Regulation of Structural Plasticity by Different Channel Types in Rod and Cone Photoreceptors

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The Journal of Neuroscience, August 15, 2002, 22(16):7065-7079

Regulation of Structural Plasticity by Different Channel Types in Rod and Cone Photoreceptors
Nan Zhang and Ellen Townes-Anderson
Department of Neurosciences, University of Medicine and Dentistry of New Jersey-New Jersey Medical School, Newark, New Jersey 07103-2714

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In response to retinal disease and injury, the axon terminals of rod photoreceptors demonstrate dramatic structural plasticity,including axonal retraction, neurite extension, and the developmentof presynaptic varicosities. Cone cell terminals, however, arerelatively inactive. Similar events are observed in primary culturesof salamander photoreceptors. To investigate the mechanisms underlyingthese disparate presynaptic responses, antagonists to voltage-gatedL-type and cGMP-gated channels, known to be present on rod andcone cell terminals, respectively, were used to block calciuminflux during critical periods of plasticity in vitro. In rodcells, L-type channel antagonists nicardipine and verapamil inhibitednot only the outgrowth of processes and the formation of varicosities,but also the synthesis of vesicle proteins, SV2 and synaptophysin.In contrast, the synthesis of opsin in rod cells was unaffected.In cone cells, L-type channel antagonists caused only modest changes.However, cobalt bromide, which blocks all calcium channels, andL-cis-diltiazem, a potent antagonist of cGMP-gated channels, significantlyinhibited varicosity formation and synthesis of SV2 in cone cells.Moreover, the cGMP-gated channel agonist 8-bromo-cGMP caused asignificant increase in varicosity formation by cone but not rodcells. Thus voltage-gated L-type channels in rod cells and cGMP-gatedchannels in cone cells are the primary calcium channels requiredfor structural plasticity and the accompanying upregulation ofsynaptic vesicle synthesis. The differing responses of rod andcone terminals to injury and disease may be determined by thesedifferences in the regulation of Ca²⁺influx.

Key words: cone; rod; neuritic process; varicosity; synaptic vesicle proteins; L-type calcium channel; cGMP-gated channel

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In response to injury and insult, adult CNS neurons display varying degrees of regeneration and reactive plasticity. Responsesrange from olfactory neurons that regenerate completely from stemcells after axotomy of the olfactory nerve (Harding et al., 1977),to afferent fibers for the septal nuclei that are able to producelimited sprouting after denervation of septal neurons (Raisman1969), to thalamic neurons that seem unable to recover from anaxonal lesion even in the presence of a peripheral nerve graft(Benfey et al., 1985). In the amphibian CNS as well, some neuronsregenerate axons easily, whereas others display no regenerativepotential (Lyon and Stelzner, 1987). Understanding the cause forthese differences holds the promise of increasing our knowledgeof the basic mechanisms of regeneration in theCNS.

In the retina, recent descriptions of human and animal models of retinitis pigmentosa (RP) and retinal detachment have illustratedthat even cells that have generally similar functions, the coneand rod photoreceptors, can have differing responses to injury.In a cat model of retinal detachment, rod cell axons retract towardtheir cell bodies, whereas cone cells are relatively unaffected(Erickson et al., 1983; Lewis et al., 1998). In human autosomaldominant RP, rod cells extend long neurites toward the inner retina.Along these neurites, varicosities filled with synaptic vesiclesare formed. Cone cell terminals, in contrast, show little change(Li et al., 1995; Milam et al., 1996). Feline rod/cone dysplasiaalso exhibits rod neurite extension into the inner retina (Chonget al., 1999). In mouse models of retinal degeneration known asrd or rds and in light-induced degeneration, rod cell terminalshave been shown to expand as adjacent rod photoreceptors die (Jansenand Sanyal, 1984, 1987, 1992). In a pig model of an autosomaldominant RP, rod cells have short sprouts emanating from theirsynaptic spherules, whereas cone synaptic pedicles remain relativelyinert, although they are able to make new synaptic connectionswith rod bipolar cells (Li et al., 1998; Peng et al., 2000). Thestimuli for and the mechanisms of structural plasticity in thecase of rod cells, and structural stability in the case of cones,areunknown.

Primary cultures of salamander rod and cone photoreceptors show many of the features of axonal and terminal plasticity seenin vivo. Rod cells retract their axons shortly after cell plating,then extend neurites, and finally form varicosities filled withsynaptic vesicles. Cone cells will also extend neurites and formvaricosities; however, the number of neurites and varicositiesis consistently lower in cone than in rod cells (Mandell et al.,1993). Recent studies using the L-type calcium channel antagonistnicardipine showed that blocking calcium influx during and immediatelyafter retinal dissociation prevented rod axonal retraction, whereascontinued application of nicardipine reduced process outgrowth(Nachman-Clewner and Townes-Anderson, 1999). There is growingevidence that distinct calcium channels exist in cone and rodcells: physiological evidence has been found that Ca²⁺ influx occurs through cGMP-gated channels at the axonal terminalsof cone but not rod cells (Rieke and Schwartz, 1994; Savchenkoet al., 1997). Immunocytochemical examination has demonstratedthat the $alpha$ -subunits of L-type calcium channels present in rodand cone terminals differ in density. A large aggregation of L-typechannels exists at the synaptic active zone of rod cells, whereaschannel distribution is diffuse in cone cells (Nachman-Clewnerand Townes-Anderson, 1999; Morgans, 2001). Finally, L-type calciumchannels in cone and rod cells possess distinct physiologicalcharacteristics (Wilkinson and Barnes, 1996; Kourennyi and Barnes,2000). We have hypothesized therefore that the functional typeof synaptic calcium channel may determine the kind of plasticitydisplayed in response to nerve cell injury. Using antagoniststo L-type and cGMP-gated channels, we present evidence here thatstructural plasticity and regenerative growth in vitro are controlledprimarily by L-type channels in the rod photoreceptor and by cGMP-gatedchannels in the conephotoreceptor.

Preliminary findings of this work have been presented previously in abstract form (Zhang and Townes-Anderson, 2000, 2001).

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antibodies, probes, and chemicals. Mouse monoclonal antibody to the synaptic vesicle glycoprotein SV2 (Buckley and Kelly,1985) was a generous gift of Dr. K. Buckley (Harvard Medical School,Cambridge, MA). Rabbit polyclonal antibody to synaptophysin (p38)(Valtorta et al., 1988), an integral synaptic vesicle membraneprotein, was a generous gift of Dr. F. Valtorta (S. Raffaele ScientificInstitute, Milan, Italy). Anti-opsin monoclonal antibody 4D2 wasa gift of Dr. R. Molday (University of British Columbia, Vancouver,Canada); 4D2 is specific for the opsin of M(red) rod photoreceptors(Hicks and Molday, 1986). Rabbit polyclonal antibody to rab6 [C19,a marker protein of trans-Golgi networks (TGNs)] (Goud et al.,1990; Antony et al., 1992; Deretic and Papermaster, 1993) waspurchased from Santa Cruz Biotechnology (Santa Cruz, CA). Thespecificity of SV2, p38, 4D2, and rab6 antibodies has been demonstratedin the salamander retina (Mandell et al., 1993; Nachman-Clewnerand Townes-Anderson, 1996). Goat anti-mouse IgG antibody for culturedish coating was purchased from Boehringer Mannheim Corporation(Indianapolis, IN). Sal-1 mouse hybridoma supernatant was generouslyprovided by Dr. P. MacLeish (Morehouse School of Medicine, Atlanta,GA). All immunolabeling reagents including goat anti-mouse rhodamineantibody, goat anti-mouse-isothiocyanate (FITC) antibody, goatanti-rabbit rhodamine antibody, and goat anti-rabbit-FITC antibodywere purchased from Boehringer Mannheim. Papain was purchasedfrom Worthington Biochemical Corporation (Lakewood, NJ). Nicardipine(Nc), verapamil (Vrp), L-cis-diltiazem (Lcd), 8-bromo-cGMP (8Br-cGMP),and dimethyl sulfoxide (DMSO) were purchased from Sigma (St. Louis,MO). Cobalt bromide (CoBr) was purchased from Fisher Scientific(Pittsburgh, PA). Channel antagonists and agonists were preparedas stock solutions and frozen at $-$ 20°C before application. Ncwas dissolved in 100% DMSO at a concentration of 10 mM; Vrp, Lcd,8Br-cGMP, and CoBr were dissolved in dH₂O at concentrations of5, 100, 22, and 100 mM,respectively.

Isolation and culture of photoreceptors. Retinas were obtained from light-adapted adult tiger salamanders (Ambystoma tigrinum,16-30 cm in length; Charles Sullivan Inc., Nashville, TN) thatwere decapitated and pithed according to protocols approved bythe Institutional Animal Care and Use Committee at the Universityof Medicine and Dentistry of New Jersey and in strict accordancewith the Policy on the Use of Animals in Neuroscience Researchof the Society for Neuroscience and guidelines from the NationalInstitutes of Health. Dissociation of the retina was performedas described previously using enzymatic digestion with papainand trituration (MacLeish and Townes-Anderson, 1988; Mandell etal., 1993). Briefly, retinas were dissected at room temperature(20-22°C) in room light, incubated for 45 min on a shaker in enzymeRinger's solution containing 14 U/ml papain, 85 mM NaCl, 1.5 mMKCl, 25 mM NaHCO₃, 0.5 mM CaCl₂, 0.5 mM NaH₂PO₄, 24 mM glucose,0.03 mM phenol red, 1.0 mM sodium pyruvate, and 2.7 mM DL-cysteine.Retinas were gently triturated with a 3-mm-diameter wide-borepipette 25 times to obtain a cell suspension containing predominantlyphotoreceptor cells. Cells were plated onto acid-cleaned glasscoverslips coated with goat anti-mouse IgG antibody and the Sal-1antibody (MacLeish et al., 1983). Cells were grown in a serum-freedefined medium containing (in mM): 108 NaCl, 2.5 KCl, 2 HEPES,1 NaHCO₃, 0.5 NaH₂PO₄, 1 sodium pyruvate, 0.5 MgCl₂, 24 glucose,1.8 CaCl₂, 7% medium 199, 1× minimum essential (MEM) vitamin mix,0.1× MEM essential amino acids, 0.1× MEM nonessential amino acids,2 glutamine, 2 µg/ml bovine insulin, 1 µg/ml transferrin, 5 taurine,0.8 µg/ml thyroxine, 10 µg/ml gentamycin, and 1.0 mg/ml bovineserum albumin. Cells were maintained in a humidified chamber at10°C in thedark.

Immunocytochemistry of cultured photoreceptors. Photoreceptors were fixed with 4% paraformaldehyde in 0.125 M phosphate buffer,pH 7.4, for at least 24 hr at 4°C and labeled by the followingprocedure. (1) Cells were washed with PBS (450 mM NaCl, 20 mMsodium phosphate buffer, pH 7.4) three times at room temperature.(2) Cells were incubated for 1 hr at room temperature in goatserum dilution buffer (GSDB; 16% normal goat serum, 450 mM NaCl,0.1% Triton X-100, 20 mM phosphate buffer, pH 7.4) to block nonspecificbinding and permeabilize the plasma membrane. (3) Cells were incubatedwith primary antibodies dissolved in GSDB at 4°C overnight. 4D2antibody was used at a dilution of 1:25; SV2 and synaptophysinantibodies were used at dilutions of 1:20 and 1:500, respectively;and rab6 antibody was used at a dilution of 1:50. For negativecontrols, no primary antibodies were added to the GSDB at thisstep. (4) Cells were rinsed with wash buffer (450 mM NaCl, 0.3%Triton X-100, and 20 mM phosphate buffer) three times followedby a rinse with PBS. (5) Cells were incubated with Triton-freeGSDB (450 mM NaCl, 16% normal goat serum, and 20 mM phosphatebuffer) for 1 hr at room temperature. (6) Cells were incubatedwith secondary antibodies conjugated with fluorescence labelsrhodamine or FITC for 50 min at room temperature in the dark.Secondary antibodies were used at a dilution of 1:35 and dissolvedin Triton-free GSDB. (7) Cells were washed with PBS three timesfollowed by a final rinse with 5 mM phosphate buffer, pH 7.4,at room temperature. (8) Cells were mounted in anti-fade mediumcontaining 90% glycerol, 10% PBS, including 2.5% (w/v) 1,4-diazobicyclo[2,2,2]octaneto prevent bleaching of immunofluorescence. For double labeling,the two primary antibodies or two secondary antibodies were dilutedtogether in GSDB buffer and applied to cellssimultaneously.

Quantification of cell outgrowth. For cell identification, see Data analysis. For the analysis of process outgrowth and formationof varicosities, cone cells were viewed with conventional phase-contrastmicroscopy, and 4D2-stained rod cells were viewed with UV lightmicroscopy on an inverted photomicroscope equipped for FITC andrhodamine epifluorescence. In some experiments, cone cells werealso viewed with UV light microscopy based on immunofluorescentstaining of vesicle proteins. Computer images of cells were capturedby a CCD camera and analyzed with NIH image software (V.1.44).Any outgrowth extending >5 µm from the soma was considered tobe a process. A process was defined as a 1^o process before it branched, a 2^o process after branching, or a 3^o process after further branching. Primary processes were furtherdivided into thick, thin, and lamellipodial-like processes. Avaricosity was defined as a swelling along a neuritic processwith a diameter >0.5 µm.

Densitometry analysis. Photoreceptors were double stained with 4D2 and synaptophysin antibodies and imaged with confocal microscopy.Briefly, an LSM410 microscope, equipped with an argon/kryptonlaser and a 63×, 1.4 numerical aperture oil immersion objective(Carl Zeiss, Oberkochen, Germany) was set to scan 1 µm opticalsections of photoreceptors. A 488 nm excitation filter and a 515-540nm narrow bandpass emission filter were used for FITC, and a 568nm excitation filter and a 590 nm long-pass emission filter wereused for rhodamine. Because synaptophysin staining levels in conecells have been shown to be significantly higher than in rod cells(Townes-Anderson and Nachman-Clewner, 2001), confocal sensitivityand contrast parameters were set separately for cone and rod cellsidentified by 4D2 staining to ensure that staining intensitiesof captured images were in the linear range for cones and rods,respectively. The optical sections were scanned at two levels:one level was close to the culture substrate to show processesand varicosities, and another level was distant from culture substrateto show intracellular structures including TGNs. Synaptophysinstaining was analyzed with the "density slice" function of NIHimage software (V.1.44). A threshold value was chosen to eliminatebackground noise before images were analyzed. A mean gray valueper unit area was determined for each cell. Lower gray valuesindicated brighter fluorescence with 1 = white and 255 = blackon a 256 grayscale. Data were collected as the area of stainingmultiplied by the average intensity ofstaining.

Colocalization analysis. The "colocalization" function of the Zeiss LSM410 system was used to measure the areas of SV2 andrab6 costaining in TGNs of photoreceptors (this method will bedescribed in detail in a separate paper; E. Townes-Anderson andN. Zhang, unpublished observations). Briefly, cone and rod cellswere identified morphologically with transmitted light, and parametersfor sensitivity and contrast were set separately for cone androd cells. Optical sections (1 µm) were taken at a level containingthe Golgi apparatus as determined by prominent rab6 staining.For every pixel in the original image, the system plots a correspondingpoint relating to the intensities of the red and green channels.On the resulting scattergram, the x-axis represents the intensityof pixels in the red channel, and the y-axis represents the intensityof pixels in the green channel. If a pixel has equal intensitiesin both channels, then the point will fall on a 45^o line in the center of the graph. The farther away the pointsare from the 45^o line, the higher the intensity is for one channel compared withthe other. In our colocalization analysis, an arbitrary but consistentlyapplied threshold was chosen by marking a constant rectangulararea on the scattergram so that background signals were excludedand pixels with high intensities in both channels were capturedappropriately. Data were collected as the total area of double-labeledpixels.

Data analysis. Cell cultures contained a mixed population of retinal neurons. Photoreceptors can always be identified by thepresence of an ellipsoid, an accumulation of mitochondria in theinner segment. Rod and cone cells were identified by the presenceand absence, respectively, of M(red) rod opsin immunostainingusing monoclonal antibody 4D2. S(green) rod cells were thus excludedfrom the rod cell category and may have been included in the conecell category. They are, however, only 1.3% of the total photoreceptorpopulation in tiger salamander (Sherry et al., 1998). Both singleand double cones were included. In experiments double labeledfor rab6 and SV2, cells were identified by phase-contrast microscopybefore analysis by confocal microscopy. Identification by lightmicroscopy was based on cell soma shape, thickness of processes,and shape of varicosities. Cone cells tend to have an ellipticalsoma, broad processes, and triangular varicosities compared withrod cells. Only cells that were felt to be positively either rodor cone were used foranalysis.

The data were collected only from photoreceptors without outer segments. All cone cells retain their axon terminals afterretinal dissociation; rod cells can either retain or lose theiraxon and terminal. Rod cells with axons display structural rearrangementfollowed by development of neurites and varicosities, whereasrod cells without axons form neurites and varicosities de novo.These two types of rod cells were previously termed denervatedand axotomized, and they differ in the rate of development butnot in the type of processes and presynaptic structures that areformed (Nachman-Clewner and Townes-Anderson, 1996).

The data are expressed as mean ± SEM. Statistical comparisons between two groups were made with the Student's t test, if thenormality and equal variance tests were passed, or with the Mann-Whitneyrank sum test, if the normality and equal variance tests failed.Comparisons among multiple groups were made with one-way ANOVA.The post hoc analysis used with the one-way ANOVA was Dunnett'smethod. Statistical analysis was performed using SigmaStat software(V2.0). Data graphs were created using SigmaPlot software (V5.0).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antagonists for the selective blockage of L-type calcium channels are divided into three classes: dihydropyridines, benzothiazepines,and phenylalkylamines. Reagents from these classes bind to thepore-forming $alpha$ ₁ subunit of the channel (Hockerman et al., 1997a,b;Peterson et al., 1997; Catterall, 2000). In the present seriesof experiments, the dihydropyridine antagonist nicardipine andthe phenylalkylamine antagonist verapamil were used to selectivelyblock the L-type channels of photoreceptors. For the blockageof cGMP-gated channels, the transition metal cobalt bromide andthe benzothiazepine antagonist L-cis-diltiazem were used. However,the effects of CoBr and Lcd are not specific: CoBr blocks alltypes of calcium channels (Hille, 1992), whereas Lcd, an isomerof the L-type channel antagonist D-cis-diltiazem and a potentblocker of photoreceptor cGMP-gated channels (Stern et al., 1986;Quandt et al., 1991), can still bind to L-type channels with lowaffinity (Ikeda et al., 1991). Reagents that more specificallyblock cGMP-gated channels are not available currently. Therefore,8Br-cGMP, which can induce Ca²⁺ current specifically through photoreceptor cGMP-gated channels(Rebrik and Korenbrot, 1998; Xiong et al., 1998), was used toactivate cGMP-gatedchannels.

Blockage of L-type calcium channels with nicardipine or verapamil: effects on neuritic processes and varicosities

Previous studies demonstrated that an immediate blockage of L-type channels with Nc inhibited axonal retraction in rod cellsand caused a reduction of process growth in photoreceptors, includingboth the cone and the rod cells (Nachman-Clewner and Townes-Anderson,1999). Effects of L-type channel antagonists applied at laterstages of neuritic and varicosity development were not tested.Therefore, the questions first addressed were (1) whether thedevelopment of neuritic processes and the formation of presynapticvaricosities by cone and rod cells require Ca²⁺ influx through L-type calcium channels and (2) whether continuousCa²⁺ influx or a brief period of Ca²⁺ influx through L-type channels is required. Photoreceptors werecultured in antagonist-free medium to allow Ca²⁺ influx for 1 hr or 1 d. Then, 10 µM Nc in 0.1% DMSO was addedto the medium, and cells were cultured for an additional 2 d (Fig.1). Two types of controls were included: (1) cells were treatedwith 0.1% DMSO alone for the entire period, and (2) cells withNc treatment were returned to normal medium after 3 d in culture(Fig. 1).

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Figure 1. Experimental design for administration of channel blockers. Photoreceptors were cultured with channel blockers for 48 hr after seeding or after 1 d in culture. Some photoreceptors were cultured for an additional 3 d after channel blockers were removed from the culture medium.

During the first 2-3 d in culture in Nc-free medium, growth of neuritic processes with branching structures as well as formationof presynaptic varicosities were observed in both cone and rodcells (Fig. 2A,C). For cone cells, 7.64 processes per cell and0.27 varicosities per cell were observed in 2-d-old cultures,whereas 8.32 processes per cell and 0.57 varicosities per cellwere observed in 3-d-old cultures (Table 1, Fig. 3A,B); varicositydevelopment was statistically significant during this period (p< 0.01). For rod cells, 15.95 processes per cell and 0.41 varicositiesper cell were observed in 2-d-old cultures, whereas 27.90 processesper cell and 1.88 varicosities per cell were observed in 3-d-oldcultures on average (Table 1, Fig. 3A,B); both neurite outgrowth(p < 0.001) and varicosity development (p < 0.001) were significantlyincreased from 2 to 3 d in cultured rod cells. In a few rod cellsgrown in antagonist-free medium, as many as 11 varicosities wereobserved in a single cell. Thus, in this culture system, rod cellsgrew more processes and formed more varicosities than cone cells,and the period of the first 2-3 d in culture was a critical periodfor the development of axonal structures for both cone and rodcells. These data were consistent with previously reported results(Mandell et al., 1993; Sherry et al., 1998).

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Figure 2. Morphological changes of photoreceptors treated with nicardipine. A, Phase-contrast microscopy of an untreated cone cell. Neuritic processes with branching structures were present. Varicosities (arrows) had formed along the processes. B, Nc-treated cone cell. Processes showed fewer branches, but varicosities (arrow) had still formed along the processes. C, Fluorescence microscopy of an untreated rod cell labeled with rod opsin antibody. The rod cell showed prominent process outgrowth with obvious branching. Multiple varicosities (arrows) had formed along the thicker processes, the neurites. D, Nc-treated rod cell labeled with rod opsin antibody. The rod cell showed fewer processes and no varicosities. Cells were from 3-d-old cultures; Nc treatment started after 1 d in culture. Scale bar, 10 µm.


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Table 1. Effects of L-type calcium channel antagonist nicardipine (Nc) on the process outgrowth and varicosity formation of cone and rod cells

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Figure 3. Effect of nicardipine (Nc) treatment and removal on the growth of processes and varicosities by photoreceptors as determined by quantitative analysis. A, Growth of neuritic processes. Nc treatment caused a significant decrease in the total number of processes per cell as compared with controls in both cone and rod cells from 3-d-old cultures. B, Growth of varicosities. Nc-treated rod cells from both 2- and 3-d-old cultures showed a significant decrease in the number of varicosities as compared with controls. The decrease in cone cells did not reach statistical significance. C, Growth of neuritic processes after removal of Nc. Nc was removed from the medium, and photoreceptors were cultured for an additional 3 d; there was a prominent growth of processes in rod cells, but no change in the total number of processes from cone cells. D, Growth of varicosities after removal of Nc. After Nc was removed from the medium and photoreceptors were cultured for another 3 d, there was also a prominent increase in the number of varicosities in rod cells. In cone cells, no significant growth of processes or varicosities was seen after removal of Nc. A total of 880 cells in 14 cultures from three animals were analyzed in A and B, and a total of 250 cells in 10 cultures from one animal were analyzed in C and D.

The blockage of L-type calcium channels caused changes in photoreceptor growth patterns that were more prominent in rod thancone cells (Fig. 2B,D). Additionally, compared with controls,Nc-treated photoreceptors from 3-d-old cultures showed more significantchanges in growth than 2-d-old cultures (Table 1, Fig. 3A,B).In 3-d-old cultures, for instance, Nc reduced the number of neuriticprocesses by 21.8% in rod cells and by 14.1% in cone cells. Amongall subtypes of processes, 3^o processes, small-branching structures, were the most affected(Table 1). Nc-treated rod cells also showed a significant decreasein the number of varicosities, with a 51.1% reduction in 2-d-oldcultures and a 68.6% reduction in 3-d-old cultures (Table 1,Fig. 3B). In Nc-treated cone cells, the decrease in varicositynumber, although present, was not statistically significant (Table1, Fig. 3B). These data show that although blockage of L-typecalcium channels inhibited process outgrowth in both cone androd cells, varicosity formation was significantly inhibited onlyin rodcells.

To exclude the possibility that the inhibition of Nc was caused by toxicity, neuritic structures were analyzed after Nc wasremoved from the medium and cells were allowed to grow for anadditional 3 d. After Nc removal, both cone and rod cells resumedgrowth of processes, and varicosity development resumed in rodcells (Table 2, Fig. 3C,D). Furthermore, Nc treatment causedno reduction of photoreceptor cell density (data not shown). Thus,Nc-treated cells were viable, and no cell death occurred.


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Table 2. Process outgrowth and varicosity formation of cultured photoreceptors after removal of nicardipine (Nc)

The phenylalkylamine antagonist verapamil (5 µM) was also used to block L-type calcium channels. Delayed (after 1 d) blockageof L-type calcium channels by Vrp significantly inhibited varicosityformation by 31.5% in rod but not in cone cells. Thus, anotherclass of L-type channel antagonist gave results consistent withNc (Fig. 4).

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Figure 4. Effect of verapamil treatment on the growth of varicosities by photoreceptors in 3-d-old cultures. A, Growth of varicosities by cone cells. Neither 5 µM Vrp nor 10 µM Nc caused significant inhibition of varicosity formation in cone cells. B, Growth of varicosities by rod cells. Both 5 µM Vrp and 10 µM Nc caused significant inhibition of varicosity formation in rod cells. A total of 300 cells in eight cultures from one animal were analyzed. *p < 0.05; **p < 0.01.

Blockage of L-type calcium channels with nicardipine: effects on synaptic vesicle proteins

Presynaptic varicosities are formed by photoreceptors as synaptic vesicles accumulate near the terminals of neurites (Mandellet al., 1993). In the previous section, inhibition of varicosityformation by Nc was observed. This inhibition could be causedby (1) the inhibition of vesicle protein synthesis or (2) theinhibition of anterograde vesicle transport in neurites, or both.Because reduced vesicle protein synthesis could also explain reducedtransport, we chose to investigate the synthesis of vesicle proteins,specifically SV2 and synaptophysin, in Nc-treated cone and rodcells.

Proteins synthesized in the endoplasmic reticulum (ER) are transported peripherally after maturation and packaging in theGolgi complex. The level of protein in the Golgi complex givessome indication of the level of protein synthesis in the ER (Hannahet al., 1999). Indeed, cycloheximide, which blocks protein synthesisin general, reduced opsin in the Golgi complex of rod cells asseen with double immunolabeling (Townes-Anderson, unpublisheddata). We used this principle in conjunction with image analysisto analyze relative levels of synthesis of synaptic vesicle proteinin different cell types, the cone and rod cells, in the same culture.In the first series of experiments, the presence of synaptic vesicleprotein SV2 in the trans-Golgi network was analyzed by colabelingfor SV2 and a TGN marker protein, rab6 (Fig. 5). Three-day-oldcultures that had been treated with Nc for 2 d were examined.The confocal microscopic images of untreated cone and rod cellsshowed strong SV2 immunostaining in the rab6-positive Golgi area(Fig. 6A,C). After Nc treatment, the TGN in cone cells continuedto have strong SV2 labeling, whereas that in rod cells had reducedSV2 staining (Fig. 6B,D). Colocalization analysis of rab6 andSV2 immunostaining further demonstrated that the Nc treatmentdid not cause a decrease in the area of colocalization in conecells but did cause a significant 59.1% decrease in the area ofcolocalization in rod cells (Fig. 7A). After Nc was removed fromthe medium and cells were cultured for 3 more days, the averagearea of colocalized rab6 and SV2 staining in Nc-treated cone cellswas unchanged, but the average colocalization area of rab6 andSV2 in Nc-treated rod cells showed a 117.5% increase in size (Fig.7B). These data demonstrated that delayed blockage of L-type calciumchannels did not influence the synthesis of vesicle protein SV2in cone cells but sensitively and reversibly inhibited the synthesisof vesicle protein SV2 in rod cells.

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Figure 5. Diagram of expected Golgi labeling in the presence and absence of protein synthesis. Left panel, Double staining of the Golgi apparatus by SV2 (green) and rab6 (red). When SV2, an integral membrane protein of all vesicles, is being synthesized, it appears in the Golgi as well as other locations in the cell. Rab6 is present only in the trans-Golgi network and post-Golgi vesicles. Double staining (yellow) indicates the presence of SV2 and rab6 in the TGN. Yellow stain will only appear when SV2 is being actively synthesized and is passing through the TGN. Right panel, When no SV2 is synthesized, there is little double staining. SV2 may be present in the cell soma but is in low levels in the Golgi apparatus. Rab6 staining occurs in the trans-Golgi, and a red body appears in the cell soma. Thus, the area of double staining gives an indication of the amount of SV2 synthesis.

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Figure 6. Photoreceptors from 3-d-old cultures double stained with rab6 and SV2 antibodies. Optical sections (1 µm) were obtained at a level showing the Golgi apparatus. Images are displayed in red-green-blue (A1, B1, C1, and D1), red (A2, B2, C2, and D2), and green channels (A3, B3, C3, and D3), respectively. A1-A3, Untreated cone. The Golgi apparatus and post-Golgi vesicles were labeled by rab6 and SV2 antibodies and appeared yellow (arrow), indicating the synthesis of SV2. B1-B3, Nc-treated cone. Nc treatment did not cause an obvious change of rab6 and SV2 staining in the Golgi apparatus, suggesting the continued presence of SV2 in the TGN (arrow). C1-C3, Untreated rod. Both rab6 and SV2 antibodies stained the trans-Golgi apparatus, which appears yellow (arrow). SV2 staining (green) is also present in other locations in the cell soma such as the cis-Golgi. D1-D3, Nc-treated rod. Nc treatment reduced SV2 staining in the Golgi area. The arrow indicates the Golgi apparatus that showed rab6 label (red), but SV2 staining (green) occurred primarily in areas outside the Golgi apparatus. This suggests that SV2 synthesis had been reduced but that SV2, perhaps in old synaptic vesicles, continues to be present in the cell soma. Scale bar, 10 µm.

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Figure 7. The effects of application and removal of nicardipine (Nc) on SV2 and opsin synthesis in photoreceptors as measured with colocalization analysis. Area is derived from the number of pixels labeled by rab6 and either SV2 or opsin antibodies. A, SV2 and rab6 labeling in cone and rod cells from 3-d-old cultures that had been treated with Nc after 1 d in culture. In rod cells, the Nc treatment significantly reduced the SV2 labeling in the Golgi, resulting in a smaller average area of colocalized staining. There was no change in cone cells. A total of 120 cells in six cultures from three animals were analyzed. B, SV2 and rab6 labeling in cone and rod cells from 6-d-old cultures; Nc had been removed at day 3 (Fig. 1). The SV2 staining increased significantly in Nc-treated rod cells after Nc removal, increasing the areas of colocalization (**p < 0.01), but showed no significant change in Nc-treated cone cells. A total of 80 cells in four cultures from one animal were analyzed. C, Rod opsin (4D2) and rab6 labeling in rod cells from 3-d-old cultures. No change in the area of double labeling was observed in Nc-treated rod cells compared with untreated cells, suggesting that Nc had no effect on opsin synthesis. A total of 40 cells in four cultures from two animals were analyzed.

To test for the possibility that the Nc-induced inhibition of SV2 in the Golgi was a nonspecific effect and that all proteinsynthesis was reduced when calcium channels were blocked, thecolocalization analysis was applied to rod opsin, a protein thatappears to be constitutively expressed in cultured rod cells (Nachman-Clewnerand Townes-Anderson, 1996). Nc-treated rod cells showed no significantdecrease of the area of colocalization for rab6 and rod opsinas compared with untreated rod cells (Fig. 7C). The data shownot only that opsin expression is not influenced by L-type channelblockage, but also that rab6 expression is unchanged. Thus, thereduction of SV2 synthesis in rod cells by L-type channel blockagerepresents a specific effect and not a general depression of proteinsynthesis.

To confirm the data obtained with SV2, the effects of L-type channel blockage on the level of another vesicle protein, synaptophysin,in photoreceptors was investigated. Cultured photoreceptors weredivided into four groups: (1) untreated, cells were cultured inNc-free medium for 3 d; (2) Nc-treated, cells were cultured inNc-containing medium for 2 d after 1 d preincubation in Nc-freemedium; (3) Nc-removed, Nc-treated cells were subsequently culturedin Nc-free medium for 3 more days; and (4) Nc-remained, Nc-treatedcells were cultured in Nc-containing medium for 5 d after 1 din Nc-free medium (see Fig. 9A). Cells were double labeled withsynaptophysin and rod opsin antibodies, and confocal microscopicsections were taken at two levels, with one level containing processesand another level containing the Golgi apparatus. Confocal imagesof cone cells from the above groups showed no significant changesin synaptophysin staining (pictures not shown). However, in confocalmicroscopic images of rod cells, changes of synaptophysin stainingcould be observed. In untreated rod cells, strong synaptophysinstaining appeared in the soma as well as growing varicosities(Fig. 8A). In the Nc-treated group of rod cells, there was inhibitionof process outgrowth and varicosity formation (Fig. 8B), and synaptophysinstaining appeared primarily in the soma. After Nc was removedfrom the medium, regenerating processes and varicosities couldbe observed in rod cells, and synaptophysin staining appearedin newly formed varicosities (Fig. 8C). Prolonged Nc treatmentcaused almost complete disappearance of synaptophysin stainingin rod cells (Fig. 8D).

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Figure 8. Effect of nicardipine treatment on synaptophysin labeling in photoreceptors. Rod cells were stained with rod opsin (red) and synaptophysin (green) antibodies. Confocal microscopic sections (1 µm) from a level containing processes and varicosities are shown. A, An untreated rod cell. The cell had prominent process outgrowth and several varicosities (arrows). Strong synaptophysin staining was present in both the soma and varicosities in the 3-d-old culture. B, Nc-treated rod cell. There was clear inhibition of process outgrowth and varicosity formation and weaker synaptophysin staining in the soma in the 3-d-old culture. C, A rod cell after Nc removal. The cell had resumed process growth and varicosity formation. Although the synaptophysin staining in the soma was still weak, strong synaptophysin staining was present in varicosities (arrow), suggesting a transport of synaptophysin to peripheral structures from the soma after Nc was removed in the 6-d-old culture. D, A rod cell treated with Nc for 5 d after 1 d in Nc-free culture. The prolonged treatment of rod cells with Nc caused a drastic decrease of synaptophysin staining in addition to the inhibition of growth in the 6-d-old culture. Scale bar, 10 µm.

Synaptophysin staining was further analyzed with densitometry of rod and cone cells identified by the presence or absenceof 4D2 staining. Densitometric analysis confirmed that Nc treatmentsignificantly decreased synaptophysin immunostaining only in rodand not in cone cells (Fig. 9B,C). The Nc-remained group of conecells did show a slight decrease in the staining intensity atthe process level; however, this decrease was not statisticallysignificant (Fig. 9B). In rod cells, prolonged Nc treatment (Nc-remainedgroup) caused a dramatic decrease in staining intensity (86.3%decrease at the process level and 70.2% decrease at the Golgilevel). Removal of Nc (Nc-removed group) from the medium reducedthe extent of this decrease (46.2% decrease at the process leveland 37.1% at the Golgi level) (Fig. 9C).

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Figure 9. Effect of nicardipine (Nc) treatment on synaptophysin staining as measured with densitometric analysis. The analysis was performed on 1 µm optical sections taken from a level showing processes and a level showing the Golgi apparatus. A, Experimental design for Nc application and Nc removal. Nc (10 µM) was added to and removed from the culture medium as indicated. B, Densitometry of cone cells. Cone cells did not show a significant decrease of synaptophysin staining intensity in Nc-treated, Nc-removed, and Nc-remained groups as compared with the untreated group at both levels. C, Densitometry of rod cells. Although rod cells from the Nc-treated group showed only a trend toward decreased synaptophysin staining intensity as compared with the untreated group, prolonged Nc treatment (Nc-Remained group) caused a significant decrease in synaptophysin staining intensity at both process and Golgi levels. Removal of Nc from the medium reduced the extent of this decrease (Nc-Removed group). A total of 160 cells in eight cultures from one animal were analyzed.

Rod opsin staining at the Golgi level was also analyzed with densitometry. Compared with the untreated group, prolonged Nctreatment in rod cells did not cause a statistically significantdecrease in 4D2 staining density (470.4 ± 51.6 area × intensity10³ units for the untreated group and 349.8 ± 41.2 area × intensity10³ units for the Nc-remained group; p = 0.076; a total of 40 rodcells in four cultures from one animal wereanalyzed).

These data reinforced the selective inhibition of L-type calcium channel blockage on rod cell vesicle proteinsynthesis.

Blockage of cGMP-gated channels with cobalt bromide or L-cis diltiazem: effects on processes, varicosities, and the vesicle protein SV2

The results in previous sections established that varicosity formation as well as vesicle protein synthesis in cone cellswere resistant to the blockage of L-type calcium channels. Thismay be explained if (1) varicosity formation and vesicle proteinsynthesis in cone cells do not require Ca²⁺ influx or (2), although Ca²⁺ influx through L-type calcium channels was blocked, other channelsexist through which Ca²⁺ can enter cone cells. To address the above possibilities, alltypes of calcium channels were blocked by application of cobaltbromide. Delayed blockage of calcium channels with 1 mM CoBr inhibitedprocess outgrowth and varicosity formation not only in rod cellsbut also in cone cells (Fig. 10). In rod cells, there was a 36.0%reduction of processes and a 79.0% reduction of opsin-stainedvaricosities. In cone cells, there was a 57.1% reduction of processesand a 56.2% reduction of varicosities (Fig. 10A,B). In addition,there was a 85.3% decrease in the areas of rab6 and SV2 colocalizationin TGNs of CoBr-treated as compared with untreated cone cells(Fig. 10C). Cell density after CoBr treatment was also analyzed.No decrease in cell density was observed in CoBr-treated as comparedwith untreated cultures (101.1 ± 7.2 cells/20× field in CoBr-treatedand 92.3 ± 4.8 cells/20× field in untreated cultures; p = 0.417;a total of 40 fields in four cultures from one animal were analyzed),suggesting that 1 mM CoBr was not significantly cytotoxic. Theseresults demonstrated that the development of presynaptic varicositiesand the synthesis of SV2 in cone cells required Ca²⁺ influx. Moreover, it indicated that in cone cells, in additionto L-type calcium channels, there indeed exist channels otherthan L-type channels that can provide the Ca²⁺ required for presynaptic development.

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Figure 10. Effects of a 2 d application of cobalt bromide (CoBr) on process outgrowth, varicosity formation, and SV2 synthesis in 3-d-old cultures. A, Process outgrowth and varicosity formation in cone cells. Processes and anti-synaptophysin-labeled varicosities were counted. The CoBr application significantly reduced the growth of processes and varicosities in cone cells. A total of 200 cone cells in four cultures from one animal were analyzed. B, Process outgrowth and varicosity formation in rod cells. Processes and anti-synaptophysin-labeled varicosities were counted. The CoBr application also significantly reduced the growth of processes and varicosities in rod cells. A total of 200 rod cells in four cultures from one animal were analyzed. Rod and cone cells were identified by the presence and absence, respectively, of rod opsin antibody labeling. C, SV2 and rab6 labeling of cone cells. Cone cells treated with 1 mM CoBr showed an 85.3% reduction of the area of colocalized staining. A total of 40 cone cells in four cultures from two animals were analyzed.

As mentioned previously, physiological evidence has shown Ca²⁺ influx through cGMP-gated channels in the inner segments andsynaptic areas of salamander cone cells (Rieke and Schwartz, 1994).L-cis-diltiazem (100 µM) was used to block cGMP-gated channels.The delayed administration of Lcd (Fig. 11A) caused a ~50% inhibitionof the number of varicosities in cone cells. In rod cells, Lcdgave similar results (Fig. 11B). Combined application of 100 µMLcd and 10 µM Nc did not significantly increase the inhibition.At the same time, 10 µM Nc caused significant inhibition of varicosityformation in rod but not cone cells, consistent with previousdata (Fig. 11A,B). In confocal microscopic images, Lcd-treatedcone cells showed weaker staining for SV2 and synaptophysin thanuntreated cone cells (images not shown). Using colocalizationanalysis, there was a 46.3% decrease in the areas of rab6 andSV2 double staining in cone cells treated with Lcd as comparedwith controls (Fig. 11C). Thus, CA²⁺ influx through cGMP-gated channels was required by cone cellsfor formation of presynaptic varicosities and synthesis of vesicleproteins. The effects on rod cells are attributed, at least inpart, to the ability of Lcd to block L-type channels.

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Figure 11. Effects of a 2 d application of the cGMP-gated channel antagonist L-cis-diltiazem (Lcd) on varicosity formation and SV2 synthesis in 3-d-old cultures. A, Varicosity formation by cone cells. Varicosities were analyzed with phase-contrast microscopy. Lcd caused a 49.4% decrease in varicosity production; Lcd plus nicardipine (Lcd + Nc) also caused a significant decrease, but Nc alone caused no significant changes in varicosity formation by cone cells. A total of 400 cone cells in 16 cultures from two animals were analyzed. B, Varicosity formation by rod cells. Anti-opsin-stained varicosities were counted. Both Nc and Lcd caused significant decreases in varicosity formation by rod cells. A total of 400 rod cells in 16 cultures from two animals were analyzed. C, SV2 and rab6 immunocytochemical labeling of cone cells. Cone cells treated with Lcd showed a 46.8% reduction in the area of colocalized staining, suggesting a decrease in SV2 synthesis. A total of 40 cone cells in four cultures from one animal were analyzed.

Effects of activation of cGMP-gated channels with agonist 8Br-cGMP on varicosity formation by cones

Although CoBr and Lcd can inhibit varicosity formation, they are not specific antagonists of cGMP-gated channels. One of thecharacteristics of cGMP-gated channels is that they can be sensitivelyregulated by intracellular cGMP (Cobbs et al., 1985; Zimmerman,1995), and cGMP and its analogs, including 8Br-cGMP, have beenused to specifically activate cGMP-gated channels (Rebrik andKorenbrot, 1998; Xiong et al., 1998). A further advantage of theapplication of an analog such as 8Br-cGMP is that it activatescGMP-gated channels without stimulating the production of nitricoxide, which has been reported to modulate Ca²⁺ current in salamander rod cells (Kurenny et al., 1994). We speculatedthat if Ca²⁺ influx through cGMP-gated channels could be increased by activationwith cGMP analogs, the development of presynaptic varicositieswould be stimulated. Three concentrations (35, 350, and 1400 µM)of 8Br-cGMP were added to the medium, and cells were allowed togrow for 3 d (Fig. 12A). 8Br-cGMP at 350 µM significantly increasedvaricosity formation in cone cells but significantly decreasedvaricosity formation in rod cells (Fig. 12B,C). Interestingly,the highest concentration (1.4 mM) of 8Br-cGMP did not furtherincrease the number of varicosities in cone cells (Fig. 12B,C).8Br-cGMP is also an activator of the protein kinase G family (Surkset al., 1999; Matsunobu and Schacht, 2000), and the activationof this kinase could contribute to an increase or decrease ofvaricosity development. For instance, it is possible that rodcells are inhibited by protein kinase G activation. Overall, thedata with 8Br-cGMP further supported the hypothesis that Ca²⁺ influx through cGMP-gated channels is essential for the developmentof presynaptic varicosities in cone cells.

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Figure 12. Effect of cGMP-gated channel agonist 8Br-cGMP (an analog of cGMP) on the varicosity formation of photoreceptors. A, Experimental design for the administration of 8Br-cGMP. 8Br-cGMP was added to the culture medium immediately after cell plating. B, Varicosity formation by cone cells. Varicosities were analyzed with phase-contrast microscopy. 8Br-cGMP, at 350 mM, caused a significant increase, whereas the other two concentrations caused no significant changes in varicosity formation. C, Varicosity formation by rod cells. Anti-opsin-stained varicosities were counted. 8Br-cGMP caused a dose-dependent inhibition of varicosity formation by rod cells. A total of 800 cells in 16 cultures from two animals were analyzed.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Distinct types of calcium-permeable channels in cone and rod cells are required for structural plasticity and regeneration

The present study demonstrates that L-type calcium channels in rod cells and cGMP-gated channels in cone cells are the primarycalcium channels required for structural plasticity, includingregenerative process outgrowth, varicosity formation, and vesicleprotein synthesis in salamander photoreceptors. This conclusionis based on the different responses of cone and rod cells to theapplication of calcium channel antagonists and anagonist.

L-type calcium channels have been found to be essential in the development of neuritic outgrowth in several different neuronalcell types [chick retinal neurons (Suarez-Isla et al., 1984);PC12 cells (Doherty et al., 1991); rat cerebellar, hippocampal,and cortical neurons (Williams et al., 1994, Shitaka et al., 1996,Ramakers et al., 1998)]. This list now includes rod photoreceptors.Our data, however, clearly show that cone cells are less dependenton L-type channel activity for neuritic outgrowth. cGMP-gatedchannels are widely expressed in the CNS (Wei et al., 1998). Therole of cGMP-gated cationic channels in phototransduction in thephotoreceptor outer segment has been well established (Yau andBaylor, 1989; Kaupp, 1995), and Ca²⁺ influx through cGMP-gated channels in the inner segments andpresynaptic areas of cone cells is known to contribute to neurotransmitterrelease (Rieke and Schwartz, 1994; Savchenko et al., 1997). Recently,cGMP-gated channels have also been shown to play a role in axonaloutgrowth. In olfactory neurons (Kafitz et al., 2000) and snailspinal neurons, activation of guanylyl cyclase leads to filopodialextension as well as an increase of [Ca²⁺]_i (Van Wagenen and Rehder, 1999, 2001). Like these CNS neurons,cone cells have presynaptic growth that can be modulated by acyclic nucleotide-gated channel. To our knowledge, this is thefirst report that cone and rod cells require the activity of distinctchannels for reactive plasticity. This is also the first demonstrationof an agent that can stimulate presynaptic development in adultphotoreceptors: 8Br-cGMP significantly increased varicosity formationin cone cells. This does not rule out, however, the possibilitythat L-type calcium channels play some role in cone cell axonalplasticity, especially because branching tertiary processes weresignificantly reduced in cone cells after nicardipineapplication.

The use of different calcium-permeable channels in control of axonal activity by cone and rod cells is supported by reportsshowing that these two photoreceptor types possess many distinctcharacteristics related to their Ca²⁺ regulation. Cone and rod cells contain different cGMP-gated cationchannels in their outer segments (Wei et al., 1998); in addition,cGMP-gated channels in rod cells, but not in cone cells, may beregulated by Ca²⁺-calmodulin (Haynes and Stotz, 1997). Caffeine causes transientincreases of intracellular Ca²⁺ concentration ([Ca²⁺]_i) in salamander rod cells, but no similar [Ca²⁺]_i increase was reported in cone cells (Krizaj et al., 1999).Rod cells do not contain the Ca²⁺ binding protein calbindin, which is present in cone cells (Pasteelset al., 1990). Finally, the type of L-type channel in rod andcone cells appears to be different. In mammalian retina, coneL-type channels have been reported to contain the $alpha$ _1D subunit(Taylor and Morgans, 1998; Morgans, 1999), whereas rod L-typechannels contain the $alpha$ _1F subunit (Bech-Hansen et al., 1998; Stromet al., 1998; Morgans, 2001). In salamanders, Ca²⁺ current profiles reflecting $alpha$ _1D subunits in cone cells and $alpha$ _1Fsubunits in rod cells have been reported (Wilkinson and Barnes,1996; Kourennyi and Barnes, 2000). Freshly isolated salamanderrod cells contained much denser staining by an antibody raisedagainst the $alpha$ _1C subunit of L-type calcium channels, than conecells (Nachman-Clewner and Townes-Anderson, 1999), and somatostatinreduced voltage-gated L-type Ca²⁺ current in rod cells but increased this current in cone cellsfrom salamanders (Akopian et al., 2000).

The differences in calcium homeostatic mechanisms between cone and rod cells could contribute to the differential responsesthat we observed when calcium channel blockers were applied. Thesedifferences, however, should not obscure a fundamental differencein the activation mechanisms of the two channel types: membranepotential change for the L-type channels and cGMP concentrationfor the cyclic nucleotide-gated channels. We hypothesize thatbecause of these unique forms of activation, the rod and conecells react differently to disease at their synaptic terminals.In human retinitis pigmentosa, in animal models of retinal degeneration,and in retinal detachment, rod cell axons and terminals displaydramatic structural plasticity but cone cells do not (Li et al.,1995, 1998; Milam et al., 1996; Lewis et al., 1998). It is possiblethat voltage-gated channels are more easily activated by mechanicalperturbation and degenerative disease leading to an increase of[Ca²⁺]_i than cGMP-regulated channels. This idea should be amenableto testing in vitro.

Regulation of calcium channels involved in axonal plasticity and regeneration

Although L-type calcium channels are opened by depolarization, in our experiments photoreceptors were cultured in a mediumcontaining 2.5 mM KCl, a concentration too low to make globalcellular changes in calcium concentration in photoreceptors (Nachman-Clewnerand Townes-Anderson, 1999; Uchida and Iuvone, 1999). Nonetheless,the application of L-type calcium channel antagonists inhibitedaxonal plasticity in rod cells. There are several possible explanationsfor these results. (1) Although cultured photoreceptors were notintentionally stimulated, the membrane potential of photoreceptorscan intrinsically fluctuate, causing Ca²⁺ influx into cells in minute amounts, enough to activate growthof neuritic structures. In fact, spontaneous, transient depolarizationsunder basal conditions have been observed in cultured embryonicchicken photoreceptors (Uchida and Iuvone, 1999). (2) Even ifthere is no fluctuation of membrane potential, it is possiblethat a small percentage of L-type calcium channels remain in an"active" state, allowing growth-sustaining amounts of Ca²⁺ into the cells. (3) Mechanisms other than membrane depolarizationcan regulate the activity of L-type calciumchannels.

Ca²⁺ transients in growth cone filopodia that can lead to more global elevations of [Ca²⁺]_i have been observed using various culture substrates (Kuhn etal., 1998; Gomez et al., 2001). These transients occur in theabsence of depolarization and do not involve voltage-gated channels.However, cell adhesion molecules including NCAM, N-cadherin, andL1 have been reported to regulate activities of voltage-gatedcalcium channels and have been implicated in the regulation oflocal Ca²⁺ concentrations during axonal growth (for review, see Dohertyet al., 2000). L-type channels are susceptible to this activation.The mechanism involved most likely includes signaling moleculeslike arachidonic acid (Doherty et al., 2000). It is not clearwhether cGMP-gated calcium channels can also be regulated by celladhesion molecules, but nitric oxide has been shown to promoteboth calcium influx and filopodial growth in B5 snail neurons,presumably through cGMP-gated channels (Van Wagenen and Rehder,1999). Additionally, both L-type (for review, see Catterall, 2000)and cGMP-gated channels (Molokanova et al., 1999) can be regulatedby phosphorylation. Thus, regulation of calcium influx that isnot voltage dependent appears possible and in fact may be commonin motile growthcones.

Continuous Ca²⁺ influx is required for presynaptic development of cultured photoreceptors

Distinct spatial and temporal patterns of Ca²⁺ signals are involved in different neuronal activities (De Koninck and Schulman,1998; Svoboda and Mainen, 1999). For example, only millisecondsare needed for Ca²⁺ influx to trigger neurotransmitter release from synaptic terminals(Borst and Sakmann, 1996), whereas it takes minutes to hours forsome gene expression to be regulated after Ca²⁺ influx (Hardingham et al., 1997; Tao et al., 1998; Rajadhyakshaet al., 1999). To distinguish between a short-term influx of calciumand a longer-term, perhaps continuous influx as a requirementof structural plasticity in photoreceptors, blockage of L-typecalcium channels was delayed by two different time periods (1hr versus 1 d). In both cases, however, process outgrowth in rodswas inhibited, suggesting that the process continues to requirecalcium influx even after 24 hr. For the cGMP-gated channels aswell, it appears that long-term activity is necessary because24 hr without blockage was not adequate to support normal presynapticgrowth. These data, however, do not distinguish which part ofthe process, gene regulation, protein synthesis, anterograde transport,vesicle exocytosis, or cytoskeletal turnover, continues to beCa²⁺dependent.

The synthesis of vesicle proteins requires Ca²⁺ influx

Blockage of L-type calcium channels in rod cells and cGMP-gated channels in cone cells not only inhibited presynaptic plasticitybut also significantly inhibited the synthesis of vesicle proteinsas measured by the presence of protein in the TGNs. Normally,an increase in vesicle protein synthesis occurs after 24-48 hrin culture (Nachman-Clewner and Townes-Anderson, 1996; Zhang andTownes-Anderson, unpublished observations), suggesting that generegulation is involved. Calcium has been known to participatein gene regulation since the 1980s when the opening of L-typevoltage-gated calcium channels by membrane depolarization of PC12cells was reported to induce expression of c-fos, an immediateearly gene (Greenberg et al., 1986; Morgan and Curran, 1986).The Ca²⁺-dependent signaling pathways in cone and rod cells that mightregulate the synthesis of vesicle proteins remain to be discovered.However, it is known that mRNA levels for melatonin N-transferaseare regulated by Ca²⁺ influx via cAMP (Gan et al., 1995; Gréve et al., 1999). It ispossible that a similar mechanism may be involved in the regulationof genes such as those for synaptic vesicle proteins necessaryfor plasticity and regeneration. Future in situ hybridizationexperiments on vesicle protein mRNA will help differentiate betweenthe effects of Ca²⁺ influx on gene transcription and mRNAtranslation.

  FOOTNOTES

Received Jan. 8, 2002; revised April 12, 2002; accepted May 7, 2002.

This study was supported by National Institutes of Health Grant EY12031 and by the Coalition for Brain Injury Research. Wethank Dr. John Reeves (Department of Pharmacology and Physiology,University of Medicine and Dentistry of New Jersey) for criticalreading of thismanuscript.

Correspondence should be addressed to Dr. Ellen Townes-Anderson, Department of Neurosciences, University of Medicine and Dentistryof New Jersey, 185 South Orange Avenue, Newark, NJ 07103-2714.E-mail: andersel{at}umdnj.edu.

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DISCUSSION
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