr or to continuous fluorescent room light for 4 d.The retinas and brains from these dark-adapted and light-exposedrats were used for immunohistochemicalinvestigations.

  Results

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

pChAT immunohistochemistry in the retina and visual pathway in intact rats

In retinal whole mounts of control rats, pChAT-like immunoreactivity was present in thick fibers converging toward the centraloptic disc (Fig. 1A). No cell bodies were found to be immunoreactive.In transverse sections of eye cups, positive fibers ran throughthe optic fiber layer of the retina and could be traced into theoptic nerve head (Fig. 1B). At more caudal levels in the orbit,some optic nerve fibers were only weakly stained. Positive cellsomata in the ciliary ganglia and positive fiber bundles in ciliarynerves were observed along the optic nerve. The localization ofpChAT-positive nerve elements around the optic nerve will be describedin detail elsewhere. In brain sections, the optic chiasm and theoptic tract were devoid of positive fibers or contained a fewweakly stained fibers for pChAT.

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Figure 1. pChAT immunoreactive structures in the retina and primary visual pathway in an intact rat (A, B) and a rat with unilateral enucleation (C-H). A, B, A retinal whole mount (A) and a transverse section of the optic nerve head (B) in an intact rat. Black star in A indicates the central optic disk. Arrowheads in B indicate positive ciliary fibers. V, Vitreous body; R, retina; h, optic nerve head. C-H, A rat after unilateral enucleation of the right eye. C, D, Right (C) and left (D) optic nerve in the intraorbital portion. Arrowheads in C and D indicate positive ciliary fibers. E, Optic nerves in the intracranial portion. Inset shows high-power photomicrograph of the right optic nerve, indicated by an arrow, showing fragmented positive fiber debris. F, Optic chiasm. G, H, Right (G) and left (H) optic tracts. Scale bars: D (for A-D), H (for E-H), 500 µm.

Enucleation

To verify the derivation of positive fibers in the optic nerve, particularly in the optic nerve head, the right eyeball wasenucleated and the localization of the pChAT immunoreactivitywas analyzed. Fourteen days after unilateral enucleation of theright eyeball, the pChAT immunostaining revealed positive stainingin only a few fragmented nerve fibers in the optic nerve of theenucleated side (right) (Fig. 1C,E). In contrast, pChAT immunoreactivitywas observed intensely in the contralateral left optic nerve (left)(Fig. 1D,E). In the optic chiasm, intensely stained fibers ranobliquely from the left side to the ventrolateral region of theright side, contrasting sharply with the remaining unstained region(Fig. 1F). However, the latter region contained a number of positiveoval to round structures (data not shown). At more caudal levels,positive fibers could be traced to the right optic tract (Fig.1G). Positive fibers were not observed in the left optic tract,although it was weakly and diffusely stained (Fig. 1H). Twenty-eightdays after enucleation, the patterns of staining were similarto those seen at 14 d after surgery, except that the number ofpositive oval structures was greatly decreased in both optic nerveand optic chiasm of the enucleated side (data not shown). Thepositive oval to round structures were reasonably regarded asaxonal debris of the optic nerve undergoing Wallerian degenerationafter enucleation. Thus, most of the pChAT-positive fibers inthe optic nerve were concluded to be retinofugal derived fromcertain population of retinal ganglion cells. In other words,some retinal ganglion cells were expected to expresspChAT.

Visualization of pChAT-immunoreactive cells in the retina

To verify the possible existence of retinal ganglion cells containing pChAT, colchicine, a blocker of axonal transport, wasinjected into the right vitreous body. As expected, 4 d aftercolchicine treatment, pChAT-positive cells became visible in theGCL. Figure 2A shows the positive cells in the GCL in transverseretinal sections after intravitreal colchicine injection. Thesecells frequently extended processes into the inner plexiform layer(IPL). Neither positive cell somata nor positive fibers were observedin other retinal layers. Most of such positive cells had smallcell bodies, whereas a few large cells were also stained positivelyfor pChAT. Occasionally, axon-like processes could be seen emanatingfrom these cells.

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Figure 2. Comparison of pChAT-positive cells after colchicine treatment (A) and cChAT-positive cells (B) in transverse sections of the retina. INL, Inner nuclear layer; IPL, inner plexiform layer; GCL, ganglion cell layer. Scale bars, 50 µm.

The pattern of staining with the pChAT antiserum was compared with those with the commercially obtained antibody to ChAT (cChAT)in the retina. cChAT immunoreactivity was present in two cellpopulations: one with cell bodies in the inner nuclear layer (INL)and the other with cell bodies in the GCL (Fig. 2B). The processesof these neurons ramified to form two strata in the IPL. The patternwas consistent with previous immunohistochemical studies in theretina of various species, in which cholinergic amacrine cellsand displaced amacrine cells were described (Tumosa et al., 1984;Millar et al., 1985; Schmidt et al., 1985; Pourcho and Osman,1986a; Tumosa and Stell, 1986; Voigt, 1986). As shown in Figure2, A and B, the pattern of positive cell distribution for cChATdiffered fundamentally from that for pChAT. Moreover, such cChAT-positivecells in the GCL were distinct in both shape and size from pChAT-positiveones. Therefore, pChAT- and cChAT-positive neurons appeared torepresent separate populations in retinallayers.

In retinal whole mounts of rats pretreated with intravitreal colchicine, many pChAT-positive neurons were observed among intenselystained thick fiber trees converging toward the central opticdisc (Fig. 3A). Apparently, there were at least two types of immunostainedcells (Fig. 3B). The first group of positive cells had large cellbodies, ranging from 20 to 35 µm in diameter, with three to sixthick fiber processes. The second group of positive cells hadsmall cell bodies, fusiform or round, of diameters from 10 to17 µm, with a few fine processes. In some sections, fiber processesemanating from such positive cells were observed to join fiberbundles, somewhat regularly arranged in groups to converge towardthe central optic disc. Small cells outnumbered large ones. Cellcounts were performed in an area of 0.25 × 0.25 mm at both thecentral and peripheral retinal regions. The density of positivecells was 292.7 ± 9.5 cells per square millimeter (means ± SEM;n = 3) in the central region and 370.3 ± 14.1 cells per squaremillimeter in the peripheral region, respectively. The total numberof pChAT-positive cells in the whole retina was estimated to be~22,800.

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Figure 3. Visualization of pChAT-positive cells in the retinal whole mounts. A, B, Colchicine treatment. A, Low-power photomicrograph. Black star indicates the central optic disk. B, High-power photomicrograph showing configurations of positive cells. C, Optic nerve crush. D, Ethanol injection into the optic nerve. Note that two types of cells, large (arrow) and small (arrowheads), are positive for pChAT. Scale bars: A, B (for B-D), 100 µm.

Visualization of positive cells in the retina was also achieved by damaging the optic nerve. Either optic nerve crush (Fig.3C) or alcohol injection into the optic nerve (Fig. 3D) causedmany pChAT-immunoreactive cells to be visible in the retina, aswas the case with intravitreal colchicineinjection.

Retrograde tracer labeling

To confirm the identity of pChAT-immunoreactive cells with retinal ganglion cells, a double-labeling experiment was performed.Ganglion cells were labeled with a retrograde tracer, red latexFluoSpheres, which had been applied to the contralateral superiorcolliculus. After an intravitreal colchicine injection, pChAT-positivecells were labeled with FITC-conjugated secondary antibody. Asshown in Figure 4, virtually every pChAT-positive cell was alsolabeled with the retrograde tracer. In two composite images ofthe mid-peripheral region covering an area of 0.6 mm², the numbers of double-labeled and single-labeled cells werecounted. The density of FluoSphere-containing retinal ganglioncells was 1503 cells per square millimeter. Ninety-two percentof pChAT-positive cells contained FluoSphere, whereas 19% of FluoSphere-containingganglion cells exhibited pChAT immunoreactivity. In contrast,our immunohistochemical examination for cChAT did not reveal anydoubly labeled cells with the tracer experiment (data not shown).

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Figure 4. The retinal whole mount doubly labeled for pChAT and a retrograde tracer, red latex FluoSperes, after injection into the contralateral superior colliculus. A, Confocal image of pChAT-immunoreactive cells in the retina (green). B, Retrogradely labeled cells with red latex FluoSperes (red). C, Superimposed image of A and B showing double-labeled cells (yellow to orange). Arrows indicate corresponding cells. Scale bar, 50 µm.

Analysis of ChAT mRNA expression in the retina

Expression of ChAT mRNA was analyzed by RT-PCR, using RNA preparations extracted from tissues of the striatum and retinasof control rats. As shown in Figure 5, the first-step PCR usingP1 and P3 primers revealed a single band of ~1138 bp in both striatumand retina, which corresponded to the expected size of the PCRproduct from cChAT cDNA. To further characterize ChAT gene expression,nested PCR was done using P2 and P4 primers and the first PCRproducts as templates. In the nested PCR, multiple bands weredetected in the striatum (three bands) and retina (four bands).The larger three bands were detected in both striatum and retina,whereas the smallest band was detected exclusively in the retina.Nucleotide sequence analysis revealed that the largest band representedthe cChAT gene product [852 bp; molecular weight (MW) of the encodedprotein, 72 kDa]. The second larger band corresponded to a ChATgene product, which lacked exon 6 (671 bp). This type of ChATmRNA encodes a truncated protein of 164 amino acid (MW 18 kDa).The nucleotide sequence of the third band (504 bp) lacked exons7 and 8. This type of mRNA is expected to encode a full-lengthprotein of 529 amino acids (MW 59 kDa). The smallest band, whichwas detected specifically in the retina, was identified to representthe PCR product of the pChAT cDNA (224 bp). The deduced molecularweight of pChAT is 49 kDa.

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Figure 5. Expression of ChAT mRNA in the striatum and retina revealed by RT-PCR. A, Schematic drawing showing the exon organizations of cChAT and pChAT, as well as the positions of primers used. B, A 3% agarose gel showing the result of the first RT-PCR and the nested PCR for ChAT. Lane 1, Striatum (First PCR); lane 2, retina (First PCR); lane 3, striatum (Nest PCR); lane 4, retina (Nest PCR). The positions of DNA size markers (1 kb DNA ladder; Invitrogen) and those of positive bands are indicated to the left and right of the gel, respectively.

Western blot analysis

Tissue homogenates from the striatum and the retina were analyzed by Western blot using the cChAT and pChAT antibodies. Asshown in Figure 6A, the cChAT antibody gave a positive band of~69 kDa in the striatum as well as the retina of both colchicine-injectedand uninjected sides. In contrast, the pChAT antiserum detecteda band at ~55 kDa in the retina of the colchicine-treated sidebut not in the striatum (Fig. 6B). The retina of the colchicine-untreatedside showed no band or a weakly stained band at the same molecularweight as that in the colchicine-treated retina (data not shown).The size (55 kDa) was slightly larger than the deduced molecularweight (49 kDa) of pChAT.

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Figure 6. Western blot analysis using tissues of the striatum and colchicine-treated retina. A, Probed with the cChAT antibody. B, Probed with the pChAT antiserum. Lane 1, Striatum; lane 2, colchicine-treated retina. Note that the cChAT antibody reveals a 69 kDa band in the striatum and retina, whereas the pChAT antiserum detects a 55 kDa band in the retina but not in the striatum. The positions of the protein size markers (Prestained Precision Standards; Bio-Rad) are indicated to the left.

ChAT activities in the retina and optic nerve

To verify the cholinergic properties of retinal ganglion cells of rats, enzyme activities for ChAT were measured in the retinaand optic nerve. The protein extracts from intact retinas andoptic nerves gave ChAT activity of 1985.9 ± 107.8 and 30.9 ± 13.9pmol · min¹ · mg¹ protein (mean ± SEM; n = 6), respectively. Because the valuein intact optic nerves showed significant individual variations,it was suggested that possible centrifugal cholinergic fibersmight participate in the optic nerve. Hence we performed intracranialoptic nerve crush unilaterally just anterior to the optic chasm.Four days after the nerve crush, the remaining optic nerve stillexhibited significant ChAT activity with an acceptable variation(25.8 ± 2.4 pmol · min¹ · mg¹ protein; n = 4). These data indicate that ChAT activity is indeedpresent in some retinofugal fibers in the opticnerve.

Effects of darkness and light exposure on pChAT staining

The effects of light and darkness on pChAT-positive structures in the pathway were examined immunohistochemically using thepChAT antiserum. The first group of rats were dark-adapted for1 or 4 d. Although positive ganglion cells were not visible inany one of the rats that were dark-adapted for 1 d, an increasein pChAT immunoreactivity was observed in the optic nerve. Thisbecame more evident after prolonged adaptation for 4 d in darkness.Figure 7A-C shows pChAT immunoreactivity in the primary visualpathway of the rat dark-adapted for 4 d. Intensely stained fibersran through the optic nerve (Fig. 7A) and optic chiasm (Fig. 7B).Less intensely stained fibers were recognized in the optic tract(Fig. 7C), and they could be traced up to the close vicinity ofthe superior colliculus. The expression of pChAT was apparentlyincreased as compared with that in normal control rats, wherestaining was limited to the optic nerve head (Fig. 7D-F). A similareffect was observed on exposure to light. A questionable increasein immunoreactivity was noted after exposure to light for 4 hr,but the increase was evident after overnight light exposure. Ratskept under continuous room light for 4 d showed a staining patternsimilar to that seen after dark adaptation for 4 d (Fig. 7G-I).From these results, it is concluded that prolonged exposure tolight and dark adaptation were both effective in increasing theexpression of pChAT in the primary visual pathway.

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Figure 7. Effects of darkness and light exposure on pChAT immunoreactivity in the primary visual pathway: the optic nerve head (A, D, G), optic chiasm (B, E, H), and optic tracts (C, F, I). A-C, Light exposure for 4 d. D-F, No treatment. G-I, Dark adaptation for 4 d. Arrows in C, F, and I indicate the optic tract. Note that both light exposure and dark adaptation are effective in increasing pChAT immunoreactivity in the visual pathway. Scale bar, 500 µm.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The present study demonstrates pChAT-positive retinal ganglion cells in rats by immunohistochemistry. Biochemically, expressionof pChAT in rat retina is confirmed at both levels of proteinand mRNA. The enzyme activity of ChAT, the ability of ACh synthesis,is also verified in the optic nerve. These results indicate thata subpopulation of retinal ganglion cells are cholinergic. Ourphysiological experiments further suggest that these retinal cholinergicganglion cells are regulateddynamically.

pChAT-positive cells in rat retina are ganglion cells

pChAT-positive cells became visible after pretreatment with colchicine. Damage given in two different ways to the optic nervewas also effective in visualizing pChAT-positive cells. Therefore,visualization should be the result of the blockage of axonal transportrather than the toxic stimulation of colchicine (Morgan and Mundy,1982).

The double-labeling experiment in colchicine-treated retinas showed that 92% of pChAT-positive cells were retrogradely labeledafter the injection of FluoSpheres into the contralateral superiorcolliculus. This percentage may be an underestimate because asmall proportion of retinal ganglion cells might be unlabeledby our retrograde tracing technique. First, the density of retrogradelylabeled ganglion cells in this study (1503 cells per square millimeterin the peripheral region) was slightly lower (approximately $-$ 6%)than that reported by Perry (1981) (1600 cells per square millimeter).Second, 5% of retinal ganglion cells of rats project to the ipsilateralsuperior colliculus (Linden and Perry, 1983). Thus, it is stronglyassumed that every pChAT-positive cell in rat retina is a ganglioncell.

As mentioned above, the density of ganglion cells in rat retina was estimated to be 2500 cells per square millimeter in thecentral region and 1600 cells per square millimeter in the peripheralregion (Perry, 1981). In this study, the densities of pChAT-positivecells in the colchicine-treated retina were 292.7 ± 9.5 cellsper square millimeter (mean ± SEM) in the central region (12%of the total ganglion cells) and 370.3 ± 14.1 cells per squaremillimeter in the peripheral region (23% of ganglion cells). Bydouble labeling, 19% of retrogradely labeled ganglion cells exhibitedpChAT immunoreactivity in the peripheral region of the retina.It is uncertain whether the somewhat lower incidence of pChAT-positiveganglion cells in the central region may reflect some functionalproperties ofpChAT.

In the cat, retinal ganglion cells have been classified into various types according to their sizes, dendritic patterns, andelectrophysiological reactions to retinal illuminations. Althoughmuch less information is available in rats, three types of retinalganglion cells have been described in rats: type I, II, and IIIcells (Perry, 1979, 1981) and RG_A, RG_B, and RG_C cells (Huxlinand Goodchild, 1997). In the present study, two types of pChAT-positivecells, one with large somata characteristic of the type I cells(RG_A cells) and another with small somata of type II or type IIIcells (RG_B or RG_C cells), respectively, were observed in the retinalwhole mounts. Thus, the occurrence of pChAT immunoreactivity appearsnot to be cell type dependent. Future studies are needed for furthermorphological characterization of pChAT-positive retinal ganglioncells.

Multiple ChAT mRNAs in rat striatum and retina

Our RT-PCR technique has revealed expressions of multiple ChAT mRNAs in rat striatum and retina. They include mRNAs for cChATand pChAT (ChAT5-10) and two additional splice variants of ChATmRNA. The cChAT mRNA was expressed in both striatum and retina,whereas the pChAT mRNA was expressed exclusively in the retina.Two additional variants of ChAT mRNA that have never been reportedbefore, one lacking exon 6 (ChAT5-7) and another lacking exons7 and 8 (ChAT6-9), were unexpectedly identified in the striatumand retina. The splice pattern of ChAT5-7 mRNA generates a frameshift and, subsequently, a stop codon just downstream to the splicejoint. Thus, it encodes a truncated protein (MW 18 kDa) lackingthe catalytic domain in exon 10. In contrast, ChAT6-9 mRNA showsno frame shift and encodes a protein carrying domains essentialfor enzyme activity (MW 59kDa).

Our pChAT antibody detected a single 55 kDa band only in the retina by Western blot analysis. Because our antibody does notrecognize the recombinant ChAT6-9 protein (our unpublished observation),the 55 kDa band should represent pChAT but not other variant proteins.The difference between the molecular weight of the detected band(55 kDa) and the deductive size of pChAT (49 kDa) may indicatesome post-translational modification. It remains to be clarifiedwhether ChAT5-7 and ChAT6-9 proteins actually function in vivo.

ChAT activity in the retina and optic nerve

To address whether pChAT is capable of synthesizing ACh in the visual pathway, we measured ChAT activities in the retina andoptic nerve. In accordance with previous studies (Ross et al.,1975; Mindel and Mittag, 1976), the retina exhibited high ChATactivity. To avoid the influence of enzyme activity from wellknown cholinergic amacrine cells that are all intrinsic withinthe retina, we measured the enzyme activity in the optic nerve.In intact optic nerves, ChAT activity was detectable with a largeindividual variation. Accordingly, ChAT activities in intact mouseoptic nerves were shown to vary greatly among individuals (Rossand McDougal, 1976). Although the reason for such a large variationis unknown, one possible explanation may be that ChAT in the opticnerve is under rapid transportation. In addition, a possible presenceof centrifugal cholinergic fibers in the optic nerve (Wenk etal., 1981) may make the analysis complicated. After intracranialoptic nerve crush, however, a significant and consistent ChATactivity was still detected in the optic nerve peripheral to thelesioned site. The result indicates that the optic nerve containsretinofugal cholinergic fibers and thus provides evidence thatsome retinal ganglion cells arecholinergic.

Comparison with previous studies

To date, several methods have been used to demonstrate cholinergic cells, including (1) ChAT immunohistochemistry, (2) autoradiographyfor choline uptake and ACh synthesis, and (3) histochemistry foracetylcholinesterase (AChE), a metabolizing enzyme for ACh. Allof the hitherto available antibodies against ChAT have failedto stain any retinal ganglion cell, but they consistently stainedsome amacrine cells in the retina (Eckenstein and Thoenen, 1982;Tumosa et al., 1984; Schmidt et al., 1985; Pourcho and Osman,1986a,b; Tumosa and Stell, 1986; Voigt, 1986). This is compatiblewith the present results using the cChAT antibody. In contrast,the pChAT antibody did not stain amacrine cells but stained someganglion cells after colchicine treatment. Therefore, the resultsuggests that some retinal ganglion cells contain pChAT, whichis antigenically different fromcChAT.

Several in vitro autoradiographic studies have also failed to reveal any cholinergic retinal ganglion cells. Freeze-dry autoradiographicstudies have suggested that choline uptake (Baughman and Bader,1977) as well as ACh synthesis (Masland and Mills, 1979; Haydenet al., 1980; Masland et al., 1984) are confined to amacrine cellsin the retina. However, there are possible explanations for thenegative labeling of ganglion cells in these studies. In our immunohistochemicalstudy, retinal ganglion cell somata show no pChAT immunoreactivityunder normal conditions. Therefore, the level of ACh synthesismay normally be too low to be detected by autoradiography. Itis also possible that high-affinity choline uptake may occur atsynaptic terminals in the target tissue as has been proposed (Suszkiwand Pilar, 1976). If this holds true, the negative labeling ofganglion cells may not indicate the noncholinergic nature of suchcells but may only reflect the distance between the cell bodiesin the retina and synaptic terminals in the superior colliculus.Moreover, autoradiographic data may vary according to methodologicaldifferences. For example, large retinal ganglion cells have beenreported to contain positive ACh synthesis signals in tissuesfixed with 5% phosophomolybdic acid (Pourcho and Osman, 1986a).It suffices to say, therefore, that there is room for argumentregarding the results of previous autoradiographicstudies.

The other technique for demonstrating cholinergic structures is AChE histochemistry. Although AChE is not a specific markerfor cholinergic cells, the presence of AChE activity would bea necessity for such cells (Fibiger, 1982). Previous studies revealedthat most ganglion cells, in addition to amacrine cells, showedAChE activity (Hebb, 1957; Reale et al., 1971; Millar et al.,1985; Pourcho and Osman, 1986b). In addition, it is noteworthythat some ganglion cells exhibited AChE activity even after diisopropyl-fluorophosphatepretreatment (Nichols and Koelle, 1968), the feature interpretedas one indicator of cholinergic cells (Butcher and Woolf, 1984).

In summary, previous morphological studies seem to provide no decisive evidence against the presence of cholinergic retinalganglion cells. Rather, reappraisal of published information,in the light of the discovery of pChAT, indicates that some studiescould favor theirpresence.

Significance of pChAT-positive retinal ganglion cells

The mechanism of the induction of pChAT mRNA and the functional significance of pChAT in the primary visual pathway are sofar unclear. As mentioned, previous reports have demonstratedan increase in Fos-like immunoreactivity in the INL and GCL ofthe retina (Sagar and Sharp, 1990; Gudehithlu et al., 1993), occurringmostly in amacrine and ganglion cells (Koistinaho and Sagar, 1995).The expressions of c-fos, c-jun, and jun B mRNAs in the INL andGCL are induced transiently by light exposure (Gudehithlu et al.,1993; Yoshida et al., 1993; Imaki et al., 1995). Both Fos andJun can bind to a DNA regulatory element known as AP-1, whichis involved in gene expression (Morgan and Curran, 1989). AP-1binding motifs are associated with regulation of various neuropeptidesand neurotransmitter-synthesizing enzymes, including ChAT (Misawaet al., 1992). Indeed, the immunohistochemical localization ofChAT closely overlaps with that of Fos/Jun in rat spinal cordand lower brainstem (Herdegen et al., 1991) and in amacrine cellsof rabbit retina (Koistinaho and Sagar, 1995). The stimulatoryeffect of light on ACh synthesis has also been reported in amacrinecells of rabbit retina (Masland and Livingstone, 1976). Thesefacts may lead us to assume that light exposure may have directlyelevated the expression of pChAT up to the detectable level throughthe Fos-mediated mechanism. However, similar consequences of continuouslight exposure and constant darkness in pChAT staining in thisstudy appear incompatible with the view that expression of pChATis involved in the formation of circadian rhythm. In this context,it is noteworthy that after unilateral enucleation of an eyeball,pChAT immunoreactivity was increased in the contralateral intactoptic nerve under a 12 hr light/dark cycle. Thus, it is possiblethat a factor regardless of the light/dark condition, such asattention, may augment itsexpression.

Another implication is that ACh produced by pChAT may not be acting merely as a neurotransmitter, but rather may play differentroles in retinal ganglion cells, as has been suggested in non-neuronalACh (Wessler et al., 1998). For example, ChAT, ACh, and ACh receptorshave been detected in non-neuronal epithelial cells, in whichACh is suggested to participate in the regulation of importantcell functions, such as trophic signaling, cell cycle, and cell-cellcontact (Wessler et al., 1998). This notion may explain why thepChAT antibody failed to detect positive terminals in the superiorcolliculus of rats. Whatever is the case, the results suggestthat expression of pChAT is physiologically regulated and thatthe cholinergic mechanism may play a role in the primary visualpathway. Future studies are needed to clarify the mechanism ofpChAT upregulations as an important clue for understanding thefunctional significance of pChAT in retinal ganglioncells.

  FOOTNOTES

Received Oct. 16, 2002; revised Jan. 2, 2003; accepted Jan. 7, 2003.

This work was supported in part by a grant-in-aid for Scientific Research from the Ministry of Education, Science, Sports,Culture and Technology of Japan. We thank M. Suzaki and T. Yamamoto(Shiga University of Medical Science) and Dr. Y. Aoki (NipponShinyaku Company, Kyoto, Japan) for technicalassistance.

Correspondence should be addressed to Hiroshi Kimura, Molecular Neuroscience Research Center, Shiga University of MedicalScience, Seta Tsukinowa-cho, Otsu 520-2192, Japan. E-mail: hkimura{at}belle.shiga-med.ac.jp.

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