Effects of Dopamine Depletion on Visual Sensitivity of Zebrafish

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The Journal of Neuroscience, March 1, 2000, 20(5):1893-1903

Effects of Dopamine Depletion on Visual Sensitivity of Zebrafish
Lei Li and John E. Dowling
Department of Molecular and Cellular Biology, Harvard University, Cambridge, Massachusetts 02138

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The visual sensitivity of zebrafish in which the retinal dopaminergic interplexiform cells (DA-IPCs) were destroyed by 6-hydroxydopaminewas measured behaviorally. During the first 6-8 min of dark adaptation,visual thresholds of DA-IPC-depleted animals were similar to thoseof control animals. Thereafter, their visual thresholds were elevatedso that by 14-18 min of dark adaptation, they were 2-3 log unitsabove those of control animals. In DA-IPC-depleted animals, theelectroretinogram was normal in terms of light sensitivity andwaveform, but the light threshold for eliciting a ganglion celldischarge was raised by 1.8 log units as compared with controlanimals. No obvious rod system function was detected in DA-IPC-depletedanimals as measured behaviorally. Partial rescue of the behavioralvisual sensitivity loss in DA-IPC-depleted animals occurred whendopamine or a long-acting dopamine agonist (2-amino-6, 7-dihydroxy-1,2, 3, 4-tetrahydronaphthalene hydrobromide) were injected intraocularly.Our data suggest that the principal visual defect shown by DA-IPC-depletedanimals is attributable to effects occurring in the inner retina,mainly on rod signals. We also show that dopamine is involvedin mediating the effect of the circadian clock on visualsensitivity.

Key words: 6-OHDA; circadian clock; dark adaptation; dopamine; dopamine receptor agonist; ADTN; ERG recording; RGC recording; visual sensitivity; zebrafish

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Dopamine plays an important modulatory role in the vertebrate visual system and has been shown to have both direct and indirecteffects on every retinal neuron. Direct dopamine effects on retinalneurons include modulation of rod-cone photoreceptor couplingin frog (Krizaj et al., 1998), altered electrical coupling andglutamate receptor sensitivity of horizontal cells in fish (Teranishiet al., 1983; Knapp et al., 1990), modulation of glutamate-gatedionic currents in bipolar cells of tiger salamander (Maguire andWerblin, 1994), modification of gap junctional permeability betweenamacrine cells in rabbit (Hampson et al., 1992), and regulationof Ca²⁺ currents in ganglion cells of turtle (Liu and Lasater, 1994).The general view advanced from the single cell studies is thatdopamine serves as a light signal in the retina, acting in particularto alter rod-cone input to second order cells (Witkovsky and Dearry,1991). This conclusion has been arrived at by studies performedmainly in the outer retina and on horizontalcells.

In fish retinas, dopamine is released exclusively by dopaminergic interplexiform cells (DA-IPCs) (Dowling and Ehinger, 1975,1978; Dowling, 1991). The DA-IPCs receive most of their synapticinput in the inner plexiform layer, mainly from amacrine cellsand centrifugal fibers, and they make synapses in both the innerand outer plexiform layers (Zucker and Dowling, 1987; Yazullaand Zucker, 1988). It is generally accepted that light, especiallyflickering light, enhances dopamine release in the retina (Kramer,1971; Bauer et al., 1980; Dearry and Burnside, 1989; Kirsch andWagner, 1989; Umino and Dowling, 1991). However, evidence fora prolonged darkness-induced dopamine release also exists (Mangeland Dowling, 1985; Yang et al., 1988a,b; Xin and Bloomfield, 1999).In isolated perch retinas kept in darkness for 2 hr, for example,the level of dopamine was elevated twofold (Weiler et al., 1997).The prolonged darkness-induced dopamine release in the perch retinawas observed only at night, suggesting that the dopamine releaseis also modified by an endogenous circadianoscillator.

Here we report evidence for dopamine modulation of visual sensitivity using behavioral and electrophysiological methods incontrol and DA-IPC-depleted zebrafish. During the course of darkadaptation after bright light adaptation, visual thresholds ofDA-IPC-depleted fish measured behaviorally were similar to thoseof control fish only for the first 6-8 min; thereafter, they increasedand stabilized at levels 2-3 log units above the absolute sensitivitylevel of control fish. The threshold elevation shown by DA-IPC-depletedanimals was caused primarily by a loss of rod system function.In DA-IPC-depleted animals, the electroretinograms (ERGs) werenormal in terms of absolute light sensitivity and response amplitudes,but the light levels required to elicit ganglion cell dischargeswere elevated. No evidence of a circadian regulation of behavioralor ERG sensitivity was observed when DA-IPCs were depleted, incontrast to controls. The behavioral visual sensitivity loss ofDA-IPC-depleted animals was partially rescued when dopamine ora long-acting dopamine agonist were injected intraocularly. Ourdata suggest that dopamine is required for maintenance of rodsystem function as well as for the circadian control of visualsensitivity.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals and maintenance. Zebrafish were maintained as described (Westerfield, 1995). Zebrafish used in this study were 8-14months old. Animals were maintained in a 14-10 hr light/dark cycle(light, 8 A.M.-10 P.M.; intensity, 1.15-2.45 µW/cm²). For some of the circadian experiments, animals were phase-shiftedto a new light/dark cycle (light, 10 P.M.-noon), and visual thresholdswere evaluated after the animals had been in the shifted light/darkcycle for at least 2 weeks. In the continuous darkness experimentsshown in Figures 4-7, visual threshold measurements were made duringthe first day of continuousdarkness.

6-Hydroxydopamine treatment. Methods used for DA-IPC depletion were similar to those as described (Negishi et al., 1982a,b;Lin and Yazulla, 1994a,b). In brief, 2 µl of a mixture of 1:16-hydroxydopamine (6-OHDA) and pargyline (Sigma, St. Louis, MO)(5 µg/µl in PBS) was injected into the vitreous of each eye. Theinjection was repeated the next day. Visual threshold measurementswere made 2 weeks after the injections, except for the recoveryexperiments shown in Figure 2.

Intraocular injection of dopamine and 2-amino-6, 7-dihydroxy-1, 2, 3, 4-tetrahydronaphthalene hydrobromide. Dopamine and along-acting dopamine receptor agonist, 2-amino-6, 7-dihydroxy-1,2, 3, 4-tetrahydronaphthalene hydrobromide (ADTN) (RBI, Natick,MA), were dissolved in PBS before the experiment. One microliterof PBS (control), dopamine (10 µM, 200 µM, or 20 mM), or ADTN(1 µM, 10 µM, or 1 mM) was injected into the vitreous of eacheye of 6-OHDA-treated animals (2 week after injection). The fishwere kept under normal room illumination and were dark-adaptedfor 20 min before thresholdmeasurements.

The behavioral assay. The apparatus used for behavioral analysis of zebrafish visual sensitivity has been described (Li andDowling, 1997). In brief, zebrafish are placed in a clear containersurrounded by a rotating circular drum. A black segment markedon the drum serves as a threatening object. The drum is illuminatedfrom above with a white light (log 0 = 4.60 × 10² µW/cm²) and turned at 10 rpm by a motor. Zebrafish were tested for escaperesponses when they visually encountered the rotating blacksegment.

Unless specified otherwise, visual threshold measurements were made during the late afternoon hours (between 4 and 8 P.M.)when the control zebrafish are most sensitive to light (Li andDowling, 1998). To measure dark adaptation, animals were firstlight-adapted for 15-20 min (3.25 × 10³ µW/cm²). During subsequent dark adaptation, the minimum light intensityfalling on the drum that was required to evoke an escape responsewhen the fish was challenged by the threatening object was recorded.The first threshold measurement was made at 2 min after the startof dark adaptation, then repeated at 2 min intervals, and completedat 26 min of dark adaptation. Log threshold intensity was plottedas a function of time in the dark. To measure the absolute visualsensitivity, animals were kept in complete dark for a minimumof 20 min before a threshold measurement was made. To measureincremental sensitivity, fully dark-adapted animals were exposedto a background light for 2 min (maximum intensity, 4.60 × 10² µW/cm²) before a threshold measurement was made. Background illuminationwas started at the dimmest level, log I = $-$ 8.0, and was increasedby steps of 1 log unit. The threshold measurement was made within10 sec after the background light was turnedoff.

Immunocytochemistry. Methods used for immunocytochemistry were similar as described (Schmitt and Dowling, 1996). Specimenswere fixed in 4% paraformaldehyde in PBS overnight. After theywere blocked with 10% normal goat serum, specimens were incubatedwith primary antiserum [tyrosine hydroxylase (TH), 1:200 (Chemicon,CA); 5E11, 1:10, provided by J. Fadool] overnight and were thenincubated with secondary antibody (FITC-conjugated, 1:50; BoehringerMannheim, Indianapolis, IN) for 2 hr. Specimens were mounted onslides and viewed by fluorescencemicroscopy.

ERG and ganglion cell recordings. Methods used for ERG recordings have been described (Li and Dowling, 1997, 1998). Zebrafishwere anesthetized with 4% 3-amino benzoic acid methylester andimmobilized with 10% gallamine triethiodide. Zebrafish were dark-adaptedfor 20-30 min before an ERG was recorded. The fish were illuminatedwith 500 msec flashes (full field, maximum intensity, 6.75 × 10³ µW/cm²). The electrical signals were recorded using a glass pipette(filled with a balanced salt solution) placed on the center ofthecornea.

Ganglion cell action potentials were recorded from the optic nerve using a tungsten microelectrode (Frederick Haer, Inc.).Fish were anesthetized and immobilized as described above. Theconnective tissue surrounding the eye was cut using a pair ofmicrosurgery scissors. The eye was pulled out of the orbit slightly(by 1-2 mm) and held with two glass rods to expose the optic nerve.The fish were illuminated with 500 msec white light flashes (fullfield, the same light source used for ERG recordings). The ganglioncell discharge was amplified and recorded conventionally. In mostcases, we recorded ganglion cell discharges simultaneously fromfour to six cells. Our criterion for threshold was the observationof an obvious increase in ganglion cell discharge on theoscilloscope.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Depletion and regeneration of retinal DA-IPCs

Retinal DA-IPCs were depleted by intraocular injections of 6-OHDA. The depletion and subsequent regeneration of DA-IPCs weremonitored by examining the cells immunoreactive to TH in the retina(Negishi et al., 1982a,b; Lin and Yazulla, 1994a,b). To ensurethat other retinal neurons were unaffected by 6-OHDA injections,we examined 6-OHDA-treated retinas using conventional histologicaland immunocytochemical methods [with 5E11, an antibody againstzebrafish amacrine cells (Fadool et al., 1999)]. No obvious differencesin the number and appearance of other inner retinal neurons wereobserved between control and 6-OHDA-treatedretinas.

Figure 1 shows confocal images of DA-IPCs taken from the nasal/ventral region of flat-mounted retinas. In control animals,DA-IPCs were found scattered quite evenly across much of the retina.The total number of DA-IPCs in control retinas varied somewhatfrom animal to animal, from ~1100 to 1300 cells per retina (n= 12). At 2 weeks after injection, virtually all of the DA-IPCswere gone, although an occasional TH-positive cell was observed(Fig. 1C). DA-IPCs gradually regenerated after the 6-OHDA treatment.At 8 weeks after injection, for example, regenerated DA-IPCs wereseen in the peripheral regions of the retina (Fig. 1D). The regenerationof DA-IPCs continued over time. By 24 weeks after injection, DA-IPCswere observed in both the peripheral and middle regions of theretina. However, the regeneration of DA-IPC was not complete evenafter 40 weeks of 6-OHDA treatment. At 9 months after injection,for example, only ~650 DA-IPCs were observed (Fig. 1E) (n = 2).Furthermore, most of the regenerated DA-IPCs (>450) were foundin the peripheral outer third of the retina. TH-positive processesthat grew out from regenerated DA-IPCs were observed projectinginto the central regions of the retina.

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Figure 1. Confocal images of DA-IPCs. A, A schematic drawing of a flat-mounted retina. Dorsal is up, and anterior is to the left. The filled circle roughly in the center of the retina indicates the optic disk. The box drawn in the nasal/ventral region of the retina indicates the location of confocal images shown in B-G. B, A confocal image showing DA-IPCs from a control retina. DA-IPCs (bright staining) were stained with an antibody against tyrosine hydroxylase. C-E, Confocal images showing the retina at 2 weeks (C), 16 weeks (D), and 9 months (E) after the 6-OHDA treatment. At 2 weeks after injection, only an occasional TH-positive cell was detected in the retina (arrow). At 16 weeks and 9 months, more TH-positive cells were observed, especially in the peripheral regions of the retina. F, G, Enlarged pictures showing DA-IPCs as well as their processes in control (F) and 9 month post-injection 6-OHDA treated (G) retinas. Scale bar: B-E, 80 µm; F, G, 40 µm.

The somata of newly regenerated DA-IPCs appeared to be smaller than those of DA-IPCs in control fish. The somata of DA-IPCsobserved in the peripheral regions of 2 and 8 week post-injectedretinas were ~7-11 µm in diameter (Fig. 1C, D), whereas they were~13-17 µm in the same region of the control fish (Fig. 1B). Overtime, the somata of regenerated DA-IPCs became larger and eventuallywere comparable in size to those of control fish (Fig. 1E). At9 months after injection, TH-positive processes that grew outfrom regenerated DA-IPCs (Fig. 1G) were similar in appearanceto those of the control animals (Fig. 1F).

Rod system function is not evident in dark-adapted DA-IPC-depleted animals

We evaluated behaviorally the visual sensitivity of 6-OHDA-treated animals. During dark adaptation after bright light adaptation,we measured the light thresholds needed to evoke escape responseswhen the fish were challenged by a threatening object. The firstthreshold measurement was made 2 min after the start of dark adaptation,then repeated in 2 min intervals, and completed at 26 min of darkadaptation (Li and Dowling, 1997).

The results are shown in Figure 2A. Thresholds determined between 2 and 8 min of dark adaptation were not significantly differentbetween control and 6-OHDA-treated animals (2, 8, and 16 weeksafter injections; n = 12 for each group). However, between 8 and14 min of dark adaptation, visual thresholds of 2 week post-injectionanimals () increased somewhat. In contrast, the behavioral visualthresholds of control fish () decreased substantially until theyplateaued at 20 min of dark adaptation, at which time they were~3 log units below the final threshold levels of 2 week post-injectionfish (Fig. 2A). With regeneration of DA-IPCs in the retina, visualthresholds of 6-OHDA-treated fish gradually recovered. By 8 weeksafter injection ( $triangle$ ), the final thresholds were ~2 log units abovecontrol thresholds, and by 16 weeks ( $open circle$ ), thresholds determinedat 20 min of dark adaptation were similar to those of controlfish () (Fig. 2A). Visual thresholds of four sham-injected zebrafish(injected with PBS) were also evaluated using the same procedureas described above. No obvious differences in behavioral visualsensitivity were observed between sham-injected and control fish(data not shown).

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Figure 2. Dark adaptation curves determined using white (A) and colored (B) illumination of the rotating drum. A, Dark adaptation curves of control (, n = 12) and 6-OHDA-treated animals (, 2 weeks after injection; $triangle$ , 8 weeks after injection; $open circle$ , 16 weeks after injection; n = 12 for each group). Between 2 and 8 min of dark adaptation, thresholds measured in 6-OHDA-treated animals were similar to thresholds measured in control fish. Note the rise in thresholds in 2 and 8 week post-injection animals between 8 and 14 min of dark adaptation. B, Dark adaptation curves determined using red (625 nm, open symbols) and green (500 nm, filled symbols) illumination of the rotating drum in control (circles, n = 8) and 6-OHDA-treated (2 weeks after injection; squares, n = 8) animals. In control animals, the threshold difference determined using these two filters was <0.3 log units at 6 min but >2 log units at 20 min of dark adaptation. At all times during dark adaptation, no threshold differences with red or green illumination were observed in 6-OHDA-treated animals. Note the threshold elevation in 6-OHDA-treated fish between 6 and 16 min of dark adaptation. Data represent the means ± SE.

The final visual thresholds of 2-week post-injection fish (referred to as DA-IPC-depleted) were raised by 2-3 log units andreached levels comparable to cone system thresholds in controlfish (Fig. 2A). To determine whether the threshold elevation inDA-IPC-depleted animals is caused by a loss of rod system function,we measured the course of dark adaptation using red (625 nm) andgreen (500 nm) illumination that was closely matched phototopically.The results are shown in Figure 2B. In control animals (n = 8),thresholds determined in green light () were slightly lower duringthe first 6 min of dark adaptation as compared with the thresholdsdetermined in red light ( $open circle$ ), but thereafter they deviated substantially.For example, the threshold differences determined with the redand green lights were <0.3 log units when measured at 6 min ofdark adaptation, but they increased to >2.0 log units when measuredat 20 min of dark adaptation. This is the classic Purkinje phenomenon;during early dark adaptation, retina is relatively red sensitive(governed by cones) and later it is more green sensitive (governedby rods) [see also Li and Dowling (1998)].

At all times during dark adaptation, visual thresholds determined with the red () and green ( $black-square$ ) lights were similar in DA-IPC-depletedanimals (n = 8) (Fig. 2B). For the first 6 min in the dark, visualthresholds of DA-IPC-depleted fish decreased; thereafter, theyincreased until they plateaued at 14-16 min of dark adaptation.The finding that DA-IPC-depleted animals were equally sensitiveto the red and green lights during the entire course of dark adaptationsuggests that the rod system is not functioning in the absenceof dopamine in the retina. Furthermore, the fact that the finalvisual thresholds (measured at 20 min of dark adaptation) of DA-IPC-depletedanimals were higher than the thresholds measured at 6-8 min ofdark adaptation suggests that there is also a cone system deficitin dark-adaptedanimals.

Cone system function is normal in DA-IPC-depleted animals in bright light

We next evaluated incremental sensitivity of control and DA-IPC-depleted fish. Animals were kept in complete darkness for20 min before the incremental sensitivity measurements were made.Background illumination was started at log I = $-$ 8.0 (maximum light,4.60 × 10² µW/cm²) and increased by steps of 1 logunit.

The results are shown in Figure 3A. With very dim background illumination, i.e., log I = $-$ 8.0, the absolute thresholds measuredin control (, n = 6) and DA-IPC-depleted animals ( $open circle$ , n = 6) weresimilar to those measured in complete darkness; the thresholdsof DA-IPC-depleted animals were ~3 log units higher than the thresholdsof control animals. With increases in background illumination,the thresholds measured in control animals rose gradually. Withbackground illumination of log I = $-$ 5.0, for example, the thresholdsof control fish were elevated ~1.5 log units as compared withthe thresholds measured in complete darkness.

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Figure 3. Incremental sensitivity curves determined using white (A) and colored (B) illumination of the rotating drum. A, Visual thresholds of control (, n = 6) and DA-IPC-depleted ( $open circle$ , n = 6) animals measured behaviorally with white light illumination of the drum. With dim background illumination (between log I = $-$ 8.0 and $-$ 7.0), the visual thresholds of control animals were ~3 log units lower than the visual thresholds of DA-IPC-depleted animals. After bright background illumination (between log I = $-$ 4.0 and log I = 0), the thresholds were similar between these two groups. B, Incremental sensitivity of control (circles, n = 6) and DA-IPC-depleted animals (squares, n = 6) using green (500 nm, filled symbols) or red (625 nm, open symbols) illumination of the rotating drum. In control animals, the threshold difference determined using these two filters was ~2 log units under dim background light (log I < $-$ 5.0) but was less than a half log unit under bright background light (log I > $-$ 1.0). In DA-IPC-depleted animals, no threshold differences were observed using green and red illumination. Data represent the means ± SE.

The thresholds of DA-IPC-depleted animals, on the other hand, remained virtually unchanged as the background illuminationincreased (Fig. 3A). Visual thresholds of control and DA-IPC-depletedanimals thus gradually converged as the background illuminationwas increased, as a result of a substantial threshold increasein the control fish along with a slight threshold decrease inDA-IPC-depleted fish. With bright background illumination (logI > $-$ 3.0), the thresholds of control and DA-IPC-depleted animalswere similar; they then rose together as the background illuminationwas increased further (Fig. 3A).

We next measured incremental sensitivity of control and DA-IPC-depleted animals using phototopically matched red and greenlights. In controls, after exposure to dim levels of white lightbackground illumination (between log I = $-$ 8.0 and log I = $-$ 6.0),the thresholds determined with the green light (500 nm, ) were~2 log units lower than the thresholds determined with the redlight (625 nm, $open circle$ ) (Fig. 3B). These results indicate that retinalfunction is governed by rods under dim background illumination.As the background illumination was increased, the threshold differencesdetermined using the green and red lights became smaller. Withthe brightest background illumination (log I = $-$ 1.0 and 0), thresholdsdetermined in control animals with the red and green lights weresimilar, indicating that visual sensitivity was now controlledby the cone system. In DA-IPC-depleted fish, thresholds determinedin bright (log I = $-$ 1.0 and 0) red () and green ( $black-square$ ) light werevirtually identical to those of the control fish, suggesting thatthe cone system function was normal in bright light. Rod systemfunction, however, was never evident in DA-IPC-depleted animals;at dimmer levels of background illumination (log I < $-$ 3.0), thresholdsmeasured with the red and green lights were always similar inDA-IPC-depleted fish (Fig. 3B).

Outer retinal function in DA-IPC-depleted animals appears normal

We next measured ERG sensitivity to determine whether the loss of rod system function in DA-IPC-depleted animals is causedby a dysfunction in the outer retina. In these experiments, wemeasured the threshold light intensity that was required to elicita threshold ERG (10-20 µV b-wave) using fully dark-adapted animals.Animals were kept in complete darkness for ~30 min before a thresholdERG was recorded. The ERG responses were averaged four to sixtimes to increase the signal-to-noise ratio. The light intensitythat was required to elicit threshold ERGs was similar betweencontrol (n = 6) and DA-IPC-depleted animals (n = 6) (Table 1),suggesting that outer retinal function was normal in the absenceof dopamine in the retina.


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Table 1. Thresholds of ERG and retinal ganglion cell spikes of control and DA-IPC-depleted animals (log I)

The ERGs also appeared normal in DA-IPC-depleted animals when measured with red and green lights. They showed normal thresholdlevels as well as the Purkinje phenomenon. At 6 min of dark adaptation,for example, the ERG threshold differences determined with redand green lights were ~0.3 log units, similar to those of controls(Table 2). At 20 min of dark adaptation, the threshold differencesas determined by red and green lights had increased to 1.2 logunits, again, similar to those of control animals (Table 2).


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Table 2. Threshold differences (log I) of ERG sensitivity determined by the red and green lights during dark adaptation

Inner retina function of DA-IPC-depleted animals is abnormal

To determine whether the threshold elevation in DA-IPC-depleted animals is caused by abnormalities occurring in the innerretina, we measured threshold light intensities that were requiredto elicit a retinal ganglion cell discharge in the optic nerve(Fig. 4). In most cases, we recorded simultaneously from fourto six cells. Our criterion for ganglion cell threshold was theobservation of an increase of ganglion cell discharge on the oscilloscopescreen.

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Figure 4. Representative ganglion cell discharge histograms from control (left) and DA-IPC-depleted zebrafish (right). Light responses to 0.5 sec of bright (log I = $-$ 1.0), medium (log I = $-$ 3.0), and dim (log I = $-$ 5.0) illumination were recorded from the optic nerve. With bright and medium illumination, ganglion cell ON and OFF responses were recorded from both control and DA-IPC-depleted fish. No obvious ganglion cell discharge was observed in DA-IPC-depleted animals when tested with dim illumination, unlike the control fish in which both ON and OFF responses were recorded, along with some sustained discharge, to this light level. on, ON responses; off, OFF responses. Calibration (bottom center): 40 spikes/sec.

Threshold light intensities that were required to fire action potentials in retinal ganglion cells were elevated in DA-IPC-depletedanimals. On average, the threshold was 1.8 log units higher inDA-IPC-depleted animals (n = 10) than in control animals (n =12) (Table 1). This result suggests that the visual defect causedby DA-IPC depletion occurs primarily in the innerretina.

The circadian rhythm of behavioral and ERG sensitivity is lost in DA-IPC-depleted animals

To determine whether the circadian rhythm of visual sensitivity persists in the absence of dopamine in the retina, we evaluatedvisual sensitivity of DA-IPC-depleted animals as a function oftime of day while animals were kept in constant darkness (DD).We measured visual thresholds behaviorally as well as by the ERG.For behavioral threshold measurements, the experiments were repeatedat 3-4 hr intervals over a 24 hr period. In controls (, n = 6),the behavioral visual thresholds fluctuated systematically betweensubjective day and night; they were highest at subjective dawnand lowest at subjective dusk (Fig. 5). In DA-IPC-depleted animals( $open circle$ , n = 6), on the other hand, visual thresholds were maintainedat a constant level; at all times during subjective day and night,they were 2-3 log units higher than the thresholds measured atsubjective dusk in control animals (Fig. 5).

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Figure 5. Absolute visual sensitivity of control (, n = 6 for each time point) and DA-IPC-depleted fish ( $open circle$ , n = 6 for each time point) measured behaviorally as function of time of day. Animals were kept in DD during the experiment. Note the threshold variation in the control fish between subjective day and night. In DA-IPC-depleted fish, on the other hand, the behavioral visual sensitivity was maintained at a constant level, ~3.0 log units above the most sensitive level of the control fish. Horizontal black bars indicate subjective night; hatched bars indicate subjective day. Data represent the means ± SE.

ERG thresholds were measured at four time points: subjective dawn, noon, dusk, and midnight, over a 24 hr period. We recordedERG sensitivity of both the rod and cone systems. For rod sensitivitymeasurements, animals were kept in complete darkness. The onlylight the fish were exposed to was the test light, which was keptclose to threshold levels. For cone sensitivity measurement, dark-adaptedanimals were exposed to background light for 2-3 min before athreshold measurement was made (log I = $-$ 3.0, the same backgroundlight used for incremental sensitivity measurement; under thislevel of illumination, no behavioral rod system function was evident)(Fig. 3A). The threshold light that was required to elicit a thresholdERG (10-15 µV b-wave) was recorded immediately (within 10 sec)after the background light was turnedoff.

The results are shown in Figure 6A,B. In control animals (; n = 6 for each time point), both the rod and cone thresholdsfluctuated by ~1.0 log units between subjective dawn and dusk.They were highest at dawn, then fell gradually, reaching theirlowest levels at dusk, and were higher again at subjective midnight.Circadian regulation of the rod and cone system ERG sensitivitywas abolished in DA-IPC-depleted animals. In DA-IPC-depleted animals( $open circle$ , n = 6 for each time point), both the rod and cone thresholdswere maintained at a constant level throughout the day and night,close to the threshold levels measured at subjective dusk in controlanimals.

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Figure 6. Rod (A) and cone (B) sensitivity determined by the ERG as function of time of day. Animals were kept in DD during the experiment. A, ERG sensitivity of rods. Note the systematic threshold variation in control fish (, n = 6 for each time point) between subjective day and night. No threshold variation was seen in DA-IPC-depleted retinas ( $open circle$ , n = 6 for each time point). B, ERG sensitivity of cones. Animals were light-adapted with log I = $-$ 3.0 for 2 min before the test. Threshold variation as a function of time of day was observed in the control fish (, n = 6 for each time point) but was not observed in DA-IPC-depleted fish ( $open circle$ , n = 6 for each time point). Horizontal black bars indicate subjective night; hatched bars indicate subjective day. Data represent the means ± SE.

The ERG waveforms were similar between control and DA-IPC-depleted animals. Figure 7 shows representative ERGs of a controland a DA-IPC-depleted fish recorded at subjective dawn and atdusk. At subjective dusk, both ON and OFF responses were observed.At subjective dawn, however, only ON responses were recorded.We plotted the ERG b-wave amplitude over 4 log units of lightintensity, a V-log I curve. In control animals (n = 6 at eachtime for each group), ERG b-wave amplitudes generated at all lightintensities were reduced at subjective dawn ( $black-square$ ) as compared withthose generated at subjective dusk (, Fig. 8A). The V-log I curvedetermined at subjective dawn was shifted to the right on theintensity axis by 1.0 log units as compared with the V-log I curvedetermined at subjective dusk. ERG V-log I curves of DA-IPC-depletedanimals, on the other hand, were similar when determined at subjectivedawn () and dusk ( $open circle$ , n = 6 at each time for each group) (Fig.8B). The ERG thresholds of DA-IPC-depleted animals were similarto those of control animals determined at subjective dusk, butthe maximal ERG amplitudes were reduced in DA-IPC-depleted animalsas compared with those of control animals.

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Figure 7. Representative ERGs recorded from a control and a DA-IPC-depleted fish at subjective dawn and dusk in animals kept in DD. Note at subjective dusk, both ON and OFF responses were recorded in both the control and DA-IPC-depleted fish. No OFF responses were evident at subjective dawn in either fish. OFF responses are indicated by arrows. Stimuli, 500 msec. Calibration, 100 µV.

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Figure 8. V-log I curves of control (A) and DA-IPC-depleted (B) fish at subjective dawn and dusk (n = 6 for each time point). Animals were kept in DD during the experiment. A, In control fish, the ERG sensitivity was reduced by ~1 log unit at subjective dawn ( $black-square$ ) as compared with ERG sensitivity at subjective dusk (); the V-log I curve determined at dawn was shifted to the right by ~1 log unit as compared with that determined at dusk. B, No ERG sensitivity changes were observed in DA-IPC-depleted animals between subjective dawn () and dusk ( $open circle$ ). Note that the V-log I curves were similar between dawn and dusk in DA-IPC-depleted fish. Data represent the means ± SE.

Dopamine and a dopamine agonist rescue partially the loss of visual sensitivity of DA-IPC-depleted animals

Both behavioral and electrophysiological findings presented in this paper suggest that dopamine is required for rod signaltransmission through the inner plexiform layer of the retina.An obvious question is whether dopamine exogenously applied tothe retina can reverse the loss of visual sensitivity observedin DA-IPC-depleted animals. To this end, intraocular injectionsof dopamine and a long-acting dopamine agonist, ADTN (Miller etal., 1974; Nicola et al., 1996), were performed. One microliterof PBS (for control), dopamine, or ADTN was injected into eacheye of the DA-IPC-depleted animals. Behavioral threshold measurementswere made at 0.5, 1, and 2 hr (for PBS and dopamine injections)and 1, 2, and 4 hr after injections (for ADTNinjections).

Both dopamine and ADTN significantly decreased the behavioral visual threshold of DA-IPC-depleted animals when applied atmoderate concentrations. Thirty minutes after the injection ofdopamine (200 µM), 6 of 10 animals showed visual threshold decreasesequal to or greater than 0.5 log units as compared with lightthreshold measured before dopamine injections. At 30 min and 1hr after the dopamine injection, the average visual thresholdof DA-IPC-depleted animals was 0.5 and 0.3 log units, respectively,below the threshold level measured before dopamine injections.An effect of dopamine on visual sensitivity was not obvious at2 hr after injection (Fig. 9B).

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Figure 9. Behaviorally measured visual thresholds of DA-IPC-depleted animals before and after intraocular injections of PBS (A), dopamine (B), and the dopamine receptor agonist ADTN (C). A, As a control, fish (n = 10) were sham-injected with PBS. No significant visual threshold changes were observed after PBS injections. B, Dopamine intraocularly injected at a concentration of 200 µM. Note the threshold decreases at 30 min and 1 hr after dopamine injection (n = 10; p < 0.001). At 2 hr after injection, the thresholds of DA-IPC-depleted animals returned to levels similar to those measured before dopamine injections. C, ADTN intraocularly injected at a concentration of 10 µM. At 1 and 2 hr after injection, visual thresholds of DA-IPC-depleted animals (n = 16) were significantly decreased (p < 0.001). The effect of ADTN on behavioral visual sensitivity was insignificant at 4 hr after injection. Data represent the means ± SE.

Intraocular injections of ADTN decreased the visual thresholds of DA-IPC-depleted animals more convincingly. At 1 hr afterADTN (10 µM) injections, 12 of 16 tested fish showed thresholddecreases equal to or greater than 0.5 log units as compared withthresholds measured before ADTN injections. The average visualthreshold measured at 1 and 2 hr after injection was 1.0 log unitbelow the threshold level measured before ADTN injections. Theeffects of ADTN on behavioral visual sensitivity decreased withtime. At 4 hr after injection, the behavioral visual thresholdsof DA-IPC-depleted animals had returned to levels similar to thosemeasured before ADTN injections (Fig. 9C).

Intraocular injections of either a low or high concentration of dopamine or ADTN produced no or little effect on behavioralvisual thresholds of DA-IPC-depleted animals. For example, 30min after an injection of dopamine (10 µM or 20 mM), the behavioralvisual thresholds of DA-IPC-depleted animals (n = 10) remainedvirtually unchanged. ADTN applied at 1 µM caused no effect onbehavioral visual sensitivity, whereas ADTN at 1 mM concentrationdecreased only slightly the visual thresholds of DA-IPC-depletedanimals. At 1 hr after ADTN injection (1 mM), the average visualthreshold of DA-IPC-depleted animals (n = 6) was 0.2 log unitsbelow the threshold level measured before ADTN injections. Intraocularinjections of PBS (sham injection, n = 10) produced no effecton behavioral visual sensitivity of DA-IPC-depleted animals (Fig.9A).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have measured visual sensitivity behaviorally as well as by the ERG and ganglion cell discharge in zebrafish in which theretinal DA-IPCs were depleted by treatment with 6-OHDA. Duringthe course of dark adaptation after bright light adaptation, thebehavioral visual thresholds of DA-IPC-depleted animals were similarto those of control fish only for the first 6-8 min; thereafter,they increased and stabilized 2-3 log units above the absolutesensitivity levels of control fish. In DA-IPC-depleted animals,the threshold elevation was observed under dim background illumination.However, after bright background illumination, visual thresholdsof DA-IPC-depleted animals and control animals were similar. Byprobing the spectral sensitivity using phototopically matchedred and green lights, we found that the threshold elevation inDA-IPC-depleted animals was caused primarily by a loss of rodsystem function. ERG measurements indicate that the rod photoreceptorcells themselves appear to function properly in DA-IPC-depletedanimals. Recordings of the ganglion cell discharge suggest thatthe loss of rod system function is caused by effects occurringin the inner retina; rod signals appear to be blocked in the innerplexiform layer in DA-IPC-depletedanimals.

Is dopamine a retinal light signal?

Our results were unanticipated and surprising in view of the generally held view that dopamine serves as a light signal inthe retina. For example, dopamine suppresses rod input while enhancingand speeding up cone input in amphibian horizontal cells (Witkovskyand Dearry, 1991; Witkovsky et al., 1993), and a number of studiesindicate that dopamine is released in the retina in the light(Bauer et al., 1980; Godley and Wurtman, 1988; Witkovsky et al.,1993). Thus, in the absence of dopamine, one would predict thatthe retina is rod-dominated, just the opposite of our findings.In DA-IPC-depleted zebrafish retinas, we find that rod systemfunction is dramatically suppressed as measuredbehaviorally.

We are unaware of any other behavioral studies examining rod visual sensitivity in DA-IPC-depleted animals. In humans withParkinson's disease in which retinal dopamine levels are presumablydepressed, a decrease of contrast sensitivity has been reported(Bodis-Wollner et al., 1984, 1987; Bodis-Wollner, 1990; Massonet al., 1993), but no reports on rod sensitivity in such patientshave appeared. In studies of ganglion cells in 6-OHDA-treatedanimals, alterations in receptive field organization have beendescribed, but these experiments were performed in the presenceof background light and did not examine rod system sensitivity[Jensen and Daw, 1984, 1986; Maguire and Smith, 1985 (but seeMaguire and Hamasaki, 1994)]. Lin and Yazulla (1994a) examinedthe tilting behavior of goldfish treated with 6-OHDA. They foundthat under uniform overhead illumination, the goldfish tiltedtoward the side of the unilaterally injected eye, suggesting thatthe light sensitivity of the injected eye was increased. However,the tilting behavior was observed only under light-adapted conditions.Within 2 min of dark adaptation, the tilting disappeared, indicatingthat the tilting phenomenon was cone system-mediated.

One might question whether our behavioral test is truly measuring rod system sensitivity or some other phenomenon. For example,we are asking the animal to distinguish a black segment on a rotatingdrum from surrounding regions whose brightness is varied. Thus,both contrast and movement are involved in the detection task.In patients suffering from Parkinson's disease, a decrease incontrast sensitivity has been reported (Bodis-Wollner, 1990; Massonet al., 1993), but it is hard to relate these findings to thepresent results. That we can plot out classic dark adaptationand incremental sensitivity curves with both cone and rod limbsusing our behavioral test [see also Li and Dowling (1997, 1998)and Figs. 2, 3] suggests that our technique does measure lightsensitivity of the rod and cone systems inzebrafish.

That we can partially rescue the loss of behavioral visual sensitivity of DA-IPC-depleted fish by an ocular injection of dopamineor a dopamine agonist provides evidence that dopamine is indeedrequired for the maintenance of light sensitivity in zebrafish.Do our other findings match earlier results? Both Lin and Yazulla(1994b) and Maguire and Smith (1985) found that the sensitivityand waveform of ERGs recorded from goldfish and cats treated with6-OHDA were normal, in accord with our finding that the ERG isessentially normal in DA-IPC-depleted zebrafish. These studiesall suggest that the outer retina is functioning reasonably normallyin DA-IPC-depleted animals. However, the a- and b-waves of theERG arise mainly from the photoreceptor, on-bipolar, and Müllercells. Significant alterations in horizontal cell or off-bipolarcell activity induced by DA-IPC depletion are not likely to beobvious in ERGrecordings.

Dopamine and inner plexiform layer function

A main conclusion of our study is that dopamine depletion in the retina has profound effects in the inner plexiform layer,particularly on rod pathways. Cone system function also appearsto be compromised in DA-IPC-depleted retinas (Fig. 2A). Althoughcone function seems to be normal during the first 6-8 min of darkadaptation, it loses ~1 log unit of sensitivity over the next6-8 min of dark adaptation. This suggests that the light-adaptedcone system in DA-IPC-depleted animals is normal but that thedark-adapted cone system is somewhat abnormal. This conclusionwas confirmed in the incremental sensitivity studies; after exposureto bright backgrounds, the sensitivity of DA-IPC-depleted fishis identical to that of control fish (Fig. 3A).

How might dopamine depletion suppress rod signals in the inner plexiform layer of the retina? In mammals, the rod signal iscarried into the inner plexiform layer by bipolar cells that connectexclusively to rods (Polyak, 1941; Boycott and Dowling, 1969).The rod signal is transmitted to cone bipolar cells via the AIIamacrine cells, which receive substantial dopaminergic input (Kolband Famiglietti, 1974; Famiglietti and Kolb, 1975; Dacheux andRaviola, 1986). One could imagine that for the rod signal to betransmitted from the rod to cone bipolar cells in the inner plexiformlayer, some dopamine is required. Although it is generally agreedthat light enhances dopamine release in the retina, there is substantialevidence that dopamine is also released in darkness (Mangel andDowling, 1985; Yang et al., 1988a,b; Weiler et al., 1997; Xinand Bloomfield, 1999).

In cold-blooded vertebrates such as fish, there are no known bipolar cells that are rod specific. All bipolar cells that connectto rods also receive some cone input (Stell, 1967; Scholes, 1975).Furthermore, it is believed that these bipolar cells innervateganglion cells directly, providing the ganglion cells with bothrod and cone signals. It is thus difficult to hypothesize howrod signals could be selectively blocked in the inner plexiformlayer of cold-blooded vertebrates such as zebrafish. However,we have observed in zebrafish that an extensive plexus of DA-IPCprocesses coexists in the lower part of the inner plexiform layerwith the large rod-dominated bipolar cell terminals [E. A. Schmittand J. E. Dowling, unpublished observations; see also Yazullaand Studholme (1997)]. Thus, the terminals of the large, rod-dominatedbipolar cells in zebrafish would appear to have ready access to,or even be bathed in,dopamine.

Dopamine and retinal circadian rhythmicity

We previously reported that the absolute visual sensitivity of zebrafish measured behaviorally varies by ~2 log units betweenearly morning and late afternoon hours (Li and Dowling, 1998).This rhythmicity of visual sensitivity persists in animals keptin continuous darkness, showing that the rhythm is endogenous.A rhythm in ERG sensitivity to light was also demonstrated, butthe extent of threshold variation was only ~l.0 log unit, suggestingthat regulation of visual sensitivity by the circadian clock mechanismoccurs at several different levels in the visual system (Li andDowling, 1998). Several studies have suggested that dopamine isa circadian clock modulator in the retina (Besharse and Iuvone,1983; Kolbinger et al., 1990; McCormack and Burnside, 1992; Manglapuset al., 1999). We measured behaviorally as well as by ERG thevisual sensitivity of DA-IPC-depleted animals as a function oftime of day. No evidence of circadian control of behavioral orERG sensitivity was detected in DA-IPC-depleted animals, unlikein control animals. The ERG sensitivity of DA-IPC-depleted animalswas at all times close to the sensitivity of control animals inthe late afternoon hours, when the ERG is maximally sensitive(Fig. 6). This suggests that the circadian mechanism acts by decreasingvisual sensitivity [see also Li and Dowling (1998)]; that is,visual sensitivity is maximal in the absence of the clock. Itmay be the case that not all circadian effects are absent in DA-IPC-depletedanimals. For example, an OFF-response is observed in the dark-adaptedERG of control fish at subjective dust but not at subjective dawn(Fig. 7). In DA-IPC-depleted fish, an ERG OFF-response is observedat subjective dusk but not at subjective dawn, like the controlfish (Fig. 7).

Retinal dopaminergic mechanisms and nbb^+/ mutant fish

The rationale for the experiments described in this paper was to test the hypothesis that the visual deficits exhibited bynbb^+/ mutants are related to a malfunction of the dopamine system inthe retina [accompanying paper (Li and Dowling, 2000)]. In manyways, depletion of the DA-IPCs in wild-type zebrafish mimics thevisual defects of nbb^+/ mutants. In both situations, the visual defect is primarily ofthe rod system. However, in the nbb^+/ mutants, rod system activity measured behaviorally fluctuatesdramatically over time, whereas in DA-IPC-depleted animals, therod system appears completely knocked out. We have recently foundthat in nbb^+/ mutants in which the DA-IPCs have been depleted, the behavioralvisual thresholds are constant throughout the day and night andidentical to those of DA-IPC-depleted wild-type zebrafish (Fig.5).

In both situations, light sensitizes the retina. That is, the retina appears more normal in the early phases of dark adaptationor after exposure to bright background illumination. In nbb^+/ fish, light sensitizes both the rods and cones. Quite normalrod and cone function is measured for the first 30 min of darkadaptation; thereafter, visual thresholds rise and begin to fluctuate.In DA-IPC-depleted fish, visual thresholds are normal only forthe first 6-8 min of dark adaptation, during the cone componentof dark adaptation. Thereafter, the visual thresholds rise by~1.0 log unit and then stabilize. No evidence of any rod systemfunction is seen during any time of dark adaptation. The ERGsof both nbb^+/ and DA-IPC-depleted fish are quite normal. On the other hand,ganglion cell thresholds are abnormal in both cases, suggestingthat the defects exhibited by both types of animal are manifestin the innerretina.

A possible explanation for the differences between nbb^+/ and DA-IPC-depleted fish is that DA-IPC-depleted animals representthe extreme case of the nbb^+/ defect. In the nbb^+/ mutation, although there is a defect in DA-IPCs, these cellsdo function to some extent. Indeed, they may act normally on occasion,explaining the fact that during dark adaptation, the visual thresholdsof nbb^+/ and wild-type fish may be indistinguishable at times. In DA-IPC-depletedanimals, on the other hand, the DA-IPCs are completely knockedout, giving rise to the more severe invariant phenotype. Thatis, the visual sensitivity is always raised, and no thresholdfluctuations areseen.

Regeneration of DA-IPCs

A final comment concerns the fact that visual threshold recovery occurs in 6-OHDA-treated retinas well before there is completeregeneration of the DA-IPCs. Indeed, the dark adaptation curveof 6-OHDA-treated animals returns to normal after just 16 weeksof recovery, whereas even after 40 weeks after 6-OHDA treatmentthe number of DA-IPC cells in the retina is only half the normalnumber [see also Yazulla and Studholme (1997)]. A conclusion thatcan be drawn from these observations is that a full complementof DA-IPCs is not needed for the maintenance of rod system functionin the retina. Several reasons for this may be advanced. For example,the DA-IPCs that have regenerated in the retina may extend theirprocesses all over the retina, or dopamine diffusing throughoutthe retina from the regenerated DA-IPCs may be sufficient to maintainnormal rod and cone visualsensitivity.

Conclusions

The main conclusion of this study is that dopamine appears to be required for the transmission of rod signals through theinner plexiform layer. In DA-IPC-depleted animals, no rod systemactivity can be detected behaviorally, but outer plexiform layerfunction appears relatively normal in these animals, as determinedby ERG recordings. However, circadian regulation of ERG lightsensitivity is not observed in DA-IPC-depleted animals. Becausecircadian mechanisms serve to decrease ERG sensitivity (Li andDowling, 1998), our findings suggest that the outer retina ismost sensitive to light in the absence of dopamine, the oppositeto that found in the inner retina where dopamine appears to berequired for the transmission of rod signals through the innerplexiform layer. How might one reconcile these apparently discrepantresults? At the present time, we do not have a simple answer.It is worth noting that dopamine has a multiplicity of effectson neurons throughout the retina, and our findings that dopaminehas quite different effects in the outer versus inner retina mayreflect this diversity of dopamineactions.

  FOOTNOTES

Received Oct. 5, 1999; revised Dec. 16, 1999; accepted Dec. 17, 1999.

This work was supported by National Institutes of Health Grants EY 00811 and EY 00824. We thank A. Adolph for expert adviceon ERG and ganglion cell recordings. We also thank E. Schmittfor sharing unpublished data, J. Fadool for providing 5E11 antibodies,and W. McCarthy, S. Harris, and S. Sciascia for maintenance ofzebrafish.
Correspondence should be addressed to Lei Li, Department of Physiology, University of Kentucky College of Medicine, 800 RoseStreet, Lexington, KY40536.

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RESULTS
DISCUSSION
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